A small RNA induced late in simian virus 40 infection can associate with early viral mRNAs

Polyomavirus Persistence

Mammalian polyomaviruses are characterized by establishing persistent infections in healthy hosts and generally causing clinical disease only in hosts whose immune systems are compromised. Despite the fact that these viruses were discovered decades ago, our knowledge of the mechanisms that govern viral persistence and reactivation is limited. Whereas mouse polyomavirus has been studied in a fair amount of detail, our understanding of the human viruses in particular is mostly inferred from experiments aimed at addressing other questions. In this review, we summarize the state of our current knowledge, draw conclusions when possible, and suggest areas that are in need of further study.

Polyomavirus miRNAs: the beginning

Polyomaviruses are small, double stranded DNA viruses that replicate in the nucleus of the infected cell. Since 2005, clear evidence for miRNAs has been presented for a subset of the members of this viral family, each of which express a single miRNA. All the miRNAs share in common the ability to regulate expression of the major viral regulatory protein, large T antigen. Growing evidence suggests that the major role of the miRNA is to control viral replication. In vitro studies suggesting an immmunomodulatory role for the miRNA have not been supported by in vivo infections. Very little is known about cellular targets of the viral miRNAs, however. Thus, much remains to be learned about these interesting non-coding RNAs.

The properties and functions of virus encoded microRNA, siRNA, and other small noncoding RNAs

microRNAs (miRNAs) represent a class of noncoding RNA species, believed to be regulating gene expression by binding to complementary sites in the 3'UTRs of target mRNAs. They play important regulatory roles in various metabolic pathways in most eukaryotes. The recent discovery of virus encoded miRNAs suggests that viruses may be using them to regulate host and viral gene expression. Another class of closely related small interfering RNAs (siRNAs) also has been found within the HIV-1 genome and shown to be exerting a limited impact on virus reproduction. Additionally, an additional type of viral noncoding RNAs named small noncoding RNAs (sncRNAs) ranging from a few tens to a few hundred nucleotides in length, has also been identified. sncRNAs have a wide phylogenesis and high levels of expression, suggesting they may play an important roles in different species. Here we discuss the genomic organization, expression, conservation as well as potential function of virally encoded miRNA, siRNA, and sncRNAs.

Efficient and accurate in vitro processing of simian virus 40-associated small RNA

Nuclei were isolated from simian virus 40 (SV40)-infected cells with a hypotonic, detergent-free buffer and incubated in vitro in a high-ionic-strength buffer containing [alpha-32P]UTP. The labeled viral RNAs produced were analyzed by gel electrophoresis together with 3-h-labeled viral RNAs extracted from SV40-infected cells. The in vitro-synthesized RNA contained a major RNA species of 62 to 64 nucleotides that appeared on the gel at the same position as in vivo-synthesized SV40-associated small RNA (SAS-RNA). Analyses of the in vitro-synthesized 62- to 64-nucleotide RNA by hybridization to restriction fragments and by the use of an SAS-RNA deletion mutant clearly identified it as SAS-RNA. The intensity of the band of the in vitro-synthesized SAS-RNA increased with an increase in the labeling time or when a short pulse was followed by a chase. Moreover, the SAS-RNA band disappeared when ITP replaced GTP in the transcription reaction mixture. These results indicate that SAS-RNA is processed from a precursor molecule and that an RNA secondary structure could be an element recognized by the processing enzyme.

Attenuation may regulate gene expression in animal viruses and cells

In eukaryotes, an abundant population of promoter-proximal RNA chains have been observed and studied, mainly in whole nuclear RNA, in denovirus type 2, and in SV40. On the basis of these results it has been suggested that a premature termination process resembling attenuation in prokaryotes occurs in eukaryotes. Moreover, these studies have shown that the adenosine analog 5,6-dichloro-1-beta-D-ribofuranosylbenzimidazole (DRB) enhances premature termination, but its mode of action is not understood. The determination of the nucleotide sequences of SV40 and other viruses and cellular genes provide means for elucidating the nucleotide sequences involved in the attenuation mechanism. A model has recently been described in which attenuation and mRNA modulation in a feedback control system quantitatively regulate SV40 gene expression. The suggested mechanism described in this model opens up approaches to the investigation of attenuation and mRNA modulation as a possible mechanism whereby eukaryotes may regulate transcription in a variety of different circumstances.

