Functional analysis of MCCA and MCCB mutations causing methylcrotonylglycinuria.

Methylcrotonylglycinuria (MCG; MIM 210200) is an autosomal recessive inherited human disorder caused by the deficiency of 3-methylcrotonyl-CoA carboxylase (MCC, E.C.6.4.1.4), involved in leucine catabolism. This mitochondrial enzyme is one of the four biotin-dependent carboxylases known in humans. MCC is composed of two different types of subunits, alpha and beta, encoded by the nuclear genes MCCA and MCCB, respectively, recently cloned and characterized. Several mutations have been identified, in both genes, the majority are missense mutations along with splicing mutations and small insertions/deletions. We have expressed four missense mutations, two MCCA and two MCCB mapping to highly evolutionarily conserved residues, by transient transfection of SV40-transformed deficient fibroblasts in order to confirm their pathogenic effect. All the missense mutations expressed resulted in null or severely diminished MCC activity providing direct evidence that they are disease-causing ones. The MCCA mutations have been analysed in the context of three-dimensional structural information modelling the changes in the crystallized biotin carboxylase subunit of the Escherichia coli acetyl-CoA carboxylase. The apparent severity of all the MCC mutations contrasts with the variety of the clinical phenotypes suggesting that there are other cellular and metabolic unknown factors that affect the resulting phenotype.

Reduced function of a phenylacetate-oxidizing cytochrome p450 caused strong genetic improvement in early phylogeny of penicillin-producing strains.

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.

A fungal perspective on human inborn errors of metabolism: alkaptonuria and beyond.

Crucial for the establishment and development of biochemical genetics as a self-standing discipline was Beadle and Tatum's choice of Neurospora crassa as experimental organism some 60 years ago. Although Garrod's insights on biochemical genetics and his astonishingly modern concepts of biochemical individuality and susceptibility to disease had been ignored by their contemporaries, Beadle acknowledged on several occasions how close Garrod had come to the "one-gene-one-enzyme" hypothesis. In an unexpected turn of events, several genes involved in human inborn errors of metabolism, including the gene for Garrod's favorite disease, alkaptonuria, have been characterized by exploitation of the experimental advantages of another mold, Aspergillus nidulans, which shares with N. crassa the experimental advantages that prompted pioneers of biochemical genetics to use them: rapid growth, facile genetic manipulation, and an environment (the composition of the growth medium) that can be manipulated à la carte.

The molecular basis of 3-methylcrotonylglycinuria, a disorder of leucine catabolism.

3-Methylcrotonylglycinuria is an inborn error of leucine catabolism and has a recessive pattern of inheritance that results from the deficiency of 3-methylcrotonyl-CoA carboxylase (MCC). The introduction of tandem mass spectrometry in newborn screening has revealed an unexpectedly high incidence of this disorder, which, in certain areas, appears to be the most frequent organic aciduria. MCC, an heteromeric enzyme consisting of alpha (biotin-containing) and beta subunits, is the only one of the four biotin-dependent carboxylases known in humans that has genes that have not yet been characterized, precluding molecular studies of this disease. Here we report the characterization, at the genomic level and at the cDNA level, of both the MCCA gene and the MCCB gene, encoding the MCC alpha and MCC beta subunits, respectively. The 19-exon MCCA gene maps to 3q25-27 and encodes a 725-residue protein with a biotin attachment site; the 17-exon MCCB gene maps to 5q12-q13 and encodes a 563-residue polypeptide. We show that disease-causing mutations can be classified into two complementation groups, denoted "CGA" and "CGB." We detected two MCCA missense mutations in CGA patients, one of which leads to absence of biotinylated MCC alpha. Two MCCB missense mutations and one splicing defect mutation leading to early MCC beta truncation were found in CGB patients. A fourth MCCB mutation also leading to early MCC beta truncation was found in two nonclassified patients. A fungal model carrying an mccA null allele has been constructed and was used to demonstrate, in vivo, the involvement of MCC in leucine catabolism. These results establish that 3-methylcrotonylglycinuria results from loss-of-function mutations in the genes encoding the alpha and beta subunits of MCC and complete the genetic characterization of the four human biotin-dependent carboxylases.

Structural and functional analysis of mutations in alkaptonuria.

Alkaptonuria (AKU), the prototypic inborn error of metabolism, was the first human disease to be interpreted as a Mendelian trait by Garrod and Bateson at the beginning of last century. AKU results from impaired function of homogentisate dioxygenase (HGO), an enzyme required for the catabolism of phenylalanine and tyrosine. With the novel 7 AKU and 22 fungal mutations reported here, a total of 84 mutations impairing this enzyme have been found in the HGO gene from humans and model organisms. Forty-three of these mutations result in single amino acid substitutions. This mutational information is analysed here in the context of the HGO structure and function using kinetic assays performed using purified AKU mutant enzymes and the crystal structure of human HGO. HGO is a topologically complex structure which assembles as a functional hexamer arranged as a dimer of trimers. We show how the intricate pattern of intra- and inter-subunit interactions and the extensive surfaces required for subunit folding and association of this oligomeric enzyme can be inactivated at multiple levels by single-residue substitutions. This explains, in part, the predominance of missense mutations (67%) in AKU.

