13S mRNA Research Articles

Mutations in the leader sequence and initiation codon of the gene for ribosomal protein S20 (rpsT) affect both translational efficiency and autoregulation.

We have transferred the complete structural gene and part of the leader for ribosomal protein S20 of Escherichia coli to a controllable expression vector and have used oligonucleotide-directed mutagenesis to create mutations in the untranslated leader of the plasmid-borne gene. We have assayed for posttranscriptional regulation of the synthesis of S20 after inducing transcription of the mutant S20 mRNA from the expression vector. We found that two mutations lead to loss of feedback control of S20 synthesis: (i) a change of the initiation codon from UUG to AUG and (ii) a replacement of part of the S20 leader with a nonhomologous sequence including an AUG initiation codon. These mutations also lead to increases in both the intrinsic translational efficiency of the plasmid-encoded S20 mRNA in vitro and its half-life in vivo. A double mutation (GA to CT) at residues -3 and -4 relative to the initiation codon does not result in overproduction of S20. Rather, it reduces translational efficiency in vitro and mRNA stability in vivo. Our results demonstrate the fundamental importance of the UUG initiation codon in mediating autogenous repression of S20 synthesis.

Heterogeneity of adenovirus type 5 E1A proteins: multiple serine phosphorylations induce slow-migrating electrophoretic variants but do not affect E1A-induced transcriptional activation or transformation

The 289-amino-acid product encoded by the adenovirus E1A 13S mRNA has several pleiotropic activities, including transcriptional activation, transcriptional repression, and when acting in concert with certain oncogene products, cell transformation. In all cell types in which E1A has been introduced (except bacteria), E1A protein is extensively posttranslationally modified to yield several isoelectric and molecular weight variants. The most striking variant is one that has a retarded mobility, by about Mr = 2,000, in sodium dodecyl sulfate gels. We have investigated the nature of this modification and have assessed its importance for E1A activity. Phosphorylation is responsible for the altered mobility of E1A, since acid phosphatase treatment eliminates the higher apparent molecular weight products. By using several E1A deletion mutants, we show that at least two seryl residues, residing between residues 86 and 120 and 224 and 289, are the sites of phosphorylation and that each phosphorylation can independently induce the mobility shift. However, E1A mutants lacking these seryl residues transcriptionally activate the adenovirus E3 and E2A promoters and transform baby rat kidney cells to near wild-type levels.

EIa-mediated stimulation of the adenovirus EIII promoter involves an enhancer element within the nearby EIIa promoter

The transcriptional induction of adenovirus early genes by the viral immediate early gene EIa constitutes an attractive model system for the study of control mechanisms involved in eucaryotic promoter function. The EIa-mediated activation of the divergently transcribed EIIa early (EIIaE) and EIII promoters was investigated in experiments in which recombinant plasmids containing the entire EIIa-EIII control region were cotransfected with a plasmid expressing the EIa 13S mRNA. First, both promoters were activated by low levels of EIa, but the extent of EIII induction decreased with increasing EIa concentrations, whereas EIIaE stimulation remained unchanged. Second, transcriptional analysis of deletion mutants revealed that an element of the EIIaE promoter contributed to maximal EIa responsiveness of the nearby EIII promoter. This element, located between positions -82 and -71 with respect to the EIIaE major cap site, corresponded to the central portion of an EIa-dependent enhancer, originally mapped between about -110 and -50 (P. Jalinot and C. Kédinger, Nucleic Acids Res. 14:2651-2669, 1986). The implication of these observations in the coordinate expression from the EIIaE and EIII promoters during lytic infection is discussed.

Biosynthesis of reovirus-specified polypeptides: effect of point mutation of the sequences flanking the 5'-proximal AUG initiator codons of the reovirus S1 and S4 genes on the efficiency of mRNA translation.

