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.     

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.     

Synthesis and properties of 5-azido-UDP-glucose. Development of photoaffinity probes for nucleotide diphosphate sugar binding sites

A new active site directed photoaffinity probe, which is a model compound for studying nucleotide diphosphate sugar binding proteins, has been synthesized by coupling 5-azido-UTP and [32P]Glc-1-P using yeast UDP-glucose pyrophosphorylase to produce [beta-32P]5-azidouridine 5'-diphosphoglucose (5N3UDP-Glc). This probe has photochemical properties similar to that of 5-azidoUTP (Evans, R. K., and Haley, B. E. (1987) Biochemistry 26, 269-276). The efficacy of 5N3UDP-Glc as an active site directed probe was demonstrated using yeast UDP-Glc pyrophosphorylase. Saturation effects of photoinsertion were observed with an apparent Kd of 51 microM and the natural substrate, UDP-Glc, prevented photoinsertion of [beta-32P]5N3UDP-Glc with an apparent Kd of 87 microM. Prevention of photoinsertion was also seen with UTP and pyrophosphate with apparent Kd values less than 200 microM. UMP, UDP, ATP, and GTP were much less effective competitors. Selective photoinsertion was observed with several partially purified enzymes including UDP-Glc dehydrogenase, UDP-Gal-4-epimerase, Gal-1-P uridyltransferase, and phosphorylase a. The absence of nonselective photoinsertion into bulk proteins was demonstrated with crude homogenates of rabbit liver as well as with several UDP-Glc binding proteins. Of the six purified enzymes tested, only phosphoglucomutase has been shown to incorporate radiolabel from the photoprobe in the absence of UV irradiation. These results and a discussion of the utility of 5N3UDP-Glc for detecting UDP-Glc binding proteins and isolating active site peptides are presented.     

Two distinct proton donors at the active site of Escherichia coli 2,4-dienoyl-CoA reductase are responsible for the formation of different products

NADPH-dependent 2,4-dienoyl-CoA reductase (DCR) is one of the auxiliary enzymes required for the beta-oxidation of unsaturated fatty acids. Mutants of Escherichia coli DCR were generated by site-directed mutagenesis to explore the molecular mechanism of this enzyme. The Tyr166Phe mutant, which was expected to be inactive due to the loss of its putative proton donor residue, exhibited 27% of the wild-type activity. However, the product of the reduction was 3-enoyl-CoA instead of 2-enoyl-CoA, the normal product. Glu164 seems to function as proton donor in the Tyr166Phe mutant, because the Tyr166Phe/ Glu164Gln double mutant was inactive whereas the Glu164Ala mutant exhibited low but significant activity. His252 is important for the efficient operation of Tyr166 because a His252Ala mutation by itself reduced the activity of DCR by 3 orders of magnitude, whereas the Tyr166Phe/His252Ala double mutation exhibited 4.4% of the wild-type activity. This data supports a mechanism that has Tyr166 with the assistance of His252 acting as proton donor in the wild-type enzyme to produce 2-enoyl-CoA, whereas Glu164 serves as the proton donor in the absence of Tyr166 to yield 3-enoyl-CoA. A Cys337Ala mutation, which resulted in the loss of most of the iron and acid-labile sulfur, decreased the reductase activity more than 1000-fold. This observation agrees with the proposed operation of an intramolecular electron transport chain that is essential for the effective catalysis of E. coli DCR.     

The binding of beta-glycerophosphate to glycogen phosphorylase b in the crystal

The binding of beta-glycerophosphate (glycerol-2-P) to glycogen phosphorylase b in the crystal has been studied by X-ray diffraction at 3 A resolution. Glycerol-2-P binds to the allosteric effector site in a position close to that of AMP, glucose-6-P, UDP-Glc, and phosphate. In this position, glycerol-2-P is stabilized through interactions of its phosphate moiety with the guanidinium groups of Arg 309 and Arg 310 which undergo conformational changes, and the hydroxyl group of Tyr 75, while the same residues and solvent are involved in van der Waals interactions with the remaining part of the molecule. Kinetic experiments indicate that glycerol-2-P partially competes with both the activator (AMP) and the inhibitor (glucose 6-phosphate) of phosphorylase b. A comparison of the positions of glycerol-2-P, AMP, glucose 6-phosphate, UDP-Glc, and Pi at the allosteric site is presented.     

