Genetic evidence for a positive-acting regulatory factor mediating induction in the tryptophan pathway of Pseudomonas aeruginosa

Effects of mutations in the Pseudomonas putida miaA gene: regulation of the trpE and trpGDC operons in P. putida by attenuation

Tn5 insertion mutants defective in regulation of the Pseudomonas putida trpE and trpGDC operons by tryptophan were found to contain insertions in the P. putida miaA gene, whose product (in Escherichia coli) modifies tRNA(Trp) and is required for attenuation. Nucleotide sequences upstream of trpE and trpG encode putative leader peptides similar in sequence to leader peptides found in other bacterial species, and the phenotypes of the mutants strongly suggest that transcription of these operons is regulated solely by attenuation.

Recognition of binding sites I and II by the TrpI activator protein of pseudomonas aeruginosa: efficient binding to both sites requires InGP even when site II is replaced by site I

TrpI protein, the activator of transcription of the trpBA operon of three species of fluorescent Pseudomonads, bends the DNA when it forms either of two well-characterized complexes with the trpBA regulatory region. In complex 1, TrpI is bound only to its strong binding site (site I), whereas in complex 2, which is required for activation of the trpBA promoter, TrpI is bound both to site I and to the weaker site II. Indoleglycerol phosphate (InGP) strongly stimulates formation of complex 2 and is required for activation. The present study focuses on the binding of TrpI to DNA containing a duplication of site I and the effect of the duplication on TrpI-induced DNA bending. We find that even on DNA containing a tandem (direct or inverted) duplication of site I, the formation of DNA-TrpI complexes with both sites occupied is strongly stimulated by InGP. Thus, even when TrpI binding to two adjacent sites needs not be cooperative, InGP significantly promotes the formation of complex 2. Gel binding data indicate that InGP can have several effects: (1) TrpI molecules bound to either of two adjacent strong binding sites appear to interfere with binding to the other site; InGP relieves this apparent interference. (2) InGP increases the intrinsic affinity of TrpI for sites I and II and/or enhances cooperative TrpI binding to adjacent DNA sites. Furthermore, a third molecule of TrpI can form a footprint adjacent to the duplication on DNA containing a direct (but not inverted) repeat of site I, indicating that TrpI bound to site I is oriented asymmetrically in spite of the quasi-symmetry of the binding site. The calculated bending angle for DNA in complex 2 is increased by approximately 20 degrees when site I is substituted in either orientation for site II; thus, on DNA containing a site I duplication, the bending angle of complex 2 is nearly twice that of complex 1.

DNA bending by the TrpI protein of Pseudomonas aeruginosa

TrpI protein, the activator of transcription of the trpBA operon of fluorescent pseudomonads, bends the DNA when it forms either of two well-characterized complexes with the trpBA regulatory region. In complex 1, with TrpI bound only to its strong binding site (site I), the calculated bending angle is 65 to 67 degrees and the center of bending is in the middle of site I. In complex 2, which is required for activation of the trpBA promoter, with TrpI bound both to site I and to the weaker site II, the bending angle is increased to 89 to 90 degrees and the center of bending is at the site I-site II boundary. Indoleglycerol phosphate (InGP), which strongly stimulates formation of complex 2 and is required for activation, does not affect the bending angle of either complex. However, a mutation (-10C/11C) shown previously to affect activation has a small but detectable effect on bending, reducing the calculated bending angle to 83 to 86 degrees. These results suggest a way that DNA bending and InGP may be important for activation.

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.

