Your search keyword '"Helfrich MH"' showing total 78 results

1. A new heterozygous mutation (R714C) of the osteopetrosis gene, pleckstrin homolog domain contining family M (with Run Domain) member 1 (PLEKHM1), impairs vesicular acidification and increases tartrate-resistant acid phosphatase secretion in osteoclasts

Author

DEL FATTORE, A, Fornari, R, VAN WESENBEECK, L, DE FREITAS, F, Timmermans, Jp, Peruzzi, B, Cappariello, A, Rucci, Nadia, Spera, G, Helfrich, Mh, VAN HUL, W, Migliaccio, S, and Teti, A.

Published

2008

2. Van Wesenbeeck L, Odgren PR, Coxon FP, Frattini A, Moens P, Perdu B, MacKay CA, Van Hul E, Timmermans JP, Vanhoenacker F, Jacobs R, Peruzzi B, Teti A, Helfrich MH, Rogers MJ, Villa A, Van Hul W

Author

Van Wesenbeeck L, Odgren PR, Coxon FP, Frattini A, Moens P, Perdu B, MacKay CA, Van Hul E, Timmermans JP, Vanhoenacker F, Jacobs R, Peruzzi B, Teti AM, Helfrich MH, Rogers MJ, Villa A, and Van Hul W.

Abstract

This study illustrates that Plekhm1 is an essential protein for bone resorption, as loss-of-function mutations were found to underlie the osteopetrotic phenotype of the incisors absent rat as well as an intermediate type of human osteopetrosis. Electron and confocal microscopic analysis demonstrated that monocytes from a patient homozygous for the mutation differentiated into osteoclasts normally, but when cultured on dentine discs, the osteoclasts failed to form ruffled borders and showed little evidence of bone resorption. The presence of both RUN and pleckstrin homology domains suggests that Plekhm1 may be linked to small GTPase signaling. We found that Plekhm1 colocalized with Rab7 to late endosomal/lysosomal vesicles in HEK293 and osteoclast-like cells, an effect that was dependent on the prenylation of Rab7. In conclusion, we believe PLEKHM1 to be a novel gene implicated in the development of osteopetrosis, with a putative critical function in vesicular transport in the osteoclast.

Published

2007

3. Detection of noncollagenous bone proteins in methylmethacrylate-embedded human bone sections

Author

van Leeuwen, Hans, Derkx, Pieter, Helfrich, MH, Ralston, SH, and Internal Medicine

Published

2003

4. Guidelines for the use and interpretation of assays for monitoring autophagy.

Author

Klionsky, Dj, Abdalla, Fc, Abeliovich, H, Abraham, Rt, Acevedo-Arozena, A, Adeli, K, Agholme, L, Agnello, M, Agostinis, P, Aguirre-Ghiso, Ja, Ahn, Hj, Ait-Mohamed, O, Ait-Si-Ali, S, Akematsu, T, Akira, S, Al-Younes, Hm, Al-Zeer, Ma, Albert, Ml, Albin, Rl, Alegre-Abarrategui, J, Aleo, Mf, Alirezaei, M, Almasan, A, Almonte-Becerril, M, Amano, A, Amaravadi, R, Amarnath, S, Amer, Ao, Andrieu-Abadie, N, Anantharam, V, Ann, Dk, Anoopkumar-Dukie, S, Aoki, H, Apostolova, N, Arancia, G, Aris, Jp, Asanuma, K, Asare, Ny, Ashida, H, Askanas, V, Askew, D, Auberger, P, Baba, M, Backues, Sk, Baehrecke, Eh, Bahr, Ba, Bai, Xy, Bailly, Y, Baiocchi, R, Baldini, G, Balduini, W, Ballabio, A, Bamber, Ba, Bampton, Et, Bánhegyi, G, Bartholomew, Cr, Bassham, Dc, Bast RC, Jr, Batoko, H, Bay, Bh, Beau, I, Béchet, Dm, Begley, Tj, Behl, C, Behrends, C, Bekri, S, Bellaire, B, Bendall, Lj, Benetti, L, Berliocchi, L, Bernardi, H, Bernassola, F, Besteiro, S, Bhatia-Kissova, I, Bi, X, Biard-Piechaczyk, M, Blum, J, Boise, Lh, Bonaldo, P, Boone, Dl, Bornhauser, Bc, Bortoluci, Kr, Bossis, I, Bost, F, Bourquin, Jp, Boya, P, Boyer-Guittaut, M, Bozhkov, Pv, Brady, Nr, Brancolini, C, Brech, A, Brenman, Je, Brennand, A, Bresnick, Eh, Brest, P, Bridges, D, Bristol, Ml, Brookes, P, Brown, Ej, Brumell, Jh, Brunetti-Pierri, N, Brunk, Ut, Bulman, De, Bultman, Sj, Bultynck, G, Burbulla, Lf, Bursch, W, Butchar, Jp, Buzgariu, W, Bydlowski, Sp, Cadwell, K, Cahová, M, Cai, D, Cai, J, Cai, Q, Calabretta, B, Calvo-Garrido, J, Camougrand, N, Campanella, M, Campos-Salinas, J, Candi, E, Cao, L, Caplan, Ab, Carding, Sr, Cardoso, Sm, Carew, J, Carlin, Cr, Carmignac, V, Carneiro, La, Carra, S, Caruso, Ra, Casari, G, Casas, C, Castino, R, Cebollero, E, Cecconi, F, Celli, J, Chaachouay, H, Chae, Hj, Chai, Cy, Chan, Dc, Chan, Ey, Chang, Rc, Che, Cm, Chen, Cc, Chen, Gc, Chen, Gq, Chen, M, Chen, Q, Chen, S, Chen, W, Chen, X, Chen, Yg, Chen, Y, Chen, Yj, Chen, Z, Cheng, A, Cheng, Ch, Cheng, Y, Cheong, H, Cheong, Jh, Cherry, S, Chess-Williams, R, Cheung, Zh, Chevet, E, Chiang, Hl, Chiarelli, R, Chiba, T, Chin, L, Chiou, Sh, Chisari, Fv, Cho, Ch, Cho, Dh, Choi, Am, Choi, D, Choi, K, Choi, Me, Chouaib, S, Choubey, D, Choubey, V, Chu, Ct, Chuang, Th, Chueh, Sh, Chun, T, Chwae, Yj, Chye, Ml, Ciarcia, R, Ciriolo, Mr, Clague, Mj, Clark, R, Clarke, Pg, Clarke, R, Codogno, P, Coller, Ha, Colombo, Mi, Comincini, S, Condello, M, Condorelli, F, Cookson, Mr, Coombs, Gh, Coppens, I, Corbalan, R, Cossart, P, Costelli, P, Costes, S, Coto-Montes, A, Couve, E, Coxon, Fp, Cregg, Jm, Crespo, Jl, Cronjé, Mj, Cuervo, Am, Cullen, Jj, Czaja, Mj, D'Amelio, M, Darfeuille-Michaud, A, Davids, Lm, Davies, Fe, De Felici, M, de Groot, Jf, de Haan, Ca, De Martino, L, De Milito, A, De Tata, V, Debnath, J, Degterev, A, Dehay, B, Delbridge, Lm, Demarchi, F, Deng, Yz, Dengjel, J, Dent, P, Denton, D, Deretic, V, Desai, Sd, Devenish, Rj, Di Gioacchino, M, Di Paolo, G, Di Pietro, C, Díaz-Araya, G, Díaz-Laviada, I, Diaz-Meco, Mt, Diaz-Nido, J, Dikic, I, Dinesh-Kumar, Sp, Ding, Wx, Distelhorst, Cw, Diwan, A, Djavaheri-Mergny, M, Dokudovskaya, S, Dong, Z, Dorsey, Fc, Dosenko, V, Dowling, Jj, Doxsey, S, Dreux, M, Drew, Me, Duan, Q, Duchosal, Ma, Duff, K, Dugail, I, Durbeej, M, Duszenko, M, Edelstein, Cl, Edinger, Al, Egea, G, Eichinger, L, Eissa, Nt, Ekmekcioglu, S, El-Deiry, W, Elazar, Z, Elgendy, M, Ellerby, Lm, Eng, Ke, Engelbrecht, Am, Engelender, S, Erenpreisa, J, Escalante, R, Esclatine, A, Eskelinen, El, Espert, L, Espina, V, Fan, H, Fan, J, Fan, Qw, Fan, Z, Fang, S, Fang, Y, Fanto, M, Fanzani, A, Farkas, T, Farré, Jc, Faure, M, Fechheimer, M, Feng, Cg, Feng, J, Feng, Q, Feng, Y, Fésüs, L, Feuer, R, Figueiredo-Pereira, Me, Fimia, Gm, Fingar, Dc, Finkbeiner, S, Finkel, T, Finley, Kd, Fiorito, F, Fisher, Ea, Fisher, Pb, Flajolet, M, Florez-McClure, Ml, Florio, S, Fon, Ea, Fornai, F, Fortunato, F, Fotedar, R, Fowler, Dh, Fox, H, Franco, R, Frankel, Lb, Fransen, M, Fuentes, Jm, Fueyo, J, Fujii, J, Fujisaki, K, Fujita, E, Fukuda, M, Furukawa, Rh, Gaestel, M, Gailly, P, Gajewska, M, Galliot, B, Galy, V, Ganesh, S, Ganetzky, B, Ganley, Ig, Gao, Fb, Gao, Gf, Gao, J, Garcia, L, Garcia-Manero, G, Garcia-Marcos, M, Garmyn, M, Gartel, Al, Gatti, E, Gautel, M, Gawriluk, Tr, Gegg, Me, Geng, J, Germain, M, Gestwicki, Je, Gewirtz, Da, Ghavami, S, Ghosh, P, Giammarioli, Am, Giatromanolaki, An, Gibson, Sb, Gilkerson, Rw, Ginger, Ml, Ginsberg, Hn, Golab, J, Goligorsky, M, Golstein, P, Gomez-Manzano, C, Goncu, E, Gongora, C, Gonzalez, Cd, Gonzalez, R, González-Estévez, C, González-Polo, Ra, Gonzalez-Rey, E, Gorbunov, Nv, Gorski, S, Goruppi, S, Gottlieb, Ra, Gozuacik, D, Granato, Ge, Grant, Gd, Green, Kn, Gregorc, A, Gros, F, Grose, C, Grunt, Tw, Gual, P, Guan, Jl, Guan, Kl, Guichard, Sm, Gukovskaya, A, Gukovsky, I, Gunst, J, Gustafsson, Ab, Halayko, Aj, Hale, An, Halonen, Sk, Hamasaki, M, Han, F, Han, T, Hancock, Mk, Hansen, M, Harada, H, Harada, M, Hardt, Se, Harper, Jw, Harris, Al, Harris, J, Harris, Sd, Hashimoto, M, Haspel, Ja, Hayashi, S, Hazelhurst, La, He, C, He, Yw, Hébert, Mj, Heidenreich, Ka, Helfrich, Mh, Helgason, Gv, Henske, Ep, Herman, B, Herman, Pk, Hetz, C, Hilfiker, S, Hill, Ja, Hocking, Lj, Hofman, P, Hofmann, Tg, Höhfeld, J, Holyoake, Tl, Hong, Mh, Hood, Da, Hotamisligil, G, Houwerzijl, Ej, Høyer-Hansen, M, Hu, B, Hu, Ca, Hu, Hm, Hua, Y, Huang, C, Huang, J, Huang, S, Huang, Wp, Huber, Tb, Huh, Wk, Hung, Th, Hupp, Tr, Hur, Gm, Hurley, Jb, Hussain, Sn, Hussey, Pj, Hwang, Jj, Hwang, S, Ichihara, A, Ilkhanizadeh, S, Inoki, K, Into, T, Iovane, V, Iovanna, Jl, Ip, Ny, Isaka, Y, Ishida, H, Isidoro, C, Isobe, K, Iwasaki, A, Izquierdo, M, Izumi, Y, Jaakkola, Pm, Jäättelä, M, Jackson, Gr, Jackson, Wt, Janji, B, Jendrach, M, Jeon, Jh, Jeung, Eb, Jiang, H, Jiang, Jx, Jiang, M, Jiang, Q, Jiang, X, Jiménez, A, Jin, M, Jin, S, Joe, Co, Johansen, T, Johnson, De, Johnson, Gv, Jones, Nl, Joseph, B, Joseph, Sk, Joubert, Am, Juhász, G, Juillerat-Jeanneret, L, Jung, Ch, Jung, Yk, Kaarniranta, K, Kaasik, A, Kabuta, T, Kadowaki, M, Kagedal, K, Kamada, Y, Kaminskyy, Vo, Kampinga, Hh, Kanamori, H, Kang, C, Kang, Kb, Kang, Ki, Kang, R, Kang, Ya, Kanki, T, Kanneganti, Td, Kanno, H, Kanthasamy, Ag, Kanthasamy, A, Karantza, V, Kaushal, Gp, Kaushik, S, Kawazoe, Y, Ke, Py, Kehrl, Jh, Kelekar, A, Kerkhoff, C, Kessel, Dh, Khalil, H, Kiel, Ja, Kiger, Aa, Kihara, A, Kim, Dr, Kim, Dh, Kim, Ek, Kim, Hr, Kim, J, Kim, Jh, Kim, Jc, Kim, Jk, Kim, Pk, Kim, Sw, Kim, Y, Kimchi, A, Kimmelman, Ac, King, J, Kinsella, Tj, Kirkin, V, Kirshenbaum, La, Kitamoto, K, Kitazato, K, Klein, L, Klimecki, Wt, Klucken, J, Knecht, E, Ko, Bc, Koch, Jc, Koga, H, Koh, Jy, Koh, Yh, Koike, M, Komatsu, M, Kominami, E, Kong, Hj, Kong, Wj, Korolchuk, Vi, Kotake, Y, Koukourakis, Mi, Kouri Flores, Jb, Kovács, Al, Kraft, C, Krainc, D, Krämer, H, Kretz-Remy, C, Krichevsky, Am, Kroemer, G, Krüger, R, Krut, O, Ktistakis, Nt, Kuan, Cy, Kucharczyk, R, Kumar, A, Kumar, R, Kumar, S, Kundu, M, Kung, Hj, Kurz, T, Kwon, Hj, La Spada, Ar, Lafont, F, Lamark, T, Landry, J, Lane, Jd, Lapaquette, P, Laporte, Jf, László, L, Lavandero, S, Lavoie, Jn, Layfield, R, Lazo, Pa, Le, W, Le Cam, L, Ledbetter, Dj, Lee, Aj, Lee, Bw, Lee, Gm, Lee, J, Lee, Jh, Lee, M, Lee, Sh, Leeuwenburgh, C, Legembre, P, Legouis, R, Lehmann, M, Lei, Hy, Lei, Qy, Leib, Da, Leiro, J, Lemasters, Jj, Lemoine, A, Lesniak, M, Lev, D, Levenson, Vv, Levine, B, Levy, E, Li, F, Li, Jl, Li, L, Li, S, Li, W, Li, Xj, Li, Yb, Li, Yp, Liang, C, Liang, Q, Liao, Yf, Liberski, Pp, Lieberman, A, Lim, Hj, Lim, Kl, Lim, K, Lin, Cf, Lin, Fc, Lin, J, Lin, Jd, Lin, K, Lin, Ww, Lin, Wc, Lin, Yl, Linden, R, Lingor, P, Lippincott-Schwartz, J, Lisanti, Mp, Liton, Pb, Liu, B, Liu, Cf, Liu, K, Liu, L, Liu, Qa, Liu, W, Liu, Yc, Liu, Y, Lockshin, Ra, Lok, Cn, Lonial, S, Loos, B, Lopez-Berestein, G, López-Otín, C, Lossi, L, Lotze, Mt, Lőw, P, Lu, B, Lu, Z, Luciano, F, Lukacs, Nw, Lund, Ah, Lynch-Day, Ma, Ma, Y, Macian, F, Mackeigan, Jp, Macleod, Kf, Madeo, F, Maiuri, L, Maiuri, Mc, Malagoli, D, Malicdan, Mc, Malorni, W, Man, N, Mandelkow, Em, Manon, S, Manov, I, Mao, K, Mao, X, Mao, Z, Marambaud, P, Marazziti, D, Marcel, Yl, Marchbank, K, Marchetti, P, Marciniak, Sj, Marcondes, M, Mardi, M, Marfe, G, Mariño, G, Markaki, M, Marten, Mr, Martin, Sj, Martinand-Mari, C, Martinet, W, Martinez-Vicente, M, Masini, M, Matarrese, P, Matsuo, S, Matteoni, R, Mayer, A, Mazure, Nm, Mcconkey, Dj, Mcconnell, Mj, Mcdermott, C, Mcdonald, C, Mcinerney, Gm, Mckenna, Sl, Mclaughlin, B, Mclean, Pj, Mcmaster, Cr, Mcquibban, Ga, Meijer, Aj, Meisler, Mh, Meléndez, A, Melia, Tj, Melino, G, Mena, Ma, Menendez, Ja, Menna-Barreto, Rf, Menon, Mb, Menzies, Fm, Mercer, Ca, Merighi, A, Merry, De, Meschini, S, Meyer, Cg, Meyer, Tf, Miao, Cy, Miao, Jy, Michels, Pa, Michiels, C, Mijaljica, D, Milojkovic, A, Minucci, S, Miracco, C, Miranti, Ck, Mitroulis, I, Miyazawa, K, Mizushima, N, Mograbi, B, Mohseni, S, Molero, X, Mollereau, B, Mollinedo, F, Momoi, T, Monastyrska, I, Monick, Mm, Monteiro, Mj, Moore, Mn, Mora, R, Moreau, K, Moreira, Pi, Moriyasu, Y, Moscat, J, Mostowy, S, Mottram, Jc, Motyl, T, Moussa, Ce, Müller, S, Muller, S, Münger, K, Münz, C, Murphy, Lo, Murphy, Me, Musarò, A, Mysorekar, I, Nagata, E, Nagata, K, Nahimana, A, Nair, U, Nakagawa, T, Nakahira, K, Nakano, H, Nakatogawa, H, Nanjundan, M, Naqvi, Ni, Narendra, Dp, Narita, M, Navarro, M, Nawrocki, St, Nazarko, Ty, Nemchenko, A, Netea, Mg, Neufeld, Tp, Ney, Pa, Nezis, Ip, Nguyen, Hp, Nie, D, Nishino, I, Nislow, C, Nixon, Ra, Noda, T, Noegel, Aa, Nogalska, A, Noguchi, S, Notterpek, L, Novak, I, Nozaki, T, Nukina, N, Nürnberger, T, Nyfeler, B, Obara, K, Oberley, Td, Oddo, S, Ogawa, M, Ohashi, T, Okamoto, K, Oleinick, Nl, Oliver, Fj, Olsen, Lj, Olsson, S, Opota, O, Osborne, Tf, Ostrander, Gk, Otsu, K, Ou, Jh, Ouimet, M, Overholtzer, M, Ozpolat, B, Paganetti, P, Pagnini, U, Pallet, N, Palmer, Ge, Palumbo, C, Pan, T, Panaretakis, T, Pandey, Ub, Papackova, Z, Papassideri, I, Paris, I, Park, J, Park, Ok, Parys, Jb, Parzych, Kr, Patschan, S, Patterson, C, Pattingre, S, Pawelek, Jm, Peng, J, Perlmutter, Dh, Perrotta, I, Perry, G, Pervaiz, S, Peter, M, Peters, Gj, Petersen, M, Petrovski, G, Phang, Jm, Piacentini, M, Pierre, P, Pierrefite-Carle, V, Pierron, G, Pinkas-Kramarski, R, Piras, A, Piri, N, Platanias, Lc, Pöggeler, S, Poirot, M, Poletti, A, Poüs, C, Pozuelo-Rubio, M, Prætorius-Ibba, M, Prasad, A, Prescott, M, Priault, M, Produit-Zengaffinen, N, Progulske-Fox, A, Proikas-Cezanne, T, Przedborski, S, Przyklenk, K, Puertollano, R, Puyal, J, Qian, Sb, Qin, L, Qin, Zh, Quaggin, Se, Raben, N, Rabinowich, H, Rabkin, Sw, Rahman, I, Rami, A, Ramm, G, Randall, G, Randow, F, Rao, Va, Rathmell, Jc, Ravikumar, B, Ray, Sk, Reed, Bh, Reed, Jc, Reggiori, F, Régnier-Vigouroux, A, Reichert, A, Reiners JJ, Jr, Reiter, Rj, Ren, J, Revuelta, Jl, Rhodes, Cj, Ritis, K, Rizzo, E, Robbins, J, Roberge, M, Roca, H, Roccheri, Mc, Rocchi, S, Rodemann, Hp, Rodríguez de Córdoba, S, Rohrer, B, Roninson, Ib, Rosen, K, Rost-Roszkowska, Mm, Rouis, M, Rouschop, Km, Rovetta, F, Rubin, Bp, Rubinsztein, Dc, Ruckdeschel, K, Rucker EB, 3rd, Rudich, A, Rudolf, E, Ruiz-Opazo, N, Russo, R, Rusten, Te, Ryan, Km, Ryter, Sw, Sabatini, Dm, Sadoshima, J, Saha, T, Saitoh, T, Sakagami, H, Sakai, Y, Salekdeh, Gh, Salomoni, P, Salvaterra, Pm, Salvesen, G, Salvioli, R, Sanchez, Am, Sánchez-Alcázar, Ja, Sánchez-Prieto, R, Sandri, M, Sankar, U, Sansanwal, P, Santambrogio, L, Saran, S, Sarkar, S, Sarwal, M, Sasakawa, C, Sasnauskiene, A, Sass, M, Sato, K, Sato, M, Schapira, Ah, Scharl, M, Schätzl, Hm, Scheper, W, Schiaffino, S, Schneider, C, Schneider, Me, Schneider-Stock, R, Schoenlein, Pv, Schorderet, Df, Schüller, C, Schwartz, Gk, Scorrano, L, Sealy, L, Seglen, Po, Segura-Aguilar, J, Seiliez, I, Seleverstov, O, Sell, C, Seo, Jb, Separovic, D, Setaluri, V, Setoguchi, T, Settembre, C, Shacka, Jj, Shanmugam, M, Shapiro, Im, Shaulian, E, Shaw, Rj, Shelhamer, Jh, Shen, Hm, Shen, Wc, Sheng, Zh, Shi, Y, Shibuya, K, Shidoji, Y, Shieh, Jj, Shih, Cm, Shimada, Y, Shimizu, S, Shintani, T, Shirihai, O, Shore, Gc, Sibirny, Aa, Sidhu, Sb, Sikorska, B, Silva-Zacarin, Ec, Simmons, A, Simon, Ak, Simon, Hu, Simone, C, Simonsen, A, Sinclair, Da, Singh, R, Sinha, D, Sinicrope, Fa, Sirko, A, Siu, Pm, Sivridis, E, Skop, V, Skulachev, Vp, Slack, R, Smaili, S, Smith, Dr, Soengas, M, Soldati, T, Song, X, Sood, Ak, Soong, Tw, Sotgia, F, Spector, Sa, Spies, Cd, Springer, W, Srinivasula, Sm, Stefanis, L, Steffan, J, Stendel, R, Stenmark, H, Stephanou, A, Stern, St, Sternberg, C, Stork, B, Strålfors, P, Subauste, C, Sui, X, Sulzer, D, Sun, J, Sun, Sy, Sun, Zj, Sung, Jj, Suzuki, K, Suzuki, T, Swanson, M, Swanton, C, Sweeney, St, Sy, Lk, Szabadkai, G, Tabas, I, Taegtmeyer, H, Tafani, M, Takács-Vellai, K, Takano, Y, Takegawa, K, Takemura, G, Takeshita, F, Talbot, Nj, Tan, K, Tanaka, K, Tang, D, Tanida, I, Tannous, Ba, Tavernarakis, N, Taylor, G, Taylor, Ga, Taylor, Jp, Terada, L, Terman, A, Tettamanti, G, Thevissen, K, Thompson, Cb, Thorburn, A, Thumm, M, Tian, F, Tian, Y, Tocchini-Valentini, G, Tolkovsky, Am, Tomino, Y, Tönges, L, Tooze, Sa, Tournier, C, Tower, J, Towns, R, Trajkovic, V, Travassos, Lh, Tsai, Tf, Tschan, Mp, Tsubata, T, Tsung, A, Turk, B, Turner, L, Tyagi, Sc, Uchiyama, Y, Ueno, T, Umekawa, M, Umemiya-Shirafuji, R, Unni, Vk, Vaccaro, Mi, Valente, Em, Van den Berghe, G, van der Klei, Ij, van Doorn, W, van Dyk, Lf, van Egmond, M, van Grunsven, La, Vandenabeele, P, Vandenberghe, Wp, Vanhorebeek, I, Vaquero, Ec, Velasco, G, Vellai, T, Vicencio, Jm, Vierstra, Rd, Vila, M, Vindis, C, Viola, G, Viscomi, Maria Teresa, Voitsekhovskaja, Ov, von Haefen, C, Votruba, M, Wada, K, Wade-Martins, R, Walker, Cl, Walsh, Cm, Walter, J, Wan, Xb, Wang, A, Wang, C, Wang, D, Wang, F, Wang, G, Wang, H, Wang, Hg, Wang, Hd, Wang, J, Wang, K, Wang, M, Wang, Rc, Wang, X, Wang, Yj, Wang, Y, Wang, Z, Wang, Zc, Wansink, Dg, Ward, Dm, Watada, H, Waters, Sl, Webster, P, Wei, L, Weihl, Cc, Weiss, Wa, Welford, Sm, Wen, Lp, 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Zuckerbraun, B., and Viscomi M. T. (ORCID:0000-0002-9096-4967)

