Studies of the catalytic mechanism of microsomal UDP-glucuronyltransferase. Alpha-glucuronidase activity and its stimulation by phospholipids

The rate at which a specific, purified form of microsomal UDP-glucuronyltransferase (designated as the GT2P type of this enzyme) catalyzes the hydrolysis of UDP-glucuronic acid was measured with pure, delipidated enzyme and enzyme reconstituted with different lysophosphatidylcholines. This activity of the GT2P type of UDP-glucuronyltransferase is referred to as alpha-glucuronidase activity. For delipidated enzyme, the rate of hydrolysis of UDP-glucuronic acid catalyzed by GT2P extrapolated to infinite concentrations of UDP-glucuronic acid was 1 X 10(-9) mol/min/mg of protein. This compares with a rate of glucuronidation of p-nitrophenol of 96 X 10(-9) mol/min/mg of enzyme, for delipidated enzyme. Addition of oleoyl- or myristoyllysophosphatidylcholine to GT2P did not affect the alpha-glucuronidase activity significantly. This activity was stimulated, however, in the presence of compounds that bind at the aglycone site but that do not undergo glucuronidation. alpha-Glucuronidase activity extrapolated to infinite concentration of UDP-glucuronic acid was 4.0 X 10(-9) mol/min/mg for delipidated enzyme assayed in the presence of less than saturating concentrations of p-nitrophenyl phenyl ether. Moreover, when the aglycone site of GT2P was occupied by ethers, the alpha-glucuronidase activity of this enzyme was enhanced by addition of phospholipids to delipidated enzyme. The extent of activation of the alpha-glucuronidase activity of GT2P, when the aglycone site was occupied, depended on the acyl chain of the lipid added to delipidated enzyme. These data indicate that the GT2P form of UDP-glucuronyltransferase catalyzes the hydrolysis of UDP-glucuronic acid at a significant rate and that lysophosphatidylcholines can influence this rate.     

The donor substrate specificity of the human beta 1,3-glucuronosyltransferase I toward UDP-glucuronic acid is determined by two crucial histidine and arginine residues

The human beta1,3-glucuronosyltransferase I (GlcAT-I) plays a key role in proteoglycan biosynthesis by catalyzing the transfer of glucuronic acid onto the trisaccharide-protein linkage structure Galbeta1,3Galbeta1,4Xylbeta-O-Ser, a prerequisite step for polymerization of glycosaminoglycan chains. In this study, we identified His(308) and Arg(277) residues as essential determinants for the donor substrate (UDP-glucuronic acid) selectivity of the human GlcAT-I. Analysis of the UDP-glucuronic acid-binding site by computational modeling in conjunction with site-directed mutagenesis indicated that both residues interact with glucuronic acid. Substitution of His(308) by arginine induced major changes in the donor substrate specificity of GlcAT-I. Interestingly, the H308R mutant was able to efficiently utilize nucleotide sugars UDP-glucose, UDP-mannose, and UDP-N-acetylglucosamine, which are not naturally accepted by the wild-type enzyme, as co-substrate in the transfer reaction. To gain insight into the role of Arg(277), site-directed mutagenesis in combination with chemical modification was carried out. Substitution of Arg(277) with alanine abrogated the activity of GlcAT-I. Furthermore, the arginine-directed reagent 2,3-butanedione irreversibly inhibited GlcAT-I, which was effectively protected against inactivation by UDP-glucuronic acid but not by UDP-glucose. It is noteworthy that the activity of the H308R mutant toward UDP-glucose was unaffected by the arginine-directed reagent. Our results are consistent with crucial interactions between the His(308) and Arg(277) residues and the glucuronic acid moiety that governs the specificity of GlcAT-I toward the nucleotide sugar donor substrate.     

6-Amino-chrysene, a potent inhibitor of transferase activity in single living RTG2 cells

Previous reports on the inhibitory effect of 6-amino-chrysene (6AC) on benzo(a)pyrene (BP) metabolism using single living cells have suggested that aryl hydrocarbon hydroxylase (AHH) is not the only pathway for 6AC metabolism. We present here results demonstrating that direct glucuronidation may constitute an alternative pathway for 6AC elimination. First, we describe the conjugate of 6AC to UDP-glucuronic acid (UDPGA) in solution. We performed competition experiments between 6AC and monohydroxy BP, which are known to be good substrates for glucuronic transferase (GT), in RTG2 cells, using microspectrofluorimetry. Because of intracellular accumulation of fluorescent metabolites during BP metabolism, RTG2 cells can be used as a tool for simultaneous study of AHH and GT activities. When RTG2 cells have been simultaneously treated with BP and 6AC, GT appeared to be a more specific target for 6AC than AHH in these cells. Therefore, 6AC can be expected to act as a more specific inhibitor for GT than for AHH activity.     

