A hybrid model to study pathological mutations of the human ADP/ATP carriers

The adenine nucleotide carrier (Ancp) plays an essential role in the metabolism of cellular energy by catalyzing the transport of ADP and ATP across the inner mitochondrial membrane. Previous reports have indicated that mutations in the HANC1 gene, encoding the muscle isoform of human Ancp (HAnc1p), are directly involved in several diseases, including autosomal dominant progressive external ophthalmoplegia and cardiomyopathies. In this work, we studied three pathogenic HANC1 mutations at the biochemical level. To do so, we expressed the DdANCA gene, encoding the unique Ancp carrier of Dictyostelium discoideum (DdAncAp), in a yeast strain lacking all endogenous ANC genes. Our results indicate that DdAncAp is a good model for the human protein. It allows the carrier to be studied in yeast, and provides information on how the HANC1 mutations impair ADP/ATP transport in humans. A94D, A126D and V291M mutations, corresponding to A90D, A123D and V289M in HAnc1p, respectively, did not affect levels of DdAncAp in yeast mitochondria. However, while the wild-type DdAncAp fully restored growth of the ANC-null yeast strain on a non-fermentable carbon source, the carriers encompassing either the A94D or the A126D mutation failed to complement the null strain. The effect of the V291M mutation was not as pronounced, but led to impairment mainly of the nucleotide translocation process per se. These findings provide new insights into the mechanisms responsible for the diseases induced by HAnc1p mutations.     

Valine 181 is critical for the nucleotide exchange activity of human mitochondrial ADP/ATP carriers in yeast

We isolated yeast Saccharomyces cerevisiae cells transformed with one of the three human adenine nucleotide carrier genes (HANC) that exhibited higher growth capacity than previously observed. The HANC genes were isolated from these clones, and we identified two independent mutations of HANC that led to replacement of valine 181 located in the fourth transmembrane segment by methionine or phenylalanine. Tolerance of this position toward substitution with various amino acids was systematically investigated, and since HANC/V181M was among the most efficient in growth complementation, it was more extensively studied. Here we show that increased growth capacities were associated with higher ADP/ATP exchange activities and not with higher human carrier amount in yeast mitochondria. These results are discussed in the light of the bovine Ancp structure, that shares more than 90% amino acid identity with Hancps, and its interaction with the lipid environment.     

The Saccharomyces cerevisiae ADP/ATP carrier-iso 1 cytochrome c fusion protein: one-step purification and functional analysis in vitro

Genetic expression versus plasmidic overexpression of a functional recombinant fusion protein combining the yeast Saccharomyces cerevisiae mitochondrial ADP/ATP carrier (Anc2p) and the iso-1-cytochrome c (Cyc1p) has been investigated, with the main aim of increasing the polar surface of the carrier to improve its crystallization properties. The gene encoding the his6-tagged fusion protein was expressed in yeast under the control of the regulatory sequences of ScANC2 or under the control of the strong yeast PMA1 promoter. In both cases, the chimeric carrier, Anc2-Cyc1(His6)p, was able to restore growth on a non-fermentable carbon source of a yeast strain devoid of functional ADP/ATP carrier, demonstrating its transport activity. Nevertheless, when the expression vector was used, the level of expression of Anc2-Cyc1(His6)p was no greater than that of the chimeric carrier obtained in yeast mitochondria after homologous recombination. Optimal conditions to extract and to purify Anc2-Cyc1(His6)p were determined. A series of detergents was screened for their ability to extract and to preserve in vitro the chimeric carrier. A rapid, single step purification of Anc2-Cyc1(His6)p was developed, using n-dodecyl-beta-d-maltoside (DoDM) as the best detergent to solubilize the chimeric protein. Carboxyatractyloside- (CATR-) and nucleotide-binding sites were preserved in the purified protein. Moreover, the Cyc1p moiety of Anc2-Cyc1(His6)p-CATR complex solubilized in DoDM was still able to interact in vitro with the cytochrome c oxidase (COX), with the same affinity as yeast Cyc1p. Improved production and purification of Anc2-Cyc1(His6)p-CATR complex opens up new possibilities for the use of this protein in crystallographic approaches to the yeast ADP/ATP carrier. Furthermore, Anc2-Cyc1(His6)p may be an useful molecular tool to investigate in vivo interactions between components of the respiratory chain complexes such as COX and the proteins implicated in ATP biogenesis, such as the ATP/ADP carrier.     

