The emerging SARS-CoV-2 papain-like protease: Its relationship with recent coronavirus epidemics.

The papain-like protease (PLpro ) is an important enzyme for coronavirus polyprotein processing, as well as for virus-host immune suppression. Previous studies reveal that a molecular analysis of PLpro indicates the catalytic activity of viral PLpro and its interactions with ubiquitin. By using sequence comparisons, molecular models, and protein-protein interaction maps, PLpro was compared in the three recorded fatal CoV epidemics, which involved severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2), severe acute respiratory syndrome CoV (SARS-CoV), and Middle East respiratory syndrome coronavirus (MERS-CoV). The pairwise sequence comparison of SARS-CoV-2 PLpro indicated similarity percentages of 82.59% and 30.06% with SARS-CoV PLpro and MERS-CoV PLpro , respectively. In comparison with SARS-CoV PLpro , in SARS-CoV-2, the PLpro had a conserved catalytic triad of C111, H278, and D293, with a slightly lower number of polar interface residues and of hydrogen bonds, a higher number of buried interface sizes, and a lower number of residues that interact with ubiquitin and PLpro . These features might contribute to a similar or slightly lower level of deubiquitinating activity in SARS-CoV-2 PLpro. It was, however, a much higher level compared to MERS-CoV, which contained amino acid mutations and a low number of polar interfaces. SARS-CoV-2 PLpro and SARS-CoV PLpro showed almost the same catalytic site profiles, interface area compositions and polarities, suggesting a general similarity in deubiquitination activity. Compared with MERS-CoV, SARS-CoV-2 had a higher potential for binding interactions with ubiquitin. These estimated parameters contribute to the knowledge gap in understanding how the new virus interacts with the immune system.

In vitro translation of virally-encoded replication polyproteins to recapitulate polyprotein maturation processes.

Single-stranded, positive-sense RNA viruses encode essential replication polyproteins which are composed of several domains. They are usually subjected to finely regulated proteolytic maturation processes to generate cleavage intermediates and end-products. Both polyproteins and maturation products play multiple key roles that ultimately allow synthesis of viral genome progeny. Despite the importance of these proteins in the course of viral replication, their structural properties, including the conformational changes regulating their numerous functions, are poorly described at the structural level. This lack of information is mainly due to the extreme difficulty to express large, membrane-bound, multi-domain proteins with criteria suitable for structural biology methods. To tackle this challenge, we have used a wheat-germ cell-free expression system. We firstly establish that this approach allows to synthesize viral polyproteins encoded by two unrelated positive-sense RNA viruses, a human norovirus and a plant tymovirus. Then, we demonstrate that these polyproteins are fully functional and are spontaneously auto-cleaved by their active protease domain, giving rise to natural maturation products. Moreover, we show that introduction of point mutations in polyproteins allows to inhibit the proteolytic maturation process of each virus. This allowed us to express and partially purify the uncleaved full-length norovirus polyprotein and the tymoviral RNA-dependent RNA polymerase. Thus, this study provides a powerful tool to obtain soluble viral polyproteins and their maturation products in order to conduct challenging structural biology projects and therefore solve unanswered questions.

Cotranslational folding stimulates programmed ribosomal frameshifting in the alphavirus structural polyprotein.

Viruses maximize their genetic coding capacity through a variety of biochemical mechanisms, including programmed ribosomal frameshifting (PRF), which facilitates the production of multiple proteins from a single mRNA transcript. PRF is typically stimulated by structural elements within the mRNA that generate mechanical tension between the transcript and ribosome. However, in this work, we show that the forces generated by the cotranslational folding of the nascent polypeptide chain can also enhance PRF. Using an array of biochemical, cellular, and computational techniques, we first demonstrate that the Sindbis virus structural polyprotein forms two competing topological isomers during its biosynthesis at the ribosome-translocon complex. We then show that the formation of one of these topological isomers is linked to PRF. Coarse-grained molecular dynamics simulations reveal that the translocon-mediated membrane integration of a transmembrane domain upstream from the ribosomal slip site generates a force on the nascent polypeptide chain that scales with observed frameshifting. Together, our results indicate that cotranslational folding of this viral protein generates a tension that stimulates PRF. To our knowledge, this constitutes the first example in which the conformational state of the nascent polypeptide chain has been linked to PRF. These findings raise the possibility that, in addition to RNA-mediated translational recoding, a variety of cotranslational folding or binding events may also stimulate PRF.

