Strain-dependent occurrence of functional GTP:AMP phosphotransferase (AK3) in Saccharomyces cerevisiae

Proteome-wide discovery and characterizations of nucleotide-binding proteins with affinity-labeled chemical probes

Nucleotide-binding proteins play pivotal roles in many cellular processes including cell signaling. However, targeted studies of the subproteome of nucleotide-binding proteins, especially protein kinases and GTP-binding proteins, remain challenging. Here, we report a general strategy in using affinity-labeled chemical probes to enrich, identify, and quantify ATP- and GTP-binding proteins in the entire human proteome. Our results revealed that the ATP/GTP affinity probes facilitated the identification of 100 GTP-binding proteins and 206 kinases with the use of low milligram quantities of lysate of HL-60 cells. In combination with the use of the stable isotope labeling by amino acids in cell culture-based quantitative proteomics method, we assessed the ATP/GTP binding selectivities of nucleotide-binding proteins at the global proteome scale. Our results confirmed known and, more importantly, unveiled new ATP/GTP-binding preferences of hundreds of nucleotide-binding proteins. Additionally, our strategy led to the identification of three and one unique nucleotide-binding motifs for kinases and GTP-binding proteins, respectively, and the characterizations of the nucleotide-binding selectivities of individual motifs. Our strategy for capturing and characterizing ATP/GTP-binding proteins should be generally applicable for those proteins that can interact with other nucleotides.

Acid phosphatases of budding yeast as a model of choice for transcription regulation research

Acid phosphatases of budding yeast have been studied for more than forty years. This paper covers biochemical characteristics of acid phosphatases and different aspects in expression regulation of eukaryotic genes, which were researched using acid phosphatases model. A special focus is devoted to cyclin-dependent kinase Pho85p, a negative transcriptional regulator, and its role in maintaining mitochondrial genome stability and to pleiotropic effects of pho85 mutations.

2-D DIGE analysis of the mitochondrial proteome from human skeletal muscle reveals time course-dependent remodelling in response to 14 consecutive days of endurance exercise training

Adaptation of skeletal muscle to repeated bouts of endurance exercise increases aerobic capacity and improves mitochondrial function. However, the adaptation of human skeletal muscle mitochondrial proteome to short-term endurance exercise training has not been investigated. Eight sedentary males cycled for 60 min at 80% of peak oxygen consumption (VO(2peak) ) each day for 14 consecutive days, resulting in an increase in VO(2peak) of 17.5±3.8% (p<0.01). Mitochondria-enriched protein fractions from skeletal muscle biopsies taken from m. vastus lateralis at baseline, and on the morning following the 7th and 14th training sessions were subjected to 2-D DIGE analysis with subsequent MS followed by database interrogation to identify the proteins of interest. Thirty-one protein spots were differentially expressed after either 7 or 14 days of training (ANOVA, p<0.05). These proteins included subunits of the electron transport chain, enzymes of the tricarboxylic acid cycle, phosphotransfer enzymes, and regulatory factors in mitochondrial protein synthesis, oxygen transport, and antioxidant capacity. Several proteins demonstrated a time course-dependent induction during training. Our results illustrate the phenomenon of skeletal muscle plasticity with the extensive remodelling of the mitochondrial proteome occurring after just 7 days of exercise training suggestive of enhanced capacity for adenosine triphosphate generation at a cellular level.

Profiling the Monascus pilosus proteome during nitrogen limitation

Monascus species have the unique ability to economically produce many secondary metabolites. However, the influence of nitrogen limitation on Monascus secondary metabolite production and metabolic performance remains unclear. Varying the carbon/nitrogen (C/N) ratios in the range from 20 to 60 in cultivation of Monascus pilosus by glucose nitrate medium, our resulting data showed that red pigment production was significantly suppressed and more sensitive to nitrogen limitation than cellular biomass growth at a C/N ratio of 60. Using a comparative proteomic approach, combining two-dimensional gel electrophoresis, matrix-assisted laser desorption ionization time-of-flight/time-of-flight liquid chromatography-mass spectrometry, and tandem mass spectrometry, proteins with modified expression in the nitrogen-limited (C/N ratio 60) Monascus filamentous cells were identified. The results revealed that the deregulated proteins identified were involved in amino acid biosynthesis, protein translation, antioxidant-related enzymes, glycolysis, and transcriptional regulation. The results suggested that, under nitrogen limitation-induced suppression of protein translation and of expression of the related energy-generating enzymes, nitrogen limitation induced a switch of metabolic flux from glycolysis to the tricarboxylic acid (TCA) cycle for maintaining cellular energy homeostasis, resulting in repression of the metabolic shift of the polyketide biosynthesis pathway for red pigment production.

