Nucleotide sequences and genomic constitution of five tryptophan genes of Lactobacillus casei

Five trp genes, trpD, trpC, trpF, trpB, and trpA, of Lactobacillus casei were cloned by transformation of tryptophan auxotrophic mutants of the respective trp genes in Escherichia coli. These trp genes appear to constitute an operon and are located in the above order in a segment of DNA of 6,468 base pairs. The entire nucleotide sequence of this DNA segment was determined. Five contiguous open reading frames in this segment can encode proteins consisting of 341, 260, 199, 406, and 266 amino acids, respectively, in the same direction. The amino acid sequences of these proteins exhibit 25.5-50.2% homology with the amino acid sequences of the corresponding trp enzymes of E. coli. Two trp genes, trpC and trpF, from L. casei can complement mutant alleles of the corresponding genes of E. coli. However, neither the trpA gene nor the trpB gene of L. casei can complement mutations in the E. coli trpA gene and the trpB gene, respectively, suggesting that the protein products of the L. casei and E. coli trpA and trpB genes, respectively, cannot form heterodimers of tryptophan synthetase with activity. Other features of the coding and flanking regions of the trp genes are also described.     

Restoration of a translational stop-start overlap reinstates translational coupling in a mutant trpB''-trpA gene pair of the Escherichia coli tryptophan operon.

The trpB and trpA coding regions of the polycistronic trp mRNA of Escherichia coli are separated by overlapping translation stop and start codons. Efficient translation of the trpA coding region is subject to translational coupling, i.e., maximal trpA expression is dependent on prior translation of the trpB coding region. Previous studies demonstrated that the trpA Shine-Dalgarno sequence (within trpB) and/or the location of the trpB stop codon influenced trpA expression. To examine the effect of stop codon location specifically, we constructed plasmids in which different nucleotide sequences preceding the trpA start codon were retained, and only the reading frame was changed. When trpB translation proceeded in the wild type reading frame and terminated at the normal trpB stop codon, trpA polypeptide levels were elevated over the levels observed when translation stopped before or after the natural trpB stop codon. The proximity of the trpB stop codon to the trpA start codon therefore markedly influences trpA expression.     

Construction of new cloning vehicles with genes of the tryptophan operon of Escherichia coli as genetic markers

In vitro recombination techniques were used to construct a series of new cloning vehicles with genes of the tryptophan (trp) operon of Escherichia coli as selective marker. To construct these plasmids we have made a restriction cleavage map of the trp operon for the enzymes AosI, AvaI, BglI, BglII, HindIII, HpaI, PvuII, SalI, SstI and XhoI. The constructed plasmids pHP39, pEP392, pEP3921 and pEP3923 are derived from the amplifiable plasmid pBR345 and carry two or more genes of the trp operon, which are controlled by the trp regulatory elements. Plasmid pEP3921 (7.0 kb) carries intact trpE and trpA genes and contains single BglII and SstI sites in trpE, a single HindIII site located between trpE and trpA, and single EcoRI, SalI and XhoI sites located outside the trp genes. Plasmid pEP121 (12 kb) is similar to pEP3921, but has an extra selective marker conferring bacterial resistance to ampicillin. Plasmid pEP3923 (7.4 kb) comprises intact trpB and trpA genes and single BglII, HindIII, EcoRI, SalI and XhoI sites. Plasmids pHP39 (9.8 kb) and pEP392 (9.8 kb) carry an intact trp operon and have two and one EcoRI site, respectively. Plasmid pHP3 (18 kb) carries an intact trp operon and markers for tetracycline and ampicillin resistance.     

A ribosome binding site sequence is necessary for efficient expression of the distal gene of a translationally-coupled gene pair

Expression of trpB and trpA of the Escherichia coli tryptophan operon is shown to be "translationally coupled", i.e., efficient translation of the trpA coding region is dependent on prior translation of the trpB coding region and termination of translation at the trpB stop codon. To examine the dependence of trpA expression on the ribosome binding site sequence in the distal segment of trpB, deletions were produced that replaced this trpB sequence. Analysis of trpA expression in these deletion mutants established that the ribosome binding site sequence is required for efficient translation of the trpA segment of trp mRNA. A modest effect of translation over the trpA ribosome binding site on independent initiation at that site was also observed.     

