Roles of the tnaC-tnaA spacer region and Rho factor in regulating expression of the tryptophanase operon of Proteus vulgaris.

To localize the DNA regions responsible for basal-level and induced expression of the tryptophanase (tna) operon of Proteus vulgaris, short deletions were introduced in the 115-bp spacer region separating tnaC, the leader peptide coding region, from tnaA. Deletions were incorporated into a tnaA'-'lacZ reporter construct containing the intact tna promoter-leader region. Expression was examined in Escherichia coli. Deletions that removed 28 to 30 bp from the region immediately following tnaC increased basal-level expression about threefold and allowed threefold induction by 1-methyltryptophan. A deletion removing 34 bp from the distal segment of the leader permitted basal and induced expression comparable to that of the parental construct. The mutant with the largest spacer deletion, 89 bp, exhibited a 30-fold increase in basal-level expression, and most importantly, inducer presence reduced operon expression by ca. 60%. Replacing the tnaC start codon or replacing or removing Trp codon 20 of tnaC of this deletion derivative eliminated inducer inhibition of expression. These findings suggest that the spacer region separating tnaC and tnaA is essential for Rho action. They also suggest that juxtaposition of the tnaC stop codon and the tnaA ribosome binding site in the 89-bp deletion derivative allows the ribosome that has completed translation of tnaC to inhibit translation initiation at the tnaA start codon when cells are exposed to inducer. These findings are consistent with results in the companion article that suggest that inducer allows the TnaC peptide to inhibit ribosome release at the tnaC stop codon.     

tRNA(Trp) translation of leader peptide codon 12 and other factors that regulate expression of the tryptophanase operon.

Tryptophanase (tna) operon expression in Escherichia coli is induced by tryptophan. This response is mediated by features of a 319-base-pair leader region preceding the major structural genes of the operon. Translation of the coding region (tnaC) for a 24-amino-acid leader peptide is essential for induction. We have used site-directed mutagenesis to investigate the role of the single Trp codon, at position 12 in tnaC, in regulation of the operon. Codon 12 was changed to either a UAG or UGA stop codon or to a CGG arginine codon. Induction by tryptophan was eliminated by any of these changes. Studies with suppressor tRNAs indicated that tRNA(Trp) translation of codon 12 in tnaC is essential for induction of the operon. Reduction of tna expression by a miaA mutation supports a role for translation by tRNA(Trp) in regulation of the operon. Frameshift mutations and suppression that allows translation of tnaC to proceed beyond the normal stop codon result in constitutive tna operon expression. Deletion of a potential site for Rho factor utilization just beyond tnaC also results in partial constitutive expression. These studies suggest possible models for tryptophan induction of tna operon expression involving tRNA(Trp)-mediated frame shifting or readthrough at the tnaC stop codon.     

Features of ribosome-peptidyl-tRNA interactions essential for tryptophan induction of tna operon expression

Certain nascent peptide sequences, when within the ribosomal exit tunnel, can inhibit translation termination and/or peptide elongation. The 24 residue leader peptidyl-tRNA of the tna operon of E. coli, TnaC-tRNA(Pro), in the presence of excess tryptophan, resists cleavage at the tnaC stop codon. TnaC residue Trp12 is crucial for this inhibition. The approximate location of Trp12 in the exit tunnel was determined by crosslinking Lys11 of TnaC-tRNA(Pro) to nucleotide A750 of 23S rRNA. Methylation of nucleotide A788 of 23S rRNA was reduced by the presence of Trp12 in TnaC-tRNA(Pro), implying A788 displacement. Inserting an adenylate at position 751, or introducing the change U2609C in 23S rRNA or the change K90H or K90W in ribosomal protein L22, virtually eliminated tryptophan induction. These modified and mutated regions are mostly located near the putative site occupied by Trp12 of TnaC-tRNA(Pro). These findings identify features of the ribosomal exit tunnel essential for tna operon induction.     

Physiological studies of tryptophan transport and tryptophanase operon induction in Escherichia coli.

