Showing papers on "RNA-dependent RNA polymerase published in 1994"

An RNA polymerase II holoenzyme responsive to activators

Abstract: RNA POLYMERASE II requires multiple general transcription factors to initiate site-specific transcription1–3 These proteins can assemble in an ordered fashion onto promoter DNA in vitro2–8, and such ordered assembly may occur in vivo (Fig la) Some general transcription factors can interact with RNA polymerase II in the absence of DNA3,9–15, however, suggesting that RNA polymerase II may also assemble into a multi-component complex containing a subset of initiation factors before binding to promoter DNA (Fig Ib) Here we present evidence from the yeast Saccharo-myces cerevisiae for such an RNA polymerase II holoenzyme, a multi-subunit complex containing roughly equimolar amounts of RNA polymerase II, a subset of general transcription factors, and SRB regulatory proteins Transcription by this holoenzyme is stimulated by the activator protein GAL4-VP16, a feature not observed with purified RNA polymerase II and general transcription factors alone We propose that the holoenzyme is a form of RNA polymerase II readily recruited to promoters in vivo

A tRNA-like structure is present in 10Sa RNA, a small stable RNA from Escherichia coli

Abstract: We have determined that 10Sa RNA (one of the small stable RNAs found in Escherichia coli) has an interesting structural feature: the 5' end and the 3' end of 10Sa RNA can be arranged in a structure that is equivalent to a half-molecule (acceptor stem and TFC stem-loop) of alanine tRNA of E. coli. Primer-extension analysis of 10Sa RNA extracted from a bacterial mutant with temperature-sensitive RNase P function revealed that the precursor to 10Sa RNA (pre-10Sa RNA) is folded into a pre-tRNA-like structure in vivo such that it can be cleaved by RNase P to generate the 5' end of the mature 10Sa RNA. The purified 10Sa RNA can be charged with alanine in vitro. Disruption of the gene encoding 10Sa RNA (ssrA) caused a reduction in the rate of cell growth, which was especially apparent at 45 degrees C, and a reduction in motility on semisolid agar. These phenotypic characteristics of the deletion strain (delta ssrA) allowed us to investigate the effects of some mutations in 10Sa RNA in vivo, although the exact function of 10Sa RNA still remains unclear. When the G.U pair (G3.U357) in 10Sa RNA, which may be equivalent to the determinant G.U pair of alanine tRNA, was changed to a G.A or G.C pair, the ability to complement the phenotypic mutations of the delta ssrA strain was lost. Furthermore, this inability to complement the mutant phenotypes that was caused by the substitution of the determinant bases by a G.A pair could be overcome by the introduction of a gene encoding alanyl-tRNA synthetase (alaS) on a multicopy plasmid. The evidence suggests that the proposed structural features of 10Sa RNA are indeed manifested in vivo.

Transcript cleavage by RNA polymerase II arrested by a cyclobutane pyrimidine dimer in the DNA template.

Abstract: A current model for transcription-coupled DNA repair is that RNA polymerase, arrested at a DNA lesion, directs the repair machinery to the transcribed strand of an active gene. To help elucidate this role of RNA polymerase, we constructed DNA templates containing the major late promoter of adenovirus and a cyclobutane pyrimidine dimer (CPD) at a specific site. CPDs, the predominant DNA lesions formed by ultraviolet radiation, are good substrates for transcription-coupled repair. A CPD located on the transcribed strand of the template was a strong block to polymerase movement, whereas a CPD located on the nontranscribed strand had no effect on transcription. Furthermore, the arrested polymerase shielded the CPD from recognition by photolyase, a bacterial DNA repair protein. Transcription elongation factor SII (also called TFIIS) facilitates read-through of a variety of transcriptional pause sites by a process in which RNA polymerase II cleaves the nascent transcript before elongation resumes. We show that SII induces nascent transcript cleavage by RNA polymerase II stalled at a CPD. However, this cleavage does not remove the arrested polymerase from the site of the DNA lesion, nor does it facilitate translesional bypass by the polymerase. The arrested ternary complex is stable and competent to resume elongation, demonstrating that neither the polymerase nor the RNA product dissociates from the DNA template.

Crystal structure of an RNA bacteriophage coat protein-operator complex.

