Close linkage between ochre and missense suppressors in Escherichia coli

Suppressor sufJ: a novel type of tRNA mutant that induces translational frameshifting

We describe the DNA sequence change responsible for the creation of a frameshift-suppressor gene in Salmonella typhimurium. The suppressor, sufJ, results from a base-pair insertion in the gene coding for a threonine transfer RNA (tRNA3Thr). Unlike previously studied frameshift suppressor mutations, the sufJ insertion does not fall within the sequence corresponding to the tRNA anticodon. The insertion (a G.C base pair) occurs within a run of three G.C base pairs in that region of the gene coding for one strand of the anticodon stem. In the secondary structure of the mature tRNA, the net result is that an extra, unpaired cytidine residue is pushed into the anticodon loop, thus increasing the size of the loop to eight nucleotides. These findings are discussed in connection with the peculiar "three-out-of-four" method of reading by the sufJ suppressor. A unifying model is presented accounting for the contrasting decoding behaviors of tRNAs with eight-nucleotide-long anticodon loops.

Genetic characterization of the sufj frameshift suppressor in Salmonella typhimurium

A new suppressor of +1 frameshift mutations has been isolated in Salmonella typhimurium. This suppressor, sufJ, maps at minute 89 on the Salmonella genetic map between the argH and rpo(rif) loci, closely linked to the gene for the ochre suppressor tyrU(supM). The suppressor mutation is dominant to its wild-type allele, consistent with the suppressor phenotype being caused by an altered tRNA species. The sufJ map position coincides with that of a threonine tRNA(ACC/U) gene; the suppressor has been shown to read the related fourbase codons ACCU, ACCC, ACCA.--The ability of sufJ to correct one particular mutation depends on the presence of a hisT mutation which causes a defect in tRNA modification. This requirement is allele specific, since other frameshift mutations can be corrected by sufJ regardless of the state of the hisT locus.--Strains carrying both a sufJ and a hisT mutation are acutely sensitive to growth inhibition by uracil; the inhibition is reversed by arginine. This behavior is characteristic of strains with mutations affecting the arginine-uracil biosynthetic enzyme carbamyl phosphate synthetase. The combination of two mutations affecting tRNA structure may reduce expression of the structural gene for this enzyme (pyrA).

Dual function transcripts specifying tRNA and mRNA

A cluster of four tRNA genes in Escherichia coli is co-transcribed with an adjacent gene encoding elongation factor Tu. The resultant transcript that specifies both structural (tRNA) and informational (mRNA) RNA may not be an uncommon occurrence and has interesting regulatory implications.

Structure and organization of the two tRNATyr gene clusters on the E. coli chromosome

The structure and organization of the gene clusters coding for the two tyrosine-accepting tRNA species (tRNA1Tyr and tRNA2Tyr) on the E. coli chromosome have been determined. The mature structural sequences of the two tRNATyr genes, located on opposite sides of the E. coli chromosome, differ by only 2 bp, but sequences surrounding these portions of the genes are very different. The genes coding for tRNA1Tyr (tyrT) comprise two mature structural sequences separated by a 200 bp "intergenic spacer." It is known that in transducing phage, the region adjoining the CCA end of the second mature structural sequence comprises a 178 bp repeated sequence which contains an in vitro, rho-dependent transcriptional termination site. We find that these potentially genetically unstable repeated sequences are present in the E. coli chromosome with the same organization as that determined from transducing phage analyses. The gene that codes for tRNA2Tyr (tyrU) is present in a single copy and is tightly clustered with three other tRNA genes. One of these genes (to be called thrU) encodes a previously undescribed tRNA (to be called tRNA4Thr). The organization of this cluster on the E. coli chromosome is tRNA4Thr--8 bp--tRNA2Tyr--115 bp--tRNA2Gly--6 bp--tRNA3Thr. The importance of correlating structural analyses derived from specialized transducing phage with those determined for the chromosome itself is demonstrated by results which show that out of four independently isolated tRNATyr transducing phage, two carrying the tRNA1Tyr genes [phi80psu3+,- (Cambridge) and phi80sus2psu3+ (Kyoto)] and two carrying the tRNA2Tyr gene (lambdarifd 18 and lambdah80dglyTsu+36), only the first phage from each group has the same gene organization as that found in the E. coli chromosome.

