Alkaptonuria (AKU) occupies a unique place in the history of human genetics because it was the first disease to be interpreted as a mendelian recessive trait by Garrod in 1902. Alkaptonuria is a rare metabolic disorder resulting from loss of homogentisate 1,2 dioxygenase (HGO) activity. Affected individuals accumulate large quantities of homogentisic acid, an intermediary product of the catabolism of tyrosine and phenylalanine, which darkens the urine and deposits in connective tissues causing a debilitating arthritis. Here we report the cloning of the human HGO gene and establish that it is the AKU gene. We show that HGO maps to the same location described for AKU, illustrate that HGO harbours missense mutations that cosegregate with the disease, and provide biochemical evidence that at least one of these missense mutations is a loss-of-function mutation.
We report here the first characterization of a gene encoding a homogentisate dioxygenase, the Aspergillus nidulans hmgA gene. The HmgA protein catalyzes an essential step in phenylalanine catabolism, and disruption of the gene results in accumulation of homogentisate in broths containing phenylalanine. hmgA putatively encodes a 448-residue polypeptide (M r ؍ 50,168) containing 21 histidine and 23 tyrosine residues. This polypeptide has been expressed in Escherichia coli as a fusion to glutathione S-transferase, and the affinity-purified protein has homogentisate dioxygenase activity.A. nidulans, an ascomycete amenable to classical and reverse genetic analysis, is a good metabolic model to study inborn errors in human Phe catabolism. One such disease, alkaptonuria, was the first human inborn error recognized (Garrod, A. E. (1902) Lancet 2, 1616 -1620) and results from loss of homogentisate dioxygenase. Here we take advantage of the high degree of conservation between the amino acid sequences of the fungal and higher eukaryote enzymes of this pathway to identify expressed sequence tags encoding human and plant homologues of HmgA. This is a significant advance in characterizing the genetic defect(s) of alkaptonuria and illustrates the usefulness of our fungal model.The physiologically versatile filamentous ascomycete Aspergillus nidulans is able to grow on Phe or PhAc 1 as the sole carbon source. The A. nidulans Phe catabolic pathway is notably similar to its human counterpart (Ferná ndez-Cañ ón and Peñ alva, 1995). As in humans ( Fig. 1), Phe is degraded to homogentisate (2,5-dihydroxy-PhAc). The aromatic ring is then cleaved by homogentisate dioxygenase to yield, after an isomerization step, fumarylacetoacetate, which is split by fumarylacetoacetate hydrolase into fumarate and acetoacetate (see Fig. 1). Aspergillus can also catabolize PhAc through homogentisate after two sequential hydroxylation reactions in the aromatic ring.2 This PhAc pathway is absent in humans. Humans are very sensitive to defects in Phe catabolism. Loss-of-function mutations in structural genes of this pathway cause different metabolic diseases. Alkaptonuria is one such disease, resulting from loss of homogentisate dioxygenase (EC 1.13.11.15) (La Du et al., 1958). This moderately disabling disease, whose main clinical features are darkening of the urine, pigmentation of cartilages, and arthritis in adults, was the first inborn error of metabolism to be described (Garrod, 1902). However, the gene encoding homogentisate dioxygenase has not been characterized from humans or any other organism (see McKusick (1994)). Therefore, definitive evidence that the disease results from a loss-of-function mutation in this gene has not yet been obtained. Type I tyrosinaemia, resulting from fumarylacetoacetate hydrolase deficiency, is a different defect in human Phe catabolism with severe consequences. Our characterization of the fahA gene, encoding A. nidulans fumarylacetoacetate hydrolase, showed 47% identity at the amino acid level with its human hom...
