Coordinate regulation of siderophore and exotoxin A production: molecular cloning and sequencing of the Pseudomonas aeruginosa fur gene.

A 5.9-kb DNA fragment was cloned from Pseudomonas aeruginosa PA103 by its ability to functionally complement a fur mutation in Escherichia coli. A fur null mutant E. coli strain that contains multiple copies of the 5.9-kb DNA fragment produces a 15-kDa protein which cross-reacts with a polyclonal anti-E. coli Fur serum. Sequencing of a subclone of the 5.9-kb DNA fragment identified an open reading frame predicted to encode a protein 53% identical to E. coli Fur and 49% identical to Vibrio cholerae Fur and Yersinia pestis Fur. While there is extensive homology among these Fur proteins, Fur from P. aeruginosa differs markedly at its carboxy terminus from all of the other Fur proteins. It has been proposed that this region is a metal-binding domain in E. coli Fur. A positive selection procedure involving the isolation of manganese-resistant mutants was used to isolate mutants of strain PA103 that produce altered Fur proteins. These manganese-resistant Fur mutants constitutively produce siderophores and exotoxin A when grown in concentrations of iron that normally repress their production. A multicopy plasmid carrying the P. aeruginosa fur gene restores manganese susceptibility and wild-type regulation of exotoxin A and siderophore production in these Fur mutants.     

Analysis of ferrichrome biosynthesis in the phytopathogenic fungus Ustilago maydis: cloning of an ornithine-N5-oxygenase gene

By using a non-enterobactin-producing enb-7 mutant of Salmonella typhimurium LT2 as a biological indicator, a novel screening method was developed for identifying mutants of Ustilago maydis defective in the biosynthesis of the siderophores ferrichrome and ferrichrome A. Two classes of siderophore mutations, both recessive, were isolated after mutagenesis of haploid cells of the corn smut fungus. Class I mutants no longer produced ferrichrome while retaining the ability to produce ferrichrome A; class II mutants were defective in the production of both ferrichrome and ferrichrome A. Genetic and biochemical data suggest that class II mutants are defective in the ability to hydroxylate L-ornithine to delta-N-hydroxyornithine, the first step in the biosynthesis of these siderophores. A genomic library of wild-type U. maydis DNA was constructed in the cosmid transformation vector pCU3, which contains a dominant selectable marker for hygromycin B resistance. Two cosmids, pSid1 and pSid2, were identified in this library by their ability to complement class II siderophore auxotrophs. The production of both siderophores was concomitantly restored in the majority of the resultant transformants. Transforming DNA could be recovered from the fungal, cosmid-containing transformants by in vitro packaging with lambda bacteriophage extracts. Alternatively, the clones could be identified by a sib selection procedure. Cotransformation was found to occur at a high frequency in the fungus and was used to determine that a 2.5-kilobase HindIII-NruI fragment in pSid1 was responsible for complementing the class II siderophore biosynthetic mutation.     

Elucidation of the complete ferrichrome A biosynthetic pathway in Ustilago maydis

Iron is an important element for many essential processes in living organisms. To acquire iron, the basidiomycete Ustilago maydis synthesizes the iron‐chelating siderophores ferrichrome and ferrichrome A. The chemical structures of these siderophores have been elucidated long time ago but so far only two enzymes involved in their biosynthesis have been described. Sid1, an ornithine monoxygenase, is needed for the biosynthesis of both siderophores, and Sid2, a non‐ribosomal peptide synthetase (NRPS), is involved in ferrichrome generation. In this work we identified four novel enzymes, Fer3, Fer4, Fer5 and Hcs1, involved in ferrichrome A biosynthesis in U. maydis. By HPLC‐MS analysis of siderophore accumulation in culture supernatants of deletion strains, we show that Fer3, an NRPS, Fer4, an enoyl‐coenzyme A (CoA)‐hydratase, and Fer5, an acylase, are required for ferrichrome A production. We demonstrate by conditional expression of the hydroxymethyl glutaryl (HMG)‐CoA synthase Hcs1 in U. maydis that HMG‐CoA is an essential precursor for ferrichrome A. In addition, we heterologously expressed and purified Hcs1, Fer4 and Fer5, and demonstrated the enzymatic activities by in vitro experiments. Thus, we describe the first complete fungal siderophore biosynthetic pathway by functionally characterizing four novel genes responsible for ferrichrome A biosynthesis in U. maydis.     

