The aroQ-encoded monofunctional chorismate mutase (CM-F) protein is a periplasmic enzyme in Erwinia herbicola.

Enteric bacteria possess two species of chorismate mutase which exist as catalytic domains on the amino termini of the bifunctional PheA and TyrA proteins. In addition, some of these organisms possess a third chorismate mutase, CM-F, which exists as a small monofunctional protein. The CM-F gene (denoted aroQ) from Erwinia herbicola was cloned and sequenced for the first time. A strategy for selection by functional complementation in a chorismate mutase-free Escherichia coli background was devised by using a recombinant plasmid derivative of pUC18 carrying a Zymomonas mobilis tyrC insert which encodes cyclohexadienyl dehydrogenase. The aroQ gene is 543 bp in length, predicting a 181-residue protein product having a calculated molecular mass of 20,299 Da. The E. herbicola aroQ promoter is recognized by E. coli, and a putative sigma-70 promoter region was identified. N-terminal amino acid sequencing of the purified CM-F protein indicated cleavage of a 20-residue signal peptide. This was consistent with the monomeric molecular mass determined for the enzyme of about 18,000 Da. The native enzyme is a homodimer. The implied translocation of CM-F was confirmed by osmotic shock experiments which demonstrated a periplasmic location. Immunogold electron microscopy indicated a polar localization within the periplasm. Polyclonal antibody raised against E. herbicola CM-F did not cross-react with the CM-F protein from the closely related Serratia rubidaea, as well as from a number of other gram-negative bacteria. Furthermore, when the E. herbicola aroQ gene was used as a probe in Southern blot hybridizations with EcroRI digests of chromosomal DNA from S. rubidaea and other enteric organisms, no hybridization was detected at low stringency. Thus, the aroQ gene appears to be unusually divergent among closely related organisms. The deduced CM-F amino acid sequence did not exhibit compelling evidence for homology with the monofunctional chorismate mutase protein of Bacillus subtilis.     

The Helicobacter pylori ureC gene codes for a phosphoglucosamine mutase.

The function of UreC, the product of a 1,335-bp-long open reading frame upstream from the urease structural genes (ureAB) of Helicobacter pylori, was investigated. We present data showing that the ureC gene product is a phosphoglucosamine mutase. D. Mengin-Lecreulx and J. van Heijenoort (J. Biol. Chem. 271:32-39, 1996) observed that UreC is similar (43% identity) to the GlmM protein of Escherichia coli. Those authors showed that GlmM is a phosphoglucosamine mutase catalyzing interconversion of glucosamine-6-phosphate into glucosamine-1-phosphate, which is subsequently transformed into UDP-N-acetylglucosamine. The latter product is one of the main cytoplasmic precursors of cell wall peptidoglycan and outer membrane lipopolysaccharides. The present paper reports that, like its E. coli homolog glmM, the H. pylori ureC gene is essential for cell growth. It was known that growth of a lethal conditional glmM mutant of E. coli at a nonpermissive temperature can be restored in the presence of the ureC gene. We showed that complete complementation of the glmM mutant can be obtained with a plasmid overproducing UreC. The peptidoglycan content and the specific phosphoglucosamine mutase activity of such a complemented strain were measured; these results demonstrated that the ureC gene product functions as a phosphoglucosamine mutase. Homologs of the UreC and GlmM proteins were identified in Haemophilus influenzae, Mycobacterium leprae, Clostridium perfringens, Synechocystis sp. strain PCC6803, and Methanococcus jannaschii. Significant conservation of the amino acid sequence of these proteins in such diverse organisms suggests a very ancient common ancestor for the genes and defines a consensus motif for the phosphoglucosamine mutase active site. We propose renaming the H. pylori ureC gene the glmM gene.     

Identification of a gene for beta-tubulin in Aspergillus nidulans.

