Different carbon sources affect lifespan and protein redox state during Saccharomyces cerevisiae chronological ageing.

In this study, a proteomic approach that combines selective labelling of proteins containing reduced cysteine residues with two-dimensional electrophoresis/mass spectrometry was used to evaluate the redox state of protein cysteines during chronological ageing in Saccharomyces cerevisiae. The procedure was developed on the grounds that biotin-conjugated iodoacetamide (BIAM) specifically reacts with reduced cysteine residues. BIAM-labelled proteins can then be selectively isolated by streptavidin affinity capture. We compared cells grown on 2% glucose in the exponential phase and during chronological ageing and we found that many proteins undergo cysteine oxidation. The target proteins include enzymes involved in glucose metabolism. Both caloric restriction and growth on glycerol resulted in a decrease in the oxidative modification. Furthermore, in these conditions a reduced production of ROS and a more negative glutathione half cell redox potential were observed.

Expression of the Stp1 LMW-PTP and inhibition of protein CK2 display a cooperative effect on immunophilin Fpr3 tyrosine phosphorylation and Saccharomyces cerevisiae growth.

Although the yeast genome does not encode bona fide protein tyrosine kinases, tyrosine-phosphorylated proteins are numerous, suggesting that besides dual-specificity kinases, some Ser/Thr kinases are also committed to tyrosine phosphorylation in Saccharomyces cerevisiae. Here we show that blockage of the highly pleiotropic Ser/Thr kinase CK2 with a specific inhibitor synergizes with the overexpression of Stp1 low-molecular-weight protein tyrosine phosphatase (PTP) in inducing a severe growth-defective phenotype, consistent with a prominent role for CK2 in tyrosine phosphorylation in yeast. We also present in vivo evidence that immunophilin Fpr3, the only tyrosine-phosphorylated CK2 substrate recognized so far, interacts with and is dephosphorylated by Spt1. These data disclose a functional correlation between CK2 and LMW-PTPs, and suggest that reversible phosphorylation of Fpr3 plays a role in the regulation of growth rate and budding in S. cerevisiae.

Expression of the small tyrosine phosphatase (Stp1) in Saccharomyces cerevisiae: a study on protein tyrosine phosphorylation.

Small tyrosine phoshatase 1 (Stp1) is a Schizosaccharomyces pombe low-molecular-mass phosphotyrosine-phosphatase 50% identical to Saccharomyces cerevisiae Ltp1. In order to investigate the role of Stp1 in yeast, a mutant was generated having the characteristic of a dominant negative molecule. Changes in protein tyrosine phosphorylation in S. cerevisiae proteome in response to Stp1 or its dominant negative mutant expression were analyzed by high-resolution two-dimensional (2-D) electrophoresis. The most remarkable result is the modification by phosphorylation on tyrosine of several proteins involved in carbohydrate metabolism. Twelve proteins were identified on the basis of their positions in the anti-phosphotyrosine immunoblot of the 2-D electrophoresis. Ten of these present tyrosyl residues that are within the consensus sequence for protein kinase CK2 (casein kinase-2). These data open the possibility for the identification of Stp1 substrates in yeast and provide hints about the nature of tyrosine phosphorylating agents in yeast and in other organisms where bona fide tyrosine kinases are lacking.

Mmf1p, a novel yeast mitochondrial protein conserved throughout evolution and involved in maintenance of the mitochondrial genome.

A novel protein family (p14.5, or YERO57c/YJGFc) highly conserved throughout evolution has recently been identified. The biological role of these proteins is not yet well characterized. Two members of the p14.5 family are present in the yeast Saccharomyces cerevisiae. In this study, we have characterized some of the biological functions of the two yeast proteins. Mmf1p is a mitochondrial matrix factor, and homologous Mmf1p factor (Hmf1p) copurifies with the soluble cytoplasmic fraction. Deltammf1 cells lose mitochondrial DNA (mtDNA) and have a decreased growth rate, while Deltahmf1 cells do not display any visible phenotype. Furthermore, we demonstrate by genetic analysis that Mmf1p does not play a direct role in replication and segregation of the mtDNA. rho(+) Deltammf1 haploid cells can be obtained when tetrads are directly dissected on medium containing a nonfermentable carbon source. Our data also indicate that Mmf1p and Hmf1p have similar biological functions in different subcellular compartments. Hmf1p, when fused with the Mmf1p leader peptide, is transported into mitochondria and is able to functionally replace Mmf1p. Moreover, we show that homologous mammalian proteins are functionally related to Mmf1p. Human p14.5 localizes in yeast mitochondria and rescues the Deltammf1-associated phenotypes. In addition, fractionation of rat liver mitochondria showed that rat p14.5, like Mmf1p, is a soluble protein of the matrix. Our study identifies a biological function for Mmf1p and furthermore indicates that this function is conserved between members of the p14.5 family.