Abstract: THE RNA bacteriophage MS2 is a convenient model system for the study of protein–RNA interactions. The MS2 coat protein achieves control of two distinct processes—sequence-specific RNA encapsidation and repression of replicase translation—by binding to an RNA stem–loop structure of 19 nucleotides containing the initiation codon of the replicase gene. The binding of a coat protein dimer to this hairpin shuts off synthesis of the viral replicase1, switching the viral replication cycle to virion assembly rather than continued replication. The operator fragment alone can trigger self-assembly of the phage capsid at low protein concentrations and a complex of about 90 RNA operator fragments per protein capsid has been described2. We report here the crystal structure at 3.0 A resolution of a complex between recombinant MS2 cap-sids and the 19-nucleotide RNA fragment. It is the first example of a structure at this resolution for a sequence-specific protein-RNA complex apart from the transfer RNA synthetase complexes3–5. The structure shows sequence-specific interactions between conserved residues on the protein and RNA bases essential for binding.

Phosphorylation of RNA polymerase II C-terminal domain and transcriptional elongation.

Abstract: The carboxy-terminal domain (CTD) of the large subunit of RNA polymerase II is essential in vivo, and is found in either an unphosphorylated (IIa) or hyperphosphorylated (IIo) form. The Drosophila uninduced hsp70 and hsp26 genes, and the constitutively expressed beta-1 tubulin and Gapdh-2 genes, contain an RNA polymerase II complex which pauses after synthesizing a short transcript. We report here that, using an in vivo ultraviolet crosslinking technique and antibodies directed against the IIa and IIo forms of the CTD, these paused polymerases have an unphosphorylated CTD. For genes containing a 5' paused polymerase, passage of the paused RNA polymerase into an elongationally competent mode in vivo coincides with phosphorylation of the CTD. Also, the level of phosphorylation of the CTD of elongating polymerases is shown not to be related to the level of transcription, but is promoter specific.

Regulation of Sindbis virus RNA replication: uncleaved P123 and nsP4 function in minus-strand RNA synthesis, whereas cleaved products from P123 are required for efficient plus-strand RNA synthesis

Abstract: Nonstructural proteins of Sindbis virus, nsPl, nsP2, nsP3, and nsP4, as well as intermediate polyproteins, are produced from two precursor polyproteins, Pl23 and Pl234, by a proteolytic enzyme encoded in the C-terminal half of nsP2. We studied the requirements for and the functions of the intermediate and mature processing products for Sindbis virus RNA synthesis by using site-directed mutants which have a defect(s) in processing the 1/2, 2/3, or 3/4 cleavage sites either singly or in various combinations. A mutant defective in cleaving both the 1/2 and 2/3 sites, which makes only uncleavable Pl23 and mature nsP4 as final products, produced 10-3 as much virus as did the wild-type virus after 10 hat 30°C and was nonviable at 40°C. A mutant defective in processing the 2/3 site, which makes nsPl, nsP4, and P23 as well as precursor Pl23, grew 10-1 as efficiently as wild-type virus at 30°C and 10-3 as efficiently at 40°C. Early minus-strand RNA synthesis by these mutants was as efficient as that by wild-type virus, whereas plus-strand RNA synthesis was substantially decreased compared with that by wild-type virus. A mutant defective in processing the 3/4 site was nonviable at either 30 or 40°C. The 3/4 site mutant could be complemented by the mutant unable to cleave either the 1/2 or 2/3 site, which can provide mature nsP4. We interpret these results to signify that (i) mature nsP4 is required for RNA replication, (ii) nsP4 and uncleaved Pl23 function in minus-strand RNA synthesis, and (iii) cleavage of Pl23 is required for efficient plus-strand RNA synthesis. We propose that Sindbis virus RNA replication is regulated by differential proteolysis of Pl23. Early in infection, nsP4 and uncleaved Pl23 form transient minus-strand RNA replication complexes which vanish upon cleavage of Pl23. Later in infection, an elevated level of viral proteinase activity eliminates de novo synthesis of Pl23, and no further synthesis of minus-strand RNA is possible. In contrast, nsP4 and cleavage products from Pl23 form plus-strand RNA replication complexes which are stable and remain active throughout the infection cycle.

