Identification of quinone analogues as potential inhibitors of picornavirus 3C protease in vitro

Picornaviruses are non-enveloped viruses that represent a large family of positive-sense single-stranded RNA viruses including a number of causative agents of many human and animal diseases such as coxsackievirus B3 (CVB3) and rhinoviruses (HRV). In this study, we performed a high-throughput screening of a compound library composed of ～6000 small molecules in search of potential picornavirus 3C protease (3C^pro) inhibitors. As results, we identified quinone analogues that effectively inhibited both CVB3 3C^pro and HRV 3C^pro with IC₅₀ values in low micromolar range. Together with predicted binding modes of these compounds to the active site of the viral protease, it is implied that structural features of these non-peptidic inhibitors may act as useful scaffold for further anti-picornavirus drug design and development.     

Functional binding of hexanucleotides to 3C protease of hepatitis A virus

Oligonucleotides as short as 6 nt in length have been shown to bind specifically and tightly to proteins and affect their biological function. Yet, sparse structural data are available for corresponding complexes. Employing a recently developed hexanucleotide array, we identified hexadeoxyribonucleotides that bind specifically to the 3C protease of hepatitis A virus (HAV 3C^pro). Inhibition assays in vitro identified the hexanucleotide 5′-GGGGGT-3′ (G₅T) as a 3C^pro protease inhibitor. Using ¹H NMR spectroscopy, G₅T was found to form a G-quadruplex, which might be considered as a minimal aptamer. With the help of ¹H, ¹⁵N-HSQC experiments the binding site for G₅T was located to the C-terminal β-barrel of HAV 3C^pro. Importantly, the highly conserved KFRDI motif, which has previously been identified as putative viral RNA binding site, is not part of the G₅T-binding site, nor does G₅T interfere with the binding of viral RNA. Our findings demonstrate that sequence-specific nucleic acid–protein interactions occur with oligonucleotides as small as hexanucleotides and suggest that these compounds may be of pharmaceutical relevance.     

Mutations at KFRDI and VGK domains of enterovirus 71 3C protease affect its RNA binding and proteolytic activities

The 3C proteases (3C^pro) of enterovirus 71 (EV71) is a good molecular target for drug discovery. Notably, this protease was found to possess RNA-binding activity. The regions responsible for RNA binding were classified as KFRDI (positions 82–86) and VGK (positions 154–156) in 3C^pro by mutagenesis study. Although the RNA-binding regions are structurally distinct from the catalytic site of EV71 3C^pro, mutations in the RNA-binding regions influenced 3C^pro proteolytic activity. In contrast, mutations at the catalytic site had almost no influence on RNA binding ability. We identified certain mutations within 3C^pro which abrogated both the RNA-binding activity of the expressed, recombinant, protease and the ability to rescue virus from an infectious full-length clone of EV71 (pEV71). Interestingly, mutation at position 84 from Arg(R) to Lys(K) was found to retain good RNA binding and proteolytic activity for the recombinant 3C^pro; however, no virus could be rescued when pEV71 with the R84K mutation was introduced into the infectious copy. Together, these results may provide useful information for using 3C^pro as the molecular target to develop anti-EV71 agents.The second and the third authors contributed equally to this work.     