Nucleotide sequences of the trpI, trpB, and trpA genes of Pseudomonas syringae: positive control unique to fluorescent pseudomonads

A 904-bp probe from Pseudomonas aeruginosa was used to identify the trpB, trpA and trpI genes of Pseudomonas syringae. Transcription initiation at the P. syringae trpBA promoter in vitro was activated by the P. aeruginosa TrpI protein in the presence of indoleglycerol phosphate. Thus, trpB and trpA are regulated positively in three species of fluorescent pseudomonads, P. aeruginosa, P. putida, and P. syringae, but in no other eubacteria so far investigated [Crawford, Annu. Rev. Microbiol. 43 (1989) 567-600]. In addition to conservation of protein-coding sequences, there is a high degree of nucleotide sequence identity in the intergenic control region that includes the divergent trpI and trpBA promoters, especially in the binding sites for TrpI protein. Differences in patterns of codon usage distinguish the trpI genes of P. syringae and P. putida from P. aeruginosa trpI and from the trpB and trpA genes of all three species.

A two-component T7 system for the overexpression of genes in Pseudomonas aeruginosa

A two-component T7 expression system was developed for efficient expression of genes in the nonenteric bacterium, Pseudomonas aeruginosa. The first component of the expression system is a bacteriophage-based transposable element that contains a lacUV5/lacIq-regulated T7 RNA polymerase gene and a selectable antibiotic-resistance determinant. This element, designated miniD-180, was stably integrated into the P. aeruginosa PAO1 chromosome. The second component of this system includes several improved broad-host-range expression vectors containing the T7 gene 10 promoter and multiple cloning site (MCS). These vectors (pEB8, pEB11, and pEB12) contain transcriptional terminators (T1(4)) upstream from the T7 promoter, and T7 terminators downstream from the MCS. Because the T7 promoter is somewhat leaky in these vectors, pEB14 was constructed to decrease transcription of target genes by basal levels of T7 RNA polymerase. This vector contains a core sequence of the lac operator located 19 bp downstream from the transcriptional start point of the T7 promoter, thereby providing a dually regulated system. The utility of this system was demonstrated by placing a promoterless chloramphenicol acetyltransferase (CAT) cassette under control of the T7 promoter and monitoring the isopropyl-beta-D-thiogalactopyranoside-dependent accumulation of CAT in cell-free extracts of P. aeruginosa. We observed up to nearly a 60-fold increase in CAT levels 4 h post-induction, at which time this polypeptide represented up to 20% of the total soluble protein.

Up-promoter mutations in the trpBA operon of Pseudomonas aeruginosa

In Pseudomonas aeruginosa, the operon encoding tryptophan synthase (trpBA) is positively regulated by the TrpI protein and an intermediate in tryptophan biosynthesis, indoleglycerol phosphate (InGP). A gene fusion in which the trpBA promoter directs expression of the Pseudomonas putida xylE gene was constructed. By using a P. putida F1 todE mutant carrying this fusion on a plasmid, three cis-acting mutations that increased xylE expression enough to allow the todE strain to grow on toluene were isolated. The level of xylE transcript from the trpBA promoter was increased in all three mutants. All three mutations are base substitutions located in the -10 region of the trpBA promoter; two of these mutations make the promoter sequence more like the Escherichia coli RNA polymerase sigma 70 promoter consensus sequence. The activities of the wild-type and mutant trpBA promoters, as monitored by xylE expression, were assayed in P. putida PpG1 and in E. coli. The up-regulatory phenotypes of the mutants were maintained in the heterologous backgrounds, as was trpI and InGP dependence. These results indicate that the P. aeruginosa trpBA promoter has the key characteristics of a typical E. coli positively regulated promoter. The results also show that the P. aeruginosa and P. putida trpI activator gene products are functionally interchangeable.

Activation of the trpBA promoter of Pseudomonas aeruginosa by TrpI protein in vitro