Mutational analysis of acylphosphatase suggests the importance of topology and contact order in protein folding.

Muscle acylphosphatase (AcP) is a small protein that folds very slowly with two-state behavior. The conformational stability and the rates of folding and unfolding have been determined for a number of mutants of AcP in order to characterize the structure of the folding transition state. The results show that the transition state is an expanded version of the native protein, where most of the native interactions are partially established. The transition state of AcP turns out to be remarkably similar in structure to that of the activation domain of procarboxypeptidase A2 (ADA2h), a protein having the same overall topology but sharing only 13% sequence identity with AcP. This suggests that transition states are conserved between proteins with the same native fold. Comparison of the rates of folding of AcP and four other proteins with the same topology, including ADA2h, supports the concept that the average distance in sequence between interacting residues (that is, the contact order) is an important determinant of the rate of protein folding.

A novel interaction mechanism accounting for different acylphosphatase effects on cardiac and fast twitch skeletal muscle sarcoplasmic reticulum calcium pumps.

In cardiac and skeletal muscle Ca2+ translocation from cytoplasm into sarcoplasmic reticulum (SR) is accomplished by different Ca2+-ATPases whose functioning involves the formation and decomposition of an acylphosphorylated phosphoenzyme intermediate (EP). In this study we found that acylphosphatase, an enzyme well represented in muscular tissues and which actively hydrolyzes EP, had different effects on heart (SERCA2a) and fast twitch skeletal muscle SR Ca2+-ATPase (SERCA1). With physiological acylphosphatase concentrations SERCA2a exhibited a parallel increase in the rates of both ATP hydrolysis and Ca2+ transport; in contrast, SERCA1 appeared to be uncoupled since the stimulation of ATP hydrolysis matched an inhibition of Ca2+ pump. These different effects probably depend on phospholamban, which is associated with SERCA2a but not SERCA1. Consistent with this view, the present study suggests that acylphosphatase-induced stimulation of SERCA2a, in addition to an enhanced EP hydrolysis, may be due to a displacement of phospholamban, thus to a removal of its inhibitory effect.

Cloning of murine low molecular weight phosphotyrosine protein phosphatase cDNA: identification of a new isoform.

The low molecular weight phosphotyrosine protein phosphatase (LMW-PTP) is a 18 kDa cytosolic enzyme, involved in the negative regulation of cell proliferation. In different mammalian species LMW-PTPs are expressed in two molecular forms produced from a single primary transcript through an alternative splicing mechanism. In this paper we report the cloning, expression and characterization of mouse isoforms of LMW-PTPs (called m-IF1 and m-IF2), very similar to the corresponding rat and human isoenzymes. Moreover we have identified a third cDNA encoding a protein (m-IF2P) that presents three substitutions compared to m-IF2. This new isoform is still active on pNPP, although to a lower extent: this reduction is mainly due to the leucine to proline substitution in position 13, within the catalytic loop. The mRNA expression level of this isoform is comparable to those of m-IF1 and m-IF2. It is likely that a gene duplication process followed by mutations has generated this new gene.

Structural characterization of the transition state for folding of muscle acylphosphatase.

The transition state for folding of a small protein, muscle acylphosphatase, has been studied by measuring the rates of folding and unfolding under a variety of solvent conditions. A strong dependence of the folding rate on the concentration of urea suggests the occurrence in the transition state of a large shielding of those groups that are exposed to interaction with the denaturant in the unfolded state (mainly hydrophobic moieties and groups located on the polypeptide backbone). The heat capacity change upon moving from the unfolded state to the transition state is small and is indicative of a substantial solvent exposure of hydrophobic groups. The solvent-accessibility of such groups in the transition state has also been found to be significant by measuring the rates of folding and unfolding in the presence of sugars. These rates have also been found to be accelerated by the addition of small quantities of alcohols. Trifluoroethanol and hexafluoroisopropanol were particularly effective, suggesting that stabilisation of local hydrogen bonds lowers the energy of the transition state relative to the folded and unfolded states. Finally, a study with a competitive inhibitor of acylphosphatase has provided evidence for the complete loss of ligand binding affinity in the transition state, indicating that specific long-range interactions at the level of the active site are not yet formed at this stage of the folding reaction. A model of the transition state for acylphosphatase folding, in which beta-turns and one or both alpha-helices are formed to a significant extent but in which the persistent long-range interactions characteristic of the folded state are largely absent, accounts for all our data. These results are broadly consistent with models of the transition states for folding of other small proteins derived from mutagenesis studies, and suggest that solvent perturbation methods can provide complementary information about the transition region of the energy surfaces for protein folding.