Molecular Biology and Cell-free Synthesis of Poliovirus

Abstract. Poliovirus is a small icosahedral particle consisting of only five species of macromolecules: 60 copies each of the capsid protein VP1-4; and one copy of single-stranded RNA, approximately 7500 nt long. The genome, linked at the 5′ end to a small protein VPg and 3′ polyadenylylated, is of plus strand polarity. After receptor-mediated uptake of the virus and release of the RNA into the cytoplasm, the genome serves as mRNA, encoding only a single polypeptide, the polyprotein. The polyprotein is cleaved co-translationally into numerous polypeptides by its own, internal proteinases 2A^pro, 3C^pro and 3CD^pro. Initiation of translation is mediated by a novel genetic element, called internal ribosomal entry site (IRES). IRES elements, which are 400 nt long RNA segments located within the 5′ non-translated region of the viral genome, are common to all picornaviruses. Their function renders translation of picornavirus mRNAs cap- and 5′-independent, an observation that has upset the dogma of cap-dependent translation in eukaryotic cells. IRES elements have also been used to genetically dissect the viral genome and to construct novel expression vectors. Genome replication is not fully understood, the major conundrum being the initiation of RNA synthesis by the primer-dependent viral RNA polymerase 3D^pol, a process leading to VPg-linked RNA products. Nearly all non-structural proteins appear to be involved in initiation, the proteinases 2A^pro and 3CD^pro included. A HeLa cell-free system has been developed that, on programming with plasmid-transcribed viral RNA, will perform viral translation, protein processing, RNA replication, and assembly of capsid protein and newly made genomic RNA. The final yield is infectious poliovirus. This result has nullified the dictum that no virus can replicate in a cell-free medium.     

Enterovirus 71 3C Protease Cleaves a Novel Target CstF-64 and Inhibits Cellular Polyadenylation

Identification of novel cellular proteins as substrates to viral proteases would provide a new insight into the mechanism of cell–virus interplay. Eight nuclear proteins as potential targets for enterovirus 71 (EV71) 3C protease (3C^pro) cleavages were identified by 2D electrophoresis and MALDI-TOF analysis. Of these proteins, CstF-64, which is a critical factor for 3′ pre-mRNA processing in a cell nucleus, was selected for further study. A time-course study to monitor the expression levels of CstF-64 in EV71-infected cells also revealed that the reduction of CstF-64 during virus infection was correlated with the production of viral 3C^pro. CstF-64 was cleaved in vitro by 3C^pro but neither by mutant 3C^pro (in which the catalytic site was inactivated) nor by another EV71 protease 2A^pro. Serial mutagenesis was performed in CstF-64, revealing that the 3C^pro cleavage sites are located at position 251 in the N-terminal P/G-rich domain and at multiple positions close to the C-terminus of CstF-64 (around position 500). An accumulation of unprocessed pre-mRNA and the depression of mature mRNA were observed in EV71-infected cells. An in vitro assay revealed the inhibition of the 3′-end pre-mRNA processing and polyadenylation in 3C^pro-treated nuclear extract, and this impairment was rescued by adding purified recombinant CstF-64 protein. In summing up the above results, we suggest that 3C^pro cleavage inactivates CstF-64 and impairs the host cell polyadenylation in vitro, as well as in virus-infected cells. This finding is, to our knowledge, the first to demonstrate that a picornavirus protein affects the polyadenylation of host mRNA.     

Crystal structure of human enterovirus 71 3C protease

Human enterovirus 71 (EV71) is the major pathogen that causes hand, foot and mouth disease that particularly affects young children. Growing hand, foot and mouth disease outbreaks were observed worldwide in recent years and caused devastating losses both economically and politically. However, vaccines or effective drugs are unavailable to date. The genome of EV71 consists of a positive sense, single-stranded RNA of ∼ 7400 bp, encoding a large precursor polyprotein that requires proteolytic processing to generate mature viral proteins. The proteolytic processing mainly depends on EV71 3C protease (3C^pro) that possesses both proteolysis and RNA binding activities, which enable the protease to perform multiple tasks in viral replication and pathogen-host interactions. The central roles played by EV71 3C^pro make it an appealing target for antiviral drug development. We determined the first crystal structure of EV71 3C^pro and analyzed its enzymatic activity. The crystal structure shows that EV71 3C^pro has a typical chymotrypsin-like fold that is common in picornaviral 3C^pro. Strikingly, we found an important surface loop, also denoted as β-ribbon, which adopts a novel open conformation in EV71 3C^pro. We identified two important residues located at the base of the β-ribbon, Gly123 and His133, which form hinges that govern the intrinsic flexibility of the ribbon. Structure-guided mutagenesis studies revealed that the hinge residues are important to EV71 3C^pro proteolytic activities. In summary, our work provides the first structural insight into EV71 3C^pro, including a mobile β-ribbon, which is relevant to the proteolytic mechanism. Our data also provides a framework for structure-guided inhibitor design against EV71 3C^pro.     

