Defect in cell wall integrity of the yeast saccharomyces cerevisiae caused by a mutation of the GDP-mannose pyrophosphorylase gene VIG9.

The Saccharomyces cerevisiae VIG9 gene encodes GDP-mannose pyrophosphorylase, which synthesizes GDP-mannose from GTP and mannose-1-phosphate. Although the null mutant was lethal, the vig9 mutants so far obtained showed no growth defect but immature protein glycosylation and drug hypersensitivity. During our search for cell-wall mutants, we found a novel temperature-sensitive mutant, JS30, which required an osmotic stabilizer for viability. JS30 excreted cell surface proteins in the medium without any indication of cell lysis. Although conventional genetic analysis using mating was impossible, by detailed characterization of JS30 including an in vitro enzyme assay and nucleotide sequencing, we found the defect of JS30 was due to a mutation in the VIG9 gene. These results indicated a critical role of GDP-mannose in maintenance of cell-wall integrity.

Molecular characterization of a novel yeast cell-wall acid phosphatase cloned from Kluyveromyces marxianus.

A novel Kluyveromyces marxianus gene that encodes an acid phosphatase, Pho610, was cloned in Saccharomyces cerevisiae. The deduced amino acid sequence was distinct from S. cerevisiae phosphatases but similar to some fungal enzymes. A peculiar feature of the sequence is that it has hydrophobic stretches both at the N- and C-termini, which is a characteristic of the precursors of glycosylphosphatidylinositol(GPI)-anchored proteins. When the gene was expressed in S. cerevisiae, the active enzyme was recovered in the periplasmic fraction by glucanase digestion. The Pho610 polypeptide was highly glycosylated and a significant portion was covalently linked to the cell-wall glucan. The enzyme was secreted when the C-terminal region was truncated to remove the GPI signal. Therefore, Pho610 is a novel cell-wall protein having an enzyme activity.

Structural asymmetry of F1-ATPase caused by the gamma subunit generates a high affinity nucleotide binding site.

The alpha 3 beta 3 gamma and alpha 3 beta 3 complexes of F1-ATPase from a thermophilic Bacillus PS3 were compared in terms of interaction with trinitrophenyl analogs of ATP and ADP (TNP-ATP and TNP-ADP) that differed from ATP and ADP and did not destabilize the alpha 3 beta 3 complex. The results of equilibrium dialysis show that the alpha 3 beta 3 gamma complex has a high affinity nucleotide binding site and several low affinity sites, whereas the alpha 3 beta 2 complex has only low affinity sites. This is also supported from analysis of spectral change induced by TNP-ADP, which in addition indicates that this high affinity site is located on the beta subunit. Single-site hydrolysis of substoichiometric amounts of TNP-ATP by the alpha 3 beta 3 gamma complex is accelerated by the chase addition of excess ATP, whereas that by the alpha 3 beta 3 complex is not. We further examined the complexes containing mutant beta subunits (Y341L, Y341A, and Y341C). Surprisingly, in spite of very weak affinity of the isolated mutant beta subunits to nucleotides (Odaka, M., Kaibara, C., Amano, T., Matsui, T., Muneyuki, E., Ogasawara, K, Yutani, K., and Yoshida, M. (1994) J. Biochem. (Tokyo) 115, 789-796), a high affinity TNP-ADP binding site is generated on the beta subunit in the mutant alpha 3 beta 3 gamma complexes where single-site TNP-ATP hydrolysis can occur. ATP concentrations required for the chase acceleration of the mutant complexes are higher than that of the wild-type complex. The mutant alpha 3 beta 3 complexes, on the contrary, catalyze single-site hydrolysis of TNP-ATP rather slowly, and there is no chase acceleration. Thus, the gamma subunit is responsible for the generation of a high affinity nucleotide binding site on the beta subunit in F1-ATPase where cooperative catalysis can proceed.

The alpha 3 beta 3 gamma complex of the F1-ATPase from thermophilic Bacillus PS3 containing the alpha D261N substitution fails to dissociate inhibitory MgADP from a catalytic site when ATP binds to noncatalytic sites.