Drosophila melanogaster acylphosphatase: a common ancestor for acylphosphatase isoenzymes of vertebrate species.

An open reading frame encoding a putative acylphosphatase was found in Drosophila melanogaster. The corresponding gene product shows 40% identity and 22 additional amino acid residues at the C-terminus as compared to muscle- and common-type human acylphosphatases. Moreover, all the residues involved in the catalytic mechanism of vertebrate enzymes are conserved in the D. melanogaster acylphosphatase. The D. melanogaster protein and a deletion mutant, similar in length to vertebrate acylphosphatases, were produced by cloning the corresponding cDNA in Escherichia coli. The wild-type enzyme is a protein with a well-established three-dimensional fold and a markedly reduced conformational stability as compared to vertebrate isoenzymes. The specific activity of the enzyme is significantly lower than that found in vertebrate enzymes though the substrate binding capability is basically unaltered. The deletion of 22 residues does not cause a significant change in k(cat), while affecting the apparent binding parameters. This work suggests that the genes encoding the vertebrate enzymes originate from an ancestor gene by duplication and subsequent evolution.

Studies on enzymatic activity and conformational stability of muscle acylphosphatase mutated at conserved lysine residues.

An oligonucleotide-directed mutagenesis study was carried out on the five acylphosphatase conserved lysine residues to assess their possible participation in enzyme active site formation and their contribution to the enzyme conformational stability. The study was designed to eliminate the ambiguity arising from the presence of a sulfate ion, an enzyme competitive inhibitor, bound to lysine 32 and 68 in the crystal structure of the erythrocyte isoenzyme. Furthermore, previous kinetic studies suggested the presence of residues with pKa=7.9 and 11, tentatively identified as two lysines. The kinetic parameters for the mutants under investigation are not significantly different from those of the wild-type enzyme, demonstrating that none of the lysine residues are involved in catalysis or in substrate binding. In addition, thermal and urea denaturation experiments performed by circular dichroism indicate that the mutated lysine residues do not play a significant role in the enzyme structural stabilization, as the destabilizing energy averages 1.40 kJ/mol. Such results are in agreement with those obtained with other proteins indicating that lysine residues make little contribution to the stability of the native structure.

Cloning, expression and characterisation of a new human low Mr phosphotyrosine protein phosphatase originating by alternative splicing.

RT-PCR experiments on RNA from K562 and HepG2 cells and from human placenta led to the isolation of a novel cDNA, a further alternative splicing product of the primary transcript of low Mr phosphotyrosine phosphatase (LMW-PTP), already known to produce isoforms 1 and 2. This new transcript represents 15-20% of the total LMW-PTP mRNA in the cell. This novel cDNA codifies for a protein that we have named SV3 (splicing variant 3): the deduced protein sequence presents the first 49 residues identical to those of isoform 1, followed by 24 unrelated amino acids, due to a frameshift introduced at the novel exon-exon boundary. The SV3 protein, expressed in E. coli is enzymatically inactive, most probably because unfolded, as suggested by far-UV circular dichroism (CD) experiments. SV3 protein appears to possess the characteristics of an unstructured polypeptide chain lacking the packing of side chain residues and the secondary structure level that are typical of globular proteins. This protein could represent an inactive variant of the human LMW-PTP.

Conformational stability of muscle acylphosphatase: the role of temperature, denaturant concentration, and pH.

The conformational stability (delta G) of muscle acylphosphatase, a small alpha/beta globular protein, has been determined as a function of temperature, urea concentration, and pH. A combination of thermally induced and urea-induced unfolding, monitored by far-UV circular dichroism, was used to define the conformational stability over a wide range of temperature. Through analysis of all these data, the heat capacity change upon unfolding (delta Cp) could be estimated, allowing the determination of the temperature dependence of the main thermodynamic functions (delta G, delta H, delta S). Thermal unfolding in the presence of urea made it possible to extend such thermodynamic analysis to examine these parameters as a function of urea concentration. The results indicate that acylphosphatase is a relatively unstable protein with a delta G(H2O) of 22 +/- 1 kJ mol-1 at pH 7 and 25 degrees C. The midpoints of both thermal and chemical denaturation are also relatively low. Urea denaturation curves over the pH range 2-12 have allowed the pH dependence of delta G to be determined and indicate that the maximum stability of the protein occurs near pH 5.5. While the dependence of delta G on urea (the m value) does not vary with temperature, a significant increase has been found at low pH values, suggesting that the overall dimensions of the unfolded state are significantly affected by the number of charges within the polypeptide chain. The comparison of these data with those from other small proteins indicates that the pattern of conformational stability is defined by individual sequences and not by the overall structural fold.

