Reaction mechanism of fructose-2,6-bisphosphatase. A mutation of nucleophilic catalyst, histidine 256, induces an alteration in the reaction pathway

A bifunctional enzyme, fructose-6-phosphate,2-kinase/fructose 2, 6-bisphosphatase (Fru-6-P,2-kinase/Fru-2,6-Pase), catalyzes synthesis and degradation of fructose 2,6-bisphosphate (Fru-2,6-P2). Previously, the rat liver Fru-2,6-Pase reaction (Fru-2,6-P2 --> Fru-6-P + Pi) has been shown to proceed via a phosphoenzyme intermediate with His258 phosphorylated, and mutation of the histidine to alanine resulted in complete loss of activity (Tauler, A., Lin, K., and Pilkis, S. J. (1990) J. Biol. Chem. 265, 15617-15622). In the present study, it is shown that mutation of the corresponding histidine (His256) of the rat testis enzyme decreases activity by less than a factor of 10 with a kcat of 17% compared with the wild type enzyme. Mutation of His390 (in close proximity to His256) to Ala results in a kcat of 12.5% compared with the wild type enzyme. Attempts to detect a phosphohistidine intermediate with the H256A mutant enzyme were unsuccessful, but the phosphoenzyme is detected in the wild type, H390A, R255A, R305S, and E325A mutant enzymes. Data demonstrate that the mutation of His256 induces a change in the phosphatase hydrolytic reaction mechanism. Elimination of the nucleophilic catalyst, H256A, results in a change in mechanism. In the H256A mutant enzyme, His390 likely acts as a general base to activate water for direct hydrolysis of the 2-phosphate of Fru-2,6-P2. Mutation of Arg255 and Arg305 suggests that the arginines probably have a role in neutralizing excess charge on the 2-phosphate and polarizing the phosphoryl for subsequent transfer to either His256 or water. The role of Glu325 is less certain, but it may serve as a general acid, protonating the leaving 2-hydroxyl of Fru-2,6-P2.     

Kinetic and mechanistic characterization of a mammalian protein-tyrosine phosphatase, PTP1

The kinetic mechanism of the hydrolysis of phosphate monoesters catalyzed by a soluble form of rat protein-tyrosine phosphatase (PTPase), PTP1, was probed with a variety of steady-state and pre-steady-state kinetic techniques. Product inhibition and 18O exchange experiments are consistent with the enzymatic reaction proceeding through two chemical steps, i.e. formation and breakdown of a covalent phosphoenzyme intermediate. The variation of kcat/Km with pH indicates that three ionizable groups are involved in enzyme substrate binding and catalysis. The first group must be deprotonated and is attributed to the second ionization of the substrate. The other two groups with pK alpha values of 5.1 and 5.5 correspond to two enzyme active site residues. The kcat-pH profiles for both p-nitrophenyl phosphate and beta-naphthyl phosphate are bell-shaped and are superimposable, with the apparent pK alpha values derived from the acidic limb and the basic limb of the profile being 4.4 and 6.8, respectively. This suggests that the rate-limiting step corresponds to the decomposition of the phosphoenzyme intermediate at all pH values. Results from leaving group dependence of kcat at two different pH values support the above conclusion. Furthermore, burst kinetics have been demonstrated with PTP1 using p-nitrophenyl phosphate as a substrate. The rate constants for the formation and the breakdown of the intermediate are 241 and 12 s-1, respectively, at pH 6.0 and 3.5 degrees C. A normal D2O solvent isotope effect (kcatH/kcatD = 1.5) is associated with the breakdown of the phosphoenzyme intermediate, indicating a solvent-derived proton in the transition state. The leaving group dependence of kcat/Km suggests that there is a strong electrophilic interaction between the enzyme and the leaving group oxygen in the transition state of the phosphorylation event. These results are compared with those of the Yersinia PTPase and suggest that the mechanism for PTPase-catalyzed phosphate monoester hydrolysis is conserved from bacterial to mammals.     

