Galactose-1-phosphate uridylyltransferase. Purification of the enzyme and stereochemical course of each step of the double-displacement mechanism

A convenient new procedure for purifying galactose-1-phosphate uridylyltransferase from Escherichia coli is described. It departs from earlier methods by introducing the use of a Cibacron Blue-agarose (Bio-Rad Affi-Gel Blue) at an early stage. Purification is completed by ion-exchange chromatography using DEAE-Sephadex A-50. The procedure is substantially shorter than earlier methods and reproducibly yields enzyme of high specific activity suitable for use in structural work such as characterization of the intermediate uridylyl-enzyme. The first step of the galactose-1-P uridylyltransferase reaction is the transfer of the uridylyl group from UDP-glucose to N3 of a histidine residue in the enzyme to form the covalent uridylyl-enzyme and glucose-1-P. The uridylyl-enzyme intermediate then reacts in a second step with galactose-1-P to form UDP-galactose. The enzyme accepts (RP)-UDP alpha S-glucose as a good substrate, converting it to (RP)-UDP alpha S-galactose, i.e., with overall retention of configuration. In this paper we show that reaction of the enzyme with (RP)-[2-14C]UDP alpha S-glucose produces a [2-14C]uridylyl alpha S-enzyme that can be converted by base-catalyzed cyclization to (RP)-[2-14C]cUMPS. Inasmuch as cyclization must have proceeded with inversion of configuration at phosphorus, the corresponding configuration in the intermediate must have been the inverse of that in the substrate. Therefore, formation of uridylyl alpha S-enzyme from (RP)-UDP alpha S-glucose proceeds with inversion of configuration, and overall retention arises from inversion in each of the two steps. The results support the authenticity of the isolated uridylyl-enzyme as the true reaction intermediate.(ABSTRACT TRUNCATED AT 250 WORDS)     

Galactose-1-phosphate uridylyltransferase: isolation and properties of a uridylyl-enzyme intermediate.

Galactose-1-P uridylyltransferase catalyzes the interconversion of UDP-galactose and galactose-1-P with UDP-galactose and glucose-1-P by a double displacement pathway involving a uridylyl-enzyme intermediate. The amount of radioactivity incorporated into the protein by uracil-labeled UDP-glucose is decreased by the presence of UDP-galactose, which completes with UDP-glucose for uridylylating the enzyme. The amount of glucose-1-P released upon reaction of the enzyme with UDP-glucose indicates that the dimeric enzyme contains more than one active site per molecule, 1.7 on the average for the most active preparation obtained. This suggests that there is one uridylylation site per subunit and that the subunits are similar or identical. The ureidylyl-enzyme is stable to mild alkaline conditions, 0.10 M NaOH at 60 degrees C for 1 h, but is very sensitive to acid, being largely hydrolyzed after 12 h at pH 3.5 and 4 degrees C. The principal radioactive product resulting from hydrolysis of [uracil-2-14C]uridylyl-ens of the uridylyl-enzyme under the latter conditions is [l]ump. The hydrolytic properties of the uridylyl-enzyme show that the uridylyl moiety is bonded to the protein through a phosphoramidate linkage. Complementary studies on the effects of group selective reagents on the activity of the enzyme suggest that the active site nucleophile to which the uridylyl group is bonded may be a histidine residue. The enzyme is rapidly inactivated by diethyl pyrocarbonate at pH 6 and 0 degrees C and reactivated by NH2OH. UDP-glucose at 0.5 mM fully protects the enzyme against diethyl pyrocarbonate while 70 mM galactose-1-P has only a slight protective effect. Uridylyl-enzyme in inactivated by diethyl pyrocarbonate at no more than 2% of the rate for free enzyme. The enzyme is not inactivated by NaBH4 or by NaBH4 in the presence of UDP-glucose. It is not inhibited by 1 mM pyridoxal phosphate or by 0.5 mM 5-nitrosalicylaldehyde at pH 8.6 and it is not inactivated by NaBH4 in the presence of pyridoxal phosphate. The enzyme is inactivated by 5 to 50 muM p-hydroxymercuribenzoate at pH 8.5, but substrates exert no detectable protective effect against this reagent. It is concluded that the enzyme contains at least one essential sulfhydryl group which is not located in the active site in such a way as to be shielded by substrates.     

