Violaine Lantez

Picornavirus non-structural proteins as targets for new anti-virals with broad activity

Picornaviridae is one of the largest viral families and is composed of 14 genera, six of which include human pathogens. The best known picornaviruses are enteroviruses (including polio, PV, and rhinoviruses), foot-and-mouth disease virus (FMDV), and hepatitis A virus (HAV). Although infections often are mild, certain strains may cause pandemic outbreaks accompanied with meningitis and/or paralysis. Vaccines are available for PV, HAV and FMDV. When the oral vaccines are given to immunocompromised individuals, they may be chronically infected, and remain secretors of vaccine-derived variants of virus for years. There is no effective prophylaxis available for these or other picornaviruses. So far, only the 3C protease from viruses in three genera has been fully characterized as an anti-viral target, whereas the mode of action of compounds targeting other non-structural proteins have remained largely unaddressed. Within the EU-supported FP6 project-VIZIER (Comparative Structural Genomics of Viral Enzymes Involved in Replication), the non-structural proteins were studied to identify conserved binding sites for broadly reactive anti-virals. The putative 2C helicase from echovirus-30 was shown to form ring-shaped hexamers typical for DNA-encoded SF3 helicases, and to possess ATPase activity. Hexamer formation of 2C from enterovirus 76 was in vitro shown to be dependent on the 44 N-terminal residues. Crystal structures of three enterovirus 3C proteases were solved and shown to be similar to those of other picornaviruses. A new binding site of VPg to the bottom of the thumb domain of CV-B3 3D polymerase was identified as a potential target. Broad anti-enterovirus compounds against 2C and 3A proteins were also identified, including thiazolobenzimidazoles (active against 2C) and TTP-8307 (targeting 3A). There is a need for more potent inhibitors against PV and other picornaviruses, which are potential silent reservoirs for re-emerging PV-like disease.

Structure of the Methyltransferase Domain from the Modoc Virus, a Flavivirus with No Known Vector.

The Modoc virus (MODV) is a flavivirus with no known vector (NKV). Evolutionary studies have shown that the viruses in the MODV group have evolved in association with mammals (bats, rodents) without transmission by an arthropod vector. MODV methyltransferase is the first enzyme from this evolutionary branch to be structurally characterized. The high-resolution structure of the methyltransferase domain of the MODV NS5 protein (MTase(MODV)) was determined. The protein structure was solved in the apo form and in complex with its cofactor S-adenosyl-L-methionine (SAM). Although it belongs to a separate evolutionary branch, MTase(MODV) shares structural characteristics with flaviviral MTases from the other branches. Its capping machinery is a relatively new target in flaviviral drug development and the observed structural conservation between the three flaviviral branches indicates that it may be possible to identify a drug that targets a range of flaviviruses. The structural conservation also supports the choice of MODV as a possible model for flavivirus studies.

Comparative Production Analysis of Three Phlebovirus Nucleoproteins under Denaturing or Non-Denaturing Conditions for Crystallographic Studies

Nucleoproteins (NPs) encapsidate the Phlebovirus genomic (-)RNA. Upon recombinant expression, NPs tend to form heterogeneous oligomers impeding characterization of the encapsidation process through crystallographic studies. To overcome this problem, we set up a standard protocol in which production under both non-denaturing and denaturing/refolding conditions can be investigated and compared. The protocol was applied for three phlebovirus NPs, allowing an optimized production strategy for each of them. Remarkably, the Rift Valley fever virus NP was purified as a trimer under native conditions and yielded protein crystals whereas the refolded version could be purified as a dimer. Yields of trimeric Toscana virus NP were higher from denaturing than from native condition and lead to crystals. The production of Sandfly Fever Sicilian virus NP failed in both protocols. The comparative protocols described here should help in rationally choosing between denaturing or non-denaturing conditions, which would finally result in the most appropriate and relevant oligomerized protein species. The structure of the Rift Valley fever virus NP has been recently published using a refolded monomeric protein and we believe that the process we devised will contribute to shed light in the genome encapsidation process, a key stage in the viral life cycle.

Reconstitution of Membrane Protein Complexes Involved in Pneumococcal Septal Cell Wall Assembly

The synthesis of peptidoglycan, the major component of the bacterial cell wall, is essential to cell survival, yet its mechanism remains poorly understood. In the present work, we have isolated several membrane protein complexes consisting of the late division proteins of Streptococcus pneumoniae: DivIB, DivIC, FtsL, PBP2x and FtsW, or subsets thereof. We have co-expressed membrane proteins from S. pneumoniae in Escherichia coli. By combining two successive affinity chromatography steps, we obtained membrane protein complexes with a very good purity. These complexes are functional, as indicated by the retained activity of PBP2x to bind a fluorescent derivative of penicillin and to hydrolyze the substrate analogue S2d. Moreover, we have evidenced the stabilizing role of protein-protein interactions within each complex. This work paves the way for a complete reconstitution of peptidoglycan synthesis in vitro, which will be critical to the elucidation of its intricate regulation mechanisms.

