Construction of a tyrP-lac operon fusion strain and its use in the isolation and analysis of mutants derepressed for tyrP expression.

The gene tyrP, which codes for a component of the tyrosine-specific transport system, has been localized on the Escherichia coli K-12 chromosome at min 42. A tyrP-lac operon fusion was constructed and used to isolate mutants that have altered expression from the tyrP promoter. All putative tyrP operator mutations were transferred onto a plasmid vector by recombination in vivo. Restriction enzyme analysis of the resultant plasmids suggests that some of these mutants arose from either an insertion or a deletion of DNA occurring within the region of DNA that contains the tyrP promoter.     

Translational autocontrol of the Escherichia coli ribosomal protein S15

When rpsO, the gene encoding the ribosomal protein S15 in Escherichia coli, is carried by a multicopy plasmid, the mRNA synthesis rate of S15 increases with the gene dosage but the rate of synthesis of S15 does not rise. A translational fusion between S15 and beta-galactosidase was introduced on the chromosome in a delta lac strain and the expression of beta-galactosidase studied under different conditions. The presence of S15 in trans represses the beta-galactosidase level five- to sixfold, while the synthesis rate of the S15-beta-galactosidase mRNA decreases by only 30 to 50%. These data indicate that S15 is subject to autogenous translational control. Derepressed mutants were isolated and sequenced. All the point mutations map in the second codon of S15, suggesting a location for the operator site that is very near to the translation initiation codon. However, the creation of deletion mutations shows that the operator extends into the 5' non-coding part of the message, thus overlapping the ribosome loading site.     

The cloning and sequence analysis of the aspC and tyrB genes from Escherichia coli K12. Comparison of the primary structures of the aspartate aminotransferase and aromatic aminotransferase of E. coli with those of the pig aspartate aminotransferase isoenzymes.

In this paper we describe the cloning and sequence analysis of the tyrB and aspC genes from Escherichia coli K12, which encode the aromatic aminotransferase and aspartate aminotransferase respectively. The tyrB gene was isolated from a cosmid carrying the nearby dnaB gene, identified by its ability to complement a dnaB lesion. Deletion and linker insertion analysis located the tyrB gene to a 1.7-kilobase NruI-HindIII-digest fragment. Sequence analysis revealed a gene encoding a 43 000 Da polypeptide. The gene starts with a GTG codon and is closely followed by a structure resembling a rho independent terminator. The aspC gene was cloned by screening gene banks, prepared from a prototrophic E. coli K12 strain, for plasmids able to complement the aspC tyrB lesions in the aminotransferase-deficient strain HW225. Sub-cloning and deletion analysis located the aspC gene on a 1.8-kilobase HincII-StuI-digest fragment. Sequence analysis revealed the presence of a gene encoding a 43 000 Da protein, the sequence of which is identical with that previously obtained for the aspartate aminotransferase from E. coli B. Considerable overproduction of the two enzymes was demonstrated. We compared the deduced protein sequences with those of the pig mitochondrial and cytoplasmic aspartate aminotransferases. From the extensive homology observed we are able to propose that the two E. coli enzymes possess subunit structures, subunit interactions and coenzyme-binding and substrate-binding sites that are very similar both to each other and to those of the mammalian enzymes and therefore must also have very similar catalytic mechanisms. Comparison of the aspC and tyrB gene sequences reveals that they appear to have diverged as much as is possible within the constraints of functionality and codon usage.     

Mutations in the bacteriophage lambda pL/oL region that spontaneously occur in plasmid pRPZ126

In a previous study (Chen and Porter, 1988), we isolated spontaneous mutations in a test plasmid that had occurred under non-selective conditions and assigned them to 1 of 6 different categories or groups. The test plasmid, pRPZ126, is a pBR322 derivative containing the bacteriophage lambda immunity region with the cI857 allele so that plasmid-containing cells shifted to 42 degrees C survive only if the expression of the lambda kil gene is prevented by mutation. 75% of the total spontaneous mutations obtained fall into two of these groups where there is no readily detectable change in plasmid size. The two groups differ in that the plasmids from the group 4 mutations are missing a specific HincII site while the plasmids from the group 5 mutations had no detectable plasmid change whatsoever. In this study, we randomly selected ten group 4 mutants and ten group 5 mutants and sequenced the lambda pL/oL region of the mutant plasmid. Of the ten group 4 mutants (HincII site missing), five involved a 24- or 44-basepair deletion in the pL/oL region of the plasmid. The other five group 4 mutants and four of the ten group 5 mutants were A-T to G-C transitions in the pL/oL region. The remaining six group 5 mutants did not demonstrate any sequence change in the pL/oL region of the plasmids. 8 out of 9 of these transition mutations occurred next to the 3' end of 3 different 5'-PyGGNPuNTG-3' sequences in the lambda operator region, and this same sequence is found adjacent to the A-T to G-C transition hotspot in the lac operator region (Schaaper et al., 1986). The 9th mutation, where the A-T to G-C transition occurred one basepair away from the lambda operator, was adjacent to a very similar sequence.     

Regulatory mutants of the aroF-tyrA operon of Escherichia coli K-12.

The regulatory region of the aroF-tyrA operon was fused to the chloramphenicol acetyltransferase (cat) gene on a plasmid vector. Expression of the cat gene was subject to repression by tyrR+. This fusion was used to isolate regulatory mutants with increased expression of the cat gene in which repression by tyrR+ was affected. Nucleotide sequencing of these mutants has led to the identification of three sites involved in the repression of aroF by tyrR+. The existence of a functional promoter divergently transcribing from the aroF regulatory region was also demonstrated by using the cat fusion vector. The expression of this promoter is also regulated by tyrR+.