We have previously used Aspergillus nidulans as a fungal model for human phenylalanine catabolism. This model was crucial for our characterization of the human gene involved in alcaptonuria. We use here an identical approach to characterize at the cDNA level the human gene for maleylacetoacetate isomerase (MAAI, EC 5.2.1.2), the only as yet unidentified structural gene of the phenylalanine catabolic pathway.We report here the first characterization of a gene encoding a MAAI enzyme from any organism, the A. nidulans maiA gene. maiA disruption prevents growth on phenylalanine (Phe) and phenylacetate and results in the absence of MAAI activity in vitro and Phe toxicity. The MaiA protein shows strong amino acid sequence identity to glutathione S-transferases and has MAAI activity when expressed in Escherichia coli. maiA is clustered with fahA and hmgA, the genes encoding the two other enzymes of the common part of the Phe/phenylacetate pathways.Based on the high amino acid sequence conservation existing between other homologous A. nidulans and human enzymes of this pathway, we used the MaiA sequence in data base searches to identify human expressed sequence tags encoding its putative homologues. Four such cDNAs were sequenced and shown to be encoded by the same gene. They encode a protein with 45% sequence identity to MaiA, which showed MAAI activity when expressed in E. coli.Human MAAI deficiency would presumably cause tyrosinemia that would be characterized by the absence of succinylacetone, the diagnostic compound resulting from fumarylacetoacetate hydrolase deficiency in humans and fungi. Culture supernatants of an A. nidulans strain disrupted for maiA are succinylacetone-negative but specifically contain cis and/or trans isomers of 2,4-dioxohept-2-enoic acid. We suggest that this compound(s) might be diagnostic for human MAAI deficiency.
In mammals, the catabolic pathway of phenylalanine and tyrosine is found in liver (hepatocytes) and kidney (proximal tubular cells). There are well-described human diseases associated with deficiencies of all enzymes in this pathway except for maleylacetoacetate isomerase (MAAI), which converts maleylacetoacetate (MAA) to fumarylacetoacetate (FAA). MAAI is also known as glutathione transferase zeta (GSTZ1). Here, we describe the phenotype of mice with a targeted deletion of the MAAI (GSTZ1) gene. MAAI-deficient mice accumulated FAA and succinylacetone in urine but appeared otherwise healthy. This observation suggested that either accumulating MAA is not toxic or an alternate pathway for MAA metabolism exists. A complete redundancy of MAAI could be ruled out because substrate overload of the tyrosine catabolic pathway (administration of homogentisic acid, phenylalanine, or tyrosine) resulted in renal and hepatic damage. However, evidence for a partial bypass of MAAI activity was also found. Mice doubly mutant for MAAI and fumarylacetoacetate hydrolase (FAH) died rapidly on a normal diet, indicating that MAA could be isomerized to FAA in the absence of MAAI. Double mutants showed predominant renal injury, indicating that this organ is the primary target for the accumulated compound(s) resulting from MAAI deficiency. A glutathione-mediated isomerization of MAA to FAA independent of MAAI enzyme was demonstrated in vitro. This nonenzymatic bypass is likely responsible for the lack of a phenotype in nonstressed MAAI mutant mice.
Type I hereditary tyrosinaemia (HT1) is a severe human inborn disease resulting from loss of fumarylacetoacetate hydrolase (Fah). Homozygous disruption of the gene encoding Fah in mice causes neonatal lethality, seriously limiting use of this animal as a model. We report here that fahA, the gene encoding Fah in the fungus AspergiUlus nidulans, encodes a polypeptide showing 47.1% identity to its human homologue.fahA disruption results in secretion of succinylacetone (a diagnostic compound for human type I tyrosinaemia) and phenylalanine toxicity. We have isolated spontaneous suppressor mutations preventing this toxicity, presumably representing loss-of-function mutations in genes acting upstream offahA in the phenylalanine catabolic pathway. Analysis of a class of these mutations demonstrates that loss of homogentisate dioxygenase (leading to alkaptonuria in humans) prevents the effects of a Fah deficiency. Our results strongly suggest human homogentisate dioxygenase as a target for HT1 therapy and illustrate the usefulness ofthis fungus as an alternative to animal models for certain aspects of human metabolic diseases.
