Retrovirus infection and aging: Increase in UAG suppressor tRNA expression in aged mice

The effect of aging on expression of a natural glutamine suppressor tRNA (tRNA(Gln(UmUG))) was studied in different tissues of mice; this tRNA recognizes UAG and inserts glutamine at the site of the termination codon. The level of tRNA(Gln(UmUG)) was found to be strongly increased in aged mice, compared to newborn and mature animals. An elevated expression of tRNA(Gln(UmUG)) has also been found in retrovirus-infected cells; in Moloney virus-infected cells the suppressor tRNA allows to read-through the UAG codon within the retroviral protease gene. We suggest that the increase in the level of tRNA(Gln(UmUG)) may influence retroviral gene expression with age.     

Inhibition of expression of natural UAG suppressor glutamine tRNA in HIV-infected human H9 cells in vitro by Avarol

HTLV-IIIB-infected H9 cells are shown to contain a high level of the natural UAG suppressor glutamine tRNA(UmUG Gln); this tRNA has been demonstrated to be required for the synthesis of Moloney murine leukemia virus (Mo-MuLV)-encoded protease. After cultivation of HTLV-IIIB-infected H9 cells with Avarol at a concentration (1 microgram/ml), previously found to protect the cells against the cytopathic effects of HTLV-III, an almost complete inhibition of the synthesis of the tRNA(UmUG Gln) was observed. Moreover, we obtained some evidence that the processing of the HTLV-III precursor protein p53 to p24 is inhibited by Avarol in infected cells, suggesting that the compound interferes with the expression of the viral protease gene.     

Initiation of protein synthesis from a termination codon.

We show that the amber termination codon UAG can initiate protein synthesis in Escherichia coli. We mutated the initiation codon AUG of the chloramphenicol acetyltransferase (CAT) gene to UAG (CATam1) and translated mRNA derived from the mutant CAT gene in E. coli S-30 extracts. A full-length CAT polypeptide was synthesized in the presence of tRNA(fMetCUA), a mutant E. coli initiator tRNA which has a change in the anticodon sequence from CAU to CUA. Addition of purified E. coli glutaminyl-tRNA synthetase substantially stimulated synthesis of the CAT polypeptide. Thus, initiation of protein synthesis with UAG and tRNA(fMetCUA) most likely occurs with glutamine and not methionine. The UAG codon also initiates protein synthesis in vivo. To eliminate a weak secondary site of initiation from AUC, the fifth codon, we further mutagenized the CATam1 gene at codons 2 (GAG----GAC) and 5 (AUC----ACC). Transformation of E. coli with the resultant CATam1.2.5 gene yielded transformants that synthesized CAT polypeptide and were resistant to chloramphenicol only when they were also transformed with the mutant tRNA(fMetCUA) gene. Immunoblot analyses and assays for CAT enzyme activity in extracts from transformed cells indicate that initiation from UAG is efficient, 60-70% of that obtained from AUG. Initiation of protein synthesis from UAG using a mutant initiator tRNA allows tightly regulated expression of specific genes. This may be generally useful for overproduction in E. coli and other eubacteria of proteins which are toxic to these cells.     

Tetrahymena thermophila glutamine tRNA and its gene that corresponds to UAA termination codon.

Nucleotide sequence analysis of one of several tRNA genes cloned from Tetrahymena thermophila macronuclear DNA indicated that it corresponds to a tRNA species having TTA as anticodon. Subsequently, the tRNA species corresponding to that gene was isolated and its nucleotide sequence was determined by post-labeling techniques. The nucleotide sequence was found to be pG-G-U-U-C-C-A-U-A-m2G-U-A-psi-A-G-D-G-G-D- D-A-G-U-A-C-U-G-G-G-G-A-Cm-U-Um-U-A-i6A-A-psi-C-C-C-U-U-G-A-C- m5C-U-G-G-G-U-psi-C-G-m1A-A-U-C-C-C-A-G-U-G-G-G-A-C-C-U-C-C-AOH. This tRNA sequence exactly matched the DNA sequence of the corresponding tRNA gene. The first position of anticodon is 2'-O-methyluridine (Um), forming UmUA as the anticodon, which presumably recognizes the ochre termination codon UAA. This tRNA species is aminoacylated with glutamine by a Tetrahymena crude aminoacyl tRNA synthetase fraction, suggesting that ochre termination codon is used as a glutamine codon during cytoplasmic protein synthesis in Tetrahymena.     

