Tryptophan operon regulation in interspecific hybrids of enteric bacteria

The tryptophan repressor sequence is highly conserved among the Enterobacteriaceae

Tryptophan biosynthesis in Escherichia coli is regulated by the product of the trpR gene, the tryptophan (Trp) repressor. Trp aporepressor binds the corepressor, L-tryptophan, to form a holorepressor complex, which binds trp operator DNA tightly, and inhibits transcription of the tryptophan biosynthetic operon. The conservation of trp operator sequences among enteric Gram-negative bacteria suggests that trpR genes from other bacterial species can be cloned by complementation in E. coli. To clone trpR homologues, a deletion of the E. coli trpR gene, delta trpR504, was made on a plasmid by site-directed mutagenesis, then crossed onto the E. coli genome. Plasmid clones of the trpR genes of Enterobacter aerogenes and Enterobacter cloacae were isolated by complementation of the delta trpR504 allele, scored as the ability to repress beta-galactosidase synthesis from a prophage-borne trpE-lacZ gene fusion. The predicted amino acid sequences of four enteric TrpR proteins show differences, clustered on the backside of the folded repressor, opposite the DNA-binding helix-turn-helix substructures. These differences are predicted to have little effect on the interactions of the aporepressor with tryptophan, holorepressor with operator DNA, or tandemly bound holorepressor dimers with one another. Although there is some variation observed at the dimer interface, interactions predicted to stabilize the interface are conserved. The phylogenetic relationships revealed by the TrpR amino acid sequence alignment agree with the results of others.

Cloning of a restriction-modification system from Proteus vulgaris and its use in analyzing a methylase-sensitive phenotype in Escherichia coli

A 4.84-kilobase-pair plasmid was isolated from Proteus vulgaris (ATCC 13315) and cloned into the plasmid vector pBR322. Plasmid pBR322 contains substrate sites for the restriction endonucleases PvuI and PvuII. The recombinant plasmids were resistant to in vitro cleavage by PvuII but not PvuI endonuclease and were found to cause production of PvuII endonuclease or methylase activity or both in Escherichia coli HB101. The approximate endonuclease and methylase gene boundaries were determined through subcloning, Bal 31 resection, insertional inactivation, DNA-dependent translation, and partial DNA sequencing. The two genes are adjacent and appear to be divergently transcribed. Most E. coli strains tested were poorly transformed by the recombinant plasmids, and this was shown by subcloning and insertional inactivation to be due to the PvuII methylase gene. At a low frequency, stable methylase-producing transformants of a methylase-sensitive strain were obtained, and efficiently transformed cell mutants were isolated from them.

Anomalous expression of the E. coli lac operon in Proteus mirabilis. I. Effects of L8 and L8 UV5

The lac operon shows anomalous expression in Proteus mirabilis: the maximal induced level is 10% or less of that in E. coli, while repression reduces this by a factor of only 2-5. We have sought to determine whether this effect relates in any way to CRP-mediated activation of expression, by comparing expression in P. mirabilis of lac operons (introduced for technical reasons on IncP1 plasmids) either regulatorily wild-type or bearing L8 or L8UV5. Derivatives of RP1 bearing L8UV5 were obtained by homogenotisation of pGC9114 (RP1::Tn951) in a L8UV5 background; while derivatives of RP4 bearing lac+, L8 or L8UV5 were obtained by Mu-mediated translocation of chromosomal regions bearing these alleles, following partial heat-induction of Mucts62 on pGM14 (RP4::Mucts62) in the appropriate hosts. These plasmids could be readily transferred to, and stably maintained in, the P. mirabilis strains employed. It was found that L8 reduced the maximal level of beta-galactosidase activity, and L8UV5 restored this activity to around wild-type, in P. mirabilis quantitatively very much as in E. coli. Nevertheless, the low maximal level of expression and high basal level characteristic of the former host were unchanged. The simplest explanation of these results is that P. mirabilis contains a protein that mimics the E. coli CRP protein in interacting with the appropriate DNA binding site and thereby stimulating transcription; and that the anomalous regulation of lac in this host is unconnected with the CRP system.