The phosphohydrolase component of the hepatic microsomal glucose-6-phosphatase system is a 36.5-kilodalton polypeptide

The phosphohydrolase component of the microsomal glucose-6-phosphatase system has been identified as a 36.5-kDa polypeptide by 32P-labeling of the phosphoryl-enzyme intermediate formed during steady-state hydrolysis. A 36.5-kDa polypeptide was labeled when disrupted rat hepatic microsomes were incubated with three different 32P-labeled substrates for the enzyme (glucose-6-P, mannose-6-P, and PPi) and the reaction terminated with trichloroacetic acid. Labeling of the phosphoryl-enzyme intermediate with [32P]glucose-6-P was blocked by several well-characterized competitive inhibitors of glucose-6-phosphatase activity (e.g. Al(F)-4 and Pi) and by thermal inactivation, and labeling was not seen following incubations with 32Pi and [U-14C]glucose-6-P. In agreement with steady-state dictates, the amount of [32P]phosphoryl intermediate was directly and quantitatively proportional to the steady-state glucose-6-phosphatase activity measured under a variety of conditions in both intact and disrupted hepatic microsomes. The labeled 36.5-kDa polypeptide was specifically immunostained by antiserum raised in sheep against the partially purified rat hepatic enzyme, and the antiserum quantitatively immunoprecipitated glucose-6-phosphatase activity from cholate-solubilized rat hepatic microsomes. [32P]Glucose-6-P also labeled a similar-sized polypeptide in hepatic microsomes from sheep, rabbit, guinea pig, and mouse and rat renal microsomes. The glucose-6-phosphatase enzyme appears to be a minor protein of the hepatic endoplasmic reticulum, comprising about 0.1% of the total microsomal membrane proteins. The centrifugation of sodium dodecyl sulfate-solubilized membrane proteins was found to be a crucial step in the resolution of radiolabeled microsomal proteins by sodium dodecyl sulfate-polyacrylamide gel electrophoresis.     

Stereochemical retention of the configuration in the action of Fhit on phosphorus-chiral substrates

Fhit is the protein product of FHIT, a candidate human tumor suppressor gene. Fhit catalyzes the hydrolysis of diadenosine triphosphate (Ap3A) to AMP and ADP. Fhit is here shown to catalyze the hydrolysis in H218O with production of adenosine 5'-[18O]phosphate and ADP, proving that the substitution of water is at Palpha and not at Pbeta. The chain fold of Fhit is similar to that of galactose-1-phosphate uridylyltransferase, which functions by a double-displacement mechanism through the formation of a covalent nucleotidyl-enzyme intermediate and overall retention of configuration at Palpha. The active site of Fhit contains a histidine motif that is reminiscent of the HPH motif in galactose-1-phosphate uridylyltransferases, in which the first histidine residue serves as the nucleophilic catalyst to which the nucleotidyl group is bonded covalently in the covalent intermediate. In this work, the Fhit-catalyzed cleavage of (RP)- and (SP)-gamma-(m-nitrobenzyl) adenosine 5'-O-1-thiotriphosphate (mNBATPalphaS) in H218O to adenosine 5'-[18O]thiophosphate is shown to proceed with overall retention of configuration at phosphorus. gamma-(m-Nitrobenzyl) adenosine 5'-O-triphosphate (mNBATP) is approximately as good a substrate for Fhit as Ap3A, and both (RP)- and (SP)-mNBATPalphaS are substrates that react at about 0.5% of the rate of Ap3A. The stereochemical evidence indicates that hydrolysis by Fhit proceeds by a double-displacement mechanism, presumably through a covalent AMP-enzyme intermediate.     

Roles of two conserved amino acid residues in the active site of galactose-1-phosphate uridylyltransferase: an essential serine and a nonessential cysteine