Sequences on the 3' side of hexanucleotide AAUAAA affect efficiency of cleavage at the polyadenylation site

The hexanucleotide AAUAAA has been demonstrated to be part of the signal for cleavage and polyadenylation at appropriate sites on eucaryotic mRNA precursors. Since this sequence is not unique to polyadenylation sites, it cannot be the entire signal for the cleavage event. We have extended the definition of the polyadenylation cleavage signal by examining the cleavage event at the site of polyadenylation for the simian virus 40 late mRNAs. Using viable mutants, we have determined that deletion of sequences between 3 and 60 nucleotides on the 3' side of the AAUAAA decreases the efficiency of utilization of the normal polyadenylation site. These data strongly indicate a second major element of the polyadenylation signal. The phenotype of these deletion mutants is an enrichment of viral late transcripts longer than the normally polyadenylated RNA in infected cells. These extended transcripts appear to have an increased half-life due to the less efficient cleavage at the normal polyadenylation site. The enriched levels of extended transcripts in cells infected with the deletion mutants allowed us to examine regions of the late transcript which normally are difficult to study. The extended transcripts have several discrete 3' ends which we have analyzed in relation to polyadenylation and other RNA processing events. Two of these ends map to nucleotides 2794 and 2848, which lie within a region of extensive secondary structure which marks the putative processing signal for the formation of the simian virus 40-associated small RNA. A third specific 3' end reveals a cryptic polyadenylation site at approximately nucleotides 2980 to 2985, more than 300 nucleotides beyond the normal polyadenylation site. This site appears to be utilized only in mutants with debilitated normal sites. The significance of sequences on the 3' side of an AAUAAA for efficient polyadenylation at a specific site is discussed.

Sequences on the 3' side of hexanucleotide AAUAAA affect efficiency of cleavage at the polyadenylation site

The hexanucleotide AAUAAA has been demonstrated to be part of the signal for cleavage and polyadenylation at appropriate sites on eucaryotic mRNA precursors. Since this sequence is not unique to polyadenylation sites, it cannot be the entire signal for the cleavage event. We have extended the definition of the polyadenylation cleavage signal by examining the cleavage event at the site of polyadenylation for the simian virus 40 late mRNAs. Using viable mutants, we have determined that deletion of sequences between 3 and 60 nucleotides on the 3' side of the AAUAAA decreases the efficiency of utilization of the normal polyadenylation site. These data strongly indicate a second major element of the polyadenylation signal. The phenotype of these deletion mutants is an enrichment of viral late transcripts longer than the normally polyadenylated RNA in infected cells. These extended transcripts appear to have an increased half-life due to the less efficient cleavage at the normal polyadenylation site. The enriched levels of extended transcripts in cells infected with the deletion mutants allowed us to examine regions of the late transcript which normally are difficult to study. The extended transcripts have several discrete 3' ends which we have analyzed in relation to polyadenylation and other RNA processing events. Two of these ends map to nucleotides 2794 and 2848, which lie within a region of extensive secondary structure which marks the putative processing signal for the formation of the simian virus 40-associated small RNA. A third specific 3' end reveals a cryptic polyadenylation site at approximately nucleotides 2980 to 2985, more than 300 nucleotides beyond the normal polyadenylation site. This site appears to be utilized only in mutants with debilitated normal sites. The significance of sequences on the 3' side of an AAUAAA for efficient polyadenylation at a specific site is discussed.

Complete nucleotide sequence of a cDNA derived from calf lens gamma-crystallin mRNA: presence of Alu I-like DNA sequences

The nucleotide sequence of a cloned cDNA derived from gamma-crystallin mRNA of calf lens was determined. The cloned cDNA contains the entire coding region 522 bp long, 30 nucleotides of the 5' noncoding region, and 67 residues in the 3' noncoding region followed by a poly(A) tail of 25 nucleotides. The deduced amino acid sequence directly demonstrates for the first time that the calf gamma-crystallin contains 174 residues. The nucleotide sequence contains a number of interesting features including a 32-bp sequence in the 3' region with 70% complementarity to the 3' end of the first monomer unit of the consensus Alu I DNA. Within this region, a 32-bp sequence shows about 80% homology with a segment of hamster 4.5S RNA. The possible evolutionary and regulatory significance of these sequences is discussed.

A frameshift mutation affecting the carboxyl terminus of the simian virus 40 large tumor antigen results in a replication- and transformation-defective virus

We have constructed a frameshift mutation in the simian virus 40 early region using a novel method of oligonucleotide-directed mutagenesis. The mutated DNA specifies an 84,000-dalton large tumor antigen that consists of approximately equal to 75,000 daltons encoded by the wild-type reading frame and 9,000 daltons, by the alternative reading frame (wild-type large tumor antigen is approximately equal to 82,000 daltons). The frameshifted carboxyl terminus of the protein bears a strong similarity to the same region of polyoma virus middle-sized tumor antigen. We have found that the mutant DNA is unable to replicate when introduced into permissive monkey cells and incapable of transforming nonpermissive mouse cells.