Cloning and expression analysis of a UDP-galactose/glucose pyrophosphorylase from melon fruit provides evidence for the major metabolic pathway of galactose metabolism in raffinose oligosaccharide metabolizing plants

The Cucurbitaceae translocate a significant portion of their photosynthate as raffinose and stachyose, which are galactosyl derivatives of sucrose. These are initially hydrolyzed by alpha-galactosidase to yield free galactose (Gal) and, accordingly, Gal metabolism is an important pathway in Cucurbitaceae sink tissue. We report here on a novel plant-specific enzyme responsible for the nucleotide activation of phosphorylated Gal and the subsequent entry of Gal into sink metabolism. The enzyme was antibody purified, sequenced, and the gene cloned and functionally expressed in Escherichia coli. The heterologous protein showed the characteristics of a dual substrate UDP-hexose pyrophosphorylase (PPase) with activity toward both Gal-1-P and glucose (Glc)-1-P in the uridinylation direction and their respective UDP-sugars in the reverse direction. The two other enzymes involved in Glc-P and Gal-P uridinylation are UDP-Glc PPase and uridyltransferase, and these were also cloned, heterologously expressed, and characterized. The gene expression and enzyme activities of all three enzymes in melon (Cucumis melo) fruit were measured. The UDP-Glc PPase was expressed in melon fruit to a similar extent as the novel enzyme, but the expressed protein was specific for Glc-1-P in the UDP-Glc synthesis direction and did not catalyze the nucleotide activation of Gal-1-P. The uridyltransferase gene was only weakly expressed in melon fruit, and activity was not observed in crude extracts. The results indicate that this novel enzyme carries out both the synthesis of UDP-Gal from Gal-1-P as well as the subsequent synthesis of Glc-1-P from the epimerase product, UDP-Glc, and thus plays a key role in melon fruit sink metabolism.     

Separation and characteristics of galactose-1-phosphate and glucose-1-phosphate uridyltransferase from fruit peduncles of cucumber

Galactose-1-phosphate uridyltransferase (EC 2.7.7.10), responsible for the conversion of galactose-1-phosphate (Gal-1-P) to uridine diphosphate galactose (UDPgal) was examined in fruit peduncles of Cucumis sativus L. Two uridyltransferases (pyrophosphorylases), from I and II, were partially purified and resolved on a diethylamino-ethyl-cellulose column. Form I can utilize glucose-1-phosphate (Glc-1-P), while form II can utilize either Gal-1-P or Glc-1-P, with a preference for Gal-1-P. Form I was more heat stable than form II. Both Glc-1-P and Gal-1-P activities of form II were inactivated at the same rate by heating. The finding of a uridyltransferase with preference for Gal-1-P indicates that cucumber may have a Gal-1-P uridyltransferase (pyrophosphorylase) pathway for the catabolism of stachyose in the peduncles. The absence of the enzyme UDP-glucose-hexose-1-phosphate uridyltransferase (EC 2.7.7.12) in this tissue rules out catabolism by the classical Leloir pathway. The incorporation of carbon from UDPglc into Glc-1-P as opposed to sucrose may be regulated by the activities of the uridyltransferases. Pyrophosphate, in the same concentration range, inhibits UDP-gal formation (K_i=0.58±0.10 mM) and stimulates Glc-1-P formation. The ratio of units of pyrophosphatase to units of Gal-1-P uridyltransferase was higher in peduncles from growing fruit than from unpollinated fruit. Modulation of carbon partitioning through a uridyltransferase pathway may be a factor controlling growth of the cucumber fruit.Abbreviations Gal-1-P Galactose-1-phosphate - Glc-1-P glucose-1-phosphate - UDPgal uridine diphosphate galactose - UDPglc uridine diphosphate glucose Paper No. 6908 of the Journal Series of the North Carolina Agricultural Research Service, Raleigh. The use of trade names in this publication does not imply endorsement by the North Carolina Agricultural Research Service of products named, nor criticism of similar ones not mentioned     

Mediators of galactose sensitivity in UDP-galactose 4'-epimerase-impaired mammalian cells

