Identification and characterization of a novel biotin biosynthesis gene in Saccharomyces cerevisiae

Yeast Saccharomyces cerevisiae cells generally cannot synthesize biotin, a vitamin required for many carboxylation reactions. Although sake yeasts, which are used for Japanese sake brewing, are classified as S. cerevisiae, they do not require biotin for their growth. In this study, we identified a novel open reading frame (ORF) in the genome of one strain of sake yeast that we speculated to be involved in biotin synthesis. Homologs of this gene are widely distributed in the genomes of sake yeasts. However, they are not found in many laboratory strains and strains used for wine making and beer brewing. This ORF was named BIO6 because it has 52% identity with BIO3, a biotin biosynthesis gene of a laboratory strain. Further research showed that yeasts without the BIO6 gene are auxotrophic for biotin, whereas yeasts holding the BIO6 gene are prototrophic for biotin. The BIO6 gene was disrupted in strain A364A, which is a laboratory strain with one copy of the BIO6 gene. Although strain A364A is prototrophic for biotin, a BIO6 disrupted mutant was found to be auxotrophic for biotin. The BIO6 disruptant was able to grow in biotin-deficient medium supplemented with 7-keto-8-amino-pelargonic acid (KAPA), while the bio3 disruptant was not able to grow in this medium. These results suggest that Bio6p acts in an unknown step of biotin synthesis before KAPA synthesis. Furthermore, we demonstrated that expression of the BIO6 gene, like that of other biotin synthesis genes, was upregulated by depletion of biotin. We conclude that the BIO6 gene is a novel biotin biosynthesis gene of S. cerevisiae.     

Identification of the yeast ARG-11 gene as a mitochondrial ornithine carrier involved in arginine biosynthesis

The ARG-11 gene in Saccharomyces cerevisiae encodes a protein with the characteristic features of a family of 35 related membrane proteins that are encoded in the fungal genome. Some of them are known to transport various substrates and products across the inner membranes of mitochondria, but the functions of 29 members of the family are unknown. The yeast ARG-11 protein has been over-produced as inclusion bodies in Escherichia coli. It has been solubilized in the presence of sarkosyl, re-constituted into liposomes and shown to transport ornithine in exchange for protons. Its main physiological role is probably to take ornithine synthesized from glutamate in the mitochondrial matrix to the cytosol where it is converted to arginine.     

Role of the entC gene in enterobactin and menaquinone biosynthesis in Escherichia coli

Tn10 mutants of Escherichia coli MC4100 were screened for their inability to grow under iron deficiency and for their inability to grow under anaerobiosis in the presence of fumarate as an electron acceptor. A strain so obtained (E. coli PBB1) lacked the ability to convert chorismic acid to isochorismic acid. This shows that the gene (entC) encoding isochorismate synthase was mutated. E. coli PBB1 did not produce any detectable amounts of menaquinones (vitamin K2) or enterobactin. When supplemented with isochorismic acid this strain produced menaquinones, indicating that isochorismic acid is involved not only in enterobactin but also in menaquinone biosynthesis. The entC gene was isolated and was shown to be part of the enterobactin gene cluster: It was located on a DNA fragment (9 kb in length) which also carried the entA gene. The DNA fragment was identified by restriction site mapping and was compared to a previously published map of the enterobactin gene cluster. The entC gene on this fragment responds not only to conditions (iron deficiency) that stimulate enterobactin biosynthesis but also to anaerobiosis which results in increased isochorismic acid formation and increased menaquinone biosynthesis. We conclude that isochorismic acid, isochorismic synthase, and the gene (entC) encoding this enzyme are involved in catalytic events at a metabolic branch point from which both enterobactin and menaquinones originate.     

Identification of novel members in sweet orange carotenoid biosynthesis gene families

Novel expressed and genomic members in sweet orange (Citrus sinensis [L.] Osbeck) carotenoid biosynthesis gene families have been identified through mining of an expressed sequence tags (ESTs) database and hybridization with a bacterial artificial chromosome (BAC) library. These new expressed members included one phytoene synthase (PSY), one phytoene desaturase (PDS), ten zeta-carotene desaturases (ZDS), one lycopene beta-cyclase (LCYB), one lycopene epsilon-cyclase (LCYE), four carotenoid beta-ring hydroxylases (CHYB), and one capsanthin/capsorubin synthase (CCS). Most unigenes with multiple ESTs, including the ones containing the known genes and these new members, were heterozygous, in which putative single nucleotide polymorphisms distinguished two alleles. According to digital gene expression profiling, fruit was the primary tissue where at least one member of each gene family was specifically or highly expressed. Digital expression levels varied among the members and tissues. According to Southern hybridization of the identified BAC clones, genomic members of the families were either clustered in a single BAC contig or distributed in several different contigs. PSY has four members in one contig, PDS two in one, ZDS 12 in three, LCYB 11 in three, LCYE three in two, CHYB eight in one, and CCS 14 in four, respectively. The number of the genomic members in most families tended to be more than that of the expressed members, suggesting that some genomic members may not be expressed or structurally functional. These new carotenoid gene members, along with much first-hand genomic information, can be used further for functional genomics and genetic mapping.     

