Specific Cleavage of the Nuclear Pore Complex Protein Nup62 by a Viral Protease

Previous work has shown that several nucleoporins, including Nup62 are degraded in cells infected with human rhinovirus (HRV) and poliovirus (PV) and that this contributes to the disruption of certain nuclear transport pathways. In this study, the mechanisms underlying proteolysis of Nup62 have been investigated. Analysis of Nup62 in lysates from HRV-infected cells revealed that Nup62 was cleaved at multiple sites during viral infection. The addition of purified HRV2 2A protease (2A^pro) to uninfected HeLa whole cell lysates resulted in the cleavage of Nup62, suggesting that 2A^pro is a major contributor to Nup62 processing. The ability of purified 2A^pro to cleave bacterially expressed and purified Nup62 demonstrated that 2A^pro directly cleaves Nup62 in vitro. Site-directed mutagenesis of putative cleavage sites in Nup62 identified six different positions that are cleaved by 2A^pro in vitro. This analysis revealed that 2A^pro cleavage sites were located between amino acids 103 and 298 in Nup62 and suggested that the N-terminal FG-rich region of Nup62 was released from the nuclear pore complex in infected cells. Analysis of HRV- and PV-infected cells using domain-specific antibodies confirmed that this was indeed the case. These results are consistent with a model whereby PV and HRV disrupt nucleo-cytoplasmic trafficking by selectively removing FG repeat domains from a subset of nuclear pore complex proteins.     

Translation Directed by Hepatitis A Virus IRES in the Absence of Active eIF4F Complex and eIF2

Translation directed by several picornavirus IRES elements can usually take place after cleavage of eIF4G by picornavirus proteases 2A^pro or L^pro. The hepatitis A virus (HAV) IRES is thought to be an exception to this rule because it requires intact eIF4F complex for translation. In line with previous results we report that poliovirus (PV) 2A^pro strongly blocks protein synthesis directed by HAV IRES. However, in contrast to previous findings we now demonstrate that eIF4G cleavage by foot-and-mouth disease virus (FMDV) L^pro strongly stimulates HAV IRES-driven translation. Thus, this is the first observation that 2A^pro and L^pro exhibit opposite effects to what was previously thought to be the case in HAV IRES. This effect has been observed both in hamster BHK and human hepatoma Huh7 cells. In addition, this stimulation of translation is also observed in cell free systems after addition of purified L^pro. Notably, in presence of this FMDV protease, translation directed by HAV IRES takes place when eIF2α has been inactivated by phosphorylation. Our present findings clearly demonstrate that protein synthesis directed by HAV IRES can occur when eIF4G has been cleaved and after inactivation of eIF2. Therefore, translation directed by HAV IRES without intact eIF4G and active eIF2 is similar to that observed with other picornavirus IRESs.     

Lactobacillus acidophilus S-layer protein-mediated inhibition of Salmonella-induced apoptosis in Caco-2 cells

Viruses have developed multiple strategies to interfere with the gene expression of host cells at different stages to ensure their own survival. Here we report a new role for poliovirus 2A^pro modulating the alternative splicing of pre-mRNAs. Expression of 2A^pro potently inhibits splicing of reporter genes in HeLa cells. Low amounts of 2A^pro abrogate Fas exon 6 skipping, whereas higher levels of protease fully abolish Fas and FGFR2 splicing. In vitro splicing of MINX mRNA using nuclear extracts is also strongly inhibited by 2A^pro, leading to accumulation of the first exon and the lariat product containing the unspliced second exon. These findings reveal that the mechanism of action of 2A^pro on splicing is to selectively block the second catalytic step.     

A Protein Linkage Map of the P2 Nonstructural Proteins of Poliovirus

The yeast two-hybrid system was used to catalog all detectable interactions among the P2 nonstructural cleavage products of poliovirus type 1 (Mahoney). Evidence has been obtained for specific associations among 2A^pro, 2BC, 2C, and 2B. Specifically, 2A^pro can interact with itself and 2BC and its cleavage products (2B and 2C) interact in all possible combinations, with the exception of 2C/2C. Detected interactions were confirmed in vitro by a glutathione S-transferase pulldown assay, which allowed us to detect 2C/2C association. trans-dominant-negative mutants of 2B (K. Johnson and P. J. Sarnow, J. Virol. 65:4341–4349, 1991) were examined and were found to retain interaction with wild-type 2B, perhaps reflecting a need for 2B multimerization in viral RNA replication. The multimerization of 2B was examined further by screening a mutagenized library for 2B variants that have lost the ability to bind wild-type 2B. The screen identified two nonconservative missense mutations within a central hydrophobic region, as well as truncations and frameshifts that implicate the C terminus in homointeraction. Introduction of the missense mutations into the genome of the virus conferred a quasi-infectious phenotype, an observation strongly suggesting that the 2B/2B interaction is required for replication of the viral genome.     