Galactose-1-phosphate uridylyltransferase (GalT) catalyzes the reversible transformation of uridine 5'-diphosphate glucose (UDPGlc) and galactose-1-phosphate into uridine 5'-diphosphate galactose (UDPGal) and glucose-1-phosphate through a double displacement mechanism, with the intermediate formation of a covalent uridylyl-enzyme (UMP-enzyme). The covalent linkage is a phosphoramidate formed between the UMP moiety and the His 166 N(epsilon)(2) of GalT, with His 166 N(delta1) retaining a proton throughout the catalytic cycle. Cys 160 and Ser 161 in Escherichia coli GalT are engaged in hydrogen bonding with the peripheral phosphoryl oxygen atoms of the substrate in the crystalline UMP-enzyme and in the crystalline complex of H166G-GalT with UDPGlc [Wedekind, J. E., Frey, P. A., and Rayment, I. (1996) Biochemistry 35, 11560-11569; Thoden, J. B., Ruzicka, F. J., Frey, P. A., Rayment, I., and Holden, H. M. (1997) Biochemistry 36, 1212-1222]. Site-directed mutagenesis, thermodynamic, transient kinetic, and steady-state kinetic studies have been performed to investigate the roles of Cys 160 and Ser 161 in catalysis. The absence of the thiol group of Cys 160 in the variants C160S and C160A did not seriously alter the enzymatic activity. However, the variant S161A displayed 7000-fold less activity than wild-type GalT. The low activity of S161A was directly related to impaired uridylylation rate constant (3.7 x 10(-)(2) s(-)(1)) and de-uridylylation rate constant (0.5 x 10(-)(2) s(-)(1)) resulting from a higher kinetic barrier for uridylyl-group transfer by the variant S161A as compared with the wild-type GalT. Equilibrium uridylylation studies showed that neither Cys 160 nor Ser 161 was involved in stabilizing the uridylyl-enzyme intermediate. The results lead to the conclusion that the conserved Cys 160 does not play a critical role in catalysis. Ser 161 is most likely involved in donating a hydrogen bond to the beta-phosphoryl group of a substrate, thereby providing proper orientation for nucleophilic catalysis.     

Multiple ion-dependent and substrate-dependent Na+/K+-ATPase conformational states. Transient and steady-state kinetic studies

The hydrolysis of beta-(2-furyl)acryloyl phosphate (FAP), catalyzed by the Na+/K+-ATPase, is faster than the catalyzed hydrolysis of ATP. This is due to catalyzed hydrolysis of the pseudosubstrate by K+-dependent states of the enzyme, thus bypassing the Na+-dependent enzyme states that are required and are rate limiting in ATP hydrolysis. Unlike ATP, FAP is a positive effector of the E2 state. A study of FAP hydrolysis permits a detailed analysis of later steps in the overall ion translocation-ATP hydrolysis pathway. During the steady state of FAP hydrolysis in the presence of K+, substantial phosphoryl-enzyme is formed, as is indicated by the covalent incorporation of 32P from [32P]FAP. A comparison of the phosphoryl-enzyme yield with the rate of overall hydrolysis reveals that at 25 degrees C the phosphoryl-enzyme formed is all kinetically competent. Both the yield of phosphoryl-enzyme and the rate of overall hydrolysis of FAP are [K+] dependent. The transition E1 in equilibrium E2 is also [K+] dependent, but the rate of transition is differently affected by [K+] than are the above-mentioned two processes. Two distinct roles for K+ are indicated, as an effector of the E1-E2 equilibrium and as a "catalyst" in the hydrolysis of the E2-P. In contrast to the results at 25 degrees C, a virtually stoichiometric yield of phosphoryl-enzyme occurs at 0 degree C in the presence of Na+ and the absence of K+. At lower concentrations of K+ and in the presence of Na+, the hydrolysis of FAP at 0 degree C proceeds substantially through the E1-E2 pathway characteristic of ATP hydrolysis. The selectivity of FAP for the E2-K+-dependent pathway is due to the thermal inactivation of E1 at 25 degrees C in the absence of ATP or ATP analogues, even at high concentrations of Na+. These results emphasize the existence of multiple functional "E1" and "E2" states in the overall ATPase-ion translocation pathway.     

Galactose-1-phosphate uridylyltransferase: identification of histidine-164 and histidine-166 as critical residues by site-directed mutagenesis

