Vitamin requirements and biosynthesis in Saccharomyces cerevisiae.

Chemically defined media for yeast cultivation (CDMY) were developed to support fast growth, experimental reproducibility, and quantitative analysis of growth rates and biomass yields. In addition to mineral salts and a carbon substrate, popular CDMYs contain seven to nine B-group vitamins, which are either enzyme cofactors or precursors for their synthesis. Despite the widespread use of CDMY in fundamental and applied yeast research, the relation of their design and composition to the actual vitamin requirements of yeasts has not been subjected to critical review since their first development in the 1940s. Vitamins are formally defined as essential organic molecules that cannot be synthesized by an organism. In yeast physiology, use of the term "vitamin" is primarily based on essentiality for humans, but the genome of the Saccharomyces cerevisiae reference strain S288C harbours most of the structural genes required for synthesis of the vitamins included in popular CDMY. Here, we review the biochemistry and genetics of the biosynthesis of these compounds by S. cerevisiae and, based on a comparative genomics analysis, assess the diversity within the Saccharomyces genus with respect to vitamin prototrophy.

Engineering Bacillus subtilis for the conversion of the antimetabolite 4-hydroxy-l-threonine to pyridoxine.

Until now, pyridoxine (PN), the most commonly supplemented B6 vitamer for animals and humans, is chemically synthesized for commercial purposes. Thus, the development of a microbial fermentation process is of great interest for the biotech industry. Recently, we constructed a Bacillus subtilis strain that formed significant amounts of PN via a non-native deoxyxylulose 5'-phosphate-(DXP)-dependent vitamin B6 pathway. Here we report the optimization of the condensing reaction of this pathway that consists of the 4-hydroxy-l-threonine-phosphate dehydrogenase PdxA, the pyridoxine 5'-phosphate synthase PdxJ and the native DXP synthase, Dxs. To allow feeding of high amounts of 4-hydroxy-threonine (4-HO-Thr) that can be converted to PN by B. subtilis overexpressing PdxA and PdxJ, we first adapted the bacteria to tolerate the antimetabolite 4-HO-Thr. The adapted bacteria produced 28-34mg/l PN from 4-HO-Thr while the wild-type parent produced only 12mg/l PN. Moreover, by expressing different pdxA and pdxJ alleles in the adapted strain we identified a better combination of PdxA and PdxJ enzymes than reported previously, and the resulting strain produced 65mg/l PN. To further enhance productivity mutants were isolated that efficiently take up and convert deoxyxylulose (DX) to DXP, which is incorporated into PN. Although these mutants were very efficient to convert low amount of exogenous DX, at higher DX levels they performed only slightly better. The present study uncovered several enzymes with promiscuous activity and it revealed that host metabolic pathways compete with the heterologous pathway for 4-HO-Thr. Moreover, the study revealed that the B. subtilis genome is quite flexible with respect to adaptive mutations, a property, which is very important for strain engineering.

Overexpression of a non-native deoxyxylulose-dependent vitamin B6 pathway in Bacillus subtilis for the production of pyridoxine.

Vitamin B6 is a designation for the vitamers pyridoxine, pyridoxal, pyridoxamine, and their respective 5'-phosphates. Pyridoxal 5'-phosphate, the biologically most-important vitamer, serves as a cofactor for many enzymes, mainly active in amino acid metabolism. While microorganisms and plants are capable of synthesizing vitamin B6, other organisms have to ingest it. The vitamer pyridoxine, which is used as a dietary supplement for animals and humans is commercially produced by chemical processes. The development of potentially more cost-effective and more sustainable fermentation processes for pyridoxine production is of interest for the biotech industry. We describe the generation and characterization of a Bacillus subtilis pyridoxine production strain overexpressing five genes of a non-native deoxyxylulose 5'-phosphate-dependent vitamin B6 pathway. The genes, derived from Escherichia coli and Sinorhizobium meliloti, were assembled to two expression cassettes and introduced into the B. subtilis chromosome. in vivo complementation assays revealed that the enzymes of this pathway were functionally expressed and active. The resulting strain produced 14mg/l pyridoxine in a small-scale production assay. By optimizing the growth conditions and co-feeding of 4-hydroxy-threonine and deoxyxylulose the productivity was increased to 54mg/l. Although relative protein quantification revealed bottlenecks in the heterologous pathway that remain to be eliminated, the final strain provides a promising basis to further enhance the production of pyridoxine using B. subtilis.

