The complete nucleotide sequence of the potexvirus white clover mosaic virus.

The complete nucleotide sequence (5845 nucleotides) of the genomic RNA of the potexvirus white clover mosaic virus (WC1MV) has been determined from a set of overlapping cDNA clones. Forty of the most 5'-terminal nucleotides of WC1MV showed homology to the 5' sequences of other potexviruses. The genome contained five open reading frames which coded for proteins of Mr 147, 417, Mr 26,356, Mr 12,989, Mr 7,219 and Mr 20,684 (the coat protein). The Mr 147,417 protein had domains of amino acid sequence homology with putative polymerases of other RNA viruses. The Mr 26,356 and Mr 12,989 proteins had homology with proteins of the hordeivirus barley stripe mosaic virus RNA beta and the furovirus beet necrotic yellow vein virus (BNYVV) RNA-2. A portion of the Mr 26,356 protein was also conserved in the cylindrical inclusion proteins of two potyviruses. The Mr 7,219 protein had homology with the 25K putative fungal transmission factor of BNYVV RNA-3.     

The nucleic acid-binding zinc finger protein of potato virus M is translated by internal initiation as well as by ribosomal frameshifting involving a shifty stop codon and a novel mechanism of P-site slippage.

The genes for the capsid protein CP and the nucleic acid-binding 12K protein (pr12) of potato virus M (PVM) constitute the 3' terminal gene cluster of the PVM RNA genome. Both proteins are presumably translated from a single subgenomic RNA. We have identified two translational strategies operating in pr12 gene expression. Internal initiation at the first and the second AUG codon of the pr12 coding sequence results in the synthesis of the 12K protein. In addition the protein is produced as a CP/12K transframe protein by ribosomal frameshifting. For these studies parts of the CP and pr12 coding sequences including the putative frameshift region were introduced into an internal position of the beta-glucuronidase gene. Mutational analyses in conjunction with in vitro translation experiments identified a homopolymeric string of four adenosine nucleotides which together with a 3' flanking UGA stop codon were required for efficient frameshifting. The signal AAAAUGA is the first frameshift signal with a shifty stop codon to be analyzed in the eukaryotic system. Substitution of the four consecutive adenosine nucleotides by UUUU increased the efficiency of frameshifting, while substitution by GGGG or CCCC dramatically reduced the synthesis of the transframe protein. Also, UAA and UAG could replace the opal stop codon without effect on the frameshifting event, but mutation of UGA to the sense codon UGG inhibited transframe protein formation. These findings suggest that the mechanism of ribosomal frameshifting at the PVM signal is different from the one described by the 'simultaneous slippage' model in that only the string of four adenosine nucleotides represents the slippery sequence involved in a -1 P-site slippage.     

Complete nucleotide sequence of genomic RNA of the potato M-virus

The complete nucleotide sequence of potato virus M genomic RNA has been determined to be 8534 nucleotides (with the exception of the poly(A) tail at the 3' end). The sequence contains six large open reading frames coding for proteins of mol. wt. 223206, 25438, 11893, 6793, 33906, and 12183 (in 5'----3' direction). According to its primary sequence analysis the 223K protein ORF codes for a virus RNA replicase. The in vitro translation product of 34K protein gene precipitates by the antisera against the RVM indicating that the 34K protein is the virus coat protein. The general aspects of carla- and potexvirus gene organization are discussed.     

The human 18S U11/U12 snRNP contains a set of novel proteins not found in the U2-dependent spliceosome

