Your search keyword '"Akeefe, Hassibullah"' showing total 5 results

1. Ultra-sensitive AAV capsid detection by immunocapture-based qPCR following factor VIII gene transfer

Author

Sandza, Krystal, Clark, Annie, Koziol, Elli, Akeefe, Hassibullah, Yang, Fan, Holcomb, Jennifer, Patton, Kathryn, Hammon, Kevin, Mitchell, Nina, Wong, Wing Y., Zoog, Stephen J., Kim, Benjamin, Henshaw, Joshua, and Vettermann, Christian

Abstract

Adeno-associated virus (AAV)-based gene therapy vectors are replication-incompetent and thus pose minimal risk for horizontal transmission or release into the environment. In studies with AAV5-FVIII-SQ (valoctocogene roxaparvovec), an investigational gene therapy for hemophilia A, residual vector DNA was detectable in blood, secreta, and excreta, but it remained unclear how long structurally intact AAV5 vector capsids were present. Since a comprehensive assessment of vector shedding is required by regulatory agencies, we developed a new method (termed iqPCR) that utilizes capsid-directed immunocapture followed by qPCR amplification of encapsidated DNA. The limit of detection for AAV5 vector capsids was 1.17E+04 and 2.33E+04 vg/mL in plasma and semen, respectively. Acceptable precision, accuracy, selectivity, and specificity were verified; up to 1.00E+09 vg/mL non-encapsidated vector DNA showed no interference. Anti-AAV5 antibody plasma concentrations above 141 ng/mL decreased AAV5 capsid quantification, suggesting that iqPCR mainly detects free capsids and not those complexed with antibodies. In a clinical study, AAV5-FVIII-SQ capsids were found in plasma and semen but became undetectable within nine weeks after dose administration. Hence, iqPCR monitors the presence and shedding kinetics of intact vector capsids following AAV gene therapy and informs the potential risk for horizontal transmission.

Published

2021

2. Selective delipidation of plasma HDL enhances reverse cholesterol transport in vivo

Author

Sacks, Frank M., Rudel, Lawrence L., Conner, Adam, Akeefe, Hassibullah, Kostner, Gerhard, Baki, Talal, Rothblat, George, de la Llera-Moya, Margarita, Asztalos, Bela, Perlman, Timothy, Zheng, Chunyu, Alaupovic, Petar, Maltais, Jo-Ann B., and Brewer, H. Bryan

Abstract

Uptake of cholesterol from peripheral cells by nascent small HDL circulating in plasma is necessary to prevent atherosclerosis. This process, termed reverse cholesterol transport, produces larger cholesterol-rich HDL that transfers its cholesterol to the liver facilitating excretion. Most HDL in plasma is cholesterol-rich. We demonstrate that treating plasma with a novel selective delipidation procedure converts large to small HDL [HDL-selectively delipidated (HDL-sdl)]. HDL-sdl contains several cholesterol-depleted species resembling small α, preβ-1, and other preβ forms. Selective delipidation markedly increases efficacy of plasma to stimulate ABCA1-mediated cholesterol transfer from monocytic cells to HDL. Plasma from African Green monkeys underwent selective HDL delipidation. The delipidated plasma was reinfused into five monkeys. Preβ-1-like HDL had a plasma residence time of 8 ± 6 h and was converted entirely to large α-HDL having residence times of 13–14 h. Small α-HDL was converted entirely to large α-HDL. These findings suggest that selective HDL delipidation activates reverse cholesterol transport, in vivo and in vitro. Treatment with delipidated plasma tended to reduce diet-induced aortic atherosclerosis in monkeys measured by intravascular ultrasound. These findings link the conversion of small to large HDL, in vivo, to improvement in atherosclerosis.