UDP-galactose 4'-epimerase (GALE) catalyzes the final step in the Leloir pathway of galactose metabolism, interconverting UDP-galactose and UDP-glucose. Unlike its Escherichia coli counterpart, mammalian GALE also interconverts UDP-N-acetylgalactosamine and UDP-N-acetylglucosamine. Considering the key roles played by all four of these UDP-sugars in glycosylation, human GALE therefore not only contributes to the Leloir pathway, but also functions as a gatekeeper overseeing the ratios of important substrate pools required for the synthesis of glycosylated macromolecules. Defects in human GALE result in the disorder epimerase-deficiency galactosemia. To explore the relationship among GALE activity, substrate specificity, metabolic balance, and galactose sensitivity in mammalian cells, we employed a previously described GALE-null line of Chinese hamster ovary cells, ldlD. Using a transfection protocol, we generated ldlD derivative cell lines that expressed different levels of wild-type human GALE or E. coli GALE and compared the phenotypes and metabolic profiles of these lines cultured in the presence versus absence of galactose. We found that GALE-null cells accumulated abnormally high levels of Gal-1-P and UDP-Gal and abnormally low levels of UDP-Glc and UDP-GlcNAc in the presence of galactose and that human GALE expression corrected each of these defects. Comparing the human GALE- and E. coli GALE-expressing cells, we found that although GALE activity toward both substrates was required to restore metabolic balance, UDP-GalNAc activity was not required for cell proliferation in the presence of otherwise cytostatic concentrations of galactose. Finally, we found that uridine supplementation, which essentially corrected UDP-Glc and, to a lesser extent UDP-GlcNAc depletion, enabled ldlD cells to proliferate in the presence of galactose despite the continued accumulation of Gal-1-P and UDP-Gal. These data offer important insights into the mechanism of galactose sensitivity in epimerase-impaired cells and suggest a potential novel therapy for patients with epimerase-deficiency galactosemia.     

Motor domain mutation traps kinesin as a microtubule rigor complex

Conventional kinesin is a highly processive, microtubule-based motor protein that drives the movement of membranous organelles in neurons. Using in vivo genetics in Drosophila melanogaster, Glu164 was identified as an amino acid critical for kinesin function [Brendza, K. M., Rose, D. J., Gilbert, S. P., and Saxton, W. M. (1999) J. Biol. Chem. 274, 31506-31514]. Glu164 is located at the beta-strand 5a/loop 8b junction of the catalytic core and projects toward the microtubule binding face in close proximity to key residues on beta-tubulin helix alpha12. Substitution of Glu(164) with alanine (E164A) results in a dimeric kinesin with a dramatic reduction in the microtubule-activated steady-state ATPase (5 s(-1) per site versus 22 s(-1) per site for wild-type). Our analysis shows that E164A binds ATP and microtubules with a higher affinity than wild-type kinesin. The rapid quench and stopped-flow results provide evidence that ATP hydrolysis is significantly faster and the precise coordination between the motor domains is disrupted. The data reveal an E164A intermediate that is stalled on the microtubule and cannot bind and hydrolyze ATP at the second head.     

The effect of galactose metabolic disorders on rat brain acetylcholinesterase activity

To evaluate whether in classical galactosemia galactose (Gal), galactose-1-phosphate (Gal-1-P) and galactitol (Galtol) affect brain acetylcholinesterase (AChE) activity, various concentrations (1-16 mM) of these compounds were preincubated with brain homogenates of suckling rats as well as with pure eel Electroforus electricus AChE at 37 degrees C for 1 h. Initially, Galtol (up to 2.0 mM) increased (25%) AChE activity which decreased. thereafter, reaching the control value in high Galtol concentrations. Gal-1-P decreased gradually the enzyme activity reaching a plateau (38%), when incubated with 8-16 mM. However, when the usually found 2 mM of Galtol and 2 mM of Gal-1-P, concentrations in galactosemia were added in the incubation mixture simultaneously, brain AChE was stimulated (16%). Galtol or Gal-1-P modulated brain AChE as well as enzyme activity of E.electricus in the same way. Gal, Glucose (Glu) and glucose-1-phosphate (Glu-1-P) had no effect on AChE activity. It is suggested that Galtol as well as Gal-1-P can affect acetylcholine degradation acting directly on AChE molecule. Consequently the direct action of these substances on the enzyme might explain the brain cholinergic dysfunction in untreated galactosemia patients.     

Role of glutamate 144 and glutamate 164 in the catalytic mechanism of enoyl-CoA hydratase.

