Frontal analysis on a microchip.

Conventional microchip applications involving capillary electrophoresis (CE) typically inject a sample along one channel and use an intersection of two channels to define the sample plug--the portion of sample to be analysed along a second channel. In contrast to this method of zone separation, frontal analysis proceeds by injecting sample continuously into a single channel or column. Frontal analysis is more common in macroscopic procedures but there are benefits in sensitivity and device density to its application to electrophoresis on microchips. This work compares conventional microchip zone analysis with frontal analysis in the separation of PCR products. Although we detect on the order of 5000 fluorophores with a compact instrument using the zone separation CE method, we found a several-fold increase in the effective signal-to-noise ratio by using a frontal analysis method. By removing the need for additional channels and reservoirs the frontal method would allow device densities to be significantly increased, potentially improving the cost-effectiveness of microchip analyses in applications such as medical diagnostics.

Sample purification on a microfluidic device.

Sample preparation has long been recognized as a significant barrier to the implementation of macroscopic protocols on microfabricated devices. Macroscopically, such tasks as removing salts, primers and other contaminants are performed by methods involving precipitation, specialized membranes and centrifuges, none of which are readily performed in microfluidic structures. Although some microfluidic systems have been developed for performing sample purification, their complexity may hinder the degree to which they can be implemented. We present a method of microchip-based sample purification that can be performed with even the simplest microfluidic designs. The technique is demonstrated by removing primers from a sample of amplified DNA, leaving only the product DNA. This provides a new sample preparation capability for microfluidic systems.

Involvement of mitochondrial ferredoxin and Cox15p in hydroxylation of heme O.

Cox15p is essential for the biogenesis of cytochrome oxidase [Glerum et al., J. Biol. Chem. 272 (1997) 19088-19094]. We show here that cox15 mutants are blocked in heme A but not heme O biosynthesis. In Schizosaccharomyces pombe COX15 is fused to YAH1, the yeast gene for mitochondrial ferredoxin (adrenodoxin). A fusion of Cox15p and Yah1p in Saccharomyces cerevisiae rescued both cox15 and yah1 null mutants. This suggests that Yah1p functions in concert with Cox15p. We propose that Cox15p functions together with Yah1p and its putative reductase (Arh1p) in the hydroxylation of heme O.

Characterization and localization of human COX17, a gene involved in mitochondrial copper transport.

Deficiencies in cytochrome oxidase (COX), the terminal enzyme of the mitochondrial respiratory chain, are relatively rare but most often lethal. The underlying causes are beginning to be elucidated, and most mutations are thought to affect the function of proteins involved in assembling the holoenzyme. COX17 is such an assembly protein and is thought to recruit copper to mitochondria for incorporation into the COX apoenzyme. Here we present the gene structure, the expression, and chromosomal localization for COX17, a candidate gene for COX deficiency. The COXI 7 gene spans approximately 8 kb of human genomic DNA and encodes a transcript of approximately 450 bp that is expressed in all tissues tested. Although the COX17 gene was previously mapped to chromosome 13q14-21, our results suggest that a COX17 pseudogene maps to this region. The pseudogene contains several nucleotide changes, including one that would result in an altered amino acid in the putative copper binding domain. We have localized the gene encoding the COX 17 protein to the long arm of chromosome 3 by radiation hybrid mapping. Deciphering of the COX17 genomic structure will allow this gene to be assessed for mutations in COX deficient patients.

Deconstructing Mendel: new paradigms in genetic mechanisms.

As knowledge of the mechanisms of genetic action expands, this new information must be incorporated into the whole. The result is that old concepts are modified or deleted or new paradigms are created. The authors review advances in the understanding of traditional and nontraditional inheritance, including genomic imprinting and mitochondrial inheritance.

A human SCO2 mutation helps define the role of Sco1p in the cytochrome oxidase assembly pathway.

Deficiencies in cytochrome oxidase, the terminal enzyme of the mitochondrial respiratory chain, are most often caused by an inability to complete assembly of the enzyme. Pathogenic mutations in SCO2, which encodes a cytochrome oxidase assembly factor, were recently described in several cases of fatal infantile cardioencephalomyopathy. To determine the molecular etiology of these disorders, we describe the generation and characterization of the parallel mutations in the homologous yeast SCO1 gene. We show that the E155K yeast sco1 mutant is respiration-competent, whereas the S240F mutant is not. Interestingly, the S240F mutation allows partial but incorrect assembly of cytochrome oxidase, as judged by an altered cytochrome aa(3) peak. Immunoblot analysis reveals a specific absence of subunit 2 from the cytochrome oxidase in this mutant. Taken together, our data suggest that Sco1p provides copper to the Cu(A) site on subunit 2 at a step occurring late in the assembly pathway. This is the first instance of a yeast cytochrome oxidase assembly mutant that is partially assembled. The S240F mutant also represents a powerful new tool with which to elucidate further steps in the cytochrome oxidase assembly pathway.

