Genetic analysis of Escherichia coli K-12 mutants defective for the structural and regulatory genes for second purine nucleoside phosphorylase

Two types of mutants lacking the second purine nucleoside phosphorylase (PNPase 2) activity were isolated using the Escherichia coli K-12 pndR strains with constitutive or inosine-inducible synthesis of the PNPase 2. The mutations of the first type are recessive to the pndR+ allele on the F' episome. They are closely linked to the original pndR+ mutations and therefore affect the pndR gene encoding the activator protein. The mutations of the second type affect the PNPase 2 structural gene (pndA) and are recessive to the pndA+ allele on the F' episome. The nupC-pndR-pndA-ptsH-cysA gene order was established by means of four- and five-factorial transductional crosses.     

Identification and characterization of genes (xapA, xapB, and xapR) involved in xanthosine catabolism in Escherichia coli.

We have characterized four genes from the 52-min region on the Escherichia coli linkage map. Three of these genes are directly involved in the metabolism of xanthosine, whereas the function of the fourth gene is unknown. One of the genes (xapA) encodes xanthosine phosphorylase. The second gene, named xapB, encodes a polypeptide that shows strong similarity to the nucleoside transport protein NupG. The genes xapA and xapB are located clockwise of a gene identified as xapR, which encodes a positive regulator belonging to the LysR family and is required for the expression of xapA and xapB. The genes xapA and xapB form an operon, and their expression was strictly dependent on the presence of both the XapR protein and the inducer xanthosine. Expression of the xapR gene is constitutive and not autoregulated, unlike the case for many other LysR family proteins. In minicells, the XapB polypeptide was found primarily in the membrane fraction, indicating that XapB is a transport protein like NupG and is involved in the transport of xanthosine.     

A second purine nucleoside phosphorylase in Escherichia coli K-12

Summary The presence of a second purine nucleoside phosphorylase in wild-type strains of E. coli K-12 after growth on xanthosine has been demonstrated. Like other purine nucleoside phosphorylases it is able to carry out both phosphorylosis and synthesis of purine deoxy- and ribonucleosides whilst pyrimidine nucleosides cannot act as substrates. In contrast to the well characterised purine nucleoside phosphorylase of E. coli K-12 (encoded by the deoD gene) this new enzyme could act on xanthosine and is hence called xanthosine phosphorylase. Studies of its substrate specificity showed that xanthosine phosphorylase, like the mammalian purine nucleoside phosphorylases, has no activity towards adenine and the corresponding nucleosides. Determinations of K _m and gel filtration behaviour was carried out on crude dialysed extracts. The presence of xanthosine phosphorylase enables E. coli to grow on xanthosine as carbon source. Xanthosine was the only compound found which induced xanthosine phosphorylase. No other known nucleoside catabolising enzyme was induced by xanthosine. The implications of non-linear induction kinetics of xanthosine phosphorylase is discussed.     

Isolation and Characterization of Mutations in the Escherichia coli Regulatory Protein XapR

In this work, the LysR-type protein XapR has been subjected to a mutational analysis. XapR regulates the expression of xanthosine phosphorylase (XapA), a purine nucleoside phosphorylase in Escherichia coli. In the wild type, full expression of XapA requires both a functional XapR protein and the inducer xanthosine. Here we show that deoxyinosine can also function as an inducer in the wild type, although not to the same extent as xanthosine. We have isolated and characterized in detail the mutants that can be induced by other nucleosides as well as xanthosine. Sequencing of the mutants has revealed that two regions in XapR are important for correct interactions between the inducer and XapR. One region is defined by amino acids 104 and 132, and the other region, containing most of the isolated mutations, is found between amino acids 203 and 210. These regions, when modelled into the three-dimensional structure of CysB from Klebsiella aerogenes, are placed close together and are most probably directly involved in binding the inducer xanthosine.     

