Gene rearrangements in the evolution of the tryptophan synthetic pathway

Basics on network theory to analyze biological systems: a hands-on outlook

Biological processes result from interactions among molecules and cell-to-cell communications. In the last 50 years, network theory has empowered advances in understanding molecular networks' structure and dynamics that regulate biological systems. Adopting a network data analysis point of view at more laboratories might enrich their research capacity to generate forward working hypotheses. This work briefly describes network theory origins and provides basic graph analysis principles in biological systems, specific centrality measurements, and the main models for network structures. Also, we describe a workflow employing user-friendly free platforms to process, construct, and analyze transcriptome data from a network perspective. With this assay, we expect to encourage the implementation of network theory analysis on biological data in everyday laboratory research.

The tryptophan biosynthetic pathway is essential for Mycobacterium tuberculosis to cause disease

Mycobacterium tuberculosis, the causative agent of tuberculosis (TB), is the most significant cause of death from a single infectious agent worldwide. Antibiotic-resistant strains of M. tuberculosis represent a threat to effective treatment, and the long duration, toxicity and complexity of current chemotherapy for antibiotic-resistant disease presents a need for new therapeutic approaches with novel modes of action. M. tuberculosis is an intracellular pathogen that must survive phagocytosis by macrophages, dendritic cells or neutrophils to establish an infection. The tryptophan biosynthetic pathway is required for bacterial survival in the phagosome, presenting a target for new classes of antitubercular compound. The enzymes responsible for the six catalytic steps that produce tryptophan from chorismate have all been characterised in M. tuberculosis, and inhibitors have been described for some of the steps. The innate immune system depletes cellular tryptophan in response to infection in order to inhibit microbial growth, and this effect is likely to be important for the efficacy of tryptophan biosynthesis inhibitors as new antibiotics. Allosteric inhibitors of both the first and final enzymes in the pathway have proven effective, including by a metabolite produced by the gut biota, raising the intriguing possibility that the modulation of tryptophan biosynthesis may be a natural inter-bacterial competition strategy.

Effect of TMAO on the Structure and Phase Transition of Lipid Membranes: Potential Role of TMAO in Stabilizing Cell Membranes under Osmotic Stress

Extremophiles adopt strategies to deal with different environmental stresses, some of which are severely damaging to their cell membrane. To combat high osmotic stress, deep-sea organisms synthesize osmolytes, small polar organic molecules, like trimethylamine-N-oxide (TMAO), and incorporate them in the cell. TMAO is known to protect cells from high osmotic or hydrostatic pressure. Several experimental and simulation studies have revealed the roles of such osmolytes on stabilizing proteins. In contrast, the effect of osmolytes on the lipid membrane is poorly understood and broadly debated. A recent experiment has found strong evidence of the possible role of TMAO in stabilizing lipid membranes. Using the molecular dynamics (MD) simulation technique, we have demonstrated the effect of TMAO on two saturated fully hydrated lipid membranes in their fluid and gel phases. We have captured the impact of TMAO's concentration on the membrane's structural properties along with the fluid/gel phase transition temperatures. On increasing the concentration of TMAO, we see a substantial increase in the packing density of the membrane (estimated by area, thickness, and volume) and enhancement in the orientational order of lipid molecules. Having repulsive interaction with the lipid head group, the TMAO molecules are expelled away from the membrane surface, which induces dehydration of the lipid head groups, increasing the packing density. The addition of TMAO also increases the fluid/gel phase transition temperature of the membrane. All of these results are in close agreement with the experimental observations. This study, therefore, provides a molecular-level understanding of how TMAO can influence the cell membrane of deep-sea organisms and help in combating the osmotic stress condition.

Towards Photochromic Azobenzene-Based Inhibitors for Tryptophan Synthase

Light regulation of drug molecules has gained growing interest in biochemical and pharmacological research in recent years. In addition, a serious need for novel molecular targets of antibiotics has emerged presently. Herein, the development of a photocontrollable, azobenzene-based antibiotic precursor towards tryptophan synthase (TS), an essential metabolic multienzyme complex in bacteria, is presented. The compound exhibited moderately strong inhibition of TS in its E configuration and five times lower inhibition strength in its Z configuration. A combination of biochemical, crystallographic, and computational analyses was used to characterize the inhibition mode of this compound. Remarkably, binding of the inhibitor to a hitherto-unconsidered cavity results in an unproductive conformation of TS leading to noncompetitive inhibition of tryptophan production. In conclusion, we created a promising lead compound for combatting bacterial diseases, which targets an essential metabolic enzyme, and whose inhibition strength can be controlled with light.

Generation of a Stand-Alone Tryptophan Synthase α-Subunit by Mimicking an Evolutionary Blueprint

The αββα tryptophan synthase (TS), which is part of primary metabolism, is a paradigm for allosteric communication in multienzyme complexes. In particular, the intrinsically low catalytic activity of the α-subunit TrpA is stimulated several hundredfold through the interaction with the β-subunit TrpB1. The BX1 protein from Zea mays (zmBX1), which is part of secondary metabolism, catalyzes the same reaction as that of its homologue TrpA, but with high activity in the absence of an interaction partner. The intrinsic activity of TrpA can be significantly increased through the exchange of several active-site loop residues, which mimic the corresponding loop in zmBX1. The subsequent identification of activating amino acids in the generated "stand-alone" TrpA contributes to an understanding of allostery in TS. Moreover, findings suggest an evolutionary trajectory that describes the transition from a primary metabolic enzyme regulated by an interaction partner to a self-reliant, stand-alone, secondary metabolic enzyme.

