Phosphoribosylanthranilate Isomerase Activity Research Articles

Promiscuous and adaptable enzymes fill "holes" in the tetrahydrofolate pathway in Chlamydia species.

ABSTRACTFolates are tripartite molecules comprising pterin, para-aminobenzoate (PABA), and glutamate moieties, which are essential cofactors involved in DNA and amino acid synthesis. The obligately intracellular Chlamydia species have lost several biosynthetic pathways for essential nutrients which they can obtain from their host but have retained the capacity to synthesize folate. In most bacteria, synthesis of the pterin moiety of folate requires the FolEQBK enzymes, while synthesis of the PABA moiety is carried out by the PabABC enzymes. Bioinformatic analyses reveal that while members of Chlamydia are missing the genes for FolE (GTP cyclohydrolase) and FolQ, which catalyze the initial steps in de novo synthesis of the pterin moiety, they have genes for the rest of the pterin pathway. We screened a chlamydial genomic library in deletion mutants of Escherichia coli to identify the “missing genes” and identified a novel enzyme, TrpFCtL2, which has broad substrate specificity. TrpFCtL2, in combination with GTP cyclohydrolase II (RibA), the first enzyme of riboflavin synthesis, provides a bypass of the first two canonical steps in folate synthesis catalyzed by FolE and FolQ. Notably, TrpFCtL2 retains the phosphoribosyl anthranilate isomerase activity of the original annotation. Additionally, we independently confirmed the recent discovery of a novel enzyme, CT610, which uses an unknown precursor to synthesize PABA and complements E. coli mutants with deletions of pabA, pabB, or pabC. Thus, Chlamydia species have evolved a variant folate synthesis pathway that employs a patchwork of promiscuous and adaptable enzymes recruited from other biosynthetic pathways.

A sugar isomerization reaction established on various ( )8-barrel scaffolds is based on substrate-assisted catalysis

In the course of tryptophan biosynthesis, the isomerization of phosphoribosylanthranilate (PRA) is catalyzed by the (βα)₈-barrel enzyme TrpF. The reaction occurs via a general acid-base mechanism with an aspartate and a cysteine residue acting as acid and base, respectively. PRA isomerase activity could be established on two (βα)₈-barrel enzymes involved in histidine biosynthesis, namely HisA and HisF, and on a HisAF chimera, by introducing two aspartate-to-valine substitutions. We have analyzed the reaction mechanism underlying this engineered activity by measuring its pH dependence, solving the crystal structure of a HisF variant with bound product analogue, and applying molecular dynamics simulations and mixed quantum and molecular mechanics calculations. The results suggest that PRA is anchored by the C-terminal phosphate-binding sites of HisA, HisF and HisAF. As a consequence, a conserved aspartate residue, which is equivalent to Cys7 from TrpF, is properly positioned to act as catalytic base. However, no obvious catalytic acid corresponding to Asp126 from TrpF could be identified in the three proteins. Instead, this role appears to be carried out by the carboxylate group of the anthranilate moiety of PRA. Thus, the engineered PRA isomerization activity is based on a reaction mechanism including substrate-assisted catalysis and thus differs substantially from the naturally evolved reaction mechanism used by TrpF.

Identification and analysis of residues contained on β → α loops of the dual‐substrate (βα)8 phosphoribosyl isomerase A specific for its phosphoribosyl anthranilate isomerase activity

A good model to experimentally explore evolutionary hypothesis related to enzyme function is the ancient-like dual-substrate (beta alpha)(8) phosphoribosyl isomerase A (PriA), which takes part in both histidine and tryptophan biosynthesis in Streptomyces coelicolor and related organisms. In this study, we determined the Michaelis-Menten enzyme kinetics for both isomerase activities in wild-type PriA from S. coelicolor and in selected single-residue monofunctional mutants, identified after Escherichia coli in vivo complementation experiments. Structural and functional analyses of a hitherto unnoticed residue contained on the functionally important beta --> alpha loop 5, namely, Arg(139), which was postulated on structural grounds to be important for the dual-substrate specificity of PriA, is presented for the first time. Indeed, enzyme kinetics analyses done on the mutant variants PriA_Ser(81)Thr and PriA_Arg(139)Asn showed that these residues, which are contained on beta --> alpha loops and in close proximity to the N-terminal phosphate-binding site, are essential solely for the phosphoribosyl anthranilate isomerase activity of PriA. Moreover, analysis of the X-ray crystallographic structure of PriA_Arg(139)Asn elucidated at 1.95 A herein strongly implicates the occurrence of conformational changes in this beta --> alpha loop as a major structural feature related to the evolution of the dual-substrate specificity of PriA. It is suggested that PriA has evolved by tuning a fine energetic balance that allows the sufficient degree of structural flexibility needed for accommodating two topologically dissimilar substrates--within a bifunctional and thus highly constrained active site--without compromising its structural stability.