A mutation that alters the nucleotide specificity of elongation factor Tu, a GTP regulatory protein

A single amino acid substitution (Asp to Asn) at position 138 of Escherichia coli elongation factor Tu (EF-Tu) was introduced in the tufA gene clone by oligonucleotide site-directed mutagenesis. The mutated tufA gene was then expressed in maxicells. The properties of [35S]methionine-labeled mutant and wild type EF-Tu were compared by in vitro assays. The Asn-138 mutation greatly reduced the protein's affinity for GDP; however, this mutation dramatically increased the protein's affinity for xanthosine 5'-diphosphate. The mutant protein forms a stable complex with Phe-tRNA and xanthosine 5'-triphosphate, which binds to ribosomes, whereas it does not form a complex with Phe-tRNA and GTP (10 microM). These results suggest that in EF-Tu.nucleoside diphosphate complexes, amino acid residue 138 must interact with the substituent on C-2 of the purine ring. Thus, in wild type EF-Tu, Asp-138 would hydrogen bond to the 2-amino group of GDP, and in the mutant EF-Tu, Asn-138 would form an equivalent hydrogen bond with the 2-carbonyl group of xanthosine 5'-diphosphate. Aspartic acid 138 is conserved in the homologous sequences of all GTP regulatory proteins. This mutation would allow one to specifically alter the nucleotide specificity of other GTP regulatory proteins.     

Identification of an ITPase/XTPase in Escherichia coli by structural and biochemical analysis

Inosine triphosphate (ITP) and xanthosine triphosphate (XTP) are formed upon deamination of ATP and GTP as a result of exposure to chemical mutagens and oxidative damage. Nucleic acid synthesis requires safeguard mechanisms to minimize undesired lethal incorporation of ITP and XTP. Here, we present the crystal structure of YjjX, a protein of hitherto unknown function. The three-dimensional fold of YjjX is similar to those of Mj0226 from Methanococcus janschii, which possesses nucleotidase activity, and of Maf from Bacillus subtilis, which can bind nucleotides. Biochemical analyses of YjjX revealed it to exhibit specific phosphatase activity for inosine and xanthosine triphosphates and have a possible interaction with elongation factor Tu. The enzymatic activity of YjjX as an inosine/xanthosine triphosphatase provides evidence for a plausible protection mechanism by clearing the noncanonical nucleotides from the cell during oxidative stress in E. coli.     

Purification and characterization of RihC, a xanthosine-inosine-uridine-adenosine-preferring hydrolase from Salmonella enterica serovar Typhimurium

Salmonella enterica serovar Typhimurium normally salvage nucleobases and nucleosides by the action of nucleoside phosphorylases and phosphoribosyltransferases. In contrast to Escherichia coli, which catabolizes xanthosine by xanthosine phosphorylase (xapA), Salmonella cannot grow on xanthosine as the sole carbon and energy source. By functional complementation, we have isolated a nucleoside hydrolase (rihC) that can complement a xapA deletion in E. coli and we have overexpressed, purified and characterized this hydrolase. RihC is a heat stable homotetrameric enzyme with a molecular weight of 135 kDa that can hydrolyze xanthosine, inosine, adenosine and uridine with similar catalytic efficiency (k(cat)/Km=1 to 4 x 10(4) M(-1)s(-1)). Cytidine and guanosine is hydrolyzed with approximately 10-fold lower efficiency (k(cat)/Km=0.7 to 1.2 x 10(3) M(-1)s(-1)) while RihC is unable to hydrolyze the deoxyribonucleosides thymidine and deoxyinosine. The Km for all nucleosides except adenosine is in the mM range. The pH optimum is different for inosine and xanthosine and the hydrolytic capacity (k(cat)/Km) is 5-fold higher for xanthosine than for inosine at pH 6.0 while they are similar at pH 7.2, indicating that RihC most likely prefers the neutral form of xanthosine.     

