Polyoma virus giant RNAs contain tandem repeats of the nucleotide sequence of the entire viral genome.

The bulk of late virus-specific RNA synthesized in polyoma virus-infected mouse cells is larger than a single strand of poloma DNA. The arrangement of viral nucleotide sequences in these giant polyoma RNAs was studied by electron microscopy of hybrids between purified high molecular weight viral RNA and the HindII-1 fragment of polyoma DNA, which contains 91% of the viral genome. Hybrid molecules containing a short single-stranded gap (corresponding to the 9% of viral sequences not present in HindII-1), flanked by double-stranded regions, were photographed and measured. The majority of hybrid molecules contained no single-stranded loops or branches, showing that all viral sequences are transcribed contiguously and that no nonviral sequences are present in the RNA. Hybrid molecules, containing RNA up to 3.5 times the genome length, had a repeating structure of single-stranded gaps 8% of genome length interspersed with double-stranded regions 89% of genome length, showing that giant polyoma RNAs contain tandem repeats of the nucleotide sequence of the entire viral DNA. A small proportion of hybrid molecules contained single-stranded branches or deletion loops in characteristic positions, indicating that RNA "splicing" may occur on high molecular weight nuclear polyoma RNA.     

RNA interference--small RNAs effectively fight viral hepatitis.

RNA interference (RNAi) is the process of sequence-specific gene silencing, initiated by double-stranded RNA that is homologous in sequence to the target gene. This unique phenomenon has been extensively investigated during the last few years not only in the context of its mechanism and its possible role in the regulation of gene expression and cell function, but also as a potential powerful tool for gene therapy. Targeting essential viral genes or oncogenic alleles are only some of the possible applications of RNAi in the field of gene-directed therapy. This review covers the potential use of RNAi against hepatitis B and hepatitis C viruses, the main pathogens causing chronic liver disease. The major milestones along the discovery of RNAi will also be covered.     

Methylation-dependent translation of viral messenger RNAs in vitro.

Methylated reovirus and vesicular stomatitis virus mRNAs, synthesized in vitro in the presence of S-adenosylmethionine by the virion-associated polymerases (RNA nucleotidyltransferases, EC 2.7.7.6), stimulate protein synthesis by wehat germ extracts to a greater extent than unmethylated mRNAs. Addition of S-adenosylmethionine to a cell-free extract programmed with unmethylated mRNA stimulates protein synthesis and results in methylation of the mRNA. An inhibitor of mRNA methylation. S-adenosylhomocysteine, blocks translation of unmethylated, but not of methylated, mRNAs. Aurintricarboxylic acid, which inhibits polypepetide chain initiation, also prevents mRNA methylation by wheat germ extracts. In contrast, sparsomycin, which inhibits polypeptide chain elongation, does not reduce mRNA methylation. The results indicate that methylation of viral mRNA is required for translation in vitro and suggest that mRNA methylation occurs at the initiation step of protein synthesis.     

Sequence relationships among defective interfering influenza viral RNAs.

Each clone of ts-52 and ts+ WSN influenza virus, when serially passaged at high multiplicity, gives rise to defective interfering (DI) virus with a unique set of new RNA species. The new RNAs (DI RNA) from several DI viruses were examined by the technique of RNase T1 oligonucleotide two-dimensional electrophoresis. It was found that each DI RNA arises from a specific segment of standard viral RNA. All DI RNA studied arose from the viral polymerase genes (P1, P2, and P3). DI RNAs originating from the same polymerase gene were interrelated. Certain of these DI RNAs appeared to contain completely overlapping nucleotide sequences. Others contained both overlapping and nonoverlapping nucleotide sequences. The latter DI RNAs may be formed from the progenitor viral RNA segment by a mechanism other than a common initiation (or termination) point and a simple deletion from one end.     

Engineered defective interfering RNAs of Sindbis virus express bacterial chloramphenicol acetyltransferase in avian cells.

We are investigating the feasibility of using the positive-strand RNA virus Sindbis virus and its defective interfering (DI) particles as vectors for introducing foreign genes into cells. In previous work we showed by deletion mapping of a cloned cDNA derived from one of the DI RNAs that only nucleotides at the 3' and 5' termini of the RNA are essential for the DI RNA to be amplified after it is transfected into cells in the presence of helper virus. As a first step in developing a vector we replaced 75% of the internal nucleotides of this DI cDNA with foreign sequences including the bacterial chloramphenicol acetyltransferase (CAT; EC 2.3.1.28) gene. DI RNAs transcribed from this cDNA were replicated and packaged by helper Sindbis virus and became a major viral RNA species in infected cells by the third passage after transfection. They were also translated to produce enzymatically active CAT. CAT activity was measured at passage 3 but could also be detected in transfected cells. DI RNAs containing the CAT gene were translated in vivo and in vitro to produce two polypeptides immunoprecipitable by anti-CAT antibodies. One polypeptide was identical in size to the authentic CAT polypeptide; the other was the size expected for a protein initiated at an upstream, viral-specific AUG in frame with the CAT AUG. These studies establish that DI genomes of Sindbis virus can tolerate the insertion and direct the expression of at least one foreign gene.     