Structure of influenza virus RNP. I. Influenza virus nucleoprotein melts secondary structure in panhandle RNA and exposes the bases to the solvent.

Abstract: The influenza virus genome consists of eight segments of negative-sense RNA, i.e. the viral (v) RNA forms the template for the mRNA. Each segment is encapsidated by the viral nucleoprotein to form a ribonucleoprotein (RNP) particle and each RNP carries its own polymerase complex. We studied the interaction of purified nucleoprotein with RNA in vitro, by using a variety of enzymatic and chemical probes for RNA conformation. Our results suggest that the nucleoprotein binds to the vRNA backbone without apparent sequence specificity, exposing the bases to the outside and melting all secondary structure. In this way, the viral polymerase may transcribe the RNA without the need for dissociating the nucleoprotein and without being stopped by RNA secondary structure, and the viral RNPs are ready to start transcription as soon as they enter the host cell.

The influenza virus panhandle is involved in the initiation of transcription.

Abstract: The role of the influenza A virus panhandle structure formed from the 39- and 59-terminal nucleotides of virion RNA segments was studied in both an RNA polymerase binding assay and an in vitro transcription assay. Despite recent indications that promoter activity is simply a function of the 39-terminal sequence of virion RNA, our results show that both 39- and 59-terminal sequences are involved in the initiation of transcription. We propose a new model for the initiation of transcription which has implications for the mechanisms by which influenza virus transcription, replication, and polyadenylation may be regulated in the infected cell. Images

Mutational analysis of the conserved motifs of influenza A virus polymerase basic protein 1.

Abstract: Influenza virus polymerase complex is a heterotrimer consisting of polymerase basic protein 1 (PB1), polymerase basic protein 2 (PB2), and polymerase acidic protein (PA). Of these, only PB1, which has been implicated in RNA chain elongation, possesses the four conserved motifs (motifs I, II, III, and IV) and the four invariant amino acids (one in each motif) found among all viral RNA-dependent RNA or RNA-dependent DNA polymerases. We have modified an assay system developed by Huang et al. (T.-J. Huang, P. Palese, and M. Krystal, J. Virol. 64:5669-5673, 1990) to reconstitute the functional polymerase activity in vivo. Using this assay, we have examined the requirement of each of these motifs of PB1 in polymerase activity. We find that each of these invariant amino acids is critical for PB1 activity and that mutation in any one of these residues renders the protein nonfunctional. We also find that in motif III, which contains the SSDD sequence, the signature sequence of influenza virus RNA polymerase, SDD is essentially invariant and cannot accommodate sequences found in other RNA viral polymerases. However, conserved changes in the flanking sequences of SDD can be partially tolerated. These results provide the experimental evidence that influenza virus PB1 possesses a similar polymerase module as has been proposed for other RNA viruses and that the core SDD sequence of influenza virus PB1 represents a sequence variant of the GDN in negative-stranded nonsegmented RNA viruses, GDD in positive-stranded RNA virus and double-stranded RNA viruses, or MDD in retroviruses.

Rescue of synthetic genomic RNA analogs of rabies virus by plasmid-encoded proteins.

Abstract: Proteins entirely expressed from cDNA were used to rescue synthetic RNA genome analogs into infectious defective particles of rabies virus (RV). Synthetic negative-stranded RNAs containing 3'- and 5'-terminal RV sequences and transcriptional signal sequences were transcribed from plasmids transfected into cells expressing T7 RNA polymerase from recombinant vaccinia virus. After simultaneous expression of RV N, P, and L proteins from plasmids containing a T7 RNA polymerase promoter, the synthetic genomes were encapsidated, replicated, and transcribed by the RV polymerase proteins. Insertion of the bacterial chloramphenicol acetyltransferase gene or beta-galactosidase (lacZ) gene between the 3' and 5' termini containing transcriptional signal sequences resulted in transcription of mRNAs and expression of chloramphenicol acetyltransferase and beta-galactosidase, respectively. Upon simultaneous expression of N, P, M, G, and L proteins, virions carrying the foreign genes were assembled and released into the supernatant. The possibility of rescuing cDNA into rabies virions by proteins also expressed entirely from cDNA opens the possibility of studying the functions of each RV protein and analyzing cis-acting signals of the RV genome.