Fatal infantile cardioencephalomyopathy with COX deficiency and mutations in SCO2, a COX assembly gene.

Mammalian cytochrome c oxidase (COX) catalyses the transfer of reducing equivalents from cytochrome c to molecular oxygen and pumps protons across the inner mitochondrial membrane. Mitochondrial DNA (mtDNA) encodes three COX subunits (I-III) and nuclear DNA (nDNA) encodes ten. In addition, ancillary proteins are required for the correct assembly and function of COX (refs 2, 3, 4, 5, 6). Although pathogenic mutations in mtDNA-encoded COX subunits have been described, no mutations in the nDNA-encoded subunits have been uncovered in any mendelian-inherited COX deficiency disorder. In yeast, two related COX assembly genes, SCO1 and SCO2 (for synthesis of cytochrome c oxidase), enable subunits I and II to be incorporated into the holoprotein. Here we have identified mutations in the human homologue, SCO2, in three unrelated infants with a newly recognized fatal cardioencephalomyopathy and COX deficiency. Immunohistochemical studies implied that the enzymatic deficiency, which was most severe in cardiac and skeletal muscle, was due to the loss of mtDNA-encoded COX subunits. The clinical phenotype caused by mutations in human SCO2 differs from that caused by mutations in SURF1, the only other known COX assembly gene associated with a human disease, Leigh syndrome.

Affinity purification of yeast cytochrome oxidase with biotinylated subunits 4, 5, or 6.

Null mutants in COX4, COX5a, or COX6, which encode subunits 4, 5, and 6 of yeast cytochrome oxidase are blocked in assembly of the enzyme. The mutants are complemented by gene constructs expressing cytochrome oxidase subunits with a carboxyl terminal extension containing a biotinylation signal sequence. Spectra and enzyme activities of mitochondria from transformants expressing a biotinylated subunit indicate restoration of a functional cytochrome oxidase. Biotinylated cytochrome oxidase can be affinity-purified from mitochondrial extracts by fractionation on a monomeric avidin column. This method can be used to purify the enzyme from small amounts of starting material.

Submitochondrial distributions and stabilities of subunits 4, 5, and 6 of yeast cytochrome oxidase in assembly defective mutants.

The concentration and submitochondrial distribution of the subunit polypeptides of cytochrome oxidase have been studied in wild type yeast and in different mutants impaired in assembly of this respiratory complex. All the subunit polypeptides of the enzyme are associated with mitochondrial membranes of wild type cells, except for a small fraction of subunits 4 and 6 that is recovered in the soluble protein fraction of mitochondria. Cytochrome oxidase mutants consistently display a severe reduction in the steady-state concentration of subunit 1 due to its increased turnover. As a consequence, most of subunit 4, which normally is associated with subunit 1, is found in the soluble fraction. A similar shift from membrane-bound to soluble subunit 6 is seen in mutants blocked in expression of subunit 5a. In contrast, null mutations in COX6 coding for subunit 6 promote loss of subunit 5a. The absence of subunit 5a in the cox6 mutant is the result of proteolytic degradation rather than regulation of its expression by subunit 6. The possible role of the ATP-dependent proteases Rca1p and Afg3p in proteolysis of subunits 1 and 5a has been assessed in strains with combined mutations in COX6, RCA1, and/or AFG3. Immunochemical assays indicate that another protease(s) must be responsible for most of the proteolytic loss of these proteins.

COX15 codes for a mitochondrial protein essential for the assembly of yeast cytochrome oxidase.