Identification of amino acids inserted during suppression of UAA and UGA termination codons at the gag-pol junction of Moloney murine leukemia virus.

Expression of the murine leukemia virus pol gene occurs by translational readthrough of an in-frame UAG codon between the gag and pol coding regions. In a previous study, we mutated the UAG codon to UAA or UGA and demonstrated that both of these termination codons could be suppressed in reticulocyte lysates and in infected cells with the same efficiency as UAG. We now report the identity of the amino acids inserted in vitro in response to UAA and UGA in fusion products containing the gag-pol junction region. The results show that UAA, like UAG, directs the incorporation of glutamine, whereas UGA directs the incorporation of three amino acids, arginine, cysteine, and tryptophan. To our knowledge, this is the first report indicating misreading of UAA as glutamine and UGA as arginine and cysteine in higher eukaryotes. Interestingly, although our protein synthesis system presumably contains other known UAG and UGA suppressors, these tRNAs did not suppress the termination codons in our experiments. Thus, it seems possible that the sequence surrounding the gag-pol junction not only promotes suppression but also helps determine which tRNAs function in suppression.     

Evidence that a downstream pseudoknot is required for translational read-through of the Moloney murine leukemia virus gag stop codon.

Approximately 5% of the ribosomes translating the gag gene of murine leukemia viruses read through the UAG terminator and translate the in-frame pol gene to produce the gag-pol fusion polyprotein, the sole source of the pol gene products. We show that a pseudoknot located eight nucleotides 3' of the UAG codon in the Moloney murine leukemia virus is required for read-through. This requirement is markedly different from that known to be involved in other cases of read-through but surprisingly similar to some stimulatory sequences known to promote ribosomal frameshifting.     

An amber suppressor tRNA gene derived by site-specific mutagenesis: cloning and function in mammalian cells.

We describe the synthesis, cloning, expression, and in vivo function of a suppressor tRNA gene in mammalian cells. By using "primer-directed mutagenesis" on a Xenopus laevis tyrosine tRNA gene cloned into the recombinant single-strand phage M13mp5, we have generated an amber suppressor tRNA gene that has a nucleotide change--GTA leads to CTA--in the anticodon sequence. The suppressor (Su) tRNA gene was introduced into monkey kidney cells (CV-1) by using simian virus 40 (SV40) DNA as vector (SV40-tRNATyrSu+). CV-1 cells infected with virus containing the mutant, but not the wild-type, tRNA gene produce a functional amber suppressor tRNA as indicated by suppression of amber mutations in co-infecting adenovirus serotype 2-SV40 hybrids. Further evidence that suppression of these amber mutations is tRNA mediated was derived by isolation of total tRNA from CV-1 cells infected with the SV40-tRNATyr (Su+) recombinant and its use in demonstration of read through of an amber codon during in vitro translation of tobacco mosaic virus RNA in reticulocyte extracts. Interestingly, the amplification of an amber suppressor gene in CV-1 cells does not interfere with SV40 production, suggesting that suppression of amber codons may not be very deleterious to mammalian cell metabolism.     

