Nonhomologous RNA-RNA recombination events at the 3' nontranslated region of the Sindbis virus genome: hot spots and utilization of nonviral sequences.

The mechanism of RNA-RNA recombination at the 3' nontranslated region (3'NTR) of the Sindbis virus (SIN) genome was studied by using nonreplicative RNA precursors. The 11.7-kb SIN genome was transcribed in vitro as two nonoverlapping RNA fragments. RNA-1 contained the entire 11.4-kb protein coding sequence of SIN and also carried an additional 1.8-kb nonviral sequence at its 3' end. RNA-2 carried the remaining 0.26 or 0.3 kb of the SIN genome containing the 3'NTR. Transfection of these two fragments into BHK cells resulted in vivo RNA-RNA recombination and release of infectious SIN recombinants. Eighteen plaque-purified recombinant viruses were sequenced to precisely map the RNA-RNA crossover sites at the 3'NTR. Sixteen of the 18 recombinants were found to be genetically heterogeneous at the 3'NTR. Two major clustered sites within the 3'NTR of RNA-2 were found to be fused to multiple locations on the nonviral sequence of RNA-1, resulting in insertions of 10 to 1,085 nucleotides at the 3'NTR. Sequence analysis of crossover sites suggested only limited homology and heteroduplex-forming capability between substrate RNAs. Analysis of additional 23 recombinant viruses generated by mutagenized donor and acceptor templates supports the occurrence of recombination hot spots on donor templates. Introduction of a 17-nucleotide rudimentary replicase recognition signal in the acceptor template alone did not induce the polymerase to reinitiate at the 17-nucleotide signal. Interestingly, deletion of a 24-nucleotide hot spot locus on the donor template abolished crossover events at one of the two sites and allowed the polymerase to reinitiate at the 17-nucleotide replicase recognition signal inserted at the acceptor template. The possible roles of RNA-protein and RNA-RNA interactions in the differential regulation of apparent pausing, template selection, and reinitiation are discussed.     

Studies of defective interfering RNAs of Sindbis virus with and without tRNAAsp sequences at their 5'' termini.

Three of six independently derived defective interfering (DI) particles of Sindbis virus generated by high-multiplicity passaging in cultured cells have tRNAAsp sequences at the 5' terminus of their RNAs (Monroe and Schlesinger, J. Virol. 49:865-872, 1984). In the present work, we found that the 5'-terminal sequences of the three tRNAAsp-negative DI RNAs were all derived from viral genomic RNA. One DI RNA sample had the same 5'-terminal sequence as the standard genome. The DI RNAs from another DI particle preparation were heterogeneous at the 5' terminus, with the sequence being either that of the standard 5' end or rearrangements of regions near the 5' end. The sequence of the 5' terminus of the third DI RNA sample consisted of the 5' terminus of the subgenomic 26S mRNA with a deletion from nucleotides 24 to 67 of the 26S RNA sequence. These data showed that the 5'-terminal nucleotides can undergo extensive variations and that the RNA is still replicated by virus-specific enzymes. DI RNAs of Sindbis virus evolve from larger to smaller species. In the two cases in which we followed the evolution of DI RNAs, the appearance of tRNAAsp-positive molecules occurred at the same time as did the emergence of the smaller species of DI RNAs. In pairwise competition experiments, one of the tRNAAsp-positive DI RNAs proved to be the most effective DI RNA, but under identical conditions, a second tRNAAsp-positive DI RNA was unable to compete with the tRNAAsp-negative DIs. Therefore, the tRNAAsp sequence at the 5' terminus of a Sindbis DI RNA is not the primary factor in determining which DI RNA becomes the predominant species in a population of DI RNA molecules.     

Sequence analysis of cDNA''s derived from the RNA of Sindbis virions and of defective interfering particles

Sindbis virus generates defective interfering (DI) particles during serial high-multiplicity passage in cultured cells. These DI particles inhibit the replication of infectious virus and can be an important factor in the establishment and maintenance of persistent infection in BHK cells. In an effort to understand how these DI particles are generated and how they interfere with the replication of standard virus, we performed a partial sequence analysis of the RNA obtained from two independently isolated populations of DI particles and from two Sindbis virus variants and compared these with the RNA of the parental wild-type virus. The 3'-terminal regions of the RNAs were sequenced by the dideoxy chain terminating method. Internal regions of the RNA were examined by restriction endonuclease digestion of cDNA's made to the various RNAs and by direct chemical sequencing of 5' end-labeled restriction fragments from cDNA made to the DI RNAs. One of the variant viruses examined was originally derived from cells persistently infected with Sindbis virus for 16 months and is resistant to interference by the DI strains used. In the 3'-terminal region of the RNA from this variant, only two base changes were found; one of these occurs in the 20-nucleotide 3'-terminal sequence which is highly conserved among alphaviruses. The DI RNA sequences were found to have been produced not by a single deletional event, but by multiple deletion steps combined with sequence rearrangements; all sequences examined are derived from the plus strand of Sindbis virion RNA. Both DI RNAs had at least 50 nucleotides of wild-type sequence conserved at the 3' terminus; in addition, they both contained conserved and perhaps amplified sequences derived from the non-26S region of the genome which may be of importance in their replication and interference ability.     

