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Membrane-active sequences within gp41 membrane proximal external region (MPER) modulate MPER-containing peptidyl fusion inhibitor activity and the biosynthesis of HIV-1 structural proteins

PLoS ONE (2015) 10(7)
DOI: 10.1371/journal.pone.0134851
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Abstract

The membrane proximal external region (MPER) is a highly conserved membrane-active region located at the juxtamembrane positions within class I viral fusion glycoproteins and essential for membrane fusion events during viral entry. The MPER in the human immunodeficiency virus type I (HIV-1) envelope protein (Env) interacts with the lipid bilayers through a cluster of tryptophan (Trp) residues and a C-terminal cholesterol-interacting motif. The inclusion of the MPER N-terminal sequence contributes to the membrane reactivity and anti-viral efficacy of the first two anti-HIV peptidyl fusion inhibitors T20 and T1249. As a type I transmembrane protein, Env also interacts with the cellular membranes during its biosynthesis and trafficking. Here we investigated the roles of MPER membrane-active sequences during both viral entry and assembly, specifically, their roles in the design of peptidyl fusion inhibitors and the biosynthesis of viral structural proteins. We found that elimination of the membrane-active elements in MPER peptides, namely, penta Trp→alanine (Ala) substitutions and the disruption of the C-terminal cholesterol-interacting motif through deletion inhibited the anti-viral effect against the pseudotyped HIV-1. Furthermore, as compared to C-terminal dimerization, N-terminal dimerization of MPER peptides and N-terminal extension with five helix-forming residues enhanced their anti-viral efficacy substantially. The secondary structure study revealed that the penta-Trp→Ala substitutions also increased the helical content in the MPER sequence, which prompted us to study the biological relevance of such mutations in pre-fusion Env. We observed that Ala mutations of Trp664, Trp668 and Trp670 in MPER moderately lowered the intracellular and intraviral contents of Env while significantly elevating the content of another viral structural protein, p55/Gag and its derivative p24/capsid. The data suggest a role of the gp41 MPER in the membrane-reactive events during both viral entry and budding, and provide insights into the future development of anti-viral therapeutics.

