Physical map of the Kirsten sarcoma virus genome as determined by fingerprinting RNase T1-resistant oligonucleotides.

From analysis of the large RNase T1-resistant oligonucleotides of Kirsten sarcoma virus (Ki-SV), a physical map of the virus genome was deduced. Kirsten murine leukemia virus (Ki-MuLV) sequences were detected in T1 oligonucleotides closest to the 3' end of the viral RNA and extended approximately 1,000 nucleotides into the genome. The rat genetic sequences started at this point and extended all the way to the very 5' end of the RNA molecules, where a small stretch of Ki-MuLV sequence was detected. By comparison of the fingerprints of Ki-SV RNA and the RNA of the endogenous rat src genetic sequences, it was found that more than 50% of the T1 oligonucleotides were similar between Ki-SV and the endogenous rat src RNA, suggesting an identical primary nucleotide sequence in over 50% of the viral genomes. The results indicate that Ki-SV arose by recombination between the 5' and 3' ends of Ki-MuLV and a large portion of the homologous sequences of the endogenous rat src RNA.     

Defective interfering particles of poliovirus: mapping of the deletion and evidence that the deletions in the genomes of DI(1), (2) and (3) are located in the same region.

The deletions in RNAs of three defective interfering (DI) particles of poliovirus type 1 have been located and their approximate extent determined by three methods. (1) Digestion with RNase III of DI RNAs yields the same 3′-terminal fragments as digestion with RNase III of standard virus RNA. The longest 3′-terminal fragment has a molecular weight of 1.55 × 10⁶. This suggests that the deletions are located in the 5′-terminal half of the polio genome. (2) Fingerprints of RNase T₁-resistant oligonucleotides of all three DI RNAs are identical and lack four large oligonucleotides as compared to the fingerprints of standard virus, an observation suggesting that the deletions in all three DI RNAs are located in the same region of the viral genome. The deletion-specific oligonucleotides have also been shown to be within the 5′-terminal half of the viral genome by alkali fragmentation of the RNA and fingerprinting poly (A)-linked (3′-terminal) fragments of decreasing size. (3) Virion RNA of DI(2) particles was annealed with denatured double-stranded RNA (RF) of standard virus and the hybrid heteroduplex molecules examined in the electron microscope. A single loop, approximately 900 nucleotides long and 20% from one end of the molecules, was observed. Both the size and extent of individual deletions is somewhat variable in different heteroduplex molecules, an observation suggesting heterogeneity in the size of the deletion in RNA of the DI(2) population. Our data show that the DI RNAs of poliovirus contain an internal deletion in that region of the viral genome known to specify the capsid polypeptides. This result provides an explanation as to why poliovirus DI particles are unable to synthesize viral coat proteins.     

Mapping host range-specific oligonucleotides within genomes of the ecotropic and mink cell focus-inducing strains of Moloney murine leukemia virus.

The site of recombination of a mink cell focus-inducing strain (Mo-MuLV83) derived from an ecotropic Moloney murine leukemia virus (Mo-MuLV) was mapped by fingerprint analysis of the large RNase T1-resistant oligonucleotides, employing a two-dimensional gel electrophoresis method. Mo-MuLV83, in contrast to the ecotropic Mo-MuLV, demonstrated a broadened host range, i.e., growth not only on mouse cells but also on mink cells, and recombination involved the env gene function. The genomic RNA of these two viruses shared 42 out of a total of 51 to 53 large T1 oligonucleotides (81%) and possessed a similar subunit size of 36S. Most of these T1 oligonucleotides were mapped in their relative order to the 3' polyadenylic acid end of the viral RNA molecules. There were 10 common oligonucleotides immediately next to the 3' termini. A cluster of 7 (in Mo-MuLV83) or 10 (in Mo-MuLV) unique T1 oligonucleotides were mapped next to the common sequences at the 3' end, and they all appeared concomitantly in a polyadenylic acid-containing RNA fraction with a sedimentation coefficient slightly larger than 18S. Therefore, the env gene of Mo-MuLV was situated at a location approximately 2,000 to 4,000 nucleotides from the 3' end of the genomic RNA, and the gene order of Mo-MuLV appeared to be similar to that of the more rigorously determined avian oncornaviruses. cDNA(SFFV) specific for the xenotropic sequences in the spleen focus-forming virus RNA hybridized to the cluster of unique oligonucleotides of Mo-MuLV83 RNA. This suggests that the loci of recombination involve the homologous env gene region of a xenotropic virus.     