The tubulins of Aspergillus nidulans have been characterized in wild-type and ben A, B and C benomyl-resistant strains by two-dimensional gel electrophoresis, co-polymerization with porcine brain tubulin and peptide mapping. Four α-tubulins and at least four β-tubulins were resolved by two-dimensional gel electrophoresis of wild-type proteins. Eighteen of 26 benA mutants studied had electrophoretically abnormal β-tubulins. In these strains, one or more of the β-tubulins had either an altered isoelectric point or an altered electrophoretic mobility in the SDS gel dimension, or was diminished in amount. The a-tubulins were normal. Two-dimensional gels of protein extracts of a ben A/wild-type diploid strain demonstrated co-expression of the wild-type β-tubulins with the variant ben A tubulin. This experiment rules out post-translational modification as the source of the β-tubulin abnormalities in the benA mutants. We therefore conclude that benA must be a structural gene for β-tubulin. Due to the variety of abnormalities affecting β-tubulins in ben A mutants, and the absence of abnormalities affecting α-tubulins in any of the benomyl-resistant mutants, we also believe that the benomyl binding site must be located on the β-subunit of the tubulin dimer. The benA mutants of A. nidulans promise to be useful not only for characterizing the biochemical determinants of the benomyl binding site of tubulin but also for understanding the relationship between tubulin structure and function.     

Identification of a gene for alpha-tubulin in Aspergillus nidulans.

This paper demonstrates that revertants of temperature-sensitive benA (β-tubulin) mutations in Aspergillus nidulans can be used to identify proteins which interact with β-tubulin. Three benomyl-resistant benA (β-tubulin) mutants of Aspergillus nidulans, BEN 9, BEN 15 and BEN 19, were found to be temperature-sensitive (ts^?) for growth. Temperature sensitivity co-segregated with benomyl resistance among the progeny of outcrosses of BEN 9, 15 and 19 to a wild-type strain, FGSC#99, indicating that temperature sensitivity was caused by mutations in the benA gene in these strains. Eighteen revertants to ts⁺ were isolated by selection at the restrictive temperature. Four had back-mutations in the benA gene and fourteen carried extragenic suppressor mutations. Two of the back-mutated strains had β-tubulins which differed from the β-tubulins of their parental strains by one (1^?) or two (2^?) negative charges on two-dimensional gel electrophoresis. Although the β-tubulins of the extragenic suppressor strains were all electrophoretically identical to those of the parental strains, one of the suppressor strains, BEN 9R7, had an electrophoretic abnormality in α1-tubulin (1⁺). A heterozygous diploid between this strain and a strain with wild-type α1-tubulin was found to have both wild-type and mutant (1⁺) α1-tubulins. This experiment rules out post-translational modification as a possible cause of the α1-tubulin abnormality. Thus the suppressor mutation in BEN 9R7 must be in a structural gene for α1-tubulin. We propose that this gene be designated tubA to denote that it is a gene for α1-tubulin in A. nidulans.     

A new test for chorismate mutase activity.

Chorismate mutase (EC 5.4.99.5) catalyzes the conversion of chorismic acid to prephenic acid. A continuous test of the enzymatic activity is based on the decrease of the absorption of the substrate chorismate at 274 nm (1). In a sensitive but discontinuous test, prephenic acid, the product of the enzymatic reaction is converted to phenylpyruvic acid. The absorbance of its enolic form is determined in alkaline solution at 320 nm (2,3). Another discontinuous test makes use of the absorption of the phenylpyruvate enol-borate complex (4,5) at 300 nm. The continuous test cannot be used when aromatic compounds are to be tested as modifiers of the enzymatic activity. Similarly, the tests based on the absorption of the enolic form of phenylpyruvic acid cannot be used when compounds which show a high absorbance in the 300 to 320 nm wavelength region are tested. This paper describes a test for chrismate mutase based on the determination of the 2,4-dinitrophenylhydrazone of the α-keto acid, phenylpyruvic acid. In alkaline solution the 2,4-dinitrophenylhydrazone of phenylpyruvic acid shows an absorption maximum at 440 nm, thus allowing one to test compounds like 3-hydroxybenzoic acid and 5-hydroxyisophthalic acid as potential inhibitors of the enzymatic reaction.     

The structural gene for NADP L-glutamate dehydrogenase in Aspergillus nidulans.

A total of 41 mutants lacking NADP L-glutamate dehydrogenase (NADP-GDH) activity have been studied. All the mutations were located at the gdhA locus within 0-1% recombination of gdhAI. Two mutants, gdhAI and gdhA2, out of five examined, produced cross-reacting material which neutralized NADP-GDH anti-serum. The mutant gdhA9 has altered Km values for all five substrates: ammonium, alpha-ketoglutarate, l-glutamate, NADPH and NADP. The mutant gdhA20 had temperature-sensitive growth, abnormal ammonium-regulation characteristics and thermolabile NADP-GDH activity. These results show that gdhA is the structural gene for NADP-GDH.     