Abstract

In 2008 we published the first set of guidelines for standardizing research in autophagy. Since then, research on this topic has continued to accelerate, and many new scientists have entered the field. Our knowledge base and relevant new technologies have also been expanding. Accordingly, it is important to update these guidelines for monitoring autophagy in different organisms. Various reviews have described the range of assays that have been used for this purpose. Nevertheless, there continues to be confusion regarding acceptable methods to measure autophagy, especially in multicellular eukaryotes. A key point that needs to be emphasized is that there is a difference between measurements that monitor the numbers or volume of autophagic elements (e.g., autophagosomes or autolysosomes) at any stage of the autophagic process vs. those that measure flux through the autophagy pathway (i.e., the complete process); thus, a block in macroautophagy that results in autophagosome accumulation needs to be differentiated from stimuli that result in increased autophagic activity, defined as increased autophagy induction coupled with increased delivery to, and degradation within, lysosomes (in most higher eukaryotes and some protists such as Dictyostelium) or the vacuole (in plants and fungi). In other words, it is especially important that investigators new to the field understand that the appearance of more autophagosomes does not necessarily equate with more autophagy. In fact, in many cases, autophagosomes accumulate because of a block in trafficking to lysosomes without a concomitant change in autophagosome biogenesis, whereas an increase in autolysosomes may reflect a reduction in degradative activity. Here, we present a set of guidelines for the selection and interpretation of methods for use by investigators who aim to examine macroautophagy and related processes, as well as for reviewers who need to provide realistic and reasonable critiques of papers that are focused o

Published

2012

5. Immunolocalization of inducible nitric oxide synthase in synovium and cartilage in rheumatoid arthritis and osteoarthritis

Author

Grabowski, PS, Wright, PK, Van t Hof, RJ, Helfrich, MH, Ohshima, H, and Ralston, SH

Published

1997

6. P32. Antibodies to rat osteoclast antigens

Author

Helfrich, MH and Horton, MA

Published

1989

7. P31. Recognition of proteolytically damaged laminins by rat osteoclasts is mediated by β1 and β3 integrins

Author

Horton, MH, Bodary, S, Spragg, JH, and Helfrich, MH

Published

1994

8. Anti-CD30 (Ber-H2) epitope requires structural elements as shown by mass spectroscopy and dual-site associated kinetics.

Author

Warren PD and Smith MH

Subjects

Animals, Mice, Epitopes, Peptides, Mass Spectrometry, Epitope Mapping, Kinetics, Antibodies, Monoclonal metabolism, Ki-1 Antigen analysis, Ki-1 Antigen chemistry

Abstract

The Ber-H2 mouse monoclonal antibody has been in use for 35 years for detecting the CD-30 biomarker in a variety of lymphomas. Despite the wide use of this clone, we have not been successful in applying synthetic peptides derived from the published epitope sequence and affinity data toward the development of a new Ber-H2-based in vitro diagnostic reagent assay. We found that synthetic peptides based on the published epitope sequence do not function to inhibit antibody-binding activity, thus indicating that the sequence is not the full epitope recognized by Ber-H2. In this report, we used mass spectroscopic analysis of proteolyzed CD30 fragments capable of binding Ber-H2 to identify additional regions within the epitope that participate in binding. Using surface plasmon resonance binding kinetic analyses and immuno-histochemical peptide-inhibition assays, we also demonstrate that the epitope sequence as originally reported is missing two key elements necessary for binding the Ber-H2 antibody., (© 2023 Ventana Medical Systems. Journal of Molecular Recognition published by John Wiley & Sons Ltd.)

Published

2023

9. Glycan degradation promotes macroautophagy.

Author

Baudot AD, Wang VM, Leach JD, O'Prey J, Long JS, Paulus-Hock V, Lilla S, Thomson DM, Greenhorn J, Ghaffar F, Nixon C, Helfrich MH, Strathdee D, Pratt J, Marchesi F, Zanivan S, and Ryan KM

Subjects

Animals, Lysosomes metabolism, Mice, alpha-L-Fucosidase genetics, alpha-L-Fucosidase metabolism, Fucosidosis genetics, Fucosidosis metabolism, Macroautophagy physiology, Polysaccharides metabolism

Abstract

Macroautophagy promotes cellular homeostasis by delivering cytoplasmic constituents to lysosomes for degradation [Mizushima, Nat. Cell Biol. 20, 521-527 (2018)]. However, while most studies have focused on the mechanisms of protein degradation during this process, we report here that macroautophagy also depends on glycan degradation via the glycosidase, α-l-fucosidase 1 (FUCA1), which removes fucose from glycans. We show that cells lacking FUCA1 accumulate lysosomal glycans, which is associated with impaired autophagic flux. Moreover, in a mouse model of fucosidosis-a disease characterized by inactivating mutations in FUCA1 [Stepien et al. , Genes (Basel) 11, E1383 (2020)]-glycan and autophagosome/autolysosome accumulation accompanies tissue destruction. Mechanistically, using lectin capture and mass spectrometry, we identified several lysosomal enzymes with altered fucosylation in FUCA1-null cells. Moreover, we show that the activity of some of these enzymes in the absence of FUCA1 can no longer be induced upon autophagy stimulation, causing retardation of autophagic flux, which involves impaired autophagosome-lysosome fusion. These findings therefore show that dysregulated glycan degradation leads to defective autophagy, which is likely a contributing factor in the etiology of fucosidosis.

Published

2022

10. End stage renal disease-induced hypercalcemia may promote aortic valve calcification via Annexin VI enrichment of valve interstitial cell derived-matrix vesicles.

Author

Cui L, Rashdan NA, Zhu D, Milne EM, Ajuh P, Milne G, Helfrich MH, Lim K, Prasad S, Lerman DA, Vesey AT, Dweck MR, Jenkins WS, Newby DE, Farquharson C, and Macrae VE

Subjects

Aged, Alkaline Phosphatase genetics, Alkaline Phosphatase metabolism, Animals, Aortic Valve ultrastructure, Aortic Valve Stenosis etiology, Aortic Valve Stenosis genetics, Aortic Valve Stenosis pathology, Calcinosis etiology, Calcinosis genetics, Calcinosis pathology, Calcium metabolism, Cells, Cultured, Core Binding Factor Alpha 1 Subunit genetics, Core Binding Factor Alpha 1 Subunit metabolism, Extracellular Matrix ultrastructure, Extracellular Vesicles ultrastructure, Female, Homeodomain Proteins genetics, Homeodomain Proteins metabolism, Humans, Hypercalcemia diagnosis, Kidney Failure, Chronic diagnosis, Male, Microscopy, Electron, Transmission, Protein Interaction Maps, Proteomics methods, RNA, Messenger genetics, RNA, Messenger metabolism, Rats, Sprague-Dawley, Up-Regulation, Annexin A6 metabolism, Aortic Valve metabolism, Aortic Valve pathology, Aortic Valve Stenosis metabolism, Calcinosis metabolism, Extracellular Matrix metabolism, Extracellular Vesicles metabolism, Hypercalcemia etiology, Kidney Failure, Chronic complications

Abstract

Patients with end-stage renal disease (ESRD) have elevated circulating calcium (Ca) and phosphate (Pi), and exhibit accelerated progression of calcific aortic valve disease (CAVD). We hypothesized that matrix vesicles (MVs) initiate the calcification process in CAVD. Ca induced rat valve interstitial cells (VICs) calcification at 4.5 mM (16.4-fold; p < 0.05) whereas Pi treatment alone had no effect. Ca (2.7 mM) and Pi (2.5 mM) synergistically induced calcium deposition (10.8-fold; p < 0.001) in VICs. Ca treatment increased the mRNA of the osteogenic markers Msx2, Runx2, and Alpl (p < 0.01). MVs were harvested by ultracentrifugation from VICs cultured with control or calcification media (containing 2.7 mM Ca and 2.5 mM Pi) for 16 hr. Proteomics analysis revealed the marked enrichment of exosomal proteins, including CD9, CD63, LAMP-1, and LAMP-2 and a concomitant up-regulation of the Annexin family of calcium-binding proteins. Of particular note Annexin VI was shown to be enriched in calcifying VIC-derived MVs (51.9-fold; p < 0.05). Through bioinformatic analysis using Ingenuity Pathway Analysis (IPA), the up-regulation of canonical signaling pathways relevant to cardiovascular function were identified in calcifying VIC-derived MVs, including aldosterone, Rho kinase, and metal binding. Further studies using human calcified valve tissue revealed the co-localization of Annexin VI with areas of MVs in the extracellular matrix by transmission electron microscopy (TEM). Together these findings highlight a critical role for VIC-derived MVs in CAVD. Furthermore, we identify calcium as a key driver of aortic valve calcification, which may directly underpin the increased susceptibility of ESRD patients to accelerated development of CAVD., (© 2017 The Authors. Journal of Cellular Physiology Published by Wiley Periodicals, Inc.)

