Identification of transfer RNA suppressors in Escherichia coli. IV. Amber suppressor Su+6 a double mutant of a new species of leucine tRNA

An Escherichia coli DNA fragment containing an Su+6 amber suppressor gene (supP) was cloned into a lambda gt lambda Ch vector by the shotgun method, selecting a Su+6 transducing phage lambda pSu+6. Through prophage integration followed by induction occurring at the transducing region of the lambda pSu+6 in Su- E. coli, a counterpart transducing phage carrying the wild-type allele (Su degrees 6) was isolated (lambda pSu degrees 6). The fingerprint of a tRNA encoded by lambda pSu degrees 6 was identical to that of an unidentified tRNAE previously reported (Ikemura & Ozeki, 1977). The cloverleaf structure of this tRNA was determined by combining the results of tRNA analysis and DNA sequencing of the gene. Judging from the anticodon of 5'-CAA-3', Su degrees 6 tRNA was identified as a new type of leucine isoacceptor in E. coli. Unlike other suppressors analyzed, Su+6 tRNA differed by two nucleotides from Su degrees 6 tRNA; one at the anticodon (CAA to CUA) and the other at the junction of D- and anticodon-stem (A27 to G27). DNA sequence analysis revealed that a single stretch of tRNA is flanked by the putative sequences of promoter and terminator. Thus a single copy of the Su degrees 6 tRNA gene constitutes a solitary tRNA transcription unit. Southern blotting showed only one copy of Su degrees 6 tRNA gene per haploid genome of E. coli. Since this single gene can mutate to the Su+6 suppressor, the Su degrees 6 leucine tRNA may be accounted as a dispensable species among the leucine isoacceptor tRNAs. Two possible open reading frames are found immediately following the Su degrees 6 tRNA gene.

Identification of transfer RNA suppressors in Escherichia coli. III. Ochre suppressors of lysine tRNA

Transducing phages of lambda carrying suppressors, lysT (Su+ beta), supG and and supL, were isolated in vivo. Upon infection with each of these phages, the production of tRNALys and tRNAVal1 was markedly enhanced. Fingerprint analysis of these tRNAs revealed that they consisted of normal tRNALys, mutant tRNALys and tRNAVal1 in equimolar ratios. The mutant tRNALys carried a single-base alteration at the anticodon, from 5'-UUU-3' to 5'-UUA-3', which makes it an ochre suppressor. DNA sequence analysis of the entire transducing fragment (730 base-pairs) of lambda pSu+ beta revealed that three tRNA genes are tightly clustered within a transcription unit in the following order; i.e. promoter-(48 base-pairs)-wild-type tRNALys-(132 base-pairs)-tRNAVal1-(2 base-pairs)-Su+ beta tRNALys-. In wild-type bacteria there are two identical tRNALys genes in one operon. Although we have shown that in Su+ beta it is the distal tRNALys that has been mutated to the ochre suppressor by a single base change at the anticodon (U36 to A36), we have not determined which of the two genes bears the supG or the supL mutation. The sequences following both tRNALys genes are highly homologous: both are about 100 base-pairs long and both terminate with an 18 base-pair sequence homologous to the last 18 bases of each tRNA. The sequences of tRNALys and tRNAVal1 are also very similar. Thus, including the 3'-portions of these tRNA genes, the 18 base-pair sequence is more or less periodically repeated five times in the DNA sequence.

Transfer RNA mischarging mediated by a mutant Escherichia coli glutaminyl-tRNA synthetase

