Isolation of PDX2, a Second Novel Gene in the Pyridoxine Biosynthesis Pathway of Eukaryotes, Archaebacteria, and a Subset of Eubacteria

doi:10.1128/JB.183.11.3383-3390.2001

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Journal of Bacteriology, June 2001, p. 3383-3390, Vol. 183, No. 11
0021-9193/01/$04.00+0 DOI: 10.1128/JB.183.11.3383-3390.2001
Copyright © 2001, American Society for Microbiology. All rights reserved.

Isolation of PDX2, a Second Novel Gene in the Pyridoxine Biosynthesis Pathway of Eukaryotes, Archaebacteria, and a Subset of Eubacteria

Marilyn Ehrenshaft^* and Margaret E. Daub

Department of Plant Pathology, North Carolina State University, Raleigh, North Carolina 27795

Received 26 October 2000/Accepted 19 March 2001

	ABSTRACT

Top Abstract Introduction Materials and Methods Results Discussion References

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 biosynthesishas been thoroughly examined in Escherichia coli, recent characterizationof the Cercospora nicotianae biosynthesis gene PDX1 led to thediscovery that most organisms contain a pyridoxine synthesis genenot found in E. coli. PDX2 was isolated by a degenerate primerstrategy based on conserved sequences of a gene specific to PDX1-containingorganisms. The role of PDX2 in pyridoxine biosynthesis was confirmedby complementation of two C. nicotianae pyridoxine auxotrophsnot mutant in PDX1. Also, targeted gene replacement of PDX2 inC. nicotianae results in pyridoxine auxotrophy. Comparable toPDX1, PDX2 homologues are not found in any of the organisms withhomologues to the E. coli pyridoxine genes, but are found in thesame archaebacteria, eubacteria, fungi, and plants that containPDX1 homologues. PDX2 proteins are less well conserved than theirPDX1 counterparts but contain several protein motifs that areconserved throughout all PDX2proteins.

	INTRODUCTION

Top Abstract Introduction Materials and Methods Results Discussion References

Recent work in our laboratory with the filamentous, phytopathogenic fungus Cercospora nicotianae revealed that a highly conservedgroup of gene homologues found in eubacteria, archaebacteria,fungi, and plants play a role in a divergent pyridoxine (vitaminB₆) biosynthesis pathway (8). PDX1 was originally identifiedas a gene required for resistance of this fungus to a singlet-oxygen-generatingtoxin, cercosporin, which it produces to parasitize plants (9,10). During characterization of this gene, however, we discoveredthat it rescued both C. nicotianae and Aspergillus flavus pyridoxineauxotrophs to prototrophy (8). This observation was subsequentlyconfirmed in Aspergillus nidulans, in which a PDX1 homologue,PYROA, also rescued pyridoxine auxotrophy (24). Interestingly,despite this direct evidence for the involvement of PDX1 homologuesin pyridoxine synthesis, PDX1 shows no homology to any of theknown Escherichia coli pyridoxine biosynthesis genes or to anygene in the completely sequenced E. coli genome. Database analysisdetermined that organisms with homologues to the E. coli genes(some eubacteria) lacked PDX1 homologues and that organisms withPDX1 homologues (other eubacteria, archaebacteria, fungi, andplants) lacked homologues to the E. coli genes. These data suggestedthat a divergence in the pyridoxine synthesis pathway occurredsometime during the evolution of the eubacteria (8).

The advent of genomic and other large-scale sequencing projects allows homology comparisons on an organismal level. Saccharomycescerevisiae contains three unlinked PDX1 homologues, one of which(SNZ1, for snooze) was extensively studied because its expressionincreases dramatically during stationary phase (5). Analysesby Galperin and Koonin (12) uncovered that PDX1-containing organismsalso contained a copy of a second homologous gene and that threeof these organisms (S. cerevisiae and the eubacteria Bacillussubtilis and Haemophilus influenzae) all encode this second genein close physical proximity to their PDX1 homologues. These researchershypothesized that the protein encoded by this second open readingframe (ORF) (which they named SNZB) possesses glutamine amidotransferaseactivity. Clusters of orthologous groups of protein analysis performedat the National Center for Biotechnology Information (http://www.ncbi.nlm.nih.gov/COG/)compares protein sequences encoded in 21 complete genomes from17 major phylogenetic lineages. This analysis supports the suppositionthat PDX1 and SNZB are functionally linked because it indicatesthat there is only one other gene with the same organismal distributionpattern as PDX1, and that gene is SNZB (19, 29, 30). Padillaet al. (25) further characterized the yeast SNZB homologues,dubbing them SNO (Snz-proximal ORF), and showed that all threeSNZ/SNO pairs were coordinately regulated during growth and nutrientlimitation. They also expressed both proteins from one of thegene pairs using a yeast two-hybrid system and showed that theproteinsinteract.

Despite the above results, there is no direct evidence for a role of SNZB/SNO homologues in pyridoxine synthesis. We havefive UV-generated mutant strains of C. nicotianae that are pyridoxineauxotrophs (8, 16, 18). Three of these strains can be restoredat high frequency to prototrophy by transformation with PDX1,while the two remaining strains, CS2 (CS for cercosporin sensitive)and CS7, have wild-type PDX1 genes (9, 10), suggesting thatthey are mutant in a different gene in the biosynthesis pathway.In light of the above data, it seemed reasonable to isolate aC. nicotianae SNZB/SNO homologue and test its involvement in pyridoxinemetabolism. Here we report the successful isolation of the C.nicotianae SNZB/SNO homologue and confirmation of its role inpyridoxine biosynthesis via both targeted gene disruption andthe ability to rescue our C. nicotianae non-PDX1 pyridoxine mutantstoprototrophy.

	MATERIALS AND METHODS

Top Abstract Introduction Materials and Methods Results Discussion References

Strains, cultural conditions, and fungal transformations. The wild-type (ATCC 18366) and pyridoxine auxotrophic (CS2, CS7, CS8, and 9714-1) C. nicotianae strains used in this studywere described previously (8, 16, 18). Briefly, CS2, CS7,and CS8 were generated by UV mutagenesis, while 9714-1 is a pdx1null strain derived via targeted gene replacement. All strainswere maintained on malt medium at 28°C. Experiments to determinepyridoxine auxotrophy or prototrophy used a minimal medium (17),bacteriological agar (Sigma), and supplementation, when necessary,with pyridoxine to a final concentration of 1 µg/ml. Cercosporinresistance was assayed by growth on CM medium (17) supplementedwith 10 µM cercosporin. In both cases growth was assayed by transferringfungal mycelium as a toothpick point inoculation and measuringincrease in colony diameter after 4 days of growth at 28°C. Cercosporinresistance assays were conducted in a lighted growth chamber (45to 55 µEinsteins/m²/s). C. nicotianae strains were transformed as previously described(9, 11).

