A functional ribonucleoprotein complex forms around the 5' end of poliovirus RNA

The existence of a computer-predicted cloverleaf structure for the first 100 nucleotides at the 5' end of poliovirus RNA was verified by site-directed mutagenesis and by chemical and RNAase probing. Mutations that modified the cloverleaf in the positive strand but not the negative strand were lethal to the virus. This RNA cloverleaf structure binds a cellular protein and the viral proteins 3Cpro and 3Dpol. Mutations in specific regions of the RNA cloverleaf prevented this binding. Mutations in either 3Cpro or the RNA that disrupted ribonucleoprotein complex formation inhibited virus growth and selectively affected positive strand RNA accumulation. Phenotypic reversion of these mutations restored the ability to form the complex. Thus, a cloverleaf structure in poliovirus RNA plays a central role in organizing viral and cellular proteins involved in positive strand production.     

BALB/3T3 cells infected by the ts3 mutant of polyoma virus fail to accumulate virus-specific early RNA at the nonpermissive temperature.

We measured the accumulation of virus-specific early RNA in BALB/3T3 cells infected by the ts3 mutant of polyoma virus by annealing cytoplasmic RNA from infected cells to purified, radiolabeled, "early" strand of polyoma DNA. Cells infected by the ts3 mutant fail to accumulate virus-specific early RNA at the nonpermissive temperature.     

Native replication intermediates of the yeast 20 S RNA virus have a single-stranded RNA backbone

20 S RNA virus is a positive strand RNA virus found in Saccharomyces cerevisiae. The viral genome (2.5 kb) only encodes its RNA polymerase (p91) and forms a ribonucleoprotein complex with p91 in vivo. A lysate prepared from 20 S RNA-induced cells showed an RNA polymerase activity that synthesized the positive strands of viral genome. When in vitro products, after phenol extraction, were analyzed in a time course, radioactive nucleotides were first incorporated into double-stranded RNA (dsRNA) intermediates and then chased out to the final single-stranded RNA products. The positive and negative strands in these dsRNA intermediates were non-covalently associated, and the release of the positive strand products from the intermediates required a net RNA synthesis. We found, however, that these dsRNA intermediates were an artifact caused by phenol extraction. Native replication intermediates had a single-stranded RNA backbone as judged by RNase sensitivity experiments, and they migrated distinctly from a dsRNA form in non-denaturing gels. Upon completion of RNA synthesis, positive strand RNA products as well as negative strand templates were released from replication intermediates. These results indicate that the native replication intermediates consist of a positive strand of less than unit length and a negative strand template loosely associated, probably through the RNA polymerase p91. Therefore, W, a dsRNA form of 20 S RNA that accumulates in yeast cells grown at 37 degrees C, is not an intermediate in the 20 S RNA replication cycle, but a by-product.     

Assembly of double-stranded RNA viruses: bacteriophage ø6 and yeast virus L-A

Double-stranded RNA viruses have a virion-associated RNA-dependent RNA polymerase activity which is involved in such critical steps of viral assembly as genome packaging and minus strand synthesis. In vitro studies of a bacterial dsRNA virus, ø6, and a yeast virus, L-A, have shed light on capsid formation as well as on the protein/RNA interactions and packaging of the viral genomes. In the ø6 system, an empty dodecahedral polymerase complex (procapsid) composed of four protein species is formed without the help of other viral proteins or RNA. This particle packages positive sense viral RNA genome segments in an ATP dependent reaction. The presence of all rNTPs allows the synthesis of complementary (-) strands within the particle. Self-assembly of an additional protein shell (composed of protein P8) around this particle takes place in the presence of Ca²⁺ ions. In vivo, these nucleocapsids obtain an envelope while still residing in the cell cytoplasm. L-A, in contrast, is not known to make a prohead structure. The Pol domain of L-A's Gag-Pol fusion protein is necessary for packaging of the (+) strand RNA and probably actually binds to the (+) strand packaging site (a stem-loop with a protruding A) insuring its packaging while the Gag domain primes polymerization of the coat protein. N-Acetylation of Gag by the host MAK3 N-acetyltransferase is necessary for proper assembly, and the ratio of Gag-Pol/Gag, determined by the efficiency of - 1 ribosomal frameshifting, is critical for propagation of the M₁ satellite dsRNA.     

