Functional role of the 5′ terminal cloverleaf in Coxsackievirus RNA replication

Using cell-free reactions, we investigated the role of the 5′ cloverleaf (5′CL) and associated C-rich sequence in Coxsackievirus B3 RNA replication. We showed that the binding of poly(C) binding protein (PCBP) to the C-rich sequence was the primary determinant of RNA stability. In addition, inhibition of negative-strand synthesis was only observed when PCBP binding to both stem-loop ‘b’ and the C-rich sequence was inhibited. Taken together, these findings suggest that PCBP binding to the C-rich sequence was sufficient to support RNA stability and negative-strand synthesis. Mutational analysis of the three conserved structural elements in stem-loop ‘d’ showed that they were required for efficient negative- and positive-strand synthesis. Finally, we showed an RNA with a 5′ terminal deletion (Δ49TD RNA), which was previously isolated from persistently infected cells, replicated at low but detectable levels in these reactions. Importantly, the critical replication elements identified in this study are still present in the Δ49TD RNA.     

Mutation analysis of cis-elements in the 3'- and 5'-untranslated regions of satellite tobacco necrosis virus strain C RNA.

The putative, 3'-terminal stem-loop structure in satellite tobacco necrosis virus strain C (STNV-C) RNA constitutes an essential cis-acting structure for the promotion of negative-strand RNA synthesis and a single-stranded tail is also important. The putative, 5'-terminal stem-loop structure in STNV-C RNA is not essential for productive, plus-strand RNA accumulation but is required for optimal accumulation. Residues 2 and 3 are the minimal cis-acting sequences required for RNA synthesis. The RNA of chimeric mutants, which exchanged 3'- and 5'-untranslated regions between STNV-C and helper tobacco necrosis virus strain D RNAs, accumulated in protoplasts, implying similar replication mechanisms for both RNAs.     

Structure of the 3' extremity of barley stripe mosaic virus RNA: evidence for internal poly(A) and a 3'-terminal tRNA-like structure

The results of a previous study suggested that the poly(A) sequence in barley stripe mosaic virus (BSMV) RNA is intercalated between a 3'-terminal tyrosine-accepting structure and the 5'-terminal coding part of the BSMV genome. Here we show that poly(A)+ and poly(A)- fractions of BSMV RNA can be cleaved into two fragments specifically at the position of poly(A) or oligo(A) sequence with RNase H from Escherichia coli in the presence of oligo(dT)10. The shorter fragment (Sh) retains the ability of intact viral RNA to be aminoacylated, i.e., it represents the 3'-terminal part of BSMV RNA. Electrophoretic analysis of Sh-RNA reveals three closely positioned subspecies with an average length of about 210 nucleotides. The long 5'-terminal RNA fragment (L) produced by RNase H treatment has electrophoretic mobility similar to that of intact BSMV RNA, but displays neither amino acid-accepting ability nor infectivity. Nevertheless, L-RNA possesses the same messenger activity as the intact viral RNA and codes for the same pattern of polypeptides in rabbit reticulocyte lysate in vitro translation assays.     

Nucleotide sequence at the 3' terminus of pepper mottle virus genomic RNA: evidence for an alternative mode of potyvirus capsid protein gene organization

The sequence of the 3'-terminal 1481 nucleotides of the pepper mottle virus (PeMV) genome has been determined. The sequence was determined by dideoxy nucleotide sequencing of complementary DNA which had been inserted into M13 bacteriophage cloning vectors and was confirmed by sequencing selected regions of PeMV RNA. A discrete open reading frame of 993 nucleotides, ending 333 nucleotides from the 3'-terminal polyadenylate tract, was identified that potentially encoded a 37,669-MW protein. The amino acids predicted at positions 64 through 84 of this putative polypeptide were identical to the amino-terminal 21 amino acids of the PeMV capsid protein ascertained by chemical sequencing. These combined nucleotide and amino acid sequence data suggest that the PeMV capsid protein is encoded by the 3'-most cistron on the genomic RNA and that it may be expressed as a precursor that is proteolytically processed to produce the mature capsid protein.     