Identification and characterization of a novel mitochondrial tricarboxylate carrier

Here we report the identification and functional characterization of a novel mitochondrial tricarboxylate carrier protein, designated BBG-TCC, in rat brain. The cDNA encodes the predicted protein of 342-amino acid residues with five putative membrane-spanning domains. The protein has apparent similarity with a mitochondrial tricarboxylate carrier TCC, but is distinct from the other mitochondria anion transporters. BBG-TCC shows a citrate transport activity. It is specifically expressed in the brain and localizes in the mitochondria of Bergmann glial cells. In contrast, the expression of TCC is rather ubiquitous and strong in neuronal cells in the brain. This new family of proteins may contribute to biosynthesis and bioenergetics in the brain.     

Identification of gcpE as a novel gene of the 2-C-methyl-D-erythritol 4-phosphate pathway for isoprenoid biosynthesis in Escherichia coli

The 2-C-methyl-D-erythritol 4-phosphate (MEP) pathway for isoprenoid biosynthesis is essential in most eubacteria and plants and has remarkable biotechnological interest. However, only the first steps of this pathway have been determined. Using bioinformatic and genetic approaches, we have identified gcpE as a novel gene of the MEP pathway. The distribution of this gene in bacteria and plants strictly parallels that of the gene encoding 1-deoxy-D-xylulose 5-phosphate reductoisomerase, which catalyses the first committed step of the MEP pathway. Our data demonstrate that the gcpE gene is essential for the MEP pathway in Escherichia coli and indicate that this gene is required for the trunk line of the isoprenoid biosynthetic route.     

Identification of a novel vinyl reductase gene essential for the biosynthesis of monovinyl chlorophyll in Synechocystis sp. PCC6803

The vast majority of oxygenic photosynthetic organisms use monovinyl chlorophyll for their photosynthetic reactions. For the biosynthesis of this type of chlorophyll, the reduction of the 8-vinyl group that is located on the B-ring of the macrocycle is essential. Previously, we identified the gene encoding 8-vinyl reductase responsible for this reaction in higher plants and termed it DVR. Among the sequenced genomes of cyanobacteria, only several Synechococcus species contain DVR homologues. Therefore, it has been hypothesized that many other cyanobacteria producing monovinyl chlorophyll should contain a vinyl reductase that is unrelated to the higher plant DVR. To identify the cyanobacterial gene that is responsible for monovinyl chlorophyll synthesis, we developed a bioinformatics tool, correlation coefficient calculation tool, which calculates the correlation coefficient between the distributions of a certain phenotype and genes among a group of organisms. The program indicated that the distribution of a gene encoding a putative dehydrogenase protein is best correlated with the distribution of the DVR-less cyanobacteria. We subsequently knocked out the corresponding gene (Slr1923) in Synechocystis sp. PCC6803 and characterized the mutant. The knock-out mutant lost its ability to synthesize monovinyl chlorophyll and accumulated 3,8-divinyl chlorophyll instead. We concluded that Slr1923 encodes the vinyl reductase or a subunit essential for monovinyl chlorophyll synthesis. The function and evolution of 8-vinyl reductase genes are discussed.     

Identification of a gene cluster responsible for the biosynthesis of cyclic lipopeptide verlamelin

Only limited studies are available on the molecular-level biosynthesis of cyclic lipopeptides (cyclic and hybrid molecules consisting of peptide and fatty acid moieties) in filamentous fungi. Here, we identified and characterized biosynthetic genes of the cyclic lipopeptides, known as verlamelins. Only four genes, coding for non-ribosomal peptide synthetase (NRPS), fatty acid hydroxylase, thioesterase, and AMP-dependent ligase, were found to be involved in verlamelin biosynthesis by the analysis of corresponding gene knockouts. Surprisingly, no gene(s) coding for fatty acid synthase or polyketide synthase was present in the cluster, while verlamelin A/B contained a 5-hydroxytetradecanoic acid moiety. Precursor feeding experiment indicated that both fatty acid hydroxylase and thioesterase are involved to supply 5-hydroxytetradecanoic acid. The results suggested that 5-hydroxytetradecanoic acid was supplied from primary metabolism via fatty acid hydroxylase and loaded onto NRPS. Elongation of the peptide and final cyclization were accomplished by NRPS. The knowledge obtained through this study should provide new insight into fungal lipopeptide biosynthesis.     