We have developed an in vitro transcription system in which purified TrpI protein and indoleglycerol phosphate (InGP) activate transcription initiation at the trpBA promoter (trpPB) and repress initiation at the trpI promoter (trpPI) of Pseudomonas aeruginosa. The phenotypes resulting from mutations in the -10 region of both promoters indicate that the -10 region consensus sequence in P. aeruginosa is probably the same as that in Escherichia coli. Furthermore, in the absence of TrpI and InGP, the activities of the two promoters are inversely correlated: down mutations in trpPI lead to increased activity of trpPB, and up mutations in trpPB cause a decrease in trpPI activity. These results are a consequence of the fact that the two promoters overlap, so that RNA polymerase cannot form open complexes with both promoters simultaneously. Thus, in theory, by preventing RNA polymerase from binding at trpPI, TrpI protein could indirectly activate trpPB. However, oligonucleotide-induced mutations that completely inactivate trpPI do not relieve the requirement for TrpI and InGP to activate trpPB. Therefore, activation of trpPB is mediated by a direct effect of TrpI on transcription initiation at trpPB. In addition, the oligonucleotide-induced mutations in trpPI alter site II, the weaker of two TrpI binding sites identified in DNase I and hydroxyl radical footprinting studies (M. Chang and I. P. Crawford, Nucleic Acids Res. 18:979-988, 1990). Since these mutations prevent full activation of trpPB, we conclude that specific base pairs in site II are required for activation.

In vitro determination of the effect of indoleglycerol phosphate on the interaction of purified TrpI protein with its DNA-binding sites

Expression of the trpBA gene pair of Pseudomonas aeruginosa is regulated by the endogenous level of indoleglycerol phosphate (InGP) and the trpI gene product. The TrpI protein binds to the -77 to -32 region of the trpBA promoter. This region is divisible into two sites: site I, which is protected by TrpI in the presence and absence of InGP; and site II, which is protected by TrpI only in the presence of InGP. Recently, the trpI gene was subcloned into an expression vector and the protein was overproduced in Escherichia coli. The TrpI protein was purified to 80 to 95% purity. The molecular weight of native TrpI protein is estimated to be 129,000 by gel exclusion chromatography, and therefore it is likely a tetramer composed of 31,000-dalton monomers. Gel retardation assays with the purified TrpI protein demonstrated that InGP increases the affinity of TrpI for sites I and II approximately 17- and 14-fold, respectively. Binding of TrpI to site I is site II independent. However, the protein has low intrinsic affinity for site II and its binding to site II is site I dependent. Therefore, binding of TrpI to site II probably requires its interaction with a second TrpI molecule at site I.

RNA polymerases from Pseudomonas aeruginosa and Pseudomonas syringae respond to Escherichia coli activator proteins

The activities of RNA polymerases (RNAPs) from Pseudomonas aeruginosa and Pseudomonas syringae were compared with that of Escherichia coli RNAP. All three enzymes are able to initiate transcription at the trpBA promoter of P. aeruginosa and at the coliphage lambda promoters, pRM and pRE, in response to heterospecific activators (TrpI protein, repressor, and cII protein, respectively). However, both Pseudomonas polymerases have less stringent requirements for promoter recognition in the absence of activators than does E. coli RNAP.

The roles of indoleglycerol phosphate and the TrpI protein in the expression of trpBA from Pseudomonas aeruginosa

The TrpI protein belongs to the LysR-family of procaryotic regulatory proteins. Members of this family share a characteristic similarity of their N-terminal amino acid sequences, and many of them are activators of divergently transcribed genes or operons. In Pseudomonas aeruginosa, the genes for tryptophan synthase, trpBA, are regulated by indoleglycerol phosphate (InGP) and TrpI. We demonstrate here that in the absence of InGP, the binding site of TrpI is located in the -52 to -77 region of the trpBA promoter; in the presence of InGP, the binding region is extended to the -32 region. In addition, two major, slow moving protein-DNA complexes are seen in gel retardation assays: the faster moving complex is formed in the absence of InGP and the amount of the slower moving complex is greatly enhanced in the presence of InGP. These results suggest that the binding of a second TrpI protein molecule, promoted by InGP, plays a crucial role in activating the expression of the trpBA gene pair.

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.

