Virulence of a phosphoribosylaminoimidazole carboxylase-deficient Candida albicans strain in an immunosuppressed murine model of systemic candidiasis.

The relative pathogenicities of three Candida albicans strains differing in the function of ADE2 (the gene encoding phosphoribosylaminoimidazole carboxylase) were evaluated in a murine candidiasis model. C. albicans strain CAI7 (ade2/ade2), previously constructed by site-specific recombination, was avirulent in immunosuppressed mice compared to the parent strain, CAF2-1, and a heterozygous ADE2/ade2 strain obtained by transforming CAI7 with a wild-type allele. The reduced virulence of CAI7 was correlated with the inability to proliferate in either synthetic medium or serum without the exogenous addition of >10 microg of adenine/ml. The loss of virulence upon site-specific disruption of the ade2 locus, and the restoration of wild-type virulence with the repair of just one ade2 allele, confirmed that the ADE2 gene and de novo purine biosynthesis were required for Candida pathogenicity. The potential of the phosphoribosylaminoimidazole carboxylase enzyme as a novel target for antifungal drug discovery is discussed.

Sequence analysis of the Candida albicans ADE2 gene and physical separation of the two functionally distinct domains of the phosphoribosylaminoimidazole carboxylase.

An ADE2 genomic clone from the pathogenic fungus, Candida albicans, was isolated by complementation of an Escherichia coli purK mutant and the gene was analysed by DNA sequencing. A 1707 bp open reading frame was identified encoding a polypeptide of 569 amino acids with significant homology to all the known yeast ADE2 genes. Sequence homology to both the E. coli purE and purK genes suggests that the C. albicans ADE2 gene is the result of an evolutionary fusion. The amino-acid sequence comparison showed that the N-terminal domain of the Ade2 protein has a 52.5% identity to purK, whereas the C-terminal domain has a distinct 64.3% identity to purE. In order to establish the functional relationship of these two regions, deletion mutants of the Ade2 protein were prepared by recombinant expression of the functional domains, which were tested by complementation of their respective E. coli auxotrophs.

Identification, characterization, and cloning of a phosphonate monoester hydrolase from Burkholderia caryophilli PG2982.

The glyphosate-degrading bacterium, Burkholderia caryophilli PG2982, was observed to utilize glyceryl glyphosate as a sole phosphorus source. The hydrolysis of glyceryl glyphosate to glyphosate by a phosphonate ester hydrolase (PEH) was identified as the first metabolic step in the mineralization pathway. This observation provides the first biological role for a phosphonate ester hydrolase activity. Purified PEH enzyme hydrolyzed several phosphonate esters including p-nitrophenyl phenylphosphonate, beta-naphthyl phenylphosphonate, and 5-bromo-4-chloro-3-indolyl phenylphosphonate. The purified PEH also hydrolyzed some phosphodiesters including p-nitrophenyl 5'-thymidine monophosphate and p-nitrophenyl phosphorylcholine. The most catalytically efficient substrate identified was bis-(p-nitrophenyl) phosphate with a Km of 0.9 mM and a kcat of 6.2 x 10(2) min-1, suggesting that the enzyme may also function in vivo as a phosphodiesterase. The native enzyme was a homotetramer of 58-kDa subunits and exhibited a pI of 4.2. The enzyme activity had a pH activity optimum of 9.0 and was stimulated 14-fold by Mn2+ ions, but a metal cofactor was not essential for activity. N-terminal and tryptic fragment amino acid sequences were obtained from the purified PEH protein and used to clone the B. caryophilli PG2982 gene, designated pehA. The unique substrate specificity of the enzyme and potential use as a novel conditional lethal gene in plants are discussed.

A phosphonate monoester hydrolase from Burkholderia caryophilli PG2982 is useful as a conditional lethal gene in plants.

A bacterial phosphonate monoester hydrolase was evaluated in plants as a conditional lethal gene useful for cell ablation and negative selection. Glyphosate is a potent herbicide whereas its phosphonate monoester derivative, glyceryl glyphosate, is approximately 50-fold less active. A phosphonate monoesterase gene (pehA) encoding an enzyme that hydrolyzes phosphonate esters including glyceryl glyphosate to glyphosate and glycerol was cloned from the glyphosate metabolizing bacterium, Burkholderia caryophilli PG2982. Constitutive expression of the pehA gene in Escherichia coli and Arabidopsis thaliana RLD had no observable phenotypic effects on growth and development. However, cells and plants expressing the pehA gene were killed when treated with glyceryl glyphosate. The phytotoxicity resulted from the hydrolysis of glyceryl glyphosate to glyphosate and subsequent inhibition of aromatic amino acid biosynthesis. As an example of tissue-specific cell ablation, floral sterility without vegetative toxicity was demonstrated by expressing the pehA gene using a tapetal-specific promoter and treating the mature plants with glyceryl glyphosate. A chromogenic phosphonate ester substrate, 5-bromo-4-chloro-indolyl phenylphosphonate, was used to monitor in situ expression of the pehA gene. The general utility of the pehA gene as a heterologous conditional lethal gene in plants is discussed.