We have isolated mutations in the Escherichia coli glnS gene encoding glutaminyl-tRNA synthetase [GlnS; L-glutamine:tRNAGln ligase (AMP-forming), EC 6.1.1.18] that give rise to gene products with altered specificity for tRNA and are designated "mischarging" enzymes. These were produced by nitrosoguanine mutagenesis of the glnS gene carried on a transducing phage (lambda pglnS+). We then selected for mischarging of su+3 tRNATyr with glutamine by requiring suppression of a glutamine-requiring beta-galactosidase amber mutation (lacZ1000). Three independently isolated mutants (glnS7, glnS8, and glnS9) were characterized by genetic and biochemical means. The enzymes encoded by glnS7, glnS8, and glnS9 appear to be highly selective for su+3 tRNATyr, because in vivo mischarging of other amber suppressor tRNAs was not detected. The GlnS mutants described here retain their capacity to correctly aminoacylate tRNAGln. All three independently isolated mutant genes encode proteins with isoelectric points that differ from those of the wild-type enzyme but are identical to each other. This suggests that only a single site in the enzyme structure is altered to give the observed mischarging properties. In vitro aminoacylation reactions with purified GlnS7 protein show that this enzyme can also mischarge some tRNA species lacking the amber anticodon. This is an example of mischarging phenotype conferred by a mutation in an aminoacyl-tRNA synthetase gene; the results are discussed in the context of earlier genetic studies with mutant tRNAs.

Escherichia coli glutaminyl-tRNA synthetase. I. Isolation and DNA sequence of the glnS gene

We have isolated a lambda-transducing phage carrying the gene (glnS) for Escherichia coli glutaminyl-tRNA synthetase. The location of the glnS gene within the 13.5-kilobase E. coli DNA transducing fragment was determined by genetic means. The glnS gene was recloned into plasmid pBR322 and its nucleotide sequence was established. The DNA sequence translates to a protein of 550 amino acids.

In vitro transcription of the supB-E tRNA operon of Escherichia coli. Characterization of transcription products

The seven tRNA genes clustered in the supB-E region of the Escherichia coli chromosome were transcribed in vitro with purified RNA polymerase, using a restriction fragment from lambda psu degrees 2, a transducing phage carrying the chromosome region, as template. A single major transcript was synthesized, which was about 770 nucleotides long and contained all seven tRNA sequences. The terminal sequences of the transcript were determined and mapped on the DNA sequence of the supB-E region previously determined. The transcription start site is seven base pairs downstream from the Pribnow box sequence, as expected from the DNA sequence analysis and consistent with the findings on the trimeric tRNA precursor (pppG--tRNAMETM-tRNALeu-tRNAGln1) which was detected in an RNase P mutant and shown to be coded for by the supB-E region. Cleavage of the restriction fragment at the -35 region with another restriction endonuclease abolished the template activity of the fragment. Transcription of the supB-E tRNA operon was relatively unaffected by the presence of rho factor. Transcription termination occurs within a region of three bases between positions 770 and 772 from the transcription start site. Immediately upstream from the termination sites, there is a region of 26 nucleotides that could form a stem structure, thereby consistent with the general feature of rho-independent termination sites.

Two classes of region III flagellar genes in Escherichia coli

We infected various nonflagellated mutants of Escherichia coli with fla-transducing phages and followed the kinetics of the appearance of motility. Our analysis revealed two distinct classes of region III fla genes. Class II fla genes (hag, flaD) functioned 15 min later than class I fla genes (flaN, flaB, flaC, flaO, flaA, flbD, flaQ, flaP) in flagellar morphogenesis. We suggest that the two classes of fla genes are involved in two different stages, initiation (class I) and completion (class II), of flagellar formation.

Organization and structure of an E. coli tRNA operon containing seven tRNA genes

The structure and organization on the Escherichia coli chromosome of the gene cluster coding for two methionine tRNAs (tRNAmMet), four glutamine tRNAs (two tRNA1Gln and two tRNA2Gln), and a previously unidentified tRNA (called tRNAx) have been studied by restriction enzyme analysis and DNA sequencing, utilizing a specialized transducing bacteriophage (lambda psu degrees 2) carrying the supB-supE region. From the sequence analysis, the previously unidentified tRNA has been shown to have an anticodon sequence (5'-UAG-3') corresponding to a leucine codon. The organization of this tRNA gene cluster on the E. coli chromosome is tRNAmMet-9 base pairs-tRNAx-23 base pairs-tRNA1Gln-34 base pairs-tRNA1Gln-15 base pairs-tRNAmMet-47 base pairs-tRNA2Gln-37 base pairs-tRNA2Gln. The duplicated genes coding for tRNAmMet, tRNA,Gln, and tRNA2Gln have identical sequences, which are the same as the sequences determined previously with tRNA molecules. These tRNA sequences are preceded by a single promoter region where a "Pribnow box" sequence is present seven base pairs upstream from the transcription start site. The spacer regions separating the seven tRNA sequences are different from each other both in size and in nucleotide sequence. The possible implication of these sequences for precursor processing is discussed. A restriction fragment that has been originally identified in lambda psu degrees 2 DNA and shown to contain the seven tRNA genes has been detected in the E. coli chromosome, thereby suggesting that this tRNA gene cluster is present in the bacterial genome with the same organization as in the transducing phage genome.