Cloning of PDX2. Degenerate primers for amplification of an internal portion of the C. nicotianae PDX2 gene were designed by the CODEHOP (consensus-degeneratehybrid oligonucleotide primers) program (http://blocks.fhcrc.org/blocks/codehop.html)(27), based on protein sequences from Neurospora crassa, Schizosaccharomycespombe, and the three yeast homologues. The 5' and 3' primers were,respectively, GACCAACATAAACCTACTTGGGGTACNTGYGCNGG and GATCAATAATTTCTTCAATAACAGGAGCNCKDATRAA(see Fig. 4A for regions of the protein to which these correspond).Amplification was performed using Amplitaq Gold (PE Biosystems),an annealing temperature of 57°C, and 50 cycles of amplification.Because the amplification reaction also contained a high-molecular-weightfragment unlikely to correspond to the desired product, an approximately200-bp band was gel purified and cloned in pGEM-T-Easy (Promega).Sequence analysis confirmed that the cloned fragment correspondedto the desiredproduct.

The entire gene plus flanking regions was recovered using inverse PCR. Southern hybridization analysis was used to determinewhich restriction enzymes digested the C. nicotianae genome intofragments suitable for inverse PCR amplification. EcoRI-digestedDNA was then self-ligated at dilute concentrations and used asa template for an inverse PCR amplification. When a fragment ofthe expected size was amplified, it was cloned into pGEM-T-Easy(Promega) for sequence analysis. After sufficient sequence wasobtained to encompass the entire ORF plus upstream promoter anddownstream sequences, primers were designed to amplify the intactgene from C. nicotianae genomic DNA using the high-fidelity DNAPfu polymerase (Promega). After addition of an A residue to bothends, the amplification product was cloned into pGEM-T-Easy forsequence analysis. It was then recovered from pGEM-T-Easy forcloning into the fungal vector pBARKS1 (28) for transformationinto C. nicotianae mutantstrains.

Gene disruption. To produce a gene disruption construct, the cloned inverse PCR product was recovered from pGEM-T-Easy and cloned into thefungal transformation vector pBARKS1. Because the PDX2 gene islocated at either end of the recovered fragment, ligation intopBARKS1 produced a gene disruption construct with the entire vectorinterrupting the PDX2ORF.

PCR amplification of PDX2 from mutant strains CS2 and CS7 and RT-PCR. The PDX2 ORFs were amplified from CS2 and CS7 genomic DNA with the high-fidelity Pfu DNA polymerase using conditions describedby the manufacturer (Promega). Reverse transcription (RT)-PCRwas performed using the Access RT-PCR kit (Promega) accordingto the manufacturer'sspecifications.

Manipulations of nucleic acids. Fungal genomic DNA was extracted as described (36), digested with restriction enzymes, and electrophoresed though 0.8% agaroseprior to transfer to Magnagraph membrane (Osmonics). Probes weregenerated via PCR incorporation of digoxigenin-dUTP using eitherdegenerate primers or, for the full-length PDX2 probe, the primersthat span the start and stop codons, as shown in Fig. 1. Hybridizationswere carried out in aqueous buffer at 65°C and washes at highstringency. Standard methods were used for the construction ofplasmids and transformation into E. coli strain DH5 $alpha$ .

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FIG. 1. Nucleotide sequence of C. nicotianae PDX2 gene. The nucleotides shown are sufficient to complement the two non-pdx1 pyridoxine auxotrophs, CS2 and CS7. The nucleotides in italics at either end represent the primers used to amplify this sequence from C. nicotianae genomic DNA. The underlined nucleotides are the primers used to amplify the RT-PCR product and to label the coding sequence with digoxigenin-11-dUTP. The putative AP-1 recognition sequence is shown in bold. The boxed nucleotides represent the regions of the CS2 and CS7 pdx2 genes that are missing a single nucleotide. The bold italic amino acid residues are identical in all known PDX2 proteins, while the additional amino acid residues shown in bold type are completely conserved only among fungal PDX2 proteins.

DNA sequence analysis. DNA sequence analysis was performed at the Molecular Genetics Facility at the University of Georgia, Athens. Homology searcheswere performed at the National Center for Biotechnology Informationwith the Blast network service (1). Both strands of the entirewild-type gene were sequenced, while one strand of RT-PCR productsor PDX2 products from mutants was analyzed. Multiple alignmentswere performed using the European Bioinformatics Institute ClustalW Service (http://www2.ebi.ac.uk/clustalw) (33).

Nucleotide and protein sequence accession numbers. The GenBank accession number for the C. nicotianae PDX2 gene is AF294268. The protein sequences shown in Fig. 4 includeNeurospora crassa (GenBank AW713653), S. cerevisiae homologues(Swiss-Prot P53823, Swiss-Prot Q03144, and Swiss-ProtP43544), S. pombe (GenBank AL132798), Sulfolobus solfataricus(GenBank Y18930), Pyrococcus horikoshii (GenBank AP000006),Bacillus subtilis (Swiss-Prot P37527), Mycobacterium leprae(GenBank U00011), and wheat (Triticum aestivum) (GenBank BE217011).

	RESULTS

Top Abstract Introduction Materials and Methods Results Discussion References

Amplification of PDX2. Using degenerate primers (see Materials and Methods and Fig. 4A), a fragment comparable in size to fragments amplified fromboth N. crassa and yeast SNO clones was amplified from C. nicotianaegenomic DNA and cloned. After sequence analysis revealed it toencode a partial protein with strong homology to the SNO homologuesof other fungi, the entire ORF and flanking regions were recoveredusing inverse PCR. Sufficient sequence was determined from theinverse PCR product for designing primers to amplify and clonea functional ca. 1,600-bp gene using the high-fidelity thermostablePfu DNA polymerase (Fig. 1). Sequence analysis revealed that thisfragment contains an uninterrupted ORF of 843 nucleotides encodinga putative polypeptide of 278 amino acid residues. This apparentlack of introns was confirmed by amplification, cloning, and sequenceanalysis of an RT-PCR product. No canonical promoter sequencesare found in the region upstream of the PDX2 ORF. There is, however,an AP-1 response recognition site approximately 100 bp 5' of theinitiation codon (35).