U11 and U12 snRNPs bind U12-type pre-mRNAs as a preformed di-snRNP complex, simultaneously recognizing the 5' splice site and branchpoint sequence. Thus, within the U12-type prespliceosome, U11/U12 components form a molecular bridge connecting both ends of the intron. We have affinity purified human 18S U11/U12 and 12S U11 snRNPs, and identified their protein components by using mass spectrometry. U11/U12 snRNPs lack all known U1 snRNP proteins but contain seven novel proteins (i.e., 65K, 59K, 48K, 35K, 31K, 25K, 20K) not found in the major spliceosome, four of which (59K, 48K, 35K, and 25K) are U11-associated. Thus, protein-protein and protein-RNA interactions contributing to 5' splice site recognition and/or intron bridging appear to differ significantly in the minor versus major prespliceosome. The majority of U11/U12 proteins are highly conserved in organisms known to contain U12-type introns. However, homologs of those associated with U11 were not detected in Drosophila melanogaster, consistent with the presence of a divergent U11 snRNP in flies. RNAi experiments revealed that several U11/U12 proteins are essential for cell viability, suggesting they play key roles in U12-type splicing. The presence of unique U11/U12 snRNP proteins in the U12-type spliceosome provides insight into potential evolutionary relationships between the major and minor spliceosome.     

Characterization of the AdoMet-dependent guanylyltransferase activity that is associated with the N terminus of bamboo mosaic virus replicase

Bamboo mosaic virus (BaMV), a member of the potexvirus group, infects primarily members of the Bambusoideae. Open reading frame 1 (ORF1) of BaMV encodes a 155-kDa polypeptide that has long been postulated to be a replicase involved in the replication and formation of the cap structure at the 5' end of the viral genome. To identify and characterize the enzymatic activities associated with the N-terminal domain of the BaMV ORF1 protein, the intact replicase and two C-terminally truncated proteins were expressed in Saccharomyces cerevisiae. All three versions of BaMV ORF1 proteins could be radiolabeled by [alpha-(32)P]GTP, which is a characteristic of guanylyltransferase activity. The presence of S-adenosylmethionine (AdoMet) was essential for this enzymatic activity. Thin-layer chromatography analysis suggests that the radiolabeled moiety linked to the N-terminal domain of the BaMV ORF1 protein is m(7)GMP. The N-terminal domain also exhibited methyltransferase activity that catalyzes the transfer of the [(3)H]methyl group from AdoMet to GTP or guanylylimidodiphosphate. Therefore, during cap structure formation in BaMV, methylation of GTP may occur prior to transguanylation as for alphaviruses and brome mosaic virus. This study establishes the association of RNA capping activity with the N-terminal domain of the replicase of potexviruses and further supports the idea that the reaction sequence of RNA capping is conserved throughout the alphavirus-like superfamily of RNA viruses.     

Nucleotide sequence and genome organization of foot-and-mouth disease virus.

A continuous 7802 nucleotide sequence spanning the 94% of foot and mouth disease virus RNA between the 5'-proximal poly(C) tract and the 3'-terminal poly(A) was obtained from cloned cDNA, and the total size of the RNA genome was corrected to 8450 nucleotides. A long open reading frame was identified within this sequence starting about 1300 bases from the 5' end of the RNA genome and extending to a termination codon 92 bases from its polyadenylated 3' end. The protein sequence of 2332 amino acids deduced from this coding sequence was correlated with the 260 K FMDV polyprotein. Its processing sites and twelve mature viral proteins were inferred from protein data, available for some proteins, a predicted cleavage specificity of an FMDV encoded protease for Glu/Gly(Thr, Ser) linkages, and homologies to related proteins from poliovirus. In addition, a short unlinked reading frame of 92 codons has been identified by sequence homology to the polyprotein initiation signal and by in vitro translation studies.     

Structural analyses of the 7SK ribonucleoprotein (RNP), the most abundant human small RNP of unknown function.

The human 7SK ribonucleoprotein (RNP) has been analyzed to determine its RNA secondary structure and protein constituents. HeLa cell 7SK RNA alone and within its RNP have been probed by chemical modification and enzymatic cleavage, and sites of modification or cleavage have been mapped by primer extension. The resulting secondary structure suggests that structural determinants necessary for capping (a 5' stem followed by the sequence AUPuUPuC) and nuclear migration (the sequence AUPuUPuC) of 7SK RNA may be similar to those for U6 small nuclear RNA (snRNA). It also supports existence of a 3' stem structure which could serve to self-prime cDNA synthesis during pseudogene formation. Oligonucleotide-directed RNase H digestion indicated regions of 7SK RNA capable of base pairing with other nucleic acids. Antisense 2'-O-methyl RNA oligonucleotides were used to affinity select the 7SK RNP from an in vivo 35S-labeled cell sonic extract and identify eight associated proteins of 83, 48, 45, 43, 42, 21, 18, and 13 kDa. 7SK RNA has extensive sequence complementarity to U4 snRNA, within the U4/U6 base pairing domain, and also to U11 snRNA. The possibility that the 7SK RNP is an unrecognized component of the pre-mRNA processing machinery is discussed.     