Cosmid cloning of five Zymomonas trp genes by complementation of Escherichia coli and Pseudomonas putida trp mutants.

A library of Zymomonas mobilis genomic DNA was constructed in the broad-host-range cosmid pLAFR1. The library was mobilized into a variety of Escherichia coli and Pseudomonas putida trp mutants by using the helper plasmid pRK2013. Five Z. mobilis trp genes were identified by the ability to complement the trp mutants. The trpF, trpB, and trpA genes were on one cosmid, while the trpD and trpC genes were on two separate cosmids. The organization of the Z. mobilis trp genes seems to be similar to the organization found in Rhizobium spp., Acinetobacter calcoaceticus, and Pseudomonas acidovorans. The trpF, trpB, and trpA genes appeared to be linked, but they were not closely associated with trpD or trpC genes.     

Genetic and physical analyses of Caulobacter crescentus trp genes.

Caulobacter crescentus trp mutants were identified from a collection of auxotrophs. Precursor feeding experiments, accumulation studies, and complementation experiments resulted in the identification of six genes corresponding to trpA, trpB, trpC, trpD, trpE, and trpF. Genetic mapping experiments demonstrated that the trp genes were in two clusters, trpCDE and trpFBA, and a 5.4-kilobase restriction fragment from the C. crescentus chromosome was isolated that contained the trpFBA gene cluster. Complementation experiments with clones containing the 5.4-kilobase fragment indicated that trpF was expressed in Escherichia coli and that all three genes were expressed in Pseudomonas putida. This expression was lost in both organisms when the pBR322 tet gene promoter was inactivated, indicating that all three genes were transcribed in the same orientation from the tet promoter. Thus, the C. crescentus promoters do not seem to be expressed in E. coli or P. putida. Complementation of the C. crescentus trp mutants indicated that the tet promoter was not necessary for expression in C. crescentus and suggested that at least two native promoters were present for expression of the trpF, trpB, and trpA genes. Taken together, these results indicate that C. crescentus promoters may have structures that are significantly different from the promoters of other gram-negative species.     

Polypeptide folding and dimerization in bacterial luciferase occur by a concerted mechanism in vivo

Bacterial luciferase is a heterodimeric enzyme comprising two nonidentical but homologous subunits, alpha and beta, encoded by adjacent genes, luxA and luxB. The two genes from Vibrio harveyi were separated and expressed from separate plasmids in Escherichia coli. If both plasmids were present within the same E. coli cell, the level of accumulation of active dimeric luciferase was not dramatically less than within cells containing the intact luxAB sequences. Cells carrying the individual plasmids accumulated large amounts of individual subunits, as evidenced by two-dimensional polyacrylamide gel electrophoresis. Mixing of a lysate of cells carrying the luxA gene with a lysate of cells carrying the luxB gene resulted in formation of very low levels of active heterodimeric luciferase. However, denaturation of the mixed lysates with urea followed by renaturation resulted in formation of large amounts of active luciferase. These observations demonstrate that the two subunits, alpha and beta, if allowed to fold independently in vivo, fold into structures that do not interact to form active heterodimeric luciferase. The encounter complex formed between the two subunits must be an intermediate structure on the pathway to formation of active heterodimeric luciferase.     

A novel tryptophan synthase beta-subunit from the hyperthermophile Thermotoga maritima. Quaternary structure, steady-state kinetics, and putative physiological role.