Organization of genes for transcription and translation in the rif region of the Escherichia coli chromosome

The lambdarifd18 transducing phage is known to carry several genes for components of transcriptional and translational machineries; these genes are clustered in the rif region at 88 min on the Escherichia coli genetic map. They include a set of genes for rRNA's (rrnB), a gene for spacer tRNA, tRNA2Glu (tgtB), one of the two genes for EF-Tu (tufB), genes for four ribosomal proteins (rplK, A, J, and L), genes for the beta and beta' subunits of RNA polymerase (rpoB and rpoC), and genes for three tRNA's (tyrU, gluT, and thrT). An additional tRNA gene (subsequently identified as thrU by Landy and his co-workers) and a gene for a protein (protein U) with unknown functions were found to be carried by lambdarif d18. We analyzed the organization of these genes by using various deletion and hybrid phages derived from lambdarif d18 and lambdarif d12, a phage related to lambdarif d18. The expression of various genes was examined in UV-irradiated cells infected with these transducing phages. Two main conclusions were obtained. First, the four tRNA genes are not cotranscribed with the genes in rrnB, even though these tRNA genes are located close to the distal end of rrnB. Second, the four ribosomal protein genes are organized into two separate transcriptional units; rplK and A are in one unit and rplJ and L are in the second unit. The first group of genes was shown to have a promoter separate from that for tufB or protein U. The second group of genes shares the promoter with rpoB and C, as described in a separate paper (M. Yamamoto and M. Nomura, Proc. Natl. Acad. Sci. U.S.A., 75:3891--3895). These and other results described in this paper show that the genes are organized in the following order: promoter, genes in rrnB; promoter, thrU, tyrU, (promoter?) glyT, thrT; (promoter?) tufB; promoter, a gene for protein U; promoter, rplK, rplA; promoter, rplJ, rplL, rpoB, rpoC.

Some rRNA operons in E. coli have tRNA genes at their distal ends

We have previously isolated seven rRNA operons on plasmids or lambda transducing phages and identified various tRNAs encoded by these operons. Each of the seven operons has one of two different spacer tRNA gene arrangements between the genes for 16S and 23S rRNA: either tRNAGlu2 or both tRNAIle1 and tRNAAla1B genes. In addition, various tRNA genes are located at or near the distal ends of rRNA operons. In particular, genes for tRNATrp and tRNAAsp1 are located at the distal end of rrnC at 83 min on the E. coli chromosome. Experiments with various hybrid plasmids, some of which lack the rRNA promoter, have now demonstrated that this promoter is necessary for expression of the distal tRNA genes. Rifampicin run-out experiments have also provided evidence that the tRNATrp gene is located farther from its promoter than the spacer tRNA gene or the 5S RNA gene. These results confirm the localization of genes for tRNATrp and tRNAAsp1 at the distal end of rrnC and strongly suggest that they are co-transcribed with the genes for 16S, tRNAGlu2, 23S and 5S RNA. Other such distal tRNAs have been identified, and it is suggested that they too are part of rRNA operons.

Ochre suppression in Salmonella typhimurium

A bacterial strain was constructed which permitted positive selection for ochre suppressor mutations as well as for the loss of suppressor function. A derivative bearing an ochre suppressor mutation was selected following mutagenesis with N-methyl-N-nitroso-N'-nitroguanidine. The suppressor-bearing strain was treated with nitrous acid to eliminate suppressor function by mutation, and a strain lacking suppressor activity was selected. The selected strain which had lost suppressor function was then subjected to mutagenesis to induce a second suppressor mutation. The alternating sequence (induction of an ochre suppressor mutation leads to induction of a mutation eliminating ochre suppressor activity) was repeated 29 and one-half times in a single strain. Some of the suppressor mutations were tentatively mapped at four locations on the chromosome. The first suppressor mutation selected maps at about minute 30 on the chromosome. The second suppressor selected maps at approximately minute 60, while the third suppressor maps nearby, possibly as far as minute 72. Among the subsequently selected suppressor mutations, all eleven which were mapped were cotransducible with the gal and nic loci near minute 36 on the chromosome and may represent more than one suppressor gene. Deletions were selected which inactivate two of the ochre suppressor alleles mapping near the gal-nic region, suggesting that one or more such genes are dispensable. Some evidence also suggests that the occurrence of either deletion mutations or transduction-mediated recombination events in the gal-nic region can cause instability of nearby suppressor alleles.