The 2C putative helicase of echovirus 30 adopts a hexameric ring-shaped structure

The 2C protein, which is an essential ATPase and one of the most conserved proteins across the Picornaviridae family, is an emerging antiviral target for which structural and functional characterization remain elusive. Based on a distant relationship to helicases of small DNA viruses, piconavirus 2C proteins have been predicted to unwind double-stranded RNAs. Here, a terminally extended variant of the 2C protein from echovirus 30 has been studied by means of enzymatic activity assays, transmission electron microscopy, atomic force microscopy and dynamic light scattering. The transmission electron-microscopy technique showed the existence of ring-shaped particles with ∼12 nm external diameter. Image analysis revealed that these particles were hexameric and resembled those formed by superfamily 3 DNA virus helicases.

Expression, purification and crystallization of the SARS-CoV macro domain.

The SARS-CoV macro domain was expressed, purified and crystallized. Selenomethionine-labelled crystals diffracted to 1.8 Å resolution.

Rapid automated detergent screening for the solubilization and purification of membrane proteins and complexes.

Membrane proteins constitute about one third of proteins encoded by all genomes, but only a small percentage have their structures deposited in the Protein Data Bank. One bottleneck in the pipeline from expression to structure determination is the identification of detergents that maintain the protein in a soluble, stable, and active state. Here, we describe a small‐scale automated procedure to easily and rapidly screen detergents for the solubilization and purification of membrane proteins, to perform detergent exchange, or to identify conditions preserving protein interactions in complexes. Hundreds of conditions can be tested in a few hours to select detergents that keep proteins folded and nonaggregated, from single membrane preparations of cells overexpressing the protein(s) of interest. Thirty‐one prokaryotic, eukaryotic, and viral membrane proteins were analyzed by our small‐scale procedure to identify the best‐associated detergents. Examples of results obtained with a bitopic and multitopic membrane proteins and membrane protein complexes are presented in more detail. DDM, DM, DMNG, TritonX‐100, LAPAO, and Fos‐12 appeared effective for successful membrane solubilization and protein purification of most selected targets. Eukaryotic proteins are in general more difficult to extract and purify from Escherichia coli membranes than prokaryotic proteins. The protocol has been developed for His‐tagged proteins, but can readily be adapted to other affinity tags by adjusting the chromatography resin and the buffer composition.

Preliminary insights into the non structural protein 3 macro domain of the Mayaro virus by powder diffraction

Abstract We present preliminary structural results of the non-structural protein 3 (nsP3) macro domain from the Mayaro virus (MAYV), an emerging virus of South American tropic regions, by means of synchrotron X-ray powder diffraction. Indexing of the diffraction patterns indicate a trigonal/hexagonal lattice (a = 61.60 Å, c = 94.61 Å), analogous to the known lattice of the sequence homologous nsP3 macro domain from the Chikungunia virus (CHIKV), though MAYV must have looser molecular packing: the cell dimensions of MAYV are significantly altered in comparison to CHIKV and the unit cell comprises 6 molecules and 58% solvent. The results are discussed in terms of their methodological and biological importance.

Crystallization and preliminary X-ray diffraction analysis of Nsp15 from SARS coronavirus.

Crystals of Nsp15 from the aetiological agent of SARS have been grown at room temperature. Crystals have cubic symmetry and diffract to a maximum resolution of 2.7 Å.

A Cost-Effective Protocol for the Parallel Production of Libraries of 13 CH 3 -Specifically Labeled Mutants for NMR Studies of High Molecular Weight Proteins

There is increasing interest in applying NMR spectroscopy to the study of large protein assemblies. Development of methyl-specific labeling protocols combined with improved NMR spectroscopy enable nowadays studies of proteins complexes up to 1 MDa. For such large complexes, the major interest lies in obtaining structural, dynamic and interaction information in solution, which requires sequence-specific resonance assignment of NMR signals. While such analysis is quite standard for small proteins, it remains one of the major bottlenecks when the size of the protein increases. Here, we describe implementation and latest improvements of SeSAM, a fast and user-friendly approach for assignment of methyl resonances in large proteins using mutagenesis. We have improved culture medium to boost the production of methyl-specifically labeled proteins, allowing us to perform small-scale parallel production and purification of a library of (13)CH3-specifically labeled mutants. This optimized protocol is illustrated by assignment of Alanine, Isoleucine, and Valine methyl groups of the homododecameric aminopeptidase PhTET2. We estimated that this improved method allows assignment of ca. 100 methyl cross-peaks in 2 weeks, including 4 days of NMR time and less than 2 k€ of isotopic materials.