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1. Altered TMPRSS2 usage by SARS-CoV-2 Omicron impacts infectivity and fusogenicity

Author

Meng, B., Abdullahi, A., Ferreira, I. A. T. M., Goonawardane, N., Saito, A., Kimura, I., Yamasoba, D., Gerber, P. P., Fatihi, S., Rathore, S., Zepeda, S. K., Papa, G., Kemp, S. A., Ikeda, T., Toyoda, M., Tan, T. S., Kuramochi, J., Mitsunaga, S., Ueno, T., Shirakawa, K., Takaori-Kondo, A., Brevini, T., Mallery, D. L., Charles, O. J., Baker, S., Dougan, G., Hess, C., Kingston, N., Lehner, P. J., Lyons, P. A., Matheson, N. J., Ouwehand, W. H., Saunders, C., Summers, C., Thaventhiran, J. E. D., Toshner, M., Weekes, M. P., Maxwell, P., Shaw, A., Bucke, A., Calder, J., Canna, L., Domingo, J., Elmer, A., Fuller, S., Harris, J., Hewitt, S., Kennet, J., Jose, S., Kourampa, J., Meadows, A., O'Brien, C., Price, J., Publico, C., Rastall, R., Ribeiro, C., Rowlands, J., Ruffolo, V., Tordesillas, H., Bullman, B., Dunmore, B. J., Graf, S., Hodgson, J., Huang, C., Hunter, K., Jones, E., Legchenko, E., Matara, C., Martin, J., Mescia, F., O'Donnell, C., Pointon, L., Shih, J., Sutcliffe, R., Tilly, T., Treacy, C., Tong, Z., Wood, J., Wylot, M., Betancourt, A., Bower, G., Cossetti, C., De Sa, A., Epping, M., Fawke, S., Gleadall, N., Grenfell, R., Hinch, A., Jackson, S., Jarvis, I., Krishna, B., Nice, F., Omarjee, O., Perera, M., Potts, M., Richoz, N., Romashova, V., Stefanucci, L., Strezlecki, M., Turner, L., De Bie, E. M. D. D., Bunclark, K., Josipovic, M., Mackay, M., Butcher, H., Caputo, D., Chandler, M., Chinnery, P., Clapham-Riley, D., Dewhurst, E., Fernandez, C., Furlong, A., Graves, B., Gray, J., Hein, S., Ivers, T., Le Gresley, E., Linger, R., Kasanicki, M., King, R., Meloy, S., Moulton, A., Muldoon, F., Ovington, N., Papadia, S., Penkett, C. J., Phelan, I., Ranganath, V., Paraschiv, R., Sage, A., Sambrook, J., Scholtes, I., Schon, K., Stark, H., Stirrups, K. E., Townsend, P., Walker, N., Webster, J., Butlertanaka, E. P., Tanaka, Y. L., Ito, J., Uriu, K., Kosugi, Y., Suganami, M., Oide, A., Yokoyama, M., Chiba, M., Motozono, C., Nasser, H., Shimizu, R., Kitazato, K., Hasebe, H., Irie, T., Nakagawa, S., Wu, J., Takahashi, M., Fukuhara, T., Shimizu, K., Tsushima, K., Kubo, H., Kazuma, Y., Nomura, R., Horisawa, Y., Nagata, K., Kawai, Y., Yanagida, Y., Tashiro, Y., Tokunaga, K., Ozono, S., Kawabata, R., Morizako, N., Sadamasu, K., Asakura, H., Nagashima, M., Yoshimura, K., Cardenas, P., Munoz, E., Barragan, V., Marquez, S., Prado-Vivar, B., Becerra-Wong, M., Caravajal, M., Trueba, G., Rojas-Silva, P., Grunauer, M., Gutierrez, B., Guadalupe, J. J., Fernandez-Cadena, J. C., Andrade-Molina, D., Baldeon, M., Pinos, A., Bowen, J. E., Joshi, A., Walls, A. C., Jackson, L., Martin, D., Smith, K. G. C., Bradley, J., Briggs, J. A. G., Choi, J., Madissoon, E., Meyer, K. B., Mlcochova, P., Ceron-Gutierrez, L., Doffinger, R., Teichmann, S. A., Fisher, A. J., Pizzuto, M. S., de Marco, A., Corti, D., Hosmillo, M., Lee, J. H., James, L. C., Thukral, L., Veesler, D., Sigal, A., Sampaziotis, F., Goodfellow, I. G., Sato, K., and Gupta, R. K.