The role of the pyridoxine (vitamin B6) biosynthesis enzyme PDX1 in ultraviolet-B radiation responses in plants.

Ultraviolet-B radiation regulates plant growth and morphology at low and ambient fluence rates but can severely impact on plants at higher doses. Some plant UV-B responses are related to the formation of reactive oxygen species (ROS) and pyridoxine (vitamin B(6)) has been reported to be a quencher of ROS. UV-B irradiation of Arabidopsis Col-0 plants resulted in increased levels of PDX1 protein, compared with UV-A-exposed plants. This was shown by immunoblot analysis using specific polyclonal antibodies raised against the recombinant PDX1.3 protein and confirmed by mass spectrometry analysis of immunoprecipitated PDX1. The protein was located mainly in the cytosol but also to a small extent in the membrane fraction of plant leaves. Immunohistochemical analysis performed in pea revealed that PDX1 is present in UV-B-exposed leaf mesophyll and palisade parenchyma but not in epidermal cells. Pyridoxine production increased in Col-0 plants exposed to 3 days of UV-B, whereas in an Arabidopsis pdx1.3 mutant UV-B did not induce pyridoxine biosynthesis. In gene expression studies performed after UV-B exposure, the pdx1.3 mutant showed elevated transcript levels for the LHCB1*3 gene (encoding a chlorophyll a/b-binding protein of the photosystem II light-harvesting antenna complex) and the pathogenesis-related protein 5 (PR-5) gene, compared with wild type.

Functional complementation between the PDX1 vitamin B6 biosynthetic gene of Cercospora nicotianae and pdxJ of Escherichia coli.

The pathway for de novo vitamin B(6) biosynthesis has been characterized in Escherichia coli, however plants, fungi, archaebacteria, and most bacteria utilize an alternative pathway. Two unique genes of the alternative pathway, PDX1 and PDX2, have been described. PDX2 encodes a glutaminase, however the enzymatic function of the product encoded by PDX1 is not known. We conducted reciprocal transformation experiments to determine if there was functional homology between the E. coli pdxA and pdxJ genes and PDX1 of Cercospora nicotianae. Although expression of pdxJ and pdxA in C. nicotianae pdx1 mutants, either separately or together, failed to complement the pyridoxine mutation in this fungus, expression of PDX1 restored pyridoxine prototrophy to the E. coli pdxJ mutant. Expression of PDX1 in the E. coli pdxA mutant restored very limited ability to grow on medium lacking pyridoxine. We conclude that the PDX1 gene of the alternative B(6) pathway encodes a protein responsible for synthesis of the pyridoxine ring.

Disruption of the plr1+ gene encoding pyridoxal reductase of Schizosaccharomyces pombe.

Pyridoxal (PL) reductase encoded by the plr1(+) gene practically catalyzes the irreversible reduction of PL by NADPH to form pyridoxine (PN). The enzyme has been suggested to be involved in the salvage synthesis of pyridoxal 5'-phosphate (PLP), a coenzyme form of vitamin B(6), or the excretion of PL as PN from yeast cells. In this study, a PL reductase-disrupted (plr1 Delta) strain was constructed and its phenotype was examined. The plr1 Delta cells showed almost the same growth curve as that of wild-type cells in YNB and EMM media. In EMM, the plr1 Delta strain became flocculent at the late stationary phase for an unknown reason. The plr1 Delta cells showed low but measurable PL reductase activity catalyzed by some other protein(s) than the enzyme encoded by the plr1(+) gene, which maintained the flow of "PL --> PN --> PNP --> PLP" in the salvage synthesis of PLP. The total vitamin B(6) and pyridoxamine 5'-phosphate contents in the plr1 Delta cells were significantly lower than those in the wild-type ones. The percentages of the PLP amount as to the other vitamin B(6) compounds were similar in the two cell types. The amount of PL in the culture medium of the disruptant was significantly higher than that in the wild-type. In contrast, PN was much higher in the latter than the former. The plr1 Delta cells accumulated a 6.1-fold higher amount of PL than the wild-type ones when they were incubated with PL. The results showed that PL reductase encoded by the plr1(+ )gene is involved in the excretion of PL after reducing it to PN, and may not participate in the salvage pathway for PLP synthesis.