The effect on translation of site-directed nucleotide substitutions around the 5'-proximal AUG initiation codon of the reovirus s1 mRNA specifying polypeptide sigma 1 and the reovirus s4 mRNA specifying polypeptide sigma 3 was examined. The efficiency of synthesis of the S1-encoded sigma 1 polypeptide and the S4-encoded sigma 3 polypeptide was analyzed in transfected simian COS cells. Mutant s1 mRNAs possessing either GCU AUG G or GCA AUG G sequences surrounding the 5'-proximal sigma 1 AUG were translated with an efficiency comparable to that of the wild-type s1 mRNA which possesses the flanking sequence CCU AUG G. Mutant s4 mRNAs possessing either CCU AUG G or CCA AUG G sequences surrounding the 5'-proximal sigma 3 AUG were translated with an efficiency comparable to that of wild-type s4 mRNA which possesses the flanking sequence GCA AUG G. The s4 mRNAs, both wild-type and mutant, were translated in vivo about five times more efficiently than the s1 mRNAs, both wild-type and mutant. These results suggest that nucleotide positions other than the -3, -2, -1, and +4 positions relative to the 5'-proximal initiator AUG, where the A is +1, play a dominant role in determining the efficiency of translation of these two reovirus mRNAs in vivo.

Secondary structure and expression in vivo and in vitro of messenger RNAs into which upstream AUG codons have been inserted.

We wanted to discover whether the conformation of the mRNA leader sequence is involved in translational fidelity. For this purpose we constructed several mutants of Semliki Forest virus 26S mRNA and inserted AUG codons into the leader sequence. We then analyzed the results of in vitro and in vivo translation of these mRNAs, probed enzymatically the secondary structure and performed minimal energy folding of the transcripts. Our results indicate that the position of a hairpin in the leader sequence determines at which AUG codon downstream from that hairpin translation is initiated.

In vitro splicing of adenovirus E1A transcripts: characterization of novel reactions and of multiple branch points abnormally far from the 3' splice site.

During the analysis of the in vitro alternative splicing of the natural E1A transcript of adenovirus, other minor reactions were detected (Schmitt et al., 1987, Cell 50, 31-39). We report here their characterization. The first reaction concerns the excision of a 216 nucleotide intron delineated by the 9S 5' splice site and a 3' splice site 216 nucleotides downstream. It can occur on the premRNA transcript and the 13S and 12S mRNA species. Strikingly, the reaction uses one of 3 branch points located 51, 55 or 59 residues upstream of the 3' splice site, a distance which is unusually long since all the branch points mapped up to now are located between 18-37 nucleotides of the 3' splice site. The dramatic accumulation of the corresponding lariat intermediates, likely related to this long spacing indicates that the second splicing step is relatively unefficient. The second kind of reaction analysed is a cryptic splicing which uses a 3' splice site generated by the junction of the 13S mRNA exons, and leads to the formation of psi 12S and psi 9S mRNAs. In vitro, this reaction occurs only from a 13S mRNA transcript, and not from the 13S mRNA newly formed in the splicing assay, consistent with what has been observed in vivo. Thus, both the well known alternative and the minor reactions occurring in vivo from E1A premRNA and mRNAs are detected in vitro, implying that most of the alternative splicing machinery is reconstituted in the in vitro system.

Affinities of ribosomal protein S20 and C-terminal deletion mutants for 16S rRNA and S20 mRNA

We have measured the binding of E. coli ribosomal protein S20 and a number of C-terminal deletion mutants to 16S rRNA and in vitro transcribed S20 mRNA. Mutant S20s of interest were synthesized in vitro from the appropriate plasmid templates by coupled transcription and translation. The affinity of S20 produced in vitro for 16S rRNA is 1.2 x 10(7) (M-1) in a gel filtration assay. Removal of as few as 6 residues from the C terminus of S20 results in a sharp loss of binding activity, suggesting the presence of critical residues in this region. Analysis of the amino acid sequence of S20 indicates that these residues may constitute part of a segment of alpha helix. Although S20 is known to autoregulate its own synthesis, we were unable to demonstrate any measurable affinity of S20 for its own mRNA.