Escherichia coli forms three permeases that can transport the amino acid tryptophan: Mtr, AroP, and TnaB. The structural genes for these permeases reside in separate operons that are subject to different mechanisms of regulation. We have exploited the fact that the tryptophanase (tna) operon is induced by tryptophan to infer how tryptophan transport is influenced by the growth medium and by mutations that inactivate each of the permease proteins. In an acid-hydrolyzed casein medium, high levels of tryptophan are ordinarily required to obtain maximum tna operon induction. High levels are necessary because much of the added tryptophan is degraded by tryptophanase. An alternate inducer that is poorly cleaved by tryptophanase, 1-methyltryptophan, induces efficiently at low concentrations in both tna+ strains and tna mutants. In an acid-hydrolyzed casein medium, the TnaB permease is most critical for tryptophan uptake; i.e., only mutations in tnaB reduce tryptophanase induction. However, when 1-methyltryptophan replaces tryptophan as the inducer in this medium, mutations in both mtr and tnaB are required to prevent maximum induction. In this medium, AroP does not contribute to tryptophan uptake. However, in a medium lacking phenylalanine and tyrosine the AroP permease is active in tryptophan transport; under these conditions it is necessary to inactivate the three permeases to eliminate tna operon induction. The Mtr permease is principally responsible for transporting indole, the degradation product of tryptophan produced by tryptophanase action. The TnaB permease is essential for growth on tryptophan as the sole carbon source. When cells with high levels of tryptophanase are transferred to tryptophan-free growth medium, the expression of the tryptophan (trp) operon is elevated. This observation suggests that the tryptophanase present in these cells degrades some of the synthesized tryptophan, thereby creating a mild tryptophan deficiency. Our studies assign roles to the three permeases in tryptophan transport under different physiological conditions.     

Role of leader peptide synthesis in tryptophanase operon expression in Escherichia coli K-12.

We used site-directed mutagenesis to replace the Escherichia coli tryptophanase (tna) operon leader peptide start codon with AUC. This change greatly decreased the uninduced rate of tna operon expression, and it also lowered the response to inducer. We conclude that leader peptide synthesis plays an essential role in tna operon expression.     

Nucleotide sequence of the structural gene for tryptophanase of Escherichia coli K-12.

The tryptophanase structural gene, tnaA, of Escherichia coli K-12 was cloned and sequenced. The size, amino acid composition, and sequence of the protein predicted from the nucleotide sequence agree with protein structure data previously acquired by others for the tryptophanase of E. coli B. Physiological data indicated that the region controlling expression of tnaA was present in the cloned segment. Sequence data suggested that a second structural gene of unknown function was located distal to tnaA and may be in the same operon. The pattern of codon usage in tnaA was intermediate between codon usage in four of the ribosomal protein structural genes and the structural genes for three of the tryptophan biosynthetic proteins.     

L-Tryptophan prevents Escherichia coli biofilm formation and triggers biofilm degradation

The effect of deletion of trp operon and tna operon on the Escherichia coli biofilm formation was investigated in order to elucidate the role of L-tryptophan metabolism in biofilm formation. trp operon deletion mutants ΔtrpC, ΔtrpD and ΔtrpE deficient in L-tryptophan biosynthesis showed higher biofilm formation. In addition, ΔtnaC with increased L-tryptophan degradation activity showed higher biofilm formation. On the contrary, ΔtnaA deletion mutant which lost L-tryptophan degradation activity showed low biofilm formation. From these results, it was suggested that decrease of intracellular L-tryptophan level induced biofilm formation and increase of L-tryptophan repressed biofilm formation. So the effect of the addition of L-tryptophan to the medium on the E. coli biofilm formation was investigated. L-Tryptophan addition at starting culture decreased biofilm formation and furthermore L-tryptophan addition after 16 h culture induced the degradation of preformed biofilm. From the above results, it was suggested that maintenance of high intracellular L-tryptophan concentration prevents E. coli biofilm formation and elevation of intracellular L-tryptophan concentration triggers degradation of matured biofilm.     

Location of the gene for the low-affinity tryptophan-specific permease of Escherichia coli.

L-Tryptophan uptake was assayed under conditions in which the aroT gene had been inactivated by deletion and the product of the aroP permease was competitively inhibition. A mutant carrying a deletion from bgl through tnaA showed negligible L-tryptophan uptake, in contrast to a strain possessing an intact tna region or to strains carrying point mutations in tna. The ability to take up L-tryptophan was not restored by lysogenizing the tna-deleted strain with lambda tna+.     

Use of the tna operon as a new molecular target for Escherichia coli detection

A quantitative real-time PCR targeting the tnaA gene was studied to detect Escherichia coli and distinguish E. coli from Shigella spp. These microorganisms revealed high similarity in the molecular organization of the tna operon.