The gua operon of Escherichia coli K-12: evidence for polarity from guaB to guaA

Guanine auxotrophs of Escherichia coli K-12 were isolated after mutagenesis with N-methyl-N'-nitro-N-nitrosoguanidine, ethyl methane sulfonate, or the acridine mustard ICR 372. guaA (xanthosine 5'-monophosphate [XMP] aminase-less) mutants were distinguished from guaB (inosine 5'-monophosphate [IMP] dehydrogenase-less) mutants by their growth response to xanthine and by enzyme assay. Mutations were classified as base substitutions or frameshift on the basis of mutagen-induced reversion patterns. All guaA strains, including three frameshift mutants, produced derepressed levels of IMP dehydrogenase when cultured with a growth-limiting concentration of guanine. The guaB strains were of two types: (i) those producing derepressed levels of XMP aminase, and (ii) those producing basal levels of XMP aminase when grown under conditions of guanine starvation. In the guaB strains of the second type, the expression of the adjacent guaA gene is reduced. It is proposed that this pleiotropic effect of some guaB mutations is a result of polarity. The orientation of polarity suggests the gene order "operator"-guaB-guaA. Gel diffusion studies with IMP dehydrogenase antiserum showed that strains carrying polar guaB mutations do not produce cross-reacting material (CRM). The remaining guaB mutants were either CRM(+) or CRM(-). Mapping the mutations by three-factor crosses showed that polar and nonpolar guaB sites are clustered in a small genetic region cotransducible with guaA. The relative positions of the guaB mutational sites established that the polar mutations lie within the structural gene for IMP dehydrogenase.     

Escherichia coli purine nucleoside phosphorylase II, the product of the xapA gene

Purine nucleoside phosphorylases (PNPs, E. C. 2.4.2.1) use orthophosphate to cleave the N-glycosidic bond of beta-(deoxy)ribonucleosides to yield alpha-(deoxy)ribose 1-phosphate and the free purine base. Escherichia coli PNP-II, the product of the xapA gene, is similar to trimeric PNPs in sequence, but has been reported to migrate as a hexamer and to accept xanthosine with comparable efficiency to guanosine and inosine, the usual physiological substrates for trimeric PNPs. Here, we present a detailed biochemical characterization and the crystal structure of E.coli PNP-II. In three different crystal forms, PNP-II trimers dimerize, leading to a subunit arrangement that is qualitatively different from the "trimer of dimers" arrangement of conventional high molecular mass PNPs. Crystal structures are compatible with similar binding modes for guanine and xanthine, with a preference for the neutral over the monoanionic form of xanthine. A single amino acid exchange, tyrosine 191 to leucine, is sufficient to convert E.coli PNP-II into an enzyme with the specificity of conventional trimeric PNPs, but the reciprocal mutation in human PNP, valine 195 to tyrosine, does not elicit xanthosine phosphorylase activity in the human enzyme.     

Isolation and characterisation of guanine auxotrophs in Saccharomyces cerevisiae.

Mutants of yeast which are auxotrophic for guanine have been isolated from two prototrophic haploid strains, one of which carried the suppressor of purine excretion, su-pur, and the other carried the alternative allele, su-pur+. The mutants were allocated to three genes, gual, gua2, and gua3, between which no close linkage was demonstrable. Mutants of all three genes were recessive and showed normal Mendelian segregation in crosses. The gene gual was shown by an in vivo enzyme assay procedure to specify guanosine 5'-phosphate (GMP) synthetase, the second enzyme involved in the biosynthesis of GMP from inosine 5'-phosphate (IMP). Mutants of this gene excrete large amounts of purine derivatives, predominantly xanthosine, into guanine-free, but not into guanine-supplemented, medium. The gene gau2 is probably involved in the biosynthesis of riboflavin from guanine nucleotides; the phenotype of these mutants suggests a possible interaction between aromatic amino acid metabolism and riboflavin biosynthesis. No role for gua3 can be assigned on the evidence so far available, but it is not involved in the specification of IMP dehydrogenase, the first enzyme involved in the synthesis of GMP and IMP.     