Published

2017

11. SNX10 gene mutation leading to osteopetrosis with dysfunctional osteoclasts.

Author

Stattin EL, Henning P, Klar J, McDermott E, Stecksen-Blicks C, Sandström PE, Kellgren TG, Rydén P, Hallmans G, Lönnerholm T, Ameur A, Helfrich MH, Coxon FP, Dahl N, Wikström J, and Lerner UH

Subjects

Haplotypes, Humans, RANK Ligand metabolism, Sweden, Whole Genome Sequencing, Codon, Nonsense, Frameshift Mutation, Osteoclasts pathology, Osteopetrosis genetics, Osteopetrosis pathology, Sorting Nexins genetics

Abstract

Autosomal recessive osteopetrosis (ARO) is a heterogeneous disorder, characterized by defective osteoclastic resorption of bone that results in increased bone density. We have studied nine individuals with an intermediate form of ARO, from the county of Västerbotten in Northern Sweden. All afflicted individuals had an onset in early infancy with optic atrophy, and in four patients anemia was present at diagnosis. Tonsillar herniation, foramen magnum stenosis, and severe osteomyelitis of the jaw were common clinical features. Whole exome sequencing, verified by Sanger sequencing, identified a splice site mutation c.212 + 1 G > T in the SNX10 gene encoding sorting nexin 10. Sequence analysis of the SNX10 transcript in patients revealed activation of a cryptic splice site in intron 4 resulting in a frame shift and a premature stop (p.S66Nfs * 15). Haplotype analysis showed that all cases originated from a single mutational event, and the age of the mutation was estimated to be approximately 950 years. Functional analysis of osteoclast progenitors isolated from peripheral blood of patients revealed that stimulation with receptor activator of nuclear factor kappa-B ligand (RANKL) resulted in a robust formation of large, multinucleated osteoclasts which generated sealing zones; however these osteoclasts exhibited defective ruffled borders and were unable to resorb bone in vitro.

Published

2017

12. PLEKHM1 regulates Salmonella-containing vacuole biogenesis and infection.

Author

McEwan DG, Richter B, Claudi B, Wigge C, Wild P, Farhan H, McGourty K, Coxon FP, Franz-Wachtel M, Perdu B, Akutsu M, Habermann A, Kirchof A, Helfrich MH, Odgren PR, Van Hul W, Frangakis AS, Rajalingam K, Macek B, Holden DW, Bumann D, and Dikic I

Subjects

Animals, Autophagy-Related Proteins, Carrier Proteins metabolism, Humans, Intracellular Signaling Peptides and Proteins, Membrane Proteins, Mice, Mice, Inbred C57BL, Mice, Knockout, Nuclear Proteins metabolism, Protein Binding, Protein Interaction Mapping, rab GTP-Binding Proteins metabolism, rab7 GTP-Binding Proteins, Adaptor Proteins, Signal Transducing metabolism, Bacterial Proteins metabolism, Glycoproteins metabolism, Host-Pathogen Interactions, Membrane Glycoproteins metabolism, Salmonella typhimurium growth & development, Vacuoles microbiology

Abstract

The host endolysosomal compartment is often manipulated by intracellular bacterial pathogens. Salmonella (Salmonella enterica serovar Typhimurium) secrete numerous effector proteins, including SifA, through a specialized type III secretion system to hijack the host endosomal system and generate the Salmonella-containing vacuole (SCV). To form this replicative niche, Salmonella targets the Rab7 GTPase to recruit host membranes through largely unknown mechanisms. We show that Pleckstrin homology domain-containing protein family member 1 (PLEKHM1), a lysosomal adaptor, is targeted by Salmonella through direct interaction with SifA. By binding the PLEKHM1 PH2 domain, Salmonella utilize a complex containing PLEKHM1, Rab7, and the HOPS tethering complex to mobilize phagolysosomal membranes to the SCV. Depletion of PLEKHM1 causes a profound defect in SCV morphology with multiple bacteria accumulating in enlarged structures and significantly dampens Salmonella proliferation in multiple cell types and mice. Thus, PLEKHM1 provides a critical interface between pathogenic infection and the host endolysosomal system., (Copyright © 2015 Elsevier Inc. All rights reserved.)

Published

2015

13. PLEKHM1 regulates autophagosome-lysosome fusion through HOPS complex and LC3/GABARAP proteins.

Author

McEwan DG, Popovic D, Gubas A, Terawaki S, Suzuki H, Stadel D, Coxon FP, Miranda de Stegmann D, Bhogaraju S, Maddi K, Kirchof A, Gatti E, Helfrich MH, Wakatsuki S, Behrends C, Pierre P, and Dikic I

Subjects

Adaptor Proteins, Signal Transducing antagonists & inhibitors, Adaptor Proteins, Signal Transducing metabolism, Amino Acid Sequence, Animals, Apoptosis Regulatory Proteins, Autophagy, Autophagy-Related Proteins, Endosomes metabolism, Gene Expression Regulation, HeLa Cells, Humans, Membrane Glycoproteins antagonists & inhibitors, Membrane Glycoproteins metabolism, Mice, Mice, Transgenic, Microtubule-Associated Proteins metabolism, Models, Molecular, Molecular Sequence Data, Protein Binding, Protein Interaction Domains and Motifs, Protein Transport, RNA, Small Interfering genetics, RNA, Small Interfering metabolism, Sequence Alignment, Signal Transduction, rab GTP-Binding Proteins genetics, rab GTP-Binding Proteins metabolism, rab7 GTP-Binding Proteins, Adaptor Proteins, Signal Transducing genetics, Lysosomes metabolism, Membrane Fusion genetics, Membrane Glycoproteins genetics, Microtubule-Associated Proteins genetics, Phagosomes metabolism

Abstract

The lysosome is the final destination for degradation of endocytic cargo, plasma membrane constituents, and intracellular components sequestered by macroautophagy. Fusion of endosomes and autophagosomes with the lysosome depends on the GTPase Rab7 and the homotypic fusion and protein sorting (HOPS) complex, but adaptor proteins that link endocytic and autophagy pathways with lysosomes are poorly characterized. Herein, we show that Pleckstrin homology domain containing protein family member 1 (PLEKHM1) directly interacts with HOPS complex and contains a LC3-interacting region (LIR) that mediates its binding to autophagosomal membranes. Depletion of PLEKHM1 blocks lysosomal degradation of endocytic (EGFR) cargo and enhances presentation of MHC class I molecules. Moreover, genetic loss of PLEKHM1 impedes autophagy flux upon mTOR inhibition and PLEKHM1 regulates clearance of protein aggregates in an autophagy- and LIR-dependent manner. PLEKHM1 is thus a multivalent endocytic adaptor involved in the lysosome fusion events controlling selective and nonselective autophagy pathways., (Copyright © 2015 Elsevier Inc. All rights reserved.)

Published

2015

14. Osteopetrosis: genetics, treatment and new insights into osteoclast function.

Author

Sobacchi C, Schulz A, Coxon FP, Villa A, and Helfrich MH

Subjects

Animals, Humans, Osteopetrosis congenital, Osteopetrosis diagnosis, Osteopetrosis genetics, RANK Ligand metabolism, Signal Transduction genetics, Signal Transduction physiology, Osteopetrosis therapy

Abstract

Osteopetrosis is a genetic condition of increased bone mass, which is caused by defects in osteoclast formation and function. Both autosomal recessive and autosomal dominant forms exist, but this Review focuses on autosomal recessive osteopetrosis (ARO), also known as malignant infantile osteopetrosis. The genetic basis of this disease is now largely uncovered: mutations in TCIRG1, CLCN7, OSTM1, SNX10 and PLEKHM1 lead to osteoclast-rich ARO (in which osteoclasts are abundant but have severely impaired resorptive function), whereas mutations in TNFSF11 and TNFRSF11A lead to osteoclast-poor ARO. In osteoclast-rich ARO, impaired endosomal and lysosomal vesicle trafficking results in defective osteoclast ruffled-border formation and, hence, the inability to resorb bone and mineralized cartilage. ARO presents soon after birth and can be fatal if left untreated. However, the disease is heterogeneous in clinical presentation and often misdiagnosed. This article describes the genetics of ARO and discusses the diagnostic role of next-generation sequencing methods. The management of affected patients, including guidelines for the indication of haematopoietic stem cell transplantation (which can provide a cure for many types of ARO), are outlined. Finally, novel treatments, including preclinical data on in utero stem cell treatment, RANKL replacement therapy and denosumab therapy for hypercalcaemia are also discussed.

Published

2013

15. Endothelial nitric oxide synthase is not essential for nitric oxide production by osteoblasts subjected to fluid shear stress in vitro.

Author

Bakker AD, Huesa C, Hughes A, Aspden RM, van't Hof RJ, Klein-Nulend J, and Helfrich MH

Subjects

Animals, Bone and Bones diagnostic imaging, Bone and Bones physiology, Mice, Mice, Inbred C57BL, Mice, Knockout, Stress, Mechanical, Tomography, X-Ray Computed, Nitric Oxide biosynthesis, Nitric Oxide Synthase Type III metabolism, Osteoblasts metabolism

Abstract

Endothelial nitric oxide synthase (eNOS) has long been held responsible for NO production by mechanically stimulated osteoblasts, but this has recently been disputed. We investigated whether one of the three known NOS isoforms is essential for NO production by mechanically stimulated osteoblasts in vitro and revisited the bone phenotype of the eNOS-/- mouse. Osteoblasts, obtained as outgrowths from mouse calvaria or long bones of wild-type (WT), eNOS-/-, inducible NOS-/- (iNOS-/-), or neuronal NOS-/- (nNOS-/-) mice, were subjected to mechanical stimulation by means of pulsating fluid flow (PFF); and NO production was determined. Tibiae and femora from 8-week-old mice were subjected to μCT and three-point bending tests. Deletion of single NOS isoforms did not lead to significant upregulation of alternate isoforms in cultured osteoblasts from WT, eNOS-/-, iNOS-/-, or nNOS-/- mice. Expression of eNOS mRNA in osteoblasts was below our detection limit, and no differences in growth between WT and eNOS-/- osteoblasts were found. PFF increased NO production by approximately fourfold in WT and eNOS-/- osteoblasts and significantly stimulated NO production in iNOS-/- and nNOS-/- osteoblasts. Tibiae and femora from WT and eNOS-/- mice showed no difference in bone volume and architecture or in mechanical parameters. Our data suggest that mechanical stimuli can enhance NO production by cultured osteoblasts singly deficient for each known NOS isoform and that lack of eNOS does not significantly affect bone mass and strength at 8 weeks of age. Our data challenge the notion that eNOS is a key effector of mechanically induced bone maintenance.

Published

2013

16. Autophagy: a new player in skeletal maintenance?

Author

Hocking LJ, Whitehouse C, and Helfrich MH

Subjects

Aging, Animals, Bone and Bones cytology, Cell Differentiation, Homeostasis, Humans, Immunosuppressive Agents therapeutic use, Mice, Models, Biological, Oxidative Stress, Stem Cells cytology, Autophagy physiology, Bone and Bones physiology, Osteoblasts cytology, Osteoclasts cytology, Osteocytes cytology

Abstract

Imbalances between bone resorption and formation lie at the root of disorders such as osteoporosis, Paget's disease of bone (PDB), and osteopetrosis. Recently, genetic and functional studies have implicated proteins involved in autophagic protein degradation as important mediators of bone cell function in normal physiology and in pathology. Autophagy is the conserved process whereby aggregated proteins, intracellular pathogens, and damaged organelles are degraded and recycled. This process is important both for normal cellular quality control and in response to environmental or internal stressors, particularly in terminally-differentiated cells. Autophagic structures can also act as hubs for the spatial organization of recycling and synthetic process in secretory cells. Alterations to autophagy (reduction, hyperactivation, or impairment) are associated with a number of disorders, including neurodegenerative diseases and cancers, and are now being implicated in maintenance of skeletal homoeostasis. Here, we introduce the topic of autophagy, describe the new findings that are starting to emerge from the bone field, and consider the therapeutic potential of modifying this pathway for the treatment of age-related bone disorders., (Copyright © 2012 American Society for Bone and Mineral Research.)