Galactose-1-phosphate uridylyltransferase catalyzes the interconversion of UDP-glucose and galactose-1-P with UDP-galactose and glucose-1-P by a double-displacement mechanism involving the compulsory formation of a uridylyl enzyme intermediate. The uridylyl group is covalently bonded to the N3 position of a histidine residue in the uridylyl enzyme. The galT gene of Escherichia coli, which codes for the uridylyltransferase and is contained in a plasmid for transformation of E. coli, has been sequenced, and the positions of the 15 histidine residues have been determined from the deduced amino acid sequence of this protein. Fifteen mutant genes, in each of which one of the 15 histidine codons has been changed to an asparagine codon, have been generated and used to transform the E. coli strain JM101. When extracts of the transformants were assayed for uridylyltransferase, 13 exhibited high levels of activity. Two of the extracts containing mutant uridylyltransferase exhibited less than control levels of activity. These mutant proteins, H164N and H166N, were overexpressed, isolated, and tested for their ability to form the compulsory uridylyl enzyme intermediate. Neither the H164N nor the H166N mutant proteins could form the intermediate. Thus, both His-164 and His-166 are critical for activity, and their proximity suggests that both are in the active site. One is the essential nucleophilic catalyst to which the uridylyl group is bonded in the intermediate, and the other serves an equally important, as yet unknown, function. The active-site sequence His(164)-Pro-His(166) is conserved in this enzyme from E. coli, humans, Saccharomyces, and Streptomyces.     

Studies on a rat-liver cell-sap protein yielding 3-[32P]-phosphohistidine after incubation with [32P]ATP and alkaline hydrolysis. Identification of the protein as ATP citrate lyase

1. The rat-liver cell-sap material from which 3-[32P]phosphohistidine was previously isolated after incubation with [gamma-32P]ATP and alkaline hydrolysis, was shown to increase about 6-fold on a high-carbohydrate diet. This increase in 32P labelling corresponded to the increase in ATP citrate lyase activity of livers of rats fed on a high-carbohydrate diet, as reported by others. 2. ATP citrate lyase [ATP:citrate oxaloacetate-lyase (CoA-acetylating and ATP-dephopshorylating), EC 4.1.3.8] was purified from rat liver essentially according to the method of Plowman and Cleland (J. Biol. Chem., 242 (1967) 4239). The purified enzyme was incubated for a short time at 0 degree with [gamma-32P]ATP in the presence of 20 mM magnesium acetate. The phosphorylated protein was hydrolysed in alkali and the main part of the radioactivity was identified as 3-[32P]phosphohistidine. The identity of the phosphorylated amino acid was established by Dowex-1 chromatography, paper electrophoresis, paper chromatography and by analysis of the stability to acid. 3. It is concluded from these and previous results from this laboratory that ATP citrate lyase and nucleoside diphosphate kinase (ATP:nucleoside diphosphate phosphotransferase, EC 2.7.4.6) account for most of the normal rat-liver cell-sap protein which is rapidly phosphorylated by ATP.     

The mechanism of action of the fragile histidine triad, Fhit: isolation of a covalent adenylyl enzyme and chemical rescue of H96G-Fhit

The human fragile histidine triad protein Fhit catalyzes the Mg(2+)-dependent hydrolysis of P(1)-5'-O-adenosine-P(3)-5'-O-adenosine triphosphate, Ap(3)A, to AMP and ADP. The reaction is thought to follow a two-step mechanism, in which the complex of Ap(3)A and Mg(2+) reacts in the first step with His96 of the enzyme to form a covalent Fhit-AMP intermediate and release MgADP. In the second step, the intermediate Fhit-AMP undergoes hydrolysis to AMP and Fhit. The mechanism is inspired by the chain-fold similarities of Fhit to galactose-1-phosphate uridylyltransferase, which functions by an analogous mechanism, and the observation of overall retention in configuration at phosphorus in the action of Fhit (Abend, A., Garrison, P. N., Barnes, L. D., and Frey, P. A. (1999) Biochemistry 38, 3668-3676). Direct evidence in support of this mechanism is reported herein. Reaction of Fhit with [8,8'-(3)H]-Ap(3)A and denaturation of the enzyme in the steady state leads to protein-bound tritium corresponding to 11% of the active sites. Similar experiments with the poor substrate MgATP leads to 0.9% labeling. The mutated protein H96G-Fhit is completely inactive against MgAp(3)A. However, it is chemically rescued by free histidine. H96G-Fhit also catalyzes the hydrolysis of adenosine-5'-phosphoimidazolide, AMP-Im, and of adenosine-5'-phospho-N-methylimidazolide, AMP-N-MeIm. The hydrolyses of AMP-Im and of AMP-N-MeIm by H96G-Fhit are thought to represent chemical rescue of the covalent Fhit-AMP intermediate. Wild-type Fhit is also found to catalyze the hydrolyses of AMP-Im and of AMP-N-MeIm nearly as efficiently as the hydrolysis of MgAp(3)A. The results indicate that Mg(2+) in the reaction of Ap(3)A is required for the first step, the formation of the covalent intermediate Fhit-AMP, and not for the hydrolysis of the intermediate in the second step.     

