Suppression of Glutamic Acid Codons by Mutant Glycine Transfer Ribonucleic Acid

In previous mutational studies with mutant trpA46 (Gly [GGA] --> Glu [GAA] at position 211 of the tryptophan synthetase alpha chain) of Escherichia coli, no missense suppressors were detected. Such suppressors have now been obtained by single mutations in gly Vins, the structural gene for a GGA/G-reading, mutationally altered form of gly V transfer ribonucleic acid (tRNA) (tRNA(Gly) which reads GGU/C). A trpA46 strain containing the gly Vins alteration was mutagenized with hydroxylamine, and suppressor mutations were detected in the prototrophs obtained. Eighteen independent suppressors were examined and shown to have alterations which map in the gly V region. Chromatography of the glycyl-tRNAs of one suppressed mutant on a benzoylated diethylaminoethyl-cellulose column revealed an alteration in the tRNA(ins) (Gly) peak. The trpA46 suppressor mutation thus appears to involve a change of tRNA(ins) (Gly) from a GGA/G (Gly) reader to a GAA (Glu) reader. Since this suppressor presumably retains the "wobble" pairing of gly Vins tRNA, it was used to select the conversion of GAU (Asp211) to GAG (Glu211) in the alpha chain. supD (serine-inserting amber suppressor) was then used to obtain the conversion of GAG (Glu211) to UAG211. Missense revertants of trpA (UAG211) are being isolated as a means of introducing new codons which can be used in the selection of additional missense suppressors.     

Multiple gene loci for a single species of glycine transfer ribonucleic acid.

The study of suppressors of tryptophan synthase A protein missense mutations in Escherichia coli has led to the establishment of two nonadjacent genetic loci (gly V and gly W) specifying identical nucleotide sequences for a single isoaccepting species of glycine transfer ribonucleic acid (tRNA GLY 3 GGU/C). In one case, suppression of the missense mutation trpA78 was due to a mutation in a structural gene (gly W) for tRNA Gly 3 GGU/C. This mutation resulted in a base change in the anticodon and modification of an A residue adjacent to the 3' side of the anticodon, leading to the production of a tRNA Gly 3 UGU/C species. The resulting glyW51 (SU UGU/C) allele was mapped by interrupted mating and was located at approximately 37 min on the Escherichia coli genetic map. Other suppressor mutations affecting the primary sequence of tRNA Gly GGU/C and giving rise to the Ins and SU+A58 phenotypes were positioned at 86 min (glyV). Several independently arising missense suppressor mutations resulting in the SU+A78 phenotypes were isolated and mapped at these two genetic loci (glyV and glyW). The ratio of appearance of suppressor mutations at glyV and glyW suggests that there are three of four tRNAGly3 GGU/C structural gene copies at the glyV locus to one copy at the glyW locus. Structural genes for tRNA ly isoacceptors are now known at four distinct locations on the Escherichia coli chromosome: glyT (77 MIN), TRNA Gly 2 GGA/G; gly U (55 min), tRNAGly-1 minus; and gly V (86 MIN) AND GLYW (37 min), tRNAGly 3 GGU/C.     

Suppressors of a UGG missense mutation in Escherichia coli

As part of our investigation of tRNA structure-function relationships, we isolated and preliminarily characterized translational suppressors of the tryptophan codon UGG in a trpA missense mutant of Escherichia coli. the parent strain also contained two other mutant alleles relevant to the suppressor search; these were supD, which codes for a serine-inserting amber suppressor tRNA, and gly V55, the gene for a GGA/G-reading mutationally altered glycine tRNA. On the basis of map location, reversed-phase (RPC-5) column chromatography of glycyl-tRNA, and codon response, several classes have been distinguished so far. The number of suppressors in each class, their codon responses, and their apparent genic identities, respectively, are as follows: class 1--4 suppressors, UGG, supD; class 2--12 suppressors, UGG, glyU; class 3--9 suppressors, UGA and UGG, glyT; class 4--2 suppressors, UGG, glyT; class 5--7 suppressors, UGG, gly V55. Besides these, one suppressor retains supD activity, but so far its map location has not been distinguished from that of supD. Another suppressor clearly does not map near supD or any of the glycine tRNA genes mentioned. These last two suppressors may represent novel missense suppressors such as misacylated tRNA's or mutationally altered aminoacyl-tRNA synthetases, tRNA modification enzymes, or ribosomes. Finally, three other suppressors were obtained from a strain containing glyT56, the gene for an AGA/G-reading form of glyT tRNA. All three occurred at the expense of glyT56 activity and exhibited the the transductional linkage to argH that is characteristic of glyT.     