Published

2012

17. Guidelines for the use and interpretation of assays for monitoring autophagy.

Author

Klionsky DJ, Abdalla FC, Abeliovich H, Abraham RT, Acevedo-Arozena A, Adeli K, Agholme L, Agnello M, Agostinis P, Aguirre-Ghiso JA, Ahn HJ, Ait-Mohamed O, Ait-Si-Ali S, Akematsu T, Akira S, Al-Younes HM, Al-Zeer MA, Albert ML, Albin RL, Alegre-Abarrategui J, Aleo MF, Alirezaei M, Almasan A, Almonte-Becerril M, Amano A, Amaravadi R, Amarnath S, Amer AO, Andrieu-Abadie N, Anantharam V, Ann DK, Anoopkumar-Dukie S, Aoki H, Apostolova N, Arancia G, Aris JP, Asanuma K, Asare NY, Ashida H, Askanas V, Askew DS, Auberger P, Baba M, Backues SK, Baehrecke EH, Bahr BA, Bai XY, Bailly Y, Baiocchi R, Baldini G, Balduini W, Ballabio A, Bamber BA, Bampton ET, Bánhegyi G, Bartholomew CR, Bassham DC, Bast RC Jr, Batoko H, Bay BH, Beau I, Béchet DM, Begley TJ, Behl C, Behrends C, Bekri S, Bellaire B, Bendall LJ, Benetti L, Berliocchi L, Bernardi H, Bernassola F, Besteiro S, Bhatia-Kissova I, Bi X, Biard-Piechaczyk M, Blum JS, Boise LH, Bonaldo P, Boone DL, Bornhauser BC, Bortoluci KR, Bossis I, Bost F, Bourquin JP, Boya P, Boyer-Guittaut M, Bozhkov PV, Brady NR, Brancolini C, Brech A, Brenman JE, Brennand A, Bresnick EH, Brest P, Bridges D, Bristol ML, Brookes PS, Brown EJ, Brumell JH, Brunetti-Pierri N, Brunk UT, Bulman DE, Bultman SJ, Bultynck G, Burbulla LF, Bursch W, Butchar JP, Buzgariu W, Bydlowski SP, Cadwell K, Cahová M, Cai D, Cai J, Cai Q, Calabretta B, Calvo-Garrido J, Camougrand N, Campanella M, Campos-Salinas J, Candi E, Cao L, Caplan AB, Carding SR, Cardoso SM, Carew JS, Carlin CR, Carmignac V, Carneiro LA, Carra S, Caruso RA, Casari G, Casas C, Castino R, Cebollero E, Cecconi F, Celli J, Chaachouay H, Chae HJ, Chai CY, Chan DC, Chan EY, Chang RC, Che CM, Chen CC, Chen GC, Chen GQ, Chen M, Chen Q, Chen SS, Chen W, Chen X, Chen X, Chen X, Chen YG, Chen Y, Chen Y, Chen YJ, Chen Z, Cheng A, Cheng CH, Cheng Y, Cheong H, Cheong JH, Cherry S, Chess-Williams R, Cheung ZH, Chevet E, Chiang HL, Chiarelli R, Chiba T, Chin LS, Chiou SH, Chisari FV, Cho CH, Cho DH, Choi AM, Choi D, Choi KS, Choi ME, Chouaib S, Choubey D, Choubey V, Chu CT, Chuang TH, Chueh SH, Chun T, Chwae YJ, Chye ML, Ciarcia R, Ciriolo MR, Clague MJ, Clark RS, Clarke PG, Clarke R, Codogno P, Coller HA, Colombo MI, Comincini S, Condello M, Condorelli F, Cookson MR, Coombs GH, Coppens I, Corbalan R, Cossart P, Costelli P, Costes S, Coto-Montes A, Couve E, Coxon FP, Cregg JM, Crespo JL, Cronjé MJ, Cuervo AM, Cullen JJ, Czaja MJ, D'Amelio M, Darfeuille-Michaud A, Davids LM, Davies FE, De Felici M, de Groot JF, de Haan CA, De Martino L, De Milito A, De Tata V, Debnath J, Degterev A, Dehay B, Delbridge LM, Demarchi F, Deng YZ, Dengjel J, Dent P, Denton D, Deretic V, Desai SD, Devenish RJ, Di Gioacchino M, Di Paolo G, Di Pietro C, Díaz-Araya G, Díaz-Laviada I, Diaz-Meco MT, Diaz-Nido J, Dikic I, Dinesh-Kumar SP, Ding WX, Distelhorst CW, Diwan A, Djavaheri-Mergny M, Dokudovskaya S, Dong Z, Dorsey FC, Dosenko V, Dowling JJ, Doxsey S, Dreux M, Drew ME, Duan Q, Duchosal MA, Duff K, Dugail I, Durbeej M, Duszenko M, Edelstein CL, Edinger AL, Egea G, Eichinger L, Eissa NT, Ekmekcioglu S, El-Deiry WS, Elazar Z, Elgendy M, Ellerby LM, Eng KE, Engelbrecht AM, Engelender S, Erenpreisa J, Escalante R, Esclatine A, Eskelinen EL, Espert L, Espina V, Fan H, Fan J, Fan QW, Fan Z, Fang S, Fang Y, Fanto M, Fanzani A, Farkas T, Farré JC, Faure M, Fechheimer M, Feng CG, Feng J, Feng Q, Feng Y, Fésüs L, Feuer R, Figueiredo-Pereira ME, Fimia GM, Fingar DC, Finkbeiner S, Finkel T, Finley KD, Fiorito F, Fisher EA, Fisher PB, Flajolet M, Florez-McClure ML, Florio S, Fon EA, Fornai F, Fortunato F, Fotedar R, Fowler DH, Fox HS, Franco R, Frankel LB, Fransen M, Fuentes JM, Fueyo J, Fujii J, Fujisaki K, Fujita E, Fukuda M, Furukawa RH, Gaestel M, Gailly P, Gajewska M, Galliot B, Galy V, Ganesh S, Ganetzky B, Ganley IG, Gao FB, Gao GF, Gao J, Garcia L, Garcia-Manero G, Garcia-Marcos M, Garmyn M, Gartel AL, Gatti E, Gautel M, Gawriluk TR, Gegg ME, Geng J, Germain M, Gestwicki JE, Gewirtz DA, Ghavami S, Ghosh P, Giammarioli AM, Giatromanolaki AN, Gibson SB, Gilkerson RW, Ginger ML, Ginsberg HN, Golab J, Goligorsky MS, Golstein P, Gomez-Manzano C, Goncu E, Gongora C, Gonzalez CD, Gonzalez R, González-Estévez C, González-Polo RA, Gonzalez-Rey E, Gorbunov NV, Gorski S, Goruppi S, Gottlieb RA, Gozuacik D, Granato GE, Grant GD, Green KN, Gregorc A, Gros F, Grose C, Grunt TW, Gual P, Guan JL, Guan KL, Guichard SM, Gukovskaya AS, Gukovsky I, Gunst J, Gustafsson AB, Halayko AJ, Hale AN, Halonen SK, Hamasaki M, Han F, Han T, Hancock MK, Hansen M, Harada H, Harada M, Hardt SE, Harper JW, Harris AL, Harris J, Harris SD, Hashimoto M, Haspel JA, Hayashi S, Hazelhurst LA, He C, He YW, Hébert MJ, Heidenreich KA, Helfrich MH, Helgason GV, Henske EP, Herman B, Herman PK, Hetz C, Hilfiker S, Hill JA, Hocking LJ, Hofman P, Hofmann TG, Höhfeld J, Holyoake TL, Hong MH, Hood DA, Hotamisligil GS, Houwerzijl EJ, Høyer-Hansen M, Hu B, Hu CA, Hu HM, Hua Y, Huang C, Huang J, Huang S, Huang WP, Huber TB, Huh WK, Hung TH, Hupp TR, Hur GM, Hurley JB, Hussain SN, Hussey PJ, Hwang JJ, Hwang S, Ichihara A, Ilkhanizadeh S, Inoki K, Into T, Iovane V, Iovanna JL, Ip NY, Isaka Y, Ishida H, Isidoro C, Isobe K, Iwasaki A, Izquierdo M, Izumi Y, Jaakkola PM, Jäättelä M, Jackson GR, Jackson WT, Janji B, Jendrach M, Jeon JH, Jeung EB, Jiang H, Jiang H, Jiang JX, Jiang M, Jiang Q, Jiang X, Jiang X, Jiménez A, Jin M, Jin S, Joe CO, Johansen T, Johnson DE, Johnson GV, Jones NL, Joseph B, Joseph SK, Joubert AM, Juhász G, Juillerat-Jeanneret L, Jung CH, Jung YK, Kaarniranta K, Kaasik A, Kabuta T, Kadowaki M, Kagedal K, Kamada Y, Kaminskyy VO, Kampinga HH, Kanamori H, Kang C, Kang KB, Kang KI, Kang R, Kang YA, Kanki T, Kanneganti TD, Kanno H, Kanthasamy AG, Kanthasamy A, Karantza V, Kaushal GP, Kaushik S, Kawazoe Y, Ke PY, Kehrl JH, Kelekar A, Kerkhoff C, Kessel DH, Khalil H, Kiel JA, Kiger AA, Kihara A, Kim DR, Kim DH, Kim DH, Kim EK, Kim HR, Kim JS, Kim JH, Kim JC, Kim JK, Kim PK, Kim SW, Kim YS, Kim Y, Kimchi A, Kimmelman AC, King JS, Kinsella TJ, Kirkin V, Kirshenbaum LA, Kitamoto K, Kitazato K, Klein L, Klimecki WT, Klucken J, Knecht E, Ko BC, Koch JC, Koga H, Koh JY, Koh YH, Koike M, Komatsu M, Kominami E, Kong HJ, Kong WJ, Korolchuk VI, Kotake Y, Koukourakis MI, Kouri Flores JB, Kovács AL, Kraft C, Krainc D, Krämer H, Kretz-Remy C, Krichevsky AM, Kroemer G, Krüger R, Krut O, Ktistakis NT, Kuan CY, Kucharczyk R, Kumar A, Kumar R, Kumar S, Kundu M, Kung HJ, Kurz T, Kwon HJ, La Spada AR, Lafont F, Lamark T, Landry J, Lane JD, Lapaquette P, Laporte JF, László L, Lavandero S, Lavoie JN, Layfield R, Lazo PA, Le W, Le Cam L, Ledbetter DJ, Lee AJ, Lee BW, Lee GM, Lee J, Lee JH, Lee M, Lee MS, Lee SH, Leeuwenburgh C, Legembre P, Legouis R, Lehmann M, Lei HY, Lei QY, Leib DA, Leiro J, Lemasters JJ, Lemoine A, Lesniak MS, Lev D, Levenson VV, Levine B, Levy E, Li F, Li JL, Li L, Li S, Li W, Li XJ, Li YB, Li YP, Liang C, Liang Q, Liao YF, Liberski PP, Lieberman A, Lim HJ, Lim KL, Lim K, Lin CF, Lin FC, Lin J, Lin JD, Lin K, Lin WW, Lin WC, Lin YL, Linden R, Lingor P, Lippincott-Schwartz J, Lisanti MP, Liton PB, Liu B, Liu CF, Liu K, Liu L, Liu QA, Liu W, Liu YC, Liu Y, Lockshin RA, Lok CN, Lonial S, Loos B, Lopez-Berestein G, López-Otín C, Lossi L, Lotze MT, Lőw P, Lu B, Lu B, Lu B, Lu Z, Luciano F, Lukacs NW, Lund AH, Lynch-Day MA, Ma Y, Macian F, MacKeigan JP, Macleod KF, Madeo F, Maiuri L, Maiuri MC, Malagoli D, Malicdan MC, Malorni W, Man N, Mandelkow EM, Manon S, Manov I, Mao K, Mao X, Mao Z, Marambaud P, Marazziti D, Marcel YL, Marchbank K, Marchetti P, Marciniak SJ, Marcondes M, Mardi M, Marfe G, Mariño G, Markaki M, Marten MR, Martin SJ, Martinand-Mari C, Martinet W, Martinez-Vicente M, Masini M, Matarrese P, Matsuo S, Matteoni R, Mayer A, Mazure NM, McConkey DJ, McConnell MJ, McDermott C, McDonald C, McInerney GM, McKenna SL, McLaughlin B, McLean PJ, McMaster CR, McQuibban GA, Meijer AJ, Meisler MH, Meléndez A, Melia TJ, Melino G, Mena MA, Menendez JA, Menna-Barreto RF, Menon MB, Menzies FM, Mercer CA, Merighi A, Merry DE, Meschini S, Meyer CG, Meyer TF, Miao CY, Miao JY, Michels PA, Michiels C, Mijaljica D, Milojkovic A, Minucci S, Miracco C, Miranti CK, Mitroulis I, Miyazawa K, Mizushima N, Mograbi B, Mohseni S, Molero X, Mollereau B, Mollinedo F, Momoi T, Monastyrska I, Monick MM, Monteiro MJ, Moore MN, Mora R, Moreau K, Moreira PI, Moriyasu Y, Moscat J, Mostowy S, Mottram JC, Motyl T, Moussa CE, Müller S, Muller S, Münger K, Münz C, Murphy LO, Murphy ME, Musarò A, Mysorekar I, Nagata E, Nagata K, Nahimana A, Nair U, Nakagawa T, Nakahira K, Nakano H, Nakatogawa H, Nanjundan M, Naqvi NI, Narendra DP, Narita M, Navarro M, Nawrocki ST, Nazarko TY, Nemchenko A, Netea MG, Neufeld TP, Ney PA, Nezis IP, Nguyen HP, Nie D, Nishino I, Nislow C, Nixon RA, Noda T, Noegel AA, Nogalska A, Noguchi S, Notterpek L, Novak I, Nozaki T, Nukina N, Nürnberger T, Nyfeler B, Obara K, Oberley TD, Oddo S, Ogawa M, Ohashi T, Okamoto K, Oleinick NL, Oliver FJ, Olsen LJ, Olsson S, Opota O, Osborne TF, Ostrander GK, Otsu K, Ou JH, Ouimet M, Overholtzer M, Ozpolat B, Paganetti P, Pagnini U, Pallet N, Palmer GE, Palumbo C, Pan T, Panaretakis T, Pandey UB, Papackova Z, Papassideri I, Paris I, Park J, Park OK, Parys JB, Parzych KR, Patschan S, Patterson C, Pattingre S, Pawelek JM, Peng J, Perlmutter DH, Perrotta I, Perry G, Pervaiz S, Peter M, Peters GJ, Petersen M, Petrovski G, Phang JM, Piacentini M, Pierre P, Pierrefite-Carle V, Pierron G, Pinkas-Kramarski R, Piras A, Piri N, Platanias LC, Pöggeler S, Poirot M, Poletti A, Poüs C, Pozuelo-Rubio M, Prætorius-Ibba M, Prasad A, Prescott M, Priault M, Produit-Zengaffinen N, Progulske-Fox A, Proikas-Cezanne T, Przedborski S, Przyklenk K, Puertollano R, Puyal J, Qian SB, Qin L, Qin ZH, Quaggin SE, Raben N, Rabinowich H, Rabkin SW, Rahman I, Rami A, Ramm G, Randall G, Randow F, Rao VA, Rathmell JC, Ravikumar B, Ray SK, Reed BH, Reed JC, Reggiori F, Régnier-Vigouroux A, Reichert AS, Reiners JJ Jr, Reiter RJ, Ren J, Revuelta JL, Rhodes CJ, Ritis K, Rizzo E, Robbins J, Roberge M, Roca H, Roccheri MC, Rocchi S, Rodemann HP, Rodríguez de Córdoba S, Rohrer B, Roninson IB, Rosen K, Rost-Roszkowska MM, Rouis M, Rouschop KM, Rovetta F, Rubin BP, Rubinsztein DC, Ruckdeschel K, Rucker EB 3rd, Rudich A, Rudolf E, Ruiz-Opazo N, Russo R, Rusten TE, Ryan KM, Ryter SW, Sabatini DM, Sadoshima J, Saha T, Saitoh T, Sakagami H, Sakai Y, Salekdeh GH, Salomoni P, Salvaterra PM, Salvesen G, Salvioli R, Sanchez AM, Sánchez-Alcázar JA, Sánchez-Prieto R, Sandri M, Sankar U, Sansanwal P, Santambrogio L, Saran S, Sarkar S, Sarwal M, Sasakawa C, Sasnauskiene A, Sass M, Sato K, Sato M, Schapira AH, Scharl M, Schätzl HM, Scheper W, Schiaffino S, Schneider C, Schneider ME, Schneider-Stock R, Schoenlein PV, Schorderet DF, Schüller C, Schwartz GK, Scorrano L, Sealy L, Seglen PO, Segura-Aguilar J, Seiliez I, Seleverstov O, Sell C, Seo JB, Separovic D, Setaluri V, Setoguchi T, Settembre C, Shacka JJ, Shanmugam M, Shapiro IM, Shaulian E, Shaw RJ, Shelhamer JH, Shen HM, Shen WC, Sheng ZH, Shi Y, Shibuya K, Shidoji Y, Shieh JJ, Shih CM, Shimada Y, Shimizu S, Shintani T, Shirihai OS, Shore GC, Sibirny AA, Sidhu SB, Sikorska B, Silva-Zacarin EC, Simmons A, Simon AK, Simon HU, Simone C, Simonsen A, Sinclair DA, Singh R, Sinha D, Sinicrope FA, Sirko A, Siu PM, Sivridis E, Skop V, Skulachev VP, Slack RS, Smaili SS, Smith DR, Soengas MS, Soldati T, Song X, Sood AK, Soong TW, Sotgia F, Spector SA, Spies CD, Springer W, Srinivasula SM, Stefanis L, Steffan JS, Stendel R, Stenmark H, Stephanou A, Stern ST, Sternberg C, Stork B, Strålfors P, Subauste CS, Sui X, Sulzer D, Sun J, Sun SY, Sun ZJ, Sung JJ, Suzuki K, Suzuki T, Swanson MS, Swanton C, Sweeney ST, Sy LK, Szabadkai G, Tabas I, Taegtmeyer H, Tafani M, Takács-Vellai K, Takano Y, Takegawa K, Takemura G, Takeshita F, Talbot NJ, Tan KS, Tanaka K, Tanaka K, Tang D, Tang D, Tanida I, Tannous BA, Tavernarakis N, Taylor GS, Taylor GA, Taylor JP, Terada LS, Terman A, Tettamanti G, Thevissen K, Thompson CB, Thorburn A, Thumm M, Tian F, Tian Y, Tocchini-Valentini G, Tolkovsky AM, Tomino Y, Tönges L, Tooze SA, Tournier C, Tower J, Towns R, Trajkovic V, Travassos LH, Tsai TF, Tschan MP, Tsubata T, Tsung A, Turk B, Turner LS, Tyagi SC, Uchiyama Y, Ueno T, Umekawa M, Umemiya-Shirafuji R, Unni VK, Vaccaro MI, Valente EM, Van den Berghe G, van der Klei IJ, van Doorn W, van Dyk LF, van Egmond M, van Grunsven LA, Vandenabeele P, Vandenberghe WP, Vanhorebeek I, Vaquero EC, Velasco G, Vellai T, Vicencio JM, Vierstra RD, Vila M, Vindis C, Viola G, Viscomi MT, Voitsekhovskaja OV, von Haefen C, Votruba M, Wada K, Wade-Martins R, Walker CL, Walsh CM, Walter J, Wan XB, Wang A, Wang C, Wang D, Wang F, Wang F, Wang G, Wang H, Wang HG, Wang HD, Wang J, Wang K, Wang M, Wang RC, Wang X, Wang X, Wang YJ, Wang Y, Wang Z, Wang ZC, Wang Z, Wansink DG, Ward DM, Watada H, Waters SL, Webster P, Wei L, Weihl CC, Weiss WA, Welford SM, Wen LP, Whitehouse CA, Whitton JL, Whitworth AJ, Wileman T, Wiley JW, Wilkinson S, Willbold D, Williams RL, Williamson PR, Wouters BG, Wu C, Wu DC, Wu WK, Wyttenbach A, Xavier RJ, Xi Z, Xia P, Xiao G, Xie Z, Xie Z, Xu DZ, Xu J, Xu L, Xu X, Yamamoto A, Yamamoto A, Yamashina S, Yamashita M, Yan X, Yanagida M, Yang DS, Yang E, Yang JM, Yang SY, Yang W, Yang WY, Yang Z, Yao MC, Yao TP, Yeganeh B, Yen WL, Yin JJ, Yin XM, Yoo OJ, Yoon G, Yoon SY, Yorimitsu T, Yoshikawa Y, Yoshimori T, Yoshimoto K, You HJ, Youle RJ, Younes A, Yu L, Yu L, Yu SW, Yu WH, Yuan ZM, Yue Z, Yun CH, Yuzaki M, Zabirnyk O, Silva-Zacarin E, Zacks D, Zacksenhaus E, Zaffaroni N, Zakeri Z, Zeh HJ 3rd, Zeitlin SO, Zhang H, Zhang HL, Zhang J, Zhang JP, Zhang L, Zhang L, Zhang MY, Zhang XD, Zhao M, Zhao YF, Zhao Y, Zhao ZJ, Zheng X, Zhivotovsky B, Zhong Q, Zhou CZ, Zhu C, Zhu WG, Zhu XF, Zhu X, Zhu Y, Zoladek T, Zong WX, Zorzano A, Zschocke J, and Zuckerbraun B