The respiratory defect of Saccharomyces cerevisiae mutants assigned to complementation group G4 of a pet strain collection stems from their failure to synthesize cytochrome oxidase. The mutations do not affect expression of either the mitochondrially or nuclearly encoded subunits of the enzyme. The cytochrome oxidase deficiency also does not appear to be related to mitochondrial copper metabolism or heme a biosynthesis. These data suggest that the mutants are likely to be impaired in assembly of the enzyme. A gene designated COX15 has been cloned by transformation of mutants from complementation group G4. This gene is identical to reading frame YER141w on chromosome 5. To facilitate further studies, Cox15p has been expressed as a biotinylated protein. Biotinylated Cox15p fully restores cytochrome oxidase in cox15 mutants, indicating that the carboxyl-terminal sequence with biotin does not affect its function. Cox15p is a constituent of the mitochondrial inner membrane and, because of its resistance to proteolysis, probably is largely embedded in the phospholipid bilayer of the membrane. The present studies further emphasize the complexity of cytochrome oxidase assembly and report a new constituent of mitochondria involved in this process. The existence of COX15 homologs in Schizosaccharomyces pombe and Caenorhabditis elegans suggests that it may be widely distributed in eucaryotic organisms.

SHY1, the yeast homolog of the mammalian SURF-1 gene, encodes a mitochondrial protein required for respiration.

C173 and W125 are pet mutants of Saccharomyces cerevisiae, partially deficient in cytochrome oxidase but with elevated concentrations of cytochrome c. Assays of electron transport chain enzymes indicate that the mutations exert different effects on the terminal respiratory pathway, including an inefficient transfer of electrons between the bc1 and the cytochrome oxidase complexes. A cloned gene capable of restoring respiration in C173/U1 and W125 is identical to reading frame YGR112w of yeast chromosome VII (GenBank Z72897Z72897). The encoded protein is homologous to the product of the mammalian SURF-1 gene. In view of the homology, the yeast gene has been designated SHY1 (Surf Homolog of Yeast). An antibody against the carboxyl-terminal half of Shy1p has been used to localize the protein in the inner mitochondrial membrane. Deletion of part of SHY1 produces a phenotype similar to that of G91 mutants. Disruption of SHY1 at a BamHI site, located approximately 2/3 of the way into the gene, has no obvious phenotypic consequence. This evidence, together with the ability of a carboxyl-terminal coding sequence starting from the BamHI site to complement a shy1 mutant, suggests that the Shy1p contains two domains that can be separately expressed to form a functional protein.

Isolation of a cDNA encoding the human homolog of COX17, a yeast gene essential for mitochondrial copper recruitment.

The COX17 gene of Saccharomyces cerevisiae codes for a cytoplasmic protein essential for the expression of functional cytochrome oxidase. This protein has been implicated in targeting copper to mitochondria. To determine if Cox17p is present in mammalian cells, a yeast strain carrying a null mutation in COX17 was transformed with a human cDNA expression library. All the respiratory competent clones obtained from the transformations carried a common cDNA sequence with a reading frame predicting a product homologous to yeast Cox17p. The cloning of a mammalian COX17 homolog suggests that the encoded product is likely to function in copper recruitment in eucaryotic cells in general. Its presence in humans provides a possible target for genetically inherited deficiencies in cytochrome oxidase.

Purification, characterization, and localization of yeast Cox17p, a mitochondrial copper shuttle.

Cox17p was previously shown to be essential for the expression of cytochrome oxidase in Saccharomyces cerevisiae. In the present study COX17 has been placed under the control of the GAL10 promoter in an autonomously replicating plasmid. A yeast transformant harboring the high copy construct was used to purify Cox17p to homogeneity. Purified Cox17p contains 0.2-0.3 mol of copper per mol of protein. The molar copper content is increased to 1.8 after incubation of Cox17p in the presence of a 6-fold molar excess of cuprous chloride under reduced conditions. An antibody against Cox17p was obtained by immunization of rabbits with a carboxyl-terminal peptide coupled to bovine serum albumin. The antiserum detects Cox17p in both the mitochondrial and soluble protein fractions of wild type yeast and of the transformant overexpressing Cox17p. Exposure of intact mitochondria to hypotonic conditions causes most of Cox17p to be released as a soluble protein indicating that the mitochondrial fraction of Cox17p is localized in the intermembrane space. These results are consistent with the previously proposed function of Cox17p, namely in providing cytoplasmic copper for mitochondrial utilization.

Cloning and identification of HEM14, the yeast gene for mitochondrial protoporphyrinogen oxidase.

