Your search keyword '"Debnath, Asim K."' showing total 5 results

1. Antiviral activity of α-helical stapled peptides designed from the HIV-1 capsid dimerization domain

Author

Cowburn David, Cooper Alan, Waheed Abdul A, Bhattacharya Shibani, Zhang Xihui, Curreli Francesca, Zhang Hongtao, Freed Eric O, and Debnath Asim K

Subjects

Immunologic diseases. Allergy, RC581-607

Abstract

Abstract Background The C-terminal domain (CTD) of HIV-1 capsid (CA), like full-length CA, forms dimers in solution and CTD dimerization is a major driving force in Gag assembly and maturation. Mutations of the residues at the CTD dimer interface impair virus assembly and render the virus non-infectious. Therefore, the CTD represents a potential target for designing anti-HIV-1 drugs. Results Due to the pivotal role of the dimer interface, we reasoned that peptides from the α-helical region of the dimer interface might be effective as decoys to prevent CTD dimer formation. However, these small peptides do not have any structure in solution and they do not penetrate cells. Therefore, we used the hydrocarbon stapling technique to stabilize the α-helical structure and confirmed by confocal microscopy that this modification also made these peptides cell-penetrating. We also confirmed by using isothermal titration calorimetry (ITC), sedimentation equilibrium and NMR that these peptides indeed disrupt dimer formation. In in vitro assembly assays, the peptides inhibited mature-like virus particle formation and specifically inhibited HIV-1 production in cell-based assays. These peptides also showed potent antiviral activity against a large panel of laboratory-adapted and primary isolates, including viral strains resistant to inhibitors of reverse transcriptase and protease. Conclusions These preliminary data serve as the foundation for designing small, stable, α-helical peptides and small-molecule inhibitors targeted against the CTD dimer interface. The observation that relatively weak CA binders, such as NYAD-201 and NYAD-202, showed specificity and are able to disrupt the CTD dimer is encouraging for further exploration of a much broader class of antiviral compounds targeting CA. We cannot exclude the possibility that the CA-based peptides described here could elicit additional effects on virus replication not directly linked to their ability to bind CA-CTD.

Published

2011

2. Dual-acting stapled peptides target both HIV-1 entry and assembly

Author

Zhang, Hongtao, primary, Curreli, Francesca, additional, Waheed, Abdul A, additional, Mercredi, Peter Y, additional, Mehta, Mansi, additional, Bhargava, Pallavi, additional, Scacalossi, Daniel, additional, Tong, Xiaohe, additional, Lee, Shawn, additional, Cooper, Alan, additional, Summers, Michael F, additional, Freed, Eric O, additional, and Debnath, Asim K, additional

Published

2013

3. Antiviral activity of α-helical stapled peptides designed from the HIV-1 capsid dimerization domain

Author

Zhang, Hongtao, primary, Curreli, Francesca, additional, Zhang, Xihui, additional, Bhattacharya, Shibani, additional, Waheed, Abdul A, additional, Cooper, Alan, additional, Cowburn, David, additional, Freed, Eric O, additional, and Debnath, Asim K, additional

Published

2011

4. Drual-acting stapled peptides target both HIV-1 entry and assembly.

Author

Hongtao Zhang, Curreli, Francesca, Waheed, Abdul A., Mercredi, Peter Y ., Bhargava, Pallavi, Scacalossi, Daniel, Xiaohe Tong, Shawn Lee, Cooper, Alan, Summers, Michael F., Freed, Eric O., and Debnath, Asim K.

Subjects

PEPTIDES, HIV, PROTEINS, CELL culture, BIOCHEMISTRY

Abstract

Background Previously, we reported the conversion of the 12-mer linear and cell-impermeable peptide CAI to a cell-penetrating peptide NYAD-1 by using an i,i + 4 hydrocarbon stapling technique and confirmed its binding to the C-terminal domain (CTD) of the HIV-1 capsid (CA) protein with an improved affinity (Kd ~ 1 μM) compared to CAI (Kd ~ 15 μM). NYAD-1 disrupts the formation of both immature- and mature-like virus particles in in vitro and cell-based assembly assays. In addition, it displays potent anti-HIV-1 activity in cell culture against a range of laboratory-adapted and primary HIV-1 isolates. Results In this report, we expanded the study to i,i + 7 hydrocarbon-stapled peptides to delineate their mechanism of action and antiviral activity. We identified three potent inhibitors, NYAD-36, - 66 and -67, which showed strong binding to CA in NMR and isothermal titration calorimetry (ITC) studies and disrupted the formation of mature-like particles. They showed typical α- helical structures and penetrated cells; however, the cell penetration was not as efficient as observed with the i,i + 4 peptides. Unlike NYAD-1, the i,i + 7 peptides did not have any effect on virus release; however, they impaired Gag precursor processing. HIV-1 particles produced in the presence of these peptides displayed impaired infectivity. Consistent with an effect on virus entry, selection for viral resistance led to the emergence of two mutations in the gp120 subunit of the viral envelope (Env) glycoprotein, V120Q and A327P, located in the conserved region 1 (C1) and the base of the V3 loop, respectively. Conclusion The i,i + 7 stapled peptides derived from CAI unexpectedly target both CA and the V3 loop of gp120. This dual-targeted activity is dependent on their ability to penetrate cells as well as their net charge. This mechanistic revelation will be useful in further modifying these peptides as potent anti-HIV-1 agents. [ABSTRACT FROM AUTHOR]

Published

2013

5. Antiviral activity of α-helical stapled peptides designed from the HIV-1 capsid dimerization domain.

Author

Hongtao Zhang, Curreli, Francesca, Xihui Zhang, Bhattacharya, Shibani, Waheed, Abdul A., Cooper, Alan, Cowburn, David, Freed, Eric O., and Debnath, Asim K.

Subjects

HIV infections, HIV, CONFOCAL microscopy, OLIGOMERS, ANTIVIRAL agents

Abstract

Background: The C-terminal domain (CTD) of HIV-1 capsid (CA), like full-length CA, forms dimers in solution and CTD dimerization is a major driving force in Gag assembly and maturation. Mutations of the residues at the CTD dimer interface impair virus assembly and render the virus non-infectious. Therefore, the CTD represents a potential target for designing anti-HIV-1 drugs. Results: Due to the pivotal role of the dimer interface, we reasoned that peptides from the α-helical region of the dimer interface might be effective as decoys to prevent CTD dimer formation. However, these small peptides do not have any structure in solution and they do not penetrate cells. Therefore, we used the hydrocarbon stapling technique to stabilize the α-helical structure and confirmed by confocal microscopy that this modification also made these peptides cell-penetrating. We also confirmed by using isothermal titration calorimetry (ITC), sedimentation equilibrium and NMR that these peptides indeed disrupt dimer formation. In in vitro assembly assays, the peptides inhibited mature-like virus particle formation and specifically inhibited HIV-1 production in cell-based assays. These peptides also showed potent antiviral activity against a large panel of laboratory-adapted and primary isolates, including viral strains resistant to inhibitors of reverse transcriptase and protease. Conclusions: These preliminary data serve as the foundation for designing small, stable, α-helical peptides and small-molecule inhibitors targeted against the CTD dimer interface. The observation that relatively weak CA binders, such as NYAD-201 and NYAD-202, showed specificity and are able to disrupt the CTD dimer is encouraging for further exploration of a much broader class of antiviral compounds targeting CA. We cannot exclude the possibility that the CA-based peptides described here could elicit additional effects on virus replication not directly linked to their ability to bind CA-CTD. [ABSTRACT FROM AUTHOR]

Published

2011