Evidence for crossing-over between avian tumor viruses based on analysis of viral RNAs

The RNAs of several avian tumor virus recombinants that had inherited their focus-forming ability from a sarcoma virus and their host range marker from a leukosis virus were investigated. Electrophoretic analyses showed that the cloned sarcoma virus recombinants contained only size class a RNA, although they had acquired a marker that resided on class b RNA in the leukosis virus parent. Class a RNA of different recombinant clones, derived from the same pair of parental viruses and selected for the same biological markers, differed slightly in electrophoretic mobility from each other and from the parental sarcoma virus. They were also found to have different fingerprints of RNase T1-resistant oligonucleotides.The average complexity of the 60-70S RNA prepared from Prague Rous sarcoma virus of subgroup B was estimated to be 3.5 x 10(6) daltons from the size of 20 RNase T1-resistant oligonucleotides, which represented 3.9% of the RNA and that of a recombinant to be 3.3 x 10(6) daltons from 23 oligonucleotides, which represented 4.7% of the RNA. This result suggests that the genome of wild-type and of recombinant RNA tumor viruses is polyploid.The sum of these observations led us to propose that recombination among avian tumor viruses occurred by crossing-over between homologous pieces of nucleic acid.     

The conserved lysine 151 of HCV NS5B modulates viral genome replication and infectious virus production

Summary. Hepatitis C virus (HCV) nonstructural protein 5B (NS5B) is an RNA‐dependent RNA polymerase (RdRp) that is involved in genome replication and virus assembly. NS5B contains a distinct loop (loop Λ2) at the beginning of the nucleoside triphosphate tunnel with a highly conserved lysine (K151). In this study, reverse genetic analysis revealed that substitution of Jc1 NS5B K151 for alanine (K151A) and aspartic acid (K151D) affected genome replication and infectious virus production. However, genome replication and virus production by Jc1 containing NS5B K151R remained unaltered. A major deletion in loop Λ2 abolished RNA replication, suggesting a role for this structural domain in NS5B polymerase activity. In conclusion, this study demonstrated that the conserved K151 modulates infectious virus production; and loop Λ2 is essential for the polymerase activity of NS5B.     

Complementation of a red-light-indifferent cyanobacterial mutant.

Many cyanobacteria alter their phycobilisome composition in response to changes in light wavelength in a process termed complementary chromatic adaptation. Mutant strains FdR1 and FdR2 of the filamentous cyanobacterium Fremyella diplosiphon are characterized by aberrant chromatic adaptation. Instead of adjusting to different wavelengths of light, FdR1 and FdR2 behave as if they are always in green light; they do not respond to red light. We have previously reported complementation of FdR1 by conjugal transfer of a wild-type genomic library. The complementing DNA has now been localized by genetic analysis to a region on the rescued genomic subclone that contains a gene designated rcaC. This region of DNA is also able to complement FdR2. Southern blot analysis of genomic DNA from FdR1 and FdR2 indicates that these strains harbor DNA insertions within the rcaC sequence that may have resulted from the activity of transposable genetic elements. The predicted amino acid sequence of RcaC shares strong identity to response regulators of bacterial two-component regulatory systems. This relationship is discussed in the context of the signal-transduction pathway mediating regulation of genes encoding phycobilisome polypeptides during chromatic adaptation.     

Missense mutations in an infectious human immunodeficiency viral genome: functional mapping of tat and identification of the rev splice acceptor.

Single nucleotide alterations were introduced into an infectious clone of human immunodeficiency virus type 1 to create a series of missense mutants in the tat coding region. Although mutations in a proline-rich region and a basic lysine-arginine-rich region resulted in wild-type phenotypes, five of six mutations in a cysteine-rich domain completely abolished tat activity and virus replication. One cysteine mutant retained tat activity but was negative for virus expression. Surprisingly, this mutant could not be complemented by tat, and virus expression was restored only by cotransfection with a plasmid expressing the rev gene. Another mutant with an alteration toward the C-terminal region showed significantly reduced tat activity and required complementation by a combination of tat and rev for virus replication. Further analysis revealed that a previously unrecognized splice acceptor site within this region, apparently used to generate the rev mRNA, had been altered. We provide evidence suggesting that tat and rev proteins are encoded by distinct mRNA species.     

Microinjection analysis of envelope-glycoprotein messenger activities of avian leukosis viral RNAs.