Characterization of the products of the genes SNO1 and SNZ1 involved in pyridoxine synthesis in Saccharomyces cerevisiae.

Genes SNO1 and SNZ1 are Saccharomyces cerevisiae homologues of PDX2 and PDX1 which participate in pyridoxine synthesis in the fungus Cercospora nicotianae. In order to clarify their function, the two genes SNO1 and SNZ1 were expressed in Escherichia coli either individually or simultaneously and with or without a His-tag. When expressed simultaneously, the two protein products formed a complex and showed glutaminase activity. When purified to homogeneity, the complex exhibited a specific activity of 480 nmol.mg(-1).min(-1) as glutaminase, with a Km of 3.4 mm for glutamine. These values are comparable to those for other glutamine amidotransferases. In addition, the glutaminase activity was impaired by 6-diazo-5-oxo-L-norleucine in a time- and dose-dependent manner and the enzyme was protected from deactivation by glutamine. These data suggest strongly that the complex of Sno1p and Snz1p is a glutamine amidotransferase with the former serving as the glutaminase, although the activity was barely detectable with Sno1p alone. The function of Snz1p and the amido acceptor for ammonia remain to be identified.

Pyridoxine biosynthesis in yeast: participation of ribose 5-phosphate ketol-isomerase.

To identify the genes involved in pyridoxine synthesis in yeast, auxotrophic mutants were prepared. After transformation with a yeast genomic library, a transformant (A22t1) was obtained from one of the auxotrophs, A22, which lost the pyridoxine auxotrophy. From an analysis of the plasmid harboured in A22t1, the RKI1 gene coding for ribose 5-phosphate ketol-isomerase and residing on chromosome no. 15 was identified as the responsible gene. This notion was confirmed by gene disruption and tetrad analysis on a diploid prepared from the wild-type and the auxotroph. The site of mutation on the RKI1 gene was identified as position 566 with a transition from guanine to adenine, resulting in amino acid substitution of Arg-189 with lysine. The enzymic activity of the Arg189-->Lys (R189K) mutant of ribose 5-phosphate ketolisomerase was 0.6% when compared with the wild-type enzyme. Loss of the structural integrity of the protein seems to be responsible for the greatly diminished activity, which eventually leads to a shortage of either ribose 5-phosphate or ribulose 5-phosphate as the starting or intermediary material for pyridoxine synthesis.

Synthesis and antioxidative activity of 6-hydroxypyridoxine.

An attempt to synthesize 6-hydroxypyridoxine (OPN), hydroxylation on C-6 of pyridoxine (PN) by hydroxyl radical (OH*). was conducted. Application of two well-known OH* generating reactions, i.e. the Fenton reaction and the Fe2+-EDTA/ascorbate reaction, were unsuccessful, as large amounts of by-products were formed. Although generation of OH* by autoxidation of ascorbic acid in the absence of metal ions was slow, by-products were formed in small quantities, and OPN was easily obtained in colorless crystals. Its structure was confirmed by spectral analyses. OPN was comparable to polyphenols such as (+)-catechin, rutin and gallic acid in the antioxidative activity against linoleic acid peroxidation, and was an effective DPPH radical scavenger, though the DPPH radical-scavenging activity of OPN was somewhat lower than that of the polyphenols. PN was relatively inactive under the conditions used here, indicating that the introduction of a hydroxyl group on C-6 of PN greatly enhanced both activities.

Biosynthesis of vitamin B6 in Rhizobium: in vitro synthesis of pyridoxine from 1-deoxy-D-xylulose and 4-hydroxy-L-threonine.

Pyridoxine (vitamin B6) in Rhizobium is synthesized from 1-deoxy-D-xylulose and 4-hydroxy-L-threonine. To define the pathway enzymatically, we established an enzyme reaction system with a crude enzyme solution of R. meliloti IFO14782. The enzyme reaction system required NAD+, NADP+, and ATP as coenzymes, and differed from the E. coli enzyme reaction system comprising PdxA and PdxJ proteins, which requires only NAD+ for formation of pyridoxine 5'-phosphate from 1-deoxy-D-xylulose 5-phosphate and 4-(phosphohydroxy)-L-threonine.

