Intramolecular quality control: HIV-1 envelope gp160 signal-peptide cleavage as a functional folding checkpoint
McCaul, Nicholas; Quandte, Matthias; Bontjer, Ilja; van Zadelhoff, Guus; Land, Aafke; Crooks, Ema T.; Binley, James M.; Sanders, Rogier W.; Braakman, Ineke
(2021) Cell Reports, volume 36, issue 9, pp. 1 - 21
(Article)
Abstract
Removal of the membrane-tethering signal peptides that target secretory proteins to the endoplasmic reticulum is a prerequisite for proper folding. While generally thought to be removed co-translationally, we report two additional post-targeting functions for the HIV-1 gp120 signal peptide, which remains attached until gp120 folding triggers its removal. First, the
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signal peptide improves folding fidelity by enhancing conformational plasticity of gp120 by driving disulfide isomerization through a redox-active cysteine. Simultaneously, the signal peptide delays folding by tethering the N terminus to the membrane, until assembly with the C terminus. Second, its carefully timed cleavage represents intramolecular quality control and ensures release of (only) natively folded gp120. Postponed cleavage and the redox-active cysteine are both highly conserved and important for viral fitness. Considering the ∼15% proteins with signal peptides and the frequency of N-to-C contacts in protein structures, these regulatory roles of signal peptides are bound to be more common in secretory-protein biogenesis.
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Keywords: disulfide bond, disulfide isomerization, endoplasmic reticulum, envelope glycoprotein, gp120, HIV-1, membrane tethering, protein folding, redox-active cysteine, signal peptide, Biochemistry, Genetics and Molecular Biology(all)
ISSN: 2211-1247
Publisher: Elsevier Saunders
Note: Funding Information: We would like to thank members of the Braakman-Van der Sluijs and Sanders labs for their fruitful discussions and insights—in particular, Peter van der Sluijs for critical reading of the manuscript and Joseline Houwman for critical reading of the manuscript and design of Figure 7 . This work was supported by grants from the Dutch Research Council (NWO)- Chemical Sciences 711.012.008 (I. Braakman, N.M., A.L., M.Q.), the European Union 7th framework program , ITN “Virus Entry” 235649 (I. Braakman, N.M., M.Q.), and the European Union’s Horizon 2020 research and innovation program under grant 681137 (R.W.S. and I. Bontjer). R.W.S. is a recipient of a Vici grant from the Dutch Research Council (NWO: 91818627 ). Funding Information: We would like to thank members of the Braakman-Van der Sluijs and Sanders labs for their fruitful discussions and insights?in particular, Peter van der Sluijs for critical reading of the manuscript and Joseline Houwman for critical reading of the manuscript and design of Figure 7. This work was supported by grants from the Dutch Research Council (NWO)- Chemical Sciences 711.012.008 (I. Braakman, N.M. A.L. M.Q.), the European Union 7th framework program, ITN ?Virus Entry? 235649 (I. Braakman, N.M. M.Q.), and the European Union's Horizon 2020 research and innovation program under grant 681137 (R.W.S. and I. Bontjer). R.W.S. is a recipient of a Vici grant from the Dutch Research Council (NWO: 91818627). Conceptualization, N.M. M.Q. and I. Braakman; methodology, N.M.; investigation, N.M. M.Q. I. Bontjer, and A.L.; writing ? original draft, N.M. M.Q. and I. Braakman; writing ? review & editing, N.M. M.Q. I. Bontjer, R.W.S. A.L. and I Braakman; funding acquisition, R.W.S. and I. Braakman. The authors declare no competing interests. Publisher Copyright: © 2021 The Authors
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