Coupling between genome translation and replication in an RNA virus.

Abstract: The replication of poliovirus RNA genomes containing amber mutations was studied to test whether viral proteins provided in trans could rescue the replication of an RNA genome that could not be completely translated itself. Mutants containing amber codons at different positions in the genome displayed vastly different abilities to be rescued by wild-type proteins provided by a helper genome. Amber-suppressing cell lines were used to ensure that the defects in the amber mutants arose from their failure to be translated, not from defects in RNA sequence or structure. An internal region of the poliovirus genome was identified whose translation is required in cis; failure to translate this region was shown to inhibit RNA replication. This coupling between translation and RNA replication could provide a late proofreading mechanism that enables poliovirus, and possibly many other RNA viruses, to prevent the replication of defective genomes.

Site-specific RNA binding by a hepatitis B virus reverse transcriptase initiates two distinct reactions: RNA packaging and DNA synthesis.

Abstract: Hepatitis B viruses encode a polymerase (P) protein with key roles in both reverse transcription and genomic RNA encapsidation. Genetic analysis of cis-acting signals required for viral replication implicates an RNA stem-loop structure in both RNA packaging and the initiation of reverse transcription, a process in which P protein also serves as the primer. We now show that duck hepatitis B virus (DHBV) polymerase binds specifically and with high affinity to this RNA stem-loop structure. Mutational analysis indicates that all mutations in the RNA target that inhibit the P protein-RNA interaction inhibit both in vivo RNA packaging and in vitro DNA priming to comparable extents. However, certain mutations in the loop region of the RNA have minimal impact on P protein-RNA binding but are nonetheless severely defective for packaging and DNA synthesis. Thus, P protein-RNA complex formation is necessary but not sufficient to initiate these activities. In addition, examination of RNA binding by truncated P proteins indicates that the C terminus of the polymerase, although required for RNA encapsidation in vivo, is dispensable for RNA binding and DNA priming.

RNA-RNA Recombination and Evolution in Virus-Infected Plants

Abstract: Viruses that depend on RNA-dependent RNA polymerases (RdRp) for repli­ cation of their genomic and subgenomic RNAs are subject to high inherent misincorporation of nucleotides that can lead to heterogeneous mixtures of related species (46, 93). It has been proposed that RNA viruses evolved the means for correcting high error rates through an ability to recombine mutant genomes with wild-type genomes, thereby maintaining functional integrity (72). Although originally found only in a select number of animal viruses, RNA recombination is now thought to have been a major factor in the evolution of all viruses (lOS). This view is based on sequence comparisons that suggest past recombination events,as well as the detection of de novo recombinant molecules. The role of RNA recombination in virus evolution is also supported by studies indicating that recombinant viruses have a selective advantage over parental viruses in certain instances ( l0, 72, 86). All types of crossover events can occur intergenically or intragenically. Intergenic recombination occurs between the genetic material derived from two different viruses, whereas intragenic events are possible for viruses with

Sequence-specific binding of the influenza virus RNA polymerase to sequences located at the 5' ends of the viral RNAs.

Abstract: The enzymatic activity of recombinant influenza virus RNA polymerase is strictly dependent on the addition of a template RNA containing 5' and 3' viral sequences. Here we report the analysis of the binding specificity and physical characterization of the complex by using gel shift, modification interference, and density gradient techniques. The 13S complex binds specifically to short synthetic RNAs that mimic the partially double stranded panhandle structures found at the termini of both viral RNA and cRNA. The polymerase will also bind independently to the single-stranded 5' or 3' ends of viral RNA. It binds most strongly to specific sequences within the 5' end but is unable to bind these sequences in the context of a completely double stranded structure. Modification interference analysis identified the short sequence motifs at the 5' ends of the viral RNA and cRNA templates that are critical for binding.

Recombinant influenza virus polymerase: requirement of both 5' and 3' viral ends for endonuclease activity.