Nonlytic simian virus 40-specific 100K phosphoprotein is associated with anchorage-independent growth in simian virus 40-transformed and revertant mouse cell lines

Normal fibroblasts display two distinct growth controls which can be assayed as requirements for serum or for anchorage. Interaction of mouse 3T3 fibroblasts with simian virus 40 (SV40) thus generates four classes of transformed cells. We have examined viral gene expression in these four classes of cell lines. Immunoprecipitation of [35S]methionine-labeled cell extracts with an antiserum obtained from tumor-bearing hamsters detected the SV40 large T and small t proteins (94,000 molecular weight [94K], 17K) and the nonviral host 54K protein in all cell lines tested. A tumor antigen with an apparent molecular weight of 100,000 was also found in some, but not all, lines. Similar "super T" molecules have been found by others in many rodent transformed lines. We carried out an analysis of the relation of phenotype to relative amounts of these proteins in cell lines of the four classes, using the Spearman rank correlation test. The amount of the 100K T antigen relative to the 94K T antigen or to total viral protein was well correlated with the ability to form colonies in semisolid medium. No significant correlation was found between quantities of labeled 94K T antigen, 54K host antigen, or 17K t antigen and either serum or anchorage independence. Mouse cells transformed with the small t SV40 deletion mutant 884 synthesized a 100K T antigen, suggesting that small t is not required for the production of this protein. The 100K T antigen migrated more slowly than lytic T. Since mixtures of extracts from cells expressing and lacking the 100K T antigen yielded the expected amount of this protein, it is unlikely that the 100K T derives from the 94K protein by a posttranslational modification.

Hybrid selection of small RNAs by using simian virus 40 DNA: evidence that the simian virus 40-associated small RNA is synthesized by specific cleavage from large viral transcripts

The simian virus 40 (SV40)-associated small RNA (SAS-RNA), approximately 64 nucleotides, is virally encoded within a region of the viral late (+) DNA strand which encodes no known protein. The SAS-RNA arises in abundance late in SV40 lytic infection. Previous data indicate that the synthesis of the SAS-RNA may be under the control of the normal late viral promoter; i.e., inhibition of transcription from the late promoter results in cessation of SAS-RNA synthesis. The synthesis of SAS-RNA was examined to determine whether the SAS-RNA is the product of cleavage from noncoding regions of nuclear late transcripts or an independent transcription product like 5S RNA, or the adenovirus VA-RNAs. The data described below suggest that SAS-RNA is cleaved from large late transcripts. In vitro transcription of DNA fragments containing the SAS-RNA coding region yielded no SAS-RNA synthesis; this result was supported by DNA sequence analysis, which indicated no promoter-like regions either within or flanking the SAS-RNA coding region. In support of a cleavage mechanism, the SAS-RNA has a 3'-phosphate end, an occurrence which is indicative of nuclease cleavage. In addition, 5'-end labeling of the SAS-RNA was possible only after calf alkaline phosphatase treatment; this indicates that the SAS-RNA is not capped. Hybrid selection analysis was used to demonstrate that separation of the SAS-RNA coding region from the normal late promoter resulted in elimination of SAS-RNA synthesis. This was demonstrated in SV40-transformed cells in which integration of a single copy of SV40 breaks the continuity of the late coding region, so that the SAS-RNA coding region is physically separated from the normal late promoter. The lack of SAS-RNA synthesis indicates that the SAS-RNA coding region cannot function as a primary transcription unit. The same result and conclusion were obtained by using a permissive cell line transformed by SV40 (COS-1 cells); here it was found that the integrated SAS-RNA coding region was not expressed even during a viable lytic infection in which the SAS-RNA could be expressed from the infecting viral genomes. The simplest conclusion drawn from the data is that the SAS-RNA is cleaved from larger late transcripts which initiate at the normal late promoter. This conclusion suggests that many of the small RNAs found in normal eucaryotic cells may be synthesized by specific cleavage rather than by primary transcription. In the course of these studies several small cellular RNAs were detected, due to their specific hybrid selection, by using SV40 DNA. Primary mapping and characterization data of these RNAs are also presented.