Functional characterization and purification of a Saccharomyces cerevisiae ADP/ATP carrier-iso 1 cytochrome c fusion protein

A recombinant fusion protein combining the mitochondrial ADP/ATP carrier (Anc2p) and the iso-1-cytochrome c (Cyc1p), both from Saccharomyces cerevisiae, has been genetically elaborated with the aim of increasing the polar surface area of the carrier to facilitate its crystallization. The gene encoding the his-tagged fusion protein was expressed in yeast under the control of the regulatory sequences of ScANC2. The chimeric carrier, Anc2-Cyc1(His6)p, was able to restore growth on a non-fermentable carbon source of a yeast strain devoid of functional ADP/ATP carrier, which demonstrated its transport activity. The kinetic exchange properties of Anc2-Cyc1(His6)p and the wild type his-tagged carrier Anc2(His6)p were very similar. However, Anc2-Cyc1(His6)p restored cell growth less efficiently than Anc2(His6)p which correlates with the lower amount found in mitochondria. Purification of Anc2-Cyc1(His6)p in complex with carboxyatractyloside (CATR), a high affinity inhibitor of ADP/ATP transport, was achieved by combining ion-exchange chromatography and ion-metal affinity chromatography in the presence of LAPAO, an aminoxide detergent. As characterized by absorption in the visible range, heme was found to be present in isolated Anc2-Cyc1(His6)p, giving the protein a red color. Large-scale purification of Anc2-Cyc1(His6)p-CATR complex opens up novel possibilities for the use of crystallographic approaches to the yeast ADP/ATP carrier.     

Growth defects in intramitochondrial energy depleted cells: role of mitochondrial biogenesis

Simultaneous inhibition of oxidative phosphorylation by rho- mutation and adenine nucleotide exchange by op1 mutation or bongkrekic acid results in intramitochondrial energy depletion and cessation of growth in yeast. Effect of energy depletion of mitochondria on mitochondrial biogenesis was studied in intact yeast cells. Immunoblot analysis revealed an overall decrease in cellular content of two mitochondrial proteins - ADP/ATP translocase and beta subunit of mitochondrial ATPase - together with their lower ability to reach the proper intramitochondrial compartment. Both effects indicate disturbed biogenesis of energy depleted mitochondria. Quantitative differences in growth abilities and mitochondrial damage observed in two studied systems - op1 rho- double mutants and rho- cells treated with bongkrekic acid - can be explained by different degree of intramitochondrial energy depletion due to leakiness of op1 mutation in op1 rho- cells.     

Substrate-site interactions in the membrane-bound adenine-nucleotide carrier as disclosed by ADP and ATP analogs

The binding parameters of a number of ADP or ATP analogs to the adenine nucleotide carrier in mitochondria and inside-out submitochondrial particles have been explored by means of two specific inhibitors, carboxyatractyloside and bongkrekic acid. The nucleotides tested fell into two classes depending on the shape of the binding curve. Curvilinear Scatchard plots were obtained for the binding of ADP, ATP, adenosine 5'-triphospho-gamma-1-(5-sulfonic acid)naphthylamidate [gamma-AmNS)ATP) and adenylyl (beta,gamma)-methylenediphosphate (p[CH2]ppA); on the other hand, rectilinear Scatchard plots were obtained in the case of naphthoyl-ADP (N-ADP) and 8-bromo ADP (8Br-ADP) binding. The total number of binding sites for N-ADP and 8Br-ADP could be extrapolated with good accuracy to 1.3-1.5 nmol/mg protein; this value corresponds to the number of carboxyatractyloside-binding sites in heart mitochondria (Block, M.R., Pougeois, R. and Vignais, P.V. (1980) FEBS Lett. 117, 335-340). On the other hand, because of the curvilinearity of the Scatchard plots for the binding of ADP, ATP, (gamma-AmNS)ATP and p[CH2]ppA, the total number of binding sites for these nucleotides could only be approximated to a value higher than 1 nmol/mg protein, the exact value being probably equal to that found for N-ADP and 8Br-ADP binding, i.e. 1.3-1.5 nmol/mg protein. Curvilinearity of Scatchard plots was discussed in terms of negative interactions between nucleotide-binding sites located on the same face of the adenine nucleotide carrier. A possible relationship between the features of the binding plots and the transportable nature of the nucleotide is discussed. Contrary to the enhancing effect of bongkrekic acid on [14C]ADP uptake observed essentially in nucleotide-depleted heart mitochondria (Klingenberg, M., Appel, M., Babel, W. and Aquila, H. (1983) Eur. J. Biochem. 131, 647-654), binding of bongkrekic acid to nondepleted heart mitochondria was found to partially displace previously bound [14C]ADP. These opposite effects of bongkrekic acid may be explained by assuming that bongkrekic acid is able to abolish negative cooperativity between external (cytosolic) ADP-binding sites.     