The ER membrane protein complex is required to ensure correct topology and stable expression of flavivirus polyproteins.

Flaviviruses translate their genomes as multi-pass transmembrane proteins at the endoplasmic reticulum (ER) membrane. Here, we show that the ER membrane protein complex (EMC) is indispensable for the expression of viral polyproteins. We demonstrated that EMC was essential for accurate folding and post-translational stability rather than translation efficiency. Specifically, we revealed degradation of NS4A-NS4B, a region rich in transmembrane domains, in absence of EMC. Orthogonally, by serial passaging of virus on EMC-deficient cells, we identified two non-synonymous point mutations in NS4A and NS4B, which rescued viral replication. Finally, we showed a physical interaction between EMC and viral NS4B and that the NS4A-4B region adopts an aberrant topology in the absence of the EMC leading to degradation. Together, our data highlight how flaviviruses hijack the EMC for transmembrane protein biogenesis to achieve optimal expression of their polyproteins, which reinforces a role for the EMC in stabilizing challenging transmembrane proteins during synthesis.

Polyprotein strategy for stoichiometric assembly of nitrogen fixation components for synthetic biology.

Re-engineering of complex biological systems (CBS) is an important goal for applications in synthetic biology. Efforts have been made to simplify CBS by refactoring a large number of genes with rearranged polycistrons and synthetic regulatory circuits. Here, a posttranslational protein-splicing strategy derived from RNA viruses was exploited to minimize gene numbers of the classic nitrogenase system, where the expression stoichiometry is particularly important. Operon-based nif genes from Klebsiella oxytoca were regrouped into giant genes either by fusing genes together or by expressing polyproteins that are subsequently cleaved with Tobacco Etch Virus protease. After several rounds of selection based on protein expression levels and tolerance toward a remnant C-terminal ENLYFQ-tail, a system with only five giant genes showed optimal nitrogenase activity and supported diazotrophic growth of Escherichia coli This study provides an approach for efficient translation from an operon-based system into a polyprotein-based assembly that has the potential for portable and stoichiometric expression of the complex nitrogenase system in eukaryotic organisms.

Expression of Cholesterol Hydroxylase/Lyase System Proteins in Yeast S. cerevisiae Cells as a Self-Processing Polyprotein.

2A peptide discovered in Picornaviridae is capable of self-cleavage providing an opportunity to carry out synthesis of several proteins using one transcript. Dissociation in the 2A sequence during translation leads to the individual proteins formation. We constructed cDNA including genes of the bovine cholesterol hydroxylase/lyase (CHL) system proteins-cytochrome P450scc (CYP11A1), adrenodoxin (Adx) and adrenodoxin reductase (AdR), that are fused into a single ORF using FMDV 2A nucleotide sequences. The constructed vectors direct the expression of cDNA encoding polyprotein P450scc-2A-Adx-2A-AdR (CHL-2A) in Escherichia coli and Saccharomyces cerevisiae. The induced bacterial cells exhibit a high level of CHL-2A expression, but polyprotein is not cleaved at the FMDV sites. In yeast S. cerevisiae, the discrete proteins P450scc-2A, Adx-2A and AdR are expressed. Moreover, a significant proportion of AdR and Adx is present in a fusion Adx-2A-AdR. Thus, the first 2A linker provides an efficient cleavage of the polyprotein, while the second 2A linker demonstrates lower efficiency. Cholesterol hydroxylase/lyase activity registered in the recombinant yeast cell homogenate indicates that the catalytically active CHL system is present in these cells. Consequently, for the first time the mammalian system of cytochrome P450 has been successfully reconstructed in yeast cells through expressing the self-processing polyprotein.

Expression of four S. pneumoniae type 2 polysaccharide biosynthetic enzymes utilising the endogenous Kex2 protease activity in tobacco.