Site-directed mutagenesis of UbiA to promote menaquinone biosynthesis in Elizabethkingia meningoseptica

To increase the menaquinone (MK) content of an Elizabethkingia meningoseptica, site-directed mutagenesis was generated to suppress 4-hydroxybenzoate octaprenyl transferase (UbiA) activity and subsequently blocked the ubiquinone (UQ) biosynthesis pathway. Fourteen conserved residues except L174 and G211 were mutated to analyze the effect of site-directed mutagenesis. The expression of UbiA in twelve mutants was decreased in both mRNA and protein levels, which resulted in the decrease of UQ concentration. Based on MenA expression level, 12 mutants were divided into two groups. Second group such as N72A, D76A, K81A, L139A, and D198A enhanced the expression of MenA, which increased MK production by 127.1%, 87.9%, 96.2%, 109.7% and 130.0% in wt-EmUbiA, respectively. In general, blocking UQ synthesis pathway for by site-directed mutagenesis of the active site of UbiA in E. meningoseptica was a promising strategy to increase MK production in E. meningoseptica.     

Identification of a novel candidate gene for rolled leaf in rice

A semi-narrow and adaxially rolled leaf mutant, rl15(t), was induced from Korean japonica rice cultivar Ilpum by chemical mutagenesis using ethyl methanesulfonate. We characterized the mutant and identified the novel gene causing the mutant phenotype. Cytological analysis of mutant leaves indicated that the adaxial leaf-rolling phenotype is due to the reduced size and number of bulliform cells in the mutant. Genetic analysis showed that the rolled leaf trait is controlled by a single recessive gene, designated rl15(t). Using an F₂ mapping population generated from a cross between Milyang23 and the mutant, we mapped the candidate region to a 174 kb interval on the long arm of chromosome 1 near the centromeric region. Through whole genome sequencing in bulk and MutMap analysis, we identified the causal SNP within the candidate region. The results of RT-PCR analysis indicated that a splicing error occurred due to a base change from G to A at the beginning of the fifth intron of LOC_Os01g37837, which encodes a putative seryl-tRNA synthetase, resulting in the mutant phenotype. Further study of the rl15(t) gene will facilitate analysis of leaf architecture and morphogenesis in rice plants.     

Identification of a novel glycosyltransferase involved in LOS biosynthesis of Moraxella catarrhalis

Moraxella catarrhalis is an important human mucosal pathogen that contributes to otitis media in infants and exacerbates conditions such as chronic obstructive pulmonary disease in the elderly. This study describes the identification of a novel gene, lgt5 that encodes a glycosyltransferase involved in the LOS biosynthesis of M. catarrhalis. Analysis of NMR data of LOS-derived oligosaccharide from a Serotype A lgt5 mutant strain of M. catarrhalis indicate that lgt5 encodes an alpha-(1-->4)-galactosyltransferase.     

Identification of a novel protein with a role in lipoarabinomannan biosynthesis in mycobacteria

All species of Mycobacteria synthesize distinctive cell walls that are rich in phosphatidylinositol mannosides (PIMs), lipomannan (LM), and lipoarabinomannan (LAM). PIM glycolipids, having 2-4 mannose residues, can either be channeled into polar PIM species (with 6 Man residues) or hypermannosylated to form LM and LAM. In this study, we have identified a Mycobacterium smegmatis gene, termed lpqW, that is required for the conversion of PIMs to LAM and is highly conserved in all mycobacteria. A transposon mutant, Myco481, containing an insertion near the 3' end of lpqW exhibited altered colony morphology on complex agar medium. This mutant was unstable and was consistently overgrown by a second mutant, represented by Myco481.1, that had normal growth and colony characteristics. Biochemical analysis and metabolic labeling studies showed that Myco481 synthesized the complete spectrum of apolar and polar PIMs but was unable to make LAM. LAM biosynthesis was restored to near wild type levels in Myco481.1. However, this mutant was unable to synthesize the major polar PIM (AcPIM6) and accumulated a smaller intermediate, AcPIM4. Targeted disruption of the lpqW gene and complementation of the initial Myco481 mutant with the wild type gene confirmed that the phenotype of this mutant was due to loss of LpqW. These studies suggest that LpqW has a role in regulating the flux of early PIM intermediates into polar PIM or LAM biosynthesis. They also suggest that AcPIM4 is the likely branch point intermediate in polar PIM and LAM biosynthesis.     