Horizontal gene transfer and redundancy of tryptophan biosynthetic enzymes in dinotoms

A tertiary endosymbiosis between a dinoflagellate host and diatom endosymbiont gave rise to "dinotoms," cells with a unique nuclear and mitochondrial redundancy derived from two evolutionarily distinct eukaryotic lineages. To examine how this unique redundancy might have affected the evolution of metabolic systems, we investigated the transcription of genes involved in biosynthesis of the amino acid tryptophan in three species, Durinskia baltica, Kryptoperidinium foliaceum, and Glenodinium foliaceum. From transcriptome sequence data, we recovered two distinct sets of protein-coding transcripts covering the entire tryptophan biosynthetic pathway. Phylogenetic analyses suggest a diatom origin for one set of the proteins, which we infer to be expressed in the endosymbiont, and that the other arose from multiple horizontal gene transfer events to the dinoflagellate ancestor of the host lineage. This is the first indication that these cells retain redundant sets of transcripts and likely metabolic pathways for the biosynthesis of small molecules and extend their redundancy to their two distinct nuclear genomes.

Enzyme recruitment and its role in metabolic expansion

Although more than 10(9) years have passed since the existence of the last universal common ancestor, proteins have yet to reach the limits of divergence. As a result, metabolic complexity is ever expanding. Identifying and understanding the mechanisms that drive and limit the divergence of protein sequence space impact not only evolutionary biologists investigating molecular evolution but also synthetic biologists seeking to design useful catalysts and engineer novel metabolic pathways. Investigations over the past 50 years indicate that the recruitment of enzymes for new functions is a key event in the acquisition of new metabolic capacity. In this review, we outline the genetic mechanisms that enable recruitment and summarize the present state of knowledge regarding the functional characteristics of extant catalysts that facilitate recruitment. We also highlight recent examples of enzyme recruitment, both from the historical record provided by phylogenetics and from enzyme evolution experiments. We conclude with a look to the future, which promises fruitful consequences from the convergence of molecular evolutionary theory, laboratory-directed evolution, and synthetic biology.

Evolution of tryptophan biosynthetic pathway in microbial genomes: a comparative genetic study

Biosynthetic pathway evolution needs to consider the evolution of a group of genes that code for enzymes catalysing the multiple chemical reaction steps leading to the final end product. Tryptophan biosynthetic pathway has five chemical reaction steps that are highly conserved in diverse microbial genomes, though the genes of the pathway enzymes show considerable variations in arrangements, operon structure (gene fusion and splitting) and regulation. We use a combined bioinformatic and statistical analyses approach to address the question if the pathway genes from different microbial genomes, belonging to a wide range of groups, show similar evolutionary relationships within and between them. Our analyses involved detailed study of gene organization (fusion/splitting events), base composition, relative synonymous codon usage pattern of the genes, gene expressivity, amino acid usage, etc. to assess inter- and intra-genic variations, between and within the pathway genes, in diverse group of microorganisms. We describe these genetic and genomic variations in the tryptophan pathway genes in different microorganisms to show the similarities across organisms, and compare the same genes across different organisms to find the possible variability arising possibly due to horizontal gene transfers. Such studies form the basis for moving from single gene evolution to pathway evolutionary studies that are important steps towards understanding the systems biology of intracellular pathways.

Design of regulation and dynamics in simple biochemical pathways

Complex regulation of biochemical pathways in a cell is brought about by the interaction of simpler regulatory structures. Among the basic regulatory designs, feedback inhibition of gene expression is the most common motif in gene regulation and a ubiquitous control structure found in nature. In this work, we have studied a common structural feature (delayed feedback) in gene organisation and shown, both theoretically and experimentally, its subtle but important functional role in gene expression kinetics in a negatively auto-regulated system. Using simple deterministic and stochastic models with varying levels of realism, we present detailed theoretical representations of negatively auto-regulated transcriptional circuits with increasing delays in the establishment of feedback of repression. The models of the circuits with and without delay are studied analytically as well as numerically for variation of parameters and delay lengths. The positive invariance, boundedness of the solutions, local and global asymptotic stability of both the systems around the unique positive steady state are studied analytically. Existence of transient temporal dynamics is shown mathematically. Comparison of the two types of model circuits shows that even though the long-term dynamics is stable and not affected by delays in repression, there is interesting variation in the transient dynamical features with increasing delays. Theoretical predictions are validated through experimentally constructed gene circuits of similar designs. This combined theoretical and experimental study helps delineate the opposing effects of delay-induced instability, and the stability-enhancing property of negative feedback in the pathway behaviour, and gives rationale for the abundance of similar designs in real biochemical pathways.

Molecular Cloning of the Tryptophan Operon from an Aeromonas hydrophila Freshwater Isolate

A genomic library of Aeromonas hydrophila F9 was constructed by using pBR322 as a vector. From that, two DNA fragments (5.8 and 11.6 kb) were isolated containing genetic information to complement trpA and trpB defects (5.8-kb fragment) and to complement trpA, trpB, trpC, trpD, and trpE defects (11.6-kb fragment) in Escherichia coli mutants. Evidence of the existence of a secondary promoter is given.