An aminoacyl-tRNA synthetase that specifically activates pyrrolysine

Pyrrolysine, the 22nd cotranslationally inserted amino acid, was found in the Methanosarcina barkeri monomethylamine methyltransferase protein in a position that is encoded by an in-frame UAG stop codon in the mRNA. M. barkeri encodes a special amber suppressor tRNA (tRNA(Pyl)) that presumably recognizes this UAG codon. It was reported that Lys-tRNA(Pyl) can be formed by the aminoacyl-tRNA synthetase-like M. barkeri protein PylS [Srinivasan, G., James, C. M. & Krzycki, J. A. (2002) Science 296, 1459-1462], whereas a later article showed that Lys-tRNA(Pyl) is synthesized by the combined action of LysRS1 and LysRS2, the two different M. barkeri lysyl-tRNA synthetases. Pyrrolysyl-tRNA(Pyl) formation was presumed to result from subsequent modification of lysine attached to tRNA(Pyl). To investigate whether pyrrolysine can be directly attached to tRNA(Pyl) we chemically synthesized pyrrolysine. We show that PylS is a specialized aminoacyl-tRNA synthetase for charging pyrrolysine to tRNA(Pyl); lysine and tRNA(Lys) are not substrates of the enzyme. In view of the properties of PylS we propose to name this enzyme pyrrolysyl-tRNA synthetase. In contrast, the LysRS1:LysRS2 complex does not recognize pyrrolysine and charges tRNA(Pyl) with lysine. These in vitro data suggest that Methanosarcina cells have two pathways for acylating the suppressor tRNA(Pyl). This would ensure efficient translation of the in-frame UAG codon in case of pyrrolysine deficiency and safeguard the biosynthesis of the proteins whose genes contain this special codon.     

Molecular cloning of murine endogenous viral sequences and expression of a newly constructed recombinant murine leukemia virus DNA in transfected mink cells.

In the process of molecularly cloning unintegrated proviral DNA from NIH-3T3 mouse cells infected with Rauscher murine leukemia virus, we observed the occurrence of clones with inserts smaller than the expected Rauscher murine leukemia virus fragments. The insert of one of these clones, lambda.Xe-1, was characterized in more detail. It had a size of 3.5 kilobases. The restriction map was similar but not identical to that of the envelope regions of Moloney and Rauscher murine leukemia viruses. After ligation to previously cloned Moloney murine leukemia viral sequences and transfection of the ligated DNA into mink lung cells a nondefective xenotropic murine leukemia virus, XH-19, was isolated. Restriction mapping of proviral DNA isolated from mink lungs cells chronically infected with XH-19 showed the presence of Moloney murine leukemia virus-derived sequences coupled to xenotropic viral sequences.     

Replication-competent Moloney murine leukemia virus carrying a bacterial suppressor tRNA gene: selective cloning of proviral and flanking host sequences.

A bacterial suppressor tRNA gene was introduced into the long terminal repeat of the Moloney murine leukemia virus (Mo-MuLV) proviral genome to construct a retrovirus that allows easy cloning of the provirus with flanking host sequences. A replication competent virus, Mo-MuLV sup containing a tRNA amber suppressor gene, was derived that replicates to high titers in tissue culture cells and stably transduces the bacterial gene. The recombinant virus can efficiently replicate in vivo when microinjected into midgestation embryos or when injected into newborn mice and displays the same tissue tropism as wild-type Mo-MuLV. The suppressor gene in Mo-MuLV sup is functional in bacteria and allows efficient recovery of proviral genomes. This was shown by ligation of DNA from infected cells to phage lambda Charon 4A arms and selective growth of recombinant phages on su- host cells. All recovered phages contained Mo-MuLV proviral sequences and, because of the high cloning capacity of phage lambda, 1-11 kilobases of flanking host DNA. This virus should facilitate studying virus-host interactions in tissue culture cells and in animals.     

Construction of a composite tRNA gene by anticodon loop transplant.

By using sites for the restriction nuclease Hpa II, the information for the anticodon stem and loop of an altered Su+2 amber suppressor tRNA (a mutant of tRNAGln) has been transplanted to a specially prepared tRNATrp gene, which lacks it homologous anticodon stem and loop sequence. The resulting tRNA gene was cloned under lac operator-promoter control. The result is a functional, hybrid, amber-suppressor tRNA that can exhibit a moderately high efficiency in translation. It appears less efficient, however, than Su+7 tRNA, the amber suppressor that results from a direct anticodon mutation in tRNATrp. As judged by its suppressor spectrum, which is almost identical to the spectra of Su+2, and Su+7, the recomposed tRNA inserts glutamine at amber sites. This experiment is the prototype of a series of construction that examine the role of the nucleotides in the anticodon region.     