Design,selection, and characterization of a split chorismate mutase

Split proteins are versatile tools for detecting protein–protein interactions and studying protein folding. Here, we report a new, particularly small split enzyme, engineered from a thermostable chorismate mutase (CM). Upon dissecting the helical‐bundle CM from Methanococcus jannaschii into a short N‐terminal helix and a 3‐helix segment and attaching an antiparallel leucine zipper dimerization domain to the individual fragments, we obtained a weakly active heterodimeric mutase. Using combinatorial mutagenesis and in vivo selection, we optimized the short linker sequences connecting the leucine zipper to the enzyme domain. One of the selected CMs was characterized in detail. It spontaneously assembles from the separately inactive fragments and exhibits wild‐type like CM activity. Owing to the availability of a well characterized selection system, the simple 4‐helix bundle topology, and the small size of the N‐terminal helix, the heterodimeric CM could be a valuable scaffold for enzyme engineering efforts and as a split sensor for specifically oriented protein–protein interactions.     

Identification, characterization and comparative analysis of a novel chorismate mutase gene in Arabidopsis thaliana

Phenylalanine, tyrosine, and tryptophan have a dual biosynthetic role in plants; they are required for protein synthesis and are also precursors to a number of aromatic secondary metabolites critical to normal development and stress responses. Whereas much has been learned in recent years about the genetic control of tryptophan biosynthesis in Arabidopsis and other plants, relatively little is known about the genetic regulation of phenylalanine and tyrosine synthesis. We have isolated, characterized and determined the expression of Arabidopsis thaliana genes encoding chorismate mutase, the enzyme catalyzing the first committed step in phenylalanine and tyrosine synthesis. Three independent Arabidopsis chorismate mutase cDNAs were isolated by functional complementation of a Saccharomyces cerevisiae mutation. Two of these cDNAs have been reported independently (Eberhard et al., 1993. FEBS 334, 233-236; Eberhard et al., 1996. Plant J. 10, 815-821), but the third (designated CM-3) represents a novel gene. The different organ-specific expression patterns of these cDNAs, their regulation in response to pathogen infiltration, as well as the different enzymatic characteristics of the proteins they encode are also described. Together, these data suggest that each isoform may play a distinct physiological role in coordinating chorismate mutase activity with developmental and environmental signals.     

Allele specific, gene unspecific suppressors in Aspergillus nidulans.

Summary Seven suppressor mutations have been isolated in Aspergillus nidulans by coreversion of alleles in physiologically unrelated genes namely, alX, sB, alcA, putative structural genes for allantoinase, sulphate permease and alcohol dehydrogenase respectively. The suppressors are allele specific, gene unspecific. Those described map in four loci, suaA, B, C, D. suaA and suaB are on linkage group III, suaC and suaD on VII. suaB111, suaD103 and suaD108 are semi-dominant in their suppression of alX4 and sB43. suaA101, suaA105 and suaC109 are recessive and have a pleiotropic effect on morphology. SuaC109 is cold sensitive for growth as is sua115, an unmapped mutation on linkage group III which is similar in morphology to suaC109. The two mutations, SuaA101 and suaA105 have different spectra of suppression and morphologies. suaA105 weakly suppresses alX4 and sB43 whereas suaA101 strongly suppresses these and alcA125. suaD103 and suaD108 have the same spectrum of suppression. The properties of these suppressors are consistent with their being informational suppressors of the nonsense type.     

Functional analysis of the aroC gene encoding chorismate synthase from Xanthomonas oryzae pathovar oryzae

Xanthomonas oryzae pv. oryzae causes bacterial blight in rice, and this bacterial blight has been widely found in the major rice-growing areas. We constructed a transposon mutagenesis library of X. oryzae pv. oryzae and identified a mutant strain (KXOM9) that is deficient for pigment production and virulence. Furthermore, the KXOM9 mutant was unable to grow in minimal medium lacking aromatic amino acids. Thermal asymmetric interlaced-PCR and sequence analysis of KXOM9 revealed that the transposon was inserted into the aroC gene, which encodes a chorismate synthase in various bacterial pathogens. In planta growth assays revealed that bacterial growth of the KXOM9 mutant in rice leaves was severely reduced. Genetic complementation of this mutant with a 7.9-kb fragment containing aroC restored virulence, pigmentation, and prototrophy. These results suggest that the aroC gene plays a crucial role in the growth, attenuation of virulence, and pigment production of X. oryzae pv. oryzae.