Biochemical analysis of fibroblasts from patients with cytochrome c oxidase-associated Leigh syndrome

Cultured skin fibroblasts from four patients with Leigh syndrome and cytochrome c oxidase deficiency were studied. Mitochondrial DNA (mtDNA) analysis excluded large-scale deletions and known point mutations associated with Leigh syndrome. The COX activities were reduced to 18-44% of healthy probands, when measured in the presence of laurylmaltoside. COX activity from patients was shown to be more temperature sensitive than COX activity from control cells. In order to determine the subunit composition of COX immunoblotting studies were performed using mono- and polyclonal antibodies to distinct subunits. A monoclonal antibody to subunit IV crossreacted with two unknown proteins of higher apparent molecular weight in mitochondria from three patients, but not in mitochondria from control and the fourth patient. Quantification of immunoreactivity revealed a decrease of subunits II/III and IV parallel to the determined enzyme activity. In contrast, a variable amount of subunit VIIa (and/or VIIb) was found in mitochondria from different patients. The results indicate a defective COX holoenzyme complex in patients with Leigh syndrome and suggest different molecular origins of the defect.     

Reduced dosage of genes encoding ribosomal protein S18 suppresses a mitochondrial initiation codon mutation in Saccharomyces cerevisiae

A yeast mitochondrial translation initiation codon mutation affecting the gene for cytochrome oxidase subunit III (COX3) was partially suppressed by a spontaneous nuclear mutation. The suppressor mutation also caused cold-sensitive fermentative growth on glucose medium. Suppression and cold sensitivity resulted from inactivation of the gene product of RPS18A, one of two unlinked genes that code the essential cytoplasmic small subunit ribosomal protein termed S18 in yeast. The two S18 genes differ only by 21 silent substitutions in their exons; both are interrupted by a single intron after the 15th codon. Yeast S18 is homologous to the human S11 (70% identical) and the Escherichia coli S17 (35% identical) ribosomal proteins. This highly conserved family of ribosomal proteins has been implicated in maintenance of translational accuracy and is essential for assembly of the small ribosomal subunit. Characterization of the original rps18a-1 missense mutant and rps18a delta and rps18b delta null mutants revealed that levels of suppression, cold sensitivity and paromomycin sensitivity all varied directly with a limitation of small ribosomal subunits. The rps18a-1 mutant was most affected, followed by rps18a delta then rps18b delta. Mitochondrial mutations that decreased COX3 expression without altering the initiation codon were not suppressed. This allele specificity implicates mitochondrial translation in the mechanism of suppression. We could not detect an epitope-tagged variant of S18 in mitochondria. Thus, it appears that suppression of the mitochondrial translation initiation defect is caused indirectly by reduced levels of cytoplasmic small ribosomal subunits, leading to changes in either cytoplasmic translational accuracy or the relative levels of cytoplasmic translation products.     

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.     

Studies on the function of yeast phosphofructokinase subunits by in vitro mutagenesis

Genetic and biochemical analysis of phosphofructokinase in the yeast Saccharomyces cerevisiae led to contradictory hypotheses about the function of the subunits of this heterooctameric enzyme. To gain further insight, we exchanged four evolutionary conserved amino acid residues in each of the two yeast subunits affecting presumed catalytic and regulatory functions. In conjunction with a complementary wild-type subunit, each of the mutant subunits led to a loss of a maximum of 50% of phosphofructokinase activity as compared to wild-type cells. Km values for fructose 6-phosphate were increased in most of these mutants. None of the mutant subunits lacking catalytical functions was able to complement the glucose-negative phenotype of a yeast pfk1 pfk2 double mutant when expressed from a single-copy vector. For the beta-subunits, the other mutants did complement, whereas for the alpha-subunits they did not. Concentrations of fructose 1,6-bisphosphate did not drastically change in metabolite determinations in strains carrying one mutant allele, suggesting that the effect of the mutations introduced can be largely compensated by in vivo regulatory mechanisms, as long as one functional subunit is present. The data implicate that each of the yeast phosphofructokinase subunits can serve catalytically as well as regulatory functions.     

In situ detection of tissue factor within the coronary intima in rat cardiac allograft vasculopathy

Proteasomes are multicatalytic complexes that function as the major proteolytic machinery in regulated protein degradation. The eukaryotic 20S proteasome proteolytic core structure comprises 14 different subunits: 7 alpha-type and 7 beta-type. DTS7 is a dominant temperature-sensitive (DTS) lethal mutation at 29 degrees that also acts as a recessive lethal at ambient temperatures. DTS7 maps to cytological position 71AB. Molecular characterization of DTS7 reveals that this is caused by a missense mutation in a beta-type subunit gene, beta2. A previously characterized DTS mutant, l(3)73Ai1, results from a missense mutation in another beta-type subunit gene, beta6. These two mutants share a very similar phenotype, show a strong allele-specific genetic interaction, and are rescued by the same extragenic suppressor, Su(DTS)-1. We propose that these mutants might act as "poison subunits," disrupting proteasome function in a dosage-dependent manner, and suggest how they may interact on the basis of the structure of the yeast 20S proteasome.     

