Structural elements of the 3'-terminal coat protein binding site in alfalfa mosaic virus RNAs.

The 3'-terminal of the three genomic RNAs of alfalfa mosaic virus (AIMV) and ilarviruses contain a number of AUGC-motifs separated by hairpin structures. Binding of coat protein (CP) to such elements in the RNAs is required to initiate infection of these viruses. Determinants for CP binding in the 3'-terminal 39 nucleotides (nt) of AIMV RNA 3 were analyzed by band-shift assays. From the 5'- to 3'-end this 39 nt sequence contains AUGC-motif 3, stem-loop structure 2 (STLP2), AUGC-motif 2, stem-loop structure 1 (STLP1) and AUGC-motif 1. A mutational analysis showed that all three AUGC-motifs were involved in CP binding. Mutation of the A- and U-residues of motifs 1 or 3 had no effect on CP binding but similar mutations in motif 2 abolished CP binding. A mutational analysis of the stem of STLP1 and STLP2 confirmed the importance of these hairpins for CP binding. Randomization of the sequence of the stems and loops of STLP1 and STLP2 had no effect on CP binding as long as the secondary structure was maintained. This indicates that the two hairpins are not involved in sequence-specific interactions with CP. They may function in a secondary structure-specific interaction with CP and/or in the assembly of the AUGC-motifs in a configuration required for CP binding.     

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.     

Determination of the secondary structure of and cellular protein binding to the 3'-untranslated region of the hepatitis C virus RNA genome.

Hepatitis C virus (HCV) contains a positive-stranded RNA genome of approximately 9.5 kb. Despite the overall sequence diversity among individual HCV isolates, the 3'-end 98 nucleotides (nt) of the HCV RNA, which constitute part of the 3'-untranslated region (3'-UTR), are highly conserved. This conserved region may contain the cis-acting signals for RNA replication involving possibly both viral and cellular proteins. We carried out RNase digestion studies, which revealed that this 98-nt region contains three stem-loops but may also assume alternative structures. We further performed UV cross-linking experiments to detect cellular proteins that bound to this region. A 58-kDa cellular protein (p58) was detected. Its binding site was mapped to the stem-loops 2 and 3, which are the most conserved region of the 3'-UTR. Site-directed mutagenesis studies revealed that both stem structures and specific nucleotide sequence within the two loops are important for p58 binding. Mutations that disrupted stem structures abolished protein binding, while the compensatory mutations restored its binding. This region also contains partial sequence similarity to the reported consensus binding sequence for polypyrimidine tract-binding protein (PTB) (a 57-kDa protein). The UV-cross-linked protein could be immunoprecipitated with the anti-PTB antibody, and the recombinant PTB bound to the HCV 3'-UTR with the same binding specificity as p58, establishing that this protein is PTB. However, the reported PTB-binding sequence was not sufficient, but rather the entire stem-loops 2 and 3 were required, for PTB binding; thus, its binding specificity is significantly different from the reported PTB-binding sequence requirement. This protein was detected in both the nuclei and cytoplasm of most mammalian cell lines tested and human primary hepatocytes. PTB may participate in the regulation of HCV RNA synthesis or translation.     

Functional equivalence of common and unique sequences in the 3' untranslated regions of alfalfa mosaic virus RNAs 1, 2, and 3.

The 3' untranslated regions (UTRs) of alfalfa mosaic virus (AMV) RNAs 1, 2, and 3 consist of a common 3'-terminal sequence of 145 nucleotides (nt) and upstream sequences of 18 to 34 nt that are unique for each RNA. The common sequence can be folded into five stem-loop structures, A to E, despite the occurrence of 22 nt differences between the three RNAs in this region. Exchange of the common sequences or full-length UTRs between the three genomic RNAs did not affect the replication of these RNAs in vivo, indicating that the UTRs are functionally equivalent. Mutations that disturbed base pairing in the stem of hairpin E reduced or abolished RNA replication, whereas compensating mutations restored RNA replication. In vitro, the 3' UTRs of the three RNAs were recognized with similar efficiencies by the AMV RNA-dependent RNA polymerase (RdRp). A deletion analysis of template RNAs indicated that a 3'-terminal sequence of 127 nt in each of the three AMV RNAs was not sufficient for recognition by the RdRp. Previously, it has been shown that this 127-nt sequence is sufficient for coat protein binding. Apparently, sequences required for recognition of AMV RNAs by the RdRp are longer than sequences required for CP binding.     