戊型肝炎病毒亚基因组RNA的研究

本文利用同位素代谢标记在HEV感染85～10.5,6.5～7.5h分别检测到1及2个亚基因组RNA,而感染21h后及在成熟的病毒颗粒内未能检测到亚基因组RNA。通过杂交实验,发现HEV的亚基因组RNA具有典型的共3′端的半套式结构,且基因组RNA与亚基因组RNA的5′端不存在共同的引导序列。通过紫外转录图谱发现HEV的亚基因组RNA是通过独立转录的方式产生的。利用引物延伸反应发现两种亚基因组RNA的转录起始位点分别位于RNA聚合酶区及非结构区、结构区的基因间序列。     

Coronavirus multiplication strategy. II. Mapping the avian infectious bronchitis virus intracellular RNA species to the genome.

Avian infectious bronchitis virus, a coronavirus, directed the synthesis of six major single-stranded polyadenylated RNA species in infected chicken embryo kidney cells. These RNAs include the intracellular form of the genome (RNA F) and five smaller RNA species (RNAs A, B, C, D, and E). Species A, B, C, and D are subgenomic RNAs and together with the genome form a nested sequence set, with the sequences of each RNA contained within every larger RNA species (D. F. Stern and S. I. T. Kennedy, J. Virol 34:665-674, 1980). In the present paper we show by RNase T1 oligonucleotide fingerprinting that RNA E is also a member of the nested set. Partial alkaline fragmentation of the genome followed by sucrose fractionation, oligodeoxythymidylate-cellulose chromatography, and RNase T1 fingerprinting gave a partial 3'-to-5' oligonucleotide spot order. A comparison of the oligonucleotides of each of the five subgenomic RNAs with this spot order established that all of the RNAs are comprised of nucleotide sequences inward from the 3' end of the genome. This result is discussed in relation to the multiplication strategy both of coronaviruses and of other RNA-containing viruses.     

Double subgenomic alphaviruses expressing multiple fluorescent proteins using a Rhopalosiphum padi virus internal ribosome entry site element

Double subgenomic Sindbis virus (dsSINV) vectors are widely used for the expression of proteins, peptides, and RNA sequences. These recombinant RNA viruses permit high level expression of a heterologous sequence in a wide range of animals, tissues, and cells. However, the alphavirus genome structure and replication strategy is not readily amenable to the expression of more than one heterologous sequence. The Rhopalosiphum padi virus (RhPV) genome contains two internal ribosome entry site (IRES) elements that mediate cap-independent translation of the virus nonstructural and structural proteins. Most IRES elements that have been characterized function only in mammalian cells but previous work has shown that the IRES element present in the 5' untranslated region (UTR) of the RhPV genome functions efficiently in mammalian, insect, and plant systems. To determine if the 5' RhPV IRES element could be used to express more than one heterologous sequence from a dsSINV vector, RhPV 5' IRES sequences were placed between genes for two different fluorescent marker proteins in the dsSINV, TE/3'2J/mcs. While mammalian and insect cells infected with recombinant viruses containing the RhPV sequences expressed both fluorescent marker proteins, only single marker proteins were routinely observed in cells infected with dsSINV vectors in which the RhPV IRES had been replaced by a luciferase fragment, an antisense RhPV IRES, or no intergenic sequence. Thus, we report development of a versatile tool for the expression of multiple sequences in diverse cell types.     