Yeast mitochondria import ATP through the calcium-dependent ATP-Mg/Pi carrier Sal1p, and are ATP consumers during aerobic growth in glucose

Sal1p, a novel Ca²⁺-dependent ATP-Mg/Pi carrier, is essential in yeast lacking all adenine nucleotide translocases. By targeting luciferase to the mitochondrial matrix to monitor mitochondrial ATP levels, we show in isolated mitochondria that both ATP-Mg and free ADP are taken up by Sal1p with a K _m of 0.20 ± 0.03 mM and 0.28 ± 0.06 mM respectively. Nucleotide transport along Sal1p is strictly Ca²⁺ dependent. Ca²⁺ increases the V _max with a S _0.5 of 15 μM, and no changes in the K _m for ATP-Mg. Glucose sensing in yeast generates Ca²⁺ transients involving Ca²⁺ influx from the external medium. We find that carbon-deprived cells respond to glucose with an immediate increase in mitochondrial ATP levels which is not observed in the presence of EGTA or in Sal1p-deficient cells. Moreover, we now report that during normal aerobic growth on glucose, yeast mitochondria import ATP from the cytosol and hydrolyse it through H⁺-ATP synthase. We identify two pathways for ATP uptake in mitochondria, the ADP/ATP carriers and Sal1p. Thus, during exponential growth on glucose, mitochondria are ATP consumers, as those from cells growing in anaerobic conditions or deprived of mitochondrial DNA which depend on cytosolic ATP and mitochondrial ATPase working in reverse to generate a mitochondrial membrane potential. In conclusion, the results show that growth on glucose requires ATP hydrolysis in mitochondria and recruits Sal1p as a Ca²⁺-dependent mechanism to import ATP-Mg from the cytosol. Whether this mechanism is used under similar settings in higher eukaryotes is an open question.     

Kinetics of nucleotide transport in rat heart mitochondria studied by a rapid filtration technique

A rapid filtration technique has been used to measure at room temperature the kinetics of ADP and ATP transport in rat heart mitochondria in the millisecond time range. Transport was stopped by cessation of the nucleotide supply, without the use of a transport inhibitor, thus avoiding any quenching delay. The mitochondria were preincubated for 30 s either in isotonic KCl containing succinate, MgCl2, and Pi (medium P) or in isotonic KCl supplemented only with EDTA and Tris (medium K); they were referred to as energized and resting mitochondria, respectively. The kinetics of [14C]ADP transport in energized mitochondria were apparently monophasic. The plateau value for [14C]ADP uptake reached 4-5 nmol of nucleotide.(mg of protein)-1. Vmax values for [14C]ADP transport of 400-450 nmol exchanged.min-1.(mg of protein)-1 with Km values of the order of 13-15 microM were calculated, consistent with rates of phosphorylation in the presence of succinate of 320-400 nmol of ATP formed.min-1.(mg of protein)-1. The rate of transport of [14C]ATP in energized mitochondria was 5-10 times lower than that of [14C]ADP. Upon uncoupling, the rate of [14C]ATP uptake was enhanced, and that of [14C]ADP uptake was decreased. However, the two rates did not equalize, indicating that transport was not exclusively electrogenic. Transport of [14C]ADP and [14C]ATP by resting mitochondria followed biphasic kinetics.(ABSTRACT TRUNCATED AT 250 WORDS)     

Functional characterization and localization of acetyl-CoA hydrolase,Ach1p,in Saccharomyces cerevisiae