Protein-tyrosine phosphatases: biological function, structural characteristics, and mechanism of catalysis

The protein-tyrosine phosphatases (PTPases) superfamily consists of tyrosine-specific phosphatases, dual specificity phosphatases, and the low-molecular-weight phosphatases. They are modulators of signal transduction pathways that regulate numerous cell functions. Malfunction of PTPases have been linked to a number of oncogenic and metabolic disease states, and PTPases are also employed by microbes and viruses for pathogenicity. There is little sequence similarity among the three subfamilies of phosphatases. Yet, three-dimensional structural data show that they share similar conserved structural elements, namely, the phosphate-binding loop encompassing the PTPase signature motif (H/V)C(X)5R(S/T) and an essential general acid/base Asp residue on a surface loop. Biochemical experiments demonstrate that phosphatases in the PTPase superfamily utilize a common mechanism for catalysis going through a covalent thiophosphate intermediate that involves the nucleophilic Cys residue in the PTPase signature motif. The transition states for phosphoenzyme intermediate formation and hydrolysis are dissociative in nature and are similar to those of the solution phosphate monoester reactions. One strategy used by these phosphatases for transition state stabilization is to neutralize the developing negative charge in the leaving group. A conformational change that is restricted to the movement of a flexible loop occurs during the catalytic cycle of the PTPases. However, the relationship between loop dynamics and enzyme catalysis remains to be established. The nature and identity of the rate-limiting step in the PTPase catalyzed reaction requires further investigation and may be dependent on the specific experimental conditions such as temperature, pH, buffer, and substrate used. In-depth kinetic and structural analysis of a representative number of phosphatases from each group of the PTPase superfamily will most likely continue to yield insightful mechanistic information that may be applicable to the rest of the family members.     

Molecular cloning and functional expression of mannitol-1-phosphatase from the apicomplexan parasite Eimeria tenella

A metabolic pathway responsible for the biosynthesis and utilization of mannitol is present in the seven species of Eimeria that infect chickens, but is not in the avian host. Mannitol-1-phosphatase (M1Pase), a key enzyme for mannitol biosynthesis, is a highly substrate-specific phosphatase and, accordingly, represents an attractive chemotherapeutic target. Amino acid sequence of tryptic peptides obtained from biochemically purified Eimeria tenella M1Pase was used to synthesize degenerate oligonucleotide hybridization probes. Using these reagents, a partial genomic clone and full-length cDNA clones have been isolated and characterized. The deduced amino acid sequence of E. tenella M1Pase shows limited overall homology to members of the phosphohistidine family of phosphatases. This limited homology to other histidine phosphatases does, however, include several conserved residues that have been shown to be essential for their catalytic activity. Kinetic parameters of recombinant M1Pase expressed in bacteria are essentially identical to those of the biochemically purified preparation from E. tenella. Moreover, recombinant M1Pase is subject to active site-directed, hydroxylamine-reversible inhibition by the histidine-selective acylating reagent diethyl pyrocarbonate. These results indicate the presence of an essential histidine residue(s) at the M1Pase active site, as predicted for a histidine phosphatase.     

Autophosphorylation of nucleoside diphosphate kinase from Myxococcus xanthus

The nucleoside diphosphate kinase (NDP kinase) from Myxococcus xanthus has been purified to homogeneity and crystallized (J. Munoz-Dorado, M. Inouye, and S. Inouye, J. Biol. Chem. 265:2702-2706, 1990). In the presence of ATP, the NDP kinase was autophosphorylated. Phosphoamino acid analysis was carried out after acid and base hydrolyses of phosphorylated NDP kinase. It was found that the protein was phosphorylated not only at a histidine residue but also at a serine residue. Replacement of histidine 117 with a glutamine residue completely abolished the autophosphorylation and nucleotide-binding activity of the NDP kinase. Since histidine 117 is the only histidine residue that is conserved in all known NDP kinases so far characterized, the results suggest that the phosphohistidine intermediate is formed at this residue during the transphosphorylation reaction from nucleoside triphosphates to nucleoside diphosphates. Preliminary mutational analysis of putative ATP-binding sites is also presented.     