Nucleotide sequence and translation of satellite tobacco mosaic virus RNA

Satellite tobacco mosaic virus (STMV) is a plant virus with a 17-nm icosahedral particle encapsidating a 0.3 X 10(6) Mr ssRNA genome that depends on tobamoviruses for its replication. The complete nucleotide sequence of STMV RNA deduced in the experiments described here was 1059 nucleotides in length. The efficiency of labeling viral RNA with [gamma-32P]ATP using T4 polynucleotide kinase was not affected by treatment with tobacco acid pyrophosphatase and/or bacterial alkaline phosphatase, indicating that the majority of the 5' termini of encapsidated STMV RNAs were not phosphorylated. The 240 3'-terminal nucleotides of STMV RNA and either tobacco mosaic virus (TMV) U1 RNA or TMV U2/U5 RNA had greater than 65% overall sequence similarity, with two nearly identical regions of 40 and 50 bases, respectively. There were no other regions of sequence relatedness to TMV RNA. The 19 5'-terminal nucleotides of STMV RNA had greater than 65% sequence similarity with the 16 5'-terminal nucleotides of brome mosaic virus (RNA 3 and 50% sequence similarity with the 12 5'-terminal nucleotides of the Q strain of cucumber mosaic virus RNA 3. The first open reading frame (ORF) beginning at base 53 encoded a 6800 Mr protein that corresponded in size to a major in vitro translation product directed by STMV RNA. A second ORF, beginning at nucleotide 163, had the capacity to code for a protein that corresponded in size (17,500 Mr) to the other major in vitro translation product. The first 12 codons of this ORF corresponded to the sequence of the N-terminal amino acids of the capsid protein. Western-blot analysis of the in vitro translation products revealed that the 17,500 Mr protein had the same electrophoretic mobility as the authentic capsid protein; it was also antigenically related to the capsid protein, but the 6800 Mr protein was not. Time course analysis of in vitro translation demonstrated that the 6800 Mr protein was synthesized at the same time as the capsid protein and did not arise by the proteolytic cleavage of a larger precursor polypeptide. These results suggest that the genome of STMV functioned as a polycistronic messenger RNA. It has not been determined if the 6800 Mr protein is synthesized in vivo. STMV RNA had untranslated regions of 52 and 418 nucleotides at its 5' and 3' termini, respectively.(ABSTRACT TRUNCATED AT 400 WORDS)     

Complete sequences of the glycoproteins and M RNA of Punta Toro phlebovirus compared to those of Rift Valley fever virus

The complete sequence of Punta Toro virus (Phlebovirus, Bunyaviridae) middle size (M), RNA has been determined. The RNA is 4330 nucleotides long (mol wt 1.46 X 10(6), base composition: 26.7% A, 33.6% U, 18.5% G, 21.2% C) and has 3'- and 5'-terminal sequences that, depending on the arrangement, are complementary for some 15 residues. The viral RNA codes in its viral-complementary sequence for a single primary gene product (the viral glycoprotein precursor) that is comprised of 1313 amino acids (146,376 Da) and is abundant in cysteine residues but has few potential asparagine-linked glycosylation sites. The 5'-noncoding region of the Punta Toro M viral-complementary RNA is short (16 nucleotides); the 3'-noncoding sequence is much longer (372 nucleotides). The latter is rich in short stretches of adenylate residues, like the 3'-noncoding regions of the Punta Toro S mRNA species (T. Ihara, H. Akashi, and D. H. L. Bishop, 1984, Virology 136, 293-306). No other large open reading frame has been identified in either the viral, or viral-complementary, M RNA sequences. Limited amino-terminal sequence analyses of the two viral glycoproteins have indicated the gene order and potential cleavage sites in the glycoprotein precursor. The data suggest the existence of a 30 X 10(3)-Da polypeptide (designated NSM) in the glycoprotein precursor that precedes the G1 protein (i.e., gene product order: NSM-G1-G2). Examination of the sequence of the Punta Toro M gene product reveals the presence of multiple hydrophobic sequences including a 19-amino acid, carboxy-proximal, hydrophobic region (G2). This hydrophobic sequence is followed by a 13-amino acid-terminal sequence rich in charged amino acids. The size and constitution of the carboxy-terminal region is consistent with a transmembranal and anchor function for the glycoprotein in the viral envelope. Other regions of the glycoprotein precursor contain sequences of amino acids with a predominantly hydrophobic character (23, 50, and 20 amino acids in length). Their functions are unknown. The amino terminus of the G1 protein is located near the end of the 23-amino acid-long hydrophobic sequence of the presumptive precursor, the hydrophobic 50-amino acid sequence lies within G1, and the amino terminus of G2 is located in the middle of the 20-amino acid-long hydrophobic sequence.(ABSTRACT TRUNCATED AT 400 WORDS)     

An unusual coordinated cleavage event in the processing of encephalomyocarditis virus polypeptides

During the translation of encephalomyocarditis virus RNA in the rabbit reticulocyte lysate system, polypeptides 2B and 2C, encoded by the central region of the genome, appear simultaneously in the absence of any detectable 2BC precursor and at a time when translation has advanced into the region coding for polypeptide 3C. This implies the operation of closely coordinated proteolysis at two sites, with at least one cleaved by the virus-coded protease activity 3C.     