Mannosylphosphoryldolichol-mediated O-mannosylation of yeast glycoproteins: stereospecificity and recognition of the alpha-isoprene unit by a purified mannosyltransferase.

Mannosylphosphoryldolichol (Man-P-Dol):protein O-mannosyltransferase (PMT1) was solubilized by extracting a crude microsomal fraction from Saccharomyces cerevisiae with 1.2% Chaps-0.5% desoxycholate and purified 120-fold by standard chromatographic procedures. These very stable, partially purified preparations of PMT1 catalyzed the transfer of mannosyl units from exogenous Man-P-Dol to serine/threonine residues in the synthetic peptide acceptor, Tyr-Asn-Pro-Thr-Ser-Val-NH2, forming O-mannosidic linkages of the alpha-configuration. The specificity of yeast PMT1 was defined with respect to the recognition of the saturated alpha-isoprene unit, the chain length of the dolichyl moiety, and the anomeric configuration of the mannosyl-phosphoryl linkage of the lipophilic mannosyl donor. When Man-P-Dol95 and mannosylphosphorylpolyprenol (Man-P-Poly95), which contains a fully unsaturated polyprenyl chain, were compared as substrates, the initial rate for peptide mannosylation was dramatically higher with Man-P-Dol95 relative to Man-P-Poly95. The chain length of the dolichyl moiety also influenced the mannolipid-enzyme interaction as the partially purified PMT1 had a higher affinity for Man-P-Dol95 than for Man-P-Dol55. When beta-Man-P-Dol95 was compared with chemically synthesized alpha-Man-P-Dol95 as a mannosyl donor, a strict stereo-specificity was observed for the presence of a beta-mannosyl-phosphoryl linkage. In summary, a procedure for isolating a stable, partially purified preparation of PMT1 from S. cerevisiae is described. Enzymological studies with these preparations of PMT1 provide the first evidence that the recognition of the lipophilic mannosyl donor is stereospecific. These results also demonstrate that maximal O-mannosylation of serine/threonine residues in yeast glycoproteins catalyzed by the partially purified preparation of PMT1 requires the presence of a saturated alpha-isoprene unit in the dolichyl moiety of Man-P-Dol.

Kinetic studies of lysine-sensitive aspartate kinase purified from maize suspension cultures.

Steady state substrate kinetics and feedback regulation properties were determined for lysine-sensitive aspartate kinase (AK) purified from Black Mexican Sweet maize (Zea mays L.) cell suspension cultures. Two AK isoforms (AK Early and AK Late) were separated by two passages through an anion exchange column as the final steps in a procedure giving 1200-fold purification. Kinetic properties were determined for the major AK Late eluting isoform. Assays were conducted at the pH activity maximum (8.0) and with excess Mg(2+) to favor a two-substrate reaction involving aspartate and complexed MgATP. AK catalyzed a sequential reaction in which MgATP and aspartate both bind to the enzyme complex before the ADP and aspartyl-phosphate products are released. The K(m) value calculated for MgATP was 0.43 millimolar and for aspartate was 1.04 millimolar. Cooperativity in substrate binding was not observed and was not induced by lysine. The lysine concentration required for 50% inhibition of AK activity was 7 micromolar. An apparent Hill coefficient of 1.4 indicated a minimum of two lysine-binding sites on the active AK complex. At nonsaturating substrate concentrations, lysine inhibition was characteristic of an S-parabolic, I-parabolic noncompetitive allosteric inhibitor. The parabolic inhibitor replot, Hill coefficients > 1, and the lack of substrate cooperativity were consistent with a model for multiple lysine-binding sites per active AK subunit. Similar kinetic properties were observed for the AK Early isoform.

Lysine-insensitive aspartate kinase in two threonine-overproducing mutants of maize.