Translation Driven by Picornavirus IRES Is Hampered from Sindbis Virus Replicons: Rescue by Poliovirus 2A Protease

Alphavirus replicons are very useful for analyzing different aspects of viral molecular biology. They are also useful tools in the development of new vaccines and highly efficient expression of heterologous genes. We have investigated the translatability of Sindbis virus (SV) subgenomic mRNA bearing different 5′-untranslated regions, including several viral internal ribosome entry sites (IRESs) from picornaviruses, hepatitis C virus, and cricket paralysis virus. Our findings indicate that all these IRES-containing mRNAs are initially translated in culture cells transfected with the corresponding SV replicon but their translation is inhibited in the late phase of SV replication. Notably, co-expression of different poliovirus (PV) non-structural genes reveals that the protease 2A (2A^pro) is able to increase translation of subgenomic mRNAs containing the PV or encephalomyocarditis virus IRESs but not of those of hepatitis C virus or cricket paralysis virus. A PV 2A^pro variant deficient in eukaryotic initiation factor (eIF) 4GI cleavage or PV protease 3C, neither of which cleaves eIF4GI, does not increase picornavirus IRES-driven translation, whereas L protease from foot-and-mouth disease virus also rescues translation. These findings suggest that the replicative foci of SV-infected cells where translation takes place are deficient in components necessary to translate IRES-containing mRNAs. In the case of picornavirus IRESs, cleavage of eIF4GI accomplished by PV 2A^pro or foot-and-mouth disease virus protease L rescues this inhibition. eIF4GI co-localizes with ribosomes both in cells electroporated with SV replicons bearing the picornavirus IRES and in cells co-electroporated with replicons that express PV 2A^pro. These findings support the idea that eIF4GI cleavage is necessary to rescue the translation driven by picornavirus IRESs in baby hamster kidney cells that express SV replicons.     

Homology modeling, docking, molecular dynamics simulation, and structural analyses of coxsakievirus B3 2A protease: an enzyme involved in the pathogenesis of inflammatory myocarditis

2A protease of the pathogenic coxsackievirus B3 is key to the pathogenesis of inflammatory myocarditis and, therefore, an attractive drug target. However lack of a crystal structure impedes design of inhibitors. Here we predict 3D structure of CVB3 2A^pro based on sequence comparison and homology modeling with human rhinovirus 2A^pro. The two enzymes are remarkably similar in their core regions. However they have different conformations at the N-terminal. A large number of N-terminal hydrophobic residues reduce the thermal stability of CVB3 2A^pro, as we confirmed by fluorescence, western blot and turbidity measurement. Molecular dynamic simulation revealed that elevated temperature induces protein motion that results in frequent movement of the N-terminal coil. This may therefore induce successive active site changes and thus play an important role in destabilization of CVB3 2A^pro structure.     

Conformational Plasticity of the 2A Proteinase from Enterovirus 71

The 2A proteinase (2A^pro) is an enterovirally encoded cysteine protease that plays essential roles in both the processing of viral precursor polyprotein and the hijacking of host cell translation and other processes in the virus life cycle. Crystallographic studies of 2A^pro from enterovirus 71 (EV71) and its interaction with the substrate are reported here. EV71 2A^pro was comprised of an N-terminal domain of a four-stranded antiparallel β sheet and a C-terminal domain of a six-stranded antiparallel β barrel with a tightly bound zinc atom. Unlike in other 2A^pro structures, there is an open cleft across the surface of the protein in an open conformation. As demonstrated by the crystallographic studies and modeling of the complex structure, the open cleft could be fitted with the substrate. On comparison 2A^pro of EV71 to those of the human rhinovirus 2 and coxsackievirus B4, the open conformation could be closed with a hinge motion in the bII2 and cII β strands. This was supported by molecular dynamic simulation. The structural variation among different 2A^pro structures indicates a conformational flexibility in the substrate-binding cleft. The open structure provides an accessible framework for the design and development of therapeutics against the viral target.     