Published

2009

3. Selective delipidation of plasma HDL enhances reverse cholesterol transport in vivo

Author

Sacks, Frank M., Rudel, Lawrence L., Conner, Adam, Akeefe, Hassibullah, Kostner, Gerhard, Baki, Talal, Rothblat, George, de la Llera-Moya, Margarita, Asztalos, Bela, Perlman, Timothy, Zheng, Chunyu, Alaupovic, Petar, Maltais, Jo-Ann B., and Brewer, H. Bryan

Abstract

Uptake of cholesterol from peripheral cells by nascent small HDL circulating in plasma is necessary to prevent atherosclerosis. This process, termed reverse cholesterol transport, produces larger cholesterol-rich HDL that transfers its cholesterol to the liver facilitating excretion. Most HDL in plasma is cholesterol-rich. We demonstrate that treating plasma with a novel selective delipidation procedure converts large to small HDL [HDL-selectively delipidated (HDL-sdl)]. HDL-sdl contains several cholesterol-depleted species resembling small α, preβ-1, and other preβ forms. Selective delipidation markedly increases efficacy of plasma to stimulate ABCA1-mediated cholesterol transfer from monocytic cells to HDL. Plasma from African Green monkeys underwent selective HDL delipidation. The delipidated plasma was reinfused into five monkeys. Preβ-1-like HDL had a plasma residence time of 8 ± 6 h and was converted entirely to large α-HDL having residence times of 13–14 h. Small α-HDL was converted entirely to large α-HDL. These findings suggest that selective HDL delipidation activates reverse cholesterol transport, in vivo and in vitro. Treatment with delipidated plasma tended to reduce diet-induced aortic atherosclerosis in monkeys measured by intravascular ultrasound. These findings link the conversion of small to large HDL, in vivo, to improvement in atherosclerosis.

Published

2009

4. Delipidated Retroviruses as Potential Autologous Therapeutic Vaccines—A Pilot Experiment

Author

Kitabwalla, Moiz, Ansari, Aftab A., Villinger, Francois, Akeefe, Hassibullah, Conner, Adam P., Mayne, Ann E., and Hildreth, James E. K.

Published

2008

5. Overexpression of Hepatic Lipase in Transgenic Mice Decreases Apolipoprotein B-containing and High Density Lipoproteins

Author

Dichek, Helén L., Brecht, Walter, Fan, Jianglin, Ji, Zhong-Sheng, McCormick, Sally P.A., Akeefe, Hassibullah, Conzo, LoriAnna, Sanan, David A., Weisgraber, Karl H., Young, Stephen G., Taylor, John M., and Mahley, Robert W.

Abstract

To determine the mechanisms by which human hepatic lipase (HL) contributes to the metabolism of apolipoprotein (apo) B-containing lipoproteins and high density lipoproteins (HDL)in vivo, we developed and characterized HL transgenic mice. HL was localized by immunohistochemistry to the liver and to the adrenal cortex. In hemizygous (hHLTg+/0) and homozygous (hHLTg+/+) mice, postheparin plasma HL activity increased by 25- and 50-fold and plasma cholesterol levels decreased by 80% and 85%, respectively. In mice fed a high fat, high cholesterol diet to increase endogenous apoB-containing lipoproteins, plasma cholesterol decreased 33% (hHLTg+/0) and 75% (hHLTg+/+). Both apoB-containing remnant lipoproteins and HDL were reduced. To extend this observation, the HL transgene was expressed in human apoB transgenic (huBTg) and apoE-deficient (apoE−/−) mice, both of which have high plasma levels of apoB-containing lipoproteins. (Note that thehuBTgmice that were used in these studies were all hemizygous for the human apoB gene.) In both thehuBTg,hHLTg+/0mice and theapoE−/−,hHLTg+/0mice, plasma cholesterol decreased by 50%. This decrease was reflected in both the apoB-containing and the HDL fractions. To determine if HL catalytic activity is required for these decreases, we expressed catalytically inactive HL (HL-CAT) in apoE−/−mice. The postheparin plasma HL activities were similar in theapoE−/−and theapoE−/−,HL-CAT+/0mice, reflecting the activity of the endogenous mouse HL and confirming that the HL-CAT was catalytically inactive. However, the postheparin plasma HL activity was 20-fold higher in theapoE−/−,hHLTg+/0mice, indicating expression of the active human HL. Immunoblotting demonstrated high levels of human HL in postheparin plasma of bothapoE−/−,hHLTg+/0and apoE−/−,HL-CAT+/0mice. Plasma cholesterol and apoB-containing lipoprotein levels were ∼60% lower inapoE−/−,HL-CAT+/0mice than in apoE−/−mice. However, the HDL were only minimally reduced. Thus, the catalytic activity of HL is critical for its effects on HDL but not for its effects on apoB-containing lipoproteins. These results provide evidence that HL can act as a ligand to remove apoB-containing lipoproteins from plasma.

Published

1998