Amber, ochre and opal suppressor tRNA genes derived from a human serine tRNA gene.

Amber, ochre and opal suppressor tRNA genes have been generated by using oligonucleotide directed site-specific mutagenesis to change one or two nucleotides in a human serine tRNA gene. The amber and ochre suppressor (Su+) tRNA genes are efficiently expressed in CV-1 cells when introduced as part of a SV40 recombinant. The expressed amber and ochre Su+ tRNAs are functional as suppressors as demonstrated by readthrough of the amber codon which terminates the NS1 gene of an influenza virus or the ochre codon which terminates the hexon gene of adenovirus, respectively. Interestingly, several attempts to obtain the equivalent virus stock of an SV40 recombinant containing the opal suppressor tRNA gene yielded virus lacking the opal suppressor tRNA gene. This suggests that expression of an efficient opal suppressor derived from a human serine tRNA gene is highly detrimental to either cellular or viral processes.     

Synthesis of an ochre suppressor tRNA gene and expression in mammalian cells.

We have used site-specific mutagenesis to change the anticodon of a Xenopus laevis tyrosine tRNA gene so that it would recognize ochre codons. This tRNA gene is expressed when amplified in monkey cells as part of a SV40 recombinant and efficiently suppresses termination at both the ochre codon separating the adenovirus 2 hexon gene from a 23-kd downstream gene and the ochre codon at the end of the NS1 gene of influenza virus A/Tex/1/68. Termination at an amber codon of a NS1 gene of another influenza virus strain was not suppressed by the (Su+) ochre gene suggesting that in mammalian cells amber codons are not recognized by ochre suppressor tRNAs. Finally, microinjection into mammalian cells of both (Su+) ochre tRNA genes and selectible genes containing ochre nonsense mutations gives rise to colonies under selective conditions. We conclude that it should be possible to isolate a wide assortment of mammalian cell lines with ochre suppressor activity.     

Construction of a vector, pRSVcatamb38, for the rapid and sensitive assay of amber suppression in human and other mammalian cells.

We describe the generation of an amber mutation in the chloramphenicol acetyltransferase (cat) gene of the mammalian cell transfection vector pRSVcat (Gorman et.al. (1982), Proc.Natl.Acad.Sci. 79 6777-6791). We have demonstrated the in vivo suppression of this amber mutation in monkey and human cells by co-transfection with a synthetic Xenopus suppressor tRNATyr under the control of the late SV40 promoter. The vector, pRSVcatamb38, may be used to quantitate amber suppression in various mammalian cells.     

Efficient expression of small RNA polymerase III genes from a novel simian virus 40 vector and their effect on viral gene expression.

In the past, simian virus 40 (SV40) has been used as a cloning vehicle to clone foreign genes by substituting portions of the viral genome vital for viral replication. Propagation of these defective viruses required a helper virus and the recombinant viruses obtained could be grown only as a mixture. In this study, we describe a novel nondefective SV40 vector to clone small RNA polymerase III genes. Two small RNA polymerase III genes, an amber suppressor human serine tRNA gene and the adenovirus (Ad) VAI RNA gene, were cloned in the intron region of the large-T antigen gene of SV40 after deleting DNA sequences coding for the small-t polypeptide. The recombinant viruses grew to wild type levels and showed no growth defects. When CV-1p cells were infected with these viruses, the cloned RNA polymerase III genes were expressed at high levels at late times. Interestingly, large amounts VAI RNA in CV-1p cells infected with SV40-VA recombinant virus, did not enhance translation of viral mRNAs significantly but did lead to a 3 to 4 fold increase in the steady state levels of large-T mRNA suggesting a novel function for VAI RNA in SV40 infected monkey cells. Furthermore, VAI mutants which fail to function in Ad infected human cells also failed to enhance the levels of large-T mRNAs in monkey cells infected with SV40. The simple SV40 vector described here may be useful to study the structure and function of small RNA polymerase III genes in the context of a eucaryotic chromosome. In addition, the nondefective recombinant SV40 which expresses the suppressor tRNA gene at high levels may provide a useful helper system to propagate animal viruses with amber mutations in essential genes.     