Transcription of the trpR gene of Escherichia coli: an autogeneously regulated system studied by direct measurements of mRNA levels in vivo

The expression of the trpR gene of Escherichia coli was investigated by measuring trpR messenger RNA levels in vivo under various physiological conditions. Trp repressor, when present, led to significant decreases in the amount of trpR message produced; this effect was enhanced by providing excess L-tryptophan to the system. In the absence of Trp repressor, no changes in trpR message levels were observed under any of the conditions employed. Sedimentation profiles of trpR mRNA revealed a single species under all circumstances. These results suggest that autogenous repression alone acts to regulate transcription of the trpR gene. The activity of the trpR promoter in vivo was evaluated using a trpR-lacZ operon fusion. Very good agreement was found between relative promoter activity and trpR message levels under all experimental conditions.

Analysis in vivo of factors affecting the control of transcription initiation at promoters containing target sites for trp repressor

An investigation of repression in the trp system of Escherichia coli was undertaken using operon fusions and plasmids constructed via recombinant DNA technology. The promoters of the trp operon and the trpR gene were fused to lacZ, enabling the activity of these promoters to be evaluated under various conditions through measurements of beta-galactosidase production. In confirmation of earlier studies, the trpR gene was shown to be regulated autogenously. This control feature of the trp system was found to maintain intracellular Trp repressor protein at essentially invariant levels under most conditions studied. Increasing the trpR+ gene dosage did not significantly elevate Trp repressor protein levels, nor did the introduction of additional operator "sinks" result in significantly decreased levels of Trp repressor protein. Definite alterations in intracellular Trp repressor protein levels were achieved only by subverting the normal trpR regulatory elements. The placement of the lacUV5 or the lambda PL promoters upstream of the trpR gene resulted in significant increases in repression of the trp system. Substituting the primary trp promoter/operator for the native trpR promoter/operator resulted in an altered regulatory response of the trp system to tryptophan limitation or excess. The regulation of the trpR gene effectively imparts a broad range of expression to the trp operon in a manner finely attuned to fluctuations in intracellular tryptophan levels.

Control of arg gene expression in Salmonella typhimurium by the arginine repressor from Escherichia coli K-12

The regulation of synthesis of arg enzymes in Salmonella typhimurium by the arginine repressor of Escherichia coli K-12 has been reevaluated using a strain of S. typhimurium in which the argR gene was rendered nonfunctional by inserting the translocatable tetracycline-resistance element Tn10 into the argR gene. In contrast to previous studies, the introduction of the argR+ allelle of E. coli on an F-prime factor to the argR::Tn10 S. typhimurium strain reduced the synthesis of arg enzymes to essentially wild-type levels. The elevated levels of arg enzymes observed in other hybrid merodiploids may have been the consequence of the formation of hybrid repressor molecules. The readily scoreable phenotype of tetracycline resistance facilitated establishing linkage of cod and argR (0.6% cotransduction) by P22 phage-mediated transduction.

Regulatory region of the Klebsiella aerogenes tryptophan operon

The trp operon of Klebsiella aerogenes was cloned, and its regulatory region was sequenced. Comparison with previously reported trp regulatory sequences of other enteric bacteria indicates that the K. aerogenes trp promoter-operator region is most similar to the corresponding region of Salmonella typhimurium. The trp leader regions of K. aerogenes and other enteric bacteria are organized similarly, but there are significant differences in the stabilities of the predicted secondary structures in their leader transcripts. These differences should make the K. aerogenes attenuator a weaker transcription termination site than any of the other attenuator regions studied; this was confirmed in in vitro transcription experiments. The sequence of the leader transcript and the precise site of in vitro termination were determined.