In order to express multisubunit proteins, or to manipulate metabolic pathways in plants it is essential to be able to efficiently express multiple proteins within the same plant cell. To increase the efficiency of multi-protein expression, we demonstrate the use of the Golgi localized Kex2 protease activity in tobacco to process a large polyprotein precursor consisting of four individual protein domains into its individual protein constituents. Four genes encoding enzymes involved in the biosynthesis of S. pneumoniae type 2 polysaccharide were assembled into a single expression cassette as a large polyprotein driven by a single cauliflower mosaic virus (CaMV) 35S promoter. Each of the individual protein domains were separated by three sequential Kex2 protease digestion sites. At the N-terminus a Pr1b signal peptide was incorporated for efficient targeting of the polyprotein to the apoplast. Each individual protein domain was tagged with its own immuno-tag. The construct was used for the transformation of Nicotiana tabacum and stable lines were selected. All four processed proteins could be immunologically detected in protein extracts using Western blotting indicating correct expression and Kex2 processing. Utilisation of the Kex2 protease system represents an efficient way of expressing multiple proteins in the same plant. This method simplifies the transformation procedures, and presents a method for expression of multiple proteins within the same plant.

Multiprotein complex production in insect cells by using polyproteins.

A powerful approach utilizing polyproteins for balancing stoichiometry of recombinant multiprotein complexes overproduced in baculovirus expression vector systems (BEVS) is described. This procedure has been implemented here in the MultiBac system but can also be directly adapted to all commonly used BEVS. The protocol details the design principles of polyprotein-expressing DNA constructs, the generation of composite baculovirus for polyprotein production, and the expression and in vivo processing of polyproteins in baculovirus infected insect cells.

Autoprocessing mechanism of severe acute respiratory syndrome coronavirus 3C-like protease (SARS-CoV 3CLpro) from its polyproteins.

Like many other RNA viruses, severe acute respiratory syndrome coronavirus (SARS-CoV) produces polyproteins containing several non-structural proteins, which are then processed by the viral proteases. These proteases often exist within the polyproteins, and are excised by their own proteolytic activity ('autoprocessing'). It is important to investigate the autoprocessing mechanism of these proteases from the point of view of anti-SARS-CoV drug design. In this paper, we describe a new method for investigating the autoprocessing mechanism of the main protease (M(pro)), which is also called the 3C-like protease (3CL(pro)). Using our method, we measured the activities, under the same conditions, of the mature form and pro-forms with the N-terminal pro-sequence, the C-terminal pro-sequence or both pro-sequences, toward the pro-form with both N- and C-terminal pro-sequences. The data indicate that the pro-forms of the enzyme have proteolytic activity, and are stimulated by the same proteolytic activity. The stimulation occurs in two steps, with approximately eightfold stimulation by N-terminal cleavage, approximately fourfold stimulation by C-terminal cleavage, and 23-fold stimulation by the cleavage of both termini, compared to the pro-form with both the N- and C-terminal pro-sequences. Such cleavage mainly occurs in a trans manner; i.e. the pro-form dimer cleaves the monomeric form. The stimulation by N-terminal pro-sequence removal is due to the cis (intra-dimer and inter-protomer) effect of formation of the new N-terminus, whereas that by C-terminal cleavage is due to removal of its trans (inter-dimer) inhibitory effect. A numerical simulation of the maturation pathway is presented.

Expression of heterologous proteins flanked by NS3-4A cleavage sites within the hepatitis C virus polyprotein.

Hepatitis C virus (HCV) contributes substantially to human morbidity and mortality world-wide. The development of HCV genomes expressing heterologous proteins has enhanced the ability to study viral infection, but existing systems have drawbacks. Recombinant viruses often require adaptive mutations to compensate for reduced viral titers, or rely on an artificial genomic organization that uncouples viral protein expression from recombinant gene expression. Here, we sought to exploit the viral polyprotein processing machinery to express heterologous proteins within the context of the HCV polyprotein. We show that HCV genotypes 2a and 1b permit insertion of reporter proteins between NS5A and NS5B with minimal impact on viral fitness. Using this strategy we constructed reporter genomes exhibiting a wide dynamic range, simplifying analysis of HCV infection in primary hepatocytes. Expression of heterologous proteins within the HCV genome offers new opportunities to analyze HCV infection in experimental systems without perturbing functions of individual viral proteins.