Complete Protein Linkage Map of Poliovirus P3 Proteins: Interaction of Polymerase 3Dpol with VPg and with Genetic Variants of 3AB

Poliovirus has evolved to maximize its genomic information by producing multifunctional viral proteins. The P3 nonstructural proteins harbor various activities when paired with different binding partners. These viral polypeptides regulate host cell macromolecular synthesis and function as proteinases, as RNA binding proteins, or as RNA-dependent RNA polymerase. A cleavage product of the P3 region is the genome-linked protein VPg that is essential in the initiation of RNA synthesis. We have used an inducible yeast two-hybrid system to analyze directly protein-protein interactions among P3 proteins. Sixteen signals of homo- or heterodimer interactions have been observed and have been divided into three groups. Of interest is the newly discovered affinity of VPg to 3D^pol that suggests direct interaction between these molecules in genome replication. A battery of 3AB variants (eight clustered-charge-to-alanine changes and five single-amino-acid mutations) has been used to map the binding determinants of 3AB-3AB interaction which were found to differ from the amino acids critical for the 3AB-3D^pol interaction. The viral proteinase 3C^pro was not found to interact with other 3C^pro molecules or with any other P3 polypeptide in yeast cells, a result confirmed by glutaraldehyde cross-linking. The weak apparent interaction between 3AB and 3CD^pro scored in the yeast two-hybrid system was in contrast to a strong signal by far-Western blotting. The results elucidate, in part, previous results of biochemical and genetic analyses. The role of the interactions in RNA replication is addressed.     

Insights into Cleavage Specificity from the Crystal Structure of Foot-and-Mouth Disease Virus 3C Protease Complexed with a Peptide Substrate

Picornavirus replication is critically dependent on the correct processing of a polyprotein precursor by 3C protease(s) (3C^pro) at multiple specific sites with related but non-identical sequences. To investigate the structural basis of its cleavage specificity, we performed the first crystallographic structural analysis of non-covalent complexes of a picornavirus 3C^pro with peptide substrates. The X-ray crystal structure of the foot-and-mouth disease virus 3C^pro, mutated to replace the catalytic Cys by Ala and bound to a peptide (APAKQ|LLNFD) corresponding to the P5-P5′ region of the VP1-2A cleavage junction in the viral polyprotein, was determined up to 2.5 Å resolution. Comparison with free enzyme reveals significant conformational changes in 3C^pro on substrate binding that lead to the formation of an extended interface of contact primarily involving the P4-P2′ positions of the peptide. Strikingly, the deep S1′ specificity pocket needed to accommodate P1′-Leu only forms when the peptide binds. Substrate specificity was investigated using peptide cleavage assays to show the impact of amino acid substitutions within the P5-P4′ region of synthetic substrates. The structure of the enzyme-peptide complex explains the marked substrate preferences for particular P4, P2 and P1 residue types, as well as the relative promiscuity at P3 and on the P′ side of the scissile bond. Furthermore, crystallographic analysis of the complex with a modified VP1-2A peptide (APAKE|LLNFD) containing a Gln-to-Glu substitution reveals an identical mode of peptide binding and explains the ability of foot-and-mouth disease virus 3C^pro to cleave sequences containing either P1-Gln or P1-Glu. Structure-based mutagenesis was used to probe interactions within the S1′ specificity pocket and to provide direct evidence of the important contribution made by Asp84 of the Cys-His-Asp catalytic triad to proteolytic activity. Our results provide a new level of detail in our understanding of the structural basis of polyprotein cleavage by 3C^pro.     