Non-hydrated state of the acyl phosphate group in the phosphorylated intermediate of (Na+,K+)-ATPase

The position in the acyl phosphate linkage of the phosphorylated intermediate of (Na+, K+)-ATPase that is cleaved by N-methylhydroxylamine was compared with that of the model compound acetylphosphate. The products of the cleavage of the phosphoenzyme by methylhydroxylamine were the active enzyme and a N-P compound, not the inhibited enzyme and inorganic phosphate. This means that the bond cleaved by methylhydroxylamine was the O-P bond, not the C-O bond. In contrast, methylhydroxylamine did not cleave the O-P bond of acetylphosphate in solution, at pH values from 0.3 to 7.0, whether or not the phosphoryl group formed a complex with magnesium. Acetylphosphate and hydroxylamine formed acetohydroxamic acid. Therefore, the state of the acyl phosphate bond in the native phosphoenzyme and in acetylphosphate in solution was different, and the difference was not due to different dissociation states of their phosphoryl groups or the binding of magnesium to the phosphoenzyme. Molecular orbital calculations for acetylphosphate revealed that the phosphorus atom charge is more positive than the carbon atom, irrespective of the dissociation state of the phosphoryl group. Similarly, the overlapping electron population of the O-P bond is always smaller than that of the C-O bond. Thus, the electronic structure of the acyl phosphate linkage of acetylphosphate under vacuum supports the results obtained with the native phosphoenzyme, rather than those obtained with acetylphosphate in solution. The linkage in the active site of the phosphorylated intermediate of (Na+,K+)-ATPase appeared to be equivalent to the non-hydrated state of the model compound acetylphosphate. The phosphoenzyme with bound ouabain, or without a tightly bound divalent cation was insensitive to methylhydroxylamine. The native phosphoenzyme of (Ca2+)-ATPase was not susceptible to methylhydroxylamine.     

Association of N- and C-terminal domains of phospholipase D is required for catalytic activity

Rat brain phospholipase D1 (rPLD1) belongs to a superfamily defined by the highly conserved catalytic motif (H(X)K(X)4D, denoted HKD. RPLD1 contains two HKD domains, located in the N- and C-terminal regions. Deletion mutants of rPLD1 that contained only an N- or C-terminal HKD domain exhibited no catalytic activity when expressed in COS 7 cells. However, when N-terminal fragments containing one of the HKD domains were cotransfected with a C-terminal fragment containing the other HKD domain, PLD activity was restored. Furthermore, immunoprecipitation assays showed that the N- and C-terminal halves of rPLD1 were physically associated when expressed in COS 7 cells. In addition, deletion of 168 amino acids from the N terminus of rPLD1 significantly enhanced basal PLD activity while inhibiting the response to phorbol ester. Likewise, the coexpression of this truncated N-terminal half with the C-terminal half resulted in increased PLD activity. In summary, this study provides direct evidence that the enzymatic activity of rPLD1 requires the presence of the HKD domains in both the N- and C-terminal regions of the molecule. More importantly, the two halves of rPLD1 can associate, and this may be essential to bring the two HKD domains together to form an active catalytic center. These findings provide new insights into the catalytic mechanism of enzymes of the PLD superfamily.     

A chromatographic method for the preparative separation of phosphohistidines

The driving force behind this new chromatographic technique was to develop a method for purifying preparative quantities of phosphohistidines in a single step that provided good resolution wit eluants that could be easily removed. The current method can provide milligram quantities of each phosphohistidine; however, the later 1H NMR analysis of the dried, individually purified phosphohistidines showed that histidine was present along with each of the individual phosphohistidines. The stability of each phosphohistidine during storage does not appear to be a problem because the amounts of histidine contamination of freshly freeze-dried samples were compared with those of samples stored at -80 degrees C under nitrogen for 2 weeks and were found to be similar (data not shown). Possibly, the lyophilization and preparation of solutions for NMR analysis resulted in a certain amount of hydrolysis of phosphohistidine, particularly with the less stable 1- and 1,3-forms (5, 6). It was noted that when the lyophilized samples were initially dissolved in D2O for NMR analysis, the pH was between 6 and 7; this may have resulted in some hydrolysis of the phosphohistidines. This hydrolysis can be reduced by the addition of 50 mM potassium hydroxide to the pooled fractions collected from the chromatography, so that the alkalinity of the samples is maintained throughout the subsequent processes. The data obtained for the assignment of individual phosphohistidines by 1H and 31P NMR analysis seem consistent with those obtained by other independent studies (6, 10). The NMR analysis was a powerful tool in assigning the identity of each purified phosphohistidine, although caution should be used when considering free phosphohistidines as references for NMR detection of phosphohistidines in native proteins. Lecroisey et al. (10) showed that there were differences between the chemical shifts observed for free phosphohistidine compared to those for phosphohistidine in dipeptides. However, for the purposes of phosphoamino acid analysis, these purified phosphohistidines are used by this group as references in the detection of phosphohistidine in proteins.     