Subjects

Animals, Humans, Models, Biological, Autophagy genetics, Biological Assay methods

Abstract

In 2008 we published the first set of guidelines for standardizing research in autophagy. Since then, research on this topic has continued to accelerate, and many new scientists have entered the field. Our knowledge base and relevant new technologies have also been expanding. Accordingly, it is important to update these guidelines for monitoring autophagy in different organisms. Various reviews have described the range of assays that have been used for this purpose. Nevertheless, there continues to be confusion regarding acceptable methods to measure autophagy, especially in multicellular eukaryotes. A key point that needs to be emphasized is that there is a difference between measurements that monitor the numbers or volume of autophagic elements (e.g., autophagosomes or autolysosomes) at any stage of the autophagic process vs. those that measure flux through the autophagy pathway (i.e., the complete process); thus, a block in macroautophagy that results in autophagosome accumulation needs to be differentiated from stimuli that result in increased autophagic activity, defined as increased autophagy induction coupled with increased delivery to, and degradation within, lysosomes (in most higher eukaryotes and some protists such as Dictyostelium) or the vacuole (in plants and fungi). In other words, it is especially important that investigators new to the field understand that the appearance of more autophagosomes does not necessarily equate with more autophagy. In fact, in many cases, autophagosomes accumulate because of a block in trafficking to lysosomes without a concomitant change in autophagosome biogenesis, whereas an increase in autolysosomes may reflect a reduction in degradative activity. Here, we present a set of guidelines for the selection and interpretation of methods for use by investigators who aim to examine macroautophagy and related processes, as well as for reviewers who need to provide realistic and reasonable critiques of papers that are focused on these processes. These guidelines are not meant to be a formulaic set of rules, because the appropriate assays depend in part on the question being asked and the system being used. In addition, we emphasize that no individual assay is guaranteed to be the most appropriate one in every situation, and we strongly recommend the use of multiple assays to monitor autophagy. In these guidelines, we consider these various methods of assessing autophagy and what information can, or cannot, be obtained from them. Finally, by discussing the merits and limits of particular autophagy assays, we hope to encourage technical innovation in the field.

Published

2012

18. A class III semaphorin (Sema3e) inhibits mouse osteoblast migration and decreases osteoclast formation in vitro.

Author

Hughes A, Kleine-Albers J, Helfrich MH, Ralston SH, and Rogers MJ

Subjects

Animals, Blotting, Western, Cell Differentiation physiology, Cell Movement physiology, Cells, Cultured, Cytoskeletal Proteins, Mice, Mice, Inbred C57BL, Osteoblasts cytology, Osteoclasts cytology, Rabbits, Real-Time Polymerase Chain Reaction, Reverse Transcriptase Polymerase Chain Reaction, Semaphorins, Glycoproteins metabolism, Membrane Proteins metabolism, Osteoblasts metabolism, Osteoclasts metabolism

Abstract

Originally identified as axonal guidance cues, semaphorins are expressed throughout many different tissues and regulate numerous non-neuronal processes. We demonstrate that most class III semaphorins are expressed in mouse osteoblasts and are differentially regulated by cell growth and differentiation: Sema3d expression is increased and Sema3e expression decreased during proliferation in culture, while expression of Sema3a is unaffected by cell density but increases in cultures of mineralizing osteoblasts. Expression of Sema3a, -3e, and -3d is also differentially regulated by osteogenic stimuli; inhibition of GSK3β decreased expression of Sema3a and -3e, while 1,25-(OH)(2)D(3) increased expression of Sema3e. Parathyroid hormone had no effect on expression of Sema3a, -3b, or -3d. Osteoblasts, macrophages, and osteoclasts express the Sema3e receptor PlexinD1, suggesting an autocrine and paracrine role for Sema3e. No effects of recombinant Sema3e on osteoblast proliferation, differentiation, or mineralization were observed; but Sema3e did inhibit the migration of osteoblasts in a wound-healing assay. The formation of multinucleated, tartrate-resistant acid phosphatase-positive osteoclasts was decreased by 81% in cultures of mouse bone marrow macrophages incubated with 200 ng/mL Sema3e. Correspondingly, decreased expression of osteoclast markers (Itgb3, Acp5, Cd51, Nfatc1, CalcR, and Ctsk) was observed by qPCR in macrophage cultures differentiated in the presence of Sema3e. Our results demonstrate that class III semaphorins are expressed by osteoblasts and differentially regulated by differentiation, mineralization, and osteogenic stimuli. Sema3e is a novel inhibitor of osteoclast formation in vitro and may play a role in maintaining local bone homeostasis, potentially acting as a coupling factor between osteoclasts and osteoblasts.

Published

2012

19. RANK-dependent autosomal recessive osteopetrosis: characterization of five new cases with novel mutations.

Author

Pangrazio A, Cassani B, Guerrini MM, Crockett JC, Marrella V, Zammataro L, Strina D, Schulz A, Schlack C, Kornak U, Mellis DJ, Duthie A, Helfrich MH, Durandy A, Moshous D, Vellodi A, Chiesa R, Veys P, Lo Iacono N, Vezzoni P, Fischer A, Villa A, and Sobacchi C

Subjects

Amino Acid Sequence, B-Lymphocytes metabolism, Cell Compartmentation, Cell Differentiation, Female, Follow-Up Studies, Hematopoietic Stem Cell Transplantation, Humans, Infant, Infant, Newborn, Male, Molecular Sequence Data, Osteoclasts pathology, Osteopetrosis genetics, Receptor Activator of Nuclear Factor-kappa B chemistry, Mutation genetics, Osteopetrosis congenital, Receptor Activator of Nuclear Factor-kappa B genetics

Abstract

Autosomal recessive osteopetrosis (ARO) is a genetically heterogeneous disorder attributed to reduced bone resorption by osteoclasts. Most human AROs are classified as osteoclast rich, but recently two subsets of osteoclast-poor ARO have been recognized as caused by defects in either TNFSF11 or TNFRSF11A genes, coding the RANKL and RANK proteins, respectively. The RANKL/RANK axis drives osteoclast differentiation and also plays a role in the immune system. In fact, we have recently reported that mutations in the TNFRSF11A gene lead to osteoclast-poor osteopetrosis associated with hypogammaglobulinemia. Here we present the characterization of five additional unpublished patients from four unrelated families in which we found five novel mutations in the TNFRSF11A gene, including two missense and two nonsense mutations and a single-nucleotide insertion. Immunological investigation in three of them showed that the previously described defect in the B cell compartment was present only in some patients and that its severity seemed to increase with age and the progression of the disease. HSCT performed in all five patients almost completely cured the disease even when carried out in late infancy. Hypercalcemia was the most important posttransplant complication. Overall, our results further underline the heterogeneity of human ARO also deriving from the interplay between bone and the immune system, and highlight the prognostic and therapeutic implications of the molecular diagnosis., (Copyright © 2012 American Society for Bone and Mineral Research.)

Published

2012

20. The skeleton: a multi-functional complex organ: the role of key signalling pathways in osteoclast differentiation and in bone resorption.

Author

Mellis DJ, Itzstein C, Helfrich MH, and Crockett JC

Subjects

Animals, Bone Resorption metabolism, Bone and Bones cytology, Bone and Bones metabolism, Cartilage cytology, Cartilage metabolism, Humans, Models, Biological, Osteoclasts cytology, Osteoclasts metabolism, RANK Ligand metabolism, Bone Resorption physiopathology, Bone and Bones physiology, Cartilage physiology, Cell Differentiation physiology, Osteoclasts physiology, Signal Transduction physiology

Abstract

Osteoclasts are the specialised cells that resorb bone matrix and are important both for the growth and shaping of bones throughout development as well as during the process of bone remodelling that occurs throughout life to maintain a healthy skeleton. Osteoclast formation, function and survival are tightly regulated by a network of signalling pathways, many of which have been identified through the study of rare monogenic diseases, knockout mouse models and animal strains carrying naturally occurring mutations in key molecules. In this review, we describe the processes of osteoclast formation, activation and function and discuss the major transcription factors and signalling pathways (including those that control the cytoskeletal rearrangements) that are important at each stage.

Published

2011

21. Signal peptide mutations in RANK prevent downstream activation of NF-κB.

Author

Crockett JC, Mellis DJ, Shennan KI, Duthie A, Greenhorn J, Wilkinson DI, Ralston SH, Helfrich MH, and Rogers MJ

Subjects

Base Sequence, Cell Line, DNA Nucleotidyltransferases metabolism, Gene Expression Regulation, HEK293 Cells, Humans, Molecular Sequence Data, Molecular Weight, Mutant Proteins metabolism, Mutant Proteins ultrastructure, Osteoclasts metabolism, Osteoclasts ultrastructure, Protein Transport, Receptor Activator of Nuclear Factor-kappa B metabolism, Receptor Activator of Nuclear Factor-kappa B ultrastructure, Reproducibility of Results, Subcellular Fractions metabolism, Transfection, Mutation genetics, NF-kappa B metabolism, Protein Sorting Signals genetics, Receptor Activator of Nuclear Factor-kappa B genetics

Abstract

Familial expansile osteolysis and related disorders are caused by heterozygous tandem duplication mutations in the signal peptide region of the gene encoding receptor activator of NF-κB (RANK), a receptor critical for osteoclast formation and function. Previous studies have shown that overexpression of these mutant proteins causes constitutive activation of NF-κB signaling in vitro, and it has been assumed that this accounts for the focal osteolytic lesions that are seen in vivo. We show here that constitutive activation of NF-κB occurred in HEK293 cells overexpressing wild-type or mutant RANK but not in stably transfected cell lines expressing low levels of each RANK gene. Importantly, only cells expressing wild-type RANK demonstrated ligand-dependent activation of NF-κB. When overexpressed, mutant RANK did not localize to the plasma membrane but localized to extensive areas of organized smooth endoplasmic reticulum, whereas, as expected, wild-type RANK was detected at the plasma membrane and in the Golgi apparatus. This intracellular accumulation of the mutant proteins is probably the result of lack of signal peptide cleavage because, using two in vitro translation systems, we demonstrate that the mutations in RANK prevent cleavage of the signal peptide. In conclusion, signal peptide mutations lead to accumulation of RANK in the endoplasmic reticulum and prevent direct activation by RANK ligand. These results strongly suggest that the increased osteoclast formation/activity caused by these mutations cannot be explained by studying the homozygous phenotype alone but requires further detailed investigation of the heterozygous expression of the mutant RANK proteins., (Copyright © 2011 American Society for Bone and Mineral Research.)

Published

2011

22. Impaired prenylation of Rab GTPases in the gunmetal mouse causes defects in bone cell function.

Author

Taylor A, Mules EH, Seabra MC, Helfrich MH, Rogers MJ, and Coxon FP

Abstract

Vesicular trafficking is crucial for bone resorption by osteoclasts, in particular for formation of the ruffled border membrane and for removal of the resultant bone degradation products by transcytosis. These processes are regulated by Rab family GTPases, whose activity is dependent on post-translational prenylation by Rab geranylgeranyl transferase (RGGT). Specific pharmacological inhibition of RGGT inhibits bone resorption in vitro and in vivo, illustrating the importance of Rab prenylation for osteoclast function. The gunmetal (gm/gm) mouse bears a mutation in the catalytic subunit of RGGT, causing a loss of 75% of the activity of this enzyme and hence hypoprenylation of several Rabs in melanocytes, platelets and cytotoxic T cells. We have now found that prenylation of several Rab proteins is also defective in gm/gm osteoclasts. Moreover, while osteoclast formation and cytoskeletal polarization occurs normally, gm/gm osteoclasts exhibit a substantial reduction in resorptive activity in vitro compared with osteoclasts from +/gm mice, which do not have a prenylation defect. Surprisingly, rather than the osteosclerosis that would be expected to result from defective osteoclast function in vivo, gm/gm mice exhibited a slightly lower bone mass than +/gm mice, indicating that defects in other cell types, such as osteoblasts, in which hypoprenylation of Rabs was also detected, may contribute to the phenotype. However, gm/gm mice were partially protected from ovariectomy-induced bone loss, suggesting that levels of Rab prenylation in gm/gm osteoclasts may be sufficient to maintain normal physiological levels of activity, but not pathological levels of bone resorption in vivo.

Published

2011

23. Bone remodelling at a glance.

Author

Crockett JC, Rogers MJ, Coxon FP, Hocking LJ, and Helfrich MH

Subjects

Animals, Bone Resorption, Bone and Bones cytology, Bone and Bones metabolism, Cell Differentiation, Extracellular Matrix metabolism, Humans, Osteoblasts cytology, Osteoblasts metabolism, Osteoclasts cytology, Osteoclasts metabolism, Signal Transduction, Bone Remodeling

Published

2011

24. New knowledge on critical osteoclast formation and activation pathways from study of rare genetic diseases of osteoclasts: focus on the RANK/RANKL axis.

Author

Crockett JC, Mellis DJ, Scott DI, and Helfrich MH

Subjects

Animals, Disease Models, Animal, Humans, Mutation, Osteitis Deformans genetics, Osteitis Deformans metabolism, Osteopetrosis genetics, Osteopetrosis metabolism, RANK Ligand genetics, RANK Ligand physiology, Receptor Activator of Nuclear Factor-kappa B genetics, Signal Transduction physiology, Osteitis Deformans pathology, Osteoclasts physiology, Osteopetrosis pathology, Receptor Activator of Nuclear Factor-kappa B physiology

Abstract

Functional, biochemical and genetic studies have over the past decade identified many causative genes in the osteoclast diseases osteopetrosis and Paget's disease of bone. Here, we outline all osteoclast diseases and their genetic associations and then focus specifically on those diseases caused by mutations in the critical osteoclast molecule Receptor Activator of Nuclear factor Kappa B (RANK). Both loss and gain-of-function mutations have been found in humans leading to osteopetrosis and high bone turnover phenotypes, respectively. Osteopetrosis-associated RANK mutations are widely distributed over the RANK molecule. It is likely that some negatively affect ligand binding, whereas others preclude appropriate association of RANK with downstream signalling molecules. In the Paget-like disorders, familial expansile osteolysis, early onset Paget's disease and expansile skeletal hyperphosphatasia, heterozygous insertion mutations are found in the RANK signal peptide. These prevent signal peptide cleavage, trapping the protein translated from the mutated allele in the endoplasmic reticulum. Whole animal studies replicate the hyperactive osteoclast phenotype associated with these disorders and present only with heterozygous expression of the mutation, suggesting an as yet unexplained effect of the mutant allele on normal RANK function. We discuss the cell biological studies and animal models that help us to understand the nature of these different RANK defects and describe how careful dissection of these conditions can help understand critical pathways in osteoclast development and function. We highlight areas that require further study, particularly in light of the pharmacological interest in targeting the RANK signalling pathway to treat diseases caused by excessive bone resorption.

Published

2011

25. Functional interaction between sequestosome-1/p62 and autophagy-linked FYVE-containing protein WDFY3 in human osteoclasts.