Evidence for the involvement of cytosolic 5'-nucleotidase (cN-II) in the synthesis of guanine nucleotides from xanthosine

In this paper, we show that in vitro xanthosine does not enter any of the pathways known to salvage the other three main natural purine nucleosides: guanosine; inosine; and adenosine. In rat brain extracts and in intact LoVo cells, xanthosine is salvaged to XMP via the phosphotransferase activity of cytosolic 5'-nucleotidase. IMP is the preferred phosphate donor (IMP + xanthosine --> XMP + inosine). XMP is not further phosphorylated. However, in the presence of glutamine, it is readily converted to guanyl compounds. Thus, phosphorylation of xanthosine by cytosolic 5'-nucleotidase circumvents the activity of IMP dehydrogenase, a rate-limiting enzyme, catalyzing the NAD(+)-dependent conversion of IMP to XMP at the branch point of de novo nucleotide synthesis, thus leading to the generation of guanine nucleotides. Mycophenolic acid, an inhibitor of IMP dehydrogenase, inhibits the guanyl compound synthesis via the IMP dehydrogenase pathway but has no effect on the cytosolic 5'-nucleotidase pathway of guanine nucleotides synthesis. We propose that the latter pathway might contribute to the reversal of the in vitro antiproliferative effect exerted by IMP dehydrogenase inhibitors routinely seen with repletion of the guanine nucleotide pools.     

Cloning, expression, and sequence analysis of the Bacillus methanolicus C1 methanol dehydrogenase gene.

The gene (mdh) coding for methanol dehydrogenase (MDH) of thermotolerant, methylotroph Bacillus methanolicus C1 has been cloned and sequenced. The deduced amino acid sequence of the mdh gene exhibited similarity to those of five other alcohol dehydrogenase (type III) enzymes, which are distinct from the long-chain zinc-containing (type I) or short-chain zinc-lacking (type II) enzymes. Highly efficient expression of the mdh gene in Escherichia coli was probably driven from its own promoter sequence. After purification of MDH from E. coli, the kinetic and biochemical properties of the enzyme were investigated. The physiological effect of MDH synthesis in E. coli and the role of conserved sequence patterns in type III alcohol dehydrogenases have been analyzed and are discussed.     

Nucleotide sequence of the Escherichia coli rfe gene involved in the synthesis of enterobacterial common antigen. Molecular cloning of the rfe-rff gene cluster.

The genetic determinants of enterobacterial common antigen (ECA) include the rfe and rff genes located between ilv and cya near min 85 on the Escherichia coli chromosome. The rfe-rff gene cluster of E. coli K-12 was cloned in the cosmid pHC79. The cosmid clone complemented mutants defective in the synthesis of ECA due to lesions in the rfe, rffE, rffD, rffA, rffC, rffT, and rffM genes. Restriction endonuclease mapping combined with complementation studies of the original cosmid clone and six subclones revealed the order of genes in this region to be rfe-rffD/rffE-rffA/rffC-rffT-rffM . The rfe gene was localized to a 2.54-kilobase ClaI fragment of DNA, and the complete nucleotide sequence of this fragment was determined. The nucleotide sequencing data revealed two open reading frames, ORF-1 and ORF-2, located on the same strand of DNA. The putative initiation codon of ORF-1 was found to be 570 nucleotides downstream from the termination codon of rho. ORF-1 and ORF-2 specify putative proteins of 257 and 348 amino acids with calculated Mr values of 29,010 and 39,771, respectively. ORF-1 was identified as the rfe gene since ORF-1 alone was able to complement defects in the synthesis of ECA and 08-side chain synthesis in rfe mutants of E. coli. Data are also presented which suggest the possibility that the rfe gene is the structural gene for the tunicamycin sensitive UDP-GlcNAc:undecaprenylphosphate GlcNAc-1-phosphate transferase that catalyzes the synthesis of GlcNAc-pyrophosphorylundecaprenol (lipid I), the first lipid-linked intermediate involved in ECA synthesis.     

利用大肠杆菌细胞工厂生产吲哚-3-乙酸的研究

目的:利用重组大肠杆菌全细胞转化色氨酸生产IAA.方法:在大肠杆菌胞内构建两条全新的IAA合成途径,即吲哚-3-乙酰胺(indole-3-acetamide,IAM)途径和色胺(tryptamine,TRP)途径.结果:IAM途径涉及两个酶,分别是色氨酸-2-单加氧酶(IAAM)和酰胺酶(AMI1),构建好的重组大肠杆...     