Transcript secondary structures regulate transcription termination at the attenuator of S. marcescens tryptophan operon

We have analysed the regulatory behaviour of deletion mutants lacking different segments of the leader region of the tryptophan operon of Serratia marcescens. Our results support the model in which a particular RNA structure, the terminator, is recognized during transcription as a transcription termination signal, and an alternative RNA structure, the anti-terminator, prevents formation of the terminator. It appears that the role of translation, ribosome stalling and shifts between alternative RNA secondary structures, is simply to regulate formation of the terminator.

Cloning of small DNA fragments containing the Escherichia coli tryptophan operon promoter and operator

A41-bp AluI restriction fragment from the trp promoter-operator region has been cloned into the PvuII site of pBR322, regenerating PvuII sites. Transformants were selected on media that allowed the selection of trp-operator-bearing plasmids. The cloned 41-bp fragment can be released from the vector by PvuII digestion, and it possesses a functional promoter and operator as demonstrated by in vivo tests. The 41-bp fragment contains several restriction sites: HincII, TaqI, RsaI, and a HpaI site that is located at the center of the operator sequence. Two new operator derivatives, symmetrical about the HpaI site, were prepared from the 41-bp fragment by joining two right-side, or two left-side PvuII-HpaI pieces together at the HpaI site. These derivatives showed in vivo operator activity. Plasmids containing up to five copies of the 41-bp trp-promoter-operator fragment have been constructed. These plasmids should be useful in preparing large amounts of the 41-bp fragment.

Comparative studies on the regulation of tryptophan synthesis

In vitro DNA recombination techniques have revolutionized the study of genetic control of biosynthetic pathways. Using examples drawn from the pathway of tryptophan synthesis, approaches to the deciphering of regulatory signals and response mechanisms through transposition of DNA segments and DNA sequence analysis will be presented. After reviewing the known chromosomal arrangements and regulatory patterns of trp genes in the bacterial groups studied so far, and describing the results of transferring all or part of the pathway's genes from one organism to a distantly related one, the use of this technique to analyze new organisms will be described. Along with some advantages over the conventional methods there are some pitfalls. Finally, since it is likely that events analogous to recombinant DNA experiments take place readily in nature, their consequences in studies of bacterial evolution will be conjectured.

Cloning the trpR gene

In Escherichia coli, the structural gene for purine nucleoside phosphorylase, deoD, is subject to insertional inactivation by prophage lambda. From one such secondary site lambda lysogen, strain SP265, one may isolate deletions that remove all or part of the trpR gene and other genes in the deo-thr sector of the E. coli chromosome. Specialized transducing phages harboring serB+ and trpR+ were liberated following induction of SP265. All such phages were N-defective, bio-type pseudolysogens whose DNA persisted in the form of plasmids. A collection of transducing phages, differing in their complement of bacterial DNA, was used to locate cleavage sites for BamHI, SalI, and PvuI within the deoD-trpR region of the E. coli genome. The trpR gene lies within a specific 950 base pair BamHI-PvuI segment. A 1250 base pair BamHI fragment carrying a functional trpR gene was cloned into the amplifiable plasmid pBR322. A single SalI site in this fragment was shown to lie within the TrpR gene. In two situations where increased gene dosage might generate elevated amounts of Trp repressor (N-defective trpR+ pseudolysogens and strains harboring pBR322 trpR+ plasmids) neither tryptophan auxotrophy, enhanced sensitivity to DL-5-methyl-tryptophan, nor super repression of the tryptophan biosynthetic enzymes was observed.