Acetyl-CoA hydrolase (Ach1p), catalyzing the hydrolysis of acetyl-CoA, is presumably involved in regulating intracellular acetyl-CoA or CoASH pools; however, its intracellular functions and distribution remain to be established. Using site-directed mutagenesis analysis, we demonstrated that the enzymatic activity of Ach1p is dependent upon its putative acetyl-CoA binding sites. The ach1 mutant causes a growth defect in acetate but not in other non-fermentable carbon sources, suggesting that Ach1p is not involved in mitochondrial biogenesis. Overexpression of Ach1p, but not constructs containing acetyl-CoA binding site mutations, in ach1-1 complemented the defect of acetate utilization. By subcellular fractionation, most of the Ach1p in yeast was distributed with mitochondria and little Ach1p in the cytoplasm. By immunofluorescence microscopy, we show that Ach1p and acetyl-CoA binding site-mutated constructs, but not its N-terminal deleted construct, are localized in mitochondria. Moreover, the onset of pseudohyphal development in homozygote ach1-1 diploids was abolished. We infer that Ach1p may be involved in a novel acetyl-CoA biogenesis and/or acetate utilization in mitochondria and thereby indirectly affect pseudohyphal development in yeast.     

Characterization of an ectonucleoside triphosphate diphosphohydrolase 1 activity in alkaline phosphatase-depleted rat osseous plate membranes: possible functional involvement in the calcification process

An ectonucleoside triphosphate diphosphohydrolase 1 (NTPDase1) activity present in alkaline phosphatase-depleted rat osseous plate membranes, obtained 14 days after implantation of demineralized bone particles in the subcutaneous tissue of Wistar rats, was characterized. At pH 7.5, NTPDase1 hydrolyzed nucleotide triphosphates at rates 2.4-fold higher than those of nucleotide diphosphates, while the hydrolysis of nucleotide monophosphates and non-nucleotide phosphates was negligible. NTPDase 1 hydrolyzed ATP and ADP following Michaelis-Menten kinetics with V=1278.7+/-38.4 nmol Pi/min/mg and K(M)=83.3+/-2.5 microM and V=473.9+/-18.9 nmol Pi/min/mg and K(M)=150.6+/-6.0 microM, respectively, but in the absence of magnesium and calcium ions, ATP or ADP hydrolysis was negligible. The stimulation of the NTPDase1 by calcium (V=1084.7+/-32.5 nmol Pi/min/mg; and K(M)=377.8+/-11.3 microM) and magnesium (V=1367.2+/-41.0 nmol Pi/min/mg and K(M)=595.3+/-17.8 microM) ions suggested that each ion could replace the other during the catalytic cycle of the enzyme. Oligomycin, ouabain, bafilomycin A(1), theophylline, thapsigargin, ethacrynic acid, P(1),P(5)-(adenosine-5')-pentaphosphate and omeprazole had negligible effects on the hydrolysis of ATP and ADP by NTPDase1. However, suramin and sodium azide were effective inhibitors of ATP and ADP hydrolysis.To our knowledge this is the first report suggesting the presence of NTPDase1 in rat osseous plate membranes. Considering that the ectonucleoside triphosphate diphosphohydrolase family of enzymes participates in many regulatory functions, such as response to hormones, growth control, and cell differentiation, the present observations raise interesting questions about the participation of this activity in the calcification process.     

Mitochondrial affinity for ADP is twofold lower in creatine kinase knock-out muscles. Possible role in rescuing cellular energy homeostasis

Adaptations of the kinetic properties of mitochondria in striated muscle lacking cytosolic (M) and/or mitochondrial (Mi) creatine kinase (CK) isoforms in comparison to wild-type (WT) were investigated in vitro. Intact mitochondria were isolated from heart and gastrocnemius muscle of WT and single- and double CK-knock-out mice strains (cytosolic (M-CK-/-), mitochondrial (Mi-CK-/-) and double knock-out (MiM-CK-/-), respectively). Maximal ADP-stimulated oxygen consumption flux (State3 Vmax; nmol O2 x mg mitochondrial protein(-1) x min(-1)) and ADP affinity (K50ADP; microM) were determined by respirometry. State 3 Vmax and of M-CK-/- and MiM-CK-/- gastrocnemius mitochondria were twofold higher than those of WT, but were unchanged for Mi-CK-/-. For mutant cardiac mitochondria, only the of mitochondria isolated from the MiM-CK-/- phenotype was different (i.e. twofold higher) than that of WT. The implications of these adaptations for striated muscle function were explored by constructing force-flow relations of skeletal muscle respiration. It was found that the identified shift in affinity towards higher ADP concentrations in MiM-CK-/- muscle genotypes may contribute to linear mitochondrial control of the reduced cytosolic ATP free energy potentials in these phenotypes.     