Cell-to-cell movement of potexviruses: evidence for a ribonucleoprotein complex involving the coat protein and first triple gene block protein

The triple gene block proteins (TGBp1-3) and coat protein (CP) of potexviruses are required for cell-to-cell movement. Separate models have been proposed for intercellular movement of two of these viruses, transport of intact virions, or a ribonucleoprotein complex (RNP) comprising genomic RNA, TGBp1, and the CP. At issue therefore, is the form(s) in which RNA transport occurs and the roles of TGBp1-3 and the CP in movement. Evidence is presented that, based on microprojectile bombardment studies, TGBp1 and the CP, but not TGBp2 or TGBp3, are co-translocated between cells with viral RNA. In addition, cell-to-cell movement and encapsidation functions of the CP were shown to be separable, and the rate-limiting factor of potexvirus movement was shown not to be virion accumulation, but rather, the presence of TGBp1-3 and the CP in the infected cell. These findings are consistent with a common mode of transport for potexviruses, involving a non-virion RNP, and show that TGBp1 is the movement protein, whereas TGBp2 and TGBp3 are either involved in intracellular transport or interact with the cellular machinery/docking sites at the plasmodesmata.     

Serial passage of tobacco rattle virus under different selection conditions results in deletion of structural and nonstructural genes in RNA 2.

The RNA genome of tobacco rattle virus (TRV) is bipartite. RNA 2 of the nematode-transmissible TRV isolate PPK20 encodes the viral coat protein (cp) and proteins with molecular weights of 29,400 and 32,800 (29.4K and 32.8K proteins). When this isolate was serially passaged in tobacco by using phenol-extracted RNA as the inoculum in each transfer, defective interfering (DI) RNAs rapidly accumulated. A number of these DI RNAs were cloned. Six DI RNAs had single internal deletions in RNA 2 that removed most of the cp gene, the 29.4K gene, and the 5' half of the 32.8K gene. The borders of the deletions in these DI RNAs were found to be flanked in the genomic RNA 2 by short nucleotide repeats or sequences resembling the 5' end of TRV genomic and subgenomic RNAs. Two DI RNAs were found to be recombinants containing a 5' sequence derived from RNA 2 and a 3' sequence derived from RNA 1. When serial passage of TRV isolate PPK20 was carried out by using leaf homogenates as inocula in each transfer, accumulation of a DI RNA (designated D7) with a functional cp gene was observed. The deletion in D7 covered the 3' end of the cp gene, the 29.4K gene, and the 5' half of the 32.8K gene. An infectious cDNA clone of D7 RNA was made. In mixed infections, D7 RNA rapidly outcompeted RNA 2 but did not compete with RNA 1. The deletion in D7 RNA abolished the nematode transmissibility of the PPK20 isolate. These results may explain the observation that many laboratory isolates of tobraviruses have lost their nematode transmissibility and contain RNA 2 molecules of widely different lengths.     

Characterization of Rous sarcoma virus src gene products synthesized in vitro.