Differential processing of nuclear pore complex proteins by rhinovirus 2A proteases from different species and serotypes

Human rhinoviruses (HRVs) from the HRV-A, HRV-B, and HRV-C species use encoded proteases, 2A^pro and 3C^pro, to process their polyproteins and shut off host cell activities detrimental to virus replication. Reactions attributed to 2A^pro include cleavage of eIF4G-I and -II to inhibit cellular mRNA translation and cleavage of select nucleoporin proteins (Nups) within nuclear pore complexes (NPCs) to disrupt karyopherin-dependent nuclear-cytoplasmic transport and signaling. Sequence diversity among 2A^pro proteases from different HRV clades, even within species, suggested individual viruses might carry out these processes with unique mechanistic signatures. Six different recombinant 2A^pro proteases (A16, A89, B04, B14, Cw12, and Cw24) were compared for their relative substrate preferences and cleavage kinetics using eIF4G from cellular extracts and Nups presented in native (NPC) or recombinant formats. The enzyme panel attacked these substrates with different rates or processing profiles, mimicking the preferences observed during natural infection (A16 and B14). For eIF4G, all 2A^pro proteases cleaved at similar sites, but the comparative rates were species specific (HRV-A > HRV-C ≫ HRV-B). For Nup substrates, 5 of the 6 enzymes had unique product profiles (order of Nup selection) or reacted at different sites within Nup62, Nup98, and Nup153. Only A16 and A89 behaved similarly in most assays. Since each type of karyopherin receptor prefers particular Nups or uses a limited cohort of binding motifs within those Nups, the consequences of individual 2A^pro avidities could profoundly affect relative viral replication levels, intracellular signaling, or extracellular signaling, all of which are underlying triggers for different host immune responses.     

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.     

新型冠状病毒3C样蛋白酶结构和功能特征分析

采用生物信息学方法分析新型冠状病毒(Severe acute respiratory syndrome coronavirus 2, SARS-CoV-2)3C样蛋白酶(3-chymotrypsin-like protease, 3CL^pro)的理化性质、结构与功能,为抗SARS-CoV-2药物研发提供参考。通过ProtParam、ProtScale、Bioedit服务器对3CL^pro进行一级结构如氨基酸理化性质、疏水性的预测分析;COILS Server、SignalP、TMPred、TargetP Server、NetPhos Server、NetNGlyc Server服务器对3CL^pro结构进行如卷曲螺旋区、信号肽、跨膜结构域、亚细胞定位、磷酸化位点、糖基化位点的预测分析;SOPMA、SWISS MODEL服务器对3CL^pro进行二级结构、三级结构的预测分析;IEBD对3CL^pro进行B细胞表位的预测分析。3CL^pro由306个氨基酸组成,其中亮氨酸占比最高,分子质量为33 796.64,理论等电点值为5.95,半衰期为1.9 h,脂肪系数为82.12;亲水性较高,不具有卷曲螺旋区与信号肽特点,含一个跨膜区;具有4个磷酸化位点,2个糖基化修饰点;二级结构中无规则卷曲占据主导地位,三级结构能与已知的6y2g.1（SMTL ID）模型同源建模;存在4个潜在的B细胞表位,位于92~101位的氨基酸区域应答频率最高。利用生物信息学技术分析3CL^pro的结构和功能特征,可为新型冠状肺炎药物的研发提供参考。     

Intracellular Redistribution of Truncated La Protein Produced by Poliovirus 3Cpro-Mediated Cleavage