DNA sequence of the tryptophan synthase genes of Pseudomonas putida

Genes encoding the 2 subunits of tryptophan synthase in Pseudomonas putida have been identified and cloned by their similarity to the corresponding genes in Pseudomonas aeruginosa. The deduced amino acid sequences were confirmed by comparison with regions ascertained earlier by protein sequencing. The Pseudomonas amino acid sequences are 85% identical for the beta subunit and 70% identical for the alpha subunit. These sequences are compared to those of Salmonella typhimurium, where the structure is known from X-ray crystallography. Although amino acid conservation drops to 54% and 36% for the beta and alpha subunits, only 3 single residue gaps are required to maintain alignment throughout and most of the residues identified as important for catalysis or cofactor binding are conserved. The 23 residues surrounding the beta chain lysine that enters into a Schiff base linkage with the pyridoxal phosphate cofactor are compared in 13 species, including representatives from the eukaryotic and both prokaryotic kingdoms; appreciable conservation is apparent. The approximately 100 base pairs separating the trpB gene from its divergently transcribed activator gene are similar in the 2 pseudomonads, but do not resemble those of any other bacterium or fungus studied to date.

Sequence of the Pseudomonas aeruginosa trpI activator gene and relatedness of trpI to other procaryotic regulatory genes

In Pseudomonas aeruginosa, the trpI gene product regulates the expression of the trpBA gene pair encoding tryptophan synthase. trpI and trpBA are transcribed divergently. The trpI DNA sequence and deduced amino acid sequence were determined. The trpI start codon was found to be 103 base pairs from that of trpB. trpI encodes a 293-residue protein and the size of the trpI gene product, measured on sodium dodecyl sulfatepolyacrylamide gels, was close to that calculated from the amino acid sequence. The amino acid sequence of trpI resembles that of Enterobacter cloacae ampR, the regulatory gene for the ampC cephalosporinase. The N-terminal portions of trpI and ampR resemble corresponding portions of ilvY, metR, and lysR in Escherichia coli and nodD in Rhizobium meliloti. This resemblance may help to define a trpI-related family of activator proteins sharing a common structural plan.

Regulation of tryptophan biosynthesis in Caulobacter crescentus

We present an analysis of the expression of the trpE gene and the trpFBA operon in the dimorphic bacterium Caulobacter crescentus. The catalytic activity of component I of anthranilate synthase, the product of the trpE gene, was efficiently inhibited by tryptophan, the end product of the pathway, which suggests that tryptophan biosynthesis is likely controlled at the pathway level in C. crescentus. However, trpFBA mRNA levels and trpE enzyme levels did not vary significantly in wild-type C. crescentus in response to the presence of tryptophan in the growth medium or to growth in minimal versus rich medium. This lack of regulation of the trpE, trpF, trpB, and trpA genes is consistent with the idea that oligotrophic bacteria, such as C. crescentus, do not utilize regulatory mechanisms that greatly alter the biosynthetic capabilities in exponentially growing cells. In contrast, mRNA levels from the 5'-untranslated region and the upstream gene (usg) coding region increased dramatically in C. crescentus trpD or hisB auxotrophs starved for tryptophan or histidine, respectively. Surprisingly, concomitant increases in mRNA levels were not detected from the trpF, trpB, or trpA coding regions downstream in the operon. Thus, severe starvation of C. crescentus for amino acids appears to elicit a strong, general transcriptional response that is not observed in bacteria growing exponentially in medium lacking amino acids.

Transductional analysis of the flagellar genes in Pseudomonas aeruginosa

Complementation in bacteriophage E79 tv-l-mediated transduction and the phenotypic properties of the flagellar genes in Pseudomonas aeruginosa PAO were investigated by using 195 flagellar mutants of this organism. A total of 15 fla. 1 mot, and 2 che cistrons were identified. At least 5 fla cistrons (fla V to flaZ) and one mot cistron resided in one region, and at least 10 fla cistrons (flaA to flaJ) and two che cistrons (cheA and cheB) resided in another. The flaC mutants exhibited cistron-specific leakiness on motility agar plates. The flaE cistron may be the structural gene for the component protein of the flagellar filament. The cheA mutations, which resulted in pleiotropic phenotypes for flagellar formation, motility, and taxis, belonged to the same complementation group as the flaF mutations; that is, we inferred that cheA and flaF are synonymous.