Complementation of pyridoxine auxotrophs CS2 and CS7. The entire PDX2 coding sequence plus flanking regions (Fig. 1) was cloned into the fungal transformation vector pBARKS1 (28)for transformation into the two C. nicotianae pyridoxine auxotrophicstrains (CS2 and CS7) that are not pdx1 mutants. Ten and 25 bialaphos-resistanttransformants of CS2 and CS7, respectively, were tested for abilityto grow on minimal medium without pyridoxine (Fig. 2). Eightypercent of CS2 and 76% of CS7 transformants containing PDX2 grewto between 9 and 100% of wild-type growth on unsupplemented minimalmedium. Neither of the parental strains nor any of the two CS2or eight CS7 colonies transformed with the vector could grow onminimal medium. In previous work, we tested 40 CS2 and 46 CS7strains transformed with the vector, and none of these vector-transformedstrains exhibited even 1% of wild-type growth when tested forcomplementation (9).

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FIG. 2. Growth of wild-type (WT) C. nicotianae, pdx2 mutant strains CS2 and CS7, a pdx2 gene disruption mutant (DISR.), and pdx2 mutant strains complemented by transformation with the PDX2 gene (CS2/C and CS7/C) on minimal medium with (+pdx) and without ( $-$ pdx) pyridoxine. Fungal plugs (6 mm) were placed mycelium side down and incubated for 4 days at 28°C.

Targeted gene disruption of PDX2. The inverse PCR product containing PDX2 was recovered from pGEM-T-Easy and cloned into pBARKS1. Standard gene disruption constructsthat rely on double-crossover events for successful gene replacementgenerally contain an antibiotic resistance gene within the genebeing disrupted. This plasmid (Fig. 3A) corresponds to a standardgene disruption construct except that the entire vector containingan antibiotic resistance marker interrupts PDX2 and its flankingregions. The disruption construct was transformed into the C.nicotianae wild-type strain, and bialaphos-resistant transformantswere screened on minimal medium. One transformant of 758 testedwas unable to grow on minimal medium, but could be rescued towild-type growth by supplementation of the medium with pyridoxine(Fig. 2). Southern analysis (Fig. 3B) confirmed that this straincontained a disrupted pdx2 gene.

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FIG. 3. Disruption of PDX2. (A) Schematic describing the disruption plasmid. A clone was constructed in which the PDX2 inverse PCR product, which consists of the 5' and 3' ends of PDX2 separated by both 5' and 3' flanking sequences, was ligated to pBARKS1, a bialophos resistance-encoding vector. Standard gene disruption constructs that rely on double-crossover events for successful gene replacement generally contain an antibiotic resistance gene within the gene being disrupted. This plasmid corresponds to a standard gene disruption construct except that the entire vector containing the antibiotic resistance marker has been used to interrupt PDX2. (B) Southern hybridization analysis of a pdx2-disrupted strain. EcoRI-digested DNA from the wild-type (WT) and a pdx2-disrupted (DISR.) strains was probed with a PDX2-specific probe spanning the entire ORF. In the wild-type strain, the entire ORF is contained on a single EcoRI fragment, which is split into three parts in the gene disruption strain.

PDX2 protein sequence. Figure 4 shows a comparison of the C. nicotianae PDX2 protein sequence and all available complete fungal homologues (Fig.4A) and representative, homologues from other taxa (archaebacteria,eubacteria, and plants) (Fig. 4B). The C. nicotianae protein hasa region towards the C terminus that is not found in any of theother proteins. Not surprisingly, the fungal proteins exhibitthe strongest homology, while the other proteins are distinctlyless well conserved. All regions conserved in the fungal proteins,however, are also found in the PDX2 protein sequences from moredistantly related taxa, with the regions of homology tending towardsconservative and semiconservative substitutions in the lattergroup. Two regions are highly conserved across all taxa, the PGGESTmotif found at C. nicotianae residues 63 to 68 and the FHPE(LT)motif at C. nicotianae residues 253 to 258 (Fig. 1).

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FIG. 4. Comparison of the predicted amino acid sequences of PDX2 and homologues. (A) Comparison of all fungal PDX2 homologues. Species include C. nicotianae (Cn), Neurospora crassa (Nc), S. cerevisiae homologue from chromosome 6 (Y6), S. cerevisiae homologue from chromosome 14 (Y14), S. cerevisiae homologue from chromosome 13 (Y13), and S. pombe (Spom). The protein sequences from which the degenerate primers were derived are indicated by asterisks. (B) Comparison of the C. nicotianae (Cn) PDX2 protein sequence with representative sequences from other major taxa, including the archaebacteria Sulfolobus solfataricus (Sulf) and Pyrococcus horikoshii (Pyroc), the eubacteria Bacillus subtilis (Bsubt) and Mycobacterium leprae (Myclep), and the plant wheat (Triticum aestivum). The black-boxed residues with white letters indicate identical residues in all proteins, while the darker and lighter shading indicates, respectively, conserved substitutions and semiconserved substitutions.

PDX2 sequences from mutants. The gene ORFs from mutant strains CS2 and CS7 were amplified from each strain using the high-fidelity thermostable Pfu DNApolymerase and cloned for sequence analysis. Two independent amplificationreactions were used to generate two independent clones from eachstrain. One strand of each clone was sequenced. The sequencesfrom the two independent clones from each strain matched and showedthat both the CS2 and CS7 pdx2 genes were missing a single nucleotide,leading to aberrant and truncated proteins of 13 and 12.4 kDa,respectively, in contrast to the wild-type protein of 30.1 kDa.The CS2 ORF is missing one of three cytosine residues at nucleotides800 to 802, while the CS7 ORF is missing one of a guanosine residuetriplet at nucleotides 635 to 637 (Fig. 1). The sequences of theresulting proteins diverge from the wild type at the altered codons(amino acid residues 38 and 93 for CS7 and CS2, respectively),converge with one another at amino acid residue 93, and terminateafter 117 amino acid residues at the same stop codon. The CS7protein contains only the first highly conserved domain (GVLALQGA),while the CS2 protein also contains the second (PGGEST) conserveddomain.