Crystal structure of the cofactor-binding domain of the human phase II drug-metabolism enzyme UDP-glucuronosyltransferase 2B7

Human UDP-glucuronosyltransferases (UGT) are the dominant phase II conjugative drug metabolism enzymes that also play a central role in processing a range of endobiotic compounds. UGTs catalyze the covalent addition of glucuronic acid sugar moieties to a host of therapeutics and environmental toxins, as well as to a variety of endogenous steroids and other signaling molecules. We report the 1.8-A resolution apo crystal structure of the UDP-glucuronic acid binding domain of human UGT isoform 2B7 (UGT2B7), which catalyzes the conjugative elimination of opioid, antiviral, and anticancer drugs. This is the first crystal structure of any region of a mammalian UGT drug metabolism enzyme. Designated UGT2B7 mutants at residues predicted to interact with the UDP-glucuronic acid cofactor exhibited significantly impaired catalytic activity, with maximum effects observed for amino acids closest to the glucuronic acid sugar transferred to the acceptor molecule. Homology modeling of UGT2B7 with related plant flavonoid glucosyltransferases indicates human UGTs share a common catalytic mechanism. Point mutations at predicted catalytic residues in UGT2B7 abrogated activity, strongly suggesting human UGTs also utilize a serine hydrolase-like catalytic mechanism to facilitate glucuronic acid transfer.     

Backbone assignment of the apo-form of the human C-terminal domain of UDP-glucuronosyltransferase 1A (UGT1A)

A major component of phase II drug metabolism is the covalent addition of glucuronic acid to metabolites and xenobiotics. This activity is carried out by UDP-glucuronosyltransferases (UGT) which bind the UDP-glucuronic acid donor and catalyze the covalent addition of glucuronic acid sugar moieties onto a wide variety of substrates. UGTs play important roles in drug detoxification and were recently shown to act in an inducible form of multi-drug resistance in cancer patients. Despite their biological importance, structural understanding of these enzymes is limited. The C-terminal domain is identical for all UGT1A family members and required for binding to UDP-glucuronic acid as well as involved in contacts with substrates. Here, we report the backbone assignments for the C-terminal domain of UGT1A. These assignments are a critical tool for the development of a deeper biochemical understanding of substrate specificity and enzymatic activity.     

Analysis of the streptococcal hyaluronic acid synthase complex using the photoaffinity probe 5-azido-UDP-glucuronic acid.

The mucopolysaccharide, hyaluronic acid, is an important component of both mammals and pathogenic streptococci. This high molecular weight polymer is synthesized by a membrane-associated, multisubunit hyaluronate synthase which utilizes UDP-glucuronic acid and UDP-N-acetylglucosamine as substrates. Using the photoaffinity probe, [beta-32P]5-azido-UDP-glucuronic acid, three streptococcal membrane proteins (42, 33, and 27 kDa) specifically photoincorporated this probe. Labeling of these proteins was enhanced in the presence of UDP-N-acetylglucosamine, whereas UDP-galactose or UDP-glucose had no effect on incorporation. UDP-glucuronic acid inhibited the labeling of the three proteins in a dose-dependent manner. Detergent-solubilized membrane proteins from transposon-inactivated hyaluronic acid capsule mutants no longer incorporated the probe. This was also the case when membranes from stationary phase organisms were tested. Finally, glucuronic acid no longer was incorporated into high molecular weight hyaluronic acid with either the mutant or stationary phase preparations. Further biochemical analysis will be required to demonstrate the exact role each of the proteins play in hyaluronic acid biosynthesis.     

