Evolutionary differences in chromosomal locations of four early genes of the tryptophan pathway in fluorescent pseudomonads: DNA sequences and characterization of Pseudomonas putida trpE and trpGDC.

Pseudomonas putida possesses seven structural genes for enzymes of the tryptophan pathway. All but one, trpG, which encodes the small (beta) subunit of anthranilate synthase, have been mapped on the circular chromosome. This report describes the cloning and sequencing of P. putida trpE, trpG, trpD, and trpC. In P. putida and Pseudomonas aeruginosa, DNA sequence analysis as well as growth and enzyme assays of insertionally inactivated strains indicated that trpG is the first gene in a three-gene operon that also contains trpD and trpC. In P. putida, trpE is 2.2 kilobases upstream from the trpGDC cluster, whereas in P. aeruginosa, they are separated by at least 25 kilobases (T. Shinomiya, S. Shiga, and M. Kageyama, Mol. Gen. Genet., 189:382-389, 1983). The DNA sequence in P. putida shows an open reading frame on the opposite strand between trpE and trpGDC; this putative gene was not characterized. Evidence is also presented for sequence similarities in the 5' untranslated regions of trpE and trpGDC in both pseudomonads; the function of these regions is unknown, but it is possible that they play some role in regulation of these genes, since all the genes respond to repression by tryptophan. The sequences of the anthranilate synthase genes in the fluorescent pseudomonads resemble those of p-aminobenzoate synthase genes of the enteric bacteria more closely than the anthranilate synthase genes of those organisms; however, no requirement for p-aminobenzoate was found in the Pseudomonas mutants created in this study.     

Mapping of the tryptophan genes of Acinetobacter calcoaceticus by transformation

Auxotrophs of Acinetobacter calcoaceticus blocked in each reaction of the synthetic pathway from chorismic acid to tryptophan were obtained after N-methyl-N'-nitro-N-nitrosoguanidine mutagenesis. One novel class was found to be blocked in both anthranilate and p-aminobenzoate synthesis; these mutants (trpG) require p-aminobenzoate or folate as well as tryptophan (or anthranilate) for growth. The loci of six other auxotrophic classes requiring only tryptophan were defined by growth, accumulation, and enzymatic analysis where appropriate. The trp mutations map in three chromosomal locations. One group contains trpC and trpD (indoleglycerol phosphate synthetase and phosphoribosyl transferase) in addition to trpG mutations; this group is closely linked to a locus conferring a glutamate requirement. Another cluster contains trpA and trpB, coding for the two tryptophan synthetase (EC 4.2.1.20) subunits, along with trpF (phosphoribosylanthranilate isomerase); this group is weakly linked to a his marker. The trpE gene, coding for the large subunit of anthranilate synthetase, is unlinked to any of the above. This chromosomal distribution of the trp genes has not been observed in other organisms.     

Regulation of a common amidotransferase subunit.

In Bacillus subtilis the trpX locus specifies a glutamine-binding protein designated subunit X, which forms a complex with subunit E to constitute the anthranilate synthase enzyme aggregate (EX) and subunit A to constitute the p-aminobenzoate synthase enzyme aggregate (AX). Subunit X confers upon these enzyme complexes the ability to utilize glutamine as a substrate. The trpX locus has been examined to determine its map position and control. (i) The trpX locus was found to be cotransformed with the lysS and pabA loci. The results of three-factor transformation analyses suggest the following order of these markers: lysS-sul-trpX-pabA. (ii) Mutation to constitutivity of the tryptophan operon resulted in a 50- to 60-fold increase in the level of subunit X when the mutant contained functional trE and abA gene products; however, in the absence of subunit E there was only a 4- to 5-fold increase in the glutamine-binding protein. (iii) Formation of subunit X was derepressed under conditions that allow for the derepression of the trpE and/or pabA loci. (iv) Subunit X synthesis was derepressed to a greater extent in mutants that contain a functional trpE gene product than in mutants that contain a nonsense mutation in the trpE locus. These results are consistent with the hypothesis that the trpE and pabA gene products affect the expression and control of the trpX locus.     