The role of two glutamate residues (E164 and E144) in the active site of enoyl-CoA hydratase has been probed by site-directed mutagenesis. The catalytic activity of the E164Q and E144Q mutants has been determined using 3'-dephosphocrotonyl-CoA. Removal of the 3'-phosphate group reduces the affinity of the substrate for the enzyme, thereby facilitating the determination of K(m) and simplifying the analysis of the enzymes' pH dependence. k(cat) for the hydration of 3'-dephosphocrotonyl-CoA is reduced 7700-fold for the E144Q mutant and 630000-fold for the E164Q mutant, while K(m) is unaffected. These results indicate that both glutamate residues play crucial roles in the hydration chemistry catalyzed by the enzyme. Previously, we reported that, in contrast to the wild-type enzyme, the E164Q mutant was unable to exchange the alpha-proton of butyryl-CoA with D(2)O [D'Ordine, R. L., Bahnson, B. J., Tonge, P. J. , and Anderson, V. E. (1994) Biochemistry 33, 14733-14742]. Here we demonstrate that E144Q is also unable to catalyze alpha-proton exchange even though E164, the glutamate that is positioned to abstract the alpha-proton, is intact in the active site. The catalytic function of each residue has been further investigated by exploring the ability of the wild-type and mutant enzymes to eliminate 2-mercaptobenzothiazole from 4-(2-benzothiazole)-4-thiabutanoyl-CoA (BTTB-CoA). As expected, reactivity toward BTTB-CoA is substantially reduced (690-fold) for the E164Q enzyme compared to wild-type. However, E144Q is also less active than wild-type (180-fold) even though elimination of 2-mercaptobenzothiazole (pK(a) 6.8) should require no assistance from an acid catalyst. Clearly, the ability of E164 to function as an acid-base in the active site is affected by mutation of E144 and it is concluded that the two glutamates act in concert to effect catalysis.     

Evolution of enzymatic activities in the orotidine 5'-monophosphate decarboxylase suprafamily: crystallographic evidence for a proton relay system in the active site of 3-keto-L-gulonate 6-phosphate decarboxylase

3-Keto-L-gulonate 6-phosphate decarboxylase (KGPDC), a member of the orotidine monophosphate decarboxylase (OMPDC) suprafamily, catalyzes the Mg(2+)-dependent decarboxylation of 3-keto-L-gulonate 6-phosphate to L-xylulose 5-phosphate. Structural and biochemical evidence suggests that the KGPDC reaction proceeds via a Mg(2+)-stabilized 1,2-cis-enediolate intermediate. Protonation of the enediolate intermediate occurs in a nonstereospecific manner to form L-xylulose 5-phosphate. Although the exact mechanism of proton delivery is not known, Glu112, His136, and Arg139 have been implicated in this process [Yew, W. S., Wise, E., Rayment, I., and Gerlt, J. A. (2004) Biochemistry 43, 6427-6437]. Surprisingly, single amino acid substitutions of these positions do not substantially reduce catalytic activity but rather alter the stereochemical course of the reaction. Here, we report the X-ray crystal structures of four mutants, K64A, H136A, E112Q, and E112Q/H136A, each determined in the presence of L-threonohydroxamate 4-phosphate, an analogue of the enediolate intermediate, to 1.7, 1.9, 1.8, and 1.9 A resolution, respectively. These structures reveal that substitutions of Lys64, Glu112, and His136 cause changes in the positions of the intermediate analogue and two active site water molecules that were previously identified as possible proton donors. These changes correlate with the observed alterations in the reaction stereochemistry for these mutants, thereby supporting a reaction mechanism in which water molecules competitively shuttle protons from the side chains of His136 and Arg139 to alternate faces of the cis-enediolate intermediate. These studies further underscore the wide variation in the reaction mechanisms in the OMPDC suprafamily.     

Persistent binding of MgADP to the E187A mutant of Escherichia coli phosphofructokinase in the absence of allosteric effects

MgADP binding to the allosteric site enhances the affinity of Escherichia coli phosphofructokinase (PFK) for fructose 6-phosphate (Fru-6-P). X-ray crystallographic data indicate that MgADP interacts with the conserved glutamate at position 187 within the allosteric site through an octahedrally coordinated Mg(2+) ion [Shirakihara, Y., and Evans, P. R. (1988) J. Mol. Biol. 204, 973-994]. Lau and Fersht reported that substituting an alanine for this glutamate within the allosteric site of PFK (i.e., mutant E187A) causes MgADP to lose its allosteric effect upon Fru-6-P binding [Lau, F. T.-K., and Fersht, A. R. (1987) Nature 326, 811-812]. However, these authors later reported that MgADP inhibits Fru-6-P binding in the E187A mutant. The inhibition presumably occurs by preferential binding to the inactive (T) state complex of the Monod-Wyman-Changeux two-state model [Lau, F. T.-K., and Fersht, A. R. (1989) Biochemistry 28, 6841-6847]. The present study provides an alternative explanation of the role of MgADP in the E187A mutant. Using enzyme kinetics, steady-state fluorescence emission, and anisotropy, we performed a systematic linkage analysis of the three-ligand interaction between MgADP, Fru-6-P, and MgATP. We found that MgADP at low concentrations did not enhance or inhibit substrate binding. Anisotropy shows that MgADP binding at the allosteric site occurred even when MgADP produced no allosteric effect. However, as in the wild-type enzyme, the binding of MgADP to the active site in the mutant competitively inhibited MgATP binding and noncompetitively inhibited Fru-6-P binding. These results clarified the mechanism of a three-ligand interaction and offered a nontraditional perspective on allosteric mechanism.     