Interaction of a cellular 57-kilodalton protein with the internal translation initiation site of foot-and-mouth disease virus.

A cellular 57-kDa protein (p57) that binds specifically to the internal translation initiation site in the 5' untranslated region of foot-and-mouth disease virus RNA was detected in cell extracts of different mammalian species by UV cross-linking. The protein binds to two distinct sites of the translation control region which have as the only common sequence a UUUC motif. The first binding site consists of a conserved hairpin structure, whereas the second binding site contains an essential pyrimidine-rich region without obvious secondary structure. Competition experiments indicate that the complexes with the two binding sites were formed by a single p57 species. The protein binds also to the 5' untranslated region of other picornaviruses. Results from footprint analyses with foot-and-mouth disease RNA suggest the participation of additional cellular factors in the translation initiation complex.     

Template requirement and initiation site selection by hepatitis C virus polymerase on a minimal viral RNA template

RNA-dependent RNA polymerase, NS5B protein, catalyzes replication of viral genomic RNA, which presumably initiates from the 3'-end. We have previously shown that NS5B can utilize the 3'-end 98-nucleotide (nt) X region of the hepatitis C virus (HCV) genome as a minimal authentic template. In this study, we used this RNA to characterize the mechanism of RNA synthesis by the recombinant NS5B. We first showed that NS5B formed a complex with the 3'-end of HCV RNA by binding to both the poly(U-U/C)-rich and X regions of the 3'-untranslated region as well as part of the NS5B-coding sequences. Within the X region, NS5B bound stem II and the single-stranded region connecting stem-loops I and II. Truncation of 40 nt or more from the 3'-end of the X region abolished its template activity, whereas X RNA lacking 35 nt or less from the 3'-end retained template activity, consistent with the NS5B-binding site mapped. Furthermore, NS5B initiated RNA synthesis from a specific site within the single-stranded loop I. All of the RNA templates that have a double-stranded stem at the 3'-end had the same RNA initiation site. However, the addition of single-stranded nucleotides to the 3'-end of X RNA or removal of double-stranded structure in stem I generated RNA products of template size. These results indicate that HCV NS5B initiates RNA synthesis from a single-stranded region closest to the 3'-end of the X region. These results have implications for the mechanism of HCV RNA replication and the nature of HCV RNA templates in the infected cells.     

Complete nucleotide sequence of alfalfa mosaic virus RNA 2.

Double-stranded cDNA of in vitro polyadenylated alfalfa mosaic virus (AlMV) RNA 2 has been cloned and sequenced. The use of an oligodeoxyribonucleotide corresponding to the known sequence of the 5'-end of RNA 2 to prime second-strand DNA synthesis, enabled us to construct the complete primary structure of AlMV RNA 2. The sequence of 2,593 nucleotides contains a long open reading frame for a protein of Mr 89,753 starting at the first AUG codon from the 5'-end. This coding region is flanked by a 5'-terminal sequence of 54 nucleotides and a 3'-noncoding region of 166 nucleotides which includes the sequence of 145 nucleotides the three genomic RNAs of AlMV have in common.     

Adenovirus mutants with splice-enhancing mutations in the E3 complex transcription unit are also defective in E3A RNA 3'-end formation

Region E3 of adenovirus encodes about 10 overlapping mRNAs with different spliced structures. The mRNAs are 5' coterminal and form two major 3'-coterminal families termed E3A and E3B. As a group, the mRNAs have two 5' splice sites and four or five 3' splice sites. We previously described a novel class of virus mutants with deletions that enhance distant upstream and downstream 5' and 3' splice sites in region E3 (S. L. Deutscher, B. M. Bhat, M. H. Pursley, C. Cladaras, and W. S. M. Wold, Nucleic Acids Res. 13:5771-5788, 1985). We now report that two of these mutants, dl710 and dl712, are defective in RNA 3'-end formation at the E3A site. This result was surprising because the deletions in dl710 and dl712 are upstream of the putative signal for E3A RNA 3'-end formation. The explanation that we favor for this result is that the enhanced splicing activity in these mutants results in the splicing out of the E3A 3'-end site from the RNA precursor before the E3A 3' ends have a chance to form.     