A Study in Molecular Contingency: Glutamine Phosphoribosylpyrophosphate Amidotransferase is a Promiscuous and Evolvable Phosphoribosylanthranilate Isomerase

The prevalence of paralogous enzymes implies that novel catalytic functions can evolve on preexisting protein scaffolds. The weak secondary activities of proteins, which reflect catalytic promiscuity and substrate ambiguity, are plausible starting points for this evolutionary process. In this study, we observed the emergence of a new enzyme from the ASKA (A Complete Set of E. coli K-12 ORF Archive) collection of Escherichia coli open reading frames. The overexpression of (His)6-tagged glutamine phosphoribosylpyrophosphate amidotransferase (PurF) unexpectedly rescued a ΔtrpF E. coli strain from starvation on minimal media. The wild-type PurF and TrpF enzymes are unrelated in sequence, tertiary structure and catalytic mechanism. The promiscuous phosphoribosylanthranilate isomerase activity of the ASKA PurF variant apparently stems from a preexisting affinity for phosphoribosylated substrates. The relative fitness of the (His)6-PurF/ΔtrpF strain was improved 4.8-fold to nearly wild-type levels by random mutagenesis of purF and genetic selection. The evolved and ancestral PurF proteins were purified and reacted with phosphoribosylanthranilate in vitro. The best evolvant (kcat/KM=0.3 s−1 M−1) was ∼25-fold more efficient than its ancestor but >107-fold less efficient than the wild-type phosphoribosylanthranilate isomerase. These observations demonstrate in quantitative terms that the weak secondary activities of promiscuous enzymes can dramatically improve the fitness of contemporary organisms.

Retraction. Directed evolution of new catalytic activity using the alpha/beta-barrel scaffold.

Nature 403, 617–622 (2000). This laboratory reported the in vitro evolution of an enzyme with phosphoribosyl anthranilate isomerase activity (ivePRAI) from the α/β-barrel scaffold of indole-3-glycerol-phosphate synthase using a combination of rationally designed libraries, DNA shuffling, and selection with Escherichia coli, JA300, a strain that lacks an active PRAI gene.

Directed evolution of new catalytic activity using the alpha/beta-barrel scaffold.

In biological systems, enzymes catalyse the efficient synthesis of complex molecules under benign conditions, but widespread industrial use of these biocatalysts depends crucially on the development of new enzymes with useful catalytic functions. The evolution of enzymes in biological systems often involves the acquisition of new catalytic or binding properties by an existing protein scaffold. Here we mimic this strategy using the most common fold in enzymes, the alpha/beta-barrel, as the scaffold. By combining an existing binding site for structural elements of phosphoribosylanthranilate with a catalytic template required for isomerase activity, we are able to evolve phosphoribosylanthranilate isomerase activity from the scaffold of indole-3-glycerol-phosphate synthase. We find that targeting the catalytic template for in vitro mutagenesis and recombination, followed by in vivo selection, results in a new phosphoribosylanthranilate isomerase that has catalytic properties similar to those of the natural enzyme, with an even higher specificity constant. Our demonstration of divergent evolution and the widespread occurrence of the alpha/beta-barrel suggest that this scaffold may be a fold of choice for the directed evolution of new biocatalysts.

Epigenetic control of an endogenous gene family is revealed by a novel blue fluorescent mutant of arabidopsis

The Wassilewskija strain of Arabidopsis has four genes encoding the tryptophan enzyme phosphoribosylanthranilate isomerase (PAI) located at three unlinked sites. These four PAI genes are methylated over their regions of DNA homology. When PAI copy number is reduced by deletion of two tandemly arrayed genes ( MePAI1-PAI4), a mutant with fluorescent, tryptophan-deficient phenotypes results, because the two remaining methylated PAI genes ( MePA12 and McPAI3) supply insufficient PAI activity. These two methylated genes can be inherited through meiosis, even when they are segregated away from each other in crosses to a strain with unmethylated PAI genes. However, the mutant phenotypes conferred by the methylated PAI genes are unstable, and mutant plants yield occasional revertant somatic sectors and progeny. Revertant lines display coordinately reduced methylation of both PAI2 and PAI3, implying that this hypomethylation acts in a concerted manner across the genome rather than at individual sites.