The La autoantigen (also known as SS-B), a cellular RNA binding protein, may shuttle between the nucleus and cytoplasm, but it is mainly located in the nucleus. La protein is redistributed to the cytoplasm after poliovirus infection. An in vitro translation study demonstrated that La protein stimulated the internal initiation of poliovirus translation. In the present study, a part of the La protein was shown to be cleaved in poliovirus-infected HeLa cells, and this cleavage appeared to be mediated by poliovirus-specific protease 3C (3C^pro). Truncated La protein (dl-La) was produced in vitro from recombinant La protein by cleavage with purified 3C^pro at only one Gln₃₅₈-Gly₃₅₉ peptide bond in the 408-amino-acid (aa) sequence of La protein. The dl-La expressed in L cells was detected in the cytoplasm. However, green fluorescence protein linked to the C-terminal 50-aa sequence of La protein was localized in the nucleus, suggesting that this C-terminal region contributes to the steady-state nuclear localization of the intact La protein in uninfected cells. The dl-La retained the enhancing activity of translation initiation driven by poliovirus RNA in rabbit reticulocyte lysates. These results suggest that La protein is cleaved by 3C^pro in the course of poliovirus infection and that the dl-La is redistributed to the cytoplasm. dl-La, as well as La protein, may play a role in stimulating the internal initiation of poliovirus translation in the cytoplasm.     

Poliovirus/Hepatitis C Virus (Internal Ribosomal Entry Site-Core) Chimeric Viruses: Improved Growth Properties through Modification of a Proteolytic Cleavage Site and Requirement for Core RNA Sequences but Not for Core-Related Polypeptides

H.-H. Lu and E. Wimmer (Proc. Natl. Acad. Sci. USA 93:1412–1417, 1996) have demonstrated that the internal ribosomal entry site (IRES) of poliovirus (PV) can be functionally replaced by the related genetic element from hepatitis C virus (HCV). One important finding of this study was that open reading frame sequences 3′ of the initiating AUG, corresponding to the open reading frame of the HCV core polypeptide, are required to create a viable chimeric virus. This made necessary the inclusion of a PV 3C protease (3C^pro) cleavage site for proper polyprotein processing to create the authentic N terminus of the PV capsid precursor. Chimeric PV/HCV (P/H) viruses, however, grew poorly relative to PV. The goal of this study was to determine the molecular basis of impaired replication and enhance the growth properties of this chimeric virus. Genetic modifications leading to a different proteinase (PV 2A^pro) cleavage site between the HCV core sequence and the PV polyprotein (P/H701-2A) proved far superior with respect to viral protein expression, core-PV fusion polyprotein processing, plaque phenotype, and viral titer than the original prototype PV/HCV chimera containing the PV 3C^pro-specific cleavage site (P/H701). We have used this new virus model to answer two questions concerning the role of the HCV core protein in P/H chimeric viral proliferation. First, a derivative of P/H701-2A with frameshifts in the core-encoding sequence was used to demonstrate that production of the core protein was not necessary for the translation and replication of the P/H chimera. Second, a viral construct with a C-terminal truncation of 23 amino acids of the core gene was used to show that a signal sequence for signal peptidase processing, when present in the viral construct, is detrimental to P/H virus growth. The novel P/H chimera described here are suitable models for analyzing the function(s) of the HCV elements by genetic analyses in vivo and for antiviral drug discovery.     

Visualizing and quantifying the differential cleavages of the eukaryotic translation initiation factors eIF4GI and eIF4GII in the enterovirus‐infected cell

Enterovirus (EV) infection has been shown to cause a marked shutoff of host protein synthesis, an event mainly achieved through the cleavages of eukaryotic translation initiation factors eIF4GI and eIF4GII that are mediated by viral 2A protease (2A^pro). Using fluorescence resonance energy transfer (FRET), we developed genetically encoded and FRET‐based biosensors to visualize and quantify the specific proteolytic process in intact cells. This was accomplished by stable expression of a fusion substrate construct composed of the green fluorescent protein 2 (GFP²) and red fluorescent protein 2 (DsRed2), with a cleavage motif on eIF4GI or eIF4GII connected in between. The FRET biosensor showed a real‐time and quantifiable impairment of FRET upon EV infection. Levels of the reduced FRET closely correlated with the cleavage kinetics of the endogenous eIF4Gs isoforms. The FRET impairments were solely attributed to 2A^pro catalytic activity, irrespective of other viral‐encoded protease, the activated caspases or general inhibition of protein synthesis in the EV‐infected cells. The FRET biosensors appeared to be a universal platform for several related EVs. The spatiotemporal and quantitative imaging enabled by FRET can shed light on the protease–substrate behaviors in their normal milieu, permitting investigation into the molecular mechanism underlying virus‐induced host translation inhibition. Biotechnol. Bioeng. 2009; 104: 1142–1152. © 2009 Wiley Periodicals, Inc.     