Transforming genes and gene products of polyoma and SV40

The small DNA-containing viruses, SV40 and polyoma, transform cells in vitro and induce tumors in vivo. For both viruses two genes required for transformation have been found. The genes required for transformation are also involved in productive infection. Although the two viruses are similar in their effects on cells, the organization of the transforming genes and gene products is different. The purpose of this review is to compare what is known about the biology and the biochemistry of the early regions of the two viruses. The genetic and biochemical studies defining the sequences important for transformation will be reviewed. Then, the products of the transforming genes, called T antigens, will be discussed in detail. There is a substantial body of descriptive information on those products, and studies on the function of the T antigens have also begun.

Nonlytic simian virus 40-specific 100K phosphoprotein is associated with anchorage-independent growth in simian virus 40-transformed and revertant mouse cell lines

Normal fibroblasts display two distinct growth controls which can be assayed as requirements for serum or for anchorage. Interaction of mouse 3T3 fibroblasts with simian virus 40 (SV40) thus generates four classes of transformed cells. We have examined viral gene expression in these four classes of cell lines. Immunoprecipitation of [35S]methionine-labeled cell extracts with an antiserum obtained from tumor-bearing hamsters detected the SV40 large T and small t proteins (94,000 molecular weight [94K], 17K) and the nonviral host 54K protein in all cell lines tested. A tumor antigen with an apparent molecular weight of 100,000 was also found in some, but not all, lines. Similar "super T" molecules have been found by others in many rodent transformed lines. We carried out an analysis of the relation of phenotype to relative amounts of these proteins in cell lines of the four classes, using the Spearman rank correlation test. The amount of the 100K T antigen relative to the 94K T antigen or to total viral protein was well correlated with the ability to form colonies in semisolid medium. No significant correlation was found between quantities of labeled 94K T antigen, 54K host antigen, or 17K t antigen and either serum or anchorage independence. Mouse cells transformed with the small t SV40 deletion mutant 884 synthesized a 100K T antigen, suggesting that small t is not required for the production of this protein. The 100K T antigen migrated more slowly than lytic T. Since mixtures of extracts from cells expressing and lacking the 100K T antigen yielded the expected amount of this protein, it is unlikely that the 100K T derives from the 94K protein by a posttranslational modification.

mRNA in human cells contains sequences complementary to the Alu family of repeated DNA

Approximately one-half of the polysomal poly(A)+RNA from CCRF-CEM human lymphoblastoid cells associates at low R0t (10 M.sec) [where R0 is the initial concentration of RNA (M) and t is time (sec)] to form branched complexes detectable by electron microscopy. The complexes typically involve 2-16 molecules associated over double-stranded regions 120 +/- 30 base pairs long. Formation of such complexes suggests that poly(A)+RNA contains repeated-sequence elements that are highly represented in the mRNA population. Hybridization of polysomal poly(A)+RNA with a recombinant human DNA plasmid, p lambda H15C, which is shown to contain at least three regions complementary to two different members of the Alu family of DNA repeat sequences, showed a total of five regions where R loops are formed. The hybridized regions comprising these groups are 260 +/- 180, 240 +/- 170, 150 +/- 70, 180 +/- 60, and 180 +/- 80 base pairs long. The relative frequencies of R loops formed at these different sites indicate that sequences in this recombinant DNA are represented in the mRNA population at different frequencies. The hybridizing sequence of the RNA molecules is located near one terminus in 13% of the R loops and internally in 53% of the R loops. Surprisingly, 35% of the R loops apparently involve RNA molecules hybridized over their entire length of only 200 +/- 110 base pairs.

Separation of lytic and transforming functions of the simian virus 40 A region: two mutants which are temperature sensitive for lytic functions have opposite effects on transformation

Thirty-six of 40 rat cell clones transformed to anchorage independence at low multiplicity of infection by simian virus 40 tsA58 were heat sensitive for continued expression of the transformed phenotype. tsA1499 is an 81-base-pair deletion at 21 map units which is like tsA58 in that it is also heat sensitive for lytic growth, belongs to the A complementation group, and produces rat cell transformants which contain a thermolabile T antigen. Unlike tsA58, however, tsA1499 generated rat cell transformants efficiently at the temperature at which it was lytically defective, and 10 of 17 clones transformed by tsA1499 were cold rather than heat sensitive for the continued maintenance of the transformed phenotype. The lytic and transforming activities of the A region thus appeared to function independently in mutant tsA1499.