Theiler's murine encephalomyelitis virus contrasts with encephalomyocarditis and foot-and-mouth disease viruses in its functional utilization of the StopGo non-standard translation mechanism.

The picornaviruses' genome consists of a positive-sense ssRNA. Like many picornaviruses, cardioviruses synthesize two distinct polyprotein precursors from adjacent but non-overlapping genome segments. Both the [L-1ABCD-2A] and the [2BC-3ABCD] polyproteins are proteolytically processed to yield mature capsid and non-structural proteins, respectively. An unusual translational event, known as 'StopGo' or 'Stop-Carry on', is responsible for the release of the [L-1ABCD-2A] polyprotein from the ribosome and synthesis of the N-terminal amino acid of the [2BC-3ABCD] polyprotein. A common feature of these viruses is the presence of a highly conserved signature sequence for StopGo: -D(V/I)ExNPG(↓)P-, where -D(V/I)ExNPG are the last 7 aa of 2A, and the last P- is the first amino acid of 2B. Here, we report that, in contrast to encephalomyocarditis virus and foot-and-mouth disease virus, a functional StopGo does not appear to be essential for Theiler's murine encephalomyelitis virus viability when tested in vitro and in vivo.

Metabolic engineering of the flavone-C-glycoside pathway using polyprotein technology.

C-Glycosylated flavonoids are biologically active plant natural products linked to dietary health benefits. We have used polyprotein expression technology to reconstruct part of the respective biosynthetic pathway in tobacco and yeast, such that dihydrochalcone and flavanone precursors are directly converted to C-glycosides. The polyprotein system developed facilitated the simple and efficient co-expression of pathway enzymes requiring different sub-cellular localization in both plants and yeast. The pathway to flavone-C-glucosides comprised a flavanone 2-hydroxylase (F2H), co-expressed with a C-glucosyltransferase (CGT). While pathway engineering in tobacco resulted in only minor C-glycoside formation, when fed with the flavanone naringenin, yeast transformed with the F2H-CGT polyprotein construct produced high concentrations of 2-hydroxynaringenin-C-glucoside in the medium. These fermentation products could then be readily chemically converted to the respective flavone-C-glucosides. The efficiency of the biosynthesis was optimal when both the F2H and CGT were obtained from the same species (rice). These results confirm the coupled roles of the F2H and CGT in producing C-glucosides in vivo, with the use of the polyprotein expression system in yeast offering a useful system to optimize the synthesis of these natural products in quantities suitable for dietary studies.

Expression and purification of enterovirus type 71 polyprotein P1 using Pichia pastoris system.

Enterovirus type 71(EV71) causes severe hand-foot-and-mouth disease (HFMD) resulting in hundreds of deaths of children every year; However, currently, there is no effective treatment for EV71. In this study, the EV71 poly-protein (EV71-P1 protein) gene was processed and cloned into the eukaryotic expression vector pPIC9k and then expressed in Pichia pastoris strain GS115. The EV71 P1 protein with a molecular weight of 100 kD was produced and secreted into the medium. The soluble EV71 P1 protein was purified by column chromatography with a recovery efficiency of 70%. The result of the immunological analysis showed that the EV71 P1 protein had excellent immunogenicity and could stimulate the production of EV71-VP1 IgG antibody in injected rabbits. We suggest that EV71-P1 protein is an ideal candidate for an EV71 vaccine to prevent EV71 infection.

Robots, pipelines, polyproteins: enabling multiprotein expression in prokaryotic and eukaryotic cells.