Interaction of (3H) bongkrekic acid with the mitochondrial adenine nucleotide translocator.

Chemical labeling by 3H and biosynthetic labeling by 14C of bongkrekic acid (BA) are described. In the rat liver cell, mitochondria are the only subcellular particles to bind [3H]BA with high affinity. The high affinity sites for BA in mitochondria are located in the inner membrane. High affinity binding sites for BA are only displayed at pH below 7; they amount to 0.15-0.20 nmol/mg of protein in rat liver mitochondria and to 1.1-1.3 nmol/mg of protein in rat heart mitochondria. These values are similar to those found for the high affinity atractyloside binding sites and for the carboxyatractyloside binding sites. The kinetic parameters for BA binding to rat heart mitochondria at 20 degrees C are Kd = 10-40 X 10(-9) M, k+1 = 0.7 X 10(5) M-1 s-1, k-1 = 1.4 X 10(-3) M s-1. Binding assays carried out with rat heart mitochondria, under equilibrium conditions, showed that the amount of BA bound to high affinity sites increases with temperature and reaches the maximum value of 1.1-1.3 nmol/mg of protein at 32-35 degrees C. At lower temperatures, and under equilibrium conditions, a significant fraction of high affinity sites remains masked and is not titrated by BA; these masked BA sites are revealed by addition of micromolar concentrations of ADP or by energization of the mitochondria. Carboxyatractyloside added to rat heart mitochondria preloaded with [3H]BA is able to displace part of the bound [3H]BA. Displacement of the bound BA is enhanced by simultaneous additions of carboxyatractyloside plus ADP, or by energization of the mitochondria. The synergistic effect of carboxyatractyloside and ADP on displacement of bound [3H]BA is also observed in isolated inner membrane vesicles from rat liver mitochondria. When BA is preincubated with rat heart mitochondria before addition of [14C]ADP for assay of ADP transport, the inhibition of ADP transport is a mixed-type inhibition. When BA is preincubated with the mitochondria together with a very small concentration of ADP (less than 0.5 muM), the inhibition of [14C]ADP transport is markedly increased (up to ten times) and it becomes typically uncompetitive, which suggests the formation of a ternary complex, carrier-ADP-BA. The transition from a mixed-type inhibition, with high Ki value, to an uncompetitive type of inhibition, with low Ki value, upon addition of ADP, is explained by an ADP-induced conformational change of the ADP translocator.     

Expression of the mitochondrial ADP/ATP carrier in Escherichia coli. Renaturation, reconstitution, and the effect of mutations on 10 positive residues

Previously, the role of residues in the ADP/ATP carrier (AAC) from Saccharomyces cerevisiae has been studied by mutagenesis, but the dependence of mitochondrial biogenesis on functional AAC impedes segregation of the mutational effects on transport and biogenesis. Unlike other mitochondrial carriers, expression of the AAC from yeast or mammalians in Escherichia coli encountered difficulties because of disparate codon usage. Here we introduce the AAC from Neurospora crassa in E. coli, where it is accumulated in inclusion bodies and establish the reconstitution conditions. AAC expressed with heat shock vector gave higher activity than with pET-3a. Transport activity was absolutely dependent on cardiolipin. The 10 single mutations of intrahelical positive residues and of the matrix repeat (+X+) motif resulted in lower activity, except of R245A. R143A had decreased sensitivity toward carboxyatractylate. The ATP-linked exchange is generally more affected than ADP exchange. This reflects a charge network that propagates positive charge defects to ATP(4-) more strongly than to ADP(3-) transport. Comparison to the homologous mutants of yeast AAC2 permits attribution of the roles of these residues more to ADP/ATP transport or to AAC import into mitochondria.     