Aminoacylation of barley stripe mosaic virus RNA: polyadenylate-containing RNA has a 3'-terminal tyrosine-accepting structure

Barley stripe mosaic virus (BSMV) RNA which was previously reported to contain poly(A) sequences (Agranovsky et al., 1978) can be specifically esterified with tyrosine in vitro in the presence of an aminoacyl-tRNA synthetase fraction from wheat embryos. All the three RNA components of the BSMV strain with a three-component genome (Norwich) and both RNA components of a two-component strain (Russian) can be tyrosylated. The poly(A)-containing (bound to oligo(dT)-cellulose) and poly(A)-deficient (not bound to oligo(dT)-cellulose) fractions of BSMV RNA display a similar amino acid-accepting ability. The nucleotide sequence which accepts tyrosine is coupled with the intact genomic polyadenylated BSMV RNA. The viral RNA isolated after sucrose density gradient centrifugation under drastic denaturing conditions retains its aminoacylating activity, which suggests that this activity is not due to the presence in a BSMV RNA preparation of a tyrosine tRNA associated with BSMV RNA. Inhibition of aminoacylation of the 3'-oxidized (treated with sodium metaperiodate) BSMV RNA suggests that the tyrosine-accepting structure is localized at the 3' terminus of BSMV RNA molecules. It is shown that segments of different lengths obtained upon random fragmentation can be tyrosylated. The 3'-terminal (tyrosine-accepting) poly(A)+ segments can be isolated. The shortest segments of viral RNA capable of being aminoacylated [i.e., containing both tRNA-like structure and poly(A)] consists of approximately 150-200 nucleotides. The analysis of the oligonucleotides derived from individual BSMV RNA components labeled with (32)P at the 3' end revealed two types of 3'-terminal sequences different from poly(A). It is suggested that a poly(A) sequence is intercalated between a 3'-terminal tyrosine-accepting structure and the 5'-terminal portion of poly(A)+ BSMV RNA.     

Subdomain specific functions of the RNA polymerase region of poliovirus 3CD polypeptide

The 3D polymerase domain of the poliovirus 3CD polypeptide plays a role in modulating its RNA binding and protein processing activities, even though the proteinase catalytic site and RNA binding determinants appear to reside within the 3C(pro) portion of the molecule. In this study, we have generated recombinant 3CD polypeptides that contain chimeric 3D polymerase domains representing suballelic sequence exchanges between poliovirus type 1 (PV1) and coxsackievirus B3 (CVB3) to determine which portions of the 3D domain are responsible for influencing these activities. By utilizing these recombinant protein chimeras in protein processing and RNA binding studies in vitro, we have generated data suggesting the presence of separate subdomains within the polymerase domain of 3CD that may independently modulate its RNA binding and protein processing activities. In predicting where our sequence exchanges map by utilizing the previously published three-dimensional structure of the PV1 3D polymerase, we present evidence that sequences contained within the RNA recognition motif of the polymerase are critical for 3CD function in recognizing the 5' RNA cloverleaf. Furthermore, our protein processing data indicate that at least some of the substrate recognition and processing determinants within the 3D domain of 3CD are separate and distinct from the RNA binding determinants in this domain.     

Structure of the L (polymerase) protein gene of sonchus yellow net virus.

The complete nucleotide sequence of the L protein gene of sonchus yellow net virus (SYNV), a plant rhabdovirus, was determined by dideoxynucleotide sequencing of cloned cDNAs derived from the negative-strand genomic RNA. The L protein gene is composed of 6401 nucleotides (nt) located between positions 7158 and 13558 relative to the 3' end of the genomic RNA. Sequence analysis suggests that the complementary mRNA contains a 44 nt untranslated 5' leader sequence preceding an open reading frame of 6348 nucleotides that is capable of encoding a polypeptide of 2116 amino acids with a deduced molecular weight of 241,569 Da. The L protein is positively charged, has a high proportion of the amino acids Leu and Ile, and contains putative polymerase and RNA binding domains. Extended alignment of the SYNV L protein amino acid sequence with those of other nonsegmented negative-strand RNA virus polymerases reveals conservation of sequences within 12 blocks that appear sequentially along the protein. A cluster dendrogram derived from the L protein alignments indicates that SYNV is more closely related to animal rhabdoviruses than to the paramyxoviruses and that the animal rhabdoviruses have diverged less from each other than from SYNV.     