A biosynthetic gene cluster for a secreted cellobiose lipid with antifungal activity from Ustilago maydis

The phytopathogenic basidiomycetous fungus Ustilago maydis secretes large amounts of the glycolipid biosurfactant ustilagic acid (UA). UA consists of 15,16-dihydroxypalmitic or 2,15,16-trihydroxypalmitic acid, which is O-glycosidically linked to cellobiose at its terminal hydroxyl group. In addition, the cellobiose moiety is acetylated and acylated with a short-chain hydroxy fatty acid. We have identified a 58 kb spanning gene cluster that contains 12 open reading frames coding for most, if not all, enzymes needed for UA biosynthesis. Using a combination of genetic and mass spectrometric analysis we were able to assign functional roles to three of the proteins encoded by the gene cluster. This allowed us to propose a biosynthesis route for UA. The Ahd1 protein belongs to the family of non-haem diiron reductases and is required for alpha-hydroxylation of palmitic acid. Two P450 monooxygenases, Cyp1 and Cyp2, catalyse terminal and subterminal hydroxylation of palmitic acid. We could demonstrate that infection of tomato leaves by the plant pathogenic fungus Botrytis cinerea is prevented by co-inoculation with wild-type U. maydis sporidia. U. maydis mutants defective in UA biosynthesis were unable to inhibit B. cinerea infection indicating that UA secretion is critical for antagonistic activity.     

Evidence for a common siderophore transport system but different siderophore receptors in Neurospora crassa.

Uptake and competition experiments were performed with Neurospora crassa and Penicillium parvum by using 14C-labeled coprogen and 55Fe-labeled ferrichrome-type siderophores. Several siderophores of the ferrichrome family, such as ferrichrome, ferricrocin, ferrichrysin, and tetraglycyl-ferrichrome as well as the semisynthetic ferricrocin derivatives O-(phenyl-carbamoyl)-ferricrocin and O-(sulfanilyl-carbamoyl)-ferricrocin were taken up by N. crassa. The ferrichrome-type siderophores used vary in the structure of the peptide backbone but possess a common lambda-cis configuration about the iron center and three identical ornithyl-delta-N-acetyl groups as surrounding residues. This suggests that these ferrichrome-type siderophores are recognized by a common ferrichrome receptor. We also concluded that the ferrichrome receptor is lambda-cis specific from the inability to take up the synthetic enantiomers, enantio-ferrichrome and enantio-ferricrocin, possessing a delta-cis configuration about the iron center. On the other hand, we found that coprogen, possessing a delta-absolute configuration and two trans-anhydromevalonic acid residues around the metal center, was also taken up by N. crassa and was competitively inhibited by the ferrichrome-type siderophores. We therefore propose the existence of a common siderophore transport system but the presence of different siderophore receptors in N. crassa. In addition, ferrirubin, which is very slowly transported by N. crassa, inhibited both coprogen and ferrichrome-type siderophore transport. Contrary to the findings with N. crassa, transport experiments with P. parvum revealed the presence of a ferrichrome receptor but the absence of a coprogen receptor; coprogen was neither transported nor did it inhibit the ferrichrome transport.     

Molecular genetics of fungal siderophore biosynthesis and uptake: the role of siderophores in iron uptake and storage

To acquire iron, all species have to overcome the problems of iron insolubility and toxicity. In response to low iron availability in the environment, most fungi excrete ferric iron-specific chelators--siderophores--to mobilize this metal. Siderophore-bound iron is subsequently utilized via the reductive iron assimilatory system or uptake of the siderophore-iron complex. Furthermore, most fungi possess intracellular siderophores as iron storage compounds. Molecular analysis of siderophore biosynthesis was initiated by pioneering studies on the basidiomycete Ustilago maydis, and has progressed recently by characterization of the relevant structural and regulatory genes in the ascomycetes Aspergillus nidulans and Neurospora crassa. In addition, significant advances in the understanding of utilization of siderophore-bound iron have been made recently in the yeasts Saccharomyces cerevisiae and Candida albicans as well as in the filamentous fungus A. nidulans. The present review summarizes molecular details of fungal siderophore biosynthesis and uptake, and the regulatory mechanisms involved in control of the corresponding genes.     

The OPI1 gene of Saccharomyces cerevisiae, a negative regulator of phospholipid biosynthesis, encodes a protein containing polyglutamine tracts and a leucine zipper

In Saccharomyces cerevisiae, recessive mutations at the OPI1 locus result in constitutively derepressed expression of inositol 1-phosphate synthase, the product of the INO1 gene. Many of the other enzymes involved in phospholipid biosynthesis are also expressed at high derepressed levels in opi1 mutants. Thus, the OPI1 gene is believed to encode a negative regulator that is required to repress a whole subset of structural genes encoding for phospholipid biosynthetic enzymes. In this study, the OPI1 gene was mapped to chromosome VIII and cloned. When transformed into an opi1 mutant, the cloned DNA was capable of complementing the mutant phenotype and restoring correct regulation to the INO1 structural gene. Construction of two opi1 disruption alleles and subsequent genetic analysis of strains bearing these alleles confirmed that the cloned DNA was homologous to the genomic OPI1 locus. Furthermore, the OPI1 gene was found to be nonessential to the organism since mutants bearing the null allele were viable and exhibited a phenotype similar to that of previously isolated opi1 mutants. Similar to other opi1 mutants, the opi1 disruption mutants accumulated INO1 mRNA constitutively to a level 2-3-fold higher than that observed in wild-type cells. The cloned OPI1 gene was sequenced, and translation of the open reading frame predicted a protein composed of 404 amino acid residues with a molecular weight of 40,036. The predicted Opi1 protein contained a well defined heptad repeat of leucine residues that has been observed in other regulatory proteins. In addition, the predicted protein contained polyglutamine residue stretches which have also been reported in yeast genes having regulatory functions. Sequencing of opi1 mutant alleles, isolated after chemical mutagenesis, revealed that several were the result of a chain termination mutation located within the largest polyglutamine residue stretch.     