Molecular cloning and characterization of the trpC gene from Penicillium chrysogenum

We cloned the Penicillium chrysogenum trpC gene from a genomic library by complementation of an Escherichia coli trpC mutant lacking phosphoribosylanthranilate isomerase activity. The gene encodes a 2.7 kb poly(A)+ RNA. We localized the gene by sequence analysis in a 2.9 kb DNA insert found in the smallest plasmid selected from the library. Sequence data strongly suggest that the organization of the gene is similar to that described in other Ascomycetes. We found that a DNA fragment which codes only for the carboxy-terminal portion of the polypeptide is sufficient for complementation of the E. coli trpC9830 mutation.

Transformation of Aspergillus nidulans by using a trpC plasmid.

We constructed a chimeric plasmid carrying a complete copy of the trifunctional trpC gene from the Ascomycete fungus Aspergillus nidulans. This plasmid, designated pHY201, replicates in Escherichia coli, where it confers resistance to ampicillin and chloramphenicol and complements trpC mutants lacking phosphoribosylanthranilate isomerase activity. We used pHY201 to transform an A. nidulans trpC- strain to trpC+ at frequencies of greater than 20 stable transformants per microgram of DNA. Southern blot analysis of DNA from transformants showed that pHY201 DNA had integrated into the A. nidulans chromosomes in a majority of cases. Most of the integration events appeared to occur at the site of the trpC- allele of the recipient strain. In several instances, we succeeded in recovering pHY201, or derivatives thereof, from A. nidulans transformants by restriction endonuclease digestion of chromosomal DNA, ligation, and transformation of E. coli.

Developmental regulation of the Aspergillus nidulans trpC gene.

We have cloned the trifunctional trpC gene from Aspergillus nidulans by hybrid phage lambda complementation of an Escherichia coli trpC mutant lacking phosphoribosylanthranilate isomerase activity. Four different phages sharing a 4.3-kilobase region were obtained. Plasmid subclones containing this region also complemented the E. coli trpC mutant. We determined that a 1.8-kilobase DNA fragment was minimally required for complementation. The fragment hybridized with two poly(A)+ RNAs, 3.0 and 3.2 kilobases in length. We infer that these transcripts are Aspergillus trpC mRNAs and that the entire Aspergillus trpC gene is not required for complementation in E. coli. Levels of both trpC transcripts in poly(A)+ RNA are regulated by growth medium composition. They were highest when cells were grown in minimal medium containing nitrate as the nitrogen source and lowest when cells were grown in medium containing yeast extract. The concentrations of the transcripts are also regulated during conidiophore development. Conidiating cultures grown on medium containing yeast extract had significantly higher levels of both transcripts than did hyphae grown in minimal medium containing nitrate. Levels of the transcripts in mature spores were equivalent to those found in hyphae grown in minimal medium containing nitrate. Results from nutritional experiments with an A. nidulans trpC mutant suggest that developmental regulation of trpC mRNA levels may be related to a high requirement for tryptophan or a compound derived from tryptophan during conidiation.

Inactivation and partial degradation of phosphoribosylanthranilate isomerase-indoleglycerol phosphate synthetase in nongrowing cultures of Escherichia coli

The stability of tryptophan biosynthetic enzyme activities was examined in cultures of repressor-negative (trpR) strains of Escherichia coli K-12 incubated under conditions of nutrient starvation of chloramphenicol inhibition. The results show that four of the five activities examined are stable under most nongrowing conditions, whereas one activity, indoleglycerol phosphate (InGP) synthetase, carried by the trpC protein, is unstable under most conditions tested. Phosphoribosylanthranilate (PRA) isomerase activity, which is also carried by the trpC protein, is unstable during starvation for ammonium, cysteine, or sulfate but is stable under other nongrowing conditions where InGP synthetase is not. InGP synthetase activity but not PRA isomerase activity is also diminished about twofold in cultures using glycerol as a carbon-energy source. These results indicate that one or both activities of the trpC protein is specifically inactivated under several culture conditions. Experiments with antibodies to the trpC protein show that sulfate-starved and ammonium-starved cultures contain 20 to 40% less immunologically reactive trpC protein than unstarved cultures. This indicates that the trpC protein is probably partially degraded under these conditions. During recovery from sulfate starvation or ammonium starvation, cultures slowly regain normal levels of InGP synthetase and PRA isomerase activities, suggesting that inactivation may be reversible.