Tryptophan biosynthesis in stramenopiles: eukaryotic winners in the diatom complex chloroplast

Tryptophan is an essential amino acid that, in eukaryotes, is synthesized either in the plastids of photoautotrophs or in the cytosol of fungi and oomycetes. Here we present an in silico analysis of the tryptophan biosynthetic pathway in stramenopiles, based on analysis of the genomes of the oomycetes Phytophthora sojae and P. ramorum and the diatoms Thalassiosira pseudonana and Phaeodactylum tricornutum. Although the complete pathway is putatively located in the complex chloroplast of diatoms, only one of the involved enzymes, indole-3-glycerol phosphate synthase (InGPS), displays a possible cyanobacterial origin. On the other hand, in P. tricornutum this gene is fused with the cyanobacteria-derived hypothetical protein COG4398. Anthranilate synthase is also fused in diatoms. This fusion gene is almost certainly of bacterial origin, although the particular source of the gene cannot be resolved. All other diatom enzymes originate from the nucleus of the primary host (red alga) or secondary host (ancestor of chromalveolates). The entire pathway is of eukaryotic origin and cytosolic localization in oomycetes; however, one of the enzymes, anthranilate phosphoribosyl transferase, was likely transferred to the oomycete nucleus from the red algal nucleus during secondary endosymbiosis. This suggests possible retention of the complex plastid in the ancestor of stramenopiles and later loss of this organelle in oomycetes.

Molecular basis defining human Chlamydia trachomatis tissue tropism. A possible role for tryptophan synthase

Here we report the cloning and sequencing of a region of the chlamydiae chromosome termed the "plasticity zone" from all the human serovars of C. trachomatis containing the tryptophan biosynthesis genes. Our results show that this region contains orthologues of the tryptophan repressor as well as the alpha and beta subunits of tryptophan synthase. Results from reverse transcription-PCR and Western blot analyses indicate that the trpBA genes are transcribed, and protein products are expressed. The TrpB sequences from all serovars are highly conserved. In comparison with other tryptophan synthase beta subunits, the chlamydial TrpB subunit retains all conserved amino acid residues required for beta reaction activity. In contrast, the chlamydial TrpA sequences display numerous mutations, which distinguish them from TrpA sequences of all other prokaryotes. All ocular serovars contain a deletion mutation resulting in a truncated TrpA protein, which lacks alpha reaction activity. The TrpA protein from the genital serovars retains conserved amino acids required for catalysis but has mutated several active site residues involved in substrate binding. Complementation analysis in Escherichia coli strains, with defined mutations in tryptophan biosynthesis, and in vitro enzyme activity data, with cloned TrpB and TrpA proteins, indicate these mutations result in a TrpA protein that is unable to utilize indole glycerol 3-phosphate as substrate. In contrast, the chlamydial TrpB protein can carry out the beta reaction, which catalyzes the formation of tryptophan from indole and serine. The activity of the chlamydial Trp B protein differs from that of the well characterized E. coli and Salmonella TrpBs in displaying an absolute requirement for full-length TrpA. Taken together our data indicate that genital, but not ocular, serovars are capable of utilizing exogenous indole for the biosynthesis of tryptophan.

Production and oxidation of indole by Haemophilus influenzae

During growth in high concentrations of iron nitrate, H. influenzae produces compounds reactive in biochemical assays for hydroxamates. Mixing experiments established that nitrate was responsible for inducing these compounds. Analysis by 1H and 13C NMR and high resolution mass spectrometry identified the active species as 2,2-bis(3'-indolyl)indoxyl. Bacterial production of the latter compound has been previously observed only in Pseudomonas aureofaciens. A mutant defective in the production of 2,2-bis(3'-indolyl)indoxyl was constructed by marker insertion. The formation of indole and 2,2-bis (3'-indolyl)indoxyl was quantitated by reverse-phase high pressure liquid chromatography during growth in high concentrations of nitrate. The mutant produced high concentrations of indole, but only minimal amounts of 2,2-bis(3'-indolyl)indoxyl, and also proved to be defective in nitrate reduction. These data suggest that indole may function as an electron donor for nitrate reductase in H. influenzae.

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.

The trpA gene on the plastid genome of Cyanidium caldarium strain RK-1

The trpA gene (for the alpha subunit of tryptophan synthase) was found on the plastid genome of the "primitive" unicellular red alga Cyanidium caldarium strain RK-1. This is the first example of an actively-transcribed gene for tryptophan synthase encoded on a plastid genome. In contrast to trpA, trpB (the gene for the beta subunit of tryptophan synthase) was encoded in the cell nucleus. Considering the primitive characteristics of C. caldarium, trpB must have been lost from the plastid genome before trpA.