Structural and kinetic investigations on the 15-21 and 42-45 loops of muscle acylphosphatase: evidence for their involvement in enzyme catalysis and conformational stabilization.

The structural and catalytic importance of the 15-21 and 42-45 loop residues of the acylphosphatase muscular isoenzyme has been investigated by oligonucleotide-directed mutagenesis. Seven mutants involving conserved residues of the two loops have been prepared and characterized for structural, kinetic, and stability features by using different spectroscopic techniques and compared to the wild-type enzyme. The results are discussed in light of the crystal structure of the highly homologous common type acylphosphatase [Thunnissen et al. (1997) Structure 5, 69-79]. A differential role of the two loops has emerged: the 15-21 and the 42-45 loops appear mainly involved in active site formation and enzyme structural stabilization, respectively. These conclusions are supported by a strong impairment of the catalytic efficiency, in terms of enzymatic activity and substrate binding capability, for most of the 15-21 loop mutants. In particular, the Gly15Ala mutant is completely inactive and displays a native-like overall fold, indicating that the correct geometry of the 15-21 loop is an essential requisite for optimal enzymatic catalysis. Instead, the Gly45Ala mutant, though revealing unchanged catalytic properties, shows a considerably reduced conformational stability, as judged by circular dichroism and 1H NMR spectroscopy. This finding confirms previous results relative to Thr42 and Thr46 residues [Taddei et al. (1996) Biochemistry 35, 7077-7083] underlining the structural importance of the 42-45 loop as a linker for the two beta alpha beta units constituting the overall enzyme structure.

Expression of acylphosphatase in Saccharomyces cerevisiae enhances ethanol fermentation rate.

Previous experiments in vitro have demonstrated the ability of acylphosphatase to increase the rate of glucose fermentation in yeast. To evaluate the possibility of increasing fermentation in vivo also, a chemically synthesized DNA sequence coding for human muscle acylphosphatase was expressed at high level in Saccharomyces cerevisiae. Ethanol production was measured in these engineered strains in comparison with a control. Acylphosphatase expression strongly increased the rate of ethanol production both in aerobic and anaerobic culture. This finding may be potentially important for the development of more efficient industrial fermentation processes.

Looking for residues involved in the muscle acylphosphatase catalytic mechanism and structural stabilization: role of Asn41, Thr42, and Thr46.

Asn41, Thr42, and Thr46 are invariant residues in both muscle and erythrocyte acylphosphatases isolated so far. Horse muscle acylphosphatase solution structure suggests their close spatial relationship to Arg23, the main substrate binding site. The catalytic and structural role of such residues, as well as their influence on muscle acylphosphatase stability, was investigated by preparing several gene mutants (Thr42Ala, Thr46Ala, Asn41Ala, Asn41Ser, and Asn41Gln) by oligonucleotide-directed mutagenesis. The mutated genes were cloned and expressed in Escherichia coli, and the mutant enzymes were purified by affinity chromatography and investigated as compared to the wild-type enzyme. The specific activity and substrate affinity of Thr42 and Thr46 mutants were not significantly affected. On the contrary, Asn41 mutants showed a residual negligible activity (about 0.05-0.15% as compared to wild-type enzyme), though maintaining an unchanged binding capability of both substrate and inorganic phosphate, an enzyme competitive inhibitor. According to the 1H nuclear magnetic resonance spectroscopy and circular dichroism results, all mutants elicited well-constrained native-like secondary and tertiary structures. Thermodynamic parameters, as calculated from circular dichroism data, demonstrated a significantly decreased stability of the Thr42 mutant under increasing temperatures and urea concentrations. The reported results strongly support a direct participation of Asn41 to the enzyme catalytic mechanism, indicating that Asn41 mutants may well represent a useful tool for the investigation of the enzyme physiological function by the negative dominant approach.

C-terminal region contributes to muscle acylphosphatase three-dimensional structure stabilisation.

