A novel syndrome affecting multiple mitochondrial functions, located by microcell-mediated transfer to chromosome 2p14-2p13.

We have studied cultured skin fibroblasts from three siblings and one unrelated individual, all of whom had fatal mitochondrial disease manifesting soon after birth. After incubation with 1 mM glucose, these four cell strains exhibited lactate/pyruvate ratios that were six times greater than those of controls. On further analysis, enzymatic activities of the pyruvate dehydrogenase complex, the 2-oxoglutarate dehydrogenase complex, NADH cytochrome c reductase, succinate dehydrogenase, and succinate cytochrome c reductase were severely deficient. In two of the siblings the enzymatic activity of cytochrome oxidase was mildly decreased (by approximately 50%). Metabolite analysis performed on urine samples taken from these patients revealed high levels of glycine, leucine, valine, and isoleucine, indicating abnormalities of both the glycine-cleavage system and branched-chain alpha-ketoacid dehydrogenase. In contrast, the activities of fibroblast pyruvate carboxylase, mitochondrial aconitase, and citrate synthase were normal. Immunoblot analysis of selected complex III subunits (core 1, cyt c(1), and iron-sulfur protein) and of the pyruvate dehydrogenase complex subunits revealed no visible changes in the levels of all examined proteins, decreasing the possibility that an import and/or assembly factor is involved. To elucidate the underlying molecular defect, analysis of microcell-mediated chromosome-fusion was performed between the present study's fibroblasts (recipients) and a panel of A9 mouse:human hybrids (donors) developed by Cuthbert et al. (1995). Complementation was observed between the recipient cells from both families and the mouse:human hybrid clone carrying human chromosome 2. These results indicate that the underlying defect in our patients is under the control of a nuclear gene, the locus of which is on chromosome 2. A 5-cM interval has been identified as potentially containing the critical region for the unknown gene. This interval maps to region 2p14-2p13.

A case of PDH-E1 alpha mosaicism in a male patient with severe metabolic lactic acidosis.

We have characterized a novel mutation in a male patient that affects the coding sequence of PDH-E1 alpha gene and changes arginine-141 to a leucine. This nucleotide substitution was found in about 75% of the studied DNA (fibroblasts, liver and muscle), a scenario that would indicate a case of E1 alpha mosaicism in a male patient. When the mutant E1 alpha protein was expressed in human skin fibroblasts with zero endogenous pyruvate dehydrogenase complex activity and E1 alpha protein expression, no significant restoration of activity was recorded, in contrast to the wild-type cDNA. even though both wild-type and mutant protein levels were comparable. We concluded that the R141L mutation is a severe one and that it must have occurred in one of the E1 alpha alleles during early embryogenesis.

Expression and functional characterization of human protein X variants in SV40-immortalized protein X-deficient and E2-deficient human skin fibroblasts.

To gain further insight into the nature and function of the domains of the human protein X (a pyruvate dehydrogenase complex component also known as the E3-binding protein), we expressed the wild-type as well as two artificially created variants, K37E and S422H, in SV40-immortalized protein X-deficient and E2-deficient human skin fibroblasts. The former mutant does not carry the lipoic acid moiety, the latter mutant was designed to investigate the possibility that protein X could exhibit an intrinsic acetyltransferase activity and use either its own catalytic center or the catalytic center of E2. Similar experiments have been performed in the past using the Saccharomyces cerevisiae expression system. However, lack of sequence similarity between the mammalian and the yeast protein X homologues suggests they are not biochemically equivalent. Mutant cells transfected with the wild-type gene for protein X produced a PDH complex that exhibited about 50% overall activity of the control cells. None of the expressed protein X variants had an effect on the specific activity of the PDH complex, suggesting that the human protein X plays a purely structural role in the functioning of the pyruvate dehydrogenase complex.

Functional expression of four PDH-E(1)alpha recombinant histidine mutants in a human fibroblast cell line with zero endogenous PDH complex activity.

Conserved histidine residues have been implicated in the geometry and catalytic mechanism of the E(1)alpha proteins of the PDH complex. We constructed and expressed a series of PDH-E(1)alpha histidine mutants (H63, H84, H92, and H263) in a cell line with zero PDH complex activity due to a null E(1)alpha allele. Based on immunoblot and enzyme activity analyses, all introduced histidine mutations, with the exception of H92, affected the specific activity of the PDH complex. We showed that H63 and H263 are essential for the activity since mutations introduced at those sites produced a PDH complex with near-zero activity. Mutations introduced at H84 only partially reduced activity, implying that H84 may play a less critical role in the PDH complex. Mutations introduced at H92 caused the absence of immunoreactive material for both the E(1)alpha and E(1)beta subunits and may have impaired import or assembly of precursor peptides into the mature PDH complex.