A respiratory-defective mutant (C54) of Saccharomyces cerevisiae was found to have a phenotype consistent with a mutation in either mitochondrial protoporphyrinogen oxidase or ferrochelatase. The mutant is grossly deficient in hemes, accumulates protoporphyrin and is rescued by exogenous heme. The increased levels of protoporphyrin at the expense of heme is indicative of a block in one of the two last steps of the heme biosynthetic pathway. Complementation of C54 by a known ferrochelatase mutant suggested that the defect was most likely in HEM14 encoding protoporphyrinogen oxidase. A plasmid capable of complementing C54 was obtained by transformation with a yeast genomic plasmid library. A partial sequence of the insert identified the gene as reading frame YER014 of yeast chromosome V (GenBank Accession Number U18778). This reading frame codes for a protein homologous to human protoporphyrinogen oxidase. Disruption of this gene elicits a respiratory defect and accumulation of protoporphyrin. The phenotype of the null mutant together with the homology of YER014p to human protoporphyrinogen oxidase provide compelling evidence that YER014 is HEM14.

SCO1 and SCO2 act as high copy suppressors of a mitochondrial copper recruitment defect in Saccharomyces cerevisiae.

C129/U1 is a respiratory defective mutant of Saccharomyces cerevisiae arrested in cytochrome oxidase assembly due to a mutation in COX17, a nuclear gene encoding a low molecular weight cytoplasmic protein proposed to function in mitochondrial copper recruitment. In the present study we show that the respiratory defect of C129/U1 is rescuable by two multicopy suppressors, SCO1 and SCO2. SCO1 was earlier reported to code for a mitochondrial inner membrane protein with an essential function in cytochrome oxidase assembly (Buchwald, P., Krummeck, G., and Rodel, G. (1991) Mol. Gen. Genet. 229, 413-420). SCO2 is a homologue of SCO1, whose product is also localized in the mitochondrial membrane but is not required for respiration. SCO1 also suppresses a cox17 null mutant, indicating that overexpression of Sco1p can compensate for the absence of Cox17p. In contrast, neither copper, COX17 on a multicopy plasmid, or a combination of the two is able to restore respiration in sco1 mutants. Rescue of cox17 mutants by Sco1p suggests that this mitochondrial protein plays a role either in mitochondrial copper transport or insertion of copper into the active site of cytochrome oxidase. Although SCO2 can also partially restore respiratory growth in the cox17 null mutant, rescue in this case requires addition of copper to the growth medium. SCO2 does not suppress a sco1 null mutant, although it is able to partially rescue a sco1 point mutant. We interpret the ability of SCO2 to restore respiration in cox17, but not in sco1 mutants, to indicate that Sco1p and Sco2p have overlapping but not identical functions.

Characterization of COX17, a yeast gene involved in copper metabolism and assembly of cytochrome oxidase.

Mutations in the COX17 gene of Saccharomyces cerevisiae cause a respiratory deficiency due to a block in the production of a functional cytochrome oxidase complex. Because cox17 mutants are able to express both the mitochondrially and nuclearly encoded subunits of cytochrome oxidase, the Cox17p most likely affects some late posttranslational step of the assembly pathway. A fragment of yeast nuclear DNA capable of complementing the mutation has been cloned by transformation of the cox17 mutant with a library of genomic DNA. Subcloning and sequencing of the COX17 gene revealed that it codes for a cysteine-rich protein with a molecular weight of 8,057. Unlike other previously described accessory factors involved in cytochrome oxidase assembly, all of which are components of mitochondria, Cox17p is a cytoplasmic protein. The cytoplasmic location of Cox17p suggested that it might have a function in delivery of a prosthetic group to the holoenzyme. A requirement of Cox17p in providing the copper prosthetic group of cytochrome oxidase is supported by the finding that a cox17 null mutant is rescued by the addition of copper to the growth medium. Evidence is presented indicating that Cox17p is not involved in general copper metabolism in yeast but rather has a more specific function in the delivery of copper to mitochondria.

FLX1 codes for a carrier protein involved in maintaining a proper balance of flavin nucleotides in yeast mitochondria.

Respiratory defective mutants of Saccharomyces cerevisiae previously assigned to complementation group G178 are characterized by an abnormally low ratio of FAD/FMN in mitochondria. A nuclear gene, designated FLX1, was selected from a yeast genomic library, based on its ability to confer wild-type growth properties to a representative G178 mutant. Genetic evidence has confirmed that the flavin nucleotide imbalance of G178 mutants is caused by mutations in FLX1. The sequence of FLX1 is identical to a reading frame recently reported to be present on yeast chromosome IX (GenBank Z47047). The sequence and tripartite repeat structure of the FLX1 product (Flx1p) indicate it is a member of a protein family consisting of mitochondrial substrate and nucleotide carriers. In yeast, FAD synthetase is present in the soluble cytoplasmic protein fraction but not in mitochondria. Riboflavin kinase, the preceding enzyme in flavin biosynthesis, is present in both subcellular fractions. The absence of FAD synthetase in mitochondria implies that FAD is imported from the cytoplasm. The lower concentration of mitochondrial FAD in flx1 mutants suggests that Flx1p is involved in flavin transport, a role that is also supported by biochemical evidence indicating more efficient flux of FAD across mitochondrial membrane vesicles prepared from wild-type strains than membrane vesicles from flx1 mutants.

