Replication of semliki forest virus: polyadenylate in plus-strand RNA and polyuridylate in minus-strand RNA.

The 42S RNA from Semliki Forest virus contains a polyadenylate [poly(A)] sequence that is 80 to 90 residues long and is the 3'-terminus of the virion RNA. A poly(A) sequence of the same length was found in the plus strand of the replicative forms (RFs) and replicative intermediates (RIs) isolated 2 h after infection. In addition, both RFs and RIs contained a polyuridylate [poly(U)] sequence. No poly(U) was found in virion RNA, and thus the poly(U) sequence is in minus-strand RNA. The poly(U) from RFs was on the average 60 residues long, whereas that isolated from the RIs was 80 residues long. Poly(U) sequences isolated from RFs and RIs by digestion with RNase T1 contained 5'-phosphorylated pUp and ppUp residues, indicating that the poly(U) sequence was the 5'-terminus of the minus-strand RNA. The poly(U) sequence in RFs or RIs was free to bind to poly(A)-Sepharose only after denaturation of the RNAs, indicating that the poly(U) was hydrogen bonded to the poly(A) at the 3'-terminus of the plus-strand RNA in these molecules. When treated with 0.02 mug of RNase A per ml, both RFs and RIs yielded the same distribution of the three cores, RFI, RFII, and RFIII. The minus-strand RNA of both RFI and RFIII contained a poly(U) sequence. That from RFII did not. It is known that RFI is the double-stranded form of the 42S plus-strand RNA and that RFIII is the experimetnally derived double-stranded form of 26S mRNA. The poly(A) sequences in each are most likely transcribed directly from the poly(U) at the 5'-end of the 42S minus-strand RNA. The 26S mRNA thus represents the nucleotide sequence in that one-third of the 42S plus-strand RNA that includes its 3'-terminus.     

Sequence of methylated nucleotides at the 5''-terminus of adenovirus-specific RNA.

RNA labeled with [methyl-3H] methionine and [14C]uridine was isolated from the cytoplasm of adenovirus-infected cells and purified by poly(U)-Sepharose chromatography and hybridization to filters containing immobilized adeovirus DNA. Analysis by dimethyl sulfoxide-sucrose gradient sedimentation suggested that the major mRNA species were methylated. 7-Methylguanosine was identified at the 5'-terminus of the advenovirus-specific RNA and could be removed by periodate oxidation and beta-elimination. Structures of the type m7G(5')ppp(5')Nm containing the unusual nucleoside N6, O2'-dimethyladenosine, and smaller amounts of 2'-O-methyladenosine were isolated by DEAE-cellulose chromatography after P1 nuclease digestion of the RNA. Evidence for some 5'-terminal sequences, m7G(5')ppp(5')m6AmpNm, with additional 2'-O-methylribonucleosides was also obtained. A base-methylated nucleoside, N6-methyladenosine, is located within the RNA chain and is released as a mononucleotide by alkali hydrolysis.     

The 3'' untranslated region of satellite tobacco necrosis virus RNA stimulates translation in vitro.

The RNA of satellite tobacco necrosis virus (STNV) is a monocistronic messenger that lacks both a 5' cap structure and a 3' poly(A) tail. We show that in a cell-free translation system derived from wheat germ, STNV RNA lacking the 600-nucleotide trailer is translated an order of magnitude less efficiently than full-size RNA. Deletion analyses positioned the translational enhancer domain (TED) within a conserved hairpin structure immediately downstream from the coat protein cistron. TED enhances translation when fused to a heterologous mRNA, but the level of enhancement depends on the nature of the 5' untranslated sequence and is maximal in combination with the STNV leader. The STNV leader and TED have two regions of complementarity. One of the complementary regions in TED resembles picornavirus box A, which is involved in cap-independent translation but which is located upstream of the coding region.     