Identification of mitochondrial carriers in Saccharomyces cerevisiae by transport assay of reconstituted recombinant proteins

The inner membranes of mitochondria contain a family of carrier proteins that are responsible for the transport in and out of the mitochondrial matrix of substrates, products, co-factors and biosynthetic precursors that are essential for the function and activities of the organelle. This family of proteins is characterized by containing three tandem homologous sequence repeats of approximately 100 amino acids, each folded into two transmembrane alpha-helices linked by an extensive polar loop. Each repeat contains a characteristic conserved sequence. These features have been used to determine the extent of the family in genome sequences. The genome of Saccharomyces cerevisiae contains 34 members of the family. The identity of five of them was known before the determination of the genome sequence, but the functions of the remaining family members were not. This review describes how the functions of 15 of these previously unknown transport proteins have been determined by a strategy that consists of expressing the genes in Escherichia coli or Saccharomyces cerevisiae, reconstituting the gene products into liposomes and establishing their functions by transport assay. Genetic and biochemical evidence as well as phylogenetic considerations have guided the choice of substrates that were tested in the transport assays. The physiological roles of these carriers have been verified by genetic experiments. Various pieces of evidence point to the functions of six additional members of the family, but these proposals await confirmation by transport assay. The sequences of many of the newly identified yeast carriers have been used to characterize orthologs in other species, and in man five diseases are presently known to be caused by defects in specific mitochondrial carrier genes. The roles of eight yeast mitochondrial carriers remain to be established.

A GTP:AMP phosphotransferase, Adk2p, in Saccharomyces cerevisiae. Role of the C terminus in protein folding/stabilization, thermal tolerance, and enzymatic activity

Adenylate kinases participate in maintaining the homeostasis of cellular nucleotides. Depending on the yeast strains, the GTP:AMP phosphotransferase is encoded by the nuclear gene ADK2 with or without a single base pair deletion/insertion near the 3' end of the open reading frame, and the corresponding protein exists as either Adk2p (short) or Adk2p (long) in the mitochondrial matrix. These two forms are identical except that the three C-terminal residues of Adk2p (short) are changed in Adk2p (long), and the latter contains an additional nine amino acids at the C terminus of the protein. The short form of Adk2p has so far been considered to be inactive (Schricker, R., Magdolen, V., Strobel, G., Bogengruber, E., Breitenbach, M., and Bandlow, W. (1995) J. Biol. Chem. 270, 31103-31110). Using purified proteins, we show that at the physiological temperature for yeast growth (30 degrees C), both short and long forms of Adk2p are enzymatically active. However, in contrast to the short form, Adk2p (long) is quite resistant to thermal inactivation, urea denaturation, and degradation by trypsin. Unfolding of the long form by high concentrations of urea greatly stimulated its import into isolated mitochondria. Using an integration-based gene-swapping approach, we found that regardless of the yeast strains used, the steady state levels of endogenous Adk2p (long) in mitochondria were 5-10-fold lower compared with those of Adk2p (short). Together, these results suggest that the modified C-terminal domain in Adk2p (long) is not essential for enzyme activity, but it contributes to and strengthens protein folding and/or stability and is particularly important for maintaining enzyme activity under stress conditions.