Tryptophan synthase catalyzes the last two steps in the biosynthesis of the amino acid tryptophan. The enzyme is an alpha beta beta alpha complex in mesophilic microorganisms. The alpha-subunit (TrpA) catalyzes the cleavage of indoleglycerol phosphate to glyceraldehyde 3-phosphate and indole, which is channeled to the active site of the associated beta-subunit (TrpB1), where it reacts with serine to yield tryptophan. The TrpA and TrpB1 proteins are encoded by the adjacent trpA and trpB1 genes in the trp operon. The genomes of many hyperthermophilic microorganisms, however, contain an additional trpB2 gene located outside of the trp operon. To reveal the properties and potential physiological role of TrpB2, the trpA, trpB1, and trpB2 genes of Thermotoga maritima were expressed heterologously in Escherichia coli, and the resulting proteins were purified and characterized. TrpA and TrpB1 form the familiar alpha beta beta alpha complex, in which the two different subunits strongly activate each other. In contrast, TrpB2 forms a beta(2)-homodimer that has a high catalytic efficiency k(cat)/K(m)(indole) because of a very low K(m)(indole) but does not bind to TrpA. These results suggest that TrpB2 acts as an indole rescue protein, which prevents the escape of this costly hydrophobic metabolite from the cell at the high growth temperatures of hyperthermophiles.     

Restoration of Phosphoribosyl Transferase Activity by Partially Deleting the trpB Gene in the Tryptophan Operon of Salmonella typhimurium

The amber mutant trpA28, which contains a mutation mapping within the so-called "unusual" region of the tryptophan (trp) operon of Salmonella typhimurium (between the genes trpA and trpB), lacks both components of the anthranilate synthetase (AS)-phosphoribosyl transferase (PRT) enzyme complex, the products of the genes trpA and trpB, respectively. Twenty-six revertants of this mutant selected on minimal medium supplemented with anthranilic acid, a substrate of PRT, contain deletions of various segments of the "unusual" region and make a species of PRT different in every respect from the wild-type, dissociated form of this enzyme. The results indicate that the unusual region corresponds to the operator proximal end of the trpB gene. Mutants in the unusual region, however, show unexpectedly low levels of AS activity and in two cases (trpA515 and trpA28) no detectable activity of this enzyme component.     

Analysis of Polar and Nonpolar Tryptophan Mutants by Derepression Kinetics

A comparison of the rates of synthesis of the tryptophan biosynthetic enzymes of Salmonella typhimurium under derepression showed that the genes of the trp operon can be expressed in a coordinate fashion in auxotrophs carrying nonpolar mutations. This coordination disappeared in trpA polar mutants. The loss of coordination affected only trpB, the second gene in the operon, which was always more drastically affected than the three distal genes. Polar mutations in trpA, the first gene of the trp operon, reduced the rates of synthesis of the tryptophan biosynthetic enzymes under conditions of derepression. When these rates were measured and correlated with the map position of each polar mutation, a polarity gradient of decreasing intensity (moving distally from the operator end of the gene) was obtained. Certain mutations ("unusual mutations") mapping at the operator distal end of trpA, and considered by other workers to correspond to the operator proximal end of trpB, were found to be polar. The bearing of our observations on the question of coordinate versus semicoordinate expression of the trp genes and the status of the "unusual mutations" is discussed.     

Cloning of the trp gene cluster from a tryptophan-hyperproducing strain of Corynebacterium glutamicum: identification of a mutation in the trp leader sequence.

Corynebacterium glutamicum ATCC 21850 produces up to 5 g of extracellular L-tryptophan per liter in broth culture and displays resistance to several synthetic analogs of aromatic amino acids. Here we report the cloning of the tryptophan biosynthesis (trp) gene cluster of this strain on a 14.5-kb BamHI fragment. Subcloning and complementation of Escherichia coli trp auxotrophs revealed that as in Brevibacterium lactofermentum, the C. glutamicum trp genes are clustered in an operon in the order trpE, trpD, trpC, trpB, trpA. The cloned fragment also confers increased resistance to the analogs 5-methyltryptophan and 6-fluorotryptophan on E. coli. The sequence of the ATCC 21850 trpE gene revealed no significant changes when compared to the trpE sequence of a wild-type strain reported previously. However, analysis of the promoter-regulatory region revealed a nonsense (TGG-to-TGA) mutation in the third of three tandem Trp codons present within a trp leader gene. Polymerase chain reaction amplification and sequencing of the corresponding region confirmed the absence of this mutation in the wild-type strain. RNA secondary-structure predictions and sequence similarities to the E. coli trp attenuator suggest that this mutation results in a constitutive antitermination response.     