Poly(A) binding protein, C-terminally truncated by the hepatitis A virus proteinase 3C, inhibits viral translation

Proteolytic cleavage of translation initiation factors is a means to interfere with mRNA circularization and to induce translation arrest during picornaviral replication or apoptosis. It was shown that the regulated cleavages of eukaryotic initiation factor (eIF) 4G and poly(A)-binding protein (PABP) by viral proteinases correlated with early and late arrest of host cap-dependent and viral internal ribosome entry site (IRES)-dependent translation, respectively. Here we show that in contrast to coxsackievirus, eIF4G is not a substrate of proteinase 3C of hepatitis A virus (HAV 3C^pro). However, PABP is cleaved by HAV 3C^pro in vitro and in vivo, separating the N-terminal RNA-binding domain (NTD) of PABP from the C-terminal protein-interaction domain. In vitro, NTD has a dominant negative effect on HAV IRES-dependent translation and an enhanced binding affinity to the RNA structural element pY1 in the 5′ nontranslated region of the HAV RNA that is essential for viral genome replication. The results point to a regulatory role of PABP cleavage in RNA template switching of viral translation to RNA synthesis.     

Hepatitis A Virus 3C Protease Cleaves NEMO To Impair Induction of Beta Interferon

NEMO (NF-κB essential modulator) is a bridging adaptor indispensable for viral activation of interferon (IFN) antiviral response. Herein, we show that hepatitis A virus (HAV) 3C protease (3C^pro) cleaves NEMO at the Q304 residue, negating its signaling adaptor function and abrogating viral induction of IFN-β synthesis via the retinoic acid-inducible gene I/melanoma differentiation-associated protein 5 (RIG-I/MDA5) and Toll-like receptor 3 (TLR3) pathways. NEMO cleavage and IFN antagonism, however, were lost upon ablation of the catalytic activity of 3C^pro. These data describe a novel immune evasion mechanism of HAV.     

A novel cGUUAg tetraloop structure with a conserved yYNMGg-type backbone conformation from cloverleaf 1 of bovine enterovirus 1 RNA

The 5′-terminal cloverleaf (CL)-like RNA structures are essential for the initiation of positive- and negative-strand RNA synthesis of entero- and rhinoviruses. SLD is the cognate RNA ligand of the viral proteinase 3C (3C^pro), which is an indispensable component of the viral replication initiation complex. The structure of an 18mer RNA representing the apical stem and the cGUUAg D-loop of SLD from the first 5′-CL of BEV1 was determined in solution to a root-mean-square deviation (r.m.s.d.) (all heavy atoms) of 0.59 Å (PDB 1Z30). The first (antiG) and last (synA) nucleotide of the D-loop forms a novel ‘pseudo base pair’ without direct hydrogen bonds. The backbone conformation and the base-stacking pattern of the cGUUAg-loop, however, are highly similar to that of the coxsackieviral uCACGg D-loop (PDB 1RFR) and of the stable cUUCGg tetraloop (PDB 1F7Y) but surprisingly dissimilar to the structure of a cGUAAg stable tetraloop (PDB 1MSY), even though the cGUUAg BEV D-loop and the cGUAAg tetraloop differ by 1 nt only. Together with the presented binding data, these findings provide independent experimental evidence for our model [O. Ohlenschläger, J. Wöhnert, E. Bucci, S. Seitz, S. Häfner, R. Ramachandran, R. Zell and M. Görlach (2004) Structure, 12, 237–248] that the proteinase 3C^pro recognizes structure rather than sequence.     

Structure–activity relationships of heteroaromatic esters as human rhinovirus 3C protease inhibitors

Human rhinovirus 3C protease (HRV 3C^pro) is known to be a promising target for development of therapeutic agents against the common cold because of the importance of the protease in viral replication as well as its expression in a large number of serotypes. To explore non-peptidic inhibitors of HRV 3C^pro, a series of novel heteroaromatic esters was synthesized and evaluated for inhibitory activity against HRV 3C^pro, to determine the structure–activity relationships. The most potent inhibitor, 7, with a 5-bromopyridinyl group, had an IC₅₀ value of 80 nM. In addition, the binding mode of a novel analog, 19, with the 4-hydroxyquinolinone moiety, was explored by molecular docking, suggesting a new interaction in the S1 pocket.     

