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Monitoring dynamics of human adenovirus disassembly induced by mechanical fatigue
The standard pathway for virus infection of eukaryotic cells requires disassembly of the viral shell to
facilitate release of the viral genome into the host cell. Here we use mechanical fatigue, well below rupture
strength, to induce stepwise disruption of individual human adenovirus particles under physiological
conditions, and simultaneously monitor disassembly in real time. Our data show the sequence of
dismantling events in individual mature (infectious) and immature (noninfectious) virions, starting with
consecutive release of vertex structures followed by capsid cracking and core exposure. Further, our
experiments demonstrate that vertex resilience depends inextricably on maturation, and establish the
relevance of penton vacancies as seeding loci for virus shell disruption. The mechanical fatigue disruption
route recapitulates the adenovirus disassembly pathway in vivo, as well as the stability differences between
mature and immature virionsWe acknowledge funding by grants from the Ministry of Science and Innovation of Spain,
PIB2010US-00233, FIS2011-29493, Consolider CSD2010-00024 and CAM project and the
Comunidad de Madrid No. S2009/MAT-1467 to P. J. P.; BFU2010-16382/BMC to C.S.M.;
and FIS2011-16090-E to C.S.M. and P.J.P. S.J.F acknowledges funding from the National
Institutes of Health, USA (GM037705 and AI1058172). A.J.P.-B. holds a Juan de la Cierva
postdoctoral contract from the Ministry of Science and Innovation of Spain; A.O.-E. and
R.M.-C. are recipients of predoctoral fellowships from the Ministry of Education and the
Instituto de Salud Carlos III of Spain, respectivel
Structure and uncoating of immature adenovirus
Maturation via proteolytical processing is a common trait in the viral world, and is
often accompanied by large conformational changes and rearrangements in the capsid.
The adenovirus protease has been shown to play a dual role in the viral infectious
cycle: (a) in maturation, as viral assembly starts with precursors to several of the
structural proteins, but ends with proteolytically processed versions in the mature
virion; and (b) in entry, because protease-impaired viruses have difficulties in
endosome escape and uncoating. Indeed, viruses that have not undergone proteolytical
processing are not infectious. We present the 3D structure of immature adenovirus
particles, as represented by the thermosensitive mutant Ad2 ts1 grown under nonpermissive
conditions, and compare it with the mature capsid. Our 3DEM maps at
subnanometer resolution indicate that adenovirus maturation does not involve large
scale conformational changes in the capsid. Difference maps reveal the location of
unprocessed peptides pIIIa and pVI and help to define their role in capsid assembly
and maturation. An intriguing difference appears in the core, indicating a more
compact organization and increased stability of the immature cores. We have further
investigated these properties by in vitro disassembly assays. Fluorescence and
electron microscopy experiments reveal differences in the stability and uncoating of
immature viruses, both at the capsid and core levels, as well as disassembly
intermediates not previously imaged.This work was supported by grants from the Ministerio de Ciencia e Innovación of Spain (BFU2007-60228 to C.S.M. and BIO2007-67150-C03-03 to R.M.), the Comunidad Autónoma de Madrid and Consejo Superior de Investigaciones CientÃficas (CCG08-CSIC/SAL-3442 to C.S.M.) and the National Institutes of Health (5R01CA111569 to D.T.C., R0141599 to W.F.M. and GM037705 to S.J.F.). R.M.-C. is a recipient of a PFIS fellowship from the Instituto de Salud Carlos III of Spain. A.J.P.-B. holds a CSIC JAE-Doc postdoctoral position, partially funded by the European Social FundPeer reviewe
XTEND: Extending the depth of field in cryo soft X-ray tomography
We have developed a new data collection method and processing framework in full field cryo soft X-ray tomography to computationally extend the depth of field (DOF) of a Fresnel zone plate lens. Structural features of 3D-reconstructed eukaryotic cells that are affected by DOF artifacts in standard reconstruction are now recovered. This approach, based on focal series projections, is easily applicable with closed expressions to select specific data acquisition parameters.This work was partially supported by MINECO grants BFU2014-54181 to JLC and AIC-A-2011-0638, BIO2013-44647-R and BIO2016-76400-R to JMC, Madrid. Regional government grants S2013/MIT-2850 to JLC and S2010/BMD-2305 to JMC, National Science Foundation grant DMS-1114901 to GTH, the European Union through BioStruct-X Project 283570 and Horizon 2020 through grant iNEXT (INFRAIA-1-2014-2015, Proposal: 653706).S
Screening a Peptide Library by DSC and SAXD: Comparison with the Biological Function of the Parent Proteins
