Different functional sensitivity to mutation at intersubunit interfaces involved in consecutive stages of foot-and-mouth disease virus assembly

© 2015 The Authors. Small spherical viruses are paradigms of supramolecular self-assembly. Identifying the specific structural determinants for virus assembly provides guidelines to develop new antiviral drugs or engineer modified viral particles for medical or technological applications. However, very few systematic studies have been carried out so far to identify those chemical groups at interfaces between virus capsid subunits that are important for viral assembly and function. Foot-and-mouth disease virus (FMDV) and other picornaviruses are assembled in a stepwise process in which different protein–protein interfaces are formed: 5 protomeric subunits oligomerize to form a pentameric intermediate, and 12 of these stable pentameric building blocks associate to form a labile capsid. In this study, a systematic mutational analysis revealed that very few amino acid side chains involved in substantial interactions between protomers within each pentamer are individually required for virus infectivity. This result contrasts sharply with the previous finding that most amino acid side chains involved in interactions between pentamers during the next assembly step are individually required for infectivity. The dramatic difference in sensitivity to single mutations between the two types of protein–protein interfaces in FMDV is discussed in terms of possible structural strategies for achieving self-assembly and genome uncoating in the face of diverse selective constraints.This work was funded by grants from the Spanish Government (BIO2009-10092 and BIO2012-37649) and Comunidad de Madrid (S-505/MAT-0303) to M. G. M., and by an institutional grant from Fundación Ramón Areces to the Centro de Biología Molecular ‘Severo Ochoa>Peer Reviewe

Structural determinants of mechanical resistance against breakage of a virus-based protein nanoparticle at a resolution of single amino acids

Virus particles and other protein-based supramolecular complexes have a vast nanotechnological potential. However, protein nanostructures are “soft” materials prone to disruption by force. Whereas some non-biological nanoparticles (NPs) may be stronger, for certain applications protein- and virus-based NPs have potential advantages related to their structure, self-assembly, production, engineering, and/or inbuilt functions. Thus, it may be desirable to acquire the knowledge needed to engineer protein-based nanomaterials with a higher strength against mechanical breakage. Here we have used the capsid of the minute virus of mice to experimentally identify individual chemical groups that determine breakage-related properties of a virus particle. Individual amino acid side chains that establish interactions between building blocks in the viral particle were truncated using protein engineering. Indentation experiments using atomic force microscopy were carried out to investigate the role of each targeted side chain in determining capsid strength and brittleness, by comparing the maximum force and deformation each modified capsid withstood before breaking apart. Side chains with major roles in determining capsid strength against breakage included polar groups located in solvent-exposed positions, and did not generally correspond with those previously identified as determinants of mechanical stiffness. In contrast, apolar side chains buried along the intersubunit interfaces that generally determined capsid stiffness had, at most, a minor influence on strength against disruption. Whereas no correlated variations between strength and either stiffness or brittleness were found, brittleness and stiffness were quantitatively correlated. Implications for developing robust protein-based NPs and for acquiring a deeper physics-based perspective of viruses are discussedM. M. and A. V. were the respective recipients of a FPI fellowship from Universidad Autónoma de Madrid and a postdoctoral contract from the Spanish Ministerio de Economía y Competitividad (MINECO). M. G. M. is an associate member of the Institute for Biocomputation and Physics of Complex Systems, Zaragoza, Spain. This work was funded by a grant from MINECO/FEDER EU (BIO2015-69928-R) and by an institutional grant from Fundación Ramón Areces. We also acknowledge support of the publication fee by the CSIC Open Access Support Initiative through its Unit of Information Resources for Researc

Biophysical analysis of the MHR motif in folding and domain swapping of the HIV capsid protein C-terminal domain