Cloning and characterization of COX14, whose product is required for assembly of yeast cytochrome oxidase.

Nuclear respiration-deficient mutants of Saccharomyces cerevisiae previously assigned to complementation group G93 lack cytochromes a and a3 and detectable cytochrome oxidase activity. Other respiratory chain carriers and the ATPase complex are present at near wild-type levels, indicating that the mutations specifically affect cytochrome oxidase. Since synthesis of the mitochondrially derived subunits 1, 2, and 3 of cytochrome oxidase is normal, the defect cannot be related to transcription of the endogenous genes or processing and translation of the corresponding RNAs. The results of Western analysis of the cytochrome oxidase subunits encoded in nuclear DNA also argues against an effect of the mutations on expression of these constituents. The G93 mutants are complemented by a nuclear gene, designated COX14. The product of this gene is a low molecular mass protein of 7,960 Da. A gene fusion expressing a biotinylated form of Cox14p complements cox14 mutants, indicating partial functional equivalence. The biotinylated derivative has been helpful in localizing Cox14p to the mitochondrial membrane and demonstrating that it is not a hitherto unrecognized subunit of cytochrome oxidase, although it does appear to be associated with a high molecular weight complex. This evidence, combined with the assembly-arrested phenotype of cox14 mutants, indicates that Cox14p, like several other recently described mitochondrial constituents, provides an important function at some late stage of the cytochrome oxidase assembly pathway.

Cloning and characterization of FAD1, the structural gene for flavin adenine dinucleotide synthetase of Saccharomyces cerevisiae.

The FAD1 gene of Saccharomyces cerevisiae has been selected from a genomic library on the basis of its ability to partially correct the respiratory defect of pet mutants previously assigned to complementation group G178. Mutants in this group display a reduced level of flavin adenine dinucleotide (FAD) and an increased level of flavin mononucleotide (FMN) in mitochondria. The restoration of respiratory capability by FAD1 is shown to be due to extragenic suppression. FAD1 codes for an essential yeast protein, since disruption of the gene induces a lethal phenotype. The FAD1 product has been inferred to be yeast FAD synthetase, an enzyme that adenylates FMN to FAD. This conclusion is based on the following evidence. S. cerevisiae transformed with FAD1 on a multicopy plasmid displays an increase in FAD synthetase activity. This is also true when the gene is expressed in Escherichia coli. Lastly, the FAD1 product exhibits low but significant primary sequence similarity to sulfate adenyltransferase, which catalyzes a transfer reaction analogous to that of FAD synthetase. The lower mitochondrial concentration of FAD in G178 mutants is proposed to be caused by an inefficient exchange of external FAD for internal FMN. This is supported by the absence of FAD synthetase activity in yeast mitochondria and the presence of both extramitochondrial and mitochondrial riboflavin kinase, the preceding enzyme in the biosynthetic pathway. A lesion in mitochondrial import of FAD would account for the higher concentration of mitochondrial FMN in the mutant if the transport is catalyzed by an exchange carrier. The ability of FAD1 to suppress impaired transport of FAD is explained by mislocalization of the synthetase in cells harboring multiple copies of the gene. This mechanism of suppression is supported by the presence of mitochondrial FAD synthetase activity in S. cerevisiae transformed with FAD1 on a high-copy-number plasmid but not in mitochondrial of a wild-type strain.

Isolation of a human cDNA for heme A:farnesyltransferase by functional complementation of a yeast cox10 mutant.

We have cloned the human homolog of the Saccharomyces cerevisiae COX10 gene by functional complementation of a yeast cox10 null mutant. The 2.8-kb cDNA encoding the human heme A:farnesyltransferase codes for a 443-aa protein with high homology to the yeast and bacterial farnesylases. The human COX10 homolog, however, does not complement the mutation as efficiently as the yeast COX10 protein, likely due to the heterologous environment. PCR amplification and Southern analysis confirm the existence of a large mRNA for the human protein, with an unusually long 3' untranslated region. This clone can now be used to screen patients with inherited deficiencies in cytochrome oxidase in which the mutations remain unidentified and are likely to reside in a protein influencing the assembly of the enzyme.