Identification and characterization of genes for a second anthranilate synthase in Pseudomonas aeruginosa: interchangeability of the two anthranilate synthases and evolutionary implications.

Two anthranilate synthase gene pairs have been identified in Pseudomonas aeruginosa. They were cloned, sequenced, inactivated in vitro by insertion of an antibiotic resistance gene, and returned to P. aeruginosa, replacing the wild-type gene. One anthranilate synthase enzyme participates in tryptophan synthesis; its genes are designated trpE and trpG. The other anthranilate synthase enzyme, encoded by phnA and phnB, participates in the synthesis of pyocyanin, the characteristic phenazine pigment of the organism. trpE and trpG are independently transcribed; homologous genes have been cloned from Pseudomonas putida. The phenazine pathway genes phnA and phnB are cotranscribed. The cloned phnA phnB gene pair complements trpE and trpE(G) mutants of Escherichia coli. Homologous genes were not found in P. putida PPG1, a non-phenazine producer. Surprisingly, PhnA and PhnB are more closely related to E. coli TrpE and TrpG than to Pseudomonas TrpE and TrpG, whereas Pseudomonas TrpE and TrpG are more closely related to E. coli PabB and PabA than to E. coli TrpE and TrpG. We replaced the wild-type trpE on the P. aeruginosa chromosome with a mutant form having a considerable portion of its coding sequence deleted and replaced by a tetracycline resistance gene cassette. This resulted in tryptophan auxotrophy; however, spontaneous tryptophan-independent revertants appeared at a frequency of 10(-5) to 10(6). The anthranilate synthase of these revertants is not feedback inhibited by tryptophan, suggesting that it arises from PhnAB. phnA mutants retain a low level of pyocyanin production. Introduction of an inactivated trpE gene into a phnA mutant abolished residual pyocyanin production, suggesting that the trpE trpG gene products are capable of providing some anthranilate for pyocyanin synthesis.     

Tryptophan of facultative methylotrophic bacteria Pseudomonas sp. M. II. Regulation of tryptophan biosynthesis

Regulation of tryptophan biosynthesis of facultative methylotrophic Pseudomonas sp. M was studied. Repression of the trpE, trpD and trpC genes by tryptophan was demonstrated. It was also shown that the trpE and trpDC genes are derepressed noncoordinately. No regulation of the trpF gene product could be demonstrated, indicating that its synthesis is constitutive. The trpA and trpB genes are inducible by indol-3-glycerophosphate. Anthranilate synthase and tryptophan synthase were sensitive to the feedback inhibition. The tryptophan concentrations giving 50% inhibition were estimated to be 9 microM and 1 microM, respectively. Experimental evidence for activation of the N-5-phosphoribosyl anthranilate isomerase and for inhibition of the indol-3-glycerophosphate synthase by some tryptophan intermediates was obtained.     

Tryptophan operon of methylotrophic facultative Pseudomonas sp. M bacteria. I. Isolation and characterization of auxotrophic Trp-mutants

Eighteen auxotropic trp- mutants of the facultative methylotrophic bacteria Pseudomonas sp. M. induced by nitrosoguanidine were characterized. Trp- mutants were tested for a number of biochemical properties: the capacity to grow on tryptophan intermediates, their accumulation in growth medium and activities of key enzymes. The trpE, trpD, trpC, trpF, trpB and trpA mutants were identified. The trpDC121 mutant with a one-point mutation has been obtained. This mutation caused inactivation of two enzymes--anthranilate-5-phosphoribosyl transferase and indole-3-glycerophosphate synthase. Unusual trpA and trpB auxotrophs with TrpAB- phenotype were described. It may be concluded that this type of mutations cause loss of catalytic activity of a subunit of tryptophan synthase as well as its structural modification. As a result, no active tryptophan synthase complex is formed and hence, the activity of the opposite intact subunit is inhibited.     