Subjects
Adult, Male, COVID-19 Vaccines, Virus Replication, Membrane Fusion, Antibodies, Cell Line, Tissue Culture Techniques, Chlorocebus aethiops, 80 and over, Animals, Humans, Viral, Neutralizing, Lung, Aged, Multidisciplinary, Virulence, SARS-CoV-2, Immune Sera, Cell Membrane, Serine Endopeptidases, COVID-19, Convalescence, Middle Aged, Virus Internalization, Spike Glycoprotein, Intestines, Coronavirus, Nasal Mucosa, Mutation, Female, Angiotensin-Converting Enzyme 2, Aged, 80 and over, Antibodies, Neutralizing, Antibodies, Viral, Spike Glycoprotein, Coronavirus
Abstract

The SARS-CoV-2 Omicron BA.1 variant emerged in 20211 and has multiple mutations in its spike protein2. Here we show that the spike protein of Omicron has a higher affinity for ACE2 compared with Delta, and a marked change in its antigenicity increases Omicron’s evasion of therapeutic monoclonal and vaccine-elicited polyclonal neutralizing antibodies after two doses. mRNA vaccination as a third vaccine dose rescues and broadens neutralization. Importantly, the antiviral drugs remdesivir and molnupiravir retain efficacy against Omicron BA.1. Replication was similar for Omicron and Delta virus isolates in human nasal epithelial cultures. However, in lung cells and gut cells, Omicron demonstrated lower replication. Omicron spike protein was less efficiently cleaved compared with Delta. The differences in replication were mapped to the entry efficiency of the virus on the basis of spike-pseudotyped virus assays. The defect in entry of Omicron pseudotyped virus to specific cell types effectively correlated with higher cellular RNA expression of TMPRSS2, and deletion of TMPRSS2 affected Delta entry to a greater extent than Omicron. Furthermore, drug inhibitors targeting specific entry pathways3 demonstrated that the Omicron spike inefficiently uses the cellular protease TMPRSS2, which promotes cell entry through plasma membrane fusion, with greater dependency on cell entry through the endocytic pathway. Consistent with suboptimal S1/S2 cleavage and inability to use TMPRSS2, syncytium formation by the Omicron spike was substantially impaired compared with the Delta spike. The less efficient spike cleavage of Omicron at S1/S2 is associated with a shift in cellular tropism away from TMPRSS2-expressing cells, with implications for altered pathogenesis.

Published
2022
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2. Structure of the SARS-CoV-2 BA.2.75 spike glycoprotein (closed state 1)

Author

Saito, A., primary, Tamura, T., additional, Zahradnik, J., additional, Deguchi, S., additional, Tabata, K., additional, Anraku, Y., additional, Kimura, I., additional, Ito, J., additional, Yamasoba, D., additional, Nasser, H., additional, Toyoda, M., additional, Nagata, K., additional, Uriu, K., additional, Kosugi, Y., additional, Fujita, S., additional, Shofa, M., additional, Begum, M., additional, Shimizu, R., additional, Oda, Y., additional, Suzuki, R., additional, Ito, H., additional, Nao, N., additional, Wang, L., additional, Tsuda, M., additional, Yoshimatsu, K., additional, Kuramochi, J., additional, Kita, S., additional, Sasaki-Tabata, K., additional, Fukuhara, H., additional, Maenaka, K., additional, Yamamoto, Y., additional, Nagamoto, T., additional, Asakura, H., additional, Nagashima, M., additional, Sadamasu, K., additional, Yoshimura, K., additional, Ueno, T., additional, Schreiber, G., additional, Takaori-Kondo, A., additional, Shirakawa, K., additional, Sawa, H., additional, Irie, T., additional, Hashiguchi, T., additional, Takayama, K., additional, Matsuno, K., additional, Tanaka, S., additional, Ikeda, T., additional, Fukuhara, T., additional, and Sato, K., additional

Published
2022
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24. The Severity of Hyperdynamic Circulation May Predict the Effects of Direct Hemoperfusion with the Adsorbent Column Using Polymyxin B-Immobilized Fiber in Patients with Gram-Negative Septic Shock

Author

Uriu, K., Osajima, A., Kamochi, M., Watanabe, H., Aibara, K., and Kaizu, K.