Nonsense and missense translational suppression in plant cells mediated by tRNALys

A nuclear tRNA^Lys gene from Arabidopsis thaliana was cloned and mutated so as to express tRNAs with altered anticodons which bind to a UAG nonsense (amber) codon and to the Arg (AGG), Asn (AAC,AAT), Gln (CAG) or Glu (GAG) codons. Concomitantly, a codon in the firefly luciferase gene for a functionally important Lys was altered to an amber codon, or to Arg, Asn, Gln, Glu, Thr and Trp codons, so as to construct reporter genes reliant upon incorporation of Lys. The altered tRNA^Lys and luciferase genes were introduced into Nicotiana benthamiana protoplasts and expression of the mutated tRNAs was verified by translational suppression of the mutant firefly luciferase genes. Expression of the amber suppressor tRNA _CUA ^Lys from non-replicative vectors promoted 10–40% suppression of the luciferase nonsense reporters while expression of the amber and missense tRNA^Lys suppressor genes from a geminivirus vector capable of replication promoted 30–80% suppression of the luciferase nonsense reporter and up to 10% suppression of the luciferase missense reporters with Arg, Asn, Gln and Glu codons.     

Tetracycline-Regulated Suppression of Amber Codons in Mammalian Cells

As an approach to inducible suppression of nonsense mutations in mammalian cells, we described recently an amber suppression system in mammalian cells dependent on coexpression of Escherichia coli glutaminyl-tRNA synthetase (GlnRS) along with the E. coli glutamine-inserting amber suppressor tRNA. Here, we report on tetracycline-regulated expression of the E. coli GlnRS gene and, thereby, tetracycline-regulated suppression of amber codons in mammalian HeLa and COS-1 cells. The E. coli GlnRS coding sequence attached to a minimal mammalian cell promoter was placed downstream of seven tandem tetracycline operator sequences. Cotransfection of HeLa cell lines expressing a tetracycline transactivator protein, carrying a tetracycline repressor domain linked to part of a herpesvirus VP16 activation domain, with the E. coli GlnRS gene and the E. coli glutamine-inserting amber suppressor tRNA gene resulted in suppression of the amber codon in a reporter chloramphenicol acetyltransferase gene. The tetracycline transactivator-mediated expression of E. coli GlnRS was essentially completely blocked in HeLa or COS-1 cells grown in the presence of tetracycline. Concomitantly, both aminoacylation of the suppressor tRNA and suppression of the amber codon were reduced significantly in the presence of tetracycline.     

A domain of SV40 capsid polypeptide VP1 that specifies migration into the cell nucleus.

In order to identify the determinants responsible for the nuclear migration of simian virus 40 (SV40) polypeptide VP1, the 5'-terminal portion of the SV40 VP1 gene was fused with the complete cDNA sequence of poliovirus capsid polypeptide VP1 and the hybrid gene was inserted into an SV40 vector in place of the normal SV40 VP1 gene. Deletions of various length were generated in the SV40 VP1 portion of the hybrid gene, resulting in a set of truncated genes encoding 2-40 NH2-terminal amino acids from SV40 VP1, followed by poliovirus VP1. Monkey kidney cells were infected by the deleted hybrid viruses in the presence of an early SV40 amber mutant as helper, and the subcellular localization of the fusion proteins was determined by indirect immunofluorescence using an anti-poliovirus VP1 immune serum. The presence of the first 11 NH2-terminal amino acids from SV40 VP1 was found to be sufficient to target the fusion protein to the cell nucleus. Deletions extending from the NH2- towards the COOH-terminal end of the protein were next generated. Transport of the SV40 VP1-poliovirus VP1 fusion polypeptide to the nucleus was abolished when the first eight amino acids from SV40 VP1 were deleted. Thus the sequence of the first eight NH2-terminal amino acids of SV40 VP1 appears to contain a nuclear migration signal which is sufficient to target the protein to the cell nucleus.     

A nucleotide change in the anticodon of an Escherichia coli serine transfer RNA results in supD-amber suppression.

The tRNAs specified by the wild type and amber suppressor alleles of the Escherichia coli supD gene have been identified, and their primary structures determined. The sequences differ by a single nucleotide in the middle of the anticodon. A CUA anticodon allows the suppressor tRNA to read the UAG stop codon; the CGA anticodon in the minor serine tRNA species from which the suppressor is derived is specific for the serine codon UCG.     

Expression of a X. laevis tRNATyr gene in mammalian cells.

Expression of a X. laevis tRNATyr gene has been studied in mammalian cells. This tRNATyr gene has a 13 base intervening sequence adjacent to its anticodon. A fragment containing the tRNATyr gene was cloned into the late region of SV40. Cells infected with a recombinant virus stock vastly overproduce a tRNATyr that is properly spliced, processed and modified. It was also found that the X. laevis tRNATyr is identical or nearly identical to an endogenous tRNATyr of monkey kidney cells. The possibility of using the X. laevis tRNATyr gene to create an amber suppressor for mammalian cells is discussed.     