Crystal structure of human homogentisate dioxygenase.

Homogentisate dioxygenase (HGO) cleaves the aromatic ring during the metabolic degradation of Phe and Tyr. HGO deficiency causes alkaptonuria (AKU), the first human disease shown to be inherited as a recessive Mendelian trait. Crystal structures of apo-HGO and HGO containing an iron ion have been determined at 1.9 and 2.3 A resolution, respectively. The HGO protomer, which contains a 280-residue N-terminal domain and a 140-residue C-terminal domain, associates as a hexamer arranged as a dimer of trimers. The active site iron ion is coordinated near the interface between subunits in the HGO trimer by a Glu and two His side chains. HGO represents a new structural class of dioxygenases. The largest group of AKU associated missense mutations affect residues located in regions of contact between subunits.

On how a transcription factor can avoid its proteolytic activation in the absence of signal transduction.

In response to alkaline ambient pH, the Aspergillus nidulans PacC transcription factor mediating pH regulation of gene expression is activated by proteolytic removal of a negative-acting C-terminal domain. We demonstrate interactions involving the approximately 150 C-terminal PacC residues and two regions located immediately downstream of the DNA binding domain. Our data indicate two full-length PacC conformations whose relative amounts depend upon ambient pH: one 'open' and accessible for processing, the other 'closed' and inaccessible. The location of essential determinants for proteolytic processing within the two more upstream interacting regions probably explains why the interactions prevent processing, whereas the direct involvement of the C-terminal region in processing-preventing interactions explains why C-terminal truncating mutations result in alkalinity mimicry and pH-independent processing. A mutant PacC deficient in pH signal response and consequent processing behaves as though locked in the 'closed' form. Single-residue substitutions, obtained as mutations bypassing the need for pH signal transduction, identify crucial residues in each of the three interactive regions and overcome the processing deficiency in the 'permanently closed' mutant.

Ambient pH signal transduction in Aspergillus: completion of gene characterization.

Completing the molecular analysis of the six pal genes of the ambient pH signal transduction pathway in Aspergillus nidulans, we report the characterization of palC and palH. The derived translation product of palH contains 760 amino acids with prediction of seven transmembrane domains in its N-terminal moiety. Remarkably, a palH frameshift mutant lacking just over half the PalH protein, including almost all of the long hydrophilic region C-terminal to the transmembrane domains, retains some PalH function. The palC-derived translation product contains 507 amino acids, and the null phenotype of a frameshift mutation indicates that at least one of the C-terminal 142 residues is essential for function. Uniquely among the A. nidulans pH-signalling pal genes, palC appears to have no Saccharomyces cerevisiae homologue, although it does have a Neurospora crassa expressed sequence tag homologue. In agreement with findings for the palA, palB and palI genes of this signalling pathway, levels of the palC and palH mRNAs do not appear to be pH regulated.

Disruption of phacA, an Aspergillus nidulans gene encoding a novel cytochrome P450 monooxygenase catalyzing phenylacetate 2-hydroxylation, results in penicillin overproduction.

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.

Specificity determinants of proteolytic processing of Aspergillus PacC transcription factor are remote from the processing site, and processing occurs in yeast if pH signalling is bypassed.

The Aspergillus nidulans transcription factor PacC, which mediates pH regulation, is proteolytically processed to a functional form in response to ambient alkaline pH. The full-length PacC form is unstable in the presence of an operational pH signal transduction pathway, due to processing to the relatively stable short functional form. We have characterized and used an extensive collection of pacC mutations, including a novel class of "neutrality-mimicking" pacC mutations having aspects of both acidity- and alkalinity-mimicking phenotypes, to investigate a number of important features of PacC processing. Analysis of mutant proteins lacking the major translation initiation residue or truncated at various distances from the C terminus showed that PacC processing does not remove N-terminal residues, indicated that processing yields slightly heterogeneous products, and delimited the most upstream processing site to residues approximately 252 to 254. Faithful processing of three mutant proteins having deletions of a region including the predicted processing site(s) and of a fourth having 55 frameshifted residues following residue 238 indicated that specificity determinants reside at sequences or structural features located upstream of residue 235. Thus, the PacC protease cuts a peptide bond(s) remote from these determinants, possibly thereby resembling type I endonucleases. Downstream of the cleavage site, residues 407 to 678 are not essential for processing, but truncation at or before residue 333 largely prevents it. Ambient pH apparently regulates the accessibility of PacC to proteolytic processing. Alkalinity-mimicking mutations L259R, L266F, and L340S favor the protease-accessible conformation, whereas a protein with residues 465 to 540 deleted retains a protease-inaccessible conformation, leading to acidity mimicry. Finally, not only does processing constitute a crucial form of modulation for PacC, but there is evidence for its conservation during fungal evolution. Transgenic expression of a truncated PacC protein, which was processed in a pH-independent manner, showed that appropriate processing can occur in Saccharomyces cerevisiae.