Abstract

It has been reported that direct hemoperfusion with the adsorbent column using polymyxin B-immobilized fiber (DHP with PMX-F column) ameliorates hyperdynamic circulation in septic shock and improves survival rate. However, the clinical characteristics of patients with an improvement of septic shock after DHP with PMX-F column have not been evaluated. To clarify this issue, the clinical profiles of 46 patients who were suggested to have gram-negative septic shock and treated using DHP with PMX-F column were analyzed retrospectively. Of 46 patients, 31 were diagnosed with gram-negative septic shock (G group). Mean arterial pressure (MAP) just before DHP with PMX-F column was not different between the G and the non-G group. As compared with the non-G group, the G group had a higher cardiac index (CI) and a lower systemic vascular resistance (SVR). Significant increases in MAP and SVR with a significant decrease in CI were observed after DHP with PMX-F column in the G group. In the non-G group, MAP was significantly increased after the DHP therapy, but systemic hemodynamics were unchanged. Patients in the G group who fulfilled the following criteria were considered as the effective group: MAP was elevated more than 10 mm Hg or 125% of the basal MAP and/or the dose of vasopressors was reduced after DHP with PMX-F column. Twenty-one patients (67.8%) were in the effective group. In comparison with the effective group, the noneffective group was characterized by a significant increase in CI before DHP with PMX-F column. All patients with a CI less than 6 L/min/m2 were in the effective group. These data suggest that DHP with PMX-F column was useful for patients with Gram-negative septic shock who did not have severe hyperdynamic circulation.

Published
2001
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26. Relationship between K15NO3 application period and 15N enrichment of apricot blossoms and developing fruit.

Author

Weinbaum, S. A., Uriu, K., and Muraoka, T. T.

Abstract

The relationship was assessed between the period of K15 NO3 application and the level of 15N in the blossoms of 'Royal' apricot (Prunus armen iaca L.). Late summer applications of K15NO, resulted in a 34 fold greater 15N enrichment of apricot blossoms the following year than K15NO3 applied during the dormant period. In contrast, 15N enrichment was 60% higher in vegetative shoots 30 days after anthesis when K15NO3 was applied during the dormant period as occurred following summer applications. Thus, fertilizer nitrogen applied in summer may support the early development of fruit to a greater extent than nitrogen applied during the dormant period. When K15NO3 was applied in Jan, 15N accumulation in reproductive organs occurred after anthesis and corresponded with the period of shoot elongation and leaf expansion. It appears that fertilizer N must be absorbed prior to leaf fall to reach reproductive organs during anthesis.

Published
1980
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28. Optimal cellular mobility for synchronization arising from the gradual recovery of intercellular interactions

Author

Uriu, K., Ares, S., Oates, A. C., and Morelli, L. G.

Subjects
biological rhythm, morphogenesis, cell communication, Computer simulation, Biological, biological model, Article, cell motion, Biological Clocks, Cell Movement, Models, Animals, Humans, animal, human, signal transduction
Abstract

Cell movement and intercellular signaling occur simultaneously during the development of tissues, but little is known about how movement affects signaling. Previous theoretical studies have shown that faster moving cells favor synchronization across a population of locally coupled genetic oscillators. An important assumption in these studies is that cells can immediately interact with their new neighbors after arriving at a new location. However, intercellular interactions in cellular systems may need some time to become fully established. How movement affects synchronization in this situation has not been examined. Here, we develop a coupled phase oscillator model in which we consider cell movement and the gradual recovery of intercellular coupling experienced by a cell after movement, characterized by a moving rate and a coupling recovery rate, respectively. We find (1) an optimal moving rate for synchronization and (2) a critical moving rate above which achieving synchronization is not possible. These results indicate that the extent to which movement enhances synchrony is limited by a gradual recovery of coupling. These findings suggest that the ratio of time scales of movement and signaling recovery is critical for information transfer between moving cells. © 2012 IOP Publishing Ltd.