Figures

  • Fig 1. Schematic representation of HIV-1 gp41 and partial sequence alignment of the gp41 from different groups. Partial HR2, the MPER and the TMD sequences of HIV-1 group M subtypes A, B, C and D; group O and the experimental strain of this study, HIV(NL4-3) were aligned[15]. Sequences of the anti-HIV-1 first and second generation fusion inhibitor, T20 and T1498, respectively, are shown together with the MPER-containing peptides tested in this study, EK37, EL30, QK26, QT19, LK21 and LK21-5W5A, and all are aligned with the MPER sequence. The MPER sequence is highlighted in bold with its conserved residues shaded. Peptide LK21-5W5A have all five tryptophan residues in MPER sequence substituted by Ala.
  • Fig 2. Determination of the sequence requirement and the secondary structures of the MPER-containing peptidyl fusion inhibitors. A. Test for inhibition of pseudo HIV-1 (NL4-3) infection of TZM-bl cells by the MPER-containing peptides and the mutant analog LK21-5W5A. Pseudo-HIV-1 virus with concentration of 100TCID50 was incubated with peptides at various concentrations for 1 h, and then added to TZM-bl cells. Seventy-two h post-infection, tatactivated luciferase activity in TZM-bl cells was assessed as a measurement of viral entry and infection. Concentrations of the peptides yielding a 50% and 80% reduction in luciferase activity were estimated with GraphPad Prism. Results shown were summarized from three independent experiments with serial dilutions of peptides in replicates of two. B. No cytotoxicity effect was observed for the MPER-derived peptides at 50 μM in TZM-bl cells. Fifty μM of the peptides were incubated with 10,000 Vero cells for 24 h. PrestoBlue cell viability reagent was subsequently added to the cells, and cytotoxicity effects were monitored as absorbance values (OD) at 570 nm and 600 nm (baseline). C. Circular dichroism spectra and the estimated secondary structure contents of the peptide LK21, QK26, EK30, EK37 and QT19 in 10% TFE. Fifty μM of the peptides were dissolved in H2O supplemented with 10% TFE and were subjected to circular dichroism spectroscopy measurement. D. Circular dichroism spectra and the estimated secondary structure contents of peptide LK21 in increasing concentrations of TFE. Fifty μM of the peptides were dissolved in H2O supplemented with 10%, 20% or 40% TFE and were subjected to circular dichroism measurement. E. Circular dichroism spectra and the estimated secondary structure contents of peptide LK21-5W5A in increasing concentrations of TFE, measured as described in C.
  • Fig 3. Schematic representation of the peptide N- and C-terminal dimerization strategies. N-terminal dimerization employed a linker molecule consisted of two serine residues branching from a lysine, to which two peptides were attached at their N-termini via a thiazolidine linkage. C-terminal dimerization employed a MBHA resin.
  • Fig 4. The influence of N- and C-terminal dimerization on the anti-viral effects of the MPER-derived peptides. A. Test for inhibition of pseudo HIV-1 (NL4-3) infection of TZM-bl cells by dimerized peptide QK26. B. Test for inhibition of pseudo HIV-1 (NL4-3) infection of TZM-bl cells by dimerized peptide EK30.C. Test for inhibition of pseudo HIV-1 (NL4-3) infection of TZM-bl cells by dimerized peptide EK37.D. Summary of the concentrations of peptides yielding a 50% and 80% reduction in tat-activated luciferase activity, as tested in B, C and D. The concentrations were estimated with GraphPad Prism. E. No cytotoxicity effect was observed for the MPER-derived dimeric peptides at 100 μM in TZM-bl cells. Monomeric and dimeric peptides (100 μM) were incubated with 10,000 Vero cells for 24 h. PrestoBlue cell viability reagent was subsequently added to the cells, and cytotoxicity effects were monitored as absorbance values (OD) at 570 nm and 600 nm (baseline).
  • Fig 5. Expression and viral incorporation of viral structural proteins in the context of pseudotyped HIV-1. A. p55/Gag-derived p24 levels in pseudovirusproducing HLtat cells. HIV(WT), HIV(W5A), HIV(W3A) and HIV(W2A) were produced by co-transfecting HLtat cells with pNLHIVxΔuΔss and pNL1.5EU+, pNL1.5EU+W5A, pNL1.5EU+W3A, or pNL1.5EU+W2A, respectively. The p24 levels (ng) in cell lysates were quantified by the automated system Architect (Abbott). ***P < 0.001 as compared to WT by the unpaired Student’s t test.B.Steady-state intracellular levels of viral proteins in pseudovirus-producing HLtat cells. HLtat cells fromA were harvested 48 h post-transfection and the lysates were resolved by SDS-PAGE and immunoblotted with antibodies against gp41, p24, Vif, Nef and β-actin. Vif and Nef expression served as the transfection control. Un-transfected HLtat cells served as negative control.C.Densitometric analysis of protein bands in blots from two independent experiments as described in in B was performed in ImageJ and presented as means ± SD, with gp160, p55/Gag, and p24 levels in HIV(WT) standardized to 100%. *P < 0.05; **P < 0.01 as compared toWT by the unpaired Student’s t test.D. p24 levels (ng) in the culture supernatants of pseudovirus-producing HLtat cells. p24 levels in the culture supernatant of HLtat cells in A was quantified by the automated system Architect (Abbott). ****P < 0.0001 as compared to WT by the unpaired Student’s t test. E. Env gp41, p55/Gag and p24 levels in precipitated HIV(WT), HIV (W5A), HIV(W3A) and HIV(W2A). Viral particles from the cell culture supernatant fromA were precipitated, lysed, separated by SDS-PAGE and immunoblotted with antibodies against gp41 and p24. FDensitometric analysis of the blot in E was performed in ImageJ and presented asmeans, with gp41, p55/Gag and p24

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Zhang, S. M., Jejcic, A., Tam, J. P., & Vahlne, A. (2015). Membrane-active sequences within gp41 membrane proximal external region (MPER) modulate MPER-containing peptidyl fusion inhibitor activity and the biosynthesis of HIV-1 structural proteins. PLoS ONE, 10(7). https://doi.org/10.1371/journal.pone.0134851

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