Abstract: Influenza virus polymerase complexes that were expressed in the absence of genomic viral RNA and nucleoprotein were examined for endonuclease activity and transcriptase ability in vitro. Nuclear extracts of cells that express influenza virus polymerase through recombinant vaccinia virus infection did not display specific endonuclease activity in vitro. This polymerase presumably represents an early form of enzyme present in infected cells prior to ribonucleoprotein assembly. Upon addition of a virus-like model RNA template, containing the partially complementary sequence found at the ends of viral RNA, endonuclease activity is stimulated in a concentration-dependent and sequence-specific manner. Once stimulated, the polymerase is able to elongate from the added viral template. Thus, addition of viral template is required for polymerase activity, while the presence of nucleoprotein is not required for limited transcription. Also, full activation of this recombinant viral polymerase is dependent on the presence of both the 3' and 5' ends of the viral genome, as model RNA containing either end alone could not effectively trigger the endonuclease.

Recombinant negative strand RNA virus expression systems

Abstract: Recombinant negative strand virus RNA templates which may be used to express heterologous gene products and/or to construct chimeric viruses are described. Influenza viral polymerase, which was prepared depleted of viral RNA, was used to copy small RNA templates prepared from plasmid-encoded sequences. Template constructions containing only the 3' end of genomic RNA were shown to be efficiently copied, indicative that the promoter lay solely within the 15 nucleotide 3' terminus. Sequences not specific for the influenza viral termini were not copied, and, surprisingly, RNAs containing termini identical to those from plus sense cRNA were copied at low levels. The specificity for recognition of the virus-sense promoter was further defined by site-specific mutagenesis. It was also found that increased level of viral protein were required in order to catalyze both the cap-endonuclease primed and primer-free RNA synthesis from these model templates as well as from genomic length RNAs. This indicated that this reconstituted system had catalytic properties very similar to those of native viral RNPs. High levels of expression of a heterologous gene was obtained using the constructs and methods described. The system was exemplified using Influenza and respiratory syncytial virus.

A small mitochondrial double-stranded (ds) RNA element associated with a hypovirulent strain of the chestnut blight fungus and ancestrally related to yeast cytoplasmic T and W dsRNAs.

Abstract: A small double-stranded (ds) RNA element was isolated from a moderately hypovirulent strain of the chestnut blight fungus Cryphonectria parasitica (Murr.) Barr. from eastern New Jersey. Virulence was somewhat lower in the dsRNA-containing strain than in a virulent dsRNA-free control strain, but colony morphology and sporulation levels were comparable. A library of cDNA clones was constructed, and overlapping clones representing the entire genome were sequenced. The 2728-bp dsRNA was considerably smaller than previously characterized C. parasitica dsRNAs, which are 12-13 kb and ancestrally related to the Potyviridae family of plant viruses. Sequence analysis revealed one large open reading frame, but only if mitochondrial codon usage (UGA = Trp) was invoked. Nuclease assays of purified mitochondria confirmed that the dsRNA was localized within mitochondria. Assuming mitochondrial translation, the deduced amino acid sequence had landmarks typical of RNA-dependent RNA polymerases. Alignments of the conserved regions indicate that this dsRNA is more closely related to yeast T and W dsRNAs and single-stranded RNA bacteriophages such as Q beta than to other hypovirulence-associated dsRNAs.

RNA polymerase II is aberrantly phosphorylated and localized to viral replication compartments following herpes simplex virus infection.

Abstract: During lytic infection, herpes simplex virus subverts the host cell RNA polymerase II transcription machinery to efficiently express its own genome while repressing the expression of most cellular genes. The mechanism by which RNA polymerase II is directed to the viral delayed-early and late genes is still unresolved. We report here that RNA polymerase II is preferentially localized to viral replication compartments early after infection with herpes simplex virus type 1. Concurrent with recruitment of RNA polymerase II into viral compartments is a rapid and aberrant phosphorylation of the large subunit carboxy-terminal domain (CTD). Aberrant phosphorylation of the CTD requires early viral gene expression but is not dependent on viral DNA replication or on the formation of viral replication compartments. Localization of RNA polymerase II and modifications to the CTD may be instrumental in favoring transcription of viral genes and repressing specific transcription of cellular genes.

RNA template-directed RNA synthesis by T7 RNA polymerase.