ATP hydrolyses by the wild-type alpha 3 beta 3 gamma and mutant (alpha D261N)3 beta 3 gamma subcomplexes of the F1-ATPase from the thermophilic Bacillus PS3 have been compared. The wild-type complex hydrolyzes 50 microM ATP in three kinetic phases: a burst decelerates to an intermediate phase, which then gradually accelerates to a final rate. In contrast, the mutant complex hydrolyzes 50 microM or 2 mM ATP in two kinetic phases. The mutation abolishes acceleration from the intermediate phase to a faster final rate. Both the wild-type and mutant complexes hydrolyze ATP with a lag after loading a catalytic site with MgADP. The rate of the MgADP-loaded wild-type complex rapidly accelerates and approaches that observed for the wild-type apo-complex. The MgADP-loaded mutant complex hydrolyzes ATP with a more pronounced lag, and the gradually accelerating rate approaches the slow, final rate observed with the mutant apo-complex. Lauryl dimethylamide oxide (LDAO) stimulates hydrolysis of 2 mM ATP catalyzed by wild-type and mutant complexes 4- and 7.5-fold, respectively. The rate of release of [3H]ADP from the Mg[3H]ADP-loaded mutant complex during hydrolysis of 40 microM ATP is slower than observed with the wild-type complex. LDAO increases the rate of release of [3H]ADP from the preloaded wild-type and mutant complexes during hydrolysis of 40 microM ATP. Again, release is slower with the mutant complex. When the wild-type and mutant complexes are irradiated in the presence of 2-N3-[3H]ADP plus Mg2+ or 2-N3-[3H]ATP plus Mg2+ and azide, the same extent of labeling of noncatalytic sites is observed. Whereas ADP and ATP protect noncatalytic sites of the wild-type and mutant complexes about equally from labeling by 2-N3-[3H]ADP or 2-N3-[3H[ATP, respectively, AMP-PNP provides little protection of noncatalytic sites of the mutant complex. The results suggest that the substitution does not prevent binding of ADP or ATP to noncatalytic sites, but rather that it affects cross-talk between liganded noncatalytic sites and catalytic sites which is necessary to promote dissociation of inhibitory MgADP.

Tyr-341 of the beta subunit is a major Km-determining residue of TF1-ATPase: parallel effect of its mutations on Kd(ATP) of the beta subunit and on Km(ATP) of the alpha 3 beta 3 gamma complex.

Residue Tyr-341 of the F1-ATPase beta subunit from a thermophilic Bacillus strain, PS3, was mutagenized to leucine, cysteine or alanine. Each of the mutated beta subunits was isolated and its affinity for ATP-Mg was examined by means of difference circular dichroism and differential titration calorimetry. The Kd values for ATP-Mg obtained were: beta Y341 (wild type), 0.015 mM; beta Y341L, 0.7 mM; beta Y341C and beta Y341A, > 3 mM. All the mutant beta subunits could be reconstituted into the alpha 3 beta 3 gamma complex with alpha and gamma subunits. The alpha 3 beta (mutant)3 gamma complexes hydrolyzed ATP with apparent Vmax values larger than that of the alpha 3 beta (WILD)3 gamma complex. The apparent Km values of the alpha 3 beta (mutant)3 gamma complexes increased in parallel with the Kd values for ATP-Mg of the isolated mutant beta subunits. These results indicate that residue beta Y341 is directly involved in the catalytic ATP-Mg binding and is a major Km-determining residue of F1-ATPase.

Probing the specificity of nucleotide binding to the F1-ATPase from thermophilic Bacillus PS3 and its isolated alpha and beta subunits with 2-N3-[beta, gamma-32P]ATP.