Variations among glyV-derived glycine tRNA suppressors of glutamic acid codons.

Glutamic acid codon suppressors in 18 isogenic strains of Escherichia coli have been further characterized as to map location, dominance, growth rates in various media, suppression of the GAG codon, and tRNA profiles after reversed-phase column chromatography. In general the evidence supports the conclusion that all of these suppressors are due to mutations in glyV55, the gene for a GGA/G-reading mutant form of glyV tRNA, and that they represent several different classes that may correspond to at least as many different nucleotide changes. Furthermore, 17 of the 18 suppressors can coexist in a haploid genome with a glyT suppressor that is devoid of GGA-reading ability. This result indicates the retention by those glyV suppressors of some ability to respond to GGA as well as the acquisition of the ability to read GAA, and suggests the possibility of "wobble" in the middle position of the anticodons of those tRNA's.     

Suppression of a double missense mutation by a mutant tRNA(Phe) in Escherichia coli.

We report here the isolation of a mutant tRNAPhe that suppresses a double missense auxotrophic mutation in trpA of Escherichia coli, trpA218. The doubly mutant protein product differs from wild-type TrpA by the replacements of Phe22 by Leu and Gly211 by Ser. A partial revertant TrpA phenotype can be obtained from trpA218 by changing either Leu22 back to Phe or Ser211 back to Gly. Translational suppressors were previously obtained that act at codon 211, replacing the Ser211 in the TrpA218 protein, presumably with Gly. In the present study, we selected for trpA218 suppressors caused by mutation of a cloned tRNAPhe gene, pheV. DNA sequence analysis of the suppressor isolated reveals a singular structural alteration, changing the anticodon from 5'-GAA-3' to 5'-GAG-3'. Sequencing of trpA218 confirmed the likely identity of Leu22 as CUC. The new missense suppressor, designated pheV(SuCUC), is lethal to the cell when highly expressed, as from a high copy number plasmid. This may be due to efficient replacement of Leu by Phe at CUC (and, probably, CUU) codons throughout the genome. We anticipate that pheV(SuCUC) will prove, like other missense suppressors, to be extremely useful in studies on the specificity and accuracy of decoding.     

Isolation of lysine codon suppressors inEscherichia coli

Starting with anEscherichia coli strain containingglyT56, a glycine transfer RNA suppressor of the arginine codons AGA and AGG, and atrpA mutant containing lysine at position 211 of the tryptophan synthetase alpha chain, we have isolated AAG-suppressors that fall into two classes. In class 1 are dominant suppressors that arose with the simultaneous loss ofglyT56 activity. They are approximately 50% cotransducible withargE, as isglyT, and appear to be derived fromglyT56. Class 2 suppressors, located betweenpurE andtrp on theE. coli map, are not near any glycine tRNA genes, and may represent novel missense suppressors.     

Isolation of nonsense suppressor mutants in Pseudomonas.

A strain of Escherichia coli harboring the drug resistance plasmid RP1 was treated with the mutagen N-methyl-N-nitro-N-nitro-N-nitrosoguanidine, and mutants were isolated in which ampicillin resistance had been lost due to an amber mutation in the plasmid. One of these mutants was again treated, and a strain was isolated in which tetracycline resistance was also lost due to an amber mutation in the plasmid. The plasmid containing amber mutations in the genes amp and tet was named pLM2. This plasmid could be transferred to strains of Pseudomonas aeruginosa, P. phaseolicola, and P. pseudoalcaligenes. Mutants resistant to ampicillin and tetracycline could not be obtained from P. phaseolicola carrying pLM2. However, strains of E. coli, P. aeruginosa, and P. pseudoalcaligenes carrying the plasmid did produce mutants simultaneously resistant to both antibiotics. All of the mutants of E. coli had developed nonsense suppressors since they became phenotypically lac+, although harboring a lac amber mutation, and formed plaques with amber mutants of phages PRR1 and PRD1 that attack organisms carrying RP1. Approximately 20% of the resistant mutants of P. aeruginosa and P. pseudoalcaligenes were sensitive to the amber mutant of PRD1. These mutants were of variable stability and grew somewhat more slowly than their parent strains. One of the suppressor mutants of P. pseudoalcaligenes, designated ERA(pLM2)S4, was used for the isolation of nonsense mutants of bacteriophage PHA6, a virus having a segmented genome of double-stranded ribonucleic acid and an envelope of lipids and proteins.     