Aspergillus nidulans utilizes phenylacetate as a carbon source via homogentisate, which is degraded to fumarate and acetoacetate. Mutational evidence strongly suggested that phenylacetate is converted to homogentisate through two sequential hydroxylating reactions in positions 2 and 5 of the aromatic ring. Using cDNA substraction techniques, we have characterized a gene, denoted phacA, whose transcription is strongly induced by phenylacetate and which putatively encodes a cytochrome P450 protein. A disrupted phacA strain does not grow on phenylacetate but grows on 2-hydroxy-or 2,5-dihydroxyphenylacetate. Microsomal extracts of the disrupted strain are deficient in the NADPH-dependent conversion of phenylacetate to 2-hydroxyphenylacetate. We conclude that PhacA catalyzes the ortho-hydroxylation of phenylacetate, the first step of A. nidulans phenylacetate catabolism. The involvement of a P450 enzyme in the ortho-hydroxylation of a monoaromatic compound has no precedent. In addition, PhacA shows substantial sequence divergence with known cytochromes P450 and defines a new family of these enzymes, suggesting that saprophytic fungi may represent a source of novel cytochromes P450.Phenylacetate is a precursor for benzylpenicillin production. phacA disruption increases penicillin production 3-5-fold, indicating that catabolism competes with antibiotic biosynthesis for phenylacetate and strongly suggesting strategies for Penicillium chrysogenum strain improvement by reverse genetics.Aerobic degradation of aromatic hydrocarbons by microbes involves the action of oxygenases (enzymes that incorporate one or two atoms from dioxygen into substrates) acting at two different levels in specific catabolic pathways (1, 2). First, oxygenase enzymes acting at the upstream segment of these pathways incorporate one (monooxygenases, aromatic ring hydroxylases) or two (aromatic ring dioxygenases) oxygen atoms into the aromatic substrate as hydroxyl groups, preparing the ring for a subsequent ring-opening step. In this second step, the dihydroxylated aromatic ring is opened by ring-cleavage dioxygenases.Monooxygenases are a mechanistically diverse group of enzymes (1) including, for example, flavoproteins such as p-hydroxybenzoate hydroxylase (3), multicomponent enzymes such as Pseudomonas mendocina toluene 4-monoxygenase, in which one of the terminal hydroxylase polypeptides contains a binuclear iron cluster (4), or heme-containing cytochrome P450 systems. Monooxygenases of the cytochrome P450 superfamily (5, 6) are widely distributed among living organisms and catalyze a multiplicity of biosynthetic and catabolic reactions, usually with narrow substrate specificity, including the hydroxylation of a variety of lipophylic drugs.In common with other saprophytic microbes, the genetically amenable, obligate aerobic fungus Aspergillus nidulans shows notable metabolic versatility. For example, it can use the aromatic hydrocarbon compound phenylacetate (PhAc) 1 as sole carbon source. Despite the abundant information available on the cataboli...
The single-copy pahA gene from Penicillium chrysogenum encodes a phenylacetate 2-hydroxylase that catalyzes the first step of phenylacetate catabolism, an oxidative route that decreases the precursor availability for penicillin G biosynthesis. PahA protein is homologous to cytochrome P450 monooxygenases involved in the detoxification of xenobiotic compounds, with 84% identity to the Aspergillus nidulans homologue PhacA. Expression level of pahA displays an inverse correlation with the penicillin productivity of the strain and is subject to induction by phenylacetic acid. Gene expression studies have revealed a reduced oxidative activity of the protein encoded by pahA genes from penicillin-overproducing strains of P. chrysogenum compared to the activity conferred by phacA of A. nidulans. Sequencing and expression of wild-type pahA from P. chrysogenum NRRL 1951 revealed that an L181F mutation was responsible for the reduced function in present industrial strains. The mutation has been tracked down to Wisconsin 49-133, a mutant obtained at the Department of Botany of the University of Wisconsin in 1949, at the beginning of the development of the Wisconsin family of strains.
Alkaptonuria (AKU; McKusick No. 203500), a rare hereditary disorder of the phenylalanine catabolism, was the first disease to be interpreted as an inborn error of metabolism (A. E. Garrod, 1902, Lancet 2: 1616-1620). AKU patients are deficient for homogentisate 1,2-dioxygenase (HGO; EC 1.13.11.5). This enzymatic deficiency causes homogentisic aciduria, ochronosis, and arthritis. Recently we cloned the human HGO gene and showed that AKU patients carry two copies of a loss-of-function HGO allele. Here we describe the complete nucleotide sequence of the human HGO gene and the identification of its promoter region. The human HGO gene spans 54,363 bp and codes for a 1715-nt-long transcript that is split into 14 exons ranging from 35 to 360 bp. The HGO introns, 605 to 17,687 bp in length, contain representatives of the major classes of repetitive elements, including several simple sequence repeats (SSR). Two of these SSRs, a (CT)n repeat in intron 4 and a (CA)n repeat in intron 13, were found to be polymorphic in a Spanish population sample. The HGO transcription start site was determined by primer extension. We report that sequences from -1074 to +89 bp (relative to the HGO transcription start site) are sufficient to promote transcription of a CAT reporter gene in human liver cells and that this fragment contains putative binding sites for liver-enriched transcription factors that might be involved in the regulation of HGO expression in liver.
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