DNA sequences and characterization of four early genes of the tryptophan pathway in Pseudomonas aeruginosa.

Two pairs of related but easily distinguishable genes for the two subunits of anthranilate synthase have been identified in Pseudomonas aeruginosa. These were cloned, sequenced, inactivated in vitro by insertion of an antibiotic resistance cassette, and returned to the P. aeruginosa chromosome, replacing the wild-type gene. Gene replacement implicated only one of the pairs in tryptophan biosynthesis. This report describes the cloning and sequencing of the tryptophan-related gene pair, designated trpE and trpG, and presents experiments implicating their gene products in tryptophan production. DNA sequence analysis as well as growth and enzyme assays of insertionally inactivated strains indicated that trpG is the first gene in a three-gene operon that also includes trpD and trpC. Complementation of Trp auxotrophs by R-prime plasmids (T. Shinomiya, S. Shiga, and M. Kageyama, Mol. Gen. Genet., 189:382-389, 1983) has shown that a large cluster of pyocin R2 genes is flanked at one end by trpE and the other end by trpDC; the physical map that was obtained shows the distance between trpE and trpDC to be about 25 kilobases. Our restriction map of the trpE and trpGDC regions agrees with data presented by Shinomiya et al.     

Isolation and symbiotic characterization of aromatic amino acid auxotrophs of Sinorhizobium meliloti

Ten aromatic amino acid auxotrophs of Sinorhizobium meliloti (previously called Rhizobium meliloti) Rmd201 were generated by random mutagenesis with transposon Tn5 and their symbiotic properties were studied. Normal symbiotic activity, as indicated by morphological features, was observed in the tryptophan synthase mutants and the lone tyrosine mutant. The trpE and aro mutants fixed trace amounts of nitrogen whereas the phe mutant was completely ineffective in nitrogen fixation. Histology of the nodules induced by trpE and aro mutants exhibited striking similarities. Each of these nodules contained an extended infection zone and a poorly developed nitrogen fixation zone. Transmission electron microscopic studies revealed that the bacteroids in the extended infection zone of these nodules did not show maturation tendency. A leaky mutant, which has a mutation in trpC, trpD, or trpF gene, was partially effective in nitrogen fixation. The histology of the nodules induced by this strain was like that of the nodules induced by the parental strain but the inoculated plants were stunted. These studies demonstrated the involvement of anthranilic acid and at least one more intermediate of tryptophan biosynthetic pathway in bacteroidal maturation and nitrogen fixation in S. meliloti. The alfalfa plant host seems to provide tryptophan and tyrosine but not phenylalanine to bacteroids in nodules.     

The tryptophan operon of the facultative methylotrophic bacteria Pseudomonas sp. M. III. Characteristics of regulatory 5-MTR mutants

Regulatory 5-DL-methyltryptophan (5-MT)-resistant mutants of facultative methylotrophic Pseudomonas sp. M. were obtained. They are able to excrete tryptophan into the growth medium (60 to 300 g/ml). 5-MTR regulatory mutants are characterized by depression of trpE, trpD and trpC genes, which causes the production of intermediates of tryptophan biosynthesis and results in trpA and trpB genes induction as well as in two-fold activation of N-5-phosphoribosyl anthranilateisomerase (trpF gene product). Besides, all mutants demonstrate reduction of synthase feed-back inhibition about 4-11-fold. Together with tryptophan excretion, 5-MTR regulatory mutants are able to excrete tyrosine and unable to utilize this amino acid as the sole carbon source, which points to multiple nature of the selective effect of 5-MT.     

Regulation of tryptophan genes in Rhizobium leguminosarum.