5'-proximal hot spot for an inducible positive-to-negative-strand template switch by coronavirus RNA-dependent RNA polymerase

Coronaviruses have a positive-strand RNA genome and replicate through the use of a 3' nested set of subgenomic mRNAs each possessing a leader (65 to 90 nucleotides [nt] in length, depending on the viral species) identical to and derived from the genomic leader. One widely supported model for leader acquisition states that a template switch takes place during the generation of negative-strand antileader-containing templates used subsequently for subgenomic mRNA synthesis. In this process, the switch is largely driven by canonical heptameric donor sequences at intergenic sites on the genome that match an acceptor sequence at the 3' end of the genomic leader. With experimentally placed 22-nt-long donor sequences within a bovine coronavirus defective interfering (DI) RNA we have shown that matching sites occurring anywhere within a 65-nt-wide 5'-proximal genomic acceptor hot spot (nt 33 through 97) can be used for production of templates for subgenomic mRNA synthesis from the DI RNA. Here we report that with the same experimental approach, template switches can be induced in trans from an internal site in the DI RNA to the negative-strand antigenome of the helper virus. For these, a 3'-proximal 89-nt acceptor hot spot on the viral antigenome (nt 35 through 123), largely complementary to that described above, was found. Molecules resulting from these switches were not templates for subgenomic mRNA synthesis but, rather, ambisense chimeras potentially exceeding the viral genome in length. The results suggest the existence of a coronavirus 5'-proximal partially double-stranded template switch-facilitating structure of discrete width that contains both the viral genome and antigenome.     

Size analysis and relationship of murine leukemia virus-specific mRNA''s: evidence for transposition of sequences during synthesis and processing of subgenomic mRNA.

Virus-specific mRNA from purified polyribosomes of mouse cells infected with Moloney murine leukemia virus (M-MuLV) was analyzed by electrophoresis in agarose gels, followed by hybridization of gel slices with M-MuLV-specific complementary DNA (cDNA). The size resolution of the gels was better than that of sucrose gradients used in previous analyses, and two virus-specific mRNA's of 38S and 24S were detected. The 24S virus-specific mRNA is predominantly derived from the 3' half of the M-MuLV genome, since cDNAgag(pol) (complementary to the 5' half of the M-MuLV genome) could not efficiently anneal with this mRNA. However, sequences complementary to cDNA synthesized from the extreme 5' end of M-MuLV 38S RNA (cDNA 5') are present in the 24S virus-specific mRNA, since cDNA 5' (130 nucleotides) efficiently annealed with this mRNA. The annealing of cDNA 5' was not due to repetition of 5' terminal nucleotide sequences at the 3' end of M-MuLV 38S RNA, since smaller cDNA 5' molecules (60 to 70 nucleotides), which likely lack the terminal repetition, also efficiently annealed with the 24S mRNA. The sequences in 24S virus-specific mRNA recognized by cDNA 5' are not present in 3' fragments of virion RNA that are the same length. Therefore, it appears that RNA sequences from the extreme 5' end of the M-MuLV genome may be transposed to sequences from the 3' half of the M-MuLV 38S RNA during synthesis and processing of the 24S virus-specific mRNA. These results may indicate a phenomenon similar to the RNA splicing processes that occur during synthesis of adenovirus and papovavirus mRNA's.     

Control of translation by the 5'- and 3'-terminal regions of the dengue virus genome

The genomic RNAs of flaviviruses such as dengue virus (DEN) have a 5' m7GpppN cap like those of cellular mRNAs but lack a 3' poly(A) tail. We have studied the contributions to translational expression of 5'- and 3'-terminal regions of the DEN serotype 2 genome by using luciferase reporter mRNAs transfected into Vero cells. DCLD RNA contained the entire DEN 5' and 3' untranslated regions (UTRs), as well as the first 36 codons of the capsid coding region fused to the luciferase reporter gene. Capped DCLD RNA was as efficiently translated in Vero cells as capped GLGpA RNA, a reporter with UTRs from the highly expressed alpha-globin mRNA and a 72-residue poly(A) tail. Analogous reporter RNAs with regulatory sequences from West Nile and Sindbis viruses were also strongly expressed. Although capped DCLD RNA was expressed much more efficiently than its uncapped form, uncapped DCLD RNA was translated 6 to 12 times more efficiently than uncapped RNAs with UTRs from globin mRNA. The 5' cap and DEN 3' UTR were the main sources of the translational efficiency of DCLD RNA, and they acted synergistically in enhancing translation. The DEN 3' UTR increased mRNA stability, although this effect was considerably weaker than the enhancement of translational efficiency. The DEN 3' UTR thus has translational regulatory properties similar to those of a poly(A) tail. Its translation-enhancing effect was observed for RNAs with globin or DEN 5' sequences, indicating no codependency between viral 5' and 3' sequences. Deletion studies showed that translational enhancement provided by the DEN 3' UTR is attributable to the cumulative contributions of several conserved elements, as well as a nonconserved domain adjacent to the stop codon. One of the conserved elements was the conserved sequence (CS) CS1 that is complementary to cCS1 present in the 5' end of the DEN polyprotein open reading frame. Complementarity between CS1 and cCS1 was not required for efficient translation.     