Common and distinct regions of defective-interfering RNAs of Sindbis virus

Defective-interfering (DI) particles are helper-dependent deletion mutants which interfere specifically with the replication of the homologous standard virus. Serial passaging of alphaviruses in cultured cells leads to the accumulation of DI particles whose genomic RNAs are heterogeneous in size and sequence composition. In an effort to examine the sequence organization of an individual DI RNA species generated from Sindbis virus, we isolated and sequenced a representative cDNA clone derived from a Sindbis DI RNA population. Our data showed that: (i) the 3' end of the DI RNA template was identical to the 50 nucleotides at the 3' end of the standard RNA; (ii) the majority (75%) of the DI RNA template was derived from the 1,200 5'-terminal nucleotides of the standard RNA and included repeats of these sequences; and (iii) the 5' end of the DI RNA template was not derived from the standard RNA, but is nearly identical to a cellular tRNAAsp (S. S. Monroe and S. Schlesinger, Proc. Natl. Acad. Sci. U.S.A. 80:3279-3283, 1983). We have also utilized restriction fragments from cloned DNAs to probe by blot hybridization for the presence of conserved sequences in several independently derived DI RNA populations. These studies indicated that: (i) a 51-nucleotide conserved sequence located close to the 5' end of several alphavirus RNAs was most likely retained in the DI RNAs; (ii) the junction region containing the 5' end of the subgenomic 26S mRNA was deleted from the DI RNAs; and (iii) the presence of tRNAAsp sequences was a common occurrence in Sindbis virus DI RNAs derived by passaging in chicken embryo fibroblasts.     

Chimeric Sindbis-Ross River viruses to study interactions between alphavirus nonstructural and structural regions.

Sindbis virus and Ross River virus are alphaviruses whose nonstructural proteins share 64% identity and whose structural proteins share 48% identity. Starting from full-length cDNA clones of both viruses, we have generated two reciprocal Sindbis-Ross River chimeric viruses in which the structural and nonstructural regions have been exchanged. These chimeric viruses replicate readily in several cell lines. Both chimeras grow more poorly than do the parental viruses, with the chimera containing Sindbis virus nonstructural proteins and Ross River virus structural proteins growing considerably better in both mosquito and Vero cell lines than the reciprocal chimera does. The reduction in replicative capacity in comparison with the parental viruses appears to result at least in part from a reduction in RNA synthesis, which suggests that the structural proteins or sequence elements within the structural region interact with the nonstructural proteins or sequence elements within the nonstructural region, that these interactions are required for efficient RNA replication, and that these interactions are suboptimal in the chimeras. The chimeras are able to infect mice, but their growth is attenuated. Western equine encephalitis virus, a virus widely distributed throughout the Americas, has been previously shown to have arisen by natural recombination between two distinct alphaviruses, but other naturally occurring recombinant alphaviruses have not been found. The present results suggest that most nonstructural/structural chimeras that might arise by natural recombination will be viable but that interactions between different regions of the genome, some of which were previously known but some of which remain unknown, limit the ability of such recombinants to become established.     

Packaging signals in alphaviruses.

Alphaviruses synthesize large amounts of both genomic and subgenomic RNA in infected cells, but usually only the genomic RNA is packaged. This implies the existence of an encapsidation or packaging signal which would be responsible for selectivity. Previously, we had identified a region of the Sindbis virus genome that interacts specifically with the viral capsid protein. This 132-nucleotide (nt) fragment lies within the coding region of the nsP1 gene (nt 945 to 1076). We proposed that the 132-mer is important for capsid recognition and initiates the formation of the viral nucleocapsid. To study the encapsidation of Sindbis virus RNAs in infected cells, we designed a new assay that uses the self-replicating Sindbis virus genomes (replicons) which lack the viral structural protein genes and contain heterologous sequences under the control of the subgenomic RNA promoter. These replicons can be packaged into viral particles by using defective helper RNAs that contain the structural protein genes (P. Bredenbeek, I. Frolov, C. M. Rice, and S. Schlesinger, J. Virol. 67:6439-6446, 1993). Insertion of the 132-mer into the subgenomic RNA significantly increased the packaging of this RNA into viral particles. We have used this assay and defective helpers that contain the structural protein genes of Ross River virus (RRV) to investigate the location of the encapsidation signal in the RRV genome. Our results show that there are several fragments that could act as packaging signals. They are all located in a different region of the genome than the signal for the Sindbis virus genome. For RRV, the strongest packaging signal lies between nt 2761 and 3062 in the nsP2 gene. This is the same region that was proposed to contain the packaging signal for Semliki Forest virus genomic RNA.     

Replication of Sindbis Virus V. Polyribosomes and mRNA in Infected Cells

Cells infected with wild-type Sindbis virus contain at least two forms of mRNA, 26S and 49S RNA. Sindbis 26S RNA (molecular weight 1.6 x 10(6)) constitutes 90% by weight of the mRNA in infected cells, and is thought to specify the structural proteins of the virus. Sindbis 49S RNA, the viral genome (molecular weight 4.3 x 10(6)), constitutes approximately 10% of the mRNA in infected cells and is thought to supply the remaining viral functions. In cells infected with ts2, a temperature-sensitive mutant of Sindbis virus, the messenger forms also include a third species of RNA with a sedimentation coefficient of 33S and an apparent molecular weight of 2.3 x 10(6). Hybridization-competition experiments showed that 90% of the base sequences in 33S RNA from these cells are also present in 26S RNA. Sindbis 33S RNA was also isolated from cells infected with wild-type virus. After reaction with formaldehyde, this species of 33S RNA appeared to be completely converted to 26S RNA. These results indicate that 33S RNA isolated from cells infected with either wild-type Sindbis or ts2 is not a unique and separate form of Sindbis RNA.     