Taxonomic distribution of PDX2 homologues. Database searches were performed with the C. nicotianae PDX2 gene against GenBank and the finished and unfinished microbialdatabases available at the Institute for Genomic Research website (http://www.tigr.org). As with PDX1, no organism containinghomologues to the E. coli pyridoxine genes encodes a PDX2 homologue.A list of organisms encoding PDX2 homologues is shown in Table1. PDX2 homologues are encoded by archaebacteria, fungi, plants,and eubacteria of the same groups that that encode PDX1 homologues.Nearly all of the organisms listed in Table 1 also have PDX1homologues in the databases or are in the same genus as organismswith homologues. The only exceptions are a single plant (soybean,Glycine max) and a single eubacterium (Dehalococcoides ethenogenes),neither of which has been completely sequenced.

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TABLE 1. Occurrence of PDX2 homologues in organisms of diverse taxa^a

Transformation of pdx1 mutant strain CS8 and pdx1 null strain 9714-1 with PDX2. The same construct used to transform and complement pdx2 mutant strains CS2 and CS7 was also used to transform two C. nicotianaepdx1 mutant strains. CS8 is the UV-derived strain (16, 18)whose complementation led to the identification of PDX1; strain9714-1 was derived via targeted gene replacement and is null forPDX1 (10). In a previous study we showed that PDX1 can complementthe two pdx2 mutant strains CS2 and CS7 at low frequency. Whereaspdx1 mutant strains were complemented at rates of 82 to 100%,CS2 and CS7 were complemented at rates of 35 and 11%, respectively(10). Because this study was conducted prior to our discoverythat PDX1 was involved in pyridoxine synthesis, we used resistanceto cercosporin as the measure of complementation. Pyridoxine isconsumed during its quenching reaction with cercosporin-generatedsinglet oxygen, and therefore growth of a transformant in thepresence of light and cercosporin indicates that the strain iscapable of continued pyridoxine synthesis. In order to directlycompare the effect of transformation of PDX2 into pdx1 mutantstrains with the previously published converse experiment, CS8and 9714-1 PDX2 transformants were tested for complementationon CM medium supplemented with 10 µM cercosporin. None of the59 PDX2 transformants of the pdx1 null strain 9714-1 were ableto grow in our assay. One of the 59 CS8 PDX2 transformants (1.7%)did grow in the presence of cercosporin, but only to 45% of thelevel of the wild-typestrain.

	DISCUSSION

Top Abstract Introduction Materials and Methods Results Discussion References

In this work we provide evidence for a second gene involved in a recently described divergent pathway for pyridoxine biosynthesis.Using a PCR-based degenerate priming strategy, we isolated a C.nicotianae homologue of the yeast SNZB/SNO gene. Complementationof two C. nicotianae pyridoxine biosynthesis mutants with thisgene demonstrated that it is required for pyridoxine biosynthesis.Sequencing of the pdx2 genes in these mutants revealed that bothencode altered and truncated proteins, leading to their mutantphenotypes. Gene disruption experiments further corroborated thecomplementation studies and sequence analysis, and we have namedthis gene PDX2 in recognition of its newly defined role. Not surprisingly,database analysis revealed that PDX2 homologues exhibit the samedistribution pattern as the PDX1 group of genes, the only otherdefined gene in this pathway. Additionally, while PDX2 proteinsare not as well conserved as PDX1 proteins, several PDX2 domainsare conserved across diverse phylogeneticgroups.

In contrast to the situation in E. coli, very little is known about the PDX1/PDX2 biochemical pathway. ¹⁵N-labeling experiments suggested that the nitrogen of yeast pyridoxineoriginates with the amide moiety of glutamine (32), whereasin E. coli, glutamic acid provides the nitrogen (13, 14).Consistent with this, independent sequence motif analysis suggestedthat the PDX2 protein possesses glutamine amidotransferase activity(12). Data from Aspergillus nidulans, however, suggest thatammonium may be the source of the nitrogen atom (2, 3).Recent biochemical work with the eubacterium Rhizobium melilotidemonstrated that its pyridoxine biosynthesis pathway differsfrom that of E. coli (31). In E. coli, pyridoxine 5'-phosphateis formed via condensation of 4-phosphohydroxy-L-threonine and1-deoxy-D-xylulose-5-phosphate (6, 7, 20), and 4-phosphohydroxy-L-threonineis formed by a four-step process from erythrose 4-phosphate. InR. meliloti, the latter compound is derived instead from condensationof glycine and glycoaldehyde. In E. coli, 4-hydroxy-L-threoninemay be formed from glycine and glycoaldehyde, but only if glycoaldehydeis supplied. Unfortunately, no information is currently availableon whether R. meliloti encodes the E. coli or PDX1-PDX2 homologues.We are currently engaged in experiments to determine if our C.nicotianae PDX1 and PDX2 genes and the E. coli pdxA and pdxJ genes(encoding the enzymes catalyzing the final condensation step between1-deoxy-D-xylulose-5-phosphate and 4-phosphohydroxy-L-threonine)can functionally substitute for each other. In addition, we alsointend to look at expression of pyridoxine genes in A. nidulans.Further data from these studies as well as from R. meliloti shouldprovide valuable information on the actual roles of the PDX1 andPDX2 proteins and differentiate whether there are two completelyunrelated pathways or the biochemical pathway is conserved anddifferent proteins perform comparable enzymatic functions in differentorganisms.

It is currently unknown whether other genes are involved in C. nicotianae pyridoxine biosynthesis in addition to PDX1 andPDX2. Because genomic analyses strongly suggest that PDX1 andPDX2 are alone in their organismal distribution, it seems unlikelythat there are other genes unique to this metabolic pathway. InB. subtilis and H. influenzae, the PDX1 and PDX2 homologues arein the same operon; however, the other flanking genes (e.g., seryl-tRNAsynthetase and cytidylate kinase 2) have no obvious relationshipto pyridoxine biosynthesis. It is possible that genes requiredfor other metabolic pathways play a dual role in C. nicotianaepyridoxine synthesis, as is found in E. coli (21, 37). Ifso, a mutation in such a gene may be lethal. In a screen of over11,000 UV-irradiated protoplasts regenerated on complete medium,only 5 pyridoxine auxotrophs were found (8, 16, 18), andall can be complemented to wild-type phenotype with either PDX1or PDX2. Mutagenesis of any other gene in the pathway, even ifalso required for some other function, should nevertheless causepyridoxine auxotrophy. All three yeast PDX2 homologues are foundno further than 449 bp from their PDX1 cohorts, and the N. crassaPDX1 and PDX2 homologues are also closely linked (3a), and weinitially attempted to isolate the C. nicotianae PDX2 by sequencingapproximately 5 kb of DNA flanking either side of PDX1. Our sequencingefforts, however, have led us to conclude that the two known pyridoxinegenes are unlinked in C. nicotianae, as they are in A. nidulans(http://www.gla.ac.uk/Acad/IBLS/molgen/aspergillus/). Gene clusteringcan be a useful tool for identifying pathway genes in fungi (15,22, 26), but will not have utility in thiscase.