Sequences downstream of the 5' splice donor site are required for both packaging and dimerization of human immunodeficiency virus type 1 RNA

Two copies of human immunodeficiency virus type 1 RNA are incorporated into each virus particle and are further converted to a stable dimer as the virus particle matures. Several RNA segments that flank the 5' splice donor site at nucleotide (nt) 289 have been shown to act as packaging signals. Among these, RNA stem-loop 1 (SL1) (nt 243 to 277) can trigger RNA dimerization through a "kissing-loop" mechanism and thus is termed the dimerization initiation site. However, it is unknown whether other packaging signals are also needed for dimerization. To pursue this subject, we mutated stem-loop 3 (SL3) (nt 312 to 325), a GA-rich region (nt 325 to 336), and two G-rich repeats (nt 363 to 367 and nt 405 to 409) in proviral DNA and assessed the effects on RNA dimerization by performing native Northern blot analyses. Our results show that the structure but not the specific RNA sequence of SL3 is needed not only for efficient viral RNA packaging but also for dimerization. Mutations of the GA-rich sequence severely diminished viral RNA dimerization as well as packaging; the combination of mutations in both SL3 and the GA-rich region led to further decreases, implying independent roles for each of these two RNA motifs. Compensation studies further demonstrated that the RNA-packaging and dimerization activity of the GA-rich sequence may not depend on a putative interaction between this region and a CU repeat sequence at nt 227 to 233. In contrast, substitutions in the two G-rich sequences did not cause any diminution of viral RNA packaging or dimerization. We conclude that both the SL3 motif and GA-rich RNA sequences, located downstream of the 5' splice donor site, are required for efficient RNA packaging and dimerization.     

A G-C-Rich Palindromic Structural Motif and a Stretch of Single-Stranded Purines Are Required for Optimal Packaging of Mason-Pfizer Monkey Virus (MPMV) Genomic RNA

During retroviral RNA packaging, two copies of genomic RNA are preferentially packaged into the budding virus particles whereas the spliced viral RNAs and the cellular RNAs are excluded during this process. Specificity towards retroviral RNA packaging is dependent upon sequences at the 5′ end of the viral genome, which at times extend into Gag sequences. It has earlier been suggested that the Mason-Pfizer monkey virus (MPMV) contains packaging sequences within the 5′ untranslated region (UTR) and Gag. These studies have also suggested that the packaging determinants of MPMV that lie in the UTR are bipartite and are divided into two regions both upstream and downstream of the major splice donor. However, the precise boundaries of these discontinuous regions within the UTR and the role of the intervening sequences between these dipartite sequences towards MPMV packaging have not been investigated. Employing a combination of genetic and structural prediction analyses, we have shown that region “A”, immediately downstream of the primer binding site, is composed of 50 nt, whereas region “B” is composed of the last 23 nt of UTR, and the intervening 55 nt between these two discontinuous regions do not contribute towards MPMV RNA packaging. In addition, we have identified a 14-nt G-C-rich palindromic sequence (with 100% autocomplementarity) within region A that has been predicted to fold into a structural motif and is essential for optimal MPMV RNA packaging. Furthermore, we have also identified a stretch of single-stranded purines (ssPurines) within the UTR and 8 nt of these ssPurines are duplicated in region B. The native ssPurines or its repeat in region B when predicted to refold as ssPurines has been shown to be essential for RNA packaging, possibly functioning as a potential nucleocapsid binding site. Findings from this study should enhance our understanding of the steps involved in MPMV replication including RNA encapsidation process.