Role of two siderophores in Ustilago sphaerogena. Regulation of biosynthesis and uptake mechanisms

Under iron-deficient conditions the smut fungus Ustilago sphaerogena produces two kinds of siderophores, ferrichrome and ferrichrome A. Regulation of ligand biosyntheses and uptake mechanisms of the iron chelates were studied to determine the role of each chelate in U. sphaerogena. The biosynthesis of each ligand was differentially regulated. Ferrichrome A, the more effective chelate, was preferentially synthesized under more extreme conditions of iron stress, but completely repressed when the cell was supplied with sufficient iron. In contrast, biosynthesis of ferrichrome was strongly but not completely repressed by iron. The mechanism of repression was examined using a newly developed in vivo synthesis assay. Chromium and gallium-containing siderophore analogs had no effect on siderophore ligand biosynthesis. Iron, added as siderophores, resulted in increased oxygen uptake and amino acid transport, which was soon followed by decreased ligand biosynthesis, suggesting that regulation may be indirect and related to oxidative metabolism. Uptake experiments were used to rule out a ligand-exchange mechanism for ferrichrome A-iron transport. The data suggest that ferrichrome A-iron is taken up at a specific site that results in a rapid distribution of iron inside the cell.     

Functional expression of human dihydroorotate dehydrogenase (DHODH) in pyr4 mutants of ustilago maydis allows target validation of DHODH inhibitors in vivo

Dihydroorotate dehydrogenase (DHODH; EC 1.3.99.11) is a central enzyme of pyrimidine biosynthesis and catalyzes the oxidation of dihydroorotate to orotate. DHODH is an important target for antiparasitic and cytostatic drugs since rapid cell proliferation often depends on the de novo synthesis of pyrimidine nucleotides. We have cloned the pyr4 gene encoding mitochondrial DHODH from the basidiomycetous plant pathogen Ustilago maydis. We were able to show that pyr4 contains a functional mitochondrial targeting signal. The deletion of pyr4 resulted in uracil auxotrophy, enhanced sensitivity to UV irradiation, and a loss of pathogenicity on corn plants. The biochemical characterization of purified U. maydis DHODH overproduced in Escherichia coli revealed that the U. maydis enzyme uses quinone electron acceptor Q6 and is resistant to several commonly used DHODH inhibitors. Here we show that the expression of the human DHODH gene fused to the U. maydis mitochondrial targeting signal is able to complement the auxotrophic phenotype of pyr4 mutants. While U. maydis wild-type cells were resistant to the DHODH inhibitor brequinar, strains expressing the human DHODH gene became sensitive to this cytostatic drug. Such engineered U. maydis strains can be used in sensitive in vivo assays for the development of novel drugs specifically targeted at either human or fungal DHODH.     

The ornithine decarboxylase gene odc is required for alcaligin siderophore biosynthesis in Bordetella spp.: putrescine is a precursor of alcaligin.

Chromosomal insertions defining Bordetella bronchiseptica siderophore phenotypic complementation group III mutants BRM3 and BRM5 were found to reside approximately 200 to 300 bp apart by restriction mapping of cloned genomic regions associated with the insertion markers. DNA hybridization analysis using B. bronchiseptica genomic DNA sequences flanking the cloned BRM3 insertion marker identified homologous Bordetella pertussis UT25 cosmids that complemented the siderophore biosynthesis defect of the group III B. bronchiseptica mutants. Subcloning and complementation analysis localized the complementing activity to a 2.8-kb B. pertussis genomic DNA region. Nucleotide sequencing identified an open reading frame predicted to encode a polypeptide exhibiting strong similarity at the primary amino acid level with several pyridoxal phosphate-dependent amino acid decarboxylases. Alcaligin production was fully restored to group III mutants by supplementation of iron-depleted culture media with putrescine (1,4-diaminobutane), consistent with defects in an ornithine decarboxylase activity required for alcaligin siderophore biosynthesis. Concordantly, the alcaligin biosynthesis defect of BRM3 was functionally complemented by the heterologous Escherichia coli speC gene encoding an ornithine decarboxylase activity. Enzyme assays confirmed that group III B. bronchiseptica siderophore-deficient mutants lack an ornithine decarboxylase activity required for the biosynthesis of alcaligin. Siderophore production by an analogous mutant of B. pertussis constructed by allelic exchange was undetectable. We propose the designation odc for the gene defined by these mutations that abrogate alcaligin siderophore production. Putrescine is an essential precursor of alcaligin in Bordetella spp.