NMR structure of stem-loop D from human rhinovirus-14

The 5'-cloverleaf of the picornavirus RNA genome is essential for the assembly of a ribonucleoprotein replication complex. Stem-loop D (SLD) of the cloverleaf is the recognition site for the multifunctional viral protein 3Cpro. This protein is the principal viral protease, and its interaction with SLD also helps to position the viral RNA-dependent RNA polymerase (3Dpol) for replication. Human rhinovirus-14 (HRV-14) is distinct from the majority of picornaviruses in that its SLD forms a cUAUg triloop instead of the more common uYACGg tetraloop. This difference appears to be functionally significant, as 3Cpro from tetraloop-containing viruses cannot bind the HRV-14 SLD. We have determined the solution structure of the HRV-14 SLD using NMR spectroscopy. The structure is predominantly an A-form helix, but with a central pyrimidine-pyrimidine base-paired region and a significantly widened major groove. The stabilizing hydrogen bonding present in the uYACGg tetraloop was not found in the cUAUg triloop. However, the triloop uses different structural elements to present a largely similar surface: sequence and underlying architecture are not conserved, but key aspects of the surface structure are. Important structural differences do exist, though, and may account for the observed cross-isotype binding specificities between 3Cpro and SLD.     

Global RNA Structure Analysis of Poliovirus Identifies a Conserved RNA Structure Involved in Viral Replication and Infectivity

The genomes of RNA viruses often contain RNA structures that are crucial for translation and RNA replication and may play additional, uncharacterized roles during the viral replication cycle. For the picornavirus family member poliovirus, a number of functional RNA structures have been identified, but much of its genome, especially the open reading frame, has remained uncharacterized. We have now generated a global RNA structure map of the poliovirus genome using a chemical probing approach that interrogates RNA structure with single-nucleotide resolution. In combination with orthogonal evolutionary analyses, we uncover several conserved RNA structures in the open reading frame of the viral genome. To validate the ability of our global analyses to identify functionally important RNA structures, we further characterized one of the newly identified structures, located in the region encoding the RNA-dependent RNA polymerase, 3D^pol, by site-directed mutagenesis. Our results reveal that the structure is required for viral replication and infectivity, since synonymous mutants are defective in these processes. Furthermore, these defects can be partially suppressed by mutations in the viral protein 3C^pro, which suggests the existence of a novel functional interaction between an RNA structure in the 3D^pol-coding region and the viral protein(s) 3C^pro and/or its precursor 3CD^pro.     

Processing of Proteinase Precursors and Their Effect on Hepatitis A Virus Particle Formation

Proteolytic processing of the picornaviral polyprotein mediated by the differential action of virus-encoded proteinase(s) is pivotal to both RNA genome replication and capsid formation. Possibly to enlarge the array of viral proteins, picornaviral polyprotein processing results in intermediate and mature products which apparently have distinct functions within the viral life cycle. For hepatitis A virus (HAV), we report here on the autoproteolysis of precursor polypeptides comprising the only viral proteinase, 3C^pro, and on their role in viral particle formation. Following transient expression of a nested set of 3C^pro-containing proteins (P3, 3ABC, 3BCD, 3CD, 3BC, and 3C) in eukaryotic cells, the extent of processing was determined by analyzing the cleavage products. The 3C/3D site was more efficiently cleaved than those at the 3A/3B and 3B/3C sites, leading to the accumulation of the intermediate product 3ABC. In the absence of 3A from the precursor, cleavage at the 3B/3C site was further reduced and a switch to an alternative 3C/3D site was observed. Coexpression of various parts of P3 with the precursor of the viral structural proteins P1-2A showed that all 3C-containing intermediates cleaved P1-2A with almost equal efficiency; however, viral particles carrying the neutralizing epitope form much more readily in the presence of the complete P3 domain than with parts of it. These data support the notion that efficient liberation of structural proteins from P1-2A is necessary but not sufficient for productive HAV capsid formation and suggest that the polypeptides flanking 3C^pro promote the assembly of viral particles.     