Multiprotein complexes catalyze vital biological functions in the cell. A paramount objective of the SPINE2 project was to address the structural molecular biology of these multiprotein complexes, by enlisting and developing enabling technologies for their study. An emerging key prerequisite for studying complex biological specimens is their recombinant overproduction. Novel reagents and streamlined protocols for rapidly assembling co-expression constructs for this purpose have been designed and validated. The high-throughput pipeline implemented at IGBMC Strasbourg and the ACEMBL platform at the EMBL Grenoble utilize recombinant overexpression systems for heterologous expression of proteins and their complexes. Extension of the ACEMBL platform technology to include eukaryotic hosts such as insect and mammalian cells has been achieved. Efficient production of large multicomponent protein complexes for structural studies using the baculovirus/insect cell system can be hampered by a stoichiometric imbalance of the subunits produced. A polyprotein strategy has been developed to overcome this bottleneck and has been successfully implemented in our MultiBac baculovirus expression system for producing multiprotein complexes.

An active DNA vaccine against infectious pancreatic necrosis virus (IPNV) with a different mode of action than fish rhabdovirus DNA vaccines.

Although there are some commercial vaccines available against infectious pancreatic necrosis virus (IPNV), the disease still continues to be a major problem for aquaculture development worldwide. In the current work, we constructed a DNA vaccine against IPNV (pIPNV-PP) by cloning the long open reading frame of the polyprotein encoded by the viral RNA segment A. In vitro, the vaccine is properly translated giving the functional IPNV polyprotein since preVP2, VP2 and VP3 proteins were detected because of the VP4-protease cleavage. EPC cells transfected with the vaccine plasmid expressed the viral proteins and induced the expression of type I interferon (IFN)-induced Mx genes. Furthermore, IPNV synthesized proteins seemed to assemble in virus-like particles as evidenced by electron microscopy. In vivo, rainbow trout specimens were intramuscularly injected with the vaccine and expression of immune-relevant genes, the presence of neutralizing antibodies and effect on viral load was determined. The pIPNV-PP vaccine was expressed at the injection site and up-regulated MHC Ialpha, MHC IIalpha, type-I interferon (IFN), Mx, CD4 and CD8alpha gene expression in the muscle, head kidney or spleen, although to a much lower extent than the up-regulations observed in response to an effective DNA vaccine against viral hemorrhagic septicaemia virus (VHSV). However, the IPNV vaccine was also very effective in terms of acquired immunity since it elicited neutralizing antibodies (in 6 out of 8 trout fingerlings) and decreased 665-fold the viral load after IPNV infection. The effectiveness of this new IPNV DNA vaccine and its possible mechanism of action are discussed and compared to other viral vaccines.

The region between the two polyprotein initiation codons of foot-and-mouth disease virus is critical for virulence in cattle.

To explore the role in viral pathogenesis of the region located between the two functional AUG (inter-AUG) in foot-and-mouth disease virus (FMDV), we derived viruses containing transposon (tn) inserts from a mutagenized cDNA infectious clone of FMDV (pA24-WT). Mutant viruses containing an in-frame 57-nt transposon insertion grew at a slower rate and had a smaller plaque size phenotype than the parental virus (A24-WT). A mutant virus containing a 51-nt deletion in inter-AUG had a similar phenotype in cell culture to that of A24-WT. When tested by aerosol inoculation in cattle (3 animals per virus), the deletion mutant was fully virulent as was A24-WT. Mutant viruses containing insertions in inter-AUG did not cause clinical disease or viremia. However, viruses that partially or totally removed the tn insertion during animal infection reverted to virulence in 2 inoculated steers. Therefore, this study identified inter-AUG as an FMDV viral virulence determinant in cattle infected by aerosol route.

Sequencing and analyses of all known human rhinovirus genomes reveal structure and evolution.

Infection by human rhinovirus (HRV) is a major cause of upper and lower respiratory tract disease worldwide and displays considerable phenotypic variation. We examined diversity by completing the genome sequences for all known serotypes (n = 99). Superimposition of capsid crystal structure and optimal-energy RNA configurations established alignments and phylogeny. These revealed conserved motifs; clade-specific diversity, including a potential newly identified species (HRV-D); mutations in field isolates; and recombination. In analogy with poliovirus, a hypervariable 5' untranslated region tract may affect virulence. A configuration consistent with nonscanning internal ribosome entry was found in all HRVs and may account for rapid translation. The data density from complete sequences of the reference HRVs provided high resolution for this degree of modeling and serves as a platform for full genome-based epidemiologic studies and antiviral or vaccine development.

