Truncation of a P1 leader proteinase facilitates potyvirus replication in a non‐permissive host

The Potyviridae family is a major group of plant viruses that includes c. 200 species, most of which have narrow host ranges. The potyvirid P1 leader proteinase self‐cleaves from the remainder of the viral polyprotein and shows large sequence variability linked to host adaptation. P1 proteins can be classified as Type A or Type B on the basis, amongst other things, of their dependence or not on a host factor to develop their protease activity. In this work, we studied Type A proteases from the Potyviridae family, characterizing their host factor requirements. Our in vitro cleavage analyses of potyvirid P1 proteases showed that the N‐terminal domain is relevant for host factor interaction and suggested that the C‐terminal domain is also involved. In the absence of plant factors, the N‐terminal end of Plum pox virus P1 antagonizes protease self‐processing. We performed extended deletion mutagenesis analysis to define the N‐terminal antagonistic domain of P1. In viral infections, removal of the P1 protease antagonistic domain led to a gain‐of‐function phenotype, strongly increasing local infection in a non‐permissive host. Altogether, our results shed new insights into the adaptation and evolution of potyvirids.     

Three-dimensional domain swapping as a mechanism to lock the active conformation in a super-active octamer of SARS-CoV main protease

Proteolytic processing of viral polyproteins is indispensible for the lifecycle of coronaviruses. The main protease (M^pro) of SARS-CoV is an attractive target for anti-SARS drug development as it is essential for the polyprotein processing. M^pro is initially produced as part of viral polyproteins and it is matured by autocleavage. Here, we report that, with the addition of an N-terminal extension peptide, M^pro can form a domain-swapped dimer. After complete removal of the extension peptide from the dimer, the mature M^pro self-assembles into a novel super-active octamer (AO-M^pro). The crystal structure of AO-M^pro adopts a novel fold with four domain-swapped dimers packing into four active units with nearly identical conformation to that of the previously reported M^pro active dimer, and 3D domain swapping serves as a mechanism to lock the active conformation due to entanglement of polypeptide chains. Compared with the previously well characterized form of M^pro, in equilibrium between inactive monomer and active dimer, the stable AO-M^pro exhibits much higher proteolytic activity at low concentration. As all eight active sites are bound with inhibitors, the polyvalent nature of the interaction between AO-M^pro and its polyprotein substrates with multiple cleavage sites, would make AO-M^pro functionally much more superior than the M^pro active dimer for polyprotein processing. Thus, during the initial period of SARS-CoV infection, this novel active form AO-M^pro should play a major role in cleaving polyproteins as the protein level is extremely low. The discovery of AO-M^pro provides new insights about the functional mechanism of M^pro and its maturation process.     

Association of a distinct strain of Chilli veinal mottle virus with mottling and distortion disease of Datura inoxia in India

Association of a distinct strain of Chilli veinal mottle virus (ChiVMV) with severe mottling and distortion disease of Datura inoxia was investigated based on the presence of flexuous filamentous particles of ~800 × 11 nm and sequence analyses of ~1.5 kb amplicons obtained during RT-PCR from two representative samples, designated as GMT (accession JN692501) and JNP (JN624776). Both GMT and JNP isolates contained partial polyprotein gene comprising of partial nuclear inclusion b gene, complete coat protein gene and 3′ un-translated region, a hallmark gene array of genus Potyvirus. The isolates under study shared 99% nucleotide sequence identities with each other and 83–85% identities (marginal value for species demarcation recommended by ICTV) during basic local alignments and distant phylogenetic relationships with strains of ChiVMV, hence identified as isolates of a distinct strain of ChiVMV. Association of ChiVMV strain with mottling and distortion disease of D. inoxia is being reported for the first time from India.     

The endopeptidase of the maize-affecting Marafivirus type member maize rayado fino virus doubles as a deubiquitinase

Marafiviruses are capable of persistent infection in a range of plants that have importance to the agriculture and biofuel industries. Although the genomes of a few of these viruses have been studied in-depth, the composition and processing of the polyproteins produced from their main ORFs have not. The Marafivirus polyprotein consists of essential proteins that form the viral replicase, as well as structural proteins for virus assembly. It has been proposed that Marafiviruses code for cysteine proteases within their polyproteins, which act as endopeptidases to autocatalytically cleave the polyprotein into functional domains. Furthermore, it has also been suggested that Marafivirus endopeptidases may have deubiquitinating activity, which has been shown to enhance viral replication by downregulating viral protein degradation by the ubiquitin (Ub) proteasomal pathway as well as tampering with cell signaling associated with innate antiviral responses in other positive-sense ssRNA viruses. Here, we provide the first evidence of cysteine proteases from six different Marafiviruses that harbor deubiquitinating activity and reveal intragenus differences toward Ub linkage types. We also examine the structural basis of the endopeptidase/deubiquitinase from the Marafivirus type member, maize rayado fino virus. Structures of the enzyme alone and bound to Ub reveal marked structural rearrangements that occur upon binding of Ub and provide insights into substrate specificity and differences that set it apart from other viral cysteine proteases.     