The La protein functions redundantly with tRNA modification enzymes to ensure tRNA structural stability

Although the La protein stabilizes nascent pre-tRNAs from nucleases, influences the pathway of pre-tRNA maturation, and assists correct folding of certain pre-tRNAs, it is dispensable for growth in both budding and fission yeast. Here we show that the Saccharomyces cerevisiae La shares functional redundancy with both tRNA modification enzymes and other proteins that contact tRNAs during their biogenesis. La is important for growth in the presence of mutations in either the arginyl tRNA synthetase or the tRNA modification enzyme Trm1p. In addition, two pseudouridine synthases, PUS3 and PUS4, are important for growth in strains carrying a mutation in tRNA(Arg)(CCG) and are essential when La is deleted in these strains. Depletion of Pus3p results in accumulation of the aminoacylated mutant tRNA(Arg)(CCG) in nuclei, while depletion of Pus4p results in decreased stability of the mutant tRNA. Interestingly, the degradation of mutant unstable forms of tRNA(Arg)(CCG) does not require the Trf4p poly(A) polymerase, suggesting that yeast cells possess multiple pathways for tRNA decay. These data demonstrate that La functions redundantly with both tRNA modifications and proteins that associate with tRNAs to achieve tRNA structural stability and efficient biogenesis.     

Properties of the human erythrocyte glucose transport protein are determined by cellular context

Human erythrocyte hexose transfer is mediated by the glucose transport protein GLUT1 and is characterized by a complexity that is unexplained by available hypotheses for carrier-mediated sugar transport [Cloherty, E. K., Heard, K. S., and Carruthers, A. (1996) Biochemistry 35, 10411-10421]. The study presented here examines the possibility that the operational properties of GLUT1 are determined by host cell environment. A glucose transport-null strain of Saccharomyces cerevisiae (RE700A) was transfected with the p426 GPD yeast expression vector containing DNA encoding the wild-type human glucose transport protein (GLUT1), mutant GLUT1 (GLUT1(338)(-)(A3)), or carboxy-terminal hemagglutinin-polyHis-tagged GLUT1 (GLUT1-HA-H6). GLUT1 and GLUT1-HA-H6 are expressed at the yeast cell membrane and restore 2-deoxy-d-glucose, 3-O-methylglucose, and d-glucose transport capacity to RE700A. GLUT1-HA-H6 confers GLUT1-specific sugar transport characteristics to transfected RE700A, including inhibition by cytochalasin B and high-affinity transport of the nonmetabolized sugar 3-O-methylglucose. GLUT1(338)(-)(A3), a catalytically inactive GLUT1 mutant, is expressed but fails to restore RE700A sugar uptake capacity or growth on glucose. In contrast to transport in human red cells, K(m(app)) for 2-deoxy-d-glucose uptake equals K(i(app)) for 2-deoxy-d-glucose inhibition of 3-O-methylglucose uptake. Unlike transport in human red cells or transport in human embryonic kidney cells transfected with GLUT1-HA-H6, unidirectional sugar uptake in RE700A-GLUT1-HA-H6 is not inhibited by reductant and is not stimulated by intracellular sugar. Net uptake of subsaturating 3-O-methylglucose by RE700A-GLUT1-HA-H6 is a simple, first-order process. These findings support the hypothesis that red cell sugar transport complexity is host cell-specific.     

Differential RNA-dependent ATPase activities of four rRNA processing yeast DEAD-box proteins

S. cerevisiae ribosome biogenesis is a highly ordered and dynamic process that involves over 100 accessory proteins, including 18 DExD/H-box proteins that act at discrete steps in the pathway. Although often termed RNA helicases, the biochemical functions of individual DExD/H-box proteins appear to vary considerably. Four DExD/H-box proteins, Dbp3p, Dbp4p, Rok1p, and Rrp3p, involved in yeast ribosome assembly were expressed in E. coli, and all were found to be active RNA-dependent ATPases with k(cat) values ranging from 13 to 170 min(-1) and K(M)(ATP) values ranging from 0.24 to 2.3 mM. All four proteins are activated by single-stranded oligonucleotides, but they require different chain lengths for maximal ATPase activity, ranging from 10 to >40 residues. None of the four proteins shows significant specificity for yeast rRNA, compared to nonspecific control RNAs since these large RNAs contain multiple binding sites that appear to be catalytically similar. This systematic comparison of four members of the DExD/H-box family demonstrates a range of biochemical properties and lays the foundation for relating the activities of proteins to their biological functions.     