Virion RNA from the avian leukosis virus Rous-associated virus 2 (RAV-2) and poly(A)-containing RNAs from RAV-2-infected chick embryo fibroblasts were microinjected into fibroblasts transformed by the Bryan high-titer strain of Rous sarcoma virus (RSV), which is deficient in viral envelope glycoprotein. Production of infectious RSV following these injections depended upon the viral envelope-messenger activity of the injected RNA. This system constituted a sensitive and rigorous assay system for viral envelope-messenger RNA. It was found that 21S mRNA from RAV-2-infected cells expressed the highest activity, while 35S mRNA expressed comparatively little. In addition, RAV-2-virion RNA expressed little messenger activity. The rate of formation of infectious RSV following 21S mRNA injections reached a peak near 9 hr, which was followed by a rapid decline. Evidence has been obtained that a small fraction of both 35S virion RNA and 35S mRNA from virus-infected cells was encapsulated into virus particles following their injection into virus-producing cells.     

Abundant pseudogenes for small nuclear RNAs are dispersed in the human genome.

We have cloned and partially characterized 24 loci from the human genome which are complementary to U1, U2, or U3, the three major species of small nuclear RNA (snRNA) in HeLa cells. When compared to the known U1 (human) and U2 (rat) snRNA sequences, the DNA sequences we report here for the complementary regions from two of the clones, U1.11 and U2.7, reveal the presence of truncated and divergent gene copies. Furthermore, most if not all of the 24 cloned loci contain gene copies that are significantly divergent from the homologous HeLa snRNA species because DNA from every recombinant phage except U1.7 and U1.15 proved unable to form snRNA.DNA hybrids which protect full-length HeLa snRNA from ild digestion with ribonuclease T1. Hence, we refer to these loci as snRNA pseudogenes. In both clones U1.11 and U2.7, an element of the dominant middle repetitive DNA sequence family in the human genome, the Alu family, is located upstream from the snRNA pseudogene and in the same orientation. Alu elements in the same location and orientation relative to bona fide genes have previously been found in the human beta-globin gene cluster [Duncan, C. H., Biro, P. A., Choudary, P. V., Elder, J. T., Wang, R. C., Forget, G. B., deRiel, J. K. & Weissman, S. M. (1979) Proc. Natl. Acad. Sci. USA 76, 5095-5099]. We discuss the significance of these findings in relation to the nature of snRNA multigene families and other reported examples of pseudogenes.     

Deletion of the E4 region of the genome produces adenovirus DNA concatemers.

Two mutants containing large deletions in the E4 region of the adenovirus genome H5dl366 (91.9-98.3 map units) and H2dl808 (93.0-97.1 map units) were used to investigate the role of E4 genes in adenovirus DNA synthesis. Infection of KB human epidermoid carcinoma cells with either mutant resulted in production of large concatemers of viral DNA. Only monomer viral genome forms were produced, however, when mutants infected W162 cells, a monkey kidney cell line transformed with and expressing the E4 genes. Diffusible E4 gene products, therefore, complement the E4 mutant phenotype. The viral DNA concatemers produced in dl366- and dl808-infected KB cells did not have any specific orientation of monomer joining: the junctions consisted of head-to-head, head-to-tail, and tail-to-tail joints. The junctions were covalently linked molecules, but molecules were not precisely joined, and restriction enzyme maps revealed a heterogeneous size distribution of junction fragments. A series of mutants that disrupted single E4 open reading frames (ORFs) was also studied: none showed phenotypes similar to that of dl366 or dl808. Mutants containing defects in both ORF3 and ORF6, however, manifested the concatemer phenotype, indicating redundancy in genes preventing concatemer formation. These data suggest that the E4 ORFs 3 and 6 express functions critical for regulation of viral DNA replication and that concatemer intermediates may exist during adenovirus DNA synthesis.     

Characteristics of hepatitis C viral genome associated with disease progression

The clinical presentations of chronic hepatitis C are not uniform. Some patients show persistently high serum alanine transaminase (ALT) values and develop liver cirrhosis and hepatocellular carcinoma (HCC), whereas serum ALT values stay normal in other patients. The mechanism causing this diversity remains to be elucidated. The aim of this study was to identify genomic characteristics of hepatitis C virus (HCV) genotype 1b associated with disease progression. Full length sequences of HCV were determined in 14 patients who showed persistently normal serum ALT values (normal ALT group) and 13 cirrhotics with HCC (HCC group). Residues in which amino acid usage was different between these 2 groups were extracted, and Progression score was defined as the total number of residues with 7 amino acids, more frequently present in the HCC group than in the normal ALT group. In the validation of this Progression score in 9 patients with normal ALT and 25 with HCC, the score was significantly higher in the HCC group (3.1 +/- 1.1 vs. 2.0 +/- 0.9, P =.019). Finally, the correlation between the score and clinical markers related to disease progression was analyzed. In a total of 107 patients with chronic HCV infection, the Progression score was correlated significantly with platelet counts (r = -0.31, P =.0024) by multivariate analysis. In conclusion, high Progression scores were associated with the presence of HCC and low platelet counts. Sequences of the HCV-1b genome may be related to the progression of chronic hepatitis C.