Evidence of histidine phosphorylation in isocitrate lyase from Escherichia coli

Escherichia coli isocitrate lyase (EC 4.1.3.1.) can be phosphorylated in vitro by an ATP-dependent reaction. The enzyme becomes phosphorylated by an endogenous kinase when partially purified sonic extracts are incubated with [gamma-32P]ATP. Treatment of isocitrate lyase with diethyl pyrocarbonate, a histidine-modifying reagent, blocked incorporation of [32P]phosphate from [gamma-32P]ATP. The isoelectric point of the enzyme was altered by treatment with phosphoramidate, a histidine phosphorylating agent, which suggests that isocitrate lyase can be phosphorylated at a histidine residue(s). Immunoprecipitated 32P-labeled isocitrate lyase was subjected to alkaline hydrolysis, mixed with chemically synthesized phosphohistidine standards, and analyzed by anion exchange chromatography. Characterization of the phosphoamino acid was based on the demonstration that the 32P-labeled product from alkali-hydrolyzed isocitrate lyase comigrated with synthetic 1-phosphohistidine. In addition, loss of catalytic activity after treatment with potato acid phosphatase indicates that catalytically active isocitrate lyase is the phosphorylated form of the enzyme.     

Evidence for a phosphoryl-enzyme intermediate in phosphate ester hydrolysis by purple acid phosphatase from bovine spleen

The possibility of the existence of a covalent enzyme-phosphoryl intermediate, E-PO3, during catalysis of phosphate ester hydrolysis by the purple acid phosphatase (PAP) from bovine spleen has been examined. Transphosphorylation experiments show that up to 22% of the phosphoryl group from p-nitrophenyl phosphate (PNPP) can be transferred to primary alcohols. Burst experiments at high pH (9.1 or 8.1 for reduced or oxidized PAP, respectively), where hydrolysis of a phosphoenzyme intermediate is expected to be rate-limiting, show clear evidence for stoichiometric bursts of p-nitrophenolate from PNPP. The formation of base-stable, acid-sensitive adducts between PAP and the 32PO3 group of [gamma-32P]ATP has been demonstrated. The pH dependence of the kinetics parameters for reduced PAP has been determined over the range pH 3-8; a feature with a pKa of approximately 6.75 that is attributable to the enzyme-substrate complex is observed. Taken together, the present results are consistent with a two-stem pseudo Uni Bi mechanism that utilizes a covalent enzyme-phosphoryl intermediate, possibly a phosphohistidine.     

Significance of metal ions in galactose-1-phosphate uridylyltransferase: an essential structural zinc and a nonessential structural iron.

Galactose-1-phosphate uridylyltransferase (GalT) catalyzes the reversible transformation of UDP-glucose and galactose-1-phosphate (Gal-1-P) into UDP-galactose and glucose-1-phosphate (Glc-1-P) by a double displacement mechanism, with the intermediate formation of a covalent uridylyl-enzyme (UMP-enzyme). GalT is a metalloenzyme containing 1.2 mol of zinc and 0.7 mol of iron/mol of subunits [Ruzicka, F. J., Wedekind, J. E., Kim, J., Rayment, I., and Frey, P. A. (1995) Biochemistry 34, 5610-5617]. The zinc site lies 8 A from His 166 in active site, and the iron site lies 30 A from the active site [Wedekind,J. E., Frey, P. A., & Rayment, I. (1995) Biochemistry 34, 11049-11061]. Zinc is coordinated in tetrahedral geometry by Cys 52, Cys 55, His 115, and His 164. His 164 is part of the highly conserved active-site triad His 164-Pro 165-His 166, in which His 166 is the nucleophilic catalyst. Iron is coordinated in square pyramidal geometry with His 296, His 298, and Glu 182 in bidentate coordination providing the base ligands and His 281 providing the axial ligand. In the present study, site-directed mutagenesis, kinetic, and metal analysis studies show that C52S-, C55S-, and H164N-GalT are 3000-, 600-, and 10000-fold less active than wild-type. None of the variants formed the UMP-enzyme in detectable amounts upon reaction with UDP-Glc in the absence of Gal-1-P. Their zinc content was very low, and the zinc + iron content was about 50% of that for wild-type GalT. Mutation of His 115 to Asn 115 resulted in decreased activity to 2.9% of wild-type, with retention of zinc and iron. In contrast to the zinc-binding site, Glu 182 in the iron site is not important for enzymatic activity. The variant E182A-GalT displayed about half the activity of wild-type GalT, and all of the active sites underwent uridylylation to the UMP-enzyme, similar to wild-type GalT, upon reaction with UDP-Glc. Metal analysis showed that while E182A-GalT contained 0.9 equiv of zinc/subunit, it contained no iron. The residual zinc can be removed by dialysis with 1,10-phenanthroline, with the loss in activity being proportional to the amount of residual zinc. It is concluded that the presence of zinc is essential for maintaining GalT function, whereas the presence of iron is not essential.     