Previous complementation studies suggested that increasing PDX1 copy number can at least partially compensate for PDX2 mutation.The two pdx2 auxotrophs, CS2 and CS7, were transformed with completeand truncated versions of PDX1 and also with vector alone. Onlyintact copies of PDX1 could restore either CS2 or CS7 to prototrophyand only at a greatly reduced rate (9, 10). Altogether, 11and 35% of CS7 and CS2 transformants, respectively, were complementedto pyridoxine prototrophy with PDX1, compared to an 82 to 100%complementation rate of three pdx1 mutant strains. This poorerrate of complementation and the lack of mutations in the CS2 andCS7 PDX1 genes led us to conclude these two strains were defectivein a different part of the same pyridoxinepathway.

In this work we performed the corollary experiment, rescue of pdx1 mutant strains by transformation with PDX2, and showedthat this reverse complementation does not work. Only a singlePDX2 transformant of the mutant strain CS8 (1.7%) showed any rescueof the mutant phenotype, and that strain could only grow to 45%of wild-type levels. It is possible that increased amounts ofPDX1 protein yield an enhanced level of substrate for partiallyfunctional PDX2 proteins. Alternatively, the two-hybrid analysisdescribed by Padilla et al. (23) indicates that PDX1 and PDX2proteins interact, suggesting that increased dosage of PDX1 stabilizesdefective PDX2 proteins. The exact function of these proteins,however, has yet to bedefined.

The sequence analysis of the pdx2 mutations in CS2 and CS7 revealed that both strains contain frameshift mutations leadingto the translation of severely truncated proteins. While the wild-typeprotein contains 278 amino acid residues, both mutant strainsare predicted to encode proteins of 117 amino acid residues. TheCS2 protein diverges from the wild type at amino acid 93, whilethe CS7 protein diverges at residue 38. Nevertheless, the conserveddomains that remain, one in the CS7 protein and two in the CS2protein, must be sufficient for partial function. Otherwise, transformationof these strains with PDX1 would not result in rescue of theirauxotrophy.

We have also found a response element for an AP-1-like transcription factor in both the C. nicotianae PDX1 and PDX2 genes.The yeast species S. cerevisiae, S. pombe, and Kluyveromyces lactisall encode AP-1-like transcription factors essential for theirresponse to oxidative stress (4, 34, 35), and in S. pombethe PDX1 homologue is upregulated by overexpression of its AP-1-liketranscription factor (M. W. Toone, personal communication). PDX1and PDX2 were originally discovered during a search for genesinvolved in resistance to an active-oxygen-generating phototoxin,cercosporin. In organisms as diverse as rubbertree and S. cerevisiae,PDX1 homologue expression has also been linked to the presenceof reactive oxygen species (5, 14, 21). The role of theAP-1 response pathway in cercosporin resistance is not yet clear.In yeast species, gene disruption and overexpression experimentshave been valuable in delineating the biological role of theirAP-1-like transcription factors. Comparable approaches shouldprove equally valuable in C. nicotianae to define the role ofpyridoxine in oxidative stressresponse.

	ACKNOWLEDGMENTS

We thank D. K. Wetzel for expert technical assistance and Margaret Werner-Washburne for providing clones for two of the yeastSNO genes and for the unpublished sequence of the N. crassa SNOgene.

This work was supported by grants from the National Science Foundation (MCB-9904746) and the USDA National Research InitiativeCompetitive Grants Program (96-35303-3204).

	FOOTNOTES

^* Corresponding author. Mailing address: Box 7616, Department of Plant Pathology, NCSU, Raleigh, NC 27695. Phone: (919) 515-6986.Fax: (919) 515-7716. E-mail: mel{at}unity.ncsu.edu.

REFERENCES

Top
Abstract
Introduction
Materials and Methods
Results
Discussion
References

1. Altschul, S. F., W. Gish, W. Miller, E. W. Myers, and D. J. Lipman. 1990. Basic local alignment search tool. J. Mol. Biol. 215:403-410[CrossRef][Medline].

2. Arst, H. N. J. 1997. New evidence for old detective work. Microbiology 143:1481-1482[Free Full Text].

3. Arst, H. N. J., A. G. Brownlee, and S. A. Cousen. 1982. Nitrogen metabolite repression in Aspergillus nidulans: a farewell to tamA? Curr. Genet. 6:245-257[CrossRef].

3a. Bean, L. E., W. H. Dvorachek, Jr., E. L. Braun, A. Errett, G. S. Saenz, M. D. Giles, M. Werner-Washburne, M. A. Nelson, and D. O. Natvig. 2001. Analysis of the pdx-1 (snz-1/sno-1) region of the Neurospora crassa genome. Correlation of pyridoxine-requiring phenotypes with mutations in two structural genes. Genetics 157:1067-1075[Abstract/Free Full Text].

4. Billard, P., H. Dumond, and M. Bolotin-Fukuhara. 1997. Characterization of an AP-1-like transcription factor that mediates an oxidative stress response in Kluyveromyces lactis. Mol. Gen. Genet. 257:62-70[CrossRef][Medline].

5. Braun, E. L., E. K. Fuge, P. A. Padilla, and M. Werner-Washburne. 1996. A stationary-phase gene in Sacchromyces cerevisiae is a member of a novel, highly conserved gene family. J. Bacteriol. 178:6865-6872[Abstract/Free Full Text].

6. Cane, D. E., S. Du, J. K. Robinson, Y. Hsing, and I. D. Spenser. 1999. Biosynthesis of vitamin B6: enzymatic conversion of 1-deoxy-D-xylulose-5-phosphate to pyridoxal phosphate. J. Am. Chem. Soc. 121:7722-7723[CrossRef].