The sup-7(st5) X gene of Caenorhabditis elegans encodes a tRNATrpUAG amber suppressor.

In earlier studies, we identified in Caenorhabditis elegans two informational suppressors sup-5 III and sup-7 X and recently showed that these suppressors acted via an altered tRNA to suppress translational termination at amber (UAG) stop codons. We now show that the sup-7 (st5) suppressor is a tRNATrpUAG amber suppressor. These studies utilized a radiolabeled purified tRNA fraction to identify hybridizing genomic sequences in a phage genomic library. DNA sequence analysis of the hybridizing segment of one clone showed that the probe recognized a tRNATrpUGG sequence. The sup-7 gene was shown to be one of an 11 or 12 member tRNATrp family by Southern blot analysis, taking advantage of an Xba I restriction site induced in the anticodon sequence by the mutational event to suppressor. Sequence analysis of a recombinant lambda clone containing sup-7 gene proved that sup-7(st5) is a tRNATrpUAG. This conclusive proof of the nature of sup7(st5) will permit unambiguous interpretation in genetic applications, and the availability of the cloned sequences may allow the sup-7 gene to be used to select for the reintroduction of DNA into C. elegans.     

Physiological levels of normal tRNA(CAGGln) can effect partial suppression of amber mutations in the yeast Saccharomyces cerevisiae.

A number of ciliated protozoa are known to read the stop codons UAA and UAG as sense codons that specify glutamine during protein synthesis. In considering evolutionary mechanisms for this curious divergence from the standard genetic code, we propose the existence of progenitor tRNAs for glutamine that can weakly suppress UAA and UAG codons. It has been previously shown that multicopy plasmids that overexpress normal tRNA(CAAGln) and tRNA(CAGGln) genes from the yeast Saccharomyces cerevisiae can partially suppress a number of yeast ochre and amber mutations, respectively. In the present study we show that the tRNA(CAGGln) gene can also function as a weak amber suppressor when expressed in cells at physiological levels. This observation is consistent with a role of tRNA(CAGGln) as an evolutionary progenitor of tRNAs that strongly decode UAG codons.     

Characterization and nucleotide sequence of a chicken gene encoding an opal suppressor tRNA and its flanking DNA segments.

A naturally occurring opal suppressor serine tRNA has been purified from chicken liver and used as a probe to isolate the corresponding gene from a library of chicken DNA in bacteriophage lambda. This minor tRNA is encoded by a single-copy gene that is not part of a tRNA gene cluster. DNA sequence analysis of the gene and its flanking DNA segments shows that the gene is encoded in an 87-base-pair segment without intervening sequences and specifies a tRNA that reads the termination codon UGA. This gene has additional nucleotides in the 5' internal promoter region but has a normal 3' internal promoter sequence and the usual termination signal.     

Mutants of Escherichia coli initiator tRNA that suppress amber codons in Saccharomyces cerevisiae and are aminoacylated with tyrosine by yeast extracts.

We recently described mutants of Escherichia coli initiator tRNA that suppress amber termination codons (UAG) in E. coli. These mutants have changes in the anticodon sequence (CAU----CUA) that allow them to read the amber codon and changes in the acceptor stem that allow them to bind to the ribosomal aminoacyl (A) site. We show here that a subset of these mutants suppress amber codons in Saccharomyces cerevisiae and that they are aminoacylated with tyrosine by yeast extracts. Analysis of a number of mutants as substrates for yeast tyrosyl-tRNA synthetase has led to identification of the C1.G72 base pair and the discriminator base A73, conserved in all eukaryotic cytoplasmic and archaebacterial tyrosine tRNAs, as being important for recognition. Our results suggest that the C1.G72 base pair and the discriminator base, in addition to the anticodon nucleotides previously identified [Bare, L.A. & Uhlenbeck, O.C. (1986) Biochemistry 25, 5825-5830] as important in yeast tyrosyl-tRNA synthetase recognition, may comprise the critical identity determinants in yeast tyrosine tRNA.     