Mode of action, kinetic properties and physicochemical characterization of two different domains of a bifunctional (1-->4)-beta-D-xylanase from Ruminococcus flavefaciens expressed separately in Escherichia coli

Two catalytic domains, A and C, of xylanase A (XYLA) from Ruminococcus flavefaciens were expressed separately as truncated gene products from lacZ fusions in Escherichia coli. The fusion products, referred to respectively as XYLA-A1 and XYLA-C2, were purified to homogeneity by anion-exchange chromatography and chromatofocusing. XYLA-A1 was isoelectric at pH 5.0 and had a molecular mass of 30 kDa, whereas XYLA-C2 had a pI of 5.4 and a molecular mass of 44 kDa. The catalytic activity shown by both domains was optimal at 50 degrees C, but XYLA-A1 was more sensitive than XYLA-C2 to temperatures higher than the optimum. XYLA-A1 showed a higher sensitivity to pH than XYLA-C2. The enzyme activity of both domains was completely inactivated in the presence of copper or silver ions and partially inactivated by iron or zinc ions. Neither domain was active on xylo-oligosaccharides shorter than xylopentaose: the rate of degradation of longer xylo-oligosaccharides (degree of polymerization 5-10) increased as the chain length increased. Analysis of the products of hydrolysis of xylo-oligosaccharides and xylan (arabinoxylan) polysaccharide showed that the two domains differed in their modes of action: xylobiose was the shortest product of the hydrolysis. With oat spelt xylan as substrate, XYLA-A1 activity was apparently restricted to regions where xylopyranosyl residues did not carry arabinofuranosyl substituents, whereas XYLA-C2 was able to release hetero-oligosaccharides carrying arabinofuranosyl residues. Neither domain was able to release arabinose from oat spelt xylan.

Glutamate synthase is plastid-encoded in a red alga: implications for the evolution of glutamate synthases

An actively transcribed gene (glsF) encoding for ferredoxin-dependent glutamate synthase (Fd-GOGAT) was found on the plastid genome of the multicellular red alga Antithamnion sp. Fd-GOGAT is not plastid-encoded in chlorophytic plants, demonstrating that red algal plastid genomes encode for additional functions when compared to those known from green chloroplasts. Moreover, our results suggest that the plant Fd-GOGAT has an endosymbiotic origin. The same may not be true for NADPH-dependent GOGAT. In Antithamnion glsF is flanked upstream by cpcBA and downstream by psaC and is transcribed monocistronically. Implications of these results for the evolution of GOGAT enzymes and the plastid genome are discussed.

Tryptophan biosynthesis genes in Lactococcus lactis subsp. lactis

The Lactococcus lactis chromosomal region containing the seven structural genes required for tryptophan biosynthesis was characterized by cloning and sequencing. All of the trp genes were identified by the homology of their products with known Trp proteins from other organisms. The identification was confirmed for five genes by their ability to complement trp mutations in Escherichia coli. The seven structural genes are present in the order trpEGDCFBA and span a 7,968-bp segment. Each gene is preceded by a putative ribosome binding site complementary to the 3' end of the L. lactis 16S rRNA. Three pairs of genes (trpG-trpD, trpC-trpF, and trpB-trpA) overlap, and there is intercistronic spacing of 124, 46, and 585 bp between the trpE-trpG, trpD-trpC, and trpF-trpB gene pairs, respectively. No gene fusion was found. Upstream of the trp genes, a 457-bp noncoding DNA segment contains several regions fitting the consensus for gram-positive promoters and one region strongly resembling a transcription terminator. However, it seems unlikely that an attenuation mechanism similar to the one found in E. coli regulates tryptophan biosynthesis in L. lactis, since no potential leader peptide was detected. We propose that a mechanisms resembling that described in Bacillus spp. can regulate trp genes expression in L. lactis.

Aromatic amino acid biosynthesis in the yeast Saccharomyces cerevisiae: a model system for the regulation of a eukaryotic biosynthetic pathway

This review focuses on the gene-enzyme relationships and the regulation of different levels of the aromatic amino acid biosynthetic pathway in a simple eukaryotic system, the unicellular yeast Saccharomyces cerevisiae. Most reactions of this branched pathway are common to all organisms which are able to synthesize tryptophan, phenylalanine, and tyrosine. The current knowledge about the two main control mechanisms of the yeast aromatic amino acid biosynthesis is reviewed. (i) At the transcriptional level, most structural genes are regulated by the transcriptional activator GCN4, the regulator of the general amino acid control network, which couples transcriptional derepression to amino acid starvation of numerous structural genes in multiple amino acid biosynthetic pathways. (ii) At the enzyme level, the carbon flow is controlled mainly by modulating the enzyme activities at the first step of the pathway and at the branch points by feedback action of the three aromatic amino acid end products. Implications of these findings for the relationship of S. cerevisiae to prokaryotic as well as to higher eukaryotic organisms and for general regulatory mechanisms occurring in a living cell such as initiation of transcription, enzyme regulation, and the regulation of a metabolic branch point are discussed.

Nucleotide sequence and analysis of a gene encoding anthranilate synthase component I in Spirochaeta aurantia

A Spirochaeta aurantia DNA fragment containing the trpE gene and flanking chromosomal DNA was cloned, and the sequence of the trpE structural gene plus 870 bp upstream and 1,257 bp downstream of trpE was determined. The S. aurantia trpE gene codes for a polypeptide of 482 amino acid residues with a predicted molecular weight of 53,629 that showed sequence similarity to TrpE proteins from other organisms. The S. aurantia TrpE polypeptide is not more closely related to the other published spirochete TrpE sequence (that of Leptospira biflexa) than to TrpE polypeptides of other bacteria. Two additional complete open reading frames and one partial open reading frame were identified in the sequenced DNA. One of the complete open reading frames and the partial open reading frame are upstream of trpE and are encoded on the DNA strand opposite that containing trpE. The other open reading frame is downstream of trpE and on the same DNA strand as trpE. On the basis of the results of a protein sequence data base search, it appears that trpE is the only tryptophan biosynthesis gene in the sequenced DNA. This is in contrast to L. biflexa, in which trpE is separated from trpG by only 64 bp.