Identification of Escherichia coli O172 O-antigen gene cluster and development of a serogroup-specific PCR assay

AIM: To characterize the locus for O-antigen biosynthesis from Escherichia coli O172 type strain and to develop a rapid, specific and sensitive PCR-based method for identification and detection of E. coli O172. METHODS AND RESULTS: DNA of O-antigen gene cluster of E. coli O172 was amplified by long-range PCR method using primers based on housekeeping genes galF and gnd Shot gun bank was constructed and high quality sequencing was performed. The putative genes for synthesis of UDP-FucNAc, O-unit flippase, O-antigen polymerase and glycosyltransferases were assigned by the homology search. The evolutionary relationship between O-antigen gene clusters of E. coli O172 and E. coli O26 is shown by sequence comparison. Genes specific to E. coli O172 strains were identified by PCR assays using primers based on genes for O-unit flippase, O-antigen polymerase and glycosyltransferases. The specificity of PCR assays was tested using all E. coli and Shigella O-antigen type strains, as well as 24 clinical E. coli isolates. The sensitivity of PCR assays was determined, and the detection limits were 1 pg microl(-1) chromosomal DNA, 0.2 CFU g(-1) pork and 0.2 CFU ml(-1) water. The total time required from beginning to end of the procedure was within 16 h. CONCLUSION: The O-antigen gene cluster of E. coli O172 was identified and PCR assays based on O-antigen specific genes showed high specificity and sensitivity. SIGNIFICANCE AND IMPACT OF THE STUDY: An O-antigen gene cluster was identified by sequencing. The specific genes were determined for E. coli O172. The sensitivity of O-antigen specific PCR assay was tested. Although Shiga toxin-producing O172 strains were not yet isolated from clinical specimens, they may emerge as pathogens.     

Sequence and inactivation of the pss gene of Escherichia coli. Phosphatidylethanolamine may not be essential for cell viability

Phosphatidylethanolamine is the only zwitterionic phospholipid in Escherichia coli and accounts for 70-80% of the total glycerophospholipids of this organism. To investigate the function of phosphatidylethanolamine in E. coli, we constructed an inactivated allele (pss93::kan) of the gene encoding the phosphatidylserine synthase which catalyzes the committed step to the synthesis of phosphatidylethanolamine. Growth of this mutant was dependent on a plasmid-borne copy of the wild type gene. After curing the mutant of the wild type gene, growth stopped when the content of phosphatidylethanolamine reached 30% of the total phospholipid. Divalent metal ions at millimolar concentrations suppressed the growth phenotype of the mutant in the following order of efficiency: Ca2+ greater than Mg2+ greater than Sr2+. Although phosphatidylserine synthase activity was not detectable, phosphatidylethanolamine was still present at 0.007% of the total phospholipid after growth for many generations in rich medium containing 20 mM Mg2+. The remainder of the phospholipid was primarily phosphatidylglycerol and cardiolipin with no other unique phosphate-containing chloroform-soluble material present. The phospholipid to protein ratio and the fatty acid composition were very similar to the parental strain. The broad divalent metal ion auxotrophy brought about by the lack of phosphatidylethanolamine suggests a primarily structural role for this phospholipid in E. coli.     

Regulation of capsular polysaccharide synthesis in Escherichia coli K-12: characterization of three regulatory genes.

The synthesis of the Escherichia coli capsular polysaccharide varies with growth medium, temperature of growth, and genetic background. lac fusions to genes necessary for capsule synthesis (cps) demonstrated that these genes are regulated negatively in vivo by the lon gene product. We have now isolated, characterized, and mapped mutations in three new regulatory genes (rcs, for regulator of capsule synthesis) that control expression of these same fusions. rcsA and rcsB are positive regulators of capsule synthesis. rcsA is located at min 43 on the E. coli map, whereas rcsB lies at 47 min. rcsC, a negative regulator of capsule synthesis, is located at min 47, close to rcsB. All three regulatory mutations are unlinked to either the structural genes cpsA-F or lon. Mutations in all three rcs genes are recessive to the wild type. We postulate that lon may regulate capsule synthesis indirectly, by regulating the availability of one of the positive regulators.