Recombinant HIV1 protease secreted by Saccharomyces cerevisiae correctly processes myristylated gag polyprotein

The protease of the human immunodeficiency virus type I (HIV1) was expressed both intracellularly and extracellularly in Saccharomyces cerevisiae. Intracellular expression of the protease was achieved by fusing a 179 amino acid precursor form of the protease to human superoxide dismutase (hSOD). Self-processing of the viral enzyme from the hybrid precursor was demonstrated to occur within the yeast host. Secretion of the protease was achieved by fusing the leader sequence of yeast alpha-factor to the precursor form of the protease or to the 99 amino acid mature form of the protease. Authentic and active forms of the retroviral enzyme were detected in yeast supernatants of cells expressing the precursor or the mature form of the protease. A D25E active site variant of the retroviral enzyme exhibited diminished autocatalytic activity when expressed intracellularly or secreted from yeast. The wild-type protease was active in an in vitro assay on the natural substrate, myristylated gag precursor, Pr53gag. Correct processing of Pr53gag at the Tyr 138-Pro 139 junction was confirmed by amino terminal sequence analysis of the resulting capsid protein (CA, p24). The secreted protease was purified to homogeneity from yeast media using preparative isoelectric focusing and reverse-phase HPLC. Amino terminal sequence analysis showed a sequence beginning at amino acid 1 of the mature enzyme (Pro) and another sequence beginning at amino acid 6 (Trp). This shorter sequence may represent a natural autolytic product of the protease.     

Simultaneous accumulation of multiple viral coat proteins from a TEV-NIa based expression vector

We previously described an expression cassette that relies on the tobacco etch virus (TEV) nuclear inclusion a (NIa) protease and leads to the coordinated accumulation of multiple proteins through self processing of a polyprotein [21]. However, low levels of proteins accumulated when the full-length protease was encoded within the polyprotein [22].Studies were conducted to evaluate whether the disruption of NIa nuclear localization would affect the levels of proteins produced via the cassette. Modifications comprised either removal of its nuclear localization signals (NLSs), removal of the VPg domain (which includes the NLSs), and fusion to the 6 kDa protein, previously demonstrated to be a viral cytoplasmic anchor [28]. In in vitro translation reactions and in vivo protoplast experiments the modified NIa retained sequence-specific proteolysis. Moreover, the removal of the NLSs correlated with an increase in GUS reporter accumulation. The modified cassette, pPRO10, led to the synthesis of up to three viral coat protein (CPs) in addition to NIa. However, the accumulation of proteins in protoplasts depended upon the position of the CP coding sequence within the cassette as well as on the stability of the protein.     

Targeting of proteins derived from self-processing polyproteins containing multiple signal sequences

The 18aa 2A self-cleaving oligopeptide from foot-and-mouth disease virus can be used for co-expression of multiple, discrete proteins from a single ORF. 2A mediates a co-translational cleavage at its own C-terminus and is proposed to manipulate the ribosome into skipping the synthesis of a specific peptide bond (producing a discontinuity in the peptide backbone), rather than being involved in proteolysis. To explore the utility of the system to target discrete processing products, self-processing polyproteins comprising fluorescent proteins flanking 2A were constructed, permutating both the type of signal sequence and the location within the polyprotein. A polyprotein comprising a protein bearing an N-terminal signal sequence, 2A, then a protein lacking any signal sequence, was constructed. Interestingly, both proteins were translocated into the endoplasmic reticulum. Despite the discontinuity in the peptide backbone, the mammalian ribosome:translocon complex did not disassemble--the second protein (lacking any signal) 'slipstreamed' through the translocon formed by the first (signal-bearing) protein. These polyprotein systems provide a novel method of targeting proteins to different subcellular sites by transfection with a plasmid encoding a single ORF. The inclusion of a fluorescent reporter enables visualisation of expression levels, whilst inclusion of a selectable marker enables stable cell-lines to be established rapidly.     

Molecular Determinants of Human T-cell Leukemia Virus Type 1 Gag Targeting to the Plasma Membrane for Assembly

Assembly of human T-cell leukemia virus type 1 (HTLV-1) particles is initiated by the trafficking of virally encoded Gag polyproteins to the inner leaflet of the plasma membrane (PM). Gag–PM interactions are mediated by the matrix (MA) domain, which contains a myristoyl group (myr) and a basic patch formed by lysine and arginine residues. For many retroviruses, Gag–PM interactions are mediated by phosphatidylinositol 4,5-bisphosphate [PI(4,5)P₂]; however, previous studies suggested that HTLV-1 Gag–PM interactions and therefore virus assembly are less dependent on PI(4,5)P₂. We have recently shown that PI(4,5)P₂ binds directly to HTLV-1 unmyristoylated MA [myr(–)MA] and that myr(–)MA binding to membranes is significantly enhanced by inclusion of phosphatidylserine (PS) and PI(4,5)P₂. Herein, we employed structural, biophysical, biochemical, mutagenesis, and cell-based assays to identify residues involved in MA–membrane interactions. Our data revealed that the lysine-rich motif (Lys47, Lys48, and Lys51) constitutes the primary PI(4,5)P₂–binding site. Furthermore, we show that arginine residues 3, 7, 14 and 17 located in the unstructured N-terminus are essential for MA binding to membranes containing PS and/or PI(4,5)P₂. Substitution of lysine and arginine residues severely attenuated virus-like particle production, but only the lysine residues could be clearly correlated with reduced PM binding. These results support a mechanism by which HTLV-1 Gag targeting to the PM is mediated by a trio engagement of the myr group, Arg-rich and Lys-rich motifs. These findings advance our understanding of a key step in retroviral particle assembly.