Identification of the zinc ligands in cobalamin-independent methionine synthase (MetE) from Escherichia coli

Cobalamin-independent methionine synthase (MetE) from Escherichia coli catalyzes the transfer of a methyl group from methyltetrahydrofolate to homocysteine to form tetrahydrofolate and methionine. It contains 1 equiv of zinc that is essential for its catalytic activity. Extended X-ray absorption fine structure analysis of the zinc-binding site has suggested tetrahedral coordination with two sulfur (cysteine) and one nitrogen or oxygen ligands provided by the enzyme and an exchangeable oxygen or nitrogen ligand that is replaced by the homocysteine thiol group in the enzyme-substrate complex [González, J. C., Peariso, K., Penner-Hahn, J. E., and Matthews, R. G. (1996) Biochemistry 35, 12228-34]. Sequence alignment of MetE homologues shows that His641, Cys643, and Cys726 are the only conserved residues. We report here the construction, expression, and purification of the His641Gln, Cys643Ser, and Cys726Ser mutants of MetE. Each mutant displays significantly impaired activity and contains less than 1 equiv of zinc upon purification. Furthermore, each mutant binds zinc with lower binding affinity (K(a) approximately 10(14) M(-)(1)) compared to the wild-type enzyme (K(a) > 10(16) M(-)(1)). All the MetE mutants are able to bind homocysteine. X-ray absorption spectroscopy analysis of the zinc-binding sites in the mutants indicates that the four-coordinate zinc site is preserved but that the ligand sets are changed. Our results demonstrate that Cys643 and Cys726 are two of the zinc ligands in MetE from E. coli and suggest that His641 is a third endogenous ligand. The effects of the mutations on the specific activities of the mutant proteins suggest that zinc and homocysteine binding alone are not sufficient for activity; the chemical nature of the ligands is also a determining factor for catalytic activity in agreement with model studies of the alkylation of zinc-thiolate complexes.     

GALT deficiency causes UDP-hexose deficit in human galactosemic cells

Previously we reported that stable transfection of human UDP-glucose pyrophosphorylase (hUGP2) rescued galactose-1-phosphate uridyltransferase (GALT)-deficient yeast from "galactose toxicity." Here we test in human cell lines the hypothesis that galactose toxicity was caused by excess accumulation of galactose-1-phosphate (Gal-1-P), inhibition of hUGP2, and UDP-hexose deficiency. We found that SV40-transformed fibroblasts derived from a galactosemic patient accumulated Gal-1-P from 1.2+/-0.4 to 5.2+/-0.5 mM and stopped growing when transferred from 0.1% glucose to 0.1% galactose. Control fibroblasts accumulated little Gal-1-P and continued to grow. The GALT-deficient cells had 157+/-10 micromoles UDP-glucose/100 g protein and 25+/-5 micromoles UDP-galactose/100 g protein when grown in 0.1% glucose. The control cells had 236+/-25 micromoles UDP- glucose/100 g protein and 82+/-10 micromoles UDP-galactose/100 g protein when grown in identical medium. When we transfected the GALT-deficient cells with either the hUGP2 or GALT gene, their UDP-glucose content increased to 305+/-28 micromoles/100 g protein (hUGP2-transfected) and 210+/-13 micromoles/100 g protein (GALT-transfected), respectively. Similarly, UDP-galactose content increased to 75+/-12 micromoles/100 g protein (hUGP2-transfected) and 55+/-9 micromoles/100 g protein (GALT-transfected), respectively. Though the GALT-transfected cells grew in 0.1% galactose with little accumulation of Gal-1-P (0.2+/-0.02 mM), the hUGP2-transfected cells grew but accumulated some Gal-1-P (3.1+/-0.4 mM). We found that 2.5 mM Gal-1-P increased the apparent KM of purified hUGP2 for glucose-1-phosphate from 19.7 microM to 169 microM, without changes in apparent Vmax. The Ki of the reaction was 0.47 mM. Gal-1-P also inhibited UDP-N-acetylglucosamine pyrophosphorylase, which catalyzes the formation of UDP-N-acetylglucosamine. We conclude that intracellular concentrations of Gal-1-P found in classic galactosemia inhibit UDP-hexose pyrophosphorylases and reduce the intracellular concentrations of UDP-hexoses. Reduced Sambucus nigra agglutinin binding to glycoproteins isolated from cells with increased Gal-1-P is consistent with the resultant inhibition of glycoprotein glycosylation.     