Molecular cloning, nucleotide sequence, and promoter structure of the Acinetobacter calcoaceticus trpFB operon

The trpFB operon from Acinetobacter calcoaceticus encoding the phosphoribosyl anthranilate isomerase and the beta-subunit of tryptophan synthase has been cloned by complementation of a trpB mutation in A. calcoaceticus, identified by deletion analysis, and sequenced. It encodes potential polypeptides of 214 amino acids with a calculated molecular weight of 23,008 (TrpF) and 403 amino acids with a molecular weight of 44,296 (TrpB). The encoded TrpB sequence shows striking homologies to those from other bacteria, ranging from 47% amino acids identity with the Brevibacterium lactofermentum protein and 64% identity with the Caulobacter crescentus protein. The encoded TrpF sequence, on the other hand, is much less homologous to the ones from other species, ranging between 27% identity with the Bacillus subtilis enzyme and 36% identity with the C. crescentus enzyme. The homologies of both polypeptides are evenly distributed over the entire sequences. The codon usage shows the strong preference for A and T in the third positions typical for A. calcoaceticus genes. The trpFB operon appears to be unlinked to trpA. The trpFB promoter has been determined by primer extension analysis of RNA synthesized from the chromosomally and plasmid-encoded trpFB operons. The starting nucleotides are identical in both cases and define the first promoter from A. calcoaceticus. Potential regulatory features are implied by a palindromic element overlapping the -35 consensus box of the promoter.

Sequence analysis and mapping of the Salmonella typhimurium LT2 umuDC operon

In Escherichia coli, efficient mutagenesis by UV requires the umuDC operon. A deficiency in umuDC activity is believed to be responsible for the relatively weak UV mutability of Salmonella typhimurium LT2 compared with that of E. coli. To begin evaluating this hypothesis and the evolutionary relationships among umuDC-related sequences, we cloned and sequenced the S. typhimurium umuDC operon. S. typhimurium umuDC restored mutability to umuD and umuC mutants of E. coli. DNA sequence analysis of 2,497 base pairs (bp) identified two nonoverlapping open reading frames spanning 1,691 bp that were were 67 and 72% identical at the nucleotide sequence level to the umuD and umuC sequences, respectively, from E. coli. The sequences encoded proteins whose deduced primary structures were 73 and 84% identical to the E. coli umuD and umuC gene products, respectively. The two bacterial umuDC sequences were more similar to each other than to mucAB, a plasmid-borne umuDC homolog. The umuD product retained the Cys-24--Gly-25, Ser-60, and Lys-97 amino acid residues believed to be critical for RecA-mediated proteolytic activation of UmuD. The presence of a LexA box 17 bp upstream from the UmuD initiation codon suggests that this operon is a member of an SOS regulon. Mu d-P22 inserts were used to locate the S. typhimurium umuDC operon to a region between 35.9 and 40 min on the S. typhimurium chromosome. In E. coli, umuDC is located at 26 min. The umuDC locus in S. typhimurium thus appears to be near one end of a chromosomal inversion that distinguishes gene order in the 25- to 35-min regions of the E. coli and S. typhimurium chromosomes. It is likely, therefore, that the umuDC operon was present in a common ancestor before S. typhimurium and E. coli diverged approximately 150 million years ago. These results provide new information for investigating the structure, function, and evolutionary origins of umuDC and for exploring the genetic basis for the mutability differences between S. typhimurium and E. coli.

A tryptophan auxotroph of Hyoscyamus muticus lacking tryptophan-synthase activity

A variant clone of Hyoscyamus muticus (VIIIB9) with a specific, stable requirement for tryptophan has been shown to have the following characteristics: (i) no accumulation of tryptophan from anthranilic acid; (ii) growth on added tryptophan or indole but not on anthranilic acid; (iii) accumulation of indole-3-glycerol phosphate and other indole derivatives; (iv) extractable activity of the enzymes for tryptophan biosynthesis, including the partial reaction 2 of tryptophan synthase but not reactions 1 or 3. Thus these data provide in-vivo evidence for the existence of a two-component, bacterial-type tryptophan synthase in plants, the tryptophan auxotrophy of VIIIB9 probably being the consequence of a mutation in the α-subunit of the tryptophan-synthase complex.

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.

Identification and nucleotide sequence of the Acinetobacter calcoaceticus encoded trpE gene

The trpE gene from Acinetobacter calcoaceticus encoding the anthranilate synthase component I was cloned, identified by deletion analysis and sequenced. It encodes a predicted polypeptide of 497 amino acids with a calculated molecular weight of 55,323. Its primary structure shows 49% identical amino acids with the enzyme from Clostridium thermocellum, 45% with that of Thermus thermophilus and only 35% with that of Escherichia coli. The codon usage of the trpE genes encoding the most homologous enzymes differs greatly indicating selection for amino acid maintainance. The homologies are clustered in the C-terminal 200 amino acids of the sequences indicating that this part is important for enzymic activity.