Irradiation of the F1-ATPase from Bacillus PS3 (TF1) in the presence of 134 microM 2-N3-[beta, gamma-32P]ATP plus Mg2+ for 90 min led to 95% inactivation of the ATPase activity which was accompanied by exclusive labeling of the beta subunit. The isolated alpha and beta subunits were also treated separately with 2-N3-[beta, gamma-32P]ATP under similar conditions. Fractionation of a tryptic digest of photolabeled TF1 by reversed-phase HPLC resolved a major and a minor radioactive peptide. Sequence analyses showed that the major peptide contained labeled Tyr-beta 364, whereas the minor one contained labeled Tyr-beta 341, residues known to be part of noncatalytic and catalytic sites, respectively. Two closely eluting radioactive peptides were obtained when a tryptic digest of the photolabeled, isolated beta subunit was fractionated by HPLC. Sequence analyses revealed that both contained labeled Tyr-beta 341. Fractionation of a tryptic digest of the photolabeled, isolated alpha subunit by HPLC resolved two peptides which contained the majority of the radioactivity incorporated. When subjected to eight cycles of automatic Edman degradation, one gave the sequence APGVXDR, corresponding to residues 133-139, in which X is a gap and corresponds to Met-alpha 137, which presumably is the derivatized residue. Only the first five cycles yielded phenylthiohydantoin derivatives when the other radioactive peptide derived from the alpha subunit was submitted to automatic Edman degradation which revealed the sequence APGVM, suggesting that Asp-alpha 138 is derivatized. The overall results suggest that the isolated beta subunit is a useful model for studying binding of nucleotides to catalytic sites, whereas the isolated alpha subunit may be of limited value in modeling interactions of nucleotides with noncatalytic sites.

Asymmetry of the three catalytic sites on beta subunits of TF1 from a thermophilic Bacillus strain PS3.

F1-ATPase isolated from plasma membrane of a thermophilic Bacillus strain PS3 (TF1) has very little or no endogenously bound adenine nucleotides. However, it can bind one ADP per mol of the enzyme on one of three beta subunits to form a stable TF1.ADP complex when incubated with a high concentration of ADP [Yoshida, M. & Allison, W.S. (1986) J. Biol. Chem. 261, 5714-5721]. The same TF1.ADP complex was recovered after filling all ADP binding sites with [3H]ADP and repeated gel filtration. Direct binding assay revealed that the TF1.ADP complex had lost the highest affinity site for TNP-ADP. When a substoichiometric amount of TNP-ATP was added, the complex hydrolyzed TNP-ATP slowly (single site hydrolysis), like native TF1. However, this hydrolysis was not promoted by chase-addition of excess ATP. The optimal pH of the ATPase activity of TF1 or the TF1.ADP complex measured with a short reaction period, 6.5, was lower than the reported value, 9.0, under the steady-state condition. Although the bound ADP was released from the complex only when the enzyme underwent multiple catalytic turnover, the rate of this release was much slower than the turnover. These results suggest that when one ADP binds to a site on one of the beta subunits and stays there for a long time, the enzyme will change form and the bound ADP will become a special species which is not able to be directly involved in the enzyme catalysis. This binding site for ADP appears to be the first site responsible for the single-site catalysis reaction observed for native TF1.

AT(D)PMg-induced dissociation of the alpha 3 beta 3 complex of the F1-ATPase from a thermophilic Bacillus PS3 into alpha 1 beta 1 heterodimers is prevented by mutation beta (Y341C).

AT(D)PMg induces dissociation of the alpha 3 beta 3 complex of F1-ATPase from a thermophilic Bacillus strain. PS3, into the alpha 1 beta 1 heterodimers [(1991) Biochim. Biophys. Acta 1056, 279-284] but the location of the AT(D)PMg binding site responsible is not known. From the analysis of AT(D)PMg binding properties of the isolated mutant beta subunit, beta(Y341C), and the stability of the alpha 3 beta(Y341C)3 complex in the presence of AT(D)PMg, we conclude that binding of AT(D)PMg to the Tyr-341 site of the beta subunit(s) in the alpha 3 beta 3 complex triggers the dissociation of the alpha 3 beta 3 complex into the alpha 1 beta 1 heterodimers.