Transductional mapping of gene trmA responsible for the production of 5-methyluridine in transfer ribonucleic acid of Escherichia coli.

The gene trmA, responsible for the production of 5-methyluridine (ribothymidine) in transfer ribonucleic acid, has been located at 79 min on the chromosomal map of Escherichia coli K-12. In five-factor crosses the gene order was shown to be argH-trmA-rif-thiA-metA. The co-transduction frequency between argH and trmA was 65%. Furthermore, the trmA5 mutation was shown to be recessive, in agreement with the notion that the trmA gene is the structural gene for the transfer tibonucleic acid (5-methyluridine) methyltransferase.     

Three Different Missense Suppressor Mutations Affecting the tRNAGGGGly Species of Escherichia coli

The Escherichia coli suppressor mutation, supT, has been shown to cause a C → U substitution in the middle position of the tRNA_GGG^Gly anticodon. This is the same tRNA species that is altered by the glyUsu_AGA mutation studied previously. This finding indicates that the supT mutant tRNA reads the glutamic acid codon, GAG. The supT suppressor has also been converted to a new suppressor, called glyUsu_GAA, which will suppress the GAA mutation, trpA46. The in vivo suppression efficiencies of each of these three missense suppressors has been measured and are as follows: glyUsu_AGA, 3.6%; supT, 1.6%; and glyUsu_GAA, 0.4%. Mistranslation by these mutant glycine tRNA species has no adverse affects on cell growth since cultures possessing the suppressors grow as fast as cells without. The supT tRNA species can be observed as a peak in the profile of glycyl-tRNA fractionated on a RPC-5 chromatographic column, indicating that the mutant tRNA can be aminoacylated with reasonable efficiency. This finding contrasts with previous findings concerning the glyUsu_AGA mutant tRNA which is not significantly aminoacylated under the same conditions.     

Nucleotide sequence of phenylalanine transfer ribonucleic acid from pea (Pisum sativum, Alaska).

Phenylalanine transfer ribonucleic acid from peas (Pisum sativum, Alaska) was completely digested with beef pancreatic ribonuclease (RNase I) and with ribonuclease T1. The resulting oligonucleotides were compared with those from the corresponding hydrolyses of phenylalanine transfer ribonucleic acid from wheat germ. The structures of both ribonucleic acids appeared to be identical. This report is the first to show that identical structures for the same specific acceptor transfer ribonucleic acid are present in two different plant species.     

Primary structure of an unusual glycine tRNA UGA suppressor.

We have determined the nucleotide sequences of two UGA-suppressing glycine transfer RNAs. The suppressor tRNAs were previously shown to translate both UGA and UGG and to have arisen as a consequence of mutation in glyT, the gene for the GGA/G-reading glycine tRNA of Escherichia coli. In each mutant tRNA, the primary sequence change was the substitution of adenine for cytosine in the 3' position of the anticodon. In addition, a portion of mutant glyT tRNA molecules contained N6-(delta 2-isopentenyl)-2-thiomethyl adenine adjacent to the 3' end of the anticodon (nucleotide 37). The presence or absence of this hypermodification may be a determinant in some of the biological properties of the mutant tRNA.     