7. Cane, D. E., Y. Hsiung, J. A. Cormish, J. K. Robinson, and I. D. Spenser. 1998. Biosynthesis of vitamin B6: the oxidation of 4-(phosphohydroxy)-L-threonine by PdxA. J. Am. Chem. Soc. 120:1936-1937[CrossRef].

8. Ehrenshaft, M., P. Bilski, M. Li, C. F. Chignell, and M. E. Daub. 1999. A highly conserved sequence is a novel gene involved in de novo vitamin B6 biosynthesis. Proc. Natl. Acad. Sci. USA 96:9374-9378[Abstract/Free Full Text].

9. Ehrenshaft, M., K. R. Chung, A. E. Jenns, and M. E. Daub. 1999. Functional characterization of SOR1, a gene required for resistance to photosensitizing toxins in the fungus Cercospora nicotianae. Curr. Genet. 34:478-485[CrossRef][Medline].

10. Ehrenshaft, M., A. E. Jenns, K. R. Chung, and M. E. Daub. 1998. SOR1, a gene required for photosensitizer and singlet oxygen resistance in Cercospora fungi is highly conserved in divergent organisms. Mol. Cell. 1:603-609[CrossRef][Medline].

11. Ehrenshaft, M., A. E. Jenns, and M. E. Daub. 1995. Targeted gene disruption of carotenoid biosynthesis in Cercospora nicotianae reveals no role for cartenoids in photosensitizer resistance. Mol. Plant-Microbe Interact. 8:569-575.

12. Galperin, M. Y., and E. V. Koonin. 1997. Sequence conservation of an exceptionally conserved operon suggests enzymes for a new link between histidine and purine biosynthesis. Mol. Microbiol. 24:443-445[CrossRef][Medline].

13. Hill, R. E., K. Himmeldirks, I. A. Kennedy, R. M. Pauloski, B. G. Sayer, E. Wolf, and I. D. Spenser. 1996. The biogenetic anatomy of vitamin B6: a ¹³C NMR investigation of the biosynthesis of pyridoxol in Escherichia coli. J. Biol. Chem. 271:30426-30435[Abstract/Free Full Text].

14. Hill, R. E., and I. D. Spenser. 1996. Biosynthesis of vitamin B6, p. 695-703. In F. C. Neidhardt, R. Curtiss, J. L. Ingraham, E. C. C. Lin, K. B. Low, B. Magasanik, W. S. Reznikoff, M. Riley, M. Schaechter, and H. E. Umbarger (ed.), Escherichia coli and Salmonella: cellular and molecular biology, 2nd ed, vol. 2. ASM Press, Washington, D.C.

15. Hull, E. P., P. M. Green, H. N. Arst, and C. Scazzocchio. 1989. Cloning and physical characterization of the L-proline catabolism gene cluster of Aspergillus nidulans. Mol. Microbiol. 3:553-559[CrossRef][Medline].

16. Jenns, A. E., and M. E. Daub. 1995. Characterization of mutants of Cercospora nicotianae sensitive to the toxin cercosporin. Phytopathology 85:906-912[CrossRef].

17. Jenns, A. E., M. E. Daub, and R. G. Upchurch. 1989. Regulation of cercosporin accumulation in culture by medium and temperature manipulation. Phytopathology 79:213-219[CrossRef].

18. Jenns, A. E., D. L. Scott, E. F. Bowden, and M. E. Daub. 1995. Isolation of mutants of the fungus Cercospora nicotianae altered in their response to singlet-oxygen-generating photosensitizers. Photochem. Photobiol. 61:488-493[CrossRef].

19. Koonin, E. V., R. L. Tatusov, and M. Y. Galperin. 1998. Beyond complete genomes: from sequence to structure and function. Curr. Opin. Struct. Biol. 8:355-363[CrossRef][Medline].

20. Laber, B., W. Maurer, S. Scharf, K. Stepusin, and F. S. Schmidt. 1999. Vitamin B₆ biosynthesis: formation of pyridoxine 5'-phosphate from 4-(phosphohydroxy)-L-threonine and 1-deoxyxylulose-5-phosphate by PdxA and PdxJ protein. FEBS Lett. 449:45-48[CrossRef][Medline].

21. Lam, H. M., and M. E. Winkler. 1990. Metabolic relationships between pyridoxine (vitamin B₆) and serine biosynthesis in Escherichia coli K-12. J. Bacteriol. 172:6518-6528[Abstract/Free Full Text].

22. Lamb, H. K., A. R. Hawkins, M. Smith, I. J. Harvey, G. Turner, and C. F. Roberts. 1990. Spatial and biological characterization of the complete quinic acid utilization gene cluster in Aspergillus nidulans. Mol. Gen. Genet. 223:17-23[CrossRef][Medline].

23. Mehdy, M. C., Y. K. Sharma, K. Sathasivan, and N. W. Bays. 1996. The role of activated oxygen species in plant disease resistance. Physiol. Plant. 98:365-374[CrossRef].

24. Osmani, A., G. May, and S. Osmani. 1999. The extremely conserved pyroA gene of Aspergillus nidulans is required for pyridoxine synthesis and is required indirectly for resistance to photosensitizers. J. Biol. Chem. 274:23565-23569[Abstract/Free Full Text].

25. Padilla, P. A., E. K. Fuge, M. E. Crawford, A. Errett, and M. Werner-Washburne. 1998. The highly conserved, coregulated SNO and SNZ gene families in Saccharomyces cerevisiae respond to nutrient limitation. J. Bacteriol. 180:5718-5726[Abstract/Free Full Text].

26. Payne, G. A., and M. P. Brown. 1998. Genetics and physiology of aflatoxin biosynthesis. Annu. Rev. Phytopathol. 36:329-362[CrossRef][Medline].

27. Rose, T. M., E. R. Schultz, J. G. Henikoff, S. Pietrokovski, C. M. McCallum, and S. Henikoff. 1998. Consensus-degenerate hybrid oligonucleotide primers for amplification of distantly-related sequences. Nucleic Acids Res. 26:1628-1635[Abstract/Free Full Text].

28. Straubinger, B., E. Straubinger, S. Wirsel, G. Turgeon, and O. C. Yoder. 1992. Versatile fungal transformation vectors carrying the selectable bar gene of Streptomyces hygroscopicus. Fungal Genet. Newsl. 39:82-83.

29. Tatusov, R. L., M. Y. Galperin, D. A. Natale, and E. V. Koonin. 2000. The COG database: a tool for genome-scale analysis of protein functions and evolution. Nucleic Acids Res. 28:33-36[Abstract/Free Full Text].