Hydrolysis of phosphodiesters through transformation of the bacterial phosphotriesterase

The phosphotriesterase from Pseudomonas diminuta catalyzes the hydrolysis of a wide array of phosphotriesters and related phosphonates, including organophosphate pesticides and military nerve agents. It has now been shown that this enzyme can also catalyze the hydrolysis of phosphodiesters, albeit at a greatly reduced rate. However, the enzymatic hydrolysis of ethyl-4-nitrophenyl phosphate (compound I) by the wild-type enzyme was >10(8) times faster than the uncatalyzed reaction (kcat = 0.06 s-1 and Km = 38 mM). Upon the addition of various alkylamines to the reaction mixture, the kcat/Km for the phosphodiester (compound I) increased up to 200-fold. Four mutant enzymes of the phosphotriesterase were constructed in a preliminary attempt to improve phosphodiester hydrolysis activity of the native enzyme. Met-317, which is thought to reside in close proximity to the pro-S-ethoxy arm of the paraoxon substrate, was mutated to arginine, alanine, histidine, and lysine. These mutant enzymes showed slight improvements in the catalytic hydrolysis of organophosphate diesters. The M317K mutant enzyme displayed the most improvement in catalytic activity (kcat = 0.34 s-1 and Km = 30 mM). The M317A mutant enzyme catalyzed the hydrolysis of the phosphodiester (compound I) in the presence of alkylamines up to 200 times faster than the wild-type enzyme in the absence of added amines. The neutralization of the negative charge on the oxygen atom of the phosphodiester by the ammonium cation within the active site is thought to be responsible for the rate enhancement by these amines in the hydrolytic reaction. These results demonstrate that an active site optimized for the hydrolysis of organophosphate triesters can be made to catalyze the hydrolysis of organophosphate diesters.     

Site-directed mutagenesis of a human brain ecto-apyrase: evidence that the E-type ATPases are related to the actin/heat shock 70/sugar kinase superfamily

On the basis of sequence homologies observed between members of the E-type ATPases and the phosphate binding motifs of the actin/heat shock protein 70/sugar kinase superfamily, a human ecto-apyrase was analyzed by site-directed mutagenesis of conserved amino acids in apyrase conserved regions (ACR) I and IV. The expressed proteins were analyzed to assess the significance of these amino acids. A conserved aspartic acid residue in ACR IV was mutated to alanine, asparagine, and glutamic acid, and the relative activity and Km for ATP and ADP were determined. Mutation of this Asp 219 to Ala or Asn yielded an enzyme severely reduced in ATP hydrolyzing activity (>90%) and completely devoid of ADPase activity, along with a similar extent of inhibition of hydrolysis of other nucleoside di- and triphosphates. Interestingly, mutation of Asp 219 to Glu completely restored the ability of the enzyme to hydrolyze nucleoside triphosphates at levels above that of the wild-type enzyme, while the ability to hydrolyze nucleoside diphosphates was slightly reduced. Mutation of a second conserved aspartic acid in ACR I (Asp 62) and two invariant glycine residues in both ACR I (Gly 64) and ACR IV (Gly 221) also severely disrupted nucleotidase activity. These results demonstrate that the E-type ATPases contain the nucleoside phosphate binding domains present in the actin/heat shock protein/sugar kinase superfamily. Together with analysis of computer-predicted secondary structures, the results suggest that the ecto-ATPases and ecto-apyrases are part of, or closely related to, the actin superfamily of proteins.     