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.     

Home alone--meeting the needs of mothers after cesarean birth

The leukocyte NADPH oxidase is a multi-subunit enzyme that catalyzes the reduction of oxygen to O2- at the expense of a reduced pyridine nucleotide. We have used site-directed mutagenesis to examine the functional role of the four cysteines in p47PHOX, one of the subunits of the oxidase. For these experiments, mutant proteins in which a single cysteine was replaced with alanine were expressed in p47PHOX-deficient Epstein-Barr virus-transformed B lymphoblasts, and O2- production by these transfected cells was measured. The activity of the mutant C98A was similar to that of wild type, but the maximum rate of O2- production by C196A was significantly larger than seen with wild type. The other two mutants (i.e., C111A and C378A) differed from wild type not only in maximum O2- production, but also in the time required for activation, which was considerably delayed with both of these mutants. The similarity in the time courses of oxidase activation with the C111A and C378A mutants, and the finding that C378A occurs in the sequence CSE, raises the possibility that these cysteines may be involved in redox regulation of oxidase activity.     

Hourglass pore-forming domains restrict aquaporin-1 tetramer assembly

The AQP1 water channel protein is a homotetramer with 28 kDa subunits containing six transmembrane domains. The sequence-related loops B (cytoplasmic) and E (extracellular) were predicted to overlap within the membrane, forming an aqueous pore ("the hourglass") flanked by the corresponding B and E residues 73 and 189. Cryoelectron microscopy of AQP1 previously revealed the central hourglass structure surrounded by six transmembrane helices which provide contact points between subunits. Several mutants in loop B and E residues were nonfunctional when expressed in X. laevis oocytes, but their ability to form tetramers is unknown. To explore the possible functional dependence of hourglass domains in adjacent subunits, we prepared a series of tandem dimers as single 55 kDa polypeptides containing different combinations of wild-type (AQP1) or mutant subunits (A73M or C189M). In oocytes, AQP1-AQP1 exhibited high osmotic water permeability, and AQP1-C189M exhibited half activity. Dimer polypeptides with A73M were nonfunctional or not expressed. In yeast secretory vesicles, AQP1-AQP1 exhibited high water permeability, AQP1-C189M exhibited half activity, and both were inhibited by pCMBS. Although expressed, the dimer polypeptides with A73M were all nonfunctional. Tetramer formation was investigated by detergent solubilization and velocity sedimentation through sucrose gradients. Dimer polypeptides containing one A73M subunit or two C189M subunits migrated with slower velocity (s < 3.5 S). In contrast, dimer polypeptides with one C189M subunit migrated with velocity similar to native AQP1 tetramers (s approximately 6 S). Thus, although hourglass pore-forming domains are not points of subunit-subunit contact, the structure of loop B is important to normal tetramer assembly.     

Relative functions of the alpha and beta subunits of the proteasome activator, PA28

PA28 is a 180,000-dalton protein that activates hydrolysis of small nonubiquitinated peptides by the 20 S proteasome. PA28 is composed of two homologous subunits, alpha and beta, arranged in alternating positions in a ring-shaped oligomer with a likely stoichiometry of (alphabeta)3. Our previous work demonstrated that the carboxyl terminus of the alpha subunit was necessary for PA28 to bind to and activate the proteasome. The goals of this work were to define the exact structural basis for this effect and to determine the relative roles of the alpha and beta subunits in proteasome activation. Each subunit and various mutants of the alpha subunit were expressed in Escherichia coli and purified. PA28alpha stimulated the proteasome, but had a much greater Kact than native heteromeric PA28. In contrast, PA28beta was unable to stimulate the proteasome. Mutants of the alpha subunit in which the carboxyl-terminal tyrosine residue was deleted or substituted with charged amino acids could neither bind to nor activate the proteasome. However, substitution of the carboxyl-terminal tyrosine with other amino acids resulted in proteins which could stimulate the proteasome to various extents. Tryptophan mutants stimulated the proteasome as well as did native PA28, whereas serine or phenylalanine mutants stimulated the proteasome much poorer than did wild type PA28alpha. Deletion of the "KEKE" motif, a 28-amino acid domain near the amino terminus of PA28alpha, had no effect on proteasome stimulatory activity. Hetero-oligomeric PA28 proteins were reconstituted from isolated wild type and mutant subunits. PA28 reconstituted from wild type subunits had structural and functional properties that were indistinguishable from those of the native hetero-oligomeric protein. PA28 molecules reconstituted from inactive alpha subunits and wild type beta subunits remained inactive. However, PA28 molecules reconstituted from suboptimally active alpha mutants and wild type beta subunits had the same activity as native heteromeric PA28. These results indicate that the beta subunit modulates PA28 activity, perhaps by influencing the affinity of PA28 for the proteasome.     