Effects of 5'-terminal modifications on the biological activity of defective interfering RNAs of Sindbis virus

We have been studying defective interfering (DI) genomes of the RNA enveloped virus Sindbis virus. Deletion mapping of a DI cDNA demonstrated that only sequences at the 3' and 5' termini of the genome are required for the DI RNA to be biologically active. We constructed a series of cDNAs that transcribe DI RNAs differing only in 5'-terminal sequences. Two of the 5' termini identical to ones found in naturally occurring DI RNAs are the 5' terminus of the virion RNA (DI-549) and the first 142 nucleotides from the 5' terminus of the subgenomic 26S mRNA attached to the 5' terminus of the virion RNA (DI-15). The latter has a 42-nucleotide deletion from nucleotides 25 to 66 in the 26S RNA sequence. These DI RNA transcripts were biologically active, but one (DI-526) which did not have the 42-nucleotide deletion of DI-15 was not replicated. The DI RNA isolated after the presumed amplification of the DI-526 transcript had deleted the first 54 nucleotides of the 26S RNA sequences. The 5' terminus of Sindbis virion RNA contains a stem and loop region that is conserved among alphaviruses. An 11-nucleotide deletion in DI-549 that disrupted this stem and loop rendered this DI RNA inactive. In contrast, this same deletion in DI-15 and one that removed an additional 100 nucleotides of the virion 5' terminus did not prevent its amplification. We did not detect by computer analysis any common secondary structures among the biologically active DI RNAs that distinguished them from those RNAs that were not amplified. Our results support the conclusion that tertiary structure or the ability of the RNA to adapt its structure upon interaction with protein is important in the recognition process.

Adenovirus E1A gene induction of susceptibility to lysis by natural killer cells and activated macrophages in infected rodent cells.

Rodent cells immortalized by the E1A gene of nononcogenic adenoviruses are susceptible to lysis by natural killer (NK) cells and activated macrophages. This cytolysis-susceptible phenotype may contribute to the rejection of adenovirus-transformed cells by immunocompetent animals. Such increased cytolytic susceptibility has also been observed with infected rodent cells. This infection model provided a means to study the role of E1A gene products in induction of cytolytic susceptibility without cell selection during transformation. Deletion mutations outside of the E1A gene had no effect on adenovirus type 2 (Ad2) or Ad5 induction of cytolytic susceptibility in infected hamster cells, while E1A-minus mutant viruses could not induce this phenotype. E1A mutant viruses that induced expression of either E1A 12S or 13S mRNA in infected cells were competent to induce cytolytic susceptibility. Furthermore, there was a correlation between the accumulation of E1A gene products in Ad5-infected cells and the level of susceptibility of such target cells to lysis by NK cells. The results of coinfection studies indicated that the E1A gene products of highly oncogenic Ad12 could not complement the lack of induction of cytolytic susceptibility by E1A-minus Ad5 virus in infected cells and also could not block induction of this infected-cell phenotype by Ad5. These data suggest that expression of the E1A gene of nononcogenic adenoviruses may cause the elimination of infected cells by the immunologically nonspecific host inflammatory cell response prior to cellular transformation. The lack of induction of this cytolysis-susceptible phenotype by Ad12 E1A may result in an increased persistence of Ad12-infected cells in vivo and may lead to an increased Ad12-transformed cell burden for the host.

Induction of cell cycle progression by adenovirus E1A gene 13S- and 12S-mRNA products in quiescent rat cells.

Rat 3Y1 cell lines that express either adenovirus type 12 E1A 13S mRNA or 12S mRNA in response to dexamethasone treatment were established by introduction of recombinant vector DNA containing the E1A 13S- or 12S-mRNA cDNA placed downstream of the hormone-inducible promoter of mouse mammary tumor virus. These cell lines were growth arrested, and the induction of cell cycle progression was analyzed by flow cytometry after switch on of the cDNA by the addition of dexamethasone. The results indicate that the 13S- or 12S-mRNA product alone has the ability to cause progression of the cell cycle at a similar rate. The simultaneous addition of epidermal growth factor accelerated the rate of cell cycle progression in the transition from the G0/G1 phase to the S phase.