Abstract: In an attempt to synthesize an oligoribonucleotide by run-off transcription by bacteriophage T7 RNA polymerase, a major transcript was produced that was much longer than expected. Analysis of the reaction indicated that the product resulted from initial DNA-directed run-off transcription followed by RNA template-directed RNA synthesis. This reaction occurred because the RNA made from the DNA template displayed self-complementarity at its 3' end and therefore could form an intra- or intermolecular primed template. In reactions containing only an RNA template, the rate of incorporation of NTPs was quite comparable to DNA-dependent transcription. RNA template-directed RNA synthesis has been found to occur with a great number of oligoribonucleotides, even with primed templates that are only marginally stable. In one instance, we observed a multistep extension reaction converting the oligonucleotide into a final product longer than twice its original length. Presumably, such a process could have generated some of the RNAs found to be efficiently replicated by T7 RNA polymerase.

La autoantigen alleviates translational repression by the 5' leader sequence of the human immunodeficiency virus type 1 mRNA.

Abstract: The trans-activation response element (TAR) at the 5' end of the human immunodeficiency virus type 1 (HIV-1) mRNAs forms a stable hairpin structure which is a target for binding of the virally encoded protein Tat, which activates viral gene expression, as well as several cellular factors. TAR is also inhibitory to translation. One of several host factors that binds to TAR RNA is the La autoantigen, an RNA-binding protein which functions in RNA polymerase III transcription termination and has also been implicated in cap-independent internal translation initiation on poliovirus RNA. Here we show that La autoantigen alleviates translational repression by the HIV-1 leader RNA. In rabbit reticulocyte lysate, La relieves the cis-inhibitory effect of the TAR RNA on translation of bacterial chloramphenicol acetyltransferase (CAT) mRNA but not inhibition that is mediated by an artificial secondary structure element. Canonical translation factors exhibited slight (eIF-2 and GEF) or no (eIF-4A, eIF-4B, eIF-4E, eIF-4F, eIF-3, and eEF-1 alpha) stimulatory activity on translation of TAR-containing CAT mRNA. In addition, we show that poliovirus RNA, in spite of being an inefficient template in rabbit reticulocyte lysate, is a strong competitive inhibitor of translation of TAR-containing CAT mRNA but not CAT mRNA. This inhibition can be relieved by La but not by any other translation factor. The results suggest a possible involvement of the La autoantigen in HIV-1 gene expression.

Nonhomologous RNA recombination in tombusviruses: generation and evolution of defective interfering RNAs by stepwise deletions.

Abstract: We used a protoplast system to study the mechanisms involved in the generation and evolution of defective interfering (DI) RNAs of tomato bushy stunt tombusvirus (TBSV). Synthetic transcripts corresponding to different naturally occurring TBSV DI RNAs, or to various artificially constructed TBSV defective RNAs, were analyzed. The relative levels of competitiveness of different DI RNAs were determined by coinoculating their corresponding transcripts into protoplasts along with helper genomic RNA transcripts and monitoring the level of DI RNA accumulation. Further studies were performed to assess the contribution of naked DI RNA stability and DI RNA encapsidation efficiency to the observed levels of competitiveness. In addition, the ability of various defective RNAs to evolve to alternative forms was tested by serially passaging protoplast infections initiated with transcripts corresponding to helper genomic RNA and a single type of defective RNA. These studies, and the analysis of the sequences of observed recombinants, indicate that (i) replication competence is a major factor dictating DI RNA competitiveness and is likely a primary determinant in DI RNA evolution, (ii) DI RNAs are capable of evolving to both smaller and larger forms, and the rates at which various transitions occur differ, (iii) DI RNA-DI RNA recombination and/or rearrangement is responsible for the formation of the evolved RNA molecules which were examined, and (iv) sequence complementarities between positive- and negative-sense strands in the regions of the junctions suggest that, in some cases, base pairing between an incomplete replicase-associated nascent strand and acceptor template may mediate selection of recombination sites. On the basis of our data, we propose a stepwise deletion model to describe the temporal order of events leading to the formation of tombusvirus DI RNAs.

Influenza virus NS1 protein stimulates translation of the M1 protein.