Molecular cloning and characterization of a novel adenylate kinase 3 gene from Clonorchis sinensis

Adenylate kinase (AK) is a ubiquitous enzyme that contributes to the homeostasis of adenine nucleotides in living cells. AK catalyzes reversible high energy phosphoryl transfer reactions between ATP (or GTP) and AMP to generate ADP (or GDP). From a Clonorchis sinensis adult worm cDNA library, we isolated a cDNA clone encoding a novel AK3 isozyme. The 956 bp cDNA encodes a putative protein of 228 amino acids with a predicted molecular mass of 26.2 kDa. The recombinant CsAK3 protein produced in Escherichia coli can be refolded into a functional protein with AK3 activity. The optimum pH and temperature for the enzyme are 8.5 and 40 degrees C, respectively. The calculated activation energy is 56.04 kJ mol-1. The Km of the CsAK3 for AMP and GTP are 118 microM and 359 microM, respectively. CsAK3 is inhibited by Ap5A (>70% inhibition by 2.0 mM AP5A). Ap5A may be a potential lead compound acting on C. sinensis in which AK3 as a drug target.

Protein targeting of an unusual, evolutionarily conserved adenylate kinase to a eukaryotic flagellum

The eukaryotic flagellum is a large structure into which specific constituent proteins must be targeted, transported and assembled after their synthesis in the cytoplasm. Using Trypanosoma brucei and a proteomic approach, we have identified and characterized a novel set of adenylate kinase proteins that are localized to the flagellum. These proteins represent unique isoforms that are targeted to the flagellum by an N-terminal extension to the protein and are incorporated into an extraaxonemal structure (the paraflagellar rod). We show that the N-terminal extension is both necessary for isoform location in the flagellum and sufficient for targeting of a green fluorescent protein reporter protein to the flagellum. Moreover, these N-terminal extension sequences are conserved in evolution and we find that they allow the identification of novel adenylate kinases in the genomes of humans and worms. Given the existence of specific isoforms of certain central metabolic enzymes, and targeting sequences for these isoforms, we suggest that these isoforms form part of a complex, "solid-phase" metabolic capability that is built into the eukaryotic flagellum.

Identification of the mitochondrial GTP/GDP transporter in Saccharomyces cerevisiae

The genome of Saccharomyces cerevisiae contains 35 members of a family of transport proteins that, with a single exception, are found in the inner membranes of mitochondria. The transport functions of the 16 biochemically identified mitochondrial carriers are concerned with shuttling substrates, biosynthetic intermediates, and cofactors across the inner membrane. Here the identification and functional characterization of the mitochondrial GTP/GDP carrier (Ggc1p) is described. The ggc1 gene was overexpressed in bacteria. The purified protein was reconstituted into liposomes, and its transport properties and kinetic parameters were characterized. It transported GTP and GDP and, to a lesser extent, the corresponding deoxynucleotides and the structurally related ITP and IDP by a counter-exchange mechanism. Transport was saturable with an apparent K(m) of 1 microm for GTP and 5 microm for GDP. It was strongly inhibited by pyridoxal 5'-phosphate, bathophenanthroline, tannic acid, and bromcresol purple but little affected by the inhibitors of the ADP/ATP carrier carboxyatractyloside and bongkrekate. Furthermore, in contrast to the ADP/ATP carrier, the Ggc1p-mediated GTP/GDP heteroexchange is H(+)-compensated and thus electroneutral. Cells lacking the ggc1 gene had reduced levels of GTP and increased levels of GDP in their mitochondria. Furthermore, the knock-out of ggc1 results in lack of growth on nonfermentable carbon sources and complete loss of mitochondrial DNA. The physiological role of Ggc1p in S. cerevisiae is probably to transport GTP into mitochondria, where it is required for important processes such as nucleic acid and protein synthesis, in exchange for intramitochondrially generated GDP.

Redundant mitochondrial targeting signals in yeast adenylate kinase

Yeast adenylate kinase (Aky2p, Adk1p) occurs simultaneously in cytoplasm and mitochondrial intermembrane space. It has no cleavable mitochondrial targeting sequence, and the signal for mitochondrial import and submitochondrial sorting is largely unknown. The extreme N terminus of Aky2p is able to direct cytoplasmic passengers to mitochondria. However, an Aky2 mutant lacking this sequence is imported with about the same efficiency as the wild type. To identify possible import-relevant information in the interior, parts of Aky2p were exchanged by homologous in vitro recombination for the respective segments of the purely cytoplasmic isozyme, Ura6p. Import studies revealed an internal region of about 40 amino acids, which was sufficient to direct the chimera to mitochondria but not for correct submitochondrial sorting. The respective Ura6p hybrid was arrested in the mitochondrial membrane at a position where it was inaccessible to protease but was released by alkaline extraction, suggesting that it had entered an import channel and passed the initial steps of recognition and uptake. Site-specific mutations within the presumptive address-specifying segment identified the amphipathic helix 5. A Ura6 mutant protein in which helix 5 had been replaced with the respective sequence from Aky2p was imported, and this address sequence cooperates with the N terminus in the respective double mutant in a synergistic fashion.