Mouse hepatitis virus A59: mRNA structure and genetic localization of the sequence divergence from hepatotropic strain MHV-3.

The composition and structure of the mouse hepatitis virus (MHV)-specific RNA in actinomycin D-treated, infected L-2 cells were studied. SEven virus-specific RNA species with molecular weights of 0.6 X 10(6), 0.9 X 10(6), 1.2 X 10(6), 1.5 X 10(6), 3.0 X 10(6), 4.0 X 10(6), and 5.4 X 10(6) (equivalent to the viral genome) were detected. T1 oligonucleotide fingerprinting studies suggested that the sequences of each RNA species were totally included within the next large RNa species. The oligonucleotides of each RNA species were mapped on the 60S RNA genome of the virus. Each RNA species contained the oligonucleotides starting from the 3' end of the genome and extending continuously for various lengths in the 3' leads to 5' direction. All of the viral RNA species contained a polyadenylate stretch of 100 to 130 nucleotides and probably identical sequences immediately next to the polyadenylate. These data suggested that the virus-specific RNAs are mRNA's and have a stairlike structure similar to that of infectious bronchitis virus, an avian coronavirus. A proposal is presented, based on the mRNA structure, for the designation of the genes on the MHV genome. Using this proposal, the sequence differences between A59, a weakly pathogenic strain, and MHV-3, a strongly hepatotropic strain, were localized primarily in mRNA's 1 and 3, corresponding t genes A and C.     

Deletion mutant of the Bratislava-77 strain of Rous sarcoma virus containing a fusion of the group-specific antigen and envelope genes.

The genetic compositions of two independently derived preparations of the Bratislava-77 strain (B77) of Rous sarcoma virus were analyzed after each was passaged seven or more times in duck embryo fibroblasts. RNase, T1-resistant oligonucleotide fingerprint analysis of virion RNA from both preparations of duck-passaged B77 revealed the presence of two large noncontiguous deletions. Approximately 75% of the RNAs contained a deletion which spans oligonucleotides 304 to 4 on the viral genome (about 3,500 nucleotides) and encompasses all of the B77 polymerase gene. More than 90% of the RNAs also contained a deletion which spans src-specific oligonucleotides 6 and 5(about 2,200 nucleotides) and is identical to the deletion observed in transformation-defective B77. Virion RNA from duck-passaged B77 also contained two oligonucleotides (D1 and D2) not observed in the RNA of B77 virus grown on chicken embryo fibroblasts. Analysis of the virion RNA of duck-passaged B77 by denaturing agarose gel electrophoresis revealed four major subunits with molecular weights of 3.40 x 10(6), 2.65 x 10(6), 2.25 x 10(6), and 1.55 x 10(6). Whereas the 3.40- and 2.65-megadalton (Mdal) RNA species comigrated with the nondefective and transformation-defective RNAs of B77 propagated on chicken embryo fibroblasts, no counterparts to the 2.25- and 1.55-Mdal RNAs were observed in the RNA of B77 grown on chicken embryo fibroblasts. Oligonucleotide fingerprint analysis of these RNA species revealed that the 2.65-Mdal RNA contains the src-specific deletion and that 2.25-Mdal RNA contains the polymerase region deletion; both of these deletions were observed in the 1.55-Mdal RNA, which was the major RNA subunit species detected in duck-passaged B77. The new oligonucleotides (D1 and D2) observed in the duck-passaged virus were present in the 2.25- and 1.55-Mdal RNA species in vitro and in vivo and directs the synthesis of a 130,000-dalton protein (p130). p130 contains antigenic determinants specific for p27 (gag gene) and gp85 (env gene) but does not contain sequences which cross-react with antisera directed against the alpha beta form of RNA-dependent DNA polymerase (pol gene). This RNA, therefore, is generated by a fusion of the gag and env genes of Rous sarcoma virus B77.     