Cloning and characterization of the trpC gene from an aflatoxigenic strain of Aspergillus parasiticus

The trpC gene in the tryptophan biosynthetic pathway was isolated from an aflatoxigenic Aspergillus parasiticus by complementation of an Escherichia coli trpC mutant lacking phosphoribosylanthranilate isomerase (PRAI) activity. The cloned gene complemented an E. coli trpC mutant deficient in indoleglycerolphosphate synthase (IGPS) activity as well as an Aspergillus nidulans mutant strain that was defective in all three enzymatic activities of the trpC gene (glutamine amidotransferase, IGPS, and PRAI), thus indicating the presence of a complete and functional trpC gene. The location and organization of the A. parasiticus trpC gene on the cloned DNA fragment were determined by deletion mapping and by hybridization to heterologous DNA probes that were prepared from cloned trpC genes of A. nidulans and Aspergillus niger. These experiments suggested that the A. parasiticus trpC gene encoded a trifunctional polypeptide with a functional domain structure organized identically to those of analogous genes from other filamentous fungi. The A. parasiticus trpC gene was expressed constitutively regardless of the nutritional status of the culture medium. This gene should be useful as a selectable marker in developing a DNA-mediated transformation system to analyze the aflatoxin biosynthetic pathway of A. parasiticus.

Rhizobium meliloti anthranilate synthase gene: cloning, sequence, and expression in Escherichia coli

We determined the DNA sequence of the Rhizobium meliloti gene encoding anthranilate synthase, the first enzyme of the tryptophan pathway. Sequences similar to those seen for the two subunits of the enzyme as found in all other procaryotic species studied are present in a single open reading frame of 729 codons. This apparent gene fusion joins the C terminus of the large subunit (TrpE) to the N terminus of the small subunit (TrpG) through a short connecting segment. We designate the fused gene trpE(G). The gene is flanked by a typical rho-independent terminator at the 3' end and a complex regulatory region at the 5' end resembling those of operons under transcriptional attenuation control. The location of the promoter was determined by S1 nuclease protection, using Rhizobium mRNA. Although this promoter was inactive in Escherichia coli, mutations eliciting activity were easily obtained. One of these was a C----T change at position -9 in the -10 region. The +1 position of the mRNA is the first base of the initiation codon of the leader peptide, implying that unlike trpE(G), which has a normal Shine-Dalgarno sequence, the leader peptide gene lacks a ribosome-binding site.

A physical-chemical and immunological comparison shows that native and renatured Escherichia coli tryptophan synthase beta 2 subunits are identical

An acid-denaturation of the beta 2 subunit of Escherichia coli tryptophan synthase has been recently described. In the present study, renaturation yield of acid-denaturated beta 2, and the influence of temperature, protein concentration and presence of ligands are investigated. It is also demonstrated that 3 forms of the protein are obtained at the end of the renaturation process: one is fully active, and is identical to native beta 2, as indicated by some of its chemical and physical properties, as well as by its immunological reactivity towards monoclonal antibodies specific for the native protein. A second form is composed of high molecular weight insoluble and inactive aggregates. A third form consists of low molecular weight soluble and inactive aggregates. The results obtained for the immunochemical reactivity of these small aggregates indicate that they are formed with partly correctly folded beta monomers assembled by specific but incorrect quaternary interactions. The capacity of monoclonal antibodies to detect such incorrect structures and to characterize renatured proteins is particularly emphasized.

Structural organization of the TRP1 gene of Phycomyces blakesleeanus: implications for evolutionary gene fusion in fungi

The complete nucleotide (nt) sequence of the cloned TRP1 gene from Phycomyces blakesleeanus is reported. The gene encodes a trifunctional polypeptide that represents a sequential fusion of glutamine amidotransferase (TrpG), indoleglycerolphosphate synthetase (TrpC), and phosphoribosylanthranilate isomerase (TrpF) activities from the amino- to the carboxy terminus. This genetic organization is characteristic of filamentous fungi in general. The transcription start sites and the polyadenylation sites of the gene have been mapped. The two predominant TRP1 transcripts have a short leader of 13 and 18 nt, while minor species with significantly longer leaders are also detectable. Approximately 50 bp and 70 bp upstream from the major transcription start points, sequences that match the canonical eukaryotic TATA and CAAT boxes, respectively, are found. Two major polyadenylation signals are located approximately 50 and 70 nt downstream from the translational stop. Three closely clustered minor polyadenylation sites map to roughly 120-150 bp 3' to the termination codon. The TRP1 gene is the first and only Phycomyces gene that has been cloned and sequenced. The information regarding the promoter and terminator of a Phycomyces gene derived from these studies should benefit strategies aimed at gene manipulations in this organism.

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.

Nucleotide sequence of aceK, the gene encoding isocitrate dehydrogenase kinase/phosphatase

In Escherichia coli, the phosphorylation and dephosphorylation of isocitrate dehydrogenase (IDH) are catalyzed by a bifunctional protein kinase/phosphatase. We have determined the nucleotide sequence of aceK, the gene encoding IDH kinase/phosphatase. This gene consists of a single open reading frame of 1,734 base pairs preceded by a Shine-Dalgarno ribosome-binding site. Examination of the deduced amino acid sequence of IDH kinase/phosphatase revealed sequences which are similar to the consensus sequence for ATP-binding sites. This protein did not, however, exhibit the extensive sequence homologies which are typical of other protein kinases. Multiple copies of the REP family of repetitive extragenic elements were found within the intergenic region between aceA (encoding isocitrate lyase) and aceK. These elements have the potential for combining to form an exceptionally stable stem-loop structure (delta G = -54 kcal/mol [ca. -226 kJ/mol]) in the mRNA. This structure, which masks the ribosome-binding site and start codon for aceK, may contribute to the downshift in expression observed between aceA and aceK. Another potential stem-loop structure (delta G = -29 kcal/mol [ca. 121 kJ/mol]), unrelated to the REP sequences, was found within aceK.