Biosynthesis of pyridoxine in Saccharomyces cerevisiae--origin of the pyridoxine nitrogen atom differs under anaerobic and aerobic conditions.

The amide nitrogen atom of glutamine is incorporated into pyridoxine in four eukaryotes (i.e., Emericella nidulans, Mucor racemosus, Neurospora crassa and Saccharomyces cerevisiae) and two prokaryotes (i.e., Staphylococcus aureus and Bacillus subtilis). However, in the prokaryotes Pseudomonas putida, Enterobacter aerogenes and Escherichia coli, it is the nitrogen atom of glutamate that is incorporated into pyridoxine (J Nutr Sci Vitaminol (2000) 46, 55-57). As these results were from experiments conducted under aerobic conditions, we investigated the biosynthesis of pyridoxine on S. cerevisiae under anaerobic conditions. The results showed that [amide-15N]L-glutamine was not incorporated into pyridoxine, unlike the results for aerobic conditions. The incorporation of [15N]ammonium salts into pyridoxine was not inhibited in the presence of casamino acids and tryptophan. The results showed that the nitrogen atoms of amino acids are not used for the biosynthesis of pyridoxine. The incorporation of 15N into pyridoxine was inhibited in the presence of adenine, but not in that of hypoxanthine. Thus, the nitrogen atom of pyridoxine may be from the amino group attached to the C-6 of adenine.

Isolation of PDX2, a second novel gene in the pyridoxine biosynthesis pathway of eukaryotes, archaebacteria, and a subset of eubacteria.

In this paper we describe the isolation of a second gene in the newly identified pyridoxine biosynthesis pathway of archaebacteria, some eubacteria, fungi, and plants. Although pyridoxine biosynthesis has been thoroughly examined in Escherichia coli, recent characterization of the Cercospora nicotianae biosynthesis gene PDX1 led to the discovery that most organisms contain a pyridoxine synthesis gene not found in E. coli. PDX2 was isolated by a degenerate primer strategy based on conserved sequences of a gene specific to PDX1-containing organisms. The role of PDX2 in pyridoxine biosynthesis was confirmed by complementation of two C. nicotianae pyridoxine auxotrophs not mutant in PDX1. Also, targeted gene replacement of PDX2 in C. nicotianae results in pyridoxine auxotrophy. Comparable to PDX1, PDX2 homologues are not found in any of the organisms with homologues to the E. coli pyridoxine genes, but are found in the same archaebacteria, eubacteria, fungi, and plants that contain PDX1 homologues. PDX2 proteins are less well conserved than their PDX1 counterparts but contain several protein motifs that are conserved throughout all PDX2 proteins.

Structural basis for the function of pyridoxine 5'-phosphate synthase.

BACKGROUND: Pyridoxal 5'-phosphate is the active form of vitamin B(6) that acts as an essential, ubiquitous coenzyme in amino acid metabolism. In Escherichia coli, the pathway of the de novo biosynthesis of vitamin B(6) results in the formation of pyridoxine 5'-phosphate (PNP), which can be regarded as the first synthesized B(6) vitamer. PNP synthase (commonly referred to as PdxJ) is a homooctameric enzyme that catalyzes the final step in this pathway, a complex intramolecular condensation reaction between 1-deoxy-D-xylulose-5'-phosphate and 1-amino-acetone-3-phosphate. RESULTS: The crystal structure of E. coli PNP synthase was solved by single isomorphous replacement with anomalous scattering and refined at a resolution of 2.0 A. The monomer of PNP synthase consists of one compact domain that adopts the abundant TIM barrel fold. Intersubunit contacts are mediated by three additional helices, respective to the classical TIM barrel helices, generating a tetramer of symmetric dimers with 422 symmetry. In the shared active sites of the active dimers, Arg20 is directly involved in substrate binding of the partner monomer. Furthermore, the structure of PNP synthase with its physiological products, PNP and P(i), was determined at 2.3 A resolution, which provides insight into the dynamic action of the enzyme and allows us to identify amino acids critical for enzymatic function. CONCLUSION: The high-resolution structures of the free enzyme and the enzyme-product complex of E. coli PNP synthase suggest essentials of the enzymatic mechanism. The main catalytic features are active site closure upon substrate binding by rearrangement of one C-terminal loop of the TIM barrel, charge-charge stabilization of the protonated Schiff-base intermediate, the presence of two phosphate binding sites, and a water channel that penetrates the beta barrel and allows the release of water molecules in the closed state. All related PNP synthases are predicted to fold into a similar TIM barrel pattern and have comparable active site architecture. Thus, a common mechanism can be anticipated.