Structural and functional analysis of cloned deoxyribonucleic acid containing the trpR-thr region of the Escherichia coli chromosome

Specialized transducing phages containing the thr-trpR region of the Escherichia coli chromosome were derived from a strain with lambda prophage inserted in thr. Cloning of segments of the chromosomal deoxyribonucleic acid of one such lambda thr + trpR+ phage in various plasmid vectors established that a 1.3-kilobase BamHI fragment carried trpR+ intact. Strains with a multicopy plasmid vector containing the BamHI insert produced 20-fold-higher levels of trp aporepressor than did the wild-type strain of Escherichia coli. Similarly, induction of lambda thr + trpR+ lysogens resulted in increased aporepressor levels. The 1.3-kilobase trpR+ BamHI fragment was inserted in either orientation downstream from lambda pLN in a plasmid vector in which transcription from lambda pL was under the control of a temperature-sensitive lambda repressor. Induction established the orientation of transcription of trpR and led to the production of 100-fold-increased levels of trp aporepressor. A presumptive 23,500-dalton trpR+ polypeptide was detected by using lambda pLNtrpR+ plasmid deoxyribonucleic acid in a cell-free transcription-translation system.

The regulatory region of the trp operon of Serratia marcescens

The nucleotide sequence of the regulatory region of the trp operon of Serratia marcescens is presented. It contains a transcription termination control site in the transcribed leader region preceding the first structural gene of the operon as well as a regulated promoter/operator transcription initiation region. The structural organisation of the leader region differs substantially from that of Escherichia coli.

Naturally occurring promoter down mutation: nucleotide sequence of the trp promoter/operator/leader region of Shigella dysenteriae 16

The promoter/operator/leader region of the trp operon of Shigella dysenteriae 16 has single base pair differences from the corresponding region of Escherichia coli at positions -24 and -13. The difference at -13 was shown to be responsible for the 90% reduction in promoter function characteristic of the trp operon of S. dysenteriae. The base pair difference at position -13 also renders the operator partially constitutive. This allows the organism to maintain relatively high repressed levels of the trp enzymes and increases the relative importance of attenuation as a transcription control mechanism. These findings and the earlier observation that the trpE protein of S. dysenteriae is only slightly active explain the low in vivo expression of the trp operon of this organism. Nutritional studies suggest that operons involved in other amino acid biosynthetic pathways in S. dysenteriae 16 may be similarly partially inactivated.

Arginine regulon control in a Salmonella typhimurium--Escherichia coli hybrid merodiploid

The regulation of synthesis of arg enzymes was studied in a hybrid merodiploid in which an episome of Escherichia coli carrying the argR+ allele was transfered to Salmonella typhimurium argR strain. The arg enzyme levels of the hybrid merodiploid were compared to that found in argR and argR+ haploids of S. typhimurium. The results showed that repression of synthesis of arg enzymes was effected through the introduction of the E. coli argR+ allele but significant quantitative differences of arg enzyme levels in the argR+ haploid and the hybrid merodiploid were observed.

Naturally occurring sites within the Shigella dysenteriae tryptophan operon severely limit tryptophan biosynthesis

We investigated the structural, functional, and regulatory properties of the Shigella dysenteriae tryptophan (trp.) operon in transduction hybrids in which the cysB-trp-region of Escherichia coli is replaced by the corresponding region from S. dysenteriae. Tryptophan biosynthesis was largely blocked in the hybrids, although the order of the structural genes was identical with that of E. coli. Nutritional tests and enzyme assays revealed that the hybrids produced a defective anthranilate synthetase (ASase). Deletion mapping identified two distinct sites in trpE, each of which was partially responsible for the instability and low activity of ASase. We also discovered a pleiotropic site trpP (S) that maps outside the structural gene region and is closely linked to the S. dysenteriae trp operator. trpP (S) reduced the rate of trp messenger ribonucleic acid synthesis, and consequently trp enzyme levels, 10-fold relative to wild-type E. coli. In recombinants in which the structural genes of E coli were under the control of the S. dysenteriae promoter, enzyme levels were also reduced 10-fold. In some fast-growing revertants of the original hybrids, the rates of trp messenger ribonucleic acid synthesis and levels of tryptophan synthetase were restored to values characteristic of wild-type E.coli. Thus, the Trp auxotrophy associated with the S dysenteriae trp operon derives from the combination of a defective ASase and decreased expression of the entire operon imposed by trpP (S).