Nucleotide sequence of barley stripe mosaic virus RNA alpha: RNA alpha encodes a single polypeptide with homology to corresponding proteins from other viruses

The complete nucleotide sequence of RNA alpha from the Type strain of barley stripe mosaic virus has been determined. The RNA is 3768 nucleotides long and contains a single open reading frame which codes for a polypeptide of 1139 amino acids (mw 129,634). The open reading frame is flanked by a 5'-terminal sequence of 91 nucleotides and a 3'-nontranslated region composed of a short poly(A) tract followed by a 238-nucleotide tRNA-like structure. The amino acid sequence of the polypeptide (alpha a) encoded by the open reading frame has homology with the TMV 126K protein and with related polypeptides from other viruses. The carboxy-terminal portion of the alpha a polypeptide also has limited homology with the 58K (beta b) protein encoded by BSMV RNA beta and includes a consensus sequence found in mononucleotide-binding polypeptides.     

VHL-box and SOCS-box domains determine binding specificity for Cul2-Rbx1 and Cul5-Rbx2 modules of ubiquitin ligases

The ECS (Elongin B/C-Cul2/Cul5-SOCS-box protein) complex is a member of a family of ubiquitin ligases that share a Cullin-Rbx module. SOCS-box proteins recruit substrates to the ECS complex and are linked to Cullin-Rbx via Elongin B/C. VHL has been implicated as a SOCS-box protein, but lacks a C-terminal sequence (downstream of the BC box) of the SOCS box. We now show that VHL specifically interacts with endogenous Cul2-Rbx1 in mammalian cells, whereas SOCS-box proteins associate with Cul5-Rbx2. We also identify LRR-1 and FEM1B as proteins that share a region of homology with VHL (the VHL box, including the BC box and downstream residues) and associate with Cul2-Rbx1. ECS complexes can thus be classified into two distinct protein assemblies, that is, those that contain a subunit with a VHL box (composed of the BC box and a downstream Cul2 box) that interacts with Cul2-Rbx1, and those that contain a subunit with a SOCS box (BC box and downstream Cul5 box) that interacts with Cul5-Rbx2. Domain-swapping analyses showed that the specificity of interaction of VHL-box and SOCS-box proteins with Cullin-Rbx modules is determined by the Cul2 and Cul5 boxes, respectively. Finally, RNAi-mediated knockdown of the Cul2-Rbx1 inhibited the VHL-mediated degradation of HIF-2alpha, whereas knockdown of Cul5-Rbx2 did not affect it. These data suggest that the functions of the Cul2-Rbx1 and Cul5-Rbx2 modules are distinct.     

Genetic analysis of an NTP-binding motif in poliovirus polypeptide 2C.

Poliovirus polypeptide 2C is a nonstructural protein involved in replication of the viral genome. Analysis of the primary amino acid sequence of 2C shows homology to a family of proteins which contain a nucleoside-triphosphate (NTP)-binding motif. This motif consists of elements "A" (2/5 hydrophobic stretch) G/AXXGXGKS/T, where X stands for any amino acid, and "B" (3/5 hydrophobic stretch) D or DD/E. To assess the significance of the consensus sequence in 2C, we have engineered point mutations into the most conserved residues in the A and B sites and tested their effect on viral RNA replication in vivo and translation in vitro. Whereas in vitro translation of synthetic RNAs carrying mutations in the NTP-binding motif showed efficient processing of all viral proteins, indistinguishable from that of the parental strain, transfection of the RNAs into HeLa cells did not give rise to infectious virus. No viral RNA replication could be detected in cells transfected with mutant RNAs. However, revertants to the wild-type genotype in the A and B sites were obtained which gave rise to wild-type RNA synthesis, but pseudorevertants or second-site suppressors were not observed. Thus, viral RNA synthesis is greatly reduced but not entirely abolished in cells transfected with mutant RNAs. These results strongly suggest a functional role for the proposed NTP-binding motif of 2C in RNA replication and proliferation of poliovirus.