Twelve tryptophan auxotrophs of Rhizobium leguminosarum were characterized biochemically. They were grown in complex and minimal media with several carbon sources, in both limiting and excess tryptophan. Missing enzyme activities allowed assignment of all mutant to the trpE, trpD, trpB, or trpA gene, confirming earlier results with the same mutants (Johnston et al., Mol. Gen. Genet. 165:323-330, 1978). In regulatory experiments, only the first enzyme of the pathway, anthranilate synthase, responded (about 15-fold) to tryptophan excess or limitation.     

Characterization of strain HY99, a novel microorganism capable of aerobic and anaerobic degradation of aniline

We have characterized a novel microorganism, strain HY99, which is capable of aerobic and anaerobic degradation of aniline. Strain HY99 was found to aerobically metabolize aniline via catechol and 2-hydroxymuconic semialdehyde intermediates, and to transform aniline via p-aminobenzoate in anaerobic environments. Physiological and biochemical tests revealed that strain HY99 was most similar to Delftia acidovorans, but unlike D. acidovorans, strain HY99 was able to metabolize aniline under anaerobic conditions linked with nitrate reduction. Phylogenetic analysis based on 16S rDNA sequencing also revealed that strain HY99 was closely related to D. acidovorans, with 96% overall similarity.     

Mutant Strains of Escherichia coli K-12 Exhibiting Enhanced Sensitivity to 5-Methyltryptophan

Eighteen mutants (designated MT(s)), isolated in Escherichia coli K-12, showed increased sensitivity to inhibition of growth by 5-methyltryptophan. All mutants were also much more sensitive to 4-methyltryptophan and 7-azatryptophan but exhibited near normal sensitivity to 5-fluorotryptophan and 6-fluorotryptophan. All of the mutations were linked to the trp operon. Their locations within the trp operon were established by deletion mapping. There was good agreement between the map position of an MT(s) mutation and a lowered activity of one of the tryptophan pathway enzymes. Three mutants, one of which contained a mutation that mapped within the trpE gene, were deficient in their ability to use glutamine as an amino donor in the formation of anthranilic acid. Another trpE mutation led to the production of an anthranilate synthetase with an increased sensitivity to feedback inhibition by tryptophan.     

Molecular cloning and nucleotide sequence of Thermus thermophilus HB8 trpE and trpG

The trpE gene of Thermus thermophilus HB8 was cloned by complementation of an Escherichia coli tryptophan auxotroph. The E. coli harboring the cloned gene produced the anthranilate synthase I, which was heat-stable and enzymatically active at higher temperature. The nucleotide sequence of the trpE gene and its flanking regions was determined. The trpE gene was preceded by an attenuator-like structure and followed by the trpG gene, with a short gap between them. No other gene essential for tryptophan biosynthesis was observed after the trpG gene. The amino-acid sequences of the T. themophilus anthranilate synthase I and II deduced from the nucleotide sequence were compared with those of other organisms.     

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.     

Duplication-translocations of tryptophan operon genes in Escherichia coli

Mutants of Escherichia coli were selected in which a single mutational event had both relieved the polar effect of an early trpE mutation on trpB and simultaneously released the expression of trpB from tryptophan repression. The frequency at which these mutations appeared was roughly equal to the frequency of point mutations. In each of these mutants, the mutation increased the function of trpB and also increased the activity of some, but not all, of the other four tryptophan operon genes. Genetic analysis showed that the mutations were not located within the trp operon since in each case the parental trp operon could be recovered from the mutants. Each mutant was shown to carry a duplication of a trp operon segment translocated to a new position near the trp operon. Polarity is relieved since the trpB duplication-translocation is not in the same operon as the trpE polar mutation. The duplicated and translocated segments are fused to operons not regulated by tryptophan, so trpB function is no longer subject to tryptophan repression. The properties of the mutants indicate that the length of the duplicated segment and the position to which it is translocated differ in each of the seven mutants studied. The duplications are unstable, but the segregation pattern observed is not consistent with a single crossover model for segregation. That such duplication-translocation events generate a variety of new genetic arrangements at a frequency comparable with point mutations suggests they may play an important role in evolution.