30. Tatusov, R. L., E. V. Koonin, and D. J. Lipman. 1997. A genomic perspective of protein families. Science 278:631-637[Abstract/Free Full Text].

31. Tazoe, M., K. Ichikawa, and T. Hoshino. 2000. Biosynthesis of vitamin B₆ in Rhizobium. J. Biol. Chem. 275:11300-11305[Abstract/Free Full Text].

32. Tazuya, K., Y. Adachi, K. Masuda, K. Yamada, and H. Kumaoka. 1995. Origin of the nitrogen atom of pyridoxine in Saccharomyces cerevisiae. Biochim. Biophys. Acta 1244:113-116[Medline].

33. Thompson, J., D. Higgins, and T. Gibson. 1994. CLUSTAL W: improving the sensitivity of progressive multiple sequence alignment through sequence weighting, position-specific gap penalties and weight matrix choice. Nucleic Acids Res. 22:4673-4680[Abstract/Free Full Text].

34. Toda, T., M. Shimanuki, and M. Yanagida. 1991. Fission yeast genes that confer resistance to staurosporine encode an AP-1-like transcription factor and a protein kinase related to the mammalian ERK1/MAP2 and budding yeast FUS3 and KSS1 kinases. Genes Dev. 5:60-73[Abstract/Free Full Text].

35. Toone, W. M., and N. Jones. 1999. AP-1 transcription factors in yeast. Curr. Opin. Genet. Dev. 9:55-61[CrossRef][Medline].

36. Woloshuk, C. P., E. R. Seip, and G. A. Payne. 1989. Genetic transformation system for the aflatoxin-producing fungus Aspergillus flavus. Appl. Environ. Microbiol. 55:86-90[Abstract/Free Full Text].

37. Yang, Y., G. Zhao, T. K. Man, and M. E. Winkler. 1998. Involvement of the gapA-and epd (gapB)-encoded dehydrogenases in pyridoxal 5'-phosphate coenzyme biosynthesis in Escherichia coli K-12. J. Bacteriol. 180:4294-4299[Abstract/Free Full Text].