Induction of cell cycle progression by adenovirus E1A gene 13S- and 12S-mRNA products in quiescent rat cells.

Rat 3Y1 cell lines that express either adenovirus type 12 E1A 13S mRNA or 12S mRNA in response to dexamethasone treatment were established by introduction of recombinant vector DNA containing the E1A 13S- or 12S-mRNA cDNA placed downstream of the hormone-inducible promoter of mouse mammary tumor virus. These cell lines were growth arrested, and the induction of cell cycle progression was analyzed by flow cytometry after switch on of the cDNA by the addition of dexamethasone. The results indicate that the 13S- or 12S-mRNA product alone has the ability to cause progression of the cell cycle at a similar rate. The simultaneous addition of epidermal growth factor accelerated the rate of cell cycle progression in the transition from the G0/G1 phase to the S phase.

Unusual proopiomelanocortin ribonucleic acids in extrapituitary tissues: intronless transcripts in testes and long poly(A) tails in hypothalamus.

The POMC gene is predominantly expressed in the pituitary gland; it is also expressed in various extrapituitary tissues. While POMC mRNAs of similar size (approximately equal to 1000 nucleotides) are present in the anterior and neurointermediate lobes of the pituitary, other POMC-expressing tissues contain POMC mRNAs of different sizes. Longer POMC mRNAs are observed in the hypothalamus. Using S1 nuclease mapping and mRNA deadenylation by RNase H, we have shown that these large hypothalamic POMC mRNAs have longer poly(A) tails than pituitary POMC transcripts but contain the same transcripted sequences. In contrast, the testes contain POMC transcripts which are smaller than pituitary POMC mRNA. RNase and S1 nuclease mapping analyses suggest that these short transcripts do not contain sequences transcribed from pituitary exons 1 and 2. Indeed, as revealed by primer-extension experiments, these transcripts appear to initiate within exon 3 sequences of the POMC gene. The heterogeneous 5'-ends of these short testicular transcripts map into the NH2-terminal portion of the precursor in the region encoding gamma MSH; if ever translated, these transcripts would produce a form of POMC that would be truncated at the NH2-terminus and therefore would be devoid of any signal peptide sequence. Interestingly, the sequence of the short testicular transcripts corresponds to that of the mouse POMC pseudogene, suggesting that this POMC pseudogene may have derived from genomic integration of testicular transcripts via a cDNA intermediate.

Biosynthesis of reovirus-specified polypeptides: Molecular cDNA cloning and nucleotide sequence of the reovirus serotype 1 lang strain s2 mRNA which encodes the virion core polypeptide σ 2

Human reovirus serotype 1 Lang strain s2 mRNA, which encodes the virion inner capsid core polypeptide sigma 2, was cloned as a cDNA:mRNA heteroduplex in Escherichia coli using phage M13. A complete consensus nucleotide sequence was determined. The Lang strain s2 mRNA is 1331 nucleotides in length and possesses an open reading frame with a coding capacity of 335 amino acids, sufficient to account for a sigma 2 polypeptide of 37,682 daltons. Comparison of the serotype 1 Lang s2 sequence derived from cDNA clones of s2 mRNA with the serotype 3 Dearing S2 sequence derived from cDNA clones of the S2 dsRNA genome segment reveals 86 percent homology at the nucleotide level. The predicted sigma 2 polypeptides of the Lang and Dearing strains display 98 percent homology at the amino acid level. Of 147 silent nt differences in the translated region, 136 were in the third base position of codons.

Promoter trans-activation of protooncogenes c-fos and c-myc, but not c-Ha-ras, by products of adenovirus early region 1A.

The E1A (early region 1A) oncogene products of adenovirus type 2 trans-activate the other early viral transcription units, as well as some cellular promoters. Using a short-term cotransfection assay in murine NIH 3T3 fibroblasts, we show that c-fos and c-myc promoter activities are stimulated by the E1A proteins, whereas c-Ha-ras transcription is not affected. The product of E1A 13S mRNA is responsible for the trans-activation, whereas the 12S mRNA product has no effect. Analysis of the c-fos promoter sequences required for the E1A stimulation shows that responsive sequences are located between positions -402 and -240 upstream of the transcription initiation site. This same region also contains the c-fos serum-responsive element. Furthermore, transcription of the endogenous c-fos gene in HeLa cells is increased after E1A transfection.