Effect of deletion from the carboxyl terminus of the 12 S subunit on activity of transcarboxylase

Transcarboxylase from Propionibacterium shermanii is a biotin-containing enzyme which catalyzes the reversible transfer of a carboxyl group from methylmalonyl-CoA to pyruvate. The central hexameric 12 S subunit of the enzyme associates with six 6 S subunits in the complete enzyme complex. We have constructed a series of cloned genes which encode COOH-terminal truncations of the 12 S subunit. Five of these subunits, which remained soluble following expression in Escherichia coli and were missing from 39 to 97 COOH-terminal amino acids, were purified and compared to the full-length subunit after enzyme complexes were assembled in vitro. All of the truncated subunits were 90% as active in the transcarboxylase reaction as wild type except the reaction containing the shortest complex, TC-12 S (1-507), which had 54% of the wild type activity (TC-12 S-WT). The reduced activity was not due to a lack of CoA ester binding sites or the Km for substrate. However, TC-12 S (1-507) was slower to form than TC-12 S-WT and had more incomplete complexes as judged by high performance liquid chromatography gel filtration profiles and electron microscopy. Isolated TC-12 S (1-507) was 70-80% as active as TC-12 S-WT. We also noted that the truncated form was heat-labile compared to wild type. We conclude that the COOH-terminal region of the 12 S subunit plays a role in assembly and stability of the hexamer and also affects the binding of 6 S subunits to form enzyme complexes. Once complexes do form, the catalytic capacity of TC-12 S (1-507) is almost the same as TC-12 S-WT.     

Tim9p, an essential partner subunit of Tim10p for the import of mitochondrial carrier proteins

Tim10p, a protein of the yeast mitochondrial intermembrane space, was shown previously to be essential for the import of multispanning carrier proteins from the cytoplasm into the inner membrane. We now identify Tim9p, another essential component of this import pathway. Most of Tim9p is associated with Tim10p in a soluble 70 kDa complex. Tim9p and Tim10p co-purify in successive chromatographic fractionations and co-immunoprecipitated with each other. Tim9p can be cross-linked to a partly translocated carrier protein. A small fraction of Tim9p is bound to the outer face of the inner membrane in a 300 kDa complex whose other subunits include Tim54p, Tim22p, Tim12p and Tim10p. The sequence of Tim9p is 25% identical to that of Tim10p and Tim12p. A Ser67-->Cys67 mutation in Tim9p suppresses the temperature-sensitive growth defect of tim10-1 and tim12-1 mutants. Tim9p is a new subunit of the TIM machinery that guides hydrophobic inner membrane proteins across the aqueous intermembrane space.     

The active sites of the eukaryotic 20 S proteasome and their involvement in subunit precursor processing

The 26 S proteasome is the central protease involved in ubiquitin-mediated protein degradation and fulfills vital regulatory functions in eukaryotes. The proteolytic core of the complex is the 20 S proteasome, a cylindrical particle with two outer rings each made of 7 different alpha-type subunits and two inner rings made of 7 different beta-type subunits. In the archaebacterial 20 S proteasome ancestor proteolytically active sites reside in the 14 uniform beta-subunits. Their N-terminal threonine residues, released by precursor processing, perform the nucleophilic attack for peptide bond hydrolysis. By directed mutational analysis of 20 S proteasomal beta-type proteins of Saccharomyces cerevisiae, we identified three active site-carrying subunits responsible for different peptidolytic activities as follows: Pre3 for post-glutamyl hydrolyzing, Pup1 for trypsin-like, and Pre2 for chymotrypsin-like activity. Double mutants harboring only trypsin-like or chymotrypsin-like activity were viable. Mutation of two potentially active site threonine residues in the Pre4 subunit excluded its catalytic involvement in any of the three peptidase activities. The generation of different, incompletely processed forms of the Pre4 precursor in active site mutants suggested that maturation of non-active proteasomal beta-type subunits is exerted by active subunits and occurs in the fully assembled particle. This trans-acting proteolytic activity might also account for processing intermediates of the active site mutated Pre2 subunit, which was unable to undergo autocatalytic maturation.     