Relationship between an increase in thermostability and amino acid substitutions in N-carbamyl-D-amino acid amidohydrolase

To improve the production of D-amino acids using an immobilized N-carbamyl-D-amino acid amidohydrolase, the enzyme gene of Agrobacterium sp. KNK712 was mutagenized randomly to increase its thermostability. The gene was inserted into M13mp19, mutagenized with hydroxylamine, ligated into pUC19 after restriction endonuclease digestion, and then used to transform Escherichia coli. The resultant transformants were screened by a newly developed colorimetric enzyme assay method, and the candidate colonies corresponding to red spots were separated from the master plates. Using cell-free extracts of these clones, the properties of the enzymes produced were investigated, it being proved that these enzymes had almost the same activity and improved thermostability by about 5 degrees C compared with those of the native enzyme. As found on enzyme gene analysis of these mutants, the 57th amino acid, histidine, of the enzyme was changed to tyrosine, or the 203rd amino acid, proline, to leucine or serine.     

Purification of a mammalian homologue of Escherichia coli endonuclease III: identification of a bovine pyrimidine hydrate-thymine glycol DNAse/AP lyase by irreversible cross linking to a thymine glycol-containing oligoxynucleotide

We purified a homologue of the Escherichia coli DNA repair enzyme endo nuclease III 5000-fold from calf thymus which, like endonuclease III, demonstrates DNA-glycosylase activity against pyrimidine hydrates and thymine glycol and AP lyase activity (DNA strand cleavage at AP sites via beta-elimination). The functional similarity between the enzymes suggested a strategy for definitive identification of the bovine protein based on the nature of its enzyme-substrate (ES) intermediate. Prokaryotic DNA glycosylase/AP lyases function through N-acylimine (Schiff's base) ES intermediates which, upon chemical reduction to stable secondary amines, irreversibly cross link the enzyme to oligodeoxynucleotides containing substrate modified bases. We incubated endonuclease III with a 32P- labeled thymine glycol-containing oligodeoxynucleotide in the presence of NaCNBH3. This resulted in an increase in the apparent molecular weight of the enzyme by SDS-PAGE. Phosphorimaging confirmed irreversible cross linking between enzyme and DNA. Identical treatment of the most purified bovine enzyme fraction resulted in irreversible cross linking of the oligodeoxynucleotide to a predominant 31 kDa species. Amino acid analysis of the 31 kDa species revealed homology to the predicted amino acid sequence of a Caenorhabditis elegans 27.8 kDa protein which, in turn, has homology to endonuclease III. The translated amino acid sequences of two partial 3' cDNAs, from Homo sapiens and Rattus sp., also demonstrate homology to the C. elegans and bovine sequences suggesting a homologous family of endonuclease III-like DNA repair enzymes is present throughout phylogeny.     

Histidine kinase activity of the ETR1 ethylene receptor from Arabidopsis

ETR1 represents a prototypical ethylene receptor. Homologues of ETR1 have been identified in Arabidopsis as well as in other plant species, indicating that ethylene perception involves a family of receptors and that the mechanism of ethylene perception is conserved in plants. The amino-terminal half of ETR1 contains a hydrophobic domain responsible for ethylene binding and membrane localization. The carboxyl-terminal half of the polypeptide contains domains with homology to histidine kinases and response regulators, signaling motifs originally identified in bacteria. The putative histidine kinase domain of ETR1 was expressed in yeast as a fusion protein with glutathione S-transferase and affinity purified. Autophosphorylation of the purified fusion protein was observed on incubation with radiolabeled ATP. The incorporated phosphate was resistant to treatment with 3 M NaOH, but was sensitive to 1 M HCl, consistent with phosphorylation of histidine. Autophosphorylation was abolished by mutations that eliminated either the presumptive site of phosphorylation (His-353) or putative catalytic residues within the kinase domain. Truncations were used to delineate the region required for histidine kinase activity. An examination of cation requirements indicated that ETR1 requires Mn2+ for autophosphorylation. These results demonstrate that higher plants contain proteins with histidine kinase activity. Furthermore, these results indicate that aspects of ethylene signaling may be regulated by changes in histidine kinase activity of the receptor.     