Site-specific incorporation of non-natural amino acids into proteins in mammalian cells with an expanded genetic code

We describe a detailed protocol for incorporating non-natural amino acids, 3-iodo-L-tyrosine (IY) and p-benzoyl-L-phenylalanine (pBpa), into proteins in response to the amber codon (the UAG stop codon) in mammalian cells. These amino acids, IY and pBpa, are applicable for structure determination and the analysis of a network of protein-protein interactions, respectively. This method involves (i) the mutagenesis of the gene encoding the protein of interest to create an amber codon at the desired site, (ii) the expression in mammalian cells of the bacterial pair of an amber suppressor tRNA and an aminoacyl-tRNA synthetase specific to IY or pBpa and (iii) the supplementation of the growth medium with these amino acids. The amber mutant gene, together with these bacterial tRNA and synthetase genes, is introduced into mammalian cells. Culturing these cells for 16-40 h allows the expression of the full-length product from the mutant gene, which contains the non-natural amino acid at the introduced amber position. This method is implemented using the conventional tools for molecular biology and treating cultured mammalian cells. This protocol takes 5-6 d for plasmid construction and 3-4 d for incorporating the non-natural amino acids into proteins.     

Recombination Between Endogenous and Exogenous Simian Virus 40 Genes. I. Rescue of a Simian Virus 40 Temperature-Sensitive Mutant by Passage in Permissive Transformed Monkey Lines

Passage of the simian virus 40 (SV40) temperature-sensitive (ts) mutant tsD202 at the permissive temperature in each of three permissive lines of SV40-transformed monkey CV1 cells resulted in the emergence of temperature-insensitive virus, which plated like wild-type SV40 at the restrictive temperature on normal CV1 cells. In independent experiments, the amount of temperature-insensitive virus that appeared after passage on transformed cells was from 10(3)- to 10(6)-fold greater than the amount of ts-revertant virus that appeared after an equal number of passages in nontransformed CV1 cells. The virus rescued by passage on transformed cells bred true upon sequential plaque purification, plated on normal CV1 cells with single-hit kinetics at the restrictive temperature, and displayed no selective growth advantage on transformed cells compared to non-transformed cells. Hence, the reversion of the ts phenotype is neither due to complementation effects nor to the selection of preexisting revertants, which grow better on transformed cells. In the accompanying article (T. Vogel et al., J. Virol. 24:541-550, 1977), we present biochemical evidence that the rescue of tsD202 mediated by passage on transformed cells is due to recombination with the resident SV40 genome. Parallel experiments in which tsA, tsB, and tsC SV40 mutants were passaged in each of the three permissive lines of SV40-transformed monkey cells resulted in either only borderline levels of rescue (tsA mutants) or no detectable rescue (tsB and tsC mutants). Evidence is presented that the resident SV40 genome of the transformed monkey lines is itself a late ts mutant, and we suggest that this accounts for the lack of detectable rescue of the tsB and tsC mutants. We furthermore suggest that the borderline level of rescue observed with two tsA mutants is related to a previous finding (Y. Gluzman et al., J. Virol. 22:256-266, 1977) which indicated that the resident SV40 genome of the permissive transformed monkey cells is defective in the function required for initiation of viral DNA synthesis.     

Effect of mutation to streptomycin resistance on amber suppressor genes

Three classes of nonidentical streptomycin-resistant mutations were distinguished in Escherichia coli by their effect on the efficiency of suppression by an amber suppressor gene, sup E. The first class of mutation caused a strong restriction in efficiency of suppression of an amber codon in various cistrons of phage lambda and in an alkaline phosphatase structural gene of E. coli. The second class caused weak restriction, and the third class caused no restriction. The restrictive effect of the streptomycin resistance mutation of the first class on the sup E gene was reduced by addition of streptomycin. This mutation had little effect on efficiencies of suppression by amber suppressor genes sup D and sup F. Analyses on the alkaline phosphatase formed in the suppressor strain indicated that mutation to restrictive streptomycin resistance causes a reduction in translation of the amber codon in the alkaline phosphatase structural gene.     

Simian virus 40-transformed human cells that express large T antigens defective for viral DNA replication.