© 2015 Biophysical Society. Infection by human immunodeficiency virus (HIV) depends on the function, in virion morphogenesis and other stages of the viral cycle, of a highly conserved structural element, the major homology region (MHR), within the carboxyterminal domain (CTD) of the capsid protein. In a modified CTD dimer, MHR is swapped between monomers. While no evidence for MHR swapping has been provided by structural models of retroviral capsids, it is unknown whether it may occur transiently along the virus assembly pathway. Whatever the case, the MHR-swapped dimer does provide a novel target for the development of anti-HIV drugs based on the concept of trapping a nonnative capsid protein conformation. We have carried out a thermodynamic and kinetic characterization of the domain-swapped CTD dimer in solution. The analysis includes a dissection of the role of conserved MHR residues and other amino acids at the dimerization interface in CTD folding, stability, and dimerization by domain swapping. The results revealed some energetic hotspots at the domain-swapped interface. In addition, many MHR residues that are not in the protein hydrophobic core were nevertheless found to be critical for folding and stability of the CTD monomer, which may dramatically slow down the swapping reaction. Conservation of MHR residues in retroviruses did not correlate with their contribution to domain swapping, but it did correlate with their importance for stable CTD folding. Because folding is required for capsid protein function, this remarkable MHR-mediated conformational stabilization of CTD may help to explain the functional roles of MHR not only during immature capsid assembly but in other processes associated with retrovirus infection. This energetic dissection of the dimerization interface in MHR-swapped CTD may also facilitate the design of anti-HIV compounds that inhibit capsid assembly by conformational trapping of swapped CTD dimers.Spanish Government (BIO2012-37649) and Comunidad de Madrid (S-2009/MAT/1467) and by an institutional grant from Fundación Ramón Areces.Peer Reviewe

Evaluación de tres métodos de conservación del plátano mediante: escaldado, inmersión en salmuera y la combinación de ambos métodos, para la producción de tostones pre-fritos a escala de laboratorio

El estudio realizado se basó en la evaluación de tres métodos de conservación de plátano; siendo estos: salmuera utilizando una solución de 1,000ml de agua a 5% g de sal siendo 50g por cada 1,000ml de agua, otro método evaluado fue escaldado sumergiendo en agua a 75˚C durante 60, 75 y 90 segundos, al evaluar estos métodos se procedió a establecer si al combinar ambos (método combinado) mantenían las características de las muestras

Thermostability of the foot-and-mouth disease virus capsid is modulated by lethal and viability-restoring compensatory amino acid substitutions

Infection by viruses depends on a balance between capsid stability and dynamics. This study investigated biologically and biotechnologically relevant aspects of the relationship in foot-and-mouth disease virus (FMDV) between capsid structure and thermostability and between thermostability and infectivity. In the FMDV capsid, a substantial number of amino acid side chains at the interfaces between pentameric subunits are charged at neutral pH. Here a mutational analysis revealed that the essential role for virus infection of most of the 8 tested charged groups is not related to substantial changes in capsid protein expression or processing or in capsid assembly or stability against a thermally induced dissociation into pentamers. However, the positively charged side chains of R2018 and H3141, located at the interpentamer interfaces close to the capsid 2-fold symmetry axes, were found to be critical both for virus infectivity and for keeping the capsid in a state of weak thermostability. A charge-restoring substitution (N2019H) that was repeatedly fixed during amplification of viral genomes carrying deleterious mutations reverted both the lethal and capsid-stabilizing effects of the substitution H3141A, leading to a double mutant virus with close to normal infectivity and thermolability. H3141A and other thermostabilizing substitutions had no detectable effect on capsid resistance to acid-induced dissociation into pentamers. The results suggest that FMDV infectivity requires limited local stability around the 2-fold axes at the interpentamer interfaces of the capsid. The implications for the mechanism of genome uncoating in FMDV and the development of thermostabilized vaccines against foot-and-mouth disease are discussed. IMPORTANCE This study provides novel insights into the little-known structural determinants of the balance between thermal stability and instability in the capsid of foot-and-mouth disease virus and into the relationship between capsid stability and virus infectivity. The results provide new guidelines for the development of thermostabilized empty capsid-based recombinant vaccines against foot-and-mouth disease, one of the economically most important animal diseases worldwid

Electrostatic screening, acidic pH and macromolecular crowding increase the self-assembly efficiency of the minute virus of mice capsid in vitro