Phylogenetic analyses and comparative genomics of vitamin B6 (pyridoxine) and pyridoxal phosphate biosynthesis pathways.

Vitamin B6 in its active form pyridoxal phosphate is an essential coenzyme of many diverse enzymes. Biochemistry, enzymology and genetics of de novo vitamin B6 biosynthesis have been primarily investigated in Escherichia coli. Database searches revealed that the key enzymes involved in ring closure of the aromatic pyridoxin ring (PdxA; PdxJ) are present mainly in genomes of bacteria constituting the gamma subdivision of proteobacteria. The distribution of DXS, a transketolase-like enzyme involved in vitamin B6 biosynthesis as well as in thiamine and isoprenoid biosynthesis and the distribution of vitamin B6 modifying enzymes (PdxH: oxidase; PdxK: kinase) was also analyzed. These enzymes are also present in the genomes of animals. Two recent papers (Ehrenshaft et al., 1999, Proc. Natl. Acad. Sci. USA. 96: 9374-9378; Osmani et al., 1999, J. Biol. Chem. 274: 23565-23569) show the involvement of an extremely conserved protein (a member of the UPF0019 or SNZ family) found in all three domains of life (bacteria, archaea, eukarya) in an alternative vitamin B6 biosynthesis pathway. Members of this family were previously identified as a stationary phase inducible protein in yeast, as an ethylene responsible protein in plants and in a marine sponge, as a singlet oxygen resistance protein in Cercospora nicotianae and as a cumene hydroperoxide and H2O2 inducible protein in Bacillus subtilis. In yeast, the SNZ protein interacts with another protein called SNO which also represents a member of a highly conserved protein family (called UPF0030 or SNO family). Phylogenetic trees for the DXS, PdxA, PdxJ, PdxH, PdxK, SNZ and SNO protein families are presented and possible implications of the two different vitamin B6 biosynthesis pathways in cellular metabolism are discussed. A radically different view of bacterial evolution (Gupta, 2000, Crit. Rev. Microbiol. 26: 111-131) which proposes a linear rather than a treelike evolutionary relationship between procaryotic species indicates that the gamma subdivision of proteobacteria represents the most recently evolved bacterial lineage. This proposal might help to explain why the PdxA/PdxJ pathway is largely restricted to this subdivision.

Biosynthesis of vitamin B6 and structurally related derivatives.

In spite of the rather simple structure of pyridoxal 5'-phosphate (I), a member of the vitamin B6 group, the elucidation of its de novo biosynthesis remained largely unexplored until recently. Experiments designed to investigate the formation of the vitamin B6 pyridine nucleus mainly concentrated on Escherichia coli. The results of tracer experiments with radioactive and stable isotopes, feeding experiments, and molecular biological studies led to the prediction that 4-hydroxy-L-threonine (VIII, R = H) and 1-deoxy-D-xylulose (VII, R = H) are precursors which are assembled to yield the carbon-nitrogen skeleton of vitamin B6. At this point, the involvement of the phosphorylated forms of these precursors in this assembly seems quite clear. However, vitamin B6 biosynthesis in organisms other than E. coli remains largely unknown. Toxic derivatives of vitamin B6, such as ginkgotoxin, occurring in higher plants may be suitable targets to gain further insight into this tricky problem.

Biosynthesis of pyridoxine: origin of the nitrogen atom of pyridoxine in microorganisms.

The amide nitrogen atom of glutamine was incorporated into pyridoxine in four eukaryotes, Emericella nidulans, Mucor racemosus, Neurospora crassa and Saccharomyces cerevisiae, and two prokaryotes, Staphylococcus aureus and Bacillus subtilis, but not in the following prokaryotes, Pseudomonas putida, Enterobacter aerogenes and Escherichia coli. On the other hand, the nitrogen atom of glutamate was incorporated into pyridoxine in P. putida, E. aerogenes and E. coli, but not in S. aureus and B. subtilis. These results suggest that there are at least two different biosynthetic routes for pyridoxine and the difference does not depend on prokaryotes and eukaryotes.