Author

Hocking LJ, Mellis DJ, McCabe PS, Helfrich MH, and Rogers MJ

Subjects

Adaptor Proteins, Signal Transducing genetics, Autophagy-Related Proteins, Cell Line, Cell Nucleus metabolism, Cytoplasm metabolism, Humans, Immunoprecipitation, Mutation, Sequestosome-1 Protein, Stress, Physiological, Tandem Mass Spectrometry, Adaptor Proteins, Signal Transducing metabolism, Autophagy, Membrane Proteins metabolism, Osteoclasts metabolism, Transcription Factors metabolism

Abstract

Paget's disease of bone (PDB) is a late-onset disorder characterised by focal areas of increased bone resorption, with osteoclasts that are increased in size, multinuclearity, number and activity. PDB-causing missense and nonsense variants in the gene encoding Sequestosome-1/p62 (SQSTM1) have been identified, all of which cluster in and around the ubiquitin-associated (UBA) domain of the protein. SQSTM1 is ubiquitously expressed and there is, as yet, no clear reason why these mutations only appear to cause an osteoclast-related phenotype. Using co-immunoprecipitation and tandem mass spectrometry, we identified a novel interaction in human osteoclast-like cells between SQSTM1 and Autophagy-Linked FYVE domain-containing protein (ALFY/WDFY3). Endogenous ALFY and SQSTM1 both localised within the nuclei of osteoclasts and their mononuclear precursors. When osteoclasts were starved to induce autophagy, SQSTM1 and ALFY relocated to the cytoplasm where they formed large aggregates, with cytoplasmic relocalisation appearing more rapid in mature osteoclasts than in precursors in the same culture. Overexpression of wild-type SQSTM1 in HEK293 cells also resulted in the formation of cytoplasmic aggregates containing SQSTM1 and endogenous ALFY, as did overexpression of a PDB-causing missense mutant form of SQSTM1, indicating that this mutation does not impair the formation of SQSTM1- and ALFY-containing aggregates. Expression of ALFY in bone cells has not previously been reported, and the process of autophagy has not been studied with respect to osteoclast activity. We have identified a functional interaction between SQSTM1 and ALFY in osteoclasts under conditions of cell stress. The difference in response to starvation between mature osteoclasts and their precursors may begin to explain the cell-specific functional effects of SQSTM1 mutations in PDB., (Copyright © 2010 Elsevier Inc. All rights reserved.)

Published

2010

26. Parallel-plate fluid flow systems for bone cell stimulation.

Author

Huesa C, Helfrich MH, and Aspden RM

Subjects

Active Transport, Cell Nucleus, Animals, Biomechanical Phenomena, Cells, Cultured, Equipment Design, Mice, Pressure, Shear Strength, Stress, Mechanical, beta Catenin metabolism, Osteoblasts physiology, Rheology instrumentation

Abstract

Bone responds to changes in its mechanical environment, but the mechanisms by which it does so are poorly understood. One hypothesis of mechanosensing in bone states that osteocytes can sense the flow of fluid through the canalicular system. To study this in vitro a number of fluid flow devices have been designed in which cells are placed between parallel plates in sealed chambers. Fluid flows through the chambers at controlled rates, most commonly driven by a peristaltic pump. In addition to fluid flow, high pressures have been observed in these chambers, but the effect of this on the cellular responses has generally been ignored or considered irrelevant, something challenged by recent cellular experiments using pressure only. We have, therefore, devised a system in which we can considerably reduce the pressure while maintaining the flow rate to enable study of their effects individually and in combination. As reducing pressure also reduces the risk of leaks in flow chambers, our system is suitable for real-time microscopical experiments. We present details of the new systems and of experiments with osteoblasts to illustrate the effects of fluid flow with and without additional pressure on the translocation of beta-catenin to the nucleus., (Copyright 2009 Elsevier Ltd. All rights reserved.)

Published

2010

27. Osteoclast heterogeneity: lessons from osteopetrosis and inflammatory conditions.

Author

Everts V, de Vries TJ, and Helfrich MH

Subjects

Animals, Bone and Bones cytology, Bone and Bones metabolism, Bone and Bones pathology, Humans, Inflammation pathology, Osteoclasts cytology, Osteopetrosis pathology, Tooth Eruption physiology, Inflammation physiopathology, Osteoclasts physiology, Osteopetrosis physiopathology

Abstract

The multinucleated osteoclast has a unique function: degradation of mineralized tissues. It is generally taken that all osteoclasts are alike, independent of the skeletal site where they exert their activity. Recent data, however, question this view as they show that osteoclasts at different bony sites appear to differ, for example in the machinery responsible for resorption. Support for the notion that there may be heterogeneity in osteoclasts is obtained from studies in which osteoclast activity is inhibited and from observations in osteopetrosis and inflammatory bone conditions. In this review we discuss the available evidence and propose the existence of bone-site-specific osteoclast heterogeneity.

Published

2009

28. Human osteoclast-poor osteopetrosis with hypogammaglobulinemia due to TNFRSF11A (RANK) mutations.

Author

Guerrini MM, Sobacchi C, Cassani B, Abinun M, Kilic SS, Pangrazio A, Moratto D, Mazzolari E, Clayton-Smith J, Orchard P, Coxon FP, Helfrich MH, Crockett JC, Mellis D, Vellodi A, Tezcan I, Notarangelo LD, Rogers MJ, Vezzoni P, Villa A, and Frattini A

Subjects

Acid Phosphatase metabolism, Actins metabolism, Amino Acid Sequence, Amino Acid Substitution, Argentina, Arginine metabolism, Biopsy, Case-Control Studies, Cell Line, Transformed, Cell Proliferation, Cell Transformation, Viral, Cells, Cultured, Cohort Studies, Consanguinity, Cysteine metabolism, DNA Mutational Analysis, Dendrites physiology, Female, Genes, Recessive, Herpesvirus 4, Human physiology, Heterozygote, Homozygote, Humans, Ilium surgery, Isoenzymes metabolism, Leukocyte Common Antigens metabolism, Leukocytes, Mononuclear drug effects, Leukocytes, Mononuclear pathology, Lipopolysaccharides pharmacology, Macrophage Colony-Stimulating Factor pharmacology, Male, Models, Immunological, Molecular Sequence Data, Mutation, Missense, Osteoclasts metabolism, Osteoclasts ultrastructure, Osteopetrosis diagnosis, Osteopetrosis diagnostic imaging, Osteopetrosis pathology, Osteopetrosis physiopathology, Osteoprotegerin metabolism, Pakistan, Pedigree, Polymorphism, Genetic, Protein Structure, Tertiary, RANK Ligand metabolism, Radiography, Thoracic methods, Receptor Activator of Nuclear Factor-kappa B chemistry, Receptor Activator of Nuclear Factor-kappa B immunology, Receptors, Vitronectin metabolism, Sequence Homology, Amino Acid, Tartrate-Resistant Acid Phosphatase, Turkey, Agammaglobulinemia blood, Osteoclasts pathology, Osteopetrosis genetics, Receptor Activator of Nuclear Factor-kappa B genetics

Abstract

Autosomal-Recessive Osteopetrosis (ARO) comprises a heterogeneous group of bone diseases for which mutations in five genes are known as causative. Most ARO are classified as osteoclast-rich, but recently a subset of osteoclast-poor ARO has been recognized as due to a defect in TNFSF11 (also called RANKL or TRANCE, coding for the RANKL protein), a master gene driving osteoclast differentiation along the RANKL-RANK axis. RANKL and RANK (coded for by the TNFRSF11A gene) also play a role in the immune system, which raises the possibility that defects in this pathway might cause osteopetrosis with immunodeficiency. From a large series of ARO patients we selected a Turkish consanguineous family with two siblings affected by ARO and hypogammaglobulinemia with no defects in known osteopetrosis genes. Sequencing of genes involved in the RANKL downstream pathway identified a homozygous mutation in the TNFRSF11A gene in both siblings. Their monocytes failed to differentiate in vitro into osteoclasts upon exposure to M-CSF and RANKL, in keeping with an osteoclast-intrinsic defect. Immunological analysis showed that their hypogammaglobulinemia was associated with impairment in immunoglobulin-secreting B cells. Investigation of other patients revealed a defect in both TNFRSF11A alleles in six additional, unrelated families. Our results indicate that TNFRSF11A mutations can cause a clinical condition in which severe ARO is associated with an immunoglobulin-production defect.

Published

2008

29. Genetics and aetiology of Pagetic disorders of bone.

Author

Helfrich MH and Hocking LJ

Subjects

Adaptor Proteins, Signal Transducing genetics, Adaptor Proteins, Signal Transducing metabolism, Adenosine Triphosphatases genetics, Adenosine Triphosphatases metabolism, Animals, Cell Cycle Proteins genetics, Cell Cycle Proteins metabolism, Humans, Inclusion Bodies pathology, Mutation, Osteitis Deformans pathology, Osteoclasts metabolism, Osteoclasts pathology, Osteoprotegerin deficiency, Receptor Activator of Nuclear Factor-kappa B genetics, Receptor Activator of Nuclear Factor-kappa B metabolism, Sequestosome-1 Protein, Valosin Containing Protein, Genetic Predisposition to Disease, Osteitis Deformans genetics

Abstract

Paget's disease of bone (PDB) is a late-onset disorder characterised by focal areas of increased bone turnover containing enlarged hyperactive osteoclasts. The disease has a strong genetic predisposition and mutations in SQSTM1 have been associated with familial and sporadic disease in up to 40% of cases. Additional genetic loci have been associated in other cases, but genes are yet to be identified. Earlier-onset conditions with similar bone pathology (familial expansile osteolysis, expansile skeletal hyperphosphatasia and early-onset PDB) are caused by mutations in TNFRSF11A (RANK). The syndrome of inclusion body myositis, Paget's disease and frontotemporal dementia is caused by mutations in VCP. Despite the increased knowledge about genes involved in PDB and related disorders, the etiology of the diseases remains puzzling. Presence of inclusion bodies appears to link Pagetic diseases mechanistically to diseases associated with presence of misfolded proteins or abnormalities in the ubiquitin-proteasomal, or autophagy pathways. Juvenile PDB, caused by osteoprotegerin deficiency, appears mechanistically distinct from the other Pagetic diseases. This review will discuss evidence from recent studies, including new animal models for Pagetic diseases.

Published

2008

30. A new heterozygous mutation (R714C) of the osteopetrosis gene, pleckstrin homolog domain containing family M (with run domain) member 1 (PLEKHM1), impairs vesicular acidification and increases TRACP secretion in osteoclasts.

Author

Del Fattore A, Fornari R, Van Wesenbeeck L, de Freitas F, Timmermans JP, Peruzzi B, Cappariello A, Rucci N, Spera G, Helfrich MH, Van Hul W, Migliaccio S, and Teti A

Subjects

Acid Phosphatase genetics, Adaptor Proteins, Signal Transducing genetics, Adult, Autophagy-Related Proteins, Cell Communication genetics, Cell Line, DNA Mutational Analysis, Endosomes genetics, Endosomes pathology, Female, Heterozygote, Humans, Isoenzymes genetics, Membrane Glycoproteins genetics, Osteoclasts pathology, Osteopetrosis genetics, Osteopetrosis pathology, Parathyroid Hormone metabolism, Point Mutation, Tartrate-Resistant Acid Phosphatase, Acid Phosphatase metabolism, Adaptor Proteins, Signal Transducing metabolism, Amino Acid Substitution, Endosomes metabolism, Exocytosis genetics, Isoenzymes metabolism, Membrane Glycoproteins metabolism, Osteoclasts metabolism, Osteopetrosis metabolism

Abstract

Unlabelled: We studied phenotypic and cellular aspects in a patient with a heterozygous mutation of the PLEKHM1 gene and obtained some indications regarding the role of the protein in bone cell function. Plekhm1 is involved in osteoclast endosomal vesicle acidification and TRACP exocytosis, contributing to events involved in osteoclast-osteoblast cross-talk., Introduction: The gene PLEKHM1 encodes a nonsecretory adaptor protein that localizes to endosomal vesicles. A highly truncated Plekhm1 protein was previously found in a patient with intermediate autosomal recessive osteopetrosis., Materials and Methods: We describe a new heterozygous mutation in the PLEKHM1 gene in a patient presenting with low vertebral and femoral T-scores and areas of focal sclerosis. Clinical evaluation, mutational analysis, assessment of in vitro osteoclast morphology and activity, transfection studies, and evaluation of osteoclast-osteoblast cross-talk were carried out., Results: Direct DNA sequencing showed a heterozygous C to T substitution on cDNA position 2140 of the PLEKHM1 gene, predicted to lead to an R714C mutant protein. The mutation was not found in 104 control chromosomes. In vitro, patient's osteoclasts showed normal formation rate, morphology, number of nuclei, and actin rings but lower TRACP activity and higher endosomal pH than control osteoclasts. The patient had high serum PTH and TRACP, despite low TRACP activity in osteoclasts in vitro. HEK293 cells overexpressing either wildtype or Plekhm1-R714C showed no difference in localization of the variants, and co-transfection with a TRACP vector confirmed low TRACP activity in cells carrying the R714C mutation. RAW 264.7 osteoclast-like cells expressing the Plekhm1-R714C variant also showed low TRACP activity and reduced ability to acidify endosomal compartments compared with cells expressing the wildtype protein. Reduced intracellular TRACP was caused by increased protein secretion rather than reduced expression. TRACP-containing conditioned medium was able to increase osteoblast alkaline phosphatase, suggesting the focal osteosclerosis is a result of increased osteoclast-osteoblast coupling., Conclusions: We provide further evidence for a role of Plekhm-1 in osteoclasts by showing that a novel mutation in PLEKHM1 is associated with a complex bone phenotype of generalized osteopenia combined with "focal osteosclerosis." Our data suggest that the mutation affects endosomal acidification/maturation and TRACP exocytosis, with implications for osteoclast-osteoblast cross-talk.

Published

2008

31. Osteoclast-poor human osteopetrosis due to mutations in the gene encoding RANKL.

Author

Sobacchi C, Frattini A, Guerrini MM, Abinun M, Pangrazio A, Susani L, Bredius R, Mancini G, Cant A, Bishop N, Grabowski P, Del Fattore A, Messina C, Errigo G, Coxon FP, Scott DI, Teti A, Rogers MJ, Vezzoni P, Villa A, and Helfrich MH

Subjects

Animals, Consanguinity, Female, Genes, Recessive, Humans, Male, Mice, Osteoclasts, Pedigree, Osteopetrosis genetics, RANK Ligand genetics

Abstract

Autosomal recessive osteopetrosis is usually associated with normal or elevated numbers of nonfunctional osteoclasts. Here we report mutations in the gene encoding RANKL (receptor activator of nuclear factor-KB ligand) in six individuals with autosomal recessive osteopetrosis whose bone biopsy specimens lacked osteoclasts. These individuals did not show any obvious defects in immunological parameters and could not be cured by hematopoietic stem cell transplantation; however, exogenous RANKL induced formation of functional osteoclasts from their monocytes, suggesting that they could, theoretically, benefit from exogenous RANKL administration.

Published

2007

32. Multicenter blinded analysis of RT-PCR detection methods for paramyxoviruses in relation to Paget's disease of bone.

Author

Ralston SH, Afzal MA, Helfrich MH, Fraser WD, Gallagher JA, Mee A, and Rima B

Subjects

Base Sequence, Bone and Bones virology, DNA Primers genetics, Distemper Virus, Canine genetics, Distemper Virus, Canine isolation & purification, Humans, Laboratories, Leukocytes, Mononuclear virology, Measles virus genetics, Measles virus isolation & purification, Osteitis Deformans complications, Paramyxoviridae Infections complications, Paramyxoviridae Infections virology, RNA, Viral analysis, RNA, Viral genetics, Reverse Transcriptase Polymerase Chain Reaction statistics & numerical data, Sensitivity and Specificity, Osteitis Deformans virology, Paramyxovirinae genetics, Paramyxovirinae isolation & purification, Reverse Transcriptase Polymerase Chain Reaction methods

Abstract

Unlabelled: Conflicting results have been reported on the detection of paramyxovirus transcripts in Paget's disease, and a possible explanation is differences in the sensitivity of RT-PCR methods for detecting virus. In a blinded study, we found no evidence to suggest that laboratories that failed to detect viral transcripts had less sensitive RT-PCR assays, and we did not detect measles or distemper transcripts in Paget's samples using the most sensitive assays evaluated., Introduction: There is conflicting evidence on the possible role of persistent paramyxovirus infection in Paget's disease of bone (PDB). Some workers have detected measles virus (MV) or canine distemper virus (CDV) transcripts in cells and tissues from patients with PDB, but others have failed to confirm this finding. A possible explanation might be differences in the sensitivity of RT-PCR methods for detecting virus. Here we performed a blinded comparison of the sensitivity of different RT-PCR-based techniques for MV and CDV detection in different laboratories and used the most sensitive assays to screen for evidence of viral transcripts in bone and blood samples derived from patients with PDB., Materials and Methods: Participating laboratories analyzed samples spiked with known amounts of MV and CDV transcripts and control samples that did not contain viral nucleic acids. All analyses were performed on a blinded basis., Results: The limit of detection for CDV was 1000 viral transcripts in three laboratories (Aberdeen, Belfast, and Liverpool) and 10,000 transcripts in another laboratory (Manchester). The limit of detection for MV was 16 transcripts in one laboratory (NIBSC), 1000 transcripts in two laboratories (Aberdeen and Belfast), and 10,000 transcripts in two laboratories (Liverpool and Manchester). An assay previously used by a U.S.-based group to detect MV transcripts in PDB had a sensitivity of 1000 transcripts. One laboratory (Manchester) detected CDV transcripts in a negative control and in two samples that had been spiked with MV. None of the other laboratories had false-positive results for MV or CDV, and no evidence of viral transcripts was found on analysis of 12 PDB samples using the most sensitive RT-PCR assays for MV and CDV., Conclusions: We found that RT-PCR assays used by different laboratories differed in their sensitivity to detect CDV and MV transcripts but found no evidence to suggest that laboratories that previously failed to detect viral transcripts had less sensitive RT-PCR assays than those that detected viral transcripts. False-positive results were observed with one laboratory, and we failed to detect paramyxovirus transcripts in PDB samples using the most sensitive assays evaluated. Our results show that failure of some laboratories to detect viral transcripts is unlikely to be caused by problems with assay sensitivity and highlight the fact that contamination can be an issue when searching for pathogens by sensitive RT-PCR-based techniques.