Many types of human cells cultured in vitro are generally semipermissive for simian virus 40 (SV40) replication. Consequently, subpopulations of stably transformed human cells often carry free viral DNA, which is presumed to arise via spontaneous excision from an integrated DNA template. Stably transformed human cell lines that do not have detectable free DNA are therefore likely to harbor harbor mutant viral genomes incapable of excision and replication, or these cells may synthesize variant cellular proteins necessary for viral replication. We examined four such cell lines and conclude that for the three lines SV80, GM638, and GM639, the cells did indeed harbor spontaneous T-antigen mutants. For the SV80 line, marker rescue (determined by a plaque assay) and DNA sequence analysis of cloned DNA showed that a single point mutation converting serine 147 to asparagine was the cause of the mutation. Similarly, a point mutation converting leucine 457 to methionine for the GM638 mutant T allele was found. Moreover, the SV80 line maintained its permissivity for SV40 DNA replication but did not complement the SV40 tsA209 mutant at its nonpermissive temperature. The cloned SV80 T-antigen allele, though replication incompetent, maintained its ability to transform rodent cells at wild-type efficiencies. A compilation of spontaneously occurring SV40 mutations which cannot replicate but can transform shows that these mutations tend to cluster in two regions of the T-antigen gene, one ascribed to the site-specific DNA-binding ability of the protein, and the other to the ATPase activity which is linked to its helicase activity.     

Properties of permissive monkey cells transformed by UV-irradiated simian virus 40.

African green monkey cells (CV1 line) were infected with UV-irradiated simian virus 40 (SV40), and permissive lines of stably transformed cells were established. These cell lines display the SV40 T-antigen and the growth characteristics typical of nonpermissive transformed cells (e.g., reduced cell density inhibition, reduced serum dependence, ability to overgrow normal cells, and colony formation in soft agar). The level of permissiveness to superinfecting SV40 is fully comparable with that of nontransformed CV1 and BSC-1 lines. The transformed monkey lines also support SV40 plaque production under agar. By Cot analysis, the transformed permissive cells contain, on an average, 1 to 2 SV40 genome equivalents, and the majority of the viral sequences are associated with the high-molecular-weight cellular DNA. No spontaneous production of infectious SV40 has been observed. The transformed permissive monkey cells failed to support the replication of SV40 tsA mutants at the restrictive temperature. To account for this, it is suggested that the gene A product has separate functions for transformation and initiation of viral DNA synthesis, and only the former function is expressed in the transformed permissive monkey cells.     

Retroviral gag gene amber codon suppression is caused by an intrinsic cis-acting component of the viral mRNA.

In some type C retroviruses, translation of the pol gene appears to require translational suppression of the proximal gag amber codon. To identify the region of the viral nucleic acid responsible for synthesis of the pol gene products, a 300-base-pair DNA fragment containing the stop codon from a type C murine virus (AK virus) was inserted into the Escherichia coli lacZ gene such that the translational reading frame was maintained. Introduction of the resulting fusion gene into cells resulted in the suppression of the viral stop codon. As measured by beta-galactosidase production, suppression occurred at a frequency of approximately 10%. Suppression could occur in at least several vertebrate cell types and was not augmented by virus replication or the expression of viral gene products. This indicates that gag amber codon suppression does not require augmented levels of suppressor tRNA species.     

Transformation of isolated rat hepatocytes with simian virus 40

Rat hepatocytes were transformed by simian virus 40 (SV40). Hepatocytes from two different strains of rats and a temperature-sensitive mutant (SV40tsA 1609), as well as wild-type virus were used. In all cases, transformed cells arose from approximately 50% of the cultures containing hepatocytes on collagen gels or a collagen gel-nylon mesh substratum. Cells did not proliferate in mock-infected cultures. SV40-transformed hepatocytes were epithelial in morphology, retained large numbers of mitochondria, acquired an increased nucleus to cytoplasm ratio, and contained cytoplasmic vacuoles. Evidence that these cells were transformed by SV40 came from the findings that transformants were 100% positive for SV40 tumor antigen expression, and that SV40 was rescued when transformed hepatocytes were fused with monkey cells. All SV40-transformed cell lines tested formed clones in soft agarose. Several cell lines transformed by SV40tsA 1609 were temperature dependent for colony formation on plastic dishes. Transformants were diverse in the expression of characteristic liver gene functions. Of eight cell lines tested, one secreted 24% of total protein as albumin, which was comparable to albumin production by freshly plated hepatocytes; two other cell lines produced 4.2 and 5.7%, respectively. Tyrosine aminotransferase activity was present in five cell lines tested but was inducible by dexamethasone treatment in only two. We conclude from these studies that adult, nonproliferating rat hepatocytes are competent for virus transformation.