Abelson antigen: a viral tumor antigen that is also a differentiation antigen of BALB/c mice.

We report here the serologic detection of a cell surface antigen common to cells transformed by the Abelson murine leukemia virus (A-MuLV) and to normal hematopoietic cells from certain strains of mice. Serum from C57BL/6 mice hyperimmunized with syngeneic A-MuLV lymphoma cells was cytotoxic for the immunizing cells; this reaction was used as the serologic test system for recognition of A-MuLV antigens. Absorption analysis using 40 tumors and 21 cell lines revealed that two serologic specificities were detected by this test system: (i) FMR antigen(s) related to the Moloney MuLV helper (the virus from which A-MuLV was originally derived), and (ii) an antigen expressed on all cells transformed by A-MuLV. The A-MuLV-specific antigen was also present on uninfected cells from BALB/c bone marrow, spleen, and fetal liver but not from adult liver, thymus, lymph nodes, or peripheral blood. Abelson antigen was not expressed on bone marrow or spleen cells of 12 other mouse strains. In light of the original isolation of A-MuLV from a BALB/c mouse infected with Moloney virus, it is possible that Abelson antigen is a serologic marker for a gene of BALB/c mice, normally encoding a cell surface molecule, that was incorporated into the Moloney virus genome during the generation of A-MuLV.     

Selective incorporation of 5-hydroxytryptophan into proteins in mammalian cells

An orthogonal tryptophanyl-transfer RNA (tRNA) synthetase (TrpRS)-mutant opal suppressor tRNA(Trp) (mutRNA(UCA)(Trp)) pair was generated for use in mammalian cells. The anticodon loop of the Bacillus subtilis tRNA(Trp) was mutated to UCA, three positions in the D arm were mutated to generate an internal promoter sequence, and the mutRNA(UCA)(Trp) gene was inserted between the 5' and 3' flanking sequences of the tRNA(Trp-1) gene from Arabidopsis to enhance its expression in mammalian cells. In vitro aminoacylation assays and in vivo opal suppression assays showed that B. subtilis TrpRS (BsTrpRS) charges only the cognate mutRNA(UCA)(Trp) and no endogenous mammalian tRNAs. Similarly, the mutRNA(UCA)(Trp) is specifically charged by B. subtilis TrpRS and not by endogenous synthetases in mammalian cells. Site-directed mutagenesis was then used to alter the specificity of BsTrpRS to uniquely charge 5-hydoxy-l-tryptophan. The resulting mutant BsTrpRS-mutRNA(UCA)(Trp) pair allows the efficient and selective incorporation of 5-hydroxy-l-tryptophan into mammalian proteins in response to the codon, TGA. This amino acid can be used as a fluorescence probe and also undergoes electrochemical oxidation in situ to generate an efficient protein crosslinking.     

In vitro suppression of UAG and UGA mutants in the thymidine kinase gene of herpes simplex virus.

We have studied the in vitro translation, in nuclease-treated reticulocyte lysates, of mRNA from cells infected with several thymidine kinase-deficient mutants of herpes simplex virus type I. The addition of suppressor tRNAs from yeast resulted in suppression of the mutant property in the case of two mutants. Synthesis of enzymatically active viral thymidine kinase was restored by serine-inserting amber suppressor tRNA in the case of HSV TK4- and synthesis of the intact, but inactive, thymidine kinase protein was restored by serine- and leucine-inserting UGA suppressor tRNAs in the case of HSV TK43-. Read-through of the normal termination at the end of the thymidine kinase gene was promoted by UGA suppressor tRNAs. We conclude that HSV-TK4- is an amber (UAG) mutant and that HSV-TK43- is an opal (UGA) mutant.