Abstract: The influenza virus NS1 protein was shown to stimulate translation of the M1 protein. M-CAT RNA, which contains the chloramphenicol acetyltransferase (CAT) reporter gene and the terminal noncoding sequence of segment 7 (coding for the M1 and M2 proteins), was ribonucleoprotein transfected into clone 76 cells expressing the influenza virus RNA polymerase and NP proteins required for the transcription and replication of influenza virus ribonucleoproteins. When the cells were superinfected with a recombinant vaccinia virus which expresses the NS1 protein, CAT expression from the M-CAT RNA was significantly stimulated but transcription was not altered. The expression of NS-CAT RNA, which contains noncoding sequences of segment 8 (coding for the NS1 and NS2 proteins), was not altered by the NS1 protein. Site-directed mutagenesis showed that the sequence GGUAGAUA upstream of the initiation codon on segment 7 was required for stimulation.

Analysis of astrovirus serotype 1 RNA, identification of the viral RNA-dependent RNA polymerase motif, and expression of a viral structural protein.

Abstract: We report the results from sequence analysis and expression studies of the gastroenteritis agent astrovirus serotype 1. We have cloned and sequenced 5,944 nucleotides (nt) of the estimated 7.2-kb RNA genome and have identified three open reading frames (ORFs). ORF-3, at the 3' end, is 2,361 nt in length and is fully encoded in both the genomic and subgenomic viral RNAs. Expression of ORF-3 in vitro yields an 87-kDa protein that is immunoprecipitated with a monoclonal antibody specific for viral capsids. This protein comigrates with an authentic 87-kDa astrovirus protein immunoprecipitated from infected cells, indicating that this region encodes a viral structural protein. The adjacent upstream ORF (ORF-2) is 1,557 nt in length and contains a viral RNA-dependent RNA polymerase motif. The viral RNA-dependent RNA polymerase motifs from four astrovirus serotypes are compared. Partial sequence (2,018 nt) of the most 5' ORF (ORF-1) reveals a 3C-like serine protease motif. The ORF-1 sequence is incomplete. These results indicate that the astrovirus genome is organized with nonstructural proteins encoded at the 5' end and structural proteins at the 3' end. ORF-2 has no start methionine and is in the -1 frame compared with ORF-1. We present sequence evidence for a ribosomal frameshift mechanism for expression of the viral polymerase.

Requirement for intron-encoded U22 small nucleolar RNA in 18S ribosomal RNA maturation.

Abstract: The nucleoli of vertebrate cells contain a number of small RNAs that are generated by the processing of intron fragments of protein-coding gene transcripts. The host gene (UHG) for intro-encoded human U22 is unusual in that it specifies a polyadenylated but apparently noncoding RNA. Depletion of U22 from Xenopus oocytes by oligonucleotide-directed ribonuclease H targeting prevented the processing of 18S ribosomal RNA (rRNA) at both ends. The appearance of 18S rRNA was restored by injection of in vitro-synthesized U22 RNA. These results identify a cellular function for an intron-encoded small RNA.

DNA repair gene RAD3 of S. cerevisiae is essential for transcription by RNA polymerase II.

Abstract: THE RAD3 gene of Saccharomyces cerevisiae is required for excision repair of ultraviolet-damaged DNA and is essential for cell viability1. The RAD3-encoded protein shares a high degree of homology with the human ERCC2(XPD) gene product2. Mutations in XPD, besides causing the cancer-prone syndrome xeroderma pigmentosum, can also result in Cockayne's syndrome and trichothiodystrophy3. To investigate the role of RAD3 in viability, we examine here the effect of a recessive, temperature-sensitive (ts) conditional lethal mutation of the gene on transcription by RNA polymerase II. Upon transfer to the restrictive temperature, the rad3-ts mutant rapidly ceases growth and poly(A)+ RNA synthesis is inhibited drastically. Messenger RNA levels of all the genes examined, HIS3, TRP3, STE2, MET19, RAD23, CDC7, CDC9 and ACT1, decline rapidly upon loss of RAD3 activity. The synthesis of heat-shock-inducible HSP26 mRNA and galactose-inducible GAL7 and GAL10 mRNAs is also drastically inhibited in the rad3-ts mutant at the restrictive temperature. The RNA polymerase II transcriptional activity in extract from therad3-ts14 strain is thermolabile, and this in vitro transcriptional defect can be fully corrected by the addition of homogeneous RAD3 protein. These findings indicate that RAD3 protein has a direct and essential role in RNA polymerase II transcription.