Clustering of the trp genes in Burkholderia (formerly Pseudomonas) cepacia

Abstract Chromosomal location of trp genes of a strain Burkholderia cepacia (formerly Pseudomonas cepacia ) has been determined by transduction using a generalized transducing phage CP75 and by molecular analysis for a cosmid plasmid clone with trp genes isolated from the genomic gene library of the strain. The trp genes were classified into three linkage groups and they all were closely linked on a short chromosomal region probably in the order ( trpA, trpB, trpF)-(trpC, trpD)-trpE .     

Cloning and sequence analysis of tryptophan synthetase genes of an extreme thermophile, Thermus thermophilus HB27: plasmid transfer from replica-plated Escherichia coli recombinant colonies to competent T. thermophilus cells.

Tryptophan synthetase genes (trpBA) of the extreme thermophile Thermus thermophilus HB27 were cloned by a novel method of direct plasmid transfer from replica-plated Escherichia coli recombinant colonies to competent T. thermophilus HB27 trpB cells. The nucleotide sequences of the trpBA genes were determined. The amino acid sequences deduced from the nucleotide sequences of Thermus trpB and trpA were found to have identities of 54.8 and 28.7%, respectively, with those of E. coli trpB and trpA genes. Low cysteine content (one in trpB; zero in trpA) is a striking feature of these proteins, which may contribute to their thermostability.     

“Self-Feeding” Strain of Salmonella typhimurium with a Mutation in the trpB Gene and Nutritional Requirements of trpA Gene Mutants

An indole-requiring (Ind(-)) mutant of Salmonella typhimurium, isolated from a culture of a leaky trpA mutant, was genetically analyzed by P22-mediated transduction. The mutation site giving the Ind(-) phenotype was shown to be in trpB, the second gene of the trp operon. A second mutation at this site resulted in change of nutritional requirement from indole to anthranilic acid (Anth(-)). This phenotype is normally associated with mutations in the first trp gene, trpA. However, the Anth(-) mutant also excreted anthranilic acid and showed "self-feeding" on unsupplemented media. Of two possible explanations for this aberrant phenotype, the first, that the trpB mutations may be in the "unusual" region, was dismissed on genetic evidence and on the biochemical evidence that an active anthranilate synthetase (AS) is produced. The alternative explanation, that the affected enzymatic activity, phosphoribosyl transferase, is unstable in vivo, but its AS component 2 activity is stable, is considered more probable.     

Effective structure of a leader open reading frame for enhancing the expression of GC-rich genes

To overexpress broad kinds of GC-rich genes in Escherichia coli, we examined how the structures of leader open reading frames (leader ORFs) affect the expression of GC-rich genes, such as polA, trpA, and trpB, from Thermus thermophilus. When a leader ORF overlapped with the polA-initiation codon by 1 bp in the TGATG motif, gene expression increased by more than 3-fold compared to when a leader ORF was several-bp distant from the initiation codon. A 4-bp overlap with the ATGA motif was more effective than a 1-bp overlap with the TGATG motif. When a 4-bp overlapping leader ORF was placed in front of the successive trpB and trpA genes, the trpA gene was poorly expressed whereas the trpB gene was overexpressed. Mutation analysis revealed that the expression of the trpA gene was strongly enhanced by replacing G and C in the translation termination region of the leader ORF with A and T. In contrast, other mutations, such as alterations between synonymous codons in the trpA-coding region, produced diminished gene expression. Using the most effective leader ORF obtained from these results, new expression vectors were constructed.