Aspartate kinase (AK; EC 2.7.2.A) catalyzes the first reaction in the biosynthesis pathway for aspartate-derived amino acids in plants. Aspartate kinase was purified from wildtype and two maize (Zea mays L.) genotypes carrying unlinked dominant mutations,Ask LT19 andAsk2 -LT20, that conferred overproduction of threonine, lysine, methionine and isoleucine. The objective of this investigation was to characterize the AKs from mutant and wildtype plants to determine their role in regulating the synthesis of aspartate-derived amino acids in maize. Kernels of the homozygousAsk2 mutant exhibited 174-, 10-, 13- and 2-fold increases in, in this sequence, free threonine, lysine, methionine and isoleucine, compared to wildtype. In wildtype maize, AK was allosterically feedback-inhibited by lysine with 10 µML-lysine required for 50% inhibition. In contrast, AK purified from the isogenic heterozygousAsk and homozygousAsk2 mutants required 25 and 760 µM lysine for 50% inhibition, respectively, indicating thatAsk andAsk2 were separate structural loci for lysine-regulated AK subunits in maize. Further characterization of purified AK from the homozygous mutantAsk2 line indicated altered substrate and lysine inhibition kinetics. The apparent Hill coefficient was 0.7 for the mutantAsk2 AK compared with 1.6 for the wildtype enzyme, indicating that the mutant allele conferred the loss of a lysinebinding site to the mutant AK. Lysine appeared to be a linear noncompetitive inhibitor ofAsk2 AK with respect to MgATP and an uncompetitive inhibitor with respect to aspartate compared to S-parabolic, I parabolic noncompetitive inhibition of wildtype AK. Reduced lysine sensitivity of theAsk2 gene product appeared to reduce the lysine inhibition of all of the AK activity detected in homozygousAsk2 plants, indicating that maize AK is a heteromeric enzyme consisting of the two lysine-sensitive polypeptides derived from theAsk andAsk2 structural genes.

Purification and characterization of lysine-sensitive aspartate kinase from maize cell cultures.

Aspartate kinase is a feedback-regulated enzyme that controls the first step common to the biosynthesis of lysine, threonine, isoleucine, and methionine in plants. Aspartate kinase was purified from Black Mexican Sweet maize (Zea mays L.) cell suspension cultures for physical and kinetic characterization studies. Partial purification and elution from an anion exchange column resolved two lysine-sensitive aspartate kinase isoforms. Both isoforms were purified >1,200-fold to a minimum specific activity of 18 units/milligram of protein. Both isoforms were sensitive to the lysine analogues S-2-aminoethyl-l-cysteine, l-lysine ethyl ester, and delta-hydroxylysine. No threonine-sensitive form of aspartate kinase was detected at any stage during the purification. Additional purification steps were combined with preparative gel electrophoresis to obtain apparently homogeneous lysine-sensitive aspartate kinase. Aspartate kinase appeared to be a tetramer with a holoenzyme molecular weight of 254,000 and to be composed of 49,000 and 60,000 subunits. The tetramer appeared to disassociate during native gel electrophoresis to 113,000 dalton species that retained aspartate kinase activity.

Differential metabolism of sodium azide in maize callus and germinating embryos.

Sodium azide is a potent mutagen of maize (Zea mays L.) kernels that may have potential as a point mutagen for inducing biochemical mutations in maize tissue cultures. Azide mutagenicity was evaluated in friable, embryogenic maize callus and a nonregenerable maize suspension culture by determining the number of resistant variant cell lines able to grow on media containing inhibitory concentrations of lysine plus threonine (LT). The number of LT-resistant variants selected from either culture type did not increase in response to azide treatment. In addition, there was no increase in somatic mutations in more than 100 plants regenerated from azide treated LT-resistant lines. The levels of mutagenic metabolite of azide (presumably azidoalanine), were determined by bioassay in the two azide-treated maize callus types and compared to levels of mutagenic metabolite in embryos isolated from azide-treated kernels. The two types of maize tissue cultures and isolated embryos contained similar levels of mutagenic metabolite 4 h after azide treatment indicating similar uptake and conversion of azide to mutagenic metabolite in the three tissues. Mutagenic metabolite in azide-treated embryos did not significantly decrease after 40 h. However, mutagenic metabolite levels in both azide-treated tissue cultures decreased to near background levels within 20 h providing evidence for rapid metabolism of the azide mutagenic metabolite. The lack of evidence for azide mutagenicity in maize callus and its known potent mutagenicity in kernels appears to be associated with specific differences in azide metabolism between callus tissues and kernel embryos.