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.     

Characterization of the Low-Molecular-Weight RNAs Associated with the 70S RNA of Rous Sarcoma Virus

Two low-molecular-weight RNAs are associated with the 70S RNA complex of Rous sarcoma virus: a previously described 4S RNA and a newly identified 5S RNA. The 4S RNA constitutes 3 to 4% of the 70S RNA complex or the equivalent of 12 to 20 molecules per 70S RNA. It exhibits a number of structural properties characteristic of transfer RNA as revealed by two-dimensional electrophoresis of oligonucleotides obtained from a T1 ribonuclease digest of the 4S RNA species. The 5S RNA is approximately 120 nucleotides in length, constitutes 1% of the 70S RNA complex or the equivalent of 3 to 4 molecules per molecules of 70S RNA, and is identical in nucleotide composition and structure to 5S RNA from uninfected chicken embryo fibroblasts. Melting studies indicate that the 5S RNA is released from the 70S RNA complex at the same temperature required to dissociate 70S RNA into its constituent 35S subunits. In contrast, greater than 80% of the 4S RNA is released from 70S RNA prior to its conversion into subunits. The possible biological significance of these 70S-associated RNAs is discussed.     

Low frequency of (5''-3'') -C-G- connection in 70S RNA from simian sarcoma virus.

The frequency of oligonucleotides obtained from simian sarcoma virus RNA by digestion with ribonuclease T1 was compared with the frequency expected of an RNA molecule in which nucleotides are arranged in random distribution. Oligonucleotides containing C-residue attached to 3'-Gp were found significantly less in simian sarcoma virus 70S RNA than expected by random distribution.     

Structural insights into the substrate specificity of the endonuclease activity of the influenza virus cap-snatching mechanism

The endonuclease activity within the influenza virus cap-snatching process is a proven therapeutic target. The anti-influenza drug baloxavir is highly effective, but is associated with resistance mutations that threaten its clinical efficacy. The endonuclease resides within the N-terminal domain of the PA subunit (PA_N) of the influenza RNA dependent RNA polymerase, and we report here complexes of PA_N with RNA and DNA oligonucleotides to understand its specificity and the structural basis of baloxavir resistance mutations. The RNA and DNA oligonucleotides bind within the substrate binding groove of PA_N in a similar fashion, explaining the ability of the enzyme to cleave both substrates. The individual nucleotides occupy adjacent conserved pockets that flank the two-metal active site. However, the 2′ OH of the RNA ribose moieties engage in additional interactions that appear to optimize the binding and cleavage efficiency for the natural substrate. The major baloxavir resistance mutation at position 38 is at the core of the substrate binding site, but structural studies and modeling suggest that it maintains the necessary virus fitness via compensating interactions with RNA. These studies will facilitate the development of new influenza therapeutics that spatially match the substrate and are less likely to elicit resistance mutations.     

Complexity and polyadenylic acid content of visna virus 60-70S RNA.

The genomic complexity of visna virus was measured by quantitative analysis of 18 RNase T1-resistant oligonucleotides from 60-70S RNA. T1-resistant oligonucleotides were separated by two-dimensional polyacrylamide gel electrophoresis. Visna virus had a genomic complexity of 3.6 X 10(6) daltons, very close to the size of a single 30-40S RNA subunit. It was therefore concluded that the visna virus genome is largely polyploid. Visna virus 60-70S RNA polyadenylic acid segment was purified by T1 RNase digestion followed by oligodeoxythymidylic acid-cellulose column chromatography. It contained over 99% AMP and had a size of about 200 nucleotides. The binding capacities on oligodeoxythymidylic acid-cellulose of native 60-70S RNA and purified 30-40S RNA subunits were examined. It was concluded that two out of three intact subunits contain a polyadenylic acid segment.     