The cell-free synthesis of three major proteins from virion RNA of nondefective Rous sarcoma virus (RSV), but not from RNA of transformation-defective deletion mutants, has been observed. The apparent molecular weights of these transformation-specific proteins are approximately 60,000 (60K), 25K, and 17K. Tryptic maps of methionine-containing peptides revealed the 17K, 25K, and 60K proteins to be overlapping in sequence. However, only partial homology was observed between the 17K, 25K and 60K proteins synthesized from Schmidt-Ruppin strain, subgroup D, RSV RNA and those synthesized from Prague strain, subgroup B, RSV, RNA. About half of the methionine peptides in the Schmidt-Ruppin strain, subgroup D, 60K protein were shared with the Prague strain, subgroup D, 60K protein, and the rest were distinct to each. The virion RNAs coding for the 60K, 25K, and 17K proteins were found to be polyadenylated and to sediment with maximal mRNA activity at about 23, 19 to 20, and 18S, respectively. In addition, transformation-specific proteins with molecular weights of 39K and 33K were observed by in vitro synthesis. These proteins are also related to the 60K, 25K, and 17K proteins and were synthesized from polyadenylated RSV RNA of approximately 21 to 22S. RNase T1-resistant oligonucleotides were analyzed in parallel, and the src-specific oligonucleotides were found to be first present in equimolar amounts in those gradient fractions sedimenting at 21 to 22S. Our data suggest that synthesis of the 60K protein is initiated near the 5' terminus of the src gene, whereas the 39K, 33K, 25K, and 17K proteins are initiated internally in the src gene. All of these proteins appear to be initiated independently, but they may have a common termination site.     

The 12 kDa protein of potato virus M displays properties of a nucleic acid-binding regulatory protein

The 3' terminal 1.4 kb segment of potato virus M (PVM) genomic RNA was cloned and sequenced. This part of the viral genome encodes the capsid protein CP as well as a 12 kDa protein of as yet unknown function. Both proteins were expressed in bacteria and their nucleic acid-binding properties studied. The 12 kDa protein (pr12), but not the capsid protein bound single- and double-stranded nucleic acids. This property of pr12 in conjunction with a zinc finger motif located adjacent to a basic region of the 12 kDa protein suggests that it may act as a regulatory factor during virus replication.     

The complete nucleotide sequence of PEBV RNA2 reveals the presence of a novel open reading frame and provides insights into the structure of tobraviral subgenomic promoters.

The 3374 nucleotide sequence of RNA2 from the British PEBV strain SP5 has been determined. The RNA includes three open reading frames flanked by 5' and 3' noncoding regions of 509 and 480 nucleotides. The open reading frames specify coat protein, a 29.6K product homologous to the 29.1K product of TRV(TCM) RNA2 and a 23K product not homologous to any previously described protein. The homology demonstrated between the coat proteins of PRV, TRV and PEBV indicates a common evolutionary origin for these proteins. Upstream of each ORF are located sequences homologous to those with which subgenomic RNAs of other tobraviruses start. Subgenomic RNAs for the expression of the three ORFs may start at these points. On all five tobraviral RNA2 molecules sequenced to date, these sequences were found upstream of the coat protein ORF in association with a strongly-conserved potential secondary structural element. Similar potential structures were identified upstream of other tobraviral ORFs. These structures may contribute to the activity of the tobraviral subgenomic promoter.     

The structure and selectivity of the SR protein SRSF2 RRM domain with RNA

SRSF2 is a prototypical SR protein which plays important roles in the alternative splicing of pre-mRNA. It has been shown to be involved in regulatory pathways for maintaining genomic stability and play important roles in regulating key receptors in the heart. We report here the solution structure of the RNA recognition motifs (RRM) domain of free human SRSF2 (residues 9-101). Compared with other members of the SR protein family, SRSF2 structure has a longer L3 loop region. The conserved aromatic residue in the RNP2 motif is absent in SRSF2. Calorimetric titration shows that the RNA sequence 5'AGCAGAGUA3' binds SRSF2 with a K(d) of 61 ± 1 nM and a 1:1 stoichiometry. NMR and mutagenesis experiments reveal that for SFSF2, the canonical β1 and β3 interactions are themselves not sufficient for effective RNA binding; the additional loop L3 is crucial for RNA complex formation. A comparison is made between the structures of SRSF2-RNA complex with other known RNA complexes of SR proteins. We conclude that interactions involving the L3 loop, N- and C-termini of the RRM domain are collectively important for determining selectivity between the protein and RNA.     