The optimization of penicillin biosynthesis in fungi.

Penicillin production by Penicillium chrysogenum is not only commercially important but arguably the most intensively investigated secondary-metabolic pathway in fungi. Isolation of the structural genes encoding the three main penicillin-biosynthetic enzymes has stimulated the use of molecular approaches to optimize yield and permitted genetic analysis of current production strains, which are themselves the products of 50 years of strain and process improvement. Parallel studies on the penicillin-producing genetic model organism Aspergillus nidulans are now addressing questions about the genetic regulation of primary and secondary metabolism, the compartmentalization of biosynthesis and the excretion of the end products.

Putative membrane components of signal transduction pathways for ambient pH regulation in Aspergillus and meiosis in saccharomyces are homologous.

The zinc finger regions of the Aspergillus nidulans PacC transcription factor, mediating regulation of gene expression by ambient pH, and the Saccharomyces cerevisiae Rim1p transcription factor, mediating control of meiosis and invasiveness, are homologous and both transcription factors undergo proteolytic processing of the C-terminus for conversion to the functional form. In both cases, functioning of a signal transduction pathway involving several gene products is a necessary prerequisite for processing. We now show that the Aspergillus PalI pH signal transduction component is homologous to the Saccharomyces Rim9p meiotic signal transduction component throughout a region containing four hydrophobic, putative membrane-spanning segments. This suggests that PalI might be a membrane sensor for ambient pH. Deletion of the palI gene established that the less extreme phenotype of palI mutations compared with mutations in the other five genes of the pH signalling pathway is a general feature of palI mutations.

The essential Aspergillus nidulans gene pmaA encodes an homologue of fungal plasma membrane H(+)-ATPases.

pmaA, an Aspergillus nidulans gene encoding a P-ATPase, has been cloned by heterologous hybridization with the yeast PMA1 gene. The putative 990-residue PmaA polypeptide shows 50% identity to Saccharomyces cerevisiae and Neurospora crassa plasma membrane H(+)-ATPases and weak (19-26%) identity to other yeast P-type cation-translocating ATPases. PmaA contains all catalytic domains characterizing H(+)-ATPases. pmaA transcript levels are not regulated by PacC, the transcription factor mediating pH regulation, and were not significantly affected by an extreme creAd mutation resulting in carbon catabolite derepression. Deletion of pmaA causes lethality, but a single copy of the gene is sufficient to support normal growth rate in pmaA hemizygous diploids, even under acidic growth conditions. As compared to other fungal H(+)-ATPases, PmaA presents three insertions, 39, 7, and 16 residues long, in the conserved central region of the protein. Two of these insertions are predicted to be located in extracellular loops and might be of diagnostic value for the identification of Aspergillus species. Their absence from most mammalian P-type ATPases may have implications for antifungal therapy.

Mutation and polymorphism analysis of the human homogentisate 1, 2-dioxygenase gene in alkaptonuria patients.

Alkaptonuria (AKU), a rare hereditary disorder of phenylalanine and tyrosine catabolism, was the first disease to be interpreted as an inborn error of metabolism. AKU patients are deficient for homogentisate 1,2 dioxygenase (HGO); this deficiency causes homogentisic aciduria, ochronosis, and arthritis. We cloned the human HGO gene and characterized two loss-of-function mutations, P230S and V300G, in the HGO gene in AKU patients. Here we report haplotype and mutational analysis of the HGO gene in 29 novel AKU chromosomes. We identified 12 novel mutations: 8 (E42A, W97G, D153G, S189I, I216T, R225H, F227S, and M368V) missense mutations that result in amino acid substitutions at positions conserved in HGO in different species, 1 (F10fs) frameshift mutation, 2 intronic mutations (IVS9-56G-->A, IVS9-17G-->A), and 1 splice-site mutation (IVS5+1G-->T). We also report characterization of five polymorphic sites in HGO and describe the haplotypic associations of alleles at these sites in normal and AKU chromosomes. One of these sites, HGO-3, is a variable dinucleotide repeat; IVS2+35T/A, IVS5+25T/C, and IVS6+46C/A are intronic sites at which single nucleotide substitutions (dimorphisms) have been detected; and c407T/A is a relatively frequent nucleotide substitution in the coding sequence, exon 4, resulting in an amino acid change (H80Q). These data provide insight into the origin and evolution of the various AKU alleles.