Identification of a new gene required for the biosynthesis of rhodoquinone in Rhodospirillum rubrum

Rhodoquinone (RQ) is a required cofactor for anaerobic respiration in Rhodospirillum rubrum, and it is also found in several helminth parasites that utilize a fumarate reductase pathway. RQ is an aminoquinone that is structurally similar to ubiquinone (Q), a polyprenylated benzoquinone used in the aerobic respiratory chain. RQ is not found in humans or other mammals, and therefore, the inhibition of its biosynthesis may provide a novel antiparasitic drug target. To identify a gene specifically required for RQ biosynthesis, we determined the complete genome sequence of a mutant strain of R. rubrum (F11), which cannot grow anaerobically and does not synthesize RQ, and compared it with that of a spontaneous revertant (RF111). RF111 can grow anaerobically and has recovered the ability to synthesize RQ. The two strains differ by a single base pair, which causes a nonsense mutation in the putative methyltransferase gene rquA. To test whether this mutation is important for the F11 phenotype, the wild-type rquA gene was cloned into the pRK404E1 vector and conjugated into F11. Complementation of the anaerobic growth defect in F11 was observed, and liquid chromatography-time of flight mass spectrometry (LC-TOF-MS) analysis of lipid extracts confirmed that plasmid-complemented F11 was able to synthesize RQ. To further validate the requirement of rquA for RQ biosynthesis, we generated a deletion mutant from wild-type R. rubrum by the targeted replacement of rquA with a gentamicin resistance cassette. The ΔrquA mutant exhibited the same phenotype as that of F11. These results are significant because rquA is the first gene to be discovered that is required for RQ biosynthesis.     

Identification of a new gene in an operon for cellulose biosynthesis in Acetobacter xylinum

DNA sequencing of the region downstream of the cellulose synthase catalytic subunit gene of Acetobacter xylinum led to the identification of an open reading frame coding for a polypeptide of 86 kDa. The deduced amino acid sequence of this polypeptide matches from position 27 to 40 with the N-terminal amino acid sequence determined for a 93 kDa polypeptide that copurifies with the cellulose synthase catalytic subunit during purification of cellulose synthase. The cellulose synthase catalytic subunit gene and the gene encoding the 93 kDa polypeptide, along with other genes probably, are organized as an operon for cellulose biosynthesis in which the first gene is the catalytic subunit gene and the second gene codes for the 93 kDa polypeptide. The function of the 93 kDa polypeptide is not clear at present, however it appears to be tightly associated with the cellulose synthase catalytic subunit. Sequence analysis of the polypeptide shows that it is a membrane protein with a signal sequence at the N-terminal end and a transmembrane helix in the C-terminal region for anchoring it into the membrane.     

Identification of a novel polyketide synthase-nonribosomal peptide synthetase (PKS-NRPS) gene required for the biosynthesis of cyclopiazonic acid in Aspergillus oryzae

Cyclopiazonic acid (CPA) is a mycotoxin produced by several strains of Penicillium and Aspergillus species. Aspergillus oryzae strains used in fermented foods do not produce CPA; however, several wild-type A. oryzae strains produce CPA. Here, we identified a novel polyketide synthase-nonribosomal peptide synthetase (PKS-NRPS) gene involved in CPA production by comparing the telomere-adjacent region of a CPA-producing strain (A. oryzae NBRC 4177) with that of a nonproducing strain (A. oryzae RIB40). NBRC 4177 has an additional 17-18-kb sequence beyond the region corresponding to the telomere repeat in RIB40 and this additional regions contains 3' region of the PKS-NRPS gene, while RIB40 has only the 5' region of the PKS-NRPS gene. Gene disruption of the PKS-NRPS gene in NBRC 4177 resulted in elimination of CPA production. Thus, the PKS-NRPS gene is required for CPA biosynthesis, and the truncation of this gene is presumed as one of the determinants of CPA nonproductivity in A. oryzae RIB40.     

Identification of a novel GPCAT activity and a new pathway for phosphatidylcholine biosynthesis in S. cerevisiae

Turnover of phospholipids in the yeast Saccharomyces cerevisiae generates intracellular glycerophosphocholine (GPC). Here we show that GPC can be reacylated in an acyl-CoA-dependent reaction by yeast microsomal membranes. The lysophosphatidylcholine that is formed in this reaction is efficiently further acylated to phosphatidylcholine (PC) by yeast microsomes, thus providing a new pathway for PC biosynthesis that can either recycle endogenously generated GPC or utilize externally provided GPC. Genetic and biochemical evidence suggests that this new enzymatic activity, which we call GPC acyltransferase (GPCAT), is not mediated by any of the previously known acyltransferases in yeast. The GPCAT activity has an apparent V(max) of 8.7 nmol/min/mg protein and an apparent K(m) of 2.5 mM. It has a neutral pH optimum, similar to yeast glycerol-3-phosphate acyltransferase, but differs from the latter in being more heat stable. The GPCAT activity is sensitive to N-ethylmaleimide, phenanthroline, and Zn(2+) ions. In vivo experiments showed that PC is efficiently labeled when yeast cells are fed with [(3)H]choline-GPC, and that this reaction occurs also in pct1 knockout strains, where de novo synthesis of PC by the CDP-choline pathway is blocked. This suggests that GPCAT can provide an alternative pathway for PC biosynthesis in vivo.