The a-aminoadipate pathway for the biosynthesis of lysine is present only in fungi and euglena. Until now, this unique metabolic pathway has never been investigated in the opportunistic fungal pathogens Candida albicans, Cryptococcus neoformans, and AsperiUfsumigatus. Five of the eight enzymes (homocitrate synthase, homoisocitrate dehydrogenase, o-aminoadipate reductase, saccharopine reductase, and saccharopine dehydrogenase) of the a-aminoadipate pathway and glucose-6-phosphate dehydrogenase, a glycolytic enzyme used as a control, were demonstrated in wild-type cells of these organisms. All enzymes were present in Saccharomyces cerevisiae and the pathogenic organisms except C. neoformans 32608 serotype C, which exhibited no saccharopine reductase activity. The levels of enzyme activity varied considerably from strain to strain. Variation among organisms was also observed for the control enzyme. Among the pathogens, C. albicans exhibited much higher homocitrate synthase, homoisocitrate dehydrogenase, and a-aminoadipate reductase activities. Seven lysine auxotrophs of C. albicans and one of Candida tropicalis were characterized biochemically to determine the biochemical blocks and gene-enzyme relationships. Growth responses to c-aminoadipate-and lysine-supplemented media, accumulation of oc-aminoadipate semialdehyde, and the lack of enzyme activity revealed that five of the mutants (WA104, WA153, WC7-1-3, WD1-31-2, and A5155) were blocked at the a-aminoadipate reductase step, two (STN57 and WD1-3-6) were blocked at the saccharopine dehydrogenase step, and the C. tropicalis mutant (X-16) was blocked at the saccharopine reductase step. The cloned LYS] gene of C. albicans in the recombinant plasmid YpB1078 complemented saccharopine dehydrogenase (lysl) mutants of S. cerevistae and C. albicans. The Lysl+ transformed strains exhibited significant saccharopine dehydrogenase activity in comparison with untransformed mutants. The cloned LYS] gene has been localized on a 1.8-kb Hindm DNA insert of the recombinant plasmid YpB1041RG1. These results established the gene-enzyme relationship in the second half of the a-aminoadipate pathway. The presence of this unique pathway in the pathogenic fungi could be useful for their rapid detection and control.
The unique alpha-aminoadipate pathway for lysine biosynthesis is present only in fungi and involves eight enzyme steps. alpha-Aminoadipate semialdehyde dehydrogenase, commonly called alpha-aminoadipate reductase (AAR), catalyzes the conversion of alpha-aminoadipic acid to alpha-aminoadipic semialdehyde by a novel mechanism. Two genes, LYS2 and LYS5, encode the heterodimeric enzyme in Saccharomyces cerevisiae. The LYS2 gene of Candida albicans was shown to be contained in the 4.8-kb insert of the plasmid pCaLYS2. This plasmid complemented lys2 mutants of both S. cerevisiae and C. albicans. The S. cerevisiae and C. albicans Lys2(+) transformants exhibited 138% and 160% of wild-type AAR activity, respectively. The DNA-sequence analysis of the 4.8-kb region in plasmid pCaLYS2 and a PCR product from genomic DNA which overlapped with the 4.8-kb insert revealed a continuous ORF of 4173 nucleotides encoding 1391 amino-acid residues. The C. albicans LYS2 ORF exhibited 63.0% identity at the nucleotide level and 56.2% identity at the amino-acid level to the LYS2 gene of S. cerevisiae. The ORF is preceded by consensus sequences for the TATA-, CAAT- and GCN4-box elements. An S. cerevesiae-type transcription termination signal is seen in the 3' flanking region. The deduced amino-acid sequence revealed a motif for an AMP-binding site and also the highly conserved core sequences common to peptide antibiotic synthetases. The LYS2 mRNA and alpha-aminoadipate reductase activity were repressed to a higher level in YEPD-grown cells than in cells grown in the presence of lysine or minimal medium. Additionally, AAR was shown to be feedback-inhibited by lysine and the lysine analog, thialysine. The results of the present report reveal the molecular characteristics of the LYS2 gene of C. albicans, its homology to peptide antibiotic synthetases, its divergence from the LYS2 gene of S. cerevisiae, and the regulation of AAR in C. albicans.
Fungi have evolved a unique alpha-amino-adipate pathway for lysine biosynthesis. The fungal-specific enzyme homoaconitate hydratase from this pathway is moderately similar to the aconitase-family proteins from a diverse array of taxonomic groups, which have varying modes of obtaining lysine. We have used the similarity of homoaconitate hydratase to isopropylmalate isomerase (serving in leucine biosynthesis), aconitase (from the tricarboxylic acid cycle), and iron-responsive element binding proteins (cytosolic aconitase) from fungi and other eukaryotes, eubacteria, and archaea to evaluate possible evolutionary scenarios for the origin of this pathway. Refined sequence alignments show that aconitase active site residues are highly conserved in each of the enzymes, and intervening sequence sites are quite dissimilar. This pattern suggests strong purifying selection has acted to preserve the aconitase active site residues for a common catalytic mechanism; numerous other substitutions occur due to adaptive evolution or simply lack of functional constraint. We hypothesize that the similarities are the remnants of an ancestral gene duplication, which may not have occurred within the fungal lineage. Maximum likelihood, neighbor joining, and maximum parsimony phylogenetic comparisons show that the alpha-aminoadipate pathway enzyme is an outgroup to all aconitase family proteins for which sequence is currently available.
The ␣-aminoadipate pathway for lysine biosynthesis is present only in fungi. The ␣-aminoadipate reductase (AAR) of this pathway catalyzes the conversion of ␣-aminoadipic acid to ␣-aminoadipic-␦-semialdehyde by a complex mechanism involving two gene products, Lys2p and Lys5p. The LYS2 and LYS5 genes encode, respectively, a 155-kDa inactive AAR and a 30-kDa phosphopantetheinyl transferase (PPTase) which transfers a phosphopantetheinyl group from coenzyme A (CoA) to Lys2p for the activation of Lys2p and AAR activity. In the present investigation, we have confirmed the posttranslational activation of the 150-kDa Lys2p of Candida albicans, a pathogenic yeast, in the presence of CoA and C. albicans lys2 mutant (CLD2) extract as a source of PPTase (Lys5p). The recombinant Lys2p or CLD2 mutant extract exhibited no AAR activity with or without CoA. However, the recombinant 150-kDa Lys2p, when incubated with CLD2 extract and CoA, exhibited significant AAR activity compared to that of wild-type C. albicans CAI4 extract. The PPTase in the CLD2 extract was required only for the activation of Lys2p and not for AAR reaction. Site-directed mutational analysis of G882 and S884 of the Lys2p activation domain (LGGHSI) revealed no AAR activity, indicating that these two amino acids are essential for the activation. Replacement of other amino acid residues in the domain resulted in partial or full AAR activity. These results demonstrate the posttranslational activation and the requirement of specific amino acid residues in the activation domain of the AAR of C. albicans.
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