特异切割苹果锈果类病毒的核酶基因的克隆和转录物的体外活性测定

根据锤头型核酶的作用模式 ,设计、合成和克隆了特异切割苹果锈果类病毒ASSVd正链 (194-196位点 )或负链 (89- 91位点 )RNA的 2个短臂锤头型核酶基因 :42nt的RzASSVd(+)和 40nt的RzASSVd(- )。经转录获得核酶转录物和³²P标记的ASSVd正、负链转录物。将核酶与ASSVd混合 ,50℃或 37℃保温 3～ 4h ,进行 8%PAGE(含8mol L尿素 )和放射自显影分析。体外切割检测表明 :2个核酶均具有特异切割活性 ,其中RzASSVd(- )对ASSVd负链的切割活性较高 ,对ASSVd正链不起作用。RzASSVd(+)对ASSVd正链的切割活性较弱 ,对ASSVd负链亦不起作用。在此基础上 ,构建得到双价核酶基因pGEMRzASSVd(± )。     

Adenovirus type 12-specific RNA sequences during productive infection of KB cells.

The complementary strands of adenovirus type 12 DNA were separated, and virus-specific RNA was analyzed by saturation hybridization in solution. Late during infection whole cell RNA hybridized to 75% of the light (1) strand and 15% of the heavy (H) strand, whereas cytoplasmic RNA hybridized to 65% of the 1 strand and 15% of the h strand. Late nuclear RNA hybridized to about 90% of the 1 strand and at least 36% of the h strand. Double-stranded RNA was isolated from infected cells late after infection, which annealed to greater than 30% of each of the two complementary DNA strands. Early whole cell RNA hybridized to 45 to 50% of the 1 strand and 15% of the h strand, whereas early cytoplasmic RNA hybridized to about 15% of each of the complementary strands. All early cytoplasmic sequences were present in the cytoplasm at late times.     

In vitro synthesis of full-length influenza virus complementary RNA.

Influenza virus-specific RNA has been synthesized in vitro, using cytoplasmic or microsomal fractions of influenza virus-infected MDCK cells. The RNA polymerase activity was stimulated 5-30 times by priming with ApG. About 20-30% of the product was polyadenylated. Most of the in vitro product was of positive polarity, as shown by hybridization to strand specific probes and by T1 fingerprinting of the poly(A)+ and poly(A)- RNA segments encoding haemagglutinin and nucleoprotein. The size of poly(A)- RNA segments, determined on sequencing gels, was indistinguishable from that of virion RNA, whereas poly(A)+ RNA segments contain poly(A) tails approximately 50 nucleotides long. The size of in vitro synthesized RNA segments was also determined by gel electrophoresis of S1-treated double-stranded RNAs, obtained by hybridization of poly(A)+ or poly(A)- RNA fractions with excess of unlabelled virion RNA. The results of these experiments indicate that poly(A)- RNA contains full-length complementary RNA. This conclusion is further substantiated by the presence of additional oligonucleotides in the T1 fingerprints of in vitro synthesized poly(A)- haemagglutinin or nucleoprotein RNA, selected by hybridization to cloned DNA probes corresponding to the 3' termini of the genes.     

Lack of evidence for hepatitis G virus replication in the livers of patients coinfected with hepatitis C and G viruses.

The pathogenic implications of hepatitis G virus (HGV) infection are still unclear. We searched for the presence of HGV RNA and HCV RNA sequences in liver and serum samples from 10 patients with chronic liver disease, 9 of whom were coinfected with HCV. All livers were negative for the presence of the HGV RNA minus strand and only six were positive for the presence of the positive strand, albeit at low levels. In striking contrast, the HCV RNA positive strand was detectable in the liver samples from all nine HCV-positive patients in titers ranging from 10(2) to 10(8) genomic eq/microg of RNA, and the negative HCV RNA strand was present in all but two of these patients. However, the positive-strand RNA titers in serum for the two viruses had similar ranges. These findings imply that the liver is not the primary replication site for HGV, at least in the population of HCV/HGV-coinfected patients. Absence of replication in liver tissue may explain the reported lack of influence of HGV coinfection on the course of chronic hepatitis C.     

Poliovirus RNA replication requires genome circularization through a protein-protein bridge.