Adenovirus E1A requires synthesis of a cellular protein to establish a stable transcription complex in injected Xenopus laevis oocytes.

The Escherichia coli-expressed adenovirus E1A 13S mRNA product injected into Xenopus oocytes was active, as assessed by its ability to stimulate the transcription of an injected gene which is normally responsive to E1A in mammalian cells. In the presence of the protein synthesis inhibitors pactamycin or cycloheximide, E1A was correctly posttranslationally modified (phosphorylated) and transported to the nucleus; but it failed to stimulate the transcription of an injected gene containing the human heat shock protein 70 promoter. The basal (unstimulated) level of transcription of the gene was unaffected by these inhibitors. If oocytes were cultured in the presence of cycloheximide after E1A stimulated transcription, however, the high level of transcription was maintained for several hours without new protein synthesis. Results of competition studies with the same promoter (the heat shock protein 70 promoter) linked to two marked genes demonstrated that once the induction of transcription by E1A took place, the stimulated levels of transcription were maintained, even when they were challenged with excess competitor DNA. Results of these studies suggest that E1A requires the synthesis of a cellular protein to form a stable transcription complex.

Adenovirus E1A requires synthesis of a cellular protein to establish a stable transcription complex in injected Xenopus laevis oocytes.

The Escherichia coli-expressed adenovirus E1A 13S mRNA product injected into Xenopus oocytes was active, as assessed by its ability to stimulate the transcription of an injected gene which is normally responsive to E1A in mammalian cells. In the presence of the protein synthesis inhibitors pactamycin or cycloheximide, E1A was correctly posttranslationally modified (phosphorylated) and transported to the nucleus; but it failed to stimulate the transcription of an injected gene containing the human heat shock protein 70 promoter. The basal (unstimulated) level of transcription of the gene was unaffected by these inhibitors. If oocytes were cultured in the presence of cycloheximide after E1A stimulated transcription, however, the high level of transcription was maintained for several hours without new protein synthesis. Results of competition studies with the same promoter (the heat shock protein 70 promoter) linked to two marked genes demonstrated that once the induction of transcription by E1A took place, the stimulated levels of transcription were maintained, even when they were challenged with excess competitor DNA. Results of these studies suggest that E1A requires the synthesis of a cellular protein to form a stable transcription complex.

Molecular genetic characterization of the mRNA coding for an inducible suppressor factor specific for L-glutamic acid60-L-alanine30-L-tyrosine10.

The suppressor T-cell hybridoma 1556A2.1 can be induced by the monoclonal L-glutamic acid60-L-alanine30-L-tyrosine10 (GAT)-specific suppressor inducer 372B3.5 and soluble GAT to synthesize a disulfide-linked heterodimeric protein (GAT-TsF2), which directly suppresses a primary in vitro immune response to GAT. Induction and synthesis of the GAT-TsF2 protein is correlated with the appearance of specific mRNA, as detected by translation in vitro in a wheat germ cell-free extract of RNA isolated at various times after induction. The mRNA coding for the polypeptide chain that bears a serologically defined I-J determinant (I-J+ chain) appeared 8 hr after induction, whereas the mRNA coding for the antigen-binding chain (AB+ chain) was not detected until 16 hr after induction. The mRNAs coding for the individual chains sedimented as different species, suggesting that the two-chain factor is the product of two genes. The AB+ chain of the 1556A2.1 GAT-TsF2 was synthesized on membrane-bound polysomes, whereas the I-J+ chain was translated on free polysomes. The AB+ chain was synthesized from two independent mRNA species sedimenting at 10 S and 28 S, whereas a single 16S mRNA encoded the I-J+ chain. The in vitro translated I-J+ chain was bound by a monoclonal antibody against the I-J+ determinant of only the appropriate H-2 haplotype. These results suggest that posttranslational modification, including glycosylation, is not required for biological activity or for expression of the I-J epitope on the GAT-TsF2 molecule.