Analysis of the interaction between host factor Sam68 and viral elements during foot-and-mouth disease virus infections

Background

The nuclear protein Src-associated protein of 68 kDa in mitosis (Sam68) is known to bind RNA and be involved in cellular processes triggered in response to environmental stresses, including virus infection. Interestingly, Sam68 is a multi-functional protein implicated in the life cycle of retroviruses and picornaviruses and is also considered a marker of virus-induced stress granules (SGs). Recently, we demonstrated the partial redistribution of Sam68 to the cytoplasm in FMDV infected cells, its interaction with viral protease 3C^pro, and found a significant reduction in viral titers as consequence of Sam68-specific siRNA knockdowns. Despite of that, details of how it benefits FMDV remains to be elucidated.

Methods

Sam68 cytoplasmic localization was examined by immunofluorescent microscopy, counterstaining with antibodies against Sam68, a viral capsid protein and markers of SGs. The relevance of RAAA motifs in the IRES was investigated using electromobility shift assays with Sam68 protein and parental and mutant FMDV RNAs. In addition, full genome WT and mutant or G-luc replicon RNAs were tested following transfection in mammalian cells. The impact of Sam68 depletion to virus protein and RNA synthesis was investigated in a cell-free system. Lastly, through co-immunoprecipitation, structural modeling, and subcellular fractionation, viral protein interactions with Sam68 were explored.

Results

FMDV-induced cytoplasmic redistribution of Sam68 resulted in it temporarily co-localizing with SG marker: TIA-1. Mutations that disrupted FMDV IRES RAAA motifs, with putative affinity to Sam68 in domain 3 and 4 cause a reduction on the formation of ribonucleoprotein complexes with this protein and resulted in non-viable progeny viruses and replication-impaired replicons. Furthermore, depletion of Sam68 in cell-free extracts greatly diminished FMDV RNA replication, which was restored by addition of recombinant Sam68. The results here demonstrated that Sam68 specifically co-precipitates with both FMDV 3D^pol and 3C^pro consistent with early observations of FMDV 3C^pro-induced cleavage of Sam68.

Conclusion

We have found that Sam68 is a specific binding partner for FMDV non-structural proteins 3C^pro and 3D^pol and showed that mutations at RAAA motifs in IRES domains 3 and 4 cause a decrease in Sam68 affinity to these RNA elements and rendered the mutant RNA non-viable. Interestingly, in FMDV infected cells re-localized Sam68 was transiently detected along with SG markers in the cytoplasm. These results support the importance of Sam68 as a host factor co-opted by FMDV during infection and demonstrate that Sam68 interact with both, FMDV RNA motifs in the IRES and viral non-structural proteins 3C^pro and 3D^pol.

     

Allosteric Regulation of 3CL Protease of SARS-CoV-2 and SARS-CoV Observed in the Crystal Structure Ensemble