Sequence homology in DNA molecules of temperate phages phi81, phi80 and lambda

Homology maps between bacteriophages phi81, phi80 and lambda were constructed on the basis of electron microscopy observation of DNA heteroduplexes. In phi81/phi80 heteroduplex, the left half and the right terminal region of 13% the total molecular length were highly homologous, while the remaining region covering the early gene cluster was entirely nonhomologous. In phi81/lambda heteroduplex, high-degree homologies were detected at the left 14% terminal region covering the head gene cluster, the central 3.8% region covering the att-int-xis region and the 1.3% Q homology region. Low-degree homologies of shorter length were scattered at the tail gene cluster, b2 region, cIII region, PQ region and SR region. Comparing our results with the homology maps of other lambdoid phages reported by Simon et al. (1971) and Fiandt et al. (1971), a phylogenic relation of phi81 to other lambdoid phages and the role of recombination in the course of divergence of lambdoid phages are discussed.

Deletion and amber mutants of fla loci in Escherichia coli K-12

A rapid screening method for amber fla mutants of E. coli was devised and many mutants were obtained. In addition, strains with deletions of the fla genes in the his-uvrC region were isolated from high-temperature survivors of a lambda cI857 lysogen in which the prophage is located between his and fla. Utilizing these mutants, eleven fla genes (I--XI) and one hag gene were identified in the his-uvrc region, in the following order: his-supD-I-II-(III, IV)-V-(VI, VII)-VIII-IX-hag-(X, XI)-uvrC. The fla genes X and XI and hag are located at about 42.5 min and the other fla genes at about 43.0 min on the E. coli genetic map (Bachmann, Low and Taylor 1976). Mutants of fla gene X showed a slight sensitivity to chi phage, although they lack the flagellar filament.

Excision and duplication of su3+-transducing fragments carried by bacteriophage phi 80. I. Novel structure of phi 80sus2psu3+ DNA molecule

DNA molecules of phi 80sus2psu3+ and phi 80dsu3+ isolated by Andoh and Ozeki (1968) were studied by the electron microscope heteroduplex method. The phi 80sus2psu3+ and phi 80dsu3+ DNA lengths were found to be 108.7 and 103.3% of the phi 80 DNA, respectively. The phi 80sus2psu3+/phi 80 heteroduplex shows an insertion loop of 8.7% of the phi 80 DNA which migrates from 7.7 to 9.7%, as measured relative to the left (0%) and right (100%) termini of the mature phi 80 DNA molecule. The region of loop migration occupies the central region of the phi 80 head gene cluster. The presence of su3+-containing Escherichia coli DNA of 6.7% phi 80 unit flanked by two homologous regions of phage DNA of 2.0% of phi 80 unit gives rise to a movable insertion loop. In phi 80dsu3+, from which phi 80sus2psu3+ was derived, 50.5% of the phi 80 DNA at the left arm was replaced by E. coli DNA containing the su3+ gene, equivalent to about 53.8% phi 80 unit in length. The phi 80sus2psu3+/phi 80dsu3+ heteroduplex appears as a double-stranded molecule that bifurcates into two clearly visible single-stranded regions, rejoins, bifurcates, and rejoins again. The middle double-stranded stretches of 6.7% phi 80 unit correspond to the E. coli DNA inserted in phi 80sus2psu3+. Therefore the transducing fragment carried by phi 80sus2psu3+ originates from the inside region of the transducing fragment of defective phage phi 80dsu3+ by at least two illegitimate recombination events.