The hollow protein capsids from a number of different viruses are being considered for multiple biomedical or nanotechnological applications. In order to improve the applied potential of a given viral capsid as a nanocarrier or nanocontainer, specific conditions must be found for achieving its faithful and efficient assembly in vitro. The small size, adequate physical properties and specialized biological functions of the capsids of parvoviruses such as the minute virus of mice (MVM) make them excellent choices as nanocarriers and nanocontainers. In this study we analyzed the effects of protein concentration, macromolecular crowding, temperature, pH, ionic strength, or a combination of some of those variables on the fidelity and efficiency of self-assembly of the MVM capsid in vitro. The results revealed that the in vitro reassembly of the MVM capsid is an efficient and faithful process. Under some conditions, up to ~40% of the starting virus capsids were reassembled in vitro as free, non aggregated, correctly assembled particles. These results open up the possibility of encapsidating different compounds in VP2-only capsids of MVM during its reassembly in vitro, and encourage the use of virus-like particles of MVM as nanocontainersThis research was funded by grants from MICINN/FEDER EU (Spain, RTI2018-096635-B-100 and PID2021-126973OB-I00) to M.G.M. and by an institutional grant from Fundación Ramón Arece

Negatively charged amino acids at the foot-and-mouth disease virus capsid reduce the virion-destabilizing effect of viral RNA at acidic pH

Elucidation of the molecular basis of the stability of foot-and-mouth disease virus (FMDV) particles is relevant to understand key aspects of the virus cycle. Residue N17D in VP1, located at the capsid inner surface, modulates the resistance of FMDV virion to dissociation and inactivation at acidic pH. Here we have studied whether the virion-stabilizing effect of amino acid substitution VP1 N17D may be mediated by the alteration of electrostatic charge at this position and/or the presence of the viral RNA. Substitutions that either introduced a positive charge (R,K) or preserved neutrality (A) at position VP1 17 led to increased sensitivity of virions to inactivation at acidic pH, while replacement by negatively charged residues (D,E) increased the resistance of virions to acidic pH. The role in virion stability of viral RNA was addressed using FMDV empty capsids that have a virtually unchanged structure compared to the capsid in the RNA-filled virion, but that are considerably more resistant to acidic pH than WT virions, supporting a virion-destabilizing effect of the RNA. Remarkably, no differences were observed in the resistance to dissociation at acidic pH between the WT empty capsids and those harboring replacement N17D. Thus, the virion-destabilizing effect of viral RNA at acidic pH can be partially restored by introducing negatively charged residues at position VP1 N17Work in F.S´s laboratory was funded by grants from MINECO-FEDER EU (AGL2017–84097-C2–1-R), Comunidad de Madrid co-fnanced with ECFEDER funds (P2018/BAA-4370). Work in M.G.M.´s laboratory was funded by grants from MINECO-FEDER EU (BIO2015–69928-R and RTI2018–096635-B-I00). Work by both groups was also funded by an institutional grant from Fundación Ramón Areces M.G.M. is an associate member of the Institute for Biocomputation and Physics of Complex Systems, Zaragoza, Spai

Rationally Designed Interfacial Peptides Are Efficient In Vitro Inhibitors of HIV-1 Capsid Assembly with Antiviral Activity

Virus capsid assembly constitutes an attractive target for the development of antiviral therapies; a few experimental inhibitors of this process for HIV-1 and other viruses have been identified by screening compounds or by selection from chemical libraries. As a different, novel approach we have undertaken the rational design of peptides that could act as competitive assembly inhibitors by mimicking capsid structural elements involved in intersubunit interfaces. Several discrete interfaces involved in formation of the mature HIV-1 capsid through polymerization of the capsid protein CA were targeted. We had previously designed a peptide, CAC1, that represents CA helix 9 (a major part of the dimerization interface) and binds the CA C-terminal domain in solution. Here we have mapped the binding site of CAC1, and shown that it substantially overlaps with the CA dimerization interface. We have also rationally modified CAC1 to increase its solubility and CA-binding affinity, and designed four additional peptides that represent CA helical segments involved in other CA interfaces. We found that peptides CAC1, its derivative CAC1M, and H8 (representing CA helix 8) were able to efficiently inhibit the in vitro assembly of the mature HIV-1 capsid. Cocktails of several peptides, including CAC1 or CAC1M plus H8 or CAI (a previously discovered inhibitor of CA polymerization), or CAC1M+H8+CAI, also abolished capsid assembly, even when every peptide was used at lower, sub-inhibitory doses. To provide a preliminary proof that these designed capsid assembly inhibitors could eventually serve as lead compounds for development of anti-HIV-1 agents, they were transported into cultured cells using a cell-penetrating peptide, and tested for antiviral activity. Peptide cocktails that drastically inhibited capsid assembly in vitro were also able to efficiently inhibit HIV-1 infection ex vivo. This study validates a novel, entirely rational approach for the design of capsid assembly interfacial inhibitors that show antiviral activity