An MSV-specific subgenomic mRNA in MSV-transformed G8-124 cells

An intracellular subgenomic RNA species from MSV-transformed G8-124 cells was characterized by electron microscopy of RNA:cDNA heteroduplexes using long cDNAs both MSV and MuLV. This subgenomic RNA, 3.1 kb long, consisted of 5'-derived sequences of about 0.4 kb joined to 2.7 kb of RNA derived from the 3' end of the RNA genome. The 3'-derived sequences included the residual sequences from the MuLV pol region and the acquired cellular sequences of MSV. The genome of MSV was shown to retain approximately 0.13 kb from the 5' end of the MuLV env region, including sequences which span the point in the MuLV env mRNA. No subgenomic MSV RNA could be detected, however, which consisted of a 5'-derived leader sequence spliced to the retained env region sequences. Nor could a subgenomic MSV RNA be detected in which a 5'-derived leader sequence was joined directly to the acquired cellular sequences. Although its translation products are unknown, the subgenomic MSV RNA was present in preparations of poly(A)+ polysomal RNA, consistent with this RNA functioning as a messenger. The structure of this 3.1 kb MSV subgenomic RNA suggests a possible role in the expression of 3'-encoded MSV information, possibly including transformation-specific sequences.     

At least 104 nucleotides are transposed from the 5' terminus of the avian sarcoma virus genome to the 5' termini of smaller viral mRNAs.

Cells producing avian sarcoma virus (ASV) contain at least three virus-specific mRNAs, two of which are encoded within the 3' half of the viral genome. Each of these viral RNAs can hybridize with single-stranded DNA(cDNA5') that is complementary to a sequence of 101 nucleotides found at the 5' terminus of the ASV genome, but not within the 3' half of the genome. We proposed previously (Weiss, Varmus and Bishop, 1977) that this nucleotide sequence may be transposed to the 5' termini of viral mRNAs during the genesis of these RNAs. We now substantiate this proposal by reporting the isolation and chemical characterization of the nucleotide sequences complementary to cDNA5' in the genome and mRNAs of the Prague B strain of ASV. We isolated the three identified classes of ASVmRNA (38, 28 and 21S) by molecular hybridization; each class of RNA contained a "capped" oligonucleotide identical to that found at the 5' terminus of the ASV genome. When hybridized with cDNA5', each class of RNA gave rise to RNAase-resistant duplex hybrids that probably encompassed the full extent of cDNA5'. The molar yields of duplex conformed approximately to the number of virus-specific RNA molecules in the initial samples; hence most if not all of the molecules of virus-specific RNA could give rise to the duplexes. The duplexes prepared from the various RNAs all contained the capped oligonucleotide found at the 5' terminus of the viral genome and had identical "fingerprints" when analyzed by two-dimensional fractionation following hydrolysis with RNAase T1. In contrast, RNA representing the 3' half of the ASV genome did not form hybrids with cDNA5'. We conclude that a sequence of more than 100 nucleotides is transposed from the 5' end of the ASV genome to the 5' termini of smaller viral RNAs during the genesis of these RNAs. Transposition of nucleotide sequences during the production of mRNA has now been described for three families of animal viruses and may be a common feature of mRNA biogenesis in eucaryotic cells. The mechanism of transposition, however, and the function of the transposed sequences are not known.