Specific interaction of polypyrimidine tract-binding protein with the extreme 3'-terminal structure of the hepatitis C virus genome, the 3'X.

We previously identified a highly conserved 98-nucleotide (nt) sequence, the 3'X, as the extreme 3'-terminal structure of the hepatitis C virus (HCV) genome (T. Tanaka, N. Kato, M.-J. Cho, and K. Shimotohno, Biochem. Biophys. Res. Commun. 215:744-749, 1995). Since the 3' end of positive-strand viral RNA is the initiation site of RNA replication, the 3'X should contribute to HCV negative-strand RNA synthesis. Cellular factors may also be involved in this replication mechanism, since several cellular proteins have been shown to interact with the 3'-end regions of other viral genomes. In this study, we found that both 38- and 57-kDa proteins in the human hepatocyte line PH5CH bound specifically to the 3'-end structure of HCV positive-strand RNA by a UV-induced cross-linking assay. The 57-kDa protein (p57), which had higher affinities to RNA probes, recognized a 26-nt sequence including the 5'-terminal 19 nt of the 3'X and 7 flanking nt, designated the transitional region. This sequence contains pyrimidine-rich motifs and shows similarity to the consensus binding sequence of the polypyrimidine tract-binding protein (PTB), which has been implicated in alternative pre-mRNA splicing and cap-independent translation. We found that this 3'X-binding p57 is identical to PTB. The 3'X-binding p57 was immunoprecipitated by anti-PTB antibody, and recombinant PTB bound to the 3'X RNA. In addition, p57 bound solely to the 3'-end region of positive-strand RNA, not to this region of negative-strand RNA. We suggest that 3'X-PTB interaction is involved in the specific initiation of HCV genome replication.     

Structure of the black beetle virus genome and its functional implications

The black beetle virus (BBV) is an isometric insect virus whose genome consists of two messenger-active RNA molecules encapsidated in a single virion. The nucleotide sequence of BBV RNA1 (3105 bases) has been determined, and this, together with the sequence of BBV RNA2 (1399 bases) provides the complete primary structure of the BBV genome. The RNA1 sequence encompasses a 5' non-coding region of 38 nucleotides, a coding region for a protein of predicted molecular weight 101,873 (protein A, implicated in viral RNA synthesis) and a 3' proximal region encoding RNA3 (389 bases), a subgenomic messenger RNA made in infected cells but not encapsidated into virions. The RNA3 sequence starts 16 bases inside the coding region of protein A and contains two overlapping open reading frames for proteins of molecular weight 10,760 and 11,633, one of which is believed to be protein B, made in BBV-infected cells. A limited homology exists between the sequences of RNA1 and RNA2. Sequence regions have been identified that provide energetically favorable bonding between RNA2 and RNA1 possibly to facilitate their common encapsidation, and between RNA2 and negative strand RNA1 possibly to regulate the production of RNA3.     

Four nucleotides are the minimal requirement for RNA recognition by rotavirus non-structural protein NSP3.

The interaction of the group A rotavirus non-structural protein NSP3 (NSP3A) with RNA has been studied in vitro. Using semi-purified NSP3A protein expressed by a recombinant baculovirus and in vitro synthesized RNA, we determined by UV cross-linking and gel retardation assays that NSP3A binds, in a sequence-specific manner, the consensus sequence (AUGUGACC) present on the 3' ends of all group A rotavirus mRNAs. Using short oligoribonucleotides, we established that the minimal RNA sequence required for binding of NSP3A is GACC. Modifications of the UGACC oligonucleotide sequence impaired binding of the protein to the RNA. Furthermore, the recombinant NSP3 protein from rotavirus group C showed specificity for the 3' end consensus sequence (AUGUGGCU) of only group C mRNAs. Sequence analysis of the NSP3 proteins did not reveal significant homologies with other RNA binding proteins, thus the NSP3 proteins of rotaviruses are the prototypes of a new kind of sequence-specific RNA binding protein.