The 3C-like protease (3CL^pro) of SARS-CoV-2 is a potential therapeutic target for COVID-19. Importantly, it has an abundance of structural information solved as a complex with various drug candidate compounds. Collecting these crystal structures (83 Protein Data Bank (PDB) entries) together with those of the highly homologous 3CL^pro of SARS-CoV (101 PDB entries), we constructed the crystal structure ensemble of 3CL^pro to analyze the dynamic regulation of its catalytic function. The structural dynamics of the 3CL^pro dimer observed in the ensemble were characterized by the motions of four separate loops (the C-loop, E-loop, H-loop, and Linker) and the C-terminal domain III on the rigid core of the chymotrypsin fold. Among the four moving loops, the C-loop (also known as the oxyanion binding loop) causes the order (active)–disorder (collapsed) transition, which is regulated cooperatively by five hydrogen bonds made with the surrounding residues. The C-loop, E-loop, and Linker constitute the major ligand binding sites, which consist of a limited variety of binding residues including the substrate binding subsites. Ligand binding causes a ligand size dependent conformational change to the E-loop and Linker, which further stabilize the C-loop via the hydrogen bond between the C-loop and E-loop. The T285A mutation from SARS-CoV 3CL^pro to SARS-CoV-2 3CL^pro significantly closes the interface of the domain III dimer and allosterically stabilizes the active conformation of the C-loop via hydrogen bonds with Ser1 and Gly2; thus, SARS-CoV-2 3CL^pro seems to have increased activity relative to that of SARS-CoV 3CL^pro.     

EV71 3C protease cleaves host anti-viral factor OAS3 and enhances virus replication

The global spread of enteroviruses (EVs) has become more frequent, severe and life-threatening. Intereron (IFN) I has been proved to control EVs by regulating IFN-stimulated genes (ISG) expression. 20-50-oligoadenylate synthetases 3 (OAS3) is an important ISG in the OAS/RNase L antiviral system. The relationship between OAS3 and EVs is still unclear. Here, we reveal that OAS3, superior to OAS1 and OAS2, significantly inhibited EV71 replication in vitro. However, EV71 utilized autologous 3C protease (3C^pro) to cleave intracellular OAS3 and enhance viral replication. Rupintrivir, a human rhinovirus 3C protease inhibitor, completely abolished the cleavage of EV71 3C^pro on OAS3. And the proteolytically deficient mutants H40G, E71A, and C147G of EV71 3C^pro also lost the ability of OAS3 cleavage. Mechanistically, the Q982-G983 motif in C-terminal of OAS3 was identified as a crucial 3C^pro cutting site. Further investigation indicated that OAS3 inhibited not only EV71 but also Coxsackievirus B3 (CVB3), Coxsackievirus A16 (CA16), Enterovirus D68 (EVD68), and Coxsackievirus A6 (CA6) subtypes. Notably, unlike other four subtypes, CA16 3C^pro could not cleave OAS3. Two key amino acids variation Ile36 and Val86 in CA16 3C^pro might result in weak and delayed virus replication of CA16 because of failure of OAS and 3AB cleavage. Our works elucidate the broad anti-EVs function of OAS3, and illuminate a novel mechanism by which EV71 use 3C^pro to escape the antiviral effect of OAS3. These findings can be an important entry point for developing novel therapeutic strategies for multiple EVs infection.     

Seneca Valley Virus 3Cpro Substrate Optimization Yields Efficient Substrates for Use in Peptide-Prodrug Therapy

The oncolytic picornavirus Seneca Valley Virus (SVV-001) demonstrates anti-tumor activity in models of small cell lung cancer (SCLC), but may ultimately need to be combined with cytotoxic therapies to improve responses observed in patients. Combining SVV-001 virotherapy with a peptide prodrug activated by the viral protease 3C^pro is a novel strategy that may increase the therapeutic potential of SVV-001. Using recombinant SVV-001 3C^pro, we measured cleavage kinetics of predicted SVV-001 3C^pro substrates. An efficient substrate, L/VP4 (k_cat/K_M = 1932 ± 183 M^-1s^-1), was further optimized by a P2’ N→P substitution yielding L/VP4.1 (k_cat/K_M = 17446 ± 2203 M^-1s^-1). We also determined essential substrate amino acids by sequential N-terminal deletion and substitution of amino acids found in other picornavirus genera. A peptide corresponding to the L/VP4.1 substrate was selectively cleaved by SVV-001 3C^pro in vitro and was stable in human plasma. These data define an optimized peptide substrate for SVV-001 3C^pro, with direct implications for anti-cancer therapeutic development.