Biosynthesis of reovirus-specified polypeptides Efficiency of expression of cDNAs of the reovirus S1 and S4 genes in transfected animal cells differs at the level of translation

Full-length cDNAs of the reovirus serotype 1 Lang strain S1 and S4 genes were cloned in Escherichia coli using bacteriophage M13 and expressed in monkey COS cells under the control of the SV40 late promoter using the eukaryotic expression vector pJC119. The s1-encoded σ1 and s4-encoded σ3 gene products were expressed in transfected COS cells and were indistinguishable from the authentic σ1 and σ3 polypeptides synthesized in reovirion-infected COS cells. The relative translational efficiencies of the s1 and s4 mRNAs in transfected COS cells were similar to the efficiencies observed in virion-infected cells; the s4 mRNA was translated approximately five times more efficiently than the s1 mRNA. Our results suggest that the differential translation of the reovirus s1 and s4 mRNAs in vivo may be attributed to intrinsic structural properties of the individual mRNAs and is independent of competition with other viral mRNAs.

Nucleotide sequence of the genome region encoding the 26S mRNA of eastern equine encephalomyelitis virus and the deduced amino acid sequence of the viral structural proteins.

The 26S mRNA and most of the nsP4 encoding regions of the eastern equine encephalomyelitis (EEE) viral genome have been cloned. Excluding the poly(A) tail, the 26S mRNA region was determined to be 4139 nucleotides long and to share the same general organization as that of other alphaviruses. A highly conserved region of 19 nucleotides, the putative transcriptase recognition site for 26S mRNA synthesis, was present at the 26S/42S junction region of the 42S genomic RNA. Translation of the 26S mRNA began at the first AUG (positions 59 to 61) initiation codon and continued with an open reading frame that coded for a polyprotein of 1258 amino acids ending at a UAA ochre termination codon (positions 3776 to 3778). All four putative posttranslational cleavage sites used to generate the capsid, E3, E2, 6K and E1 proteins were conserved. Transmembrane domains present in the EEE virus structural polyprotein have been identified and their functions discussed. Pairwise comparison of the deduced amino acid sequences of the polyproteins of five alphaviruses (EEE, Venezuelan equine encephalitis, Sindbis, Semliki Forest and Ross River viruses) revealed EEE virus to be more closely related to VEE virus than to the other three viruses.

Differential splicing yields novel adenovirus 5 E1A mRNAs that encode 30 kd and 35 kd proteins.

In addition to the protein products of the adenovirus E1A 13S and 12S mRNAs, monoclonal antibodies specific for the E1A proteins immunoprecipitate polypeptides with relative mol. wt of 30,000 (30 kd) and 35,000 (35 kd) from extracts of infected cells. The 30 kd and 35 kd proteins are encoded by novel mRNAs referred to as the 10S and 11S mRNAs, respectively. These two mRNAs arise from differential splicing of the E1A precursor RNA. For the 10S mRNA, the precursor is spliced twice, once removing the region between nucleotides 637 and 854 and once between 974 and 1229. The splice between nucleotides 974 and 1229 is identical to the one used for the processing of the 12S mRNA. Synthesis of the 11S mRNA also utilizes two splicing events. One of these is identical to the 637/854 splice of the 10S mRNA, and the other removes the region between nucleotides 1112 and 1229, a splice junction also found in the 13S mRNA. All four mRNAs used the same reading frame and, therefore, code for related proteins. The products of the 10S and 11S mRNAs are identical to the products of the 12S and 13S mRNAs, respectively, except for an internal stretch of 27 amino acids removed by the 637/854 splice. Within this segment is a group of amino acid residues that is highly conserved between different adenovirus serotypes. Mutant adenoviruses in which the wild-type E1A sequences have been replaced with cDNA copies of the 10S or 11S mRNAs are defective for growth on HeLa cells suggesting that this region is important for viral growth.(ABSTRACT TRUNCATED AT 250 WORDS)