Phycomyces blakesleeanus TRP1 gene: organization and functional complementation in Escherichia coli and Saccharomyces cerevisiae

We have cloned the gene encoding the TRPF and TRPC functions of Phycomyces blakesleeanus by complementation of the corresponding activities of Escherichia coli. TRPF also complemented a trpl mutation in Saccharomyces cerevisiae. As in other filamentous fungi, such as Neurospora and Aspergillus spp., the P. blakesleeanus TRPF and TRPC formed part of a trifunctional polypeptide encoded by a single gene (called TRP1). Transcription of TRP1 in P. blakesleeanus did not appear to be regulated by light or by the nutritional status of the culture. The information on the structure and organization of a P. blakesleeanus gene derived from these studies should be useful in devising molecular genetic strategies to analyze the sensory physiology of this organism.

Expression of leucine genes from an extremely thermophilic bacterium in Escherichia coli

The organisation of the leucine genes in Thermus thermophilus HB8 was analysed by examining the ability of recombinant DNAs to complement Escherichia coli mutations. The arrangement of the genes is different from that in the mesophilic bacteria E. coli and Salmonella typhimurium. The promoter responsible for the expression of the leuB, leuC and leuD genes of Thermus HB8 in E. coli was identified. The sequence of Thermus DNA containing this promoter revealed structural similarities to the promoter and attenuator regions of the E. coli leucine operon.

Sequence analysis of the Brevibacterium lactofermentum trp operon

Brevibacterium lactofermentum, a Gram-positive bacterium, is a commercially important amino acid producer. In this organism, the tryptophan biosynthetic enzymes are encoded within a 7725 bp HapII-BamHI fragment. Seven open reading frames were identified as trp genes by complementation tests with various B. lactofermentum and Escherichia coli tryptophan auxotrophs. Following the nomenclature established for E. coli and Serratia marcescens, the B. lactofermentum trp genes were designated trpL, trpE, trpG, trpD, trpC (including the trpF domain), trpB, and trpA. The organization of these genes is identical to that in S. marcescens. The nucleotide sequences of the putative ribosome-binding sites for the B. lactofermentum trp genes resemble those of E. coli and Bacillus subtilis. Computer analysis revealed that the trp enzymes of B. lactofermentum resemble the enzymes of the Gram-negative E. coli more closely than those of the Gram-positive B. subtilis.

Phycomyces blakesleeanus TRP1 gene: organization and functional complementation in Escherichia coli and Saccharomyces cerevisiae

We have cloned the gene encoding the TRPF and TRPC functions of Phycomyces blakesleeanus by complementation of the corresponding activities of Escherichia coli. TRPF also complemented a trpl mutation in Saccharomyces cerevisiae. As in other filamentous fungi, such as Neurospora and Aspergillus spp., the P. blakesleeanus TRPF and TRPC formed part of a trifunctional polypeptide encoded by a single gene (called TRP1). Transcription of TRP1 in P. blakesleeanus did not appear to be regulated by light or by the nutritional status of the culture. The information on the structure and organization of a P. blakesleeanus gene derived from these studies should be useful in devising molecular genetic strategies to analyze the sensory physiology of this organism.

Three-dimensional structure of the bifunctional enzyme N-(5'-phosphoribosyl)anthranilate isomerase-indole-3-glycerol-phosphate synthase from Escherichia coli

N-(5'-Phosphoribosyl)anthranilate isomerase-indole-3-glycerol-phosphate synthase from Escherichia coli is a monomeric bifunctional enzyme of Mr 49,500 that catalyzes two sequential reactions in the biosynthesis of tryptophan. The three-dimensional structure of the enzyme has been determined at 2.8-A resolution by x-ray crystallography. The two catalytic activities reside on distinct functional domains of similar folding, that of an eightfold parallel beta-barrel with alpha-helices on the outside connecting the beta-strands. Both active sites were located with an iodinated substrate analogue and found to be in depressions on the surface of the domains created by the outward-curving loops between the carboxyl termini of the beta-sheet strands and the subsequent alpha-helices. They do not face each other, making "channeling" of the substrate between active sites virtually impossible. Despite the structural similarity of the two domains, no significant sequence homology was found when topologically equivalent residues were compared.

Complementation of a trpE deletion in Escherichia coli by Spirochaeta aurantia DNA encoding anthranilate synthetase component I activity

A 2.7-kilobase Sau3A fragment of Spirochaeta aurantia DNA cloned in pBR322 complemented a trpE deletion in Escherichia coli. Deletion analysis and Tn5 mutagenesis of the resulting plasmid pBG100 defined a 2-kilobase-pair region that was required for both the complementation and the synthesis of 59,000- and 47,000-molecular-weight polypeptides (59K and 47K polypeptides) in maxicells. Both the 59K and the 47K polypeptides appear to be encoded by a single gene. A maxicell analysis of pBG100::Tn5 mutants suggests that the 47K polypeptide is not sufficient for the trpE complementation. In vitro and in vivo anthranilate synthetase (AS) assays indicate that the complementing activity encoded by pBG100 was functionally analogous to the AS component I of E. coli in that it utilized NH3 but not glutamine as the amino donor. pBG100 did not encode a glutamine amidotransferase activity, although the AS component I it encoded was capable of interacting with E. coli AS component II to catalyze the glutamine-requiring reaction. Expression appeared to depend on a promoter in the cloned S. aurantia DNA.