Conserved functions of Arabidopsis mitochondrial late-acting maturation factors in the trafficking of iron‑sulfur clusters

Numerous proteins require iron?sulfur (Fe-S) clusters as cofactors for their function. Their biogenesis is a multi-step process occurring in the cytosol and mitochondria of all eukaryotes and additionally in plastids of photosynthetic eukaryotes. A basic model of Fe-S protein maturation in mitochondria has been obtained based on studies achieved in mammals and yeast, yet some molecular details, especially of the late steps, still require investigation. In particular, the late-acting biogenesis factors in plant mitochondria are poorly understood. In this study, we expressed the factors belonging to NFU, BOLA, SUFA/ISCA and IBA57 families in the respective yeast mutant strains. Expression of the Arabidopsis mitochondrial orthologs was usually sufficient to rescue the growth defects observed on specific media and/or to restore the abundance or activity of the defective Fe-S or lipoic acid-dependent enzymes. These data demonstrate that the plant mitochondrial counterparts, including duplicated isoforms, likely retained their ancestral functions. In contrast, the SUFA1 and IBA57.2 plastidial isoforms cannot rescue the lysine and glutamate auxotrophies of the respective isa1-isa2Δ and iba57Δ strains or of the isa1-isa2-iba57Δ triple mutant when expressed in combination. This suggests a specialization of the yeast mitochondrial and plant plastidial factors in these late steps of Fe-S protein biogenesis, possibly reflecting substrate-specific interactions in these different compartments.     

The role of the 3' untranslated region in mRNA sorting to the vicinity of mitochondria is conserved from yeast to human cells

We recently demonstrated, using yeast DNA microarrays, that mRNAs of polysomes that coisolate with mitochondria code for a subset of mitochondrial proteins. The majority of these mRNAs encode proteins of prokaryotic origin. Herein, we show that a similar association occurs between polysomes and mitochondria in human cells. To determine whether mRNA transport machinery is conserved from yeast to human cells, we examined the subcellular localization of human OXA1 mRNA in yeast. Oxa1p is a key component in the biogenesis of mitochondrial inner membrane and is conserved from bacteria to eukaryotic organelles. The expression of human OXA1 cDNA partially restores the respiratory capacity of yeast oxa1- cells. In this study, we demonstrate that 1) OXA1 mRNAs are remarkably enriched in mitochondrion-bound polysomes purified from yeast and human cells; 2) the presence of the human OXA1 3' untranslated region (UTR) is required for the function of the human Oxa1p inside yeast mitochondria; and 3) the accurate sorting of the human OXA1 mRNA to the vicinity of yeast mitochondria is due to the recognition by yeast proteins of the human 3' UTR. Therefore, it seems that the recognition mechanism of OXA1 3' UTR is conserved throughout evolution and is necessary for Oxa1p function.     

Reg1p targets protein phosphatase 1 to dephosphorylate hexokinase II in Saccharomyces cerevisiae: characterizing the effects of a phosphatase subunit on the yeast proteome.

Protein phosphatase 1 (Glc7p) and its binding protein Reg1p are essential for the regulation of glucose repression pathways in Saccharomyces cerevisiae. In order to identify physiological substrates for the Glc7p-Reg1p complex, we examined the effects of deletion of the REG1 gene on the yeast phosphoproteome. Analysis by two-dimensional phosphoprotein mapping identified two distinct proteins that were greatly increased in phosphate content in reg1Delta mutants. Mixed peptide sequencing identified these proteins as hexokinase II (Hxk2p) and the E1alpha subunit of pyruvate dehydrogenase. Consistent with increased phosphorylation of Hxk2p in response to REG1 deletion, fractionation of yeast extracts by anion-exchange chromatography identified Hxk2p phosphatase activity in wild-type strains that was selectively lost in the reg1Delta mutant. The phosphorylation state of Hxk2p and Hxk2p phosphatase activity was restored to wild-type levels in the reg1Delta mutant by expression of a LexA-Reg1p fusion protein. In contrast, expression of LexA-Reg1p containing mutations at phenylalanine in the putative PP-1C-binding site motif (K/R)(X)(I/V)XF was unable to rescue Hxk2p dephosphorylation in intact yeast or restore Hxk2p phosphatase activity. These results demonstrate that Reg1p targets PP-1C to dephosphorylate Hxk2p in vivo and that the motif (K/R)(X) (I/V)XF is necessary for its PP-1 targeting function.