The occurrence and distribution of poly(a) ribonucleic Acid in soybean

The occurrence and distribution of poly(A) sequences in the RNA of soybean (Glycine max var. Wayne) have been studied. Only one of the two species of AMP-rich RNA contains poly(A). D-RNA does not contain detectable poly(A) sequences. The TB-RNA is the poly(A) RNA in this system. At least a part (up to 50% or more) of the mRNA in polyribosomes contains a poly(A) sequence. The poly(A) RNA is heterodisperse in size but has a mean size of approximately 18S (2,000 nucleotides) in urea and formamide gels. The poly(A) fragment resulting from ribonuclease A and T₁ digestion migrates as a broad band overlapping the 4 to 5.8S regions of the gels with a mean size of somewhat greater than 5S. No evidence was found for the occurrence of a discrete oligo(A) fragment in the poly(A) RNA; however, oligonucleotides which migrate faster than the poly(A) fraction were observed in preparations which were not bound to oligo(dT) cellulose prior to electrophoresis. This oligonucleotide region was enriched in AMP (up to about 65%) as would be expected after ribonuclease A and T₁ digestion.     

Peanut yellow spot virus: A distinct tospovirus species based on serology and nucleic acid hybridisation

Nucleocapsids of peanut yellow spot virus (PYSV), purified from peanut (= groundnut) plant tissue, contained a protein with a molecular mass of 29 kDa. In ELISA and immuno-blot analysis the virus did not react with tomato spotted wilt virus (TSWV), Impatiens necrotic spot virus (INSV) and peanut bud necrosis virus (PBNV) antisera. PYSV contained three RNA species, a large (L) RNA (c.8900 nucleotides), a medium (M) RNA (c.4800 nucleotides) and a small (S) RNA (c.3000 nucleotides), similar to other tospoviruses. In addition, a fourth RNA species of approximately 1800 nucleotides was also present in purified preparations. Hybridisation analysis under high stringency conditions revealed no hybridisation between PYSV RNAs and cDNA probes representing the nucleocapsid (N) gene, the glycoprotein (GP) gene and the 3' half of the RNA polymerase gene of PBNV. PYSV genomic RNAs also failed to hybridise with cDNA probes from the GP genes of TSWV and INSV. In reciprocal tests, the cDNA clones of PYSV S and M RNAs did not hybridise with any of the PBNV RNAs. Based on the absence of serological relationships between PYSV and PBNV, TSWV and INSV and lack of nucleotide homology based on hybridisation studies between the PYSV RNAs and cDNA clones from PBNV, TSWV and INSV, PYSV should be considered as a distinct species of the genus Tospovirus under a new serogroup, putatively designated ‘V’.     

Observations concerning the sequence of two additional specifically encapsidated RNA fragments originating from the tobacco-mosaic-virus coat-protein cistron.

The incubation of 25-S tobacco mosaic virus (TMV) protein with a mixture of RNA fragments produced by partial T1 RNase digestion of TMV RNA results in the encapsidation of only a few species of RNA. In addition to the most predominant species, fragment 1, whose sequence has been described in the prededing paper, two other species, fragment 41 and fragment 21 are coated by the protein. These two RNA fragments were purified by polyacrylamide gel electrophoresis and subjected to total digestion with pancreatic and T1 RNase. The oligonucleotides were separated by paper electrophoresis and characterized insofar as possible by digestion with the complementary ribonuclease. From the amino acid coding capacity of the oligonucleotides liberated from fragments 41 and 21 by T1 RNase digestion, it appears that these two fragments, like fragment 1, are derived from the coat protein cistron. They are situated immediately prior to fragment 1 and, together with this fragment, consitute a continuous stretch of 232 nucleotides of the cistron which codes for animo acids 53 to 130 of the coat protein. The order of the fragments in the sequence is 21-41-1. A possible model for the secondary structure of this portion of the sequence is proposed.     