Identification of a nerve ending-enriched 29-kDa protein,labeled with [3-32P]1,3-bisphosphoglycerate,as monophosphoglycerate mutase: inhibition by fructose-2,6-bisphosphate via enhancement of dephosphorylation

Glucose metabolism is of vital importance in normal brain function. Evidence indicates that glycolysis, in addition to production of ATP, plays an important role in maintaining normal synaptic function. In an effort to understand the potential involvement of a glycolytic intermediate(s) in synaptic function, we have prepared [3-32P]1,3-bisphosphoglycerate and [32P]3-phosphoglycerate and sought their interaction with a specific nerve-ending protein. We have found that a 29-kDa protein is the major component labeled with either [3-32P]1,3-bisphosphoglycerate or [32P]3-phosphoglycerate. The protein was identified as monophosphoglycerate mutase (PGAM). This labeling was remarkably high in the brain and synaptosomal cytosol fraction, consistent with the importance of glycolysis in synaptic function. Of interest, fructose-2,6-bisphosphate (Fru-2,6-P2) inhibited PGAM phosphorylation and enzyme activity. Moreover, Fru-2,6-P2 potently stimulated release of [32P]phosphate from the 32P-labeled PGAM (EC50 = 1 microM), suggesting that apparent reduction of PGAM phosphorylation and enzyme activity by Fru-2,6-P2 may be due to stimulation of dephosphorylation of PGAM. The significance of these findings is discussed.     

Mechanism of the bisphosphatase reaction of 6-phosphofructo-2-kinase/fructose-2,6-bisphosphatase probed by (1)H-(15)N NMR spectroscopy

The histidines in the bisphosphatase domain of rat liver 6-phosphofructo-2-kinase/fructose-2,6-bisphosphatase were labeled with (15)N, both specifically at N1' and globally, for use in heteronuclear single quantum correlation (HSQC) NMR spectroscopic analyses. The histidine-associated (15)N resonances were assigned by correlation to the C2' protons which had been assigned previously [Okar et al., Biochemistry 38, 1999, 4471-79]. Acquisition of the (1)H-(15)N HSQC from a phosphate-free sample demonstrated that the existence of His-258 in the rare N1' tautomeric state is dependent upon occupation of the phosphate binding site filled by the O2 phosphate of the substrate, fructose-2,6-bisphosphate, and subsequently, the phosphohistidine intermediate. The phosphohistidine intermediate is characterized by two hydrogen bonds involving the catalytic histidines, His-258 and His-392, which are directly observed at the N1' positions of the imidazole rings. The N1' of phospho-His-258 is protonated ((1)H chemical shift, 14.0 ppm) and hydrogen bonded to the backbone carbonyl of Gly-259. The N1' of cationic His-392 is hydrogen bonded ((1)H chemical shift, 13.5 ppm) to the phosphoryl moiety of the phosphohistidine. The existence of a protonated phospho-His-258 intermediate and the observation of a fairly strong hydrogen bond to the same phosphohistidine implies that hydrolysis of the covalent intermediate proceeds without any requirement for an "activated" water. Using the labeled histidines as probes of the catalytic site mutation of Glu-327 to alanine revealed that, in addition to its function as the proton donor to fructose-6-phosphate during formation of the transient phosphohistidine intermediate at the N3' of His-258, this residue has a significant role in maintaining the structural integrity of the catalytic site. The (1)H-(15)N HSQC data also provide clear evidence that despite being a surface residue, His-446 has a very acidic pK(a), much less than 6.0. On the basis of these observations a revised mechanism for fructose-2,6-bisphosphatase that is consistent with all of the previously published kinetic data and X-ray crystal structures is proposed. The revised mechanism accounts for the structural and kinetic consequences produced by mutation of the catalytic histidines and Glu-327. It also provides the basis for a hypothetical mechanism of bisphosphatase activation by cAMP-dependent phosphorylation of Ser-32, which is located in the N-terminal kinase domain.     