Characterization of a fungal maleylacetoacetate isomerase gene and identification of its human homologue.

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.

The human homogentisate 1,2-dioxygenase (HGO) gene.

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.

Spectrophotometric determination of homogentisate using Aspergillus nidulans homogentisate dioxygenase.

The presence of homogentisic acid (HGA) in urine is diagnostic for alkaptonuria, a classical example of a biochemical lesion resulting from a single gene trait. We describe here simple culture conditions which induce the synthesis of high levels of homogentisate dioxygenase activity in mycelia from the filamentous ascomycete Aspergillus nidulans. Crude enzyme preparations, showing an apparent Km of 9 microM for homogentisate and an optimal pH of 6.5-7.0 are rather stable and highly specific for homogentisate. Thus, the reaction is not competed by a large molar excess of a number of substrate structural analogues, including phenylacetate and its 2-, 3-, and 4-hydroxy derivatives, phenylalanine, tyrosine, phenylpyruvate, and gentisate. We demonstrate how this enzyme preparation can be used in sensitive, spectrophotometric enzymatic determination of this compound. The accuracy is almost indistinguishable from that obtained by HPLC. The method can be applied to routine determination of homogentisate in human urine. A 1-liter culture of the mold provides sufficient enzyme activity for 1500 enzymatic assays.

Specific DNA recognition by the Aspergillus nidulans three zinc finger transcription factor PacC.

The three zinc fingers of PacC, the transcription factor mediating pH regulation in Aspergillus nidulans, are necessary and sufficient to recognise specifically the target ipnA2 site. Missing nucleoside footprints confirmed the core target (double-stranded) hexanucleotide 5'-GCCAAG-3'. Any base substitution resulted in substantial or complete loss of binding, excepting A5 (partially replaceable by G). A T preceding the hexanucleotide enhanced binding. Interference footprinting indicates that the four Gs and A4 participate in specific contacts and that five pyrimidines are essential for binding. The size of the target sequence and the amino acid sequence of finger 1 suggested that its probe helix would not participate in base-specific contacts. Using site-directed mutagenesis and analogy to GLI, we propose that finger 1 crucially interacts with finger 2, a pair of conserved Trp residues in the Cys knuckles contacting hydrophobically. Finger 2 would also participate in extensive base contacts with the 5' moiety of the hexanucleotide. The specificity mutation Lys159Gln shows that finger 3 binds the 3' moiety of the hexanucleotide. Replacement of residues in positions +3 (His128Asn) and +2 (Gln155Lys) of the reading helices of fingers 2 and 3, respectively, prevented binding. Our biochemical and molecular data plus modelling using previously determined zinc finger-DNA complexes, predict specific contacts of fingers 2 and 3 to ipnA2. Our data indicate compact organisation of the PacC-ipnA2 complex (with nearly every base involved in specific contacts), illustrate the binding versatility of zinc finger domains and should facilitate analysis of other PacC family members, including Saccharomyces cerevisiae RIM1.

Three binding sites for the Aspergillus nidulans PacC zinc-finger transcription factor are necessary and sufficient for regulation by ambient pH of the isopenicillin N synthase gene promoter.

The isopenicillin N synthase (ipnA) gene, encoding a key penicillin biosynthetic enzyme in Aspergillus nidulans, represents a prototype of an alkaline-expressed gene. ipnA is under ambient pH regulation, and its promoter (ipnAp) contains binding sites for the zinc-finger transcription factor PacC. We show here that three of these sites, denoted ipnA2, ipnA3, and ipnA4AB, are efficiently recognized by the protein in an isolated sequence context. Single, double, and triple inactivation of these sites in any possible combination reduced promoter activity under alkaline conditions but had no effect under acidic conditions (under which promoter activity was low), as measured by the expression of wild-type and mutant ipnAp::lacZ fusion genes integrated in single copy into a common chromosomal location. This establishes a physiological role for these PacC binding sites and demonstrates a direct role for PacC in ambient pH regulation of ipnA gene expression. In addition, this confirms our previous proposal that PacC is an activator for alkaline-expressed genes. Notably, our experiments show that ipnA2, the highest affinity site for PacC in the ipnAp, contributes relatively modestly to PacC-mediated activation. By contrast, the lower affinity sites ipnA3 and ipnA4AB contribute more substantially to regulation by ambient pH. Inactivation of these three binding sites reduced promoter activity under alkaline conditions to that observed under acidic conditions, showing that these three PacC sites at ipnAp are sufficient to account for its activation by alkaline ambient pH.

The molecular basis of alkaptonuria.

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.