Competition of spontaneous protein folding and mitochondrial import causes dual subcellular location of major adenylate kinase

Sorting of cytoplasmically synthesized proteins to their target compartments usually is highly efficient so that cytoplasmic precursor pools are negligible and a particular gene product occurs at one subcellular location only. Yeast major adenylate kinase (Adk1p/Aky2p) is one prominent exception to this rule. In contrast to most mitochondrial proteins, only a minor fraction (6-8%) is taken up into the mitochondrial intermembrane space, whereas the bulk of the protein remains in the cytosol in sequence-identical form. We demonstrate that Adk1p/Aky2p uses a novel mechanism for subcellular partitioning between cytoplasm and mitochondria, which is based on competition between spontaneous protein folding and mitochondrial targeting and import. Folding is spontaneous and rapid and can dispense with molecular chaperons. After denaturation, enzymatic activity of Adk1p/Aky2p returns within a few minutes and, once folded, the protein is thermally and proteolytically very stable. In an uncoupled cell-free organellar import system, uptake of Adk1p/Aky2p is negligible, but can be improved by previous chaotropic denaturation. Import ensues independently of Hsp70 or membrane potential. Thus, nascent Adk1p/Aky2p has two options: either it is synthesized to completion and folds into an enzymatically active import-incompetent conformation that remains in the cytosol; or, during synthesis and before commencement of significant tertiary structure formation, it reaches a mitochondrial surface receptor and is internalized.

Structure and expression of human mitochondrial adenylate kinase targeted to the mitochondrial matrix

The previously isolated cDNA encoding human adenylate kinase (AK) isozyme 3 was recently renamed AK4. Consequently, human AK3 cDNA remains to be identified and we have little information about the functional relationship between human AK3 and AK4. In pursuit of the physiological roles of both the AK3 and AK4 proteins, we first isolated an authentic human AK3 cDNA and compared their expression. Nucleotide sequencing revealed that the cDNA encoded a 227-amino-acid protein, with a deduced molecular mass of 25.6 kDa, that shares greater homology with the AK3 cDNAs isolated from bovine and rat than that from human. We named the isolated cDNA AK3. Northern-blot analysis revealed that AK3 mRNA was present in all tissues examined, and was highly expressed in heart, skeletal muscle and liver, moderately expressed in pancreas and kidney, and weakly expressed in placenta, brain and lung. On the other hand, we found that human AK4 mRNA was highly expressed in kidney, moderately expressed in heart and liver and weakly expressed in brain. Western-blot analysis demonstrated expression profiles of AK3 and AK4 that were similar to their mRNA expression patterns in each tissue. Over expression of AK3, but not AK4, in both Escherichia coli CV2, a temperature-sensitive AK mutant, and a human embryonic kidney-derived cell line, HEK-293, not only produced significant GTP:AMP phosphotransferase (AK3) activity, but also complemented the CV2 cells at 42 degrees C. Subcellular and submitochondrial fractionation analysis demonstrated that both AK3 and AK4 are localized in the mitochondrial matrix.

The essential protein fap7 is involved in the oxidative stress response of Saccharomyces cerevisiae