Zinc-dependent structural stability of human Sonic hedgehog.

The role of the zinc site in the N-terminal fragment of human Sonic hedgehog (ShhN) was explored by comparing the biophysical and functional properties of wild-type ShhN with those of mutants in which the zinc-coordinating residues H140, D147, and H182, or E176 which interacts with the metal ion via a bridging water molecule, were mutated to alanine. The wild-type and E176A mutant proteins retained 1 mol of zinc/mol of protein after extensive dialysis, whereas the H140A and D147A mutants retained only 0.03 and 0.05 mol of zinc/mol of protein, respectively. Assay of the wild-type and mutant proteins in two activity assays indicated that the wild-type and E176A mutant proteins had similar activity, whereas the H140A and D147A mutants were significantly less active. These assays also indicated that the H140A and D147A mutants were susceptible to proteolysis. CD, fluorescence, and (1)H NMR spectra of the H140A, D147A, and E176A mutants measured at 20 or 25 degrees C were very similar to those observed for wild-type ShhN. However, CD measurements at 37 degrees C showed evidence of some structural differences in the H140A and D147A mutants. Guanidine hydrochloride (GuHCl) denaturation studies revealed that the loss of zinc from the H140A and D147A mutants destabilized the folded proteins by approximately 3.5 kcal/mol, comparable to the effect of removing zinc from wild-type ShhN by treatment with EDTA. Thermal melting curves of wild-type ShhN gave a single unfolding transition with a midpoint T(m) of approximately 59 degrees C, whereas both the H140A and D147A mutants displayed two distinct transitions with T(m) values of 37-38 and 52-54 degrees C, similar to that observed for EDTA-treated wild-type ShhN. Addition of zinc to the H140A and D147A mutants resulted in a partial restoration of stability against thermal and GuHCl denaturation. The ability of these mutants to bind zinc was confirmed using a fluorescence-based binding assay that indicated that they bound zinc with K(d) values of approximately 1.6 and approximately 15 nM, respectively, as compared to a value of 相似文献   

MgATP-dependent activation by phosphoenolpyruvate of the E187A mutant of Escherichia coli phosphofructokinase

Using enzymatic assays and steady-state fluorescence emission, we performed a linkage analysis of the three-ligand interaction of fructose 6-phosphate (Fru-6-P), phosphoenolpyruvate (PEP), and MgATP on E187A mutant Escherichia coli phosphofructokinase (PFK). PEP allosterically inhibits Fru-6-P binding to E. coli PFK. The magnitude of antagonism is 90-fold in the absence and 60-fold in the presence of a saturating concentration of MgATP [Johnson, J. J., and Reinhart, G. D. (1997) Biochemistry 36, 12814-12822]. Substituting an alanine for the glutamate at position 187, located in the allosteric site (i.e., mutant E187A), activates Fru-6-P binding and inhibits the maximal rate of enzyme turnover [Lau, F. T.-K., and Fersht, A. R. (1987) Nature 326, 811-812]. The allosteric action of PEP appears to depend on the presence of the cosubstrate MgATP. In the presence of a saturating concentration of MgATP, PEP enhances the binding of Fru-6-P to the enzyme by a modest 2-fold. Decreasing the concentration of MgATP mitigates the extent of activation. At MgATP concentrations approaching 25 microM, PEP becomes insensitive to the binding of Fru-6-P. At MgATP concentrations < 25 microM, PEP "crosses over" and becomes antagonistic toward substrate binding. The present study examines the role of Glu 187 at the allosteric site in the binding of Fru-6-P and offers a more complex explanation of the mechanism than that described by traditional allosteric mechanistic models.