Identification of the phosphorylated intermediate of the Neurospora plasma membrane H+-ATPase as beta-aspartyl phosphate

The chemical nature of the phosphoryl enzyme linkage of the electrogenic proton-translocating ATPase (ATP phosphohydrolase, EC 3.6.1.3) in the plasma membrane of Neurospora has been identified as a mixed anhydride between phosphate and the beta-carboxyl group of an aspartic acid residue in the polypeptide chain. Incubation of isolated Neurospora plasma membrane vesicles containing 32P-labeled ATPase in buffers of increasing pH followed by analysis of the hydrolysis products yielded a pH versus hydrolysis profile characteristic of an acyl phosphate linkage. Reaction of labeled membranes with hydroxylamine at pH 5.3 also released [32P]i from the ATPase. Amino acid analyses of the Na[3H]BH4 reduction products obtained from membranes containing phosphorylated and dephosphorylated ATPase identified [3H]homoserine, the expected reduction product of beta-aspartyl phosphate, as the only additional tritiated reduction product in the samples from phosphorylated membranes. Tritium was not found in alpha-amino-delta-hydroxyvaleric acid, the reduction product of gamma-glutamyl phosphate, nor in proline, the degradation product of alpha-amino-delta-hydroxyvaleric acid. These results indicate that the phosphorylated intermediate of the Neurospora plasma membrane ATPase is a beta-aspartyl phosphate identical with that already known to exist in the Na+:K+- and Ca2+-translocating ATPases of animal cell origin. A common model for the mechanisms of all 3 ion-translocating ATPases is presented.     

Characterization of a phosphatidylinositol 4-phosphate-specific phosphomonoesterase in rat liver nuclear envelopes

Incubation of rat liver nuclear envelopes with [gamma-32P]ATP resulted in the synthesis of phosphatidylinositol-[4-32P]phosphate (PIP). Degradation of endogenously labeled PIP was observed upon the dilution of the labeled ATP with an excess of unlabeled ATP. This degradation was most rapid in the presence of EDTA, and was inhibited by MgCl2 and CaCl2. To further characterize the degradative activity, phosphatidylinositol[4-32P]phosphate and phosphatidylinositol [4,5-32P]bisphosphate (PIP2) were synthesized and isolated from erythrocyte plasma membranes. The 32P-labeled phospholipids were then resuspended in 0.4% Tween 80, a detergent that did not inhibit degradation of endogenously labeled PIP, and mixed with nuclear envelopes. [32P]PIP and [32P]PIP2 were degraded at rates of 2.25 and 0.04 nmol min-1 mg nuclear envelope protein-1, respectively. Only 32P was released from phosphatidyl[2-3H]inositol-[4-32P]phosphate, indicating that hydrolysis of PIP was due to a phosphomonoesterase activity (EC 3.1.3.36) in nuclear envelopes. Similarly, anion-exchange chromatographic analysis of the water-soluble products released from [32P]PIP indicated that inorganic phosphate was the sole 32P-labeled product. Hydrolysis of PIP was most rapid at neutral pH, and was not affected by inhibitors of acid phosphatase or alkaline phosphatase. Hydrolysis of PIP was also not inhibited by nonspecific phosphatase substrates, such as glycerophosphate, p-nitrophenylphosphate, AMP, or glucose 6-phosphate. Hydrolysis was stimulated by putrescine, and was inhibited by inositol 2-phosphate, spermidine, spermine, and neomycin.     

A novel pathway for phosphatidylcholine catabolism in rat brain homogenates.

Rat brain homogenates incubated with exogenous [32-P] phosphatidylcholine liberated: LYSO[32-P] phosphatidylcholine, sn-glycero-3-[32-P] phosphorylcholine, [32-P] phosphorylcholine, sn-gleycero-3-[32-P] phosphate and 32-Pi. Further investigation showed that [32-P] phosphorylcholine was released exclusively from sn-glycero-3-[32-P] phosphorylcholien by a novel diesterase activity. We propose that the enzyme be termed L-3-glycerylphosphinicocholine cholinephosphohydrolase (EC 3.1.4.-). Parallel experiments on rat liver homogenates and a P815Y mouse mastocytoma cell-lysate, revealed no diesterase activity.     