The mechanisms and factors involved in the replication of positive stranded RNA viruses are still unclear. Using poliovirus as a model, we show that a long-range interaction between ribonucleoprotein (RNP) complexes formed at the ends of the viral genome is necessary for RNA replication. Initiation of negative strand RNA synthesis requires a 3' poly(A) tail. Strikingly, it also requires a cloverleaf-like RNA structure located at the other end of the genome. An RNP complex formed around the 5' cloverleaf RNA structure interacts with the poly(A) binding protein bound to the 3' poly(A) tail, thus linking the ends of the viral RNA and effectively circularizing it. Formation of this circular RNP complex is required for initiation of negative strand RNA synthesis. RNA circularization may be a general replication mechanism for positive stranded RNA viruses.     

Synthesis and localization of Japanese encephalitis virus RNAs in the infected cells

Synthesis and localization of virus-specific RNA in cells infected with Japanese encephalitis virus (JEV) were examined. To prepare specific RNA probes, we constructed four kinds of plasmids which contained DNA fragments corresponding to JEV genomic RNA. Minus probes, JT18V and JT19III, transcribed by T7 RNA polymerase were able to recognize a negative strand of JEV-specific RNA synthesized in cells as early as 6 hr postinfection (p.i.). In the experiments using a plus-strand probe JT19V to hybridize the 3' end of JEV-RNA, not only full-length 42S(+) RNA but also 10S(+) RNA were detected in the infected cells at 24 hr p.i. The positive-strand 42S RNA was found in much greater abundance in the membrane fraction than in the supernatant fraction of the infected cells. In contrast, larger amounts of the negative-strand RNAs existed in the supernatant fraction. It is suggested from the data that the JEV-specific negative- and positive-strand RNAs accumulate at different sites in the infected cells.     

Significance in replication of the terminal nucleotides of the flavivirus genome

Point mutations that resulted in a substitution of the conserved 3'-penultimate cytidine in genomic RNA or the RNA negative strand of the self-amplifying replicon of the Flavivirus Kunjin virus completely blocked in vivo replication. Similarly, substitutions of the conserved 3'-terminal uridine in the RNA negative or positive strand completely blocked replication or caused much-reduced replication, respectively. The same preference for cytidine in the 3'-terminal dinucleotide was noted in reports of the in vitro activity of the RNA-dependent RNA polymerase (RdRp) for the other genera of Flaviviridae that also employ a double-stranded RNA (dsRNA) template to initiate asymmetric semiconservative RNA positive-strand synthesis. The Kunjin virus replicon results were interpreted in the context of a proposed model for initiation of RNA synthesis based on the solved crystal structure of the RdRp of phi6 bacteriophage, which also replicates efficiently using a dsRNA template with conserved 3'-penultimate cytidines and a 3'-terminal pyrimidine. A previously untested substitution of the conserved pentanucleotide at the top of the 3'-terminal stem-loop of all Flavivirus species also blocked detectable in vivo replication of the Kunjin virus replicon RNA.     

RNA recombination in brome mosaic virus: effects of strand-specific stem-loop inserts

A model system of a single-stranded trisegment Brome mosaic bromovirus (BMV) was used to analyze the mechanism of homologous RNA recombination. Elements capable of forming strand-specific stem-loop structures were inserted at the modified 3' noncoding regions of BMV RNA3 and RNA2 in either positive or negative orientations, and various combinations of parental RNAs were tested for patterns of the accumulating recombinant RNA3 components. The structured negative-strand stem-loops that were inserted in both RNA3 and RNA2 reduced the accumulation of RNA3-RNA2 recombinants to a much higher extent than those in positive strands or the unstructured stem-loop inserts in either positive or negative strands. The use of only one parental RNA carrying the stem-loop insert reduced the accumulation of RNA3-RNA2 recombinants even further, but only when the stem-loops were in negative strands of RNA2. We assume that the presence of a stable stem-loop downstream of the landing site on the acceptor strand (negative RNA2) hampers the reattachment and reinitiation processes. Besides RNA3-RNA2 recombinants, the accumulation of nontargeted RNA3-RNA1 and RNA3-RNA3 recombinants were observed. Our results provide experimental evidence that homologous recombination between BMV RNAs more likely occurs during positive- rather than negative-strand synthesis.