Ser-Ala and Ser-Ala-Ser-Ala C-terminus elongated (delta+2 and delta+4, respectively) and two C-terminus deleted (delta-2 and delta-3) muscle acylphosphatase mutants were investigated to assess the catalytic and structural roles of the C-terminal region. The kinetic analysis of these mutants shows that the removal of two or three C-terminal residues reduces the catalytic activity to 7% and 4% of the value measured for the wild-type enzyme, respectively; instead, the elongation of the C-terminus does not significantly change the enzyme behaviour. 1H Nuclear magnetic resonance spectroscopy indicates that all mutants display a native-like fold though they appear less stable, particularly delta-2 and delta-3 mutants, as compared to the wild-type enzyme. Such destabilisation of the C-terminal modified mutants is further confirmed by urea inactivation experiments. The results here presented account for an involvement of the C-terminal region in the stabilisation of the three-dimensional structure of acylphosphatase, particularly at the active-site level. Moreover, a participation of the C-terminal carboxyl group to the catalytic mechanism can be excluded.

Properties of Cys21-mutated muscle acylphosphatases.

Cys21 is an invariant residue in muscle acylphosphatases, but is absent in the erythrocyte isozymes. To assess the importance of this residue in the muscle isozymes for catalytic, structural, and stability properties, two gene mutants have been prepared by oligonucleotide-directed mutagenesis and expressed in Escherichia coli cells; in these mutants, the codon for Cys21 was replaced by those for Ser and Ala, respectively. The two mutant enzymes, purified by immunoaffinity chromatography, showed kinetic and structural properties similar to those of the wild-type recombinant enzyme; however, the specific activity of the two mutants, especially that of the C21A mutant, was lower. The urea and thermal stabilities of the mutant enzymes were reduced with respect to those of the wild-type form, contrary to the susceptibility to inactivation by mercuric ions. The reported data support the possibility that Cys21 is involved in the stabilization of the enzyme active-site conformation.

Expression, purification and kinetic behaviour of fission yeast low M(r) protein-tyrosine phosphatase.

A gene named stp1+, coding for a 17.5-kDa protein, that rescues cdc25-22 when overexpressed, has been previously isolated from fission yeast. Here we describe the expression and purification of Stp1 protein as a fusion with the glutathione S-transferase in E. coli and its kinetic characterisation. Stp1 deduced protein sequence shows an high homology to members of a class of cytosolic low M(r) protein phosphatase previously known to exist only in mammalian species. Stp1 has a kinetic behaviour that appears to be intermediate with respect to the two isoenzymatic forms of low M(r) protein tyrosine phosphatases present in mammalian tissues. These differing kinetic characteristics are mainly due to the sequence 45-56 that is spatially close to the active site pocket.

Properties of N-terminus truncated and C-terminus mutated muscle acylphosphatases.

Enzymatic activity and structure of N-terminus truncated and C-terminus substituted muscle acylphosphatase mutants were investigated by kinetic studies under different conditions and 1H NMR spectroscopy, respectively. The N-terminus truncated mutant lacked the first six residues (delta 6), whereas arginine 97 and tyrosine 98 were replaced by glutamine giving two C-terminus substituted mutants (R97Q and Y98Q, respectively). All acylphosphatase forms were obtained by modifications of a synthetic gene coding for the human muscle enzyme which was expressed in E. coli. The delta 6 deletion mutant elicited a reduced specific activity and a native-like structure. The kinetic and structural properties of R97Q and Y98Q mutants indicate a possible role of Arg-97 in the stabilisation of the active site correct conformation, most likely via back-bone and side chain interactions with Arg-23, the residue involved in phosphate binding by the enzyme. This study also suggests a possible involvement of Tyr-98 in the stabilisation of the acylphosphatase overall structure.

Arginine-23 is involved in the catalytic site of muscle acylphosphatase.

Three mutants of human muscle acylphosphatase in which arginine-23 was replaced by glutamine, histidine and lysine, respectively, were prepared by oligonucleotide-directed mutagenesis of a synthetic gene coding for the enzyme. All mutants, purified by affinity chromatography, were almost completely unable to catalyze the hydrolysis of the substrate. 1H-NMR spectroscopy experiments showed the absence of any major conformational changes of the three mutants with respect to the wild-type recombinant enzyme. Equilibrium dialysis experiments demonstrated that the mutated proteins lost the ability of binding inorganic phosphate, a competitive inhibitor of the enzyme. These results strongly support an involvement of arginine-23 at the phosphate binding-site of acylphosphatase, confirming the hypothesis of the existence of a phosphate binding structural motif recently proposed by other authors.