A lymphohistiocytic variant of anaplastic large cell lymphoma with demonstration of the t(2;5)(p23;q35) chromosome translocation

Although a seemingly simple concept, sample volume and the reaction vessel size are important considerations when undertaking an alkaline hydrolysis of a phosphoprotein, particularly if the phosphoamino acid of interest is either phosphohistidine or phosphotyrosine. It should be noted that the experiments conducted in this article used large concentrations of both phosphotyrosine and the most stable form of phosphohistidine (8), which highlights the problems that may be faced during phosphoamino acid analysis of a protein sample that contains only small amounts of either phosphoamino acid. Although not tested, it is likely that similar hydrolysis effects may occur for phospholysine. If the reaction volume is to be kept to a minimum and the alkaline digestion is from either a membrane blot or in solution, then the use of a mineral oil overlay should be considered to prevent concentration of the alkali and hydrolysis of the phosphate moiety.     

Phylogenetic aspects of laterality

Phospholipase D (PLD) enzymes catalyze the hydrolysis of phosphatidylcholine and are involved in membrane trafficking and cytoskeletal reorganization. The Saccharomyces cerevisiae SPO14 gene encodes a PLD that is essential for meiosis. We have analyzed the role of PLD in meiosis by examining two mutant proteins, one with a point mutation in a conserved residue (Spo14pK--> H) and one with an amino-terminal deletion (Spo14pDeltaN), neither of which can restore meiosis in a spo14 deletion strain. Spo14pK--> H is enzymatically inactive, indicating that PLD activity is required, whereas Spo14pDeltaN retains PLD catalytic activity in vitro, indicating that PLD activity is not sufficient for meiosis. To explore other aspects of Spo14 function, we followed the localization of the enzyme during meiosis. Spo14p is initially distributed throughout the cell, becomes concentrated at the spindle pole bodies after the meiosis I division, and at meiosis II localizes to the new spore membrane as it surrounds the nuclei and then expands to encapsulate the associated cytoplasm during the formation of spores. The catalytically inactive protein also undergoes relocalization during meiosis; however, in the absence of PLD activity, no membrane is formed. In contrast, Spo14pDeltaN does not relocalize properly, indicating that the failure of this protein to complement a spo14 mutant is due to its inability to localize its PLD activity. Furthermore, we find that Spo14p movement is correlated with phosphorylation of the protein. These experiments indicate that PLD participates in regulated membrane formation during meiosis, and that both its catalytic activity and subcellular redistribution are essential for this function.     

Structural and mechanistic comparison of prokaryotic and eukaryotic phosphoinositide-specific phospholipases C

Phosphoinositide-specific phospholipases C (PI-PLCs) are ubiquitous enzymes that catalyse the hydrolysis of phosphoinositides to inositol phosphates and diacylglycerol (DAG). Whereas the eukaryotic PI-PLCs play a central role in most signal transduction cascades by producing two second messengers, inositol-1,4,5-trisphosphate and DAG, prokaryotic PI-PLCs are of interest because they act as virulence factors in some pathogenic bacteria. Bacterial PI-PLCs consist of a single domain of 30 to 35 kDa, while the much larger eukaryotic enzymes (85 to 150 kDa) are organized in several distinct domains. The catalytic domain of eukaryotic PI-PLCs is assembled from two highly conserved polypeptide stretches, called regions X and Y, that are separated by a divergent linker sequence. There is only marginal sequence similarity between the catalytic domain of eukaryotic and prokaryotic PI-PLCs. Recently the crystal structures of a bacterial and a eukaryotic PI-PLC have been determined, both in complexes with substrate analogues thus enabling a comparison of these enzymes in structural and mechanistic terms. Eukaryotic and prokaryotic PI-PLCs contain a distorted (beta alpha)8-barrel as a structural motif with a surprisingly large structural similarity for the first half of the (beta alpha)8-barrel and a much weaker similarity for the second half. The higher degree of structure conservation in the first half of the barrel correlates with the presence of all catalytic residues, in particular two catalytic histidine residues, in this portion of the enzyme. The second half contributes mainly to the features of the substrate binding pocket that result in the distinct substrate preferences exhibited by the prokaryotic and eukaryotic enzymes. A striking difference between the enzymes is the utilization of a catalytic calcium ion that electrostatically stabilizes the transition state in eukaryotic enzymes, whereas this role is filled by an analogously positioned arginine in bacterial PI-PLCs. The catalytic domains of all PI-PLCs may share not only a common fold but also a similar catalytic mechanism utilizing general base/acid catalysis. The conservation of the topology and parts of the active site suggests a divergent evolution from a common ancestral protein.     