The genome of Uukuniemi virus consists of three unique RNA segments

The three RNA species isolated from virions of Uukuniemi virus, a proposed member of the newly defined Bunyaviridae family, have been characterized by analysis of ³²P-labeled ribonuclease T1 oligonucleotides separated on two-dimensional polyacrylamide gels. Each RNA species contains unique oligonucleotides not present in the two others, indicating that the genome of this virus is segmented. Each segment appears to contain a unique primary sequence with little or no overlapping among the segments. The complexities of the RNA segments as calculated from the radioactivity in unique oligonucleotides of defined lengths are about 8000 (L RNA), 3500 (M) and 1900 (S) nucleotides. Since these values are similar to the molecular weights determined by other methods, each size class of RNA corresponds to a single molecular species. The presence of a 5′ terminal pppAp … structure in each RNA segment confirms indications from electron microscopy that the apparently circular RNA segments are not covalently closed. The absence of either a 5′ terminal “cap” or 3′ terminal poly(A) supports the concept that Uukuniemi virus is a negative strand virus.     

The 30S Moloney sarcoma virus RNA contains leukemia virus nucleotide sequences.

The 50S-70S RNA of a Moloney sarcoma-leukemia virus [Mo-MSV(MLV)] complex produced by a particular mouse cell line was shown by gel electrophoresis to contain a major (97%) 30S sarcoma-specific subunit species and a minor (3%) 38S leukemia virus-specific subunit. On the basis of its sedimentation coefficient and known complexity, the 30S Mo-MSV RNA was estimated to be a unique RNA molecule of about 6000 nucleotides. Hybridization experiments using viral RNA and DNA complementary to viral RNA (cDNA) made by viral DNA polymerase indicated that the 30S Mo-MSV RNA shared 70% of its sequences with Mo-MLV, 30% with another MLV derived from Mo-MLV, and 30% with Kirsten sarcoma-xenotropic leukemia virus. The 30S Mo-MSV RNA sequences shared with these viruses were not additive. The Tm of a Mo-MSV RNA-MLV cDNA hybrid was 83 degrees C, indicating that large contiguous nucleotide sequences were shared between the two nucleic acids. Mo-MSV RNA and Mo-MLV RNA shared possibly seven of 20-30 RNAase T1-resistant oligonucleotides, while Mo-MSV RNA contained three, and Mo-MLV RNA contained at least five specific oligonucleotides. We conclude that the 30S Mo-MSV RNA molecule consists of approximately 70% (about 4200 nucleotides) Mo-MLV-specific sequences and of 30% (1800 nucleotides) Mo-MSV-specific sequences covalently linked. Our results favor the hypothesis that 30S Mo-MSV RNA was generated by recombination between Mo-MLV and other genetic elements. We discuss whether all or only the MSV-specific sequences of the 30S Mo-MSV RNA function as sarcoma genes. Mo-MLV cDNA was hybridized about 45% by unfractionated Mo-MSV (MLV) RNA at RNA/DNA ratios of up to 10, about 50% by electrophoretically purified 30S Mo-MSV RNA at RNA/DNA ratios up to 500, but close to 100% by unfractionated Mo-MSV(MLV) RNA at RNA/DNA ratios over 900. This indicated that unfractionated RNA of our Mo-MSV(MLV) contained a complete complement of Mo-MLV, albeit at a low ratio.     

Studies on the sequence of the 3'-terminal region of turnip-yellow-mosaic-virus RNA.

A fragment representing the 3'-terminal 'tRNA-like' region of turnip yellow mosaic (TYM) virus RNA has been purified following incubation of intact TYM virus RNA with Escherichia coli 'RNase P'. This fragment, which is 112+3-nucleotides long has been completely digested with T1 RNase and pancreatic RNase and all the oligonucleotides present in such digests have been sequenced using 32P-end labelling techniques in vitro. The TYM virus RNA fragment is free of modified nucleosides and does not contain a G-U-U-C-R sequence. Using nuclease P1 from Penicillium citrinum, the sequence of 26 nucleotides from the 5' end and 16 nucleotides from the 3' end of this fragment has been deduced. The nucleotide sequence at the 5' end of the TYM virus RNA fragment indicates that this fragment includes the end of the TYM virus coat protein gene.