We have recently identified the membranotropic regions of the hepatitis C virus proteins E1, E2, core and p7 proteins by observing the effect of protein-derived peptide libraries on model membrane integrity. We have studied in this work the ability of selected sequences of these proteins to modulate the Lβ-Lα and Lα-HII phospholipid phase transitions as well as check the viability of using both DSC and SAXD to screen a protein-derived peptide library. We demonstrate that it is feasible to screen a library of peptides corresponding to one or several proteins by both SAXD and DSC. This methodological combination should allow the identification of essential regions of membrane-interacting proteins which might be implicated in the molecular mechanism of membrane fusion and/or budding
Biophysical characterization of the fusogenic region of HCV envelope glycoprotein E1
AbstractWe have studied the binding and interaction of the peptide E1FP with various model membranes. E1FP is derived from the amino acid segment 274–291 of the hepatitis C virus envelope glycoprotein E1, which was previously proposed to host the peptide responsible for fusion to target membranes. In the present study we addressed the changes which take place upon E1FP binding in both the peptide and the phospholipid bilayer, respectively, through a series of complementary experiments. We show that peptide E1FP binds to and interacts with phospholipid model membranes, modulates the polymorphic phase behavior of membrane phospholipids, is localized in a shallow position in the membrane and interacts preferentially with cholesterol. The capability of modifying the biophysical properties of model membranes supports its role in HCV-mediated membrane fusion and suggests that the mechanism of membrane fusion elicited by class I and II fusion proteins might be similar
Identification of the Membrane-Active Regions of the Severe Acute Respiratory Syndrome Coronavirus Spike Membrane Glycoprotein Using a 16/18-Mer Peptide Scan: Implications for the Viral Fusion Mechanism
We have identified the membrane-active regions of the severe acute respiratory syndrome coronavirus (SARS CoV) spike glycoprotein by determining the effect on model membrane integrity of a 16/18-mer SARS CoV spike glycoprotein peptide library. By monitoring the effect of this peptide library on membrane leakage in model membranes, we have identified three regions on the SARS CoV spike glycoprotein with membrane-interacting capabilities: region 1, located immediately upstream of heptad repeat 1 (HR1) and suggested to be the fusion peptide; region 2, located between HR1 and HR2, which would be analogous to the loop domain of human immunodeficiency virus type 1; and region 3, which would correspond to the pretransmembrane region. The identification of these membrane-active regions, which are capable of modifying the biophysical properties of phospholipid membranes, supports their direct role in SARS CoV-mediated membrane fusion, as well as facilitating the future development of SARS CoV entry inhibitors
Scheme of the HCV polyprotein according to literature consensus, including the structural and non-structural proteins.
<p>The sequence and relative location of the 18-mer peptides used in this work, derived from the HCV core, E1, E2 and p7 proteins, are shown with respect to the sequence of the polyprotein. A summary of the normalized experimental membrane rupture data corresponding to 18-mer peptide libraries derived from the whole HCV core <a href="http://www.plosone.org/article/info:doi/10.1371/journal.pone.0004356#pone.0004356-PerezBerna2" target="_blank">[22]</a>, E1 <a href="http://www.plosone.org/article/info:doi/10.1371/journal.pone.0004356#pone.0004356-PerezBerna3" target="_blank">[23]</a>, E2 <a href="http://www.plosone.org/article/info:doi/10.1371/journal.pone.0004356#pone.0004356-PerezBerna3" target="_blank">[23]</a> and p7 <a href="http://www.plosone.org/article/info:doi/10.1371/journal.pone.0004356#pone.0004356-PerezBerna1" target="_blank">[21]</a> proteins is also shown (the darker, the higher).</p
Sequence and numbering of the peptides from the HCV proteins core, E1, E2 and p7 used in this work, as well as a summary of the experimental data.
§<p>(−), 0–15%, 15%>(+)>50%, 50%>(+++)>100% <a href="http://www.plosone.org/article/info:doi/10.1371/journal.pone.0004356#pone.0004356-PerezBerna1" target="_blank">[21]</a>, <a href="http://www.plosone.org/article/info:doi/10.1371/journal.pone.0004356#pone.0004356-PerezBerna2" target="_blank">[22]</a>, <a href="http://www.plosone.org/article/info:doi/10.1371/journal.pone.0004356#pone.0004356-PerezBerna3" target="_blank">[23]</a>.</p>*<p>(+), ΔT<sub>HII</sub> between 0 and 5°C, (++) ΔT<sub>HII</sub> greater than 5°C, (+++) No H<sub>II</sub> phase (this work).</p
Figure 5
<p>(A–C) Small angle X-ray scattering at 25°C, 45°C and 70°C and (D–F) DSC heating thermograms of DEPE in the absence (——) and in the presence (----) of the 18-mer peptides derived from the HCV E2 protein. The 18-mer peptides correspond to amino acid sequences 750–767 (A,D), 771–788 (B,E), 785–802 (C,F). The peptide/phospholipid molar ratio was 1∶50 in all cases.</p