Sequential deletion of C-terminal amino acids of the E(1)alpha component of the pyruvate dehydrogenase (PDH) complex leads to reduced steady-state levels of functional E(1)alpha(2)beta(2) tetramers: implications for patients with PDH deficiency.

Human pyruvate dehydrogenase (PDH) complex deficiency is an extremely heterogeneous disease in its presentation and clinical course. We have characterized novel mutations that affect the C-terminal portion of the PDH-E(1)alpha-coding sequence. Although the molecular defects underlying these mutations are different, both effectively produce a stop codon prematurely three amino acids from the C-terminus. The clinical and biochemical consequences of these mutations are unusual in that the affected individuals are very long-term survivors with PDH complex deficiency despite having low (<20%) activity in skin fibroblasts. These findings prompted us to investigate the C-terminus of E(1)alpha in greater detail. We constructed and expressed a series of PDH-E(1)alpha deletion mutants in a cell line with zero PDH complex activity due to a null E(1)alpha allele. Sequential deletion of the C-terminus by one, two, three and four amino acids resulted in PDH complex activities of 100, 60, 36 and 14%, respectively, compared with wild-type E(1)alpha expressed in PDH complex-deficient cells. The immunodetectable protein was decreased by the same amount as the activity, suggesting that the stability and/or assembly of the E(1)alpha(2)beta(2)heterotetramer might depend on the intactness of the PDH-E(1)alpha C-terminus. In addition, we compared the somatic and the testis-specific isoforms of E(1)alphaand concluded that they are biochemically equivalent.

Mutations in the X-linked pyruvate dehydrogenase (E1) alpha subunit gene (PDHA1) in patients with a pyruvate dehydrogenase complex deficiency.

Defects in the pyruvate dehydrogenase (PDH) complex are an important cause of primary lactic acidosis, a frequent manifestation of metabolic disease in children. Clinical symptoms can vary considerably in patients with PDH complex deficiencies, and almost equal numbers of affected males and females have been identified, suggesting an autosomal recessive mode of inheritance of the disease. However, the great majority of PDH complex deficiencies result from mutations in the X-linked pyruvate dehydrogenase (E1) alpha subunit gene (PDHA1). The major factors that contribute to the clinical variation in E1alpha deficiency and its resemblance to a recessive disease are developmental lethality in some males with severe mutations and the pattern of X-inactivation in females. To date, 37 different missense/nonsense and 39 different insertion/deletion mutations have been identified in the E1alpha subunit gene of 130 patients (61 females and 69 males) from 123 unrelated families. Insertion/deletion mutations occur preferentially in exons 10 and 11, while missense/nonsense mutations are found in all exons. In males, the majority of missense/nonsense mutations are found in exons 3, 7, 8 and 11, and three recurrent mutations at codons R72, R263 and R378 account for half of these patients with missense/nonsense mutations (25 of 50). A significantly lower number of females is found with missense/nonsense mutations (25). However, 36 females out of 55 affected patients have insertion/deletion mutations. The total number of female and male patients is thus almost the same, although a difference in the distribution of the type of mutations is evident between both sexes. In many families, the parents of the affected patients were studied for the presence of the PDHA1 mutation. The mutation was never present in the somatic cells of the father; in 63 mothers studied, 16 were carriers (25%). In four families, the origin of the new mutation was determined to be twice paternal and twice maternal.

Detection of a homozygous four base pair deletion in the protein X gene in a case of pyruvate dehydrogenase complex deficiency.

While the presence of a lipoyl-containing protein (protein X) separate from lipoyl transacetylase in the pyruvate dehydrogenase complex (PDC) has been known for some time, until recently only the cDNA for the yeast enzyme has been cloned. We have cloned, sequenced and characterized the cDNA encoding the human protein X and localized the protein X gene to chromosome 11p13. We also report here a new case of protein X deficiency identified immunologically, with decreased activity of PDC and without mutations in the E1alpha subunit or E1beta subunit. We report that the cDNA and gene of this patient for protein X has a homozygous 4 bp deletion, specifically in the putative mitochondrial targeting signal sequence which results in a premature stop codon. This is the first documented case of a molecular defect in pyruvate dehydrogenase protein X.