Genetic analysis of ribonucleic acid polymerase mutants of Bacillus subtilis

Deoxyribonucleic acid-dependent ribonucleic acid polymerase mutants of Bacillus subtilis strain Marburg were isolated after mutagenesis of spores with ethyl methane sulfonate. Genetic analysis by PBS1-mediated transduction and by transformation indicated that mutations responsible for all of the four phenotypic classes studied (rifampin resistance, streptovaricin resistance, streptolydigin resistance, and temperature sensitivity) were clustered close to the cysA14 locus. Three-factor transformation analysis has indicated the most probable marker order as follows: Rif(R)(Stv)(R)-Std(R)-Ts(418)-Ts(427). In addition, further characterization of the classical group I reference marker, cysA14, is reported.     

Physiological modification of alkylating agent induced mutagenesis. II. Influence of the numbers of chromosome replicating forks and gene copies on the frequency of mutations induced in Escherichia coli.

The frequency of reversions induced in Escherichia coli K-12 trpA58 by any of five different monofunctional alkylating agents increased as the growth rate of the organism was raised prior to mutagen treatment. The increase in mutation frequency did not correlate with growth rate-dependent changes in cell area or total cellular protein and DNA. After treatment of cells with N-methyl-N-nitrosourea (MNUA), no growth rate-dependent change was observed in the total DNA alkylation or percentage of O6-methylguanine present in the DNA extracted. The frequency of reversions induced by one mutagen, methyl methanesulphonate (MMS), increased in proportion to the average number of trpA gene copies per cell, whereas the frequency of reversions induced by the other compounds was dependent on the average number of chromosome replicating forks per cell. This difference was attributed to the different ratios of DNA base alkylation products observed, formed after treatment with MMS, an SN2-type reagent, or after treatment with the SN1-type reagents ethyl methanesulphonate (EMS), N-methyl-N'-nitro-N-nitrosoguanidine (MNNG), MNUA and N-ethyl-N-nitrosourea (ENUA). Possible reasons for the dependence of mutation frequency on the number of replicating forks per cell are discussed.     

Nature of the hisD3018 Frameshift Mutation in Salmonella typhimurium

Histidinol dehydrogenase from three differing revertants of ICR-191A-induced frameshift hisD3018 has been purified and examined for amino acid replacements. The enzyme from one spontaneously arising revertant, R7, contains an extra proline residue, whereas that from another, R5, contains an extensive frameshifted sequence, four amino acid residues of which have been identified to date. The amino acid replacement data are in agreement with the in vitro code word assignments and allow the characterization of the hisD3018 frameshift as an addition of one nucleotide pair, most likely guanine plus cytosine. Enzymatic data for those ICR-191A-induced revertants of hisD3018 arising within the hisD gene indicate that the enzyme is wild type and, therefore, that ICR-191A can cause deletions as well as additions of single base pairs. The wild-type amino acid sequence is restored in enzyme from an N-methyl-N′-nitro-N-nitrosoguanidine (NG)-induced revertant, R29, suggesting that NG is a base-deleting as well as a base-substituting mutagen. The unusual response of hisD3018 to external suppressors is considered in terms of reinitiation of protein synthesis out of phase, coupled with suppression of a nonpermissive missense codon so generated, and of an alternative hypothesis invoking a true frameshift suppressor transfer ribonucleic acid with an extended or deleted anticodon.     

Missense and nonsense suppressors can correct frameshift mutations

Missense and nonsense suppressor tRNAs, selected for their ability to read a new triplet codon, were observed to suppress one or more frameshift mutations in trpA of Escherichia coli. Two of the suppressible frameshift mutants, trpA8 and trpA46AspPR3, were cloned, sequenced, and found to be of the +1 type, resulting from the insertion of four nucleotides and one nucleotide, respectively. Twenty-two suppressor tRNAs were examined, 20 derived from one of the 3 glycine isoacceptor species, one from lysT, and one from trpT. The sequences of all but four of the mutant tRNAs are known, and two of those four were converted to suppressor tRNAs that were subsequently sequenced. Consideration of the coding specificities and anticodon sequences of the suppressor tRNAs does not suggest a unitary mechanism of frameshift suppression. Rather, the results indicate that different suppressors may shift frame according to different mechanisms. Examination of the suppression windows of the suppressible frameshift mutations indicates that some of the suppressors may work at cognate codons, either in the 0 frame or in the +1 frame, and others may act at noncognate codons (in either frame) by some as-yet-unspecified mechanism. Whatever the mechanisms, it is clear that some +1 frameshifting can occur at non-monotonous sequences. A striking example of a frameshifting missense suppressor is a mutant lysine tRNA that differs from wild-type lysine tRNA by only a single base in the amino acid acceptor stem, a C to U70 transition that results in a G.U base pair. It is suggested that when this mutant lysine tRNA reads its cognate codon, AAA, the presence of the G.U base pair sometimes leads either to a conformational change in the tRNA or to an altered interaction with some component of the translation machinery involved in translocation, resulting in a shift of reading frame. In general, the results indicate that translocation is not simply a function of anticodon loop size, that different frameshifting mechanisms may operate with different tRNAs, and that conformational features, some far removed from the anticodon region, are involved in maintaining fidelity in translocation.     