29. Interplay between intercellular signaling and cell movement in development

Author

Uriu, K., Morelli, L. G., and Oates, A. C.

Subjects
Embryology, cell migration, Physiology, morphogenesis, Review, cell motion, Cell Movement, Models, zebra fish, Animals, animal, cell synchronization, Body Patterning, nonhuman, intracellular signaling, molecular clock, embryo development, Biological, biological model, theoretical study, extracellular space, cell differentiation, cell surface, Embryonic development, neural crest cell, Cytology, neural crest, signal transduction
Abstract

Cell movement and local intercellular signaling are crucial components of morphogenesis during animal development. Intercellular signaling regulates the collective movement of a cell population via direct cell-cell contact. Cell movement, conversely, can influence local intercellular signaling by rearranging neighboring cells. Here, we first discuss theoretical models that address how intercellular signaling regulates collective cell movement during development. Examples include neural crest cell migration, convergent extension, and cell movement during vertebrate axis elongation. Second, we review theoretical studies on how cell movement may affect intercellular signaling, using the segmentation clock in zebrafish as an example. We propose that interplay between cell movement and intercellular signaling must be considered when studying morphogenesis in embryonic development. © 2014 Elsevier Ltd.

30. Dynamics of mobile coupled phase oscillators

Author

Uriu, K., Ares, S., Oates, A. C., and Morelli, L. G.

Subjects
Time-scales, Mean-field, Interaction ranges, One-dimensional lattice, Phase modulation, Coupled phase oscillators, Synchronization dynamics, Phase correlation, Relaxation oscillators, Spatial modes
Abstract

We study the transient synchronization dynamics of locally coupled phase oscillators moving on a one-dimensional lattice. Analysis of spatial phase correlation shows that mobility speeds up relaxation of spatial modes and leads to faster synchronization. We show that when mobility becomes sufficiently high, it does not allow spatial modes to form and the population of oscillators behaves like a mean-field system. Estimating the relaxation timescale of the longest spatial mode and comparing it with systems with long-range coupling, we reveal how mobility effectively extends the interaction range. © 2013 American Physical Society.

50. Virological characteristics of the SARS-CoV-2 XEC variant.

Author

Kaku Y, Okumura K, Kawakubo S, Uriu K, Chen L, Kosugi Y, Uwamino Y, Begum MM, Leong S, Ikeda T, Sadamasu K, Asakura H, Nagashima M, Yoshimura K, Ito J, and Sato K

Abstract

Competing Interests: JI declares consulting fees and honoraria for lectures from Takeda. KSat declares consulting fees from Moderna Japan and Takeda; and honoraria for lectures from Moderna Japan and Shionogi. The other authors declare no competing interests. YKa and KO contributed equally to this study. This study was supported in part by AMED ASPIRE Program (JP24jf0126002 to G2P-Japan Consortium and KSat); AMED SCARDA Japan Initiative for World-leading Vaccine Research and Development Centers “UTOPIA” (JP243fa627001h0003 to KSat); AMED SCARDA Program on R&D of new generation vaccine including new modality application (JP243fa727002 to KSat); AMED Research Program on Emerging and Re-emerging Infectious Diseases (23fk0108583 and JP24fk0108690 to KSat); JST PRESTO (JPMJPR22R2 to YU; JPMJPR22R1 to JI); JSPS KAKENHI Fund for the Promotion of Joint International Research (International Leading Research; JP23K20041 to G2P-Japan Consortium and KSat); JSPS KAKENHI Grant-in-Aid for Early-Career Scientists (JP23K14526 to JI); JSPS Research Fellow DC1 (23KJ0710 to YK); JSPS KAKENHI Grant-in-Aid for Scientific Research A (JP24H00607 to KSat); Mitsubishi UFJ Financial Group Vaccine Development Grant (to JI and KSat); the Cooperative Research Program (Joint Usage/Research Center program) of Institute for Life and Medical Sciences, Kyoto University (to KSat); the Grant for International Joint Research Project of the Institute of Medical Science, the University of Tokyo (to TI and KSat).

Published
2024
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