Chorismate Mutase Isoenzymes from Selected Plants and Their Immunological Comparison with the Isoenzymes from Sorghum bicolor

The isoenzyme pattern of chorismate mutase (EC 5.4.99.5) was examined by diethylaminoethyl-cellulose chromatography in a wide variety of plants. All plants contained a regulated form of chorismate mutase (CM-1), and most contained an additional, unregulated form (CM-2). The regulatory properties of CM-1 differed significantly between plants. Antisera prepared against CM-1 and CM-2 from Sorghum bicolor were used to test immunological cross reaction of chorismate mutases from other plants. There was a high degree of similarity between chorismate mutase isoenzymes from Sorghum bicolor and Zea mays and some with Hordeum vulgare, but all other species studied were antigenically distinct from sorghum. No homology between the structure of CM-1 and CM-2 was detected within any species.

Analysis of cloned DNA from Leptospira biflexa serovar patoc which complements a deletion of the Escherichia coli trpE gene

To analyze the cloned region of the chromosome of the spirochete Leptospira biflexa serovar patoc which complemented a defect in the trpE gene of Escherichia coli, we performed a series of experiments involving subcloning, transposon mutagenesis, and maxicells. By subcloning into pBR322 we were able to isolate the Leptospira genes on a 9.7-kilobase pair plasmid (pYC6). Transposon mutagenesis with Tn5 identified a 2.8-kilobase pair region of this plasmid as being necessary to complement a trpE deletion mutation in E. coli. Transformation of plasmid pYC6 into E. coli cells deleted for trpE and the proximal end of trpD showed that the Leptospira DNA complemented both defects. A maxicell analysis of various transposon-induced mutations of the plasmid revealed that three proteins (53.5, 23.6, and 22 kilodaltons) were encoded by the 2.8-kilobase pair region of the Leptospira genome. Two different promoters controlled the production of these three proteins.

Clustering of mutations affecting alginic acid biosynthesis in mucoid Pseudomonas aeruginosa

A 10-kilobase DNA fragment previously shown to contain the phosphomannose isomerase gene (pmi) of Pseudomonas aeruginosa was used to construct a pBR325-based hybrid that can be propagated in P. aeruginosa only by the formation of a chromosomal-plasmid cointegrate. This plasmid, designated pAD4008, was inserted into the P. aeruginosa chromosome by recombination at a site of homology between the cloned P. aeruginosa DNA and the chromosome. Mobilization of pAD4008 into P. aeruginosa PAO and 8830 and selection for the stable acquisition of tetracycline resistance resulted in specific and predictable changes in the pattern of endonuclease restriction sites in the phosphomannose isomerase gene region of the chromosomes. Chromosomal DNA from the tetracycline-resistant transformants was used to clone the drug resistance determinant with Bg/II or XbaI, thereby allowing the "walking" of the P. aeruginosa chromosome in the vicinity of the pmi gene. Analysis of overlapping tetracycline-resistant clones indicated the presence of sequences homologous to the DNA insert of plasmid pAD2, a recombinant clone of P. aeruginosa origin previously shown to complement several alginate-negative mutants. Restriction mapping, subcloning, and complementation analysis of a 30-kilobase DNA region demonstrated the tight clustering of several genetic loci involved in alginate biosynthesis. Furthermore, the tetracycline resistance determinant in PAO strain transformed by pAD4008 was mapped on the chromosome by plasmid FP2-mediated conjugation and was found to be located near 45 min.

Arrangement of genes TRP1 and TRP3 of Saccharomyces cerevisiae strains

The tryptophan biosynthetic genes TRP1 and TRP3 and partly also TRP2 and TRP4 have been compared by the technique of Southern hybridization and enzyme measurements in twelve wild isolates of Saccharomyces cerevisiae from natural sources of different continents, in the commonly used laboratory strain S. cerevisiae X2180-1A and in a Kluyveromyces marxianus strain. We could classify these strains into four groups, which did not correlate with their geographical distribution. In no case are the TRP3 and TRP1 genes fused as has been found in other ascomycetes. Two strains were found which, in contrast to strain X2180-1A, show derepression of gene TRP1. Two examples are discussed to demonstrate the usefulness of Southern hybridizations for the identification of closely related strains.

Characterization of the Bacillus subtilis tryptophan promoter region

The nucleotide sequence of the control region of the trp operon of Bacillus subtilis has been determined. The region was shown to contain the trp promoter by deletion analysis and by determination of the transcription start site. The trp promoter shows similarity to the consensus sequence for Escherichia coli and B. subtilis promoters. The presence of the trp control region on a high-copy-number plasmid confers resistance to the tryptophan analogue 5-methyltryptophan. It appears that an approximately 120-base-pair region comprising not only the trp promoter but also adjacent direct repeat sequences is necessary to confer 5-methyltryptophan resistance. We postulate that this region is involved in tryptophan regulation and confers 5-methyltryptophan resistance by titration of a trp regulatory protein. Removal of either the trp promoter or the adjacent direct repeat sequences abolished the 5-methyltryptophan-resistance phenotype. Placement of unrelated promoters adjacent to the direct repeat sequences restored 5-methyltryptophan resistance. This suggests that promoter activity is necessary for the regulatory function.