Evaluation of a non-prime site substituent and warheads combined with a decahydroisoquinolin scaffold as a SARS 3CL protease inhibitor

A non-prime site substituent and warheads combined with a decahydroisoquinolin scaffold was evaluated as a novel inhibitor for severe acute respiratory syndrome (SARS) chymotrypsin-like protease (3CL^pro). The decahydroisoquinolin scaffold has been demonstrated to be an effective hydrophobic center to interact with S2 site of SARS 3CL^pro, but the lack of interactions at S3 to S4 site is thought to be a major reason for the moderate inhibitory activity. In this study, the effects of an additional non-prime site substituent on the scaffold as well as effects of several warheads are evaluated. For the introduction of a desired non-prime site substituent, amino functionality was introduced on the decahydroisoquinolin scaffold, and the scaffold was constructed by Pd(II) catalyzed diastereoselective ring formation. The synthesized decahydroisoquinolin inhibitors showed about 2.4 times potent inhibitory activities for SARS 3CL^pro when combined with a non-prime site substituent. The present results indicated not only the expected additional interactions with the SARS 3CL^pro but also the possibility of new inhibitors containing a fused-ring system as a hydrophobic scaffold and a new warhead such as thioacetal.     

NMR analysis of the interaction of picornaviral proteinases Lb and 2A with their substrate eukaryotic initiation factor 4GII

Messenger RNA is recruited to the eukaryotic ribosome by a complex including the eukaryotic initiation factor (eIF) 4E (the cap‐binding protein), the scaffold protein eIF4G and the RNA helicase eIF4A. To shut‐off host–cell protein synthesis, eIF4G is cleaved during picornaviral infection by a virally encoded proteinase; the structural basis of this reaction and its stimulation by eIF4E is unclear. We have structurally and biochemically investigated the interaction of purified foot‐and‐mouth disease virus (FMDV) leader proteinase (Lb^pro), human rhinovirus 2 (HRV2) 2A proteinase (2A^pro) and coxsackievirus B4 (CVB4) 2A^pro with purified eIF4GII, eIF4E and the eIF4GII/eIF4E complex. Using nuclear magnetic resonance (NMR), we completed ¹³C/¹⁵N sequential backbone assignment of human eIF4GII residues 551–745 and examined their binding to murine eIF4E. eIF4GII_551–745 is intrinsically unstructured and remains so when bound to eIF4E. NMR and biophysical techniques for determining stoichiometry and binding constants revealed that the papain‐like Lb^pro only forms a stable complex with eIF4GII_551–745 in the presence of eIF4E, with K_D values in the low nanomolar range; Lb^pro contacts both eIF4GII and eIF4E. Furthermore, the unrelated chymotrypsin‐like 2A^pro from HRV2 and CVB4 also build a stable complex with eIF4GII/eIF4E, but with K_D values in the low micromolar range. The HRV2 enzyme also forms a stable complex with eIF4E; however, none of the proteinases tested complex stably with eIF4GII alone. Thus, these three picornaviral proteinases have independently evolved to establish distinct triangular heterotrimeric protein complexes that may actively target ribosomes involved in mRNA recruitment to ensure efficient host cell shut‐off.     

Inhibition of growth of proline-requiring Chinese hamster ovary cells (CHO-K1) resulting from antagonism by a system amino acids

CHO-K1 requires proline for growth. Two proline-independent revertants were isolated—K1-J and K1-6. CHO-K1 pro^? is much more sensitive than the pro⁺ cell lines to inhibition of growth by addition to the medium of amino acids and amino acid analogues that are transported through the A system. In contrast, pro⁺ cells are as sensitive as, or in some cases slightly more sensitive than, pro^? cells to glycine, basic amino acids, and to amino acids that are mainly transported by the L system. The A system analogue α(methylamino) isobutyric acid (MAIB) in low concentrations reacts competitively with proline to regulate the growth of pro^? cells, yielding a K_i for MAIB of 0.56 mM. CHO-K1 and K1-6 transport proline at the same initial rate and are equally sensitive to the inhibition of proline transport by alanine. Alanine and MAIB inhibit proline transport strongly and similarly in CHO-K1. Thus although these compounds inhibit the transport of proline by both cell types to the same extent, pro⁺ cells are immune to the effect of this starvation since they are able to synthesize their own proline. We also describe a secondary inhibition caused by high A system amino acid concentrations that affects both pro^? and pro⁺ cells.