Pos9 (Skn7) is an important transcription factor that, together with Yap1, induces the expression of oxidative stress target genes in Saccharomyces cerevisiae. The activation of Pos9 upon an oxidative stress signal occurs post-translationally. In a mutant screen for factors involved in the activation of a Pos9-dependent reporter gene upon oxidative stress, we identified the mutant fap7-1 (for factor activating Pos9). This point mutant failed to activate a Gal4-Pos9 hybrid transcription factor, assayed by hydrogen peroxide-induced GAL1-lacZ reporter gene activities. Additionally, the fap7-1 mutant strain was sensitive to oxidative stress and revealed slow growth on glucose compared with the wild type. The fap7-1 mutation also affected the induction of the Pos9 target gene TPX1 and of a synthetic promoter previously identified to be regulated in a Yap1- and Pos9-dependent manner. This lack of induction was specific as the fap7-1 mutant response to other stresses such as sodium chloride or co-application of both hydrogen peroxide and sodium chloride was not affected, as tested with the Pos9-independent expression pattern of a TPS2-lacZ reporter system. We identified the gene YDL166c to be allelic to the FAP7 gene and to be essential. Fluorescence microscopy of Fap7-GFP fusion proteins indicated a nuclear localization of the Fap7 protein. Our data suggest that Fap7 is a nuclear factor important for Pos9-dependent target gene transcription upon oxidative stress.

Herpes simplex virus type 2 glycoprotein G-negative clinical isolates are generated by single frameshift mutations

Herpes simplex virus (HSV) codes for several envelope glycoproteins, including glycoprotein G-2 (gG-2) of HSV type 2 (HSV-2), which are dispensable for replication in cell culture. However, clinical isolates which are deficient in such proteins occur rarely. We describe here five clinical HSV-2 isolates which were found to be unreactive to a panel of anti-gG-2 monoclonal antibodies and therefore considered phenotypically gG-2 negative. These isolates were further examined for expression of the secreted amino-terminal and cell-associated carboxy-terminal portions of gG-2 by immunoblotting and radioimmunoprecipitation. The gG-2 gene was completely inactivated in four isolates, with no expression of the two protein products. For one isolate a normally produced secreted portion and a truncated carboxy-terminal portion of gG-2 were detected in virus-infected cell medium. Sequencing of the complete gG-2 gene identified a single insertion or deletion of guanine or cytosine nucleotides in all five strains, resulting in a premature termination codon. The frameshift mutations were localized within runs of five or more guanine or cytosine nucleotides and were dispersed throughout the gene. For the isolate for which a partially inactivated gG-2 gene was detected, the frameshift mutation was localized upstream of but adjacent to the nucleotides coding for the transmembranous region. Thus, this study demonstrates the existence of clinical HSV-2 isolates which do not express an envelope glycoprotein and identifies the underlying molecular mechanism to be a single frameshift mutation.

Influence of N-terminal sequence variation on the sorting of major adenylate kinase to the mitochondrial intermembrane space in yeast

Major adenylate kinase (Aky2p) from yeast has no cleavable presequence and occurs in identical form in the mitochondrial intermembrane space (6-8%) and in the cytoplasm (approx. 90%). To identify the signal(s) on Aky2p that might be required for mitochondrial import, the N-terminal region was examined. The N-terminus of Aky2p can guide at least two cytoplasmic passengers, dihydrofolate reductase from mouse and UMP kinase (Ura6p) from yeast, to the intermembrane space in vivo, showing that the N-terminus harbours import information. In contrast, deletion of the eight N-terminal amino acid residues or the introduction of two compensating frameshifts into this segment does not abolish translocation into the organelle's intermembrane space. Thus internal targeting and sorting information must be present in Aky2p as well. Neither a pronounced amphiphilic alpha-helical moment nor positive charges in the N-terminal region is a necessary prerequisite for Aky2p to reach the intermembrane space. Even a surplus of negative charges in mutant N-termini does not impede basal import into the correct submitochondrial compartment. The potential to form an amphipathic alpha-helical structure of five to eight residues close to the N-terminus significantly improves import efficiency, whereas extension of this amphipathic structure, e.g. by replacing it with the homologous segment of Aky3p, a mitochondrial matrix protein from yeast, leads to misdirection of the chimaera to the matrix compartment. This shows that the topogenic N-terminal signal of Aky3p is dominant over the presumptive internal intermembrane space-targeting signal of Aky2p and argues that the sorting of wild-type Aky2p to the intermembrane space is not due to the presence in the protein of a specific sorting sequence for the intermembrane space, but rather is the consequence of being imported but not being sorted to the inner compartment. Some Aky2 mutant proteins are susceptible to proteolysis in the cytoplasm, indicating incorrect folding. They are nevertheless efficiently rescued by uptake into mitochondria, suggesting a negative correlation between folding velocity (or folding stability) and efficiency of import.