A new class of phosphotransferases phosphorylated on an aspartate residue in an amino-terminal DXDX(T/V) motif

When incubated with their substrates, human phosphomannomutase and L-3-phosphoserine phosphatase are known to form phosphoenzymes with chemical characteristics of an acyl-phosphate. The phosphorylated residue in phosphomannomutase has now been identified by mass spectrometry after reduction of the phosphoenzyme with tritiated borohydride and trypsin digestion. It is the first aspartate in a conserved DVDGT motif. Replacement of either aspartate of this motif by asparagine or glutamate resulted in complete inactivation of the enzyme. The same mutations performed in the DXDST motif of L-3-phosphoserine phosphatase also resulted in complete inactivation of the enzyme, except for the replacement of the second aspartate by glutamate, which reduced the activity by only about 40%. This suggests that the first aspartate of the motif is also the phosphorylated residue in L-3-phosphoserine phosphatase. Data banks contained seven other phosphomutases or phosphatases sharing a similar, totally conserved DXDX(T/V) motif at their amino terminus. One of these (beta-phosphoglucomutase) is shown to form a phosphoenzyme with the characteristics of an acyl-phosphate. In conclusion, phosphomannomutase and L-3-phosphoserine phosphatase belong to a new phosphotransferase family with an amino-terminal DXDX(T/V) motif that serves as an intermediate phosphoryl acceptor.     

Scanning alanine mutagenesis of the CDP-alcohol phosphotransferase motif of Saccharomyces cerevisiae cholinephosphotransferase

Cholinephosphotransferase (EC 2.7.8.2) catalyzes the formation of a phosphoester bond via the transfer of a phosphocholine moiety from CDP-choline to diacylglycerol forming phosphatidylcholine and releasing CMP. A motif, Asp113-Gly114-(X)2-Ala117-Arg118-(X)8-Gly127+ ++-(X)3-Asp131-(X)3-Asp135, located within the CDP-choline binding region of Saccharomyces cerevisiae cholinephosphotransferase (CPT1 ?/Author: Please confirm that a gene is meant here.) is also found in several other phospholipid synthesizing enzymes that catalyze the formation of a phosphoester bond utilizing a CDP-alcohol and a second alcohol as substrates. To determine if this motif is diagnostic of the above reaction type scanning alanine mutagenesis of the conserved residues within S. cerevisiae cholinephosphotransferase was performed. Enzyme activity was assessed in vitro using a mixed micelle enzyme assay and in vivo by determining the ability of the mutant enzymes to restore phosphatidylcholine synthesis from radiolabeled choline in an S. cerevisiae strain devoid of endogenous cholinephosphotransferase activity. Alanine mutants of Gly114, Gly127, Asp131, and Asp135 were inactive; mutants, Ala117 and Arg118 displayed reduced enzyme activity, and Asp113 displayed wild type activity. The analysis described is the first molecular characterization of a CDP-alcohol phosphotransferase motif and results predict a catalytic role utilizing a general base reaction proceeding through Asp131 or Asp135 via a direct nucleophilic attack of the hydroxyl of diacylglyerol on the phosphoester bond of CDP-choline that does not proceed via an enzyme bound intermediate. Residues Ala117 and Arg118 do not participate directly in catalysis but are likely involved in substrate binding or positioning with Arg118 predicted to associate with a phosphate moiety of CDP-choline.     

The diguanosine nucleotides: do they exist in aquatic fungi?

The aquatic fungi Achlya ambisexualis and Blastocladiella emersonii were grown in the presence of 32Pi and the 32P-labeled acid-soluble nucleotide fractions were analyzed by ion-exchange chromatography on DEAE-cellulose. Selected column fractions containing diguanosine tri- and tetra-phosphates (Gp3G and Gp4G) added as chromatographic markers were analyzed further for 32P by chromatography and (or) enzyme hydrolysis. The results of these experiments clearly indicate that neither Gp4G nor Gp3G is synthesized during vegetative growth of these organisms and cast doubt on the hypothesis that diguanosine nucleotides are important metabolic regulators in fungi.