Evidence for two catalytic sites on 6-phosphofructo-2-kinase/fructose 2,6-bisphosphatase. Dynamics of substrate exchange and phosphoryl enzyme formation

The bifunctional enzyme 6-phosphofructo-2-kinase/fructose 2,6-bisphosphatase appears to be the only enzyme catalyzing the formation and hydrolysis of Fru-2,6-P2. The enzyme as we isolate it, contains a trace of tightly bound Fru-6-P. In this condition, it exhibited an ATPase activity comparable to its kinase activity. Inorganic phosphate stimulated all of its activities, by increasing the affinity for all substrates and increasing the Vmax of ATP and Fru-2,6-P2 hydrolysis. The enzyme catalyzed ADP/ATP and Fru-6-P/Fru-2,6-P2 exchanges at rates comparable to net reaction rates. It was phosphorylated by both [gamma-32P]ATP and [2-32P] Fru-2,6-P2, and the label from either donor was chased by either unlabeled donor, showing that the bound phosphate is hydrolyzed if not transferred to an acceptor ligand. The rate of labeling of the enzyme by [2-32P]Fru-2,6-P2 was 2 orders of magnitude greater than the maximal velocity of the bisphosphatase and therefore sufficiently fast to be a step in the hydrolysis. Both inorganic phosphate and Fru-6-P increased the rate and steady state of enzyme phosphorylation by ATP. Fru-2,6-P2 inhibited the ATPase and kinase reactions and Fru-6-P inhibited the Fru-2,6 bisphosphatase reaction while ATP and ADP had no effect. Removal of the trace of Fru-6-P by Glu-6-P isomerase and Glu-6-P dehydrogenase reduced enzyme phosphorylation by ATP to very low levels, greatly inhibited the ATPase, and rendered it insensitive to Pi, but did not affect ADP/ATP exchange. (alpha + beta)Methylfructofuranoside-6-P did not increase the rate or steady state labeling by ATP. These results suggest that labeling of the enzyme by ATP involved the production of [2-32P]Fru-2,6-P2 from the trace Fru-6-P. The 6-phosphofructo-2-kinase, fructose 2,6-bisphosphatase, and ATP/ADP exchange were all inhibited by diethylpyrocarbonate, suggesting the involvement of histidine residues in all three reactions. These results can be most readily explained in terms of two catalytic sites, a kinase site whose phosphorylation by ATP is negligible (or whose E-P is labile) and a Fru-2,6 bisphosphatase site which is readily phosphorylated by Fru-2,6-P2.     

Metabolism of inositol 1,3,4-trisphosphate to a new tetrakisphosphate isomer in angiotensin-stimulated adrenal glomerulosa cells

Angiotensin stimulates rapid and prominent increases in inositol polyphosphates and their metabolites in bovine glomerulosa cells labeled with [3H]inositol. In addition to the early formation of inositol 1,4,5-trisphosphate (Ins-1,4,5-P3) and inositol 1,3,4-trisphosphate (Ins-1,3,4-P3), as well as their intermediate product, inositol 1,3,4,5-tetrakisphosphate (Ins-1,3,4,5-P4), delayed increases in two new InsP4 isomers were consistently observed by high resolution high performance liquid chromatography. Studies on the metabolism of purified Ins-1,3,4,5-P4 preparations, labeled with [3H]inositol and 32P to monitor sites of dephosphorylation, were performed in permeabilized glomerulosa cells. In addition to rapid degradation of Ins-1,3,4,5-P3 to Ins-1,3,4-P3 and then to Ins-3,4-P2, there was delayed formation of one of the putative InsP4 isomers observed during AII stimulation in intact cells. The kinetics of formation of the new InsP4 isomer, and the lack of phosphate in its 5 position based on isotope ratios, were consistent with its origin from Ins-1,3,4-P3. This was confirmed by the conversion of [3H]Ins-1,3,4-P3 to the new InsP4 isomer in permeabilized cells by a kinase distinct from that which phosphorylates Ins-1,4,5-P3. These results have demonstrated that the dephosphorylation sequence of Ins-1,4,5-P3 metabolism is accompanied by a complex cycle of higher phosphorylations with formation of new intermediates of potential significance in cellular regulation.