Biosynthesis of 4'-O-methylpyridoxine (Ginkgotoxin) from primary precursors.

Cell suspension cultures of Ginkgo biloba and Albizia tanganyicensis were investigated for the presence of 4'-O-methylpyridoxine (ginkgotoxin, 2), the 4'-O-methyl derivative of vitamin B(6) (pyridoxine, 1). The cultures produced the toxin even in the absence of vitamin B(6) (a common additive to plant cell culture media). This indicates that the pyridoxine ring system of ginkgotoxin is synthesized de novo by the cultured cells. A feeding experiment with D-[U-(13)C(6)]glucose revealed that the mode of incorporation of label into the pyridoxine moiety of 2 matched that observed for 1 in Escherichia coli. Thus, the data obtained in this investigation provide independent proof supporting the current hypothesis on vitamin B(6) biosynthesis. The 4'-O-methyl group of ginkgotoxin (2) was labeled from L-[methyl-(13)C(1)]methionine. This indicates that ginkgotoxin is likely to be derived by 4'-O-methylation of pyridoxine (1). The G. biloba cell suspension culture may be a suitable system to get further insight into vitamin B(6) and/or ginkgotoxin biosynthesis.

Biosynthesis of vitamin B(6) in rhizobium.

The biosynthetic pathway of pyridoxol (vitamin B(6)) in Rhizobium was clarified by studies on the incorporation of (13)C- or (15)N-labeled precursors into pyridoxol or its biosynthetic intermediates. Pyridoxol was formed by ring closure of two compounds, 1-deoxy-D-xylulose and 4-hydroxy-L-threonine. The former was formed from D-glyceraldehyde and pyruvate through decarboxylation of pyruvate, and the latter from glycine and glycolaldehyde.

A highly conserved sequence is a novel gene involved in de novo vitamin B6 biosynthesis.

The Cercospora nicotianae SOR1 (singlet oxygen resistance) gene was identified previously as a gene involved in resistance of this fungus to singlet-oxygen-generating phototoxins. Although homologues to SOR1 occur in organisms in four kingdoms and encode one of the most highly conserved proteins yet identified, the precise function of this protein has, until now, remained unknown. We show that SOR1 is essential in pyridoxine (vitamin B6) synthesis in C. nicotianae and Aspergillus flavus, although it shows no homology to previously identified pyridoxine synthesis genes identified in Escherichia coli. Sequence database analysis demonstrated that organisms encode either SOR1 or E. coli pyridoxine biosynthesis genes, but not both, suggesting that there are two divergent pathways for de novo pyridoxine biosynthesis in nature. Pathway divergence appears to have occurred during the evolution of the eubacteria. We also present data showing that pyridoxine quenches singlet oxygen at a rate comparable to that of vitamins C and E, two of the most highly efficient biological antioxidants, suggesting a previously unknown role for pyridoxine in active oxygen resistance.

The extremely conserved pyroA gene of Aspergillus nidulans is required for pyridoxine synthesis and is required indirectly for resistance to photosensitizers.

Numerous disparate studies in plants, filamentous fungi, yeast, Archaea, and bacteria have identified one of the most highly conserved proteins (SNZ family) for which no function was previously defined. Members have been implicated in the stress response of plants and yeast and resistance to singlet oxygen toxicity in the plant pathogen Cercospora. However, it is found in some anaerobic bacteria and is absent in some aerobic bacteria. We have cloned the Aspergillus nidulans homologue (pyroA) of this highly conserved gene and define this gene family as encoding an enzyme specifically required for pyridoxine biosynthesis. This realization has enabled us to define a second pathway for pyridoxine biosynthesis. Some bacteria utilize the pdx pyridoxine biosynthetic pathway defined in Escherichia coli and others utilize the pyroA pathway. However, Eukarya and Archaea exclusively use the pyroA pathway. We also found that pyridoxine is destroyed in the presence of singlet oxygen, helping to explain the connection to singlet oxygen sensitivity defined in Cercospora. These data bring clarity to the previously confusing data on this gene family. However, a new conundrum now exists; why have highly related bacteria evolved with different pathways for pyridoxine biosynthesis?