Published

2007

33. Osteoclast diseases and dental abnormalities.

Author

Helfrich MH

Subjects

Alveolar Process cytology, Animals, Bone Remodeling, Humans, Models, Animal, Osteitis Deformans pathology, Osteoclasts cytology, Tooth Loss pathology, Osteoclasts physiology, Osteopetrosis pathology, Tooth Eruption physiology

Abstract

Tooth eruption depends on the presence of osteoclasts to create an eruption pathway through the alveolar bone. In diseases where osteoclast formation, or function is reduced, such as the various types of osteopetrosis, tooth eruption is affected. Diseases in which osteoclast formation or activity is increased, such as familiar expansile osteolysis and Paget's disease, are associated with dental abnormalities such as root resorption and premature tooth loss. Less is known about the origin of the dental problems in these conditions as there are no rodent models of these diseases as yet. In this short review, the genes currently known to be mutated in human osteoclast diseases will be reviewed and, where known, the effect of osteoclast dysfunction on dental development described. It will focus on human conditions and only mention rodent disease where no clear data in the human are available.

Published

2005

34. Regulation of bone mass and bone turnover by neuronal nitric oxide synthase.

Author

van't Hof RJ, Macphee J, Libouban H, Helfrich MH, and Ralston SH

Subjects

Animals, Bone Density, Bone and Bones physiology, Mice, Mice, Knockout, Nitric Oxide Synthase genetics, Nitric Oxide Synthase Type I, Bone Remodeling physiology, Bone and Bones cytology, Nitric Oxide Synthase metabolism, Osteoblasts enzymology

Abstract

Nitric oxide (NO) is produced by NO synthase (NOS) and plays an important role in the regulation of bone cell function. The endothelial NOS isoform is essential for normal osteoblast function, whereas the inducible NOS isoform acts as a mediator of cytokine effects in bone. The role of the neuronal isoform of NOS (nNOS) in bone has been studied little thus far. Therefore, we investigated the role of nNOS in bone metabolism by studying mice with targeted inactivation of the nNOS gene. Bone mineral density (BMD) was significantly higher in nNOS knockout (KO) mice compared with wild-type controls, particularly the trabecular BMD (P < 0.01). The difference in BMD between nNOS KO and control mice was confirmed by histomorphometric analysis, which showed a 67% increase in trabecular bone volume in nNOS KO mice when compared with controls (P < 0.001). This was accompanied by reduced bone remodeling, with a significant reduction in osteoblast numbers and bone formation surfaces and a reduction in osteoclast numbers and bone resorption surfaces. Osteoblasts from nNOS KO mice, however, showed increased levels of alkaline phosphatase and no defects in proliferation or bone nodule formation in vitro, whereas osteoclastogenesis was increased in nNOS KO bone marrow cultures. These studies indicate that nNOS plays a hitherto unrecognized but important physiological role as a stimulator of bone turnover. The low level of nNOS expression in bone and the in vitro behavior of nNOS KO bone cells indicate that these actions are indirect and possibly mediated by a neurogenic relay.

Published

2004

35. Osteoclast diseases.

Author

Helfrich MH

Subjects

Animals, Bone Resorption, Cell Differentiation, Glycoproteins metabolism, Humans, Osteitis Deformans epidemiology, Osteitis Deformans genetics, Osteitis Deformans pathology, Osteitis Deformans physiopathology, Osteoclasts physiology, Osteoclasts ultrastructure, Osteolysis pathology, Osteolysis physiopathology, Osteopetrosis epidemiology, Osteopetrosis genetics, Osteopetrosis pathology, Osteopetrosis physiopathology, Osteoprotegerin, Osteosclerosis epidemiology, Osteosclerosis genetics, Osteosclerosis pathology, Osteosclerosis physiopathology, Receptors, Cytoplasmic and Nuclear metabolism, Receptors, Tumor Necrosis Factor, Bone Diseases, Bone and Bones pathology, Osteoclasts pathology

Abstract

Osteoclasts are the only cells capable of resorbing mineralised bone, dentine and cartilage. Osteoclasts act in close concert with bone forming osteoblasts to model the skeleton during embryogenesis and to remodel it during later life. A number of inherited human conditions are known that are primarily caused by a defect in osteoclasts. Most of these are rare monogenic disorders, but others, such as the more common Paget's disease, are complex diseases, where genetic and environmental factors combine to result in the abnormal osteoclast phenotype. Where the genetic defect gives rise to ineffective osteoclasts, such as in osteopetrosis and pycnodysostosis, the result is the presence of too much bone. However, the phenotype in many osteoclast diseases is a combination of osteosclerosis with osteolytic lesions. In such conditions, the primary defect is hyperactivity of osteoclasts, compensated by a secondary increase in osteoblast activity. Rapid progress has been made in recent years in the identification of the causative genes and in the understanding of the biological role of the proteins encoded. This review discusses the known osteoclast diseases with particular emphasis on the genetic causes and the resulting osteoclast phenotype. These human diseases highlight the critical importance of specific proteins or signalling pathways in osteoclasts., (Copyright 2003 Wiley-Liss, Inc.)

Published

2003

36. A mutation affecting the latency-associated peptide of TGFbeta1 in Camurati-Engelmann disease enhances osteoclast formation in vitro.

Author

McGowan NW, MacPherson H, Janssens K, Van Hul W, Frith JC, Fraser WD, Ralston SH, and Helfrich MH

Subjects

Adult, Aged, Antibodies pharmacology, Camurati-Engelmann Syndrome diagnostic imaging, Carrier Proteins pharmacology, Cell Differentiation drug effects, Cells, Cultured, Female, Humans, In Vitro Techniques, Leukocytes, Mononuclear cytology, Macrophage Colony-Stimulating Factor pharmacology, Male, Membrane Glycoproteins pharmacology, RANK Ligand, Radiography, Receptor Activator of Nuclear Factor-kappa B, Transforming Growth Factor beta immunology, Transforming Growth Factor beta1, Camurati-Engelmann Syndrome genetics, Camurati-Engelmann Syndrome physiopathology, Osteoclasts cytology, Point Mutation, Transforming Growth Factor beta genetics

Abstract

Camurati-Engelmann disease (CED) is a rare autosomal dominant disorder characterized by bone pain and osteosclerosis affecting the diaphysis of long bones. CED is caused by various missense mutations in the TGFB1 gene that encodes TGFbeta1, the most common of which is an arginine-cysteine amino acid change at codon 218 (R218C) in the latency-associated peptide domain of TGFbeta1. We studied osteoclast formation in vitro from peripheral blood mononuclear cells obtained from three related CED patients harboring the R218C mutation, in comparison with one family-based and several unrelated controls. Osteoclast formation was enhanced approximately 5-fold (P < 0.001) and bone resorption approximately 10-fold (P < 0.001) in CED patients, and the increase in osteoclast formation was inhibited by soluble TGFbeta type II receptor. Total serum TGFbeta1 levels were similar in affected and unaffected subjects, but concentrations of active TGFbeta1 in conditioned medium of osteoclast cultures was higher in the three CED patients than in the unaffected family member. We concluded that the R218C mutation increases TGFbeta1 bioactivity and enhances osteoclast formation in vitro. The activation of osteoclast activity noted here is consistent with clinical reports that have shown biochemical evidence of increased bone resorption as well as bone formation in CED.

Published

2003

37. Scanning electron microscopy of bone.

Author

Marshall D, Helfrich MH, and Aspden RM

Subjects

Animals, Bone and Bones cytology, Cell Culture Techniques methods, Humans, Tissue Fixation methods, Bone and Bones ultrastructure, Microscopy, Electron, Scanning methods

Published

2003

38. The pro and con of measles virus in Paget's disease: con.

Author

Rima BK, Gassen U, Helfrich MH, and Ralston SH

Subjects

Amino Acid Sequence, Humans, Molecular Sequence Data, Sequence Homology, Amino Acid, Measles virus pathogenicity, Osteitis Deformans virology, Viral Proteins chemistry

Published

2002

39. Pamidronate causes apoptosis of plasma cells in vivo in patients with multiple myeloma.

Author

Gordon S, Helfrich MH, Sati HI, Greaves M, Ralston SH, Culligan DJ, Soutar RL, and Rogers MJ

Subjects

Aged, Aged, 80 and over, Apoptosis drug effects, Diphosphonates pharmacology, Female, Humans, Imidazoles pharmacology, Male, Middle Aged, Multiple Myeloma metabolism, Multiple Myeloma pathology, Pamidronate, Plasma Cells metabolism, Plasma Cells pathology, Protein Prenylation, Tumor Cells, Cultured, Zoledronic Acid, Antineoplastic Agents therapeutic use, Diphosphonates therapeutic use, Multiple Myeloma drug therapy, Plasma Cells drug effects

Abstract

Anti-resorptive bisphosphonates, such as pamidronate, are an effective treatment for osteolytic disease and hypercalcaemia in patients with multiple myeloma, but have also been shown to cause apoptosis of myeloma cell lines in vitro. In this study, we found that a single infusion of pamidronate, in 16 newly diagnosed patients with multiple myeloma, caused a marked increase in apoptosis of plasma cells in vivo in 10 patients and a minimal increase in four patients (P < 0.05). The nitrogen-containing bisphosphonates pamidronate and zoledronic acid also induced apoptosis of authentic, human bone marrow-derived plasma cells in vitro. Apoptosis of plasma cells in vitro was probably caused by inhibition of the mevalonate pathway and loss of prenylated small GTPases, as even low concentrations (>or= 1 micro mol/l) of zoledronic acid caused accumulation of unprenylated Rap1A in cultures of bone marrow mononuclear cells in vitro. GGTI-298, a specific inhibitor of geranylgeranyl transferase I, also induced apoptosis in human plasma cells in vitro, suggesting that geranylgeranylated proteins play a role in signalling pathways that prevent plasma cell death. Our results suggest that pamidronate may have direct and/or indirect anti-tumour effects in patients with multiple myeloma, which has important implications for the further development of the more potent nitrogen-containing bisphosphonates, such as zoledronic acid, in the treatment of myeloma.

Published

2002

40. Identification of a novel phosphonocarboxylate inhibitor of Rab geranylgeranyl transferase that specifically prevents Rab prenylation in osteoclasts and macrophages.

Author

Coxon FP, Helfrich MH, Larijani B, Muzylak M, Dunford JE, Marshall D, McKinnon AD, Nesbitt SA, Horton MA, Seabra MC, Ebetino FH, and Rogers MJ

Subjects

Animals, Cell Line, Macrophages metabolism, Microscopy, Electron, Osteoclasts metabolism, Osteoclasts ultrastructure, Rabbits, Alkyl and Aryl Transferases antagonists & inhibitors, Diphosphonates pharmacology, Enzyme Inhibitors pharmacology, Macrophages drug effects, Osteoclasts drug effects, Protein Prenylation, Pyridines pharmacology

Abstract

Nitrogen-containing bisphosphonate drugs inhibit bone resorption by inhibiting FPP synthase and thereby preventing the synthesis of isoprenoid lipids required for protein prenylation in bone-resorbing osteoclasts. NE10790 is a phosphonocarboxylate analogue of the potent bisphosphonate risedronate and is a weak anti-resorptive agent. Although NE10790 was a poor inhibitor of FPP synthase, it did inhibit prenylation in J774 macrophages and osteoclasts, but only of proteins of molecular mass approximately 22-26 kDa, the prenylation of which was not affected by peptidomimetic inhibitors of either farnesyl transferase (FTI-277) or geranylgeranyl transferase I (GGTI-298). These 22-26-kDa proteins were shown to be geranylgeranylated by labelling J774 cells with [(3)H]geranylgeraniol. Furthermore, NE10790 inhibited incorporation of [(14)C]mevalonic acid into Rab6, but not into H-Ras or Rap1, proteins that are modified by FTase and GGTase I, respectively. These data demonstrate that NE10790 selectively prevents Rab prenylation in intact cells. In accord, NE10790 inhibited the activity of recombinant Rab GGTase in vitro, but did not affect the activity of recombinant FTase or GGTase I. NE10790 therefore appears to be the first specific inhibitor of Rab GGTase to be identified. In contrast to risedronate, NE10790 inhibited bone resorption in vitro without markedly affecting osteoclast number or the F-actin "ring" structure in polarized osteoclasts. However, NE10790 did alter osteoclast morphology, causing the formation of large intracellular vacuoles and protrusion of the basolateral membrane into large, "domed" structures that lacked microvilli. The anti-resorptive activity of NE10790 is thus likely due to disruption of Rab-dependent intracellular membrane trafficking in osteoclasts.

Published

2001

41. Visualization of bisphosphonate-induced caspase-3 activity in apoptotic osteoclasts in vitro.

Author

Benford HL, McGowan NW, Helfrich MH, Nuttall ME, and Rogers MJ

Subjects

Animals, Animals, Newborn, Apoptosis drug effects, Bone Diseases, Metabolic enzymology, Bone Diseases, Metabolic physiopathology, Bone and Bones enzymology, Bone and Bones physiopathology, Caspase 3, Caspase 6, Caspase 7, Caspases metabolism, Enzyme Inhibitors pharmacology, Fluorescent Dyes pharmacokinetics, Humans, Nitrogen metabolism, Osteoclasts cytology, Osteoclasts enzymology, Protein Prenylation drug effects, Protein Prenylation physiology, Rabbits, Tumor Cells, Cultured cytology, Tumor Cells, Cultured drug effects, Tumor Cells, Cultured enzymology, Apoptosis physiology, Bone Diseases, Metabolic drug therapy, Bone and Bones drug effects, Caspases drug effects, Diphosphonates pharmacology, Osteoclasts drug effects

Abstract

Bisphosphonates inhibit osteoclast-mediated bone resorption by mechanisms that have only recently become clear. Whereas nitrogen-containing bisphosphonates affect osteoclast function by preventing protein prenylation (especially geranylgeranylation), non-nitrogen-containing bisphosphonates have a different molecular mechanism of action. In this study, we demonstrate that nitrogen-containing bisphosphonates (risedronate, alendronate, pamidronate, and zoledronic acid) and non-nitrogen-containing bisphosphonates (clodronate and etidronate) cause apoptosis of rabbit osteoclasts, human osteoclastoma-derived osteoclasts, and human osteoclast-like cells generated in cultures of bone marrow in vitro. Osteoclast apoptosis was shown to involve characteristic morphological changes, loss of mitochondrial membrane potential, and the activation of caspase-3-like proteases capable of cleaving peptide substrates with the sequence DEVD. Caspase-3-like activity could be visualized in unfixed, dying osteoclasts and osteoclast-like cells using a cell-permeable, fluorogenic substrate. Bisphosphonate-induced osteoclast apoptosis was dependent on caspase activation, because apoptosis resulting from alendronate, clodronate, or zoledronic acid treatment was suppressed by zVAD-fmk, a broad-range caspase inhibitor, or by SB-281277, a specific isatin sulfonamide inhibitor of caspase-3/-7. Furthermore, caspase-3 (but not caspase-6 or caspase-7) activity could be detected and quantitated in lysates from purified rabbit osteoclasts, whereas the p17 fragment of active caspase-3 could be detected in human osteoclast-like cells by immunofluorescence staining. Caspase-3, therefore, appears to be the major effector caspase activated in osteoclasts by bisphosphonate treatment. Caspase activation and apoptosis induced by nitrogen-containing bisphosphonates are likely to be the consequence of the loss of geranylgeranylated rather than farnesylated proteins, because the ability to cause apoptosis and caspase activation was mimicked by GGTI-298, a specific inhibitor of protein geranylgeranylation, whereas FTI-277, a specific inhibitor of protein farnesylation, had no effect on apoptosis or caspase activity.