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1.	Altschul, S. F., W. Gish, W. Miller, E. W. Myers, and D. J. Lipman. 1990. Basic local alignment search tool. J. Mol. Biol. 215:403-410[CrossRef][Medline].
2.	Arst, H. N. J. 1997. New evidence for old detective work. Microbiology 143:1481-1482[Free Full Text].
3.	Arst, H. N. J., A. G. Brownlee, and S. A. Cousen. 1982. Nitrogen metabolite repression in Aspergillus nidulans: a farewell to tamA? Curr. Genet. 6:245-257[CrossRef].
3a.	Bean, L. E., W. H. Dvorachek, Jr., E. L. Braun, A. Errett, G. S. Saenz, M. D. Giles, M. Werner-Washburne, M. A. Nelson, and D. O. Natvig. 2001. Analysis of the pdx-1 (snz-1/sno-1) region of the Neurospora crassa genome. Correlation of pyridoxine-requiring phenotypes with mutations in two structural genes. Genetics 157:1067-1075[Abstract/Free Full Text].
4.	Billard, P., H. Dumond, and M. Bolotin-Fukuhara. 1997. Characterization of an AP-1-like transcription factor that mediates an oxidative stress response in Kluyveromyces lactis. Mol. Gen. Genet. 257:62-70[CrossRef][Medline].
5.	Braun, E. L., E. K. Fuge, P. A. Padilla, and M. Werner-Washburne. 1996. A stationary-phase gene in Sacchromyces cerevisiae is a member of a novel, highly conserved gene family. J. Bacteriol. 178:6865-6872[Abstract/Free Full Text].
6.	Cane, D. E., S. Du, J. K. Robinson, Y. Hsing, and I. D. Spenser. 1999. Biosynthesis of vitamin B6: enzymatic conversion of 1-deoxy-D-xylulose-5-phosphate to pyridoxal phosphate. J. Am. Chem. Soc. 121:7722-7723[CrossRef].
7.	Cane, D. E., Y. Hsiung, J. A. Cormish, J. K. Robinson, and I. D. Spenser. 1998. Biosynthesis of vitamin B6: the oxidation of 4-(phosphohydroxy)-L-threonine by PdxA. J. Am. Chem. Soc. 120:1936-1937[CrossRef].
8.	Ehrenshaft, M., P. Bilski, M. Li, C. F. Chignell, and M. E. Daub. 1999. A highly conserved sequence is a novel gene involved in de novo vitamin B6 biosynthesis. Proc. Natl. Acad. Sci. USA 96:9374-9378[Abstract/Free Full Text].
9.	Ehrenshaft, M., K. R. Chung, A. E. Jenns, and M. E. Daub. 1999. Functional characterization of SOR1, a gene required for resistance to photosensitizing toxins in the fungus Cercospora nicotianae. Curr. Genet. 34:478-485[CrossRef][Medline].
10.	Ehrenshaft, M., A. E. Jenns, K. R. Chung, and M. E. Daub. 1998. SOR1, a gene required for photosensitizer and singlet oxygen resistance in Cercospora fungi is highly conserved in divergent organisms. Mol. Cell. 1:603-609[CrossRef][Medline].
11.	Ehrenshaft, M., A. E. Jenns, and M. E. Daub. 1995. Targeted gene disruption of carotenoid biosynthesis in Cercospora nicotianae reveals no role for cartenoids in photosensitizer resistance. Mol. Plant-Microbe Interact. 8:569-575.
12.	Galperin, M. Y., and E. V. Koonin. 1997. Sequence conservation of an exceptionally conserved operon suggests enzymes for a new link between histidine and purine biosynthesis. Mol. Microbiol. 24:443-445[CrossRef][Medline].
13.	Hill, R. E., K. Himmeldirks, I. A. Kennedy, R. M. Pauloski, B. G. Sayer, E. Wolf, and I. D. Spenser. 1996. The biogenetic anatomy of vitamin B6: a ¹³C NMR investigation of the biosynthesis of pyridoxol in Escherichia coli. J. Biol. Chem. 271:30426-30435[Abstract/Free Full Text].
14.	Hill, R. E., and I. D. Spenser. 1996. Biosynthesis of vitamin B6, p. 695-703. In F. C. Neidhardt, R. Curtiss, J. L. Ingraham, E. C. C. Lin, K. B. Low, B. Magasanik, W. S. Reznikoff, M. Riley, M. Schaechter, and H. E. Umbarger (ed.), Escherichia coli and Salmonella: cellular and molecular biology, 2nd ed, vol. 2. ASM Press, Washington, D.C.
15.	Hull, E. P., P. M. Green, H. N. Arst, and C. Scazzocchio. 1989. Cloning and physical characterization of the L-proline catabolism gene cluster of Aspergillus nidulans. Mol. Microbiol. 3:553-559[CrossRef][Medline].
16.	Jenns, A. E., and M. E. Daub. 1995. Characterization of mutants of Cercospora nicotianae sensitive to the toxin cercosporin. Phytopathology 85:906-912[CrossRef].
17.	Jenns, A. E., M. E. Daub, and R. G. Upchurch. 1989. Regulation of cercosporin accumulation in culture by medium and temperature manipulation. Phytopathology 79:213-219[CrossRef].
18.	Jenns, A. E., D. L. Scott, E. F. Bowden, and M. E. Daub. 1995. Isolation of mutants of the fungus Cercospora nicotianae altered in their response to singlet-oxygen-generating photosensitizers. Photochem. Photobiol. 61:488-493[CrossRef].
19.	Koonin, E. V., R. L. Tatusov, and M. Y. Galperin. 1998. Beyond complete genomes: from sequence to structure and function. Curr. Opin. Struct. Biol. 8:355-363[CrossRef][Medline].
20.	Laber, B., W. Maurer, S. Scharf, K. Stepusin, and F. S. Schmidt. 1999. Vitamin B₆ biosynthesis: formation of pyridoxine 5'-phosphate from 4-(phosphohydroxy)-L-threonine and 1-deoxyxylulose-5-phosphate by PdxA and PdxJ protein. FEBS Lett. 449:45-48[CrossRef][Medline].
21.	Lam, H. M., and M. E. Winkler. 1990. Metabolic relationships between pyridoxine (vitamin B₆) and serine biosynthesis in Escherichia coli K-12. J. Bacteriol. 172:6518-6528[Abstract/Free Full Text].
22.	Lamb, H. K., A. R. Hawkins, M. Smith, I. J. Harvey, G. Turner, and C. F. Roberts. 1990. Spatial and biological characterization of the complete quinic acid utilization gene cluster in Aspergillus nidulans. Mol. Gen. Genet. 223:17-23[CrossRef][Medline].
23.	Mehdy, M. C., Y. K. Sharma, K. Sathasivan, and N. W. Bays. 1996. The role of activated oxygen species in plant disease resistance. Physiol. Plant. 98:365-374[CrossRef].
24.	Osmani, A., G. May, and S. Osmani. 1999. The extremely conserved pyroA gene of Aspergillus nidulans is required for pyridoxine synthesis and is required indirectly for resistance to photosensitizers. J. Biol. Chem. 274:23565-23569[Abstract/Free Full Text].
25.	Padilla, P. A., E. K. Fuge, M. E. Crawford, A. Errett, and M. Werner-Washburne. 1998. The highly conserved, coregulated SNO and SNZ gene families in Saccharomyces cerevisiae respond to nutrient limitation. J. Bacteriol. 180:5718-5726[Abstract/Free Full Text].
26.	Payne, G. A., and M. P. Brown. 1998. Genetics and physiology of aflatoxin biosynthesis. Annu. Rev. Phytopathol. 36:329-362[CrossRef][Medline].
27.	Rose, T. M., E. R. Schultz, J. G. Henikoff, S. Pietrokovski, C. M. McCallum, and S. Henikoff. 1998. Consensus-degenerate hybrid oligonucleotide primers for amplification of distantly-related sequences. Nucleic Acids Res. 26:1628-1635[Abstract/Free Full Text].
28.	Straubinger, B., E. Straubinger, S. Wirsel, G. Turgeon, and O. C. Yoder. 1992. Versatile fungal transformation vectors carrying the selectable bar gene of Streptomyces hygroscopicus. Fungal Genet. Newsl. 39:82-83.
29.	Tatusov, R. L., M. Y. Galperin, D. A. Natale, and E. V. Koonin. 2000. The COG database: a tool for genome-scale analysis of protein functions and evolution. Nucleic Acids Res. 28:33-36[Abstract/Free Full Text].
30.	Tatusov, R. L., E. V. Koonin, and D. J. Lipman. 1997. A genomic perspective of protein families. Science 278:631-637[Abstract/Free Full Text].
31.	Tazoe, M., K. Ichikawa, and T. Hoshino. 2000. Biosynthesis of vitamin B₆ in Rhizobium. J. Biol. Chem. 275:11300-11305[Abstract/Free Full Text].
32.	Tazuya, K., Y. Adachi, K. Masuda, K. Yamada, and H. Kumaoka. 1995. Origin of the nitrogen atom of pyridoxine in Saccharomyces cerevisiae. Biochim. Biophys. Acta 1244:113-116[Medline].
33.	Thompson, J., D. Higgins, and T. Gibson. 1994. CLUSTAL W: improving the sensitivity of progressive multiple sequence alignment through sequence weighting, position-specific gap penalties and weight matrix choice. Nucleic Acids Res. 22:4673-4680[Abstract/Free Full Text].
34.	Toda, T., M. Shimanuki, and M. Yanagida. 1991. Fission yeast genes that confer resistance to staurosporine encode an AP-1-like transcription factor and a protein kinase related to the mammalian ERK1/MAP2 and budding yeast FUS3 and KSS1 kinases. Genes Dev. 5:60-73[Abstract/Free Full Text].
35.	Toone, W. M., and N. Jones. 1999. AP-1 transcription factors in yeast. Curr. Opin. Genet. Dev. 9:55-61[CrossRef][Medline].
36.	Woloshuk, C. P., E. R. Seip, and G. A. Payne. 1989. Genetic transformation system for the aflatoxin-producing fungus Aspergillus flavus. Appl. Environ. Microbiol. 55:86-90[Abstract/Free Full Text].
37.	Yang, Y., G. Zhao, T. K. Man, and M. E. Winkler. 1998. Involvement of the gapA-and epd (gapB)-encoded dehydrogenases in pyridoxal 5'-phosphate coenzyme biosynthesis in Escherichia coli K-12. J. Bacteriol. 180:4294-4299[Abstract/Free Full Text].