Genetic and biochemical characterization of some missense mutations in the lacZ gene of Escherichia coli K-12

Some preparations of beta-galactosidase from strains of Escherichia coli carrying point mutations in their lacZ genes did not precipitate with antibody as effectively as wild-type enzyme, but did not appear to be chain-terminating mutations as judged by polarity measurements and suppression. Sodium dodecyl sulfate-polyacrylamide gel electrophoresis of crude extracts of induced Lac+ strains revealed that the monomer of beta-galactosidase ran as a band uncontaminated by other cellular proteins. This method was used to identify missense mutations in the alpha and beta portions of the lacZ gene. Six of 13 mutations investigated were judged to be missense by this criterion. Measurement of the degree of polarity, the ability to complement a nonsense mutation at the operator-distal extremity of the gene (omega-complementation), and suppressibility by 12 nonsense suppressors allowed the assignment of six other mutations as either number or ochre. The protein figments produced by these six nonsense mutations appeared to be degraded in vivo. One mutation that could not be classified was either a missense mutation whose protein product was degraded or a very leak nonsense mutation. Two lacZ alleles were suppressed by the ochre suppressors supM and supN, although they were missense by other criteria. The ability of supM to suppress both nonsense and missense mutations can be explained if it is derived from a tyrosine transfer ribonucleic acid with a modified base in the first position of the anticodon. The mutations assigned to the missense class were not suppressed by the missense suppressors supH, supQ, glyV, glyU, or glyT. Our results suggest that the criteria used in the past to distinguish between nonsense and missense mutations may not be conclusive even when used together.

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.

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.

Isolation and characterization of phi80 transducing bacteriophage for a ribonucleic acid polymerase gene

A new method for isolating specialized transducing phages is described. It was used to isolate a group of phi80 transducing phages which carry various bacterial markers from the metB region of the Escherichia coli chromosome. Some of the phages selected for transduction of the supA36 marker were also shown to carry rif, a locus known to specify the beta subunit of ribonucleic acid polymerase. Expression of the prophage rif(r) gene in lysogens was demonstrated by its ability to confer rifampin resistance on part of the cellular ribonucleic acid polymerase pool.

Transport of vitamin B12 in Escherichia coli: genetic studies

The chromosomal location of two genetic loci involved in the transport of cyanocobalamin (B(12)) in Escherichia coli K-12 was determined. One gene, btuA, is believed to code for the transport protein in the cytoplasmic membrane, because a mutant with an alteration in this gene has lost the ability to accumulate B(12) within the cell although normal levels of the surface receptors for B(12) are present. The other locus, btuB, apparently codes for the surface receptor on the outer membrane. These mutants have lost the ability to bind B(12) and have greatly reduced transport activity, although growth experiments have shown that they can utilize B(12) for growth, but with decreased efficiency. This surface receptor for B(12) also appears to function as the receptor for the E colicins, because btuB mutants are resistant to the E colicins, and mutants selected for resistance to colicin E1 are defective in B(12) binding and transport. The gene order was determined by transduction analysis to be cyc-argH-btuA-btuB-rif-purD. In addition, mutations in metH, the gene for the B(12)-dependent homocysteine methylating enzyme, were obtained in this study. This gene was localized between metA and malB.

Three adjacent transfer RNA genes in Escherichia coli

A defective varphi80 transducing phage has been isolated that carries a small section of the E. coli chromosome from the region near argH (77 min). This phage contains three E. coli tRNA genes, termed glyTsu(+) (36), tyrT, and thrT. These genes specify the structures of tRNA(2) (Gly) (su(+) (36)) tRNA(2) (Tyr), and tRNA(3) (Thr), respectively. Induction of a single lysogen bearing this phage brings about selective synthesis and amplification of only these three tRNAs.

Genetic locus determining resistance to phage BF23 and colicins E 1 , E 2 and E 3 in Escherichia coli

The gene for resistance to phage BF23 and colicins E1, E2and E3,bfe, was mapped by a combination of conjugation and transduction crosses. Co-transduction ofbfewas found with markers in the region between 76 and 79 min on theEscherichia coligenetic map. The highest frequency of co-transduction was found withargH(47%). Three-factor transductional crosses showed unambiguously thatbfelies betweenargHandsupM, at about 77·5 min on the map.