Mechanical stiffening of human rhinovirus by cavity-filling antiviral drugs

Emerging studies at the nanoscale on the relationships between the structure, mechanical properties and infectivity of virus particles are revealing important physics-based foundations of virus biology that may have biomedical and nanotechnological applications. Human rhinovirus (HRV) is the major causative agent of common colds leading to important economic losses, and is also associated with more severe diseases. There is renewed interest in developing effective anti-HRV drugs, but none have been approved so far. We have chosen HRV to explore a possible link between virus mechanics and infectivity and the antiviral effect of certain drugs. In particular, we have investigated a suggestion that the antiviral action of drugs that bind to capsid cavities (pockets) may be related to changes in virus stiffness. Mechanical analysis using atomic force microscopy shows that filling the pockets with drugs or genetically introducing bulkier amino acid side chains into the pockets stiffen HRV virions to different extents. Drug-mediated stiffening affected some regions distant from the pockets and involved in genome uncoating, and may be caused by a subtle structural rearrangement of the virus particle. The results also revealed for HRV a quantitative, logarithmic relationship between mechanical stiffening, achieved either by drug binding or introducing bulkier amino acid side chains into the pockets, and reduced infectivity. From a fundamental physics perspective, these drugs may exert their biological effect by decreasing the deformability of the virion, thus impairing its equilibrium dynamics. The results encourage the design of novel antiviral drugs that inhibit infection by mechanically stiffening the viral particles.MINECO/FEDER EU (BIO2012-37649 and BIO2015-69928-R) and by an institutional grant from Fundación Ramón ArecesPeer Reviewe

Association equilibrium of the HIV-1 capsid protein in a crowded medium reveals that hexamerization during capsid assembly requires a functional C-domain dimerization interface

Polymerization of the intact capsid protein (CA) of HIV-1 into mature capsidlike particles at physiological ionic strength in vitro requires macromolecularly crowded conditions that approach those inside the virion, where the mature capsid is assembled in vivo. The capsid is organized as a hexameric lattice. CA subunits in each hexamer are connected through interfaces that involve the CA N-terminal domain (NTD); pairs of CA subunits belonging to different hexamers are connected through a different interface that involves the C-terminal domain (CTD). At physiological ionic strength in noncrowded conditions, CA subunits homodimerize through this CTD-CTD interface, but do not hexamerize through the other interfaces (those involving the NTD). Here we have investigated whether macromolecular crowding conditions are able to promote hexamerization of the isolated NTD and/or full-length CA (with an inactive CTD-CTD interface to prevent polymerization). The oligomerization state of the proteins was determined using analytical ultracentrifugation in the absence or presence of high concentrations of an inert macromolecular crowding agent. Under the same conditions that promoted efficient assembly of intact CA dimers, neither NTD nor CA with an inactive CTD-CTD interface showed any tendency to form hexamers or any other oligomer. This inability to hexamerize was observed even in macromolecularly crowded conditions. The results indicate that a functional CTD-CTD interface is strictly required for hexamerization of HIV-1 CA through the other interfaces. Together with previous results, these observations suggest that establishment of NTD-CTD interactions involved in CA hexamerization during mature HIV-1 capsid assembly requires a homodimerization-dependent conformational switching of CTD.Spanish Government (BIO2009-10092, BIO2012-37649, BIO2011-28941-C03); Comunidad de Madrid (S-2009/MAT/1467); Fundación Ramón ArecesPeer Reviewe