Simian virus 40 early mRNA's in lytically infected and transformed cells contain six 5'-terminal caps

Late simian virus 40 (SV40) mRNA contains eight different cap structures which we have previously identified and mapped on the viral genome. As reported here, 5'-cap heterogeneity is a common feature to both the early and the late SV40 mRNA's. methyl-3H-labeled viral mRNA was purified from cells infected at 41 degrees C with SV40 mutant tsA209. Three different cap cores were identified: m7GpppGm, m7GpppCm, and m7GpppAm. An average of three to four m6A residues per mRNA molecule was found. RNase T2-resistant 32P-labeled early caps from tsA209-infected cells isolated and characterized. Six distinct cap I structures were identified: m7GpppCmpU (30%), m7GpppGmpC (24%), m7GpppAmpG (18%), m7GpppGmpU (13%), m7GpppGmpG (12%), and m7GpppAmpU (3%). A similar 5'-end heterogeneity was observed in early SV40 mRNA from BSC-1 cells infected with wild-type SV40 strain 777 in the presence of cytosine arabinoside and in the SV40 UV-transformed permissive line C-6. Five of these capped dinucleotides are complementary to DNA sequences at 0.66 map unit in a region previously identified by the primer extension method (Reddy et al., J. Virol. 30:279-296, 1979; Thompson et al., J. Virol. 31:437-438, 1979) as the 5' end of the early message. DNA sequences upstream from this region contain the TATTTAT (Hogness-Goldberg box), which is missing from upstream of the 5'-cap sites of late SV40 mRNA. Thus, 5'-end heterogeneity is not necessarily related to the presence or the absence of this putative transcriptional "initiation signal." When the possibility that SV40 5' caps represent transcriptional initiation sites is considered, the data also suggest that, on SV40 DNA, eucaryotic RNA polymerase II initiates transcription at multiple nucleotide sequences, including pyrimidines.

Simian virus 40-associated small RNA: mapping on the simian virus 40 genome and characterization of its synthesis

The simian virus 40 (SV40)-associated small RNA (SAS-RNA) has previously been shown to arise late in SV40 lytic infection and to bear homology with the SV40 early mRNA's, or the SV40 genome, at map position 0.21. By using hybridization analysis, we determined that the SAS-RNA is between 62 and 65 nucleotides in length and its homology region lies between nucleotides 2760 and 2825 of the SV40 late(+) DNA strand. Viable deletion mutants which lacked part or all of this region made no SAS-RNA, strongly indicating that this is the coding region of the SAS-RNA. The expected sequence for the SAS-RNA, determined from the DNA sequence between nucleotides 2760 and 2825, appeared to be very pyrimidine rich (76% uridine and cytidine). Deletion or alteration of sequences immediately preceding the SAS-RNA coding region (approximately nucleotides 2716 to 2748) resulted in the loss of SAS-RNA production. These sequences may be part of a promotor for SAS-RNA synthesis or a processing site for its excision from long nuclear late transcripts. Under growth conditions where late transcription was not fully initiated (tsA58 at 41 degrees C; wild-type SV40 in the presence of 1-beta-D-arabinofuranosylcytosine), no SAS-RNA was produced, indicating that the expression of the SAS-RNA is regulated by a mechanism related to the control of late transcription.

Transcription and RNA processing by the DNA tumour viruses

Messenger RNA synthesis by the DNA tumour viruses proceeds by a complex but versatile series of transcription and RNA processing steps. The major mechanistic features of this pathway are probably very similar to those used by the animal cell host itself. The viruses have, however, evolved intricate arrangements of protein coding sequences and sites for RNA initiation, polyadenylation and splicing which allow them to use their genetic information to maximum advantage.

Control of simian virus 40 gene expression at the levels of RNA synthesis and processing: thermally induced changes in the ratio of the simian virus 40 early mRNA's and proteins

Examination of the simian virus 40 early mRNA's from infected AGMK or CV-1 cells showed that the ratio of large T- to small t-antigen mRNA's increased with an increased incubation temperature. In tsA58 mutant-infected cells, an increased incubation temperature resulted in the overproduction of early RNAs'; however, the ratio of the early mRNA's was the same, at any temperature, in both wild-type- and tsA58-infected cells. Thus, the thermally induced alteration in the early mRNA ratios was apparently not affected by the tsA mutation or by the overproduction of early RNA in tsA mutant-infected cells. Time course studies at various temperatures showed that, although the ratio of large T- to small t-antigen mRNA's increased with temperature, at any one temperature it was consistent from early to late times of infection. Furthermore, the ratio of the early mRNA's adjusted in temperature shift experiments. Thus, the ratio of the early mRNA's appeared to be intrinsic to the thermodynamic environment of the cell. The thermally induced alterations in the early mRNA's were reflected at the protein level by parallel changes in the ratio of large T- to small t-antigens. These data suggest a level of gene expression control which may function at the stage of splicing.