Evidence for the Identity of Shared 5′-Terminal Sequences Between Genome RNA and Subgenomic mRNA''s of B77 Avian Sarcoma Virus

The polyribosomal fraction from chicken embryo fibroblasts infected with B77 avian sarcoma virus contained 38S, 28S, and 21S virus-specific RNAs in which sequences identical to the 5'-terminal 101 bases of the 38S genome RNA were present. The only polyadenylic acid-containing RNA species with 5' sequences which was detectable in purified virions had a sedimentation coefficient of 38S. This evidence is consistent with the hypothesis that a leader sequence derived from the 5' terminus of the RNA is spliced to the bodies of the 28S and 21S mRNA's, both of which have been shown previously to be derived from the 3' terminal half of the 38S RNA. The entire 101-base 5' terminal sequence of the genome RNA appeared to be present in the majority of the subgenomic intracellular virus-specific mRNA's, as established by several different methods. First, the extent of hybridization of DNA complementary to the 5'-terminal 101 bases of the genome to polyadenylic acid-containing subgenomic RNA was similar to the extent of its hybridization to 38S RNA from infected cells and from purified virions. Second, the fraction of the total cellular polyadenylic acid-containing RNA with 5' sequences was similar to the fraction of RNA containing sequences identical to the extreme 3' terminus of the genome RNA when calculated by the rate of hybridization of the appropriate complementary DNA probes. This suggests that most intracellular virus-specific RNA molecules contain sequences identical to those present in the 5'-terminal 101 bases of the genome. Third, the size of most of the radioactively labeled DNA complementary to the 5'-terminal 101 bases of the genome remained unchanged after the probe was annealed to either intracellular 38S RNA or to various size classes of subgenomic RNA and the hybrids were digested with S1 nuclease and denatured with alkali. However, after this procedure some DNA fragments of lower molecular weight were present. This was not the case when the DNA complementary to the 5'-terminal 101 bases of the genome was annealed to 38S genome RNA. These results suggest that, although the majority of the intracellular RNA contains the entire 101-base 5'-terminal leader sequence, a small population of virus-specific RNAs exist that contain either a shortened 5' leader sequence or additional splicing in the terminal 101 bases.     

RNA recombination in a coronavirus: recombination between viral genomic RNA and transfected RNA fragments.

Mouse hepatitis virus (MHV), a coronavirus, has been shown to undergo a high frequency of RNA recombination both in tissue culture and in animal infection. So far, RNA recombination has been demonstrated only between genomic RNAs of two coinfecting viruses. To understand the mechanism of RNA recombination and to further explore the potential of RNA recombination, we studied whether recombination could occur between a replicating MHV RNA and transfected RNA fragments. We first used RNA fragments which represented the 5' end of genomic-sense sequences of MHV RNA for transfection. By using polymerase chain reaction amplification with two specific primers, we were able to detect recombinant RNAs which incorporated the transfected fragment into the 5' end of the viral RNA in the infected cells. Surprisingly, even the anti-genomic-sense RNA fragments complementary to the 5' end of MHV genomic RNA could also recombine with the MHV genomic RNAs. This observation suggests that RNA recombination can occur during both positive- and negative-strand RNA synthesis. Furthermore, the recombinant RNAs could be detected in the virion released from the infected cells even after several passages of virus in tissue culture cells, indicating that these recombinant RNAs represented functional virion RNAs. The crossover sites of these recombinants were detected throughout the transfected RNA fragments. However, when an RNA fragment with a nine-nucleotide (CUUUAUAAA) deletion immediately downstream of a pentanucleotide (UCUAA) repeat sequence in the leader RNA was transfected into MHV-infected cells, most of the recombinants between this RNA and the MHV genome contained crossover sites near this pentanucleotide repeat sequence. In contrast, when exogenous RNAs with the intact nine-nucleotide sequence were used in similar experiments, the crossover sites of recombinants in viral genomic RNA could be detected at more-downstream sites. This study demonstrated that recombination can occur between replicating MHV RNAs and RNA fragments which do not replicate, suggesting the potential of RNA recombination for genetic engineering.