The unique hetero-oligomeric nature of the subunits in the catalytic cooperativity of the yeast Cct chaperonin complex

The structural and functional organization of the Cct complex was addressed by genetic analyses of subunit interactions and catalytic cooperativity among five of the eight different essential subunits, Cct1p-Cct8p, in the yeast Saccharomyces cerevisiae. The cct1-1, cct2-3, and cct3-1 alleles, containing mutations at the conserved putative ATP-binding motif, GDGTT, are cold-sensitive, whereas single and multiple replacements of the corresponding motif in Cct6p are well tolerated by the cell. We demonstrated herein that cct6-3 (L19S), but not the parolog cct1-5 (R26I), specifically suppresses the cct1-1, cct2-3, and cct3-1 alleles, and that this suppression can be modulated by mutations in a putative phosphorylation motif, RXS, and the putative ATP-binding pocket of Cct6p. Our results suggest that the Cct ring is comprised of a single hetero-oligomer containing eight subunits of differential functional hierarchy, in which catalytic cooperativity of ATP-binding/hydrolysis takes place in a sequential manner different from the concerted cooperativity proposed for GroEL.     

Molecular organization of the 20S proteasome gene family from Arabidopsis thaliana

The 20S proteasome is the proteolytic complex in eukaryotes responsible for degrading short-lived and abnormal intracellular proteins, especially those targeted by ubiquitin conjugation. The 700-kD complex exists as a hollow cylinder comprising four stacked rings with the catalytic sites located in the lumen. The two outer rings and the two inner rings are composed of seven different alpha and beta polypeptides, respectively, giving an alpha7/beta7/beta7/alpha7 symmetric organization. Here we describe the molecular organization of the 20S proteasome from the plant Arabidopsis thaliana. From an analysis of a collection of cDNA and genomic clones, we identified a superfamily of 23 genes encoding all 14 of the Arabidopsis proteasome subunits, designated PAA-PAG and PBA-PBG for Proteasome Alpha and Beta subunits A-G, respectively. Four of the subunits likely are encoded by single genes, and the remaining subunits are encoded by families of at least 2 genes. Expression of the alpha and beta subunit genes appears to be coordinately regulated. Three of the nine Arabidopsis proteasome subunit genes tested, PAC1 (alpha3), PAE1 (alpha5) and PBC2 (beta3), could functionally replace their yeast orthologs, providing the first evidence for cross-species complementation of 20S subunit genes. Taken together, these results demonstrate that the 20S proteasome is structurally and functionally conserved among eukaryotes and suggest that the subunit arrangement of the Arabidopsis 20S proteasome is similar if not identical to that recently determined for the yeast complex.     

The mouse embryo culture system: improving the sensitivity for use as a quality control assay for human in vitro fertilization

Endurance training leads to an increase in the content of individual mitochondrial hemeproteins in skeletal muscle. To deduce the control mechanisms involved, cytochrome oxidase (COX) activity was compared with 1) the content of COX subunits III and IV and 2) 5-aminolevulinate synthase (ALAS) activity and mRNA content. In the plantaris muscle of female rats run daily for up to 28 days, ALAS activity was elevated 100% (P < 0.01) after 3 days and remained 150 and 125% higher (P < 0.001) after 7 and 28 days of running, respectively, than control. COX activity was also increased, but not until day 7 (40%; P < 0.05), and reached a maximal value 80% higher than control (P < 0.001) in the 28-day group. Compared with control, the content of COX subunit III and IV and ALAS mRNAs was not significantly changed by the training. The increased activities of COX and ALAS appear to be regulated by translational or posttranslational steps in the protein expression pathway. The induction of ALAS before COX suggests that the increased activity of COX may require increased synthesis of heme.     

Mutations in the A subunit affect yield, stability, and protease sensitivity of nontoxic derivatives of heat-labile enterotoxin

Heat-labile toxin (LT) is a protein related to cholera toxin, produced by enterotoxigenic Escherichia coli strains, that is organized as an AB5 complex. A number of nontoxic derivatives of LT, useful for new or improved vaccines against diarrheal diseases or as mucosal adjuvants, have been constructed by site-directed mutagenesis. Here we have studied the biochemical properties of the nontoxic mutants LT-K7 (Arg-7-->Lys), LT-D53 (Val-53-->Asp), LT-K63 (Ser-63-->Lys), LT-K97 (Val-97-->Lys), LT-K104 (Tyr-104-->Lys), LT-K114 (Ser-114-->Lys), and LT-K7/K97 (Arg-7-->Lys and Val-97-->Lys). We have found that mutations in the A subunit may have profound effects on the ability to form the AB5 structure and on the stability and trypsin sensitivity of the purified proteins. Unstable mutants, during long-term storage at 4 degrees C, showed a decrease in the amount of the assembled protein in solution and a parallel appearance of soluble monomeric B subunit. This finding suggests that the stability of the B pentamer is influenced by the A subunit which is associated with it. Among the seven nontoxic mutants tested, LT-K63 was found to be efficient in AB5 production, extremely stable during storage, resistant to proteolytic attack, and very immunogenic. In conclusion, LT-K63 is a good candidate for the development of antidiarrheal vaccines and mucosal adjuvants.