Published

2001

42. Cytokine-activated endothelium recruits osteoclast precursors.

Author

McGowan NW, Walker EJ, Macpherson H, Ralston SH, and Helfrich MH

Subjects

Bone Marrow Cells drug effects, Bone Remodeling drug effects, Capillaries cytology, Cell Adhesion drug effects, Cell Separation, Endothelium, Vascular cytology, Humans, Monocytes drug effects, Stem Cells drug effects, Cytokines pharmacology, Endothelium, Vascular drug effects, Osteoclasts drug effects

Abstract

Osteoclast precursors reach sites of osteoclast formation and remodelling via the vasculature and are therefore destined to encounter endothelium before migrating to the bone surface. Here we investigated the hypothesis that endothelium may be involved in the regulation of osteoclast precursor recruitment to sites of bone resorption. Osteoclast precursors in human peripheral blood were identified by their ability to form mature osteoclasts in 21-day cultures supplemented with RANKLigand, M-CSF, 1,25(OH)(2)-vitamin D(3), dexamethasone and prostaglandin E(2). Under control conditions few osteoclast precursors adhered to endothelial cells (the human bone marrow-derived endothelial cell line BMEC-1). However, BMEC-1 cells treated with the resorption stimulating cytokines IL-1beta and TNFalpha depleted the PBMC population of all osteoclast precursors. These results provide the first evidence that osteoclast precursors can adhere to endothelium and suggest that endothelium could play an important role in the recruitment of osteoclast precursors to sites of bone resorption.

Published

2001

43. Defective bone formation and anabolic response to exogenous estrogen in mice with targeted disruption of endothelial nitric oxide synthase.

Author

Armour KE, Armour KJ, Gallagher ME, Gödecke A, Helfrich MH, Reid DM, and Ralston SH

Subjects

Alkaline Phosphatase metabolism, Animals, Bone Density, Bone and Bones metabolism, Bone and Bones pathology, Cell Differentiation physiology, Cell Division physiology, Cells, Cultured, Female, Male, Mice, Mice, Inbred C57BL, Mice, Knockout genetics, Nitric Oxide Synthase deficiency, Nitric Oxide Synthase genetics, Nitric Oxide Synthase Type II, Nitric Oxide Synthase Type III, Ovariectomy, Reference Values, Bone Development physiology, Estradiol pharmacology, Nitric Oxide Synthase physiology

Abstract

Nitric oxide (NO) is a pleiotropic signaling molecule that is produced by bone cells constitutively and in response to diverse stimuli such as proinflammatory cytokines, mechanical strain, and sex hormones. Endothelial nitric oxide synthase (eNOS) is the predominant NOS isoform expressed in bone, but its physiological role in regulating bone metabolism remains unclear. Here we studied various aspects of bone metabolism in female mice with targeted disruption of the eNOS gene. Mice with eNOS deficiency (eNOS KO) had reduced bone mineral density, and cortical thinning when compared with WT controls and histomorphometric analysis of bone revealed profound abnormalities of bone formation, with reduced osteoblast numbers, surfaces and mineral apposition rate. Studies in vitro showed that osteoblasts derived from eNOS KO mice had reduced rates of growth when compared with WT and were less well differentiated as reflected by lower levels of alkaline phosphatase activity. Mice with eNOS deficiency lost bone normally following ovariectomy but exhibited a significantly blunted anabolic response to high dose exogenous estrogen. We conclude that the eNOS pathway plays an essential role in regulating bone mass and bone turnover by modulating osteoblast function.

Published

2001

44. Formation of non-resorbing osteoclasts from peripheral blood mononuclear cells of patients with malignant juvenile osteopetrosis.

Author

Helfrich MH and Gerritsen EJ

Subjects

Animals, Bone Resorption, Bone and Bones embryology, Cell Differentiation, Cells, Cultured, Coculture Techniques, Female, Humans, Infant, Mice, Models, Biological, Leukocytes, Mononuclear pathology, Osteoclasts pathology, Osteopetrosis pathology

Abstract

The genetic defects that cause human infantile malignant osteopetrosis, a disease with recessive inheritance characterized by lack of bone resorption and the presence of large numbers of inactive osteoclasts, are only partially known. Studies of osteoclasts in vitro may help to identify or exclude candidate genes in this disorder. Here, we established co-cultures of peripheral blood mononuclear cells with mouse fetal bone rudiments to generate osteoclasts from three infants with malignant osteopetrosis. Osteoclasts generated in vitro displayed the same inability to form ruffled borders and resorb bone as seen in bone biopsies. This culture model may contribute to understanding the pathogenesis of this disease.

Published

2001

45. A negative search for a paramyxoviral etiology of Paget's disease of bone: molecular, immunological, and ultrastructural studies in UK patients.

Author

Helfrich MH, Hobson RP, Grabowski PS, Zurbriggen A, Cosby SL, Dickson GR, Fraser WD, Ooi CG, Selby PL, Crisp AJ, Wallace RG, Kahn S, and Ralston SH

Subjects

Aged, Aged, 80 and over, Biopsy, Case-Control Studies, DNA Primers, DNA, Viral isolation & purification, Distemper Virus, Canine isolation & purification, Female, Humans, Immunohistochemistry, In Situ Hybridization, Male, Measles virus isolation & purification, Middle Aged, Osteitis Deformans blood, Reproducibility of Results, Respiratory Syncytial Viruses isolation & purification, Respirovirus genetics, Respirovirus immunology, Reverse Transcriptase Polymerase Chain Reaction, Sensitivity and Specificity, United Kingdom, Bone and Bones ultrastructure, Osteitis Deformans pathology, Osteitis Deformans virology, Respirovirus isolation & purification

Abstract

Paget's disease of bone is a common bone disease characterized by increased and disorganized bone remodeling at focal sites throughout the skeleton. The etiology of the disease is unresolved. A persistent viral infection has long been suggested to cause the disease. Antigen and/or nucleic acid sequences of paramyxoviruses (in particular measles virus [MV], canine distemper virus [CDV], and respiratory syncytial virus [RSV]) have been reported in pagetic bone by a number of groups; however, others have been unable to confirm this and so far no virus has been isolated from patients. Here, we reexamined the question of viral involvement in Paget's disease in a study involving 53 patients with established disease recruited from seven centers throughout the United Kingdom. Thirty-seven patients showed clear signs of active disease by bone scan and/or histological assessment of the bone biopsy specimens and 12 of these had not received any therapy before samples were taken. Presence of paramyxovirus nucleic acid sequences was sought in bone biopsy specimens, bone marrow, or peripheral blood mononuclear cells using reverse-transcription polymerase chain reaction (RT-PCR) with a total of 18 primer sets (7 of which were nested), including 10 primer sets (including 3 nested sets) specifically for MV or CDV. For each patient at least one sample was tested with all primer sets by RT-PCR and no evidence for the presence of paramyxovirus RNA was found in any patient. In 6 patients, bone biopsy specimens with clear histological evidence of active disease tested negative for presence of measles and CDV using immunocytochemistry (ICC) and in situ hybridization (ISH). Intranuclear inclusion bodies, similar to those described by others previously, were seen in pagetic osteoclasts. The pagetic inclusions were straight, smooth tubular structures packed tightly in parallel bundles and differed from nuclear inclusions, known to represent MV nucleocapsids, in a patient with subacute sclerosing panencephalitis (SSPE) in which undulating, diffuse structures were found, arranged loosely in a nonparallel fashion. In the absence of amplification of viral sequences from tissues that contain frequent nuclear inclusions and given that identical inclusions are found in other bone diseases with a proven genetic, rather than environmental, etiology, it is doubtful whether the inclusions in pagetic osteoclasts indeed represent viral nucleocapsids. Our findings in this large group of patients recruited from throughout the United Kingdom do not support a role for paramyxovirus in the etiology of Paget's disease.

Published

2000

46. A mutation in the c-myc-IRES leads to enhanced internal ribosome entry in multiple myeloma: a novel mechanism of oncogene de-regulation.

Author

Chappell SA, LeQuesne JP, Paulin FE, deSchoolmeester ML, Stoneley M, Soutar RL, Ralston SH, Helfrich MH, and Willis AE

Subjects

5' Untranslated Regions, Base Sequence, Bone Marrow physiology, Cell Line, Gene Expression Regulation, Neoplastic, Humans, Molecular Sequence Data, Protein Biosynthesis, Proto-Oncogene Mas, Proto-Oncogene Proteins c-myc metabolism, Recombinant Proteins genetics, Recombinant Proteins metabolism, Multiple Myeloma genetics, Point Mutation, Proto-Oncogene Proteins c-myc genetics, Regulatory Sequences, Nucleic Acid, Ribosomes

Abstract

The 5' untranslated region of the proto-oncogene c-myc contains an internal ribosome entry segment (IRES) (Nanbru et al., 1997; Stoneley et al., 1998) and thus c-myc protein synthesis can be initiated by a cap-independent as well as a cap-dependent mechanism (Stoneley et al., 2000). In cell lines derived from patients with multiple myeloma (MM) there is aberrant translational regulation of c-myc and this correlates with a C-T mutation in the c-myc-IRES (Paulin et al., 1996). RNA derived from the mutant IRES displays enhanced binding of protein factors (Paulin et al., 1998). Here we show that the same mutation is present in 42% of bone marrow samples obtained from patients with MM, but was not present in any of 21 controls demonstrating a strong correlation between this mutation and the disease. In a tissue culture based assay, the mutant version of the c-myc-IRES was more active in all cell types tested, but showed the greatest activity in a cell line derived from a patient with MM. Our data demonstrate that a single mutation in the c-myc-IRES is sufficient to cause enhanced initiation of translation via internal ribosome entry and represents a novel mechanism of oncogenesis.

Published

2000

47. Protein geranylgeranylation is required for osteoclast formation, function, and survival: inhibition by bisphosphonates and GGTI-298.

Author

Coxon FP, Helfrich MH, Van't Hof R, Sebti S, Ralston SH, Hamilton A, and Rogers MJ

Subjects

Animals, Apoptosis drug effects, Bone Resorption, Cell Differentiation drug effects, Cell Survival drug effects, Cells, Cultured, Chick Embryo, Cytoskeleton drug effects, Methionine analogs & derivatives, Methionine pharmacology, Mice, Osteoclasts metabolism, Osteoclasts physiology, Rabbits, Benzamides pharmacology, Diphosphonates pharmacology, Enzyme Inhibitors pharmacology, Osteoclasts drug effects, Protein Prenylation drug effects

Abstract

Bisphosphonates are the important class of antiresorptive drugs used in the treatment of metabolic bone diseases. Although their molecular mechanism of action has not been fully elucidated, recent studies have shown that the nitrogen-containing bisphosphonates can inhibit protein prenylation in macrophages in vitro. In this study, we show that the nitrogen-containing bisphosphonates risedronate, zoledronate, ibandronate, alendronate, and pamidronate (but not the non nitrogen-containing bisphosphonates clodronate, etidronate, and tiludronate) prevent the incorporation of [14C]mevalonate into prenylated (farnesylated and geranylgeranylated) proteins in purified rabbit osteoclasts. The inhibitory effect of nitrogen-containing bisphosphonates on bone resorption is likely to result largely from the loss of geranylgeranylated proteins rather than loss of farnesylated proteins in osteoclasts, because concentrations of GGTI-298 (a specific inhibitor of geranylgeranyl transferase I) that inhibited protein geranylgeranylation in purified rabbit osteoclasts prevented osteoclast formation in murine bone marrow cultures, disrupted the osteoclast cytoskeleton, inhibited bone resorption, and induced apoptosis in isolated chick and rabbit osteoclasts in vitro. By contrast, concentrations of FTI-277 (a specific inhibitor of farnesyl transferase) that prevented protein farnesylation in purified rabbit osteoclasts had little effect on osteoclast morphology or apoptosis and did not inhibit bone resorption. These results therefore show the molecular mechanism of action of nitrogen-containing bisphosphonate drugs in osteoclasts and highlight the fundamental importance of geranylgeranylated proteins in osteoclast formation and function.

Published

2000

48. Are paramyxoviruses involved in Paget's disease? A negative view.

Author

Ralston SH and Helfrich MH

Subjects

Animals, Antibodies, Viral analysis, Humans, Immunohistochemistry, In Situ Hybridization, Osteitis Deformans epidemiology, Paramyxoviridae genetics, Paramyxoviridae immunology, Paramyxoviridae isolation & purification, Paramyxoviridae Infections epidemiology, RNA, Viral analysis, Reverse Transcriptase Polymerase Chain Reaction, United Kingdom epidemiology, Osteitis Deformans virology, Paramyxoviridae Infections virology

Abstract

We believe that the assembled data are consistent with the presence of mRNA species and/or proteins in pagetic bone that are recognized by some paramyxovirus antibodies and nucleic acid probes. The evidence presented so far is insufficient to substantiate claims for the "unequivocal" presence of paramyxovirus sequences in pagetic bone, because the molecular targets for these probes could be endogenous mRNA's and proteins rather than viruses. Positive reports of a viral presence in Paget's disease have so far been confined to two laboratories, both of which have consistently demonstrated evidence for the virus they have worked on most. We argue that independent replication of the aforementioned findings is necessary to conclude that pagetic bone can be considered a site of chronic paramyxovirus infection. For this to be convincing, we would expect to see colocalization of viral antigens, mRNA, and genomic RNA in cells that also show ultrastructural evidence of viral infection. If virus is indeed present, it should, in addition, be possible to clone and characterize extensive tracts of viral cDNA from samples of pagetic tissue. Although we acknowledge that the absence of evidence for viral mRNA in some RT-PCR studies does not constitute evidence of absence, the data implicating paramyxoviruses as causal agents is conflicting and insufficient to prove a cause-effect relationship. In view of this, we believe that the role of paramyxovirus infection as a cause Paget's disease remains uncertain.

Published

1999

49. The bisphosphonate incadronate (YM175) causes apoptosis of human myeloma cells in vitro by inhibiting the mevalonate pathway.

Author

Shipman CM, Croucher PI, Russell RG, Helfrich MH, and Rogers MJ

Subjects

Cell Cycle drug effects, Cell Division drug effects, Diterpenes pharmacology, Enzyme Inhibitors pharmacology, Farnesol pharmacology, Humans, Lovastatin analogs & derivatives, Lovastatin pharmacology, Multiple Myeloma metabolism, Multiple Myeloma pathology, Protein Prenylation drug effects, Tumor Cells, Cultured, Antineoplastic Agents pharmacology, Apoptosis drug effects, Diphosphonates pharmacology, Mevalonic Acid metabolism, Multiple Myeloma drug therapy

Abstract

It has recently been suggested that bisphosphonates may have direct antitumor effects in vivo, in addition to their therapeutic antiresorptive properties. Bisphosphonates can inhibit proliferation and cause apoptosis in human myeloma cells in vitro. In macrophages, bisphosphonate-induced apoptosis was recently found to be a result of inhibition of the mevalonate (MVA) pathway. The aim of this study was to determine whether bisphosphonates also affect human myeloma cells in vitro by inhibiting the MVA pathway. Incadronate and mevastatin (a known inhibitor of the MVA pathway) caused apoptosis in JJN-3 myeloma cells and inhibited cell proliferation. Geranylgeraniol and farnesol prevented incadronate-induced apoptosis and had a partial effect on cell cycle arrest. MVA and geranylgeraniol prevented mevastatin-induced apoptosis and inhibition of proliferation and completely prevented the effect of mevastatin on the cell cycle. These observations demonstrate that incadronate-induced apoptosis in human myeloma cells in vitro is the result of inhibition of the MVA pathway.

Published

1998

50. Nitric oxide response to shear stress by human bone cell cultures is endothelial nitric oxide synthase dependent.

Author

Klein-Nulend J, Helfrich MH, Sterck JG, MacPherson H, Joldersma M, Ralston SH, Semeins CM, and Burger EH

Subjects

Adaptation, Physiological, Adolescent, Adult, Aged, Aged, 80 and over, Base Sequence, Bone and Bones cytology, Bone and Bones metabolism, Cells, Cultured, Child, DNA Primers, Humans, Middle Aged, Nitric Oxide Synthase genetics, Nitric Oxide Synthase Type III, Physical Stimulation, Polymerase Chain Reaction, RNA, Messenger genetics, Stress, Physiological enzymology, Bone and Bones physiology, Nitric Oxide metabolism, Nitric Oxide Synthase metabolism, Stress, Physiological metabolism

Abstract

Bone cells, in particular osteocytes, are extremely sensitive to shear stress, a phenomenon that may be related to mechanical adaptation of bone. In this study we examined whether human primary bone cells produce NO in response to fluid shear stress and established by RT/PCR which NOS isoforms were expressed before and after application of shear stress. One hour pulsating fluid flow (PFF; 0.7 +/- 0.02 Pa, 5 Hz) caused a rapid (within 5 min) 2 to 4-fold increase in NO production. NO release was only transiently increased during the first 15 min of exposure to PFF, and remained at control levels during a 1-24 hr postincubation period. In both control and PFF-treated cells, mRNA was easily detected for ecNOS, but not nNOS, and only minimal amounts iNOS were found. mRNA levels for ecNOS increased 2-fold at 1 hr after 1 hr PFF treatment. These results suggest that the rapid production of NO by human bone cells in response to fluid flow results from activation of ecNOS. PFF also leads to an increase in ecNOS mRNA which is likely related to the shear stress responsive element in the promoter of ecNOS., (Copyright 1998 Academic Press.)

Published

1998