Helios gene gun particle delivery for therapy of acid maltase deficiency

Autosomal recessive deficiency of lysosomal acid maltase (GAA) or glycogen storage disease type II (GSDII) results in a spectrum of phenotypes including a rapidly fatal infantile disorder (Pompe's), juvenile, and a late-onset adult myopathy. The infantile onset form presents as hypotonia with massive accumulation of glycogen in skeletal and heart muscle, with death due to cardiorespiratory failure. Adult patients with the slowly progressive form develop severe skeletal muscle weakness and respiratory failure. Particle bombardment is a safe, efficient physical method in which high-density, subcellular-sized particles are accelerated to high velocity to carry DNA into cells. Because it does not depend on a specific ligand, receptor, or biochemical features on cell surfaces, particle-mediated gene transfer can be readily applied to a variety of systems. We evaluated particle bombardment as a delivery system for therapy of GSDII. We utilized a vector carrying the CMV promoter linked to the human GAA cDNA. Human GSDII cell lines (fibroblasts and lymphoid) as well as ex vivo with adult-onset peripheral blood cells (lymphocytes and monocytes) were transiently transfected by bombardment with a Helios gene gun delivering gold particles coated with the GAA expression plasmid. All cell types showed an increase in human GAA activity greater than 50% of normal activity. Subsequently, GAA -/- mice were treated every 2 weeks for 4 months by particle bombardment to the epidermis of the lower back and hind limbs. Muscle weakness in the hind and forelimbs was reversed. These data suggest that particle delivery of the GAA cDNA by the Helios gene gun may be a safe, effective treatment for GSDII.     

Cloning and sequence analysis of tryptophan synthetase genes of an extreme thermophile, Thermus thermophilus HB27: plasmid transfer from replica-plated Escherichia coli recombinant colonies to competent T. thermophilus cells.

Tryptophan synthetase genes (trpBA) of the extreme thermophile Thermus thermophilus HB27 were cloned by a novel method of direct plasmid transfer from replica-plated Escherichia coli recombinant colonies to competent T. thermophilus HB27 trpB cells. The nucleotide sequences of the trpBA genes were determined. The amino acid sequences deduced from the nucleotide sequences of Thermus trpB and trpA were found to have identities of 54.8 and 28.7%, respectively, with those of E. coli trpB and trpA genes. Low cysteine content (one in trpB; zero in trpA) is a striking feature of these proteins, which may contribute to their thermostability.     

Genetic analysis of mutations causing borrelidin resistance by overproduction of threonyl-transfer ribonucleic acid synthetase.

Mutations leading to borrelidin resistance in Escherichia coli by overproduction of threonyl-transfer ribonucleic acid synthetase were anaylzed genetically. The regulatory mutations were closely linked to the treonyl-transfer ribonucleic acid synthetase structural gene (thrS), located clockwise to it. The mutation that causes the threefold-increased enzyme level was more distant from thrS than the mutation responsible for the ninefold overproduction. Both mutations were cis dominant in merodiploid strains, indicating that they affected promoter-operator-like control elements. Overproduction was restricted to threonyl-transfer ribonucleic acid synthetase and was not observed for the products of genes neighboring thrS (e.g., infC, pheS, pheT, and argS), providing evidence that thrS is transcribed singly and that gene amplificationis not a likely basis for increased thrS experession.