Bilirubin glucuronyltransferase. Specific assay and kinetic studies

1. Bilirubin glucuronide was synthesized in vitro in a system containing a rat liver microsomal fraction, UDP-glucuronic acid, Mg(2+) and bilirubin. The enzymic synthesis was accomplished without the addition of a bilirubin carrier. 2. Azobilirubin and azobilirubin glucuronide were separated by t.l.c. and paper chromatography and the measurement of the conjugate provided a specific assay for bilirubin UDP-glucuronyltransferase (EC 2.4.1.17). 3. This diazo compound was labelled when [U-(14)C]UDP-glucuronic acid was employed in the transglucuronidation reaction. 4. Identity of the glucuronide nature of the product was further confirmed by hydrolysis with beta-glucuronidase prepared from limpets and Helix pomatia. In each instance azobilirubin and glucuronic acid were liberated. 5. There was a close correlation between the bilirubin glucuronyl-transferase activity as measured by two procedures, colorimetric and radioisotopic. The specific activities so measured were 19nmol of bilirubin ;equivalents' conjugated/h per mg of protein and 16.9-18.4nmol of UDP-glucuronic acid incorporated/h per mg of protein, respectively. On this basis, it was concluded that the major product formed in vitro was bilirubin monoglucuronide; this represents about 77% of the total products formed. 6. The K(m) values for bilirubin and UDP-glucuronic acid at pH8.2 are 3.3x10(-4)m and 1.67x10(-3)m, respectively. 7. The addition of Mg(2+) at a final concentration of 5mm to the reaction mixture increased the rate of conjugation by 5.6-fold in the microsomal preparation that had been subjected to overnight dialysis against 10mm-EDTA (disodium salt). 8. Diethyl-nitrosamine at a final concentration of 1-20mm has no effect on the glucuronidation of bilirubin in vitro.     

Analysis of cell-growth-phase-related variations in hyaluronate synthase activity of isolated plasma-membrane fractions of cultured human skin fibroblasts.

Hyaluronate synthase activity is localized exclusively in plasma-membrane fractions of cultured human skin fibroblasts. The enzyme activity of plasma membranes prepared from exponential-growth-phase cells was about 6.5 times that of stationary-growth-phase cells. Hyaluronate synthase from exponential-growth-phase cells exhibited lower Km and higher Vmax. values for both UDP-N-acetylglucosamine and UDP-glucuronic acid and higher rate of elongation of hyaluronate chains compared with the enzyme from stationary-growth-phase cells. Hyaluronate synthase exhibited an extremely short half-life, 2.2 h and 3.8 h respectively when cells were treated with cycloheximide and actinomycin D. The cell-growth-phase-dependent variations in hyaluronate synthase activity appear to be due to its high turnover rate as well as due to some post-translational modification of the enzyme protein as cells progress from early exponential to stationary growth phase. The isolated plasma membranes contained a protein (Mr approx. 450,000) that was selectively autophosphorylated from [gamma-32P]ATP in vitro in the presence of hyaluronate precursors in the reaction mixture and that also exhibited some hyaluronate-synthesis-related properties. The 32P-labelled protein isolated from plasma membranes of exponentially growing cells expressed an efficient UDP-[14C]glucuronic acid- and UDP-N-acetyl[3H]glucosamine-binding activity and was able to synthesize oligosaccharides (Mr 5000) of [14C]glucuronic acid and N-acetyl[3H]glucosamine residues. The corresponding protein of stationary-growth-phase cells, which expressed much higher nucleotide-sugar-precursor-binding activity, appeared to have lost its oligosaccharide-synthesizing activity.     

Essential arginine residues of creatine kinase from beef heart mitochondria

Creatine kinase from beef heart mitochondria is inactivated by 2,3-butanedione. The kinetics of inactivation of the mitochondrial enzyme is biphasic with a bend at a point corresponding to 50% inactivation. The inactivation rate constants of the first fast and the second slow phases of the reaction differ by one order of magnitude, thus suggesting the existence of two types of arginine residues, i.e. "fast" and "slow" ones, with different reactivities. The inactivation rate constant of the slow phase is very close to that for cytoplasmic creatine kinase. At saturating concentrations MgATP and MgADP afford complete protection of the slow phase of inactivation. It is assumed that the "slow" arginine is involved in the binding of metal-nucleotide substrates in the enzyme active center.     

A novel glucuronyltransferase in nervous system presumably associated with the biosynthesis of HNK-1 carbohydrate epitope on glycoproteins.

Recently, embryonic chicken brain extract was shown to contain a glucuronyltransferase, which transfers glucuronic acid from UDP-glucuronic acid to glycolipid acceptors (neolactotetraosyl ceramide). The enzyme was also suggested to transfer glucuronic acid to glycoprotein acceptors (asialoorosomucoid) (Das, K. K., Basu, M., Basu, S., Chou, D. K. H., and Jungalