Characterization of the subunit structure of the ribonucleic acid genome of influenza virus

Electron microscopy of vesicular stomatitis virus replicative ribonucleoproteins

The objective of this investigation was to examine by electron microscopy the replicative ribonucleoprotein (RNP) structures synthesized in vesicular stomatitis virus-infected HeLa cells. Pulse-labeled in vivo products of vesicular stomatitis virus replication and transcription can be separated by centrifugation in Renografin gradients. Transcription complexes are dissociated, allowing nascent messenger RNPs to remain at the top of the gradient, whereas RNPs biochemically consistent with replication complexes sediment to the middle of the gradient. Examination of these structures by electron microscopy revealed that all exist as coiled or helical RNPs having dimensions of approximately 20 by 700 nm. These structures can be further subdivided into three major morphological classes: (i) linear forms (20 by 769 +/- 158 nm), which have both ends free; (ii) circular forms (20 by 679 +/- 95 nm), which appear to have both ends joined; and (iii) complex forms, which include those structures which are branched replicative complexes as well as those which are random. To distinguish random complexes and possible transcriptive complex contaminants from replicative complexes, it was necessary to uncoil the RNP structures with EDTA so that length measurements could be made relating the nascent strand length to its position on the template. After EDTA treatment, the linear RNPs uncoiled (10 by 4,035 +/- 3,802 nm), and the circular morphology virtually disappeared. However, a new form appeared which was one-half the length and double the width (20 by 2,103 +/- 306 nm) of full-length RNPs and contained a loop at one end and two free ends at the other (alpha-form RNP). The distribution and length analysis of these structures, plus and minus EDTA, suggest that the alpha-form RNPs arise by EDTA-induced uncoiling of circular forms held together at the ends. Close scrutiny of uncoiled complex RNPs revealed no single-strand RNP templates with single-strand nascents. However, several complexes were observed which appeared to contain alpha-form templates with single-strand nascent RNPs. Length measurements suggest these complexes are neither random nor transcriptive, but are replicative. These experiments suggest that replication may, in part, occur on circular coiled RNP templates.

3'-terminal processing of ribosomal RNA precursors in mammalian cells

The 3'-terminal structures of ribosomal 28S RNA and its precursors from rat and mouse were analyzed by means of periodate oxidation followed by reduction with 3H-borohydride. 3'-terminal labeled nucleoside derivatives produced by RNase T2 digestion were determined by thin-layer chromatography and oligonucleotides generated by RNase T1 digestion were analyzed by DEAE-Sephadex chromatography. In the rat, the major 3'-terminal sequences of ribosomal 28S RNA, nucleolar 28S, 32S, 41S, and 45S RNAs were YGUoh, GZ2Uoh, GZ12Uoh, GZ2Uoh, and GZ7Goh, respectively, whereas in the mouse corresponding sequences were YGUoh, GZ1,2, or 3Uoh, Goh, Uoh and GZ 13Uoh, respectively. (Y: pyrimidine nucleoside, Z: any nucleoside other than guanosine) These results suggest that a "transcribed spacer" sequence is present at the 3'-terminus of the 45S pre-ribosomal RNA, which is gradually removed during the steps of processing.

The 3' and 5'-terminal sequences of influenza A, B and C virus RNA segments are highly conserved and show partial inverted complementarity

The 3'- and 5'-terminal nucleotides of the genome segments of an influenza A, B, and C virus were identified by directly sequencing viral RNA using two different sequencing techniques. A high degree of conservation at the 3' ends as well as at the 5' ends was observed among the genome segments of each virus and among the segments of the three different virus types. A uridine-rich region was observed from positions 17 through 22 at the 5' end of each segment. Moreover, the conserved 3' and 5'-terminal sequences showed partial and inverted complementarity. This feature results in very similar sequences at the 3' ends of the plus and minus strand RNAs and may also enable single-strand RNAs of influenza virus to form "panhandle" structures. Inverted complementary repeats may play an important role in initiation of viral RNA replication.

New procedure for the production of influenza virus-specific double-stranded DNA's

A novel technique is described for the production of pure, full-length influenza virus ds DNA's corresponding to each segment of the influenza virus genome, and suitable for molecular cloning and restriction endonuclease mapping. The method involves the synthesis of DNA complementary to both virion (negative strand) and messenger (positive strand) RNA, gel purification and annealing. By avoiding the use of SI nuclease, which often removes the terminal regions of DNA duplexes, the method allows transcription of the total sequence information of influenza virion and messenger RNA's into a ds DNA form.

Nucleotide sequence coding for the N-terminal region of the matrix protein influenza virus

After polyadenylation in vitro of the influenza virus RNA segment which contains the coding information for the matrix protein, a cDNA copy can be made using the primer p(dT)8-dA and reverse transcriptase. The sequence of 166 nucleotides of the cDNA was determined by a modification [Brownlee, G. G. & Cartwright, E. M. (1977) J. Mol. Biol, 114, 93--117] of the plus/minus method [Sanger, F. & Coulson, A. R. (1975) J. Mol. Biol. 94, 441--481] and adaptation of the "dideoxy" method [Sanger, F., Nicklen, S. & Coulson, A. R. (1977) Proc. Natl. Acad. Sci. U.S.A. 74, 5463--5467] for sequencing DNA. The cDNA sequences is of the same sense as the mRNA for matrix protein and contains a potential initiating codon, d(ATG), at position 26--28. When matrix protein purified from virus particles was digested with chymotrypsin or trypsin and the amino acid compositions of separated peptides determined, one peptide containing nine amino acids found which had a composition corresponding to that predicted by the cDNA sequence following the first methionine codon, confirming that protein synthesis initiates at this position. The compositions of four other peptides matches those predicted from the nucleotide sequence. There is no processing of the N terminus of the protein before incorporation into the virus particle except for removal of the N-terminal methionine and addition of a "blocking" group on the resulting N-terminal serine residue.

A new method for the size estimation of the RNA genome segments of influenza virus

Previous estimates of the size of the RNA genome segments of influenza virus have been unreliable because of a lack of suitable RNA species as size markers. We have attempted to overcome this problem by utilising the ability of AMV reverse transcriptase to synthesise full length DNA copies of RNA molecules in the presence of a suitable primer. By comparing such DNA copies of the RNA segments of the influenza virus genome with sequenced restriction fragments from the E. coli plasmid pBR322, we have made more reliable estimates of the sizes of the eight genome segments from influenza virus A/NT/60/68.

Segments of influenza virus complementary RNA synthesized in vitro

In the presence of Mg(2+) and a specific primer, ApG or GpG, the influenza WSN virion transcriptase synthesizes large, polyadenylic acid-containing complementary RNA (cRNA) (Plotch and Krug, J. Virol., 21:24-34, 1977). After removal of its polyadenylic acid with RNase H in the presence of polydeoxythymidylic acid, the in vitro cRNA distributed into seven discrete bands during electrophoresis in acrylamide gels containing 6 M urea. The eight known segments of virion RNA (vRNA) also distributed into seven bands under these conditions as two, rather than the expected three, large-sized segments were resolved. Each of the in vitro cRNA segments migrated slightly faster than the corresponding vRNA segment. To determine whether this difference in mobility reflects a difference in size between cRNA and vRNA, the double-stranded RNA formed by annealing labeled in vitro cRNA to unlabeled vRNA was subjected to various nuclease treatments and was analyzed by gel electrophoresis. Hybrids treated with RNase T2 or a combination of RNase T2 and RNase H migrated slightly faster than those treated only with RNase H, indicating that RNase T2 removed an RNA sequence other than polyadenylic acid, most probably a short sequence of vRNA not hydrogen bonded to cRNA. These results suggest that the in vitro cRNA segments are shorter than, and thus incomplete transcripts of the corresponding vRNA segments. All eight hybrids were resolved by gel electrophoresis, indicating that all eight vRNA segments are transcribed into cRNA in vitro. We also present evidence suggesting that the ApG primer initiates in vitro transcription exactly at the 3' end of vRNA.

Common sequence at the 5' ends of the segmented RNA genomes of influenza A and B viruses

Guanylyl- and methyltransferases, isolated from purified vaccinia virus, were used to specifically label the 5' ends of the genome RNAs of influenza A and B viruses. All eight segments were labeled with [alpha-(32)P]guanosine 5'-triphosphate or S-adenosyl[methyl-(3)H]methionine to form "cap" structures of the type m(7)G(5')pppN(m)-, of which unmethylated (p)ppN- represents the original 5' end. Further analyses indicated that m(7)G(5')pppA(m), m(7)G(5')pppA(m)pGp, and m(7)G(5')pppA(m)pGpUp were released from total and individual labeled RNA segments by digestion with nuclease P1, RNase T1, and RNase A, respectively. Consequently, the 5'-terminal sequences of most or all individual genome RNAs of influenza A and B viruses were deduced to be (p)ppApGpUp. The presence of identical sequences at the ends of RNA segments of both types of influenza viruses indicates that they have been specifically conserved during evolution.

Influenza virion transcriptase: synthesis in vitro of large, polyadenylic acid-containing complementary RNA

The influenza virion transcriptase is capable of synthesizing in vitro complementary RNA (cRNA) that is similar in several characteristics to the cRNA synthesized in the infected cell, which is the viral mRNA. Most of the in vitro cRNA is large (approximately 2.5 X 10(5) to 10(6) daltons), similar in size to in vivo cRNA. The in vitro transcripts initiate in adenosine (A) or guanosine (G) at the 5' end, as also appears to be the case with in vivo cRNA (R.M. Krug et al., 1976). The in vitro transcripts contain covalently linked polyadenylate [poly(A)] sequences, which are longer and more heterogeneous than the poly(A) sequences found on in vivo cRNA. The synthesis in vitro of cRNA with these characteristics requires both the proper divalent cation, Mg2+, and a specific dinulceside monophosphage (DNMP), ApG or GpG. These DNMPs stimulate cRNA synthesis about 100-fold in the presence of Mg2+ and act as primers to initiate RNA chains, as demonstrated by the fact that the 5'-phosphorylated derivatives of these DNMP's, 32pApG or 32pGpG, are incroporated at the 5' end of the product RNA. The RNA synthesized in vitro differs from in vivo cRNA in that neither capping nor methylation of the in vitro transcripts has been detected. The virion does contain a methylase activity, as shown by its ability to methylate exogenous methyl-deficient Escherichia coli tRNA.

Influenza viral mRNA contains internal N6-methyladenosine and 5'-terminal 7-methylguanosine in cap structures

Influenza viral complementary RNA (cRNA), i.e., viral mRNA was radioactive when purified from the cytoplasmic fraction of cordycepin-treated canine kidney cells that were incubated with [methyl-3H]methionine during infection. Approximately 55 to 60% of the methyl-3H radioactivity was in internal N6-methyladenosine, a feature distinguishing this mRNA from those viral mRNA's that are known to be synthesized in the cytoplasm. The remaining methyl-3H radioactivity was in 5'-terminal cap structures that consisted of 7-methylguanosine in pyrophosphate linkage to 2'-o-methyladenosine, N6, 2'-O-dimethyladenosine, or 2'-O-methylguanosine. Methylated adenosine was the predominant penultimate nucleoside in caps, suggesting that cRNA synthesis in infected cells initiates preferentially with adenosine at the 5' end. In contrast to cRNA, influenza virion RNA segments extracted from purified virus contained mainly 5'-terminal ppA and no detectable cap structures.

Mapping of the influenza virus genome: identification of the hemagglutinin and the neuraminidase genes

Polyacrylamide gel electrophoresis of the RNA of influenza A/PR/8/34 (H0N1) and A/Hong Kong/8/68 (H3N2) viruses and recombinant viruses derived from them revealed that each contains eight RNA segments, the fourth of which codes for hemagglutinin. (The largest RNA of the segmented genome is counted as band 1.) The neuraminidase gene was identified as the sixth segment in the RNA pattern of influenza A/PR8 virus and as the fifth segment of A/Hong Kong virus. The molecular weights of the RNAs for the hemagglutinin and the neuraminidase genes lie in the range of 600,000-700,000.

RNAs of influenza A, B, and C viruses

The nucleic acids of influenza A, B, and C viruses were compared. Susceptibility to nucleases demonstrates that influenza C virus, just as influenza A and B viruses, possesses single-stranded RNA as its genome. The base compositions of the RNAs of influenza A, B, and influenza C virus are almost identical and comparative analysis on polyacrylamide gels shows that the genome of influenza C/GL/1167/54 virus, like that of the RNAs of influenza A and B viruses, is segmented. Eight distinct RNA bands were found for influenza A/PR/8/34 virus and for influenza B/Lee/40 virus. The RNA of influenza C/GL/1167/54 virus separated into at least four segments. The total molecular weights of the RNA of influenza A/PR/8/34 and B/Lee/40 virus were calculated to be 5.29 X 10(6) and 6.43 X 10(6), respectively. A minimum value of 4.67 X 10(6) daltons was obtained for influenza C/GL/1167/54 virus RNA. The data suggest that influenza C viruses are true members of the influenza virus group.

Differences in RNA patterns of influenza A viruses

Analysis of the segmented RNAs of influenza A viruses by electrophoresis on polyacrylamide urea slab gels has provided a method for sharper resolution of the number and migration rates of different segments than previously has been possible. Using this system, the RNA genome of influenza A/WSN (HON1) virus can be separated into seven to nine separate bands, depending on whether virus is obtained after high or low multiplicity of infection, and the genome of influenza A/PR/8 (HON1) virus can be resolved into eight bands, six of which migrate differently from comparable RNA bands of WSN virus. Comparision of the RNA patterns produced by influenza A/PR/8 (HON1) and A/England/42/72 (H8n2) virus also reveals major differences in migration speeds of different bands, and analysis of the RNAs of the RNAs of an HON2 recombinant virus derived from these two strains permits the identification of RNA segments which have been derived from one particular parent. By extension of these techniques, it may be possible to define which RNA segment codes for each viral protein and to analyze recombinant strains to identify which genes have been derived from each of its parents.

Comparative study of the electrophoretic mobility of the RNA of influenza parent and recombinant strains

The electrophoretic mobility of the RNA of Influenza viruses A/WSN, A/Singapore and their antigenic recombinants X-7 and X-9 was investigated. The genome of each virus studied consisted of seven pieces of RNA. The electrophoretic profile of the influenza virus A/WSN RNA differed from that of A/Singapore but resumbled that of the recombinant X-9 genome. The essential differences were connected with the properties of the fifth fragment of the RNA. The molecular weight of this RNA species of influenza virus A/WSN and X-9 was 5.4 X 10(5) AND 5.3 X 10(5) daltons (d) respectively. The molecular weight of the corresponding component of the influenza viruses A/Sinapore and X-7 RNA was 6.2 X 10(5) and 6.3 X 10(5)d respectively.

Purification of influenza viral complementary RNA: its genetic content and activity in wheat germ cell-free extracts

Influenza viral complementary RNA (cRNA) was purified free from any detectable virion-type RNA (vRNA), and its genetic content and activity in wheat germ cell-free extracts were examined. After phenol-chloroform extraction of cytoplasmic fractions from infected cells, poly(A)-containing viral cRNA is found in two forms: in single-stranded RNA and associated with vRNA in partially and fully double-stranded RNA. To purify single-stranded cRNA free of these double-stranded forms, it was necessary to employ, as starting material, RNA fractions in which cRNA was predominantly single stranded. Two RNA fractions were successfully employed as starting material: polyribosomal RNA and the total cytoplasmic RNA from infected cells treated with 100 mug of cycloheximide (CM) per ml at 3 h after infection. In WSN virus-infected canine kidney (MDCK) cells, the addition of CM at 3 h after infection stimulates the production of cRNA threefold and causes a very large increase in the proportion of the cytoplasmic cRNA which is single stranded; double-stranded RNA forms are greatly reduced in amount. Total cRNA was obtained by oligo(dT)-cellulose chromatography, and single-stranded cRNA was separated from double-stranded forms by Sepharose 4B chromatography. The cRNA preparation purified from polyribosomes consists of 95% single-stranded cRNA, with the remaining 5% apparently being double-stranded RNA forms. The cRNA preparation purified from CM-treated cells (CM cRNA) is even more pure: 100% of the radiolabeled RNA is single-stranded cRNA. Annealing experiments, in which a limited amount of 32P-labeled genome RNA was annealed to the cRNA, indicate that the purified cRNA contains at least 84 to 90% of the genetic information in the vRNA genome. Purified viral cRNA (CM cRNA) is very active in directing the synthesis of virus-specific proteins in wheat germ cell-free extracts.

Temperature-sensitive mutants of influenza WSN virus defective in virus-specific RNA synthesis

Influenza WSN virus temperature-sensitive (ts) mutants were examined for defects in viral complementary RNA (cRNA) synthesis. The synthesis of viral cRNA was determined by hybridizing RNA from infected cells to radiolabeled virion RNA of known specific activity. Mutants in complementation groups I and III synthesized little, or no, cRNA at the nonpermissive temperature (39.5 C). When cells infected by these mutants were incubated for 5 h at the permissive temperature (33 C) and were then shifted to 39.5 C, net synthesis of cRNA ceased. This strongly suggests that mutants in these two complementation groups possess a ts defect in the transciptase complex. Mutants in group II and group V synthesize reduced amounts of cRNA at 39.5 C. In contrast to the group I and group III mutants, cRNA synthesis in cells infected by a group II or a group V mutant continues after a shift-up. This indicated that these mutants do not possess a ts transcriptase complex and that these mutants are most probably defective in some step in the amplification of cRNA synthesis. As will be discussed, the most likely defect in these mutants is in the synthesis of virion-type RNA. These results suggest that there are two influenza viral gene functions required for transcription and most likely two additional gene functions required for RNA replication.

Analysis of a viral agent isolated from multiple sclerosis brain tissue: characterization as a parainfluenzavirus type 1

A virus originally isolated from cell cultures obtained by lysolecithin-induced fusion of human multiple sclerosis brain cells with CV-1 cells has been analyzed for its antigenic, RNA, and polypeptide compositions, and for selective biological properties. Our findings establish that this isolate, designated 6/94 virus, contains a 50S RNA genome and is, as yet, indistinguishable from Sendai virus in its antigenic and total polypeptide compositions. Despite these similarities, the 6/94 and Sendai viruses differ in certain phenotypic properties. 6/94 virus is markedly less cytocidal for chick fibroblasts, especially at 37 C and, after beta-propiolactone inactivation, it possesses a greater capacity for cell fusion and a lower toxicity than does comparably treated Sendai virus. In addition, 6/94 virus shows greater hemolytic activity.

Comparison of the 3' termini of discrete segments of the double-stranded ribonucleic acid genomes of cytoplasmic polyhedrosis virus, wound tumor virus, and reovirus

The 3' terminal nucleosides of the isolated components of double-stranded ribonucleic acids of reovirus, wound tumor virus, and cytoplasmic polyhedrosis virus were determined by labeling with tritiated sodium borohydride. All wound tumor virus and cytoplasmic polyhedrosis virus components appear to contain approximately equal amounts of U(OH) and C(OH) termini. Reovirus segments have essentially only C(OH) termini.

Isolation and preliminary characterization of temperature-sensitive mutants of influenza virus

Isolation of temperature-sensitive (ts) mutants was attempted from the WSN strain of influenza A virus which was grown and assayed in MDBK cells. After growth of wild-type virus in the presence of 5-fluorouracil, 15 ts mutants were selected for which the ratio of plaquing efficiency at 39.5 C to that at 33 C was 10(-3) or less. In pairwise crosses of ts mutants, recombination and complementation were either very efficient or undetectable. It is suggested, therefore, that the viral genome consists of physically discrete units and recombination occurs as an exchange of these units. All 15 mutants have been assigned with certainty into five recombination groups. Three mutants are suspected to be double mutants. Any two complementing mutants always recombined with each other, and noncomplementing mutants did not recombine. In physiological tests, mutants showed diverse patterns of functional defects at the nonpermissive temperature. However, it was not always possible to correlate these physiological defects with the results of genetic characterization.

Structure of the ribonucleoprotein of influenza virus

The ribonucleoprotein (RNP) internal components of influenza virus were separated into distinct size classes by sedimentation in glycerol gradients and examined by electron microscopy by using positive staining with uranyl acetate. The large RNP have a peak in length distribution at 90 to 110 nm, the medium, at 60 to 90 nm, and the small, at 30 to 50 nm. These lengths can be correlated with the estimated molecular weights of the ribonucleic acids contained in the various RNP size classes. The RNP structure appears to consist of a strand which is folded back on itself and coiled in a regular double-helical arrangement.

Polyadenylic acid at the 3'-terminus of poliovirus RNA

Poliovirus RNA that has been derivatized at the 3'-end with NaIO(4)-NaB(3)H(4) yields, after hydrolysis with alkali or RNase T2, predominantly labeled residues of modified adenosine; no labeled nucleoside derivative is produced by digestion with RNase A or RNase T1. The 3'-terminal bases of the RNA are, therefore,...ApA(OH). Hydrolyzates of poliovirus [(32)P]RNA, after exhaustive digestion with RNase T1 or RNase A, contain, besides internal oligonucleotides, polynucleotides resistant to further action of ribonucleases T1 and A, respectively; these polynucleotides were isolated by membrane-filter binding or ion-exchange chromatography. The sequence of the T1-resistant polynucleotide was determined to be (Ap)(n)A(OH), that of the RNase A-resistant polynucleotide was GpGp(Ap)(n)A(OH). The chain length (n) of the polyadenylic acid, as analyzed by different methods, averages 89 nucleotides. Gel electrophoresis revealed heterogeneity of the size of poly(A). Poliovirus RNA, when labeled in vitro at the 3'-end, contains [3'-(3)H]poly(A); when labeled in vivo with [(3)H]A, it contains [(3)H](Ap)(n)A(OH). The data establish that... YpGpGp(Ap)([unk])A(OH) is the 3'-terminal sequence of poliovirus RNA, Type 1 (Mahoney). Since this mammalian virus reproduces in the cell cytoplasm, these observations may modify prior interpretations of the function of polyadenylate ends on messenger RNAs.

The 3'-terminal nucleosides of the high molecular weight RNA of avian myeloblastosis virus

The RNA isolated from avian myeloblastosis virus was fractionated by sucrose density gradient centrifugation. The 3'-OH terminal nucleosides of various fractions were determined by periodate oxidation followed by tritiated borohydride reduction. The 60-70S fraction and the 35S RNA derived from it by heating both have adenosine as the major terminal nucleoside, with cytidine as the next most frequent terminal. Control samples of tRNA(met) (f. coli) and 28S ribosomal RNA from mouse ascites tumor cells gave the expected terminal residues and molecular weights.