PDTC inhibits picornavirus polyprotein processing and RNA replication by transporting zinc ions into cells.

Previously, it was shown that pyrrolidine dithiocarbamate (PDTC) inhibits proteolytic polyprotein processing and replication of human rhinovirus by transporting metal ions into cells. Here, it is shown that PDTC also inhibits replication of two other picornaviruses: coxsackievirus B3 (CVB3), a closely related virus that belongs to the genus Enterovirus, and mengovirus, an encephalomyocarditis virus strain that belongs to the genus Cardiovirus, and that this inhibition is due to the dithiocarbamate moiety of the compound. Making use of subgenomic replicons, evidence is provided that PDTC inhibits replication of these two viruses by disturbing viral RNA synthesis. Furthermore, it is shown that PDTC transports zinc ions into cells and that these zinc ions play an important role in the antiviral activity mediated by PDTC. Finally, it is shown that PDTC interferes with proteolytic processing of the polyproteins of both CVB3 and mengovirus, but that the underlying mechanism between these two viruses differs. In CVB3-infected cells, PDTC interferes strongly with the proteolytic activity of 3CD(pro), as shown by the impaired production of the mature capsid proteins as well as the autocleavage of 3CD(pro) into 3C(pro) and 3D(pol). In mengovirus-infected cells, however, PDTC had no effect on the proteolytic production of capsid proteins or the autocleavage of 3CD(pro). Instead, PDTC caused the accumulation of a high-molecular-mass precursor protein, due to an impairment in the primary 'break' that normally occurs at the 2A-2B junction. Thus, PDTC disturbs polyprotein processing and replication of two groups of picornaviruses, enteroviruses and cardioviruses, but the underlying mechanism is different.

Sequential autoprocessing of Marek's disease herpesvirus protease differs from that of other herpesviruses.

Herpesviruses encode a unique serine protease essential for viral capsid maturation. This protease undergoes autoprocessing at two sites, R and M, at the consensus sequence (V, L, I)(P3)-X(P2)-A(P1)/S(P1') (where X is a polar amino acid). We observed complete autoprocessing at the R and M sites of Marek's disease virus (MDV) protease following production of the polyprotein in Escherichia coli. Site-directed mutagenesis confirmed the predicted sequence of the R and M sites, with the M site sequence being nonconsensual: M(P3)-N(P2)-A(P1)/S(P1'). Mutagenesis and expression kinetics studies suggested that the atypical MDV M site was cleaved exclusively by the processed short protease, a feature making MDV unique among herpesviruses.

Cap- and initiator tRNA-dependent initiation of TYMV polyprotein synthesis by ribosomes: evaluation of the Trojan horse model for TYMV RNA translation.

Turnip yellow mosaic virus (TYMV) RNA directs the translation of two overlapping open reading frames. Competing models have been previously published to explain ribosome access to the downstream polyprotein cistron. The Trojan horse model, based on cell-free experiments, proposes noncanonical cap-independent initiation in which the 3'-terminal tRNA-like structure (TLS) functionally replaces initiator tRNA, and the valine bound to the TLS becomes cis-incorporated into viral protein. The initiation coupling model, based on in vivo expression and ribosome toe-printing studies, proposes a variation of canonical leaky scanning. Here, we have re-examined the wheat germ extract experiments that led to the Trojan horse model, incorporating a variety of controls. We report that (1) translation in vitro from the polyprotein AUG of TYMV RNA is unchanged after removal of the 3' TLS but is stimulated by the presence of a 5'-cap; (2) the presence of free cap analog or edeine (which interferes with initiation at the ribosomal P site and its tRNA(i) (Met) involvement) inhibits translation from the polyprotein AUG; (3) the toe-prints of immediately post-initiation ribosomes on TYMV RNA are similar with and without an intact TLS; and (4) significant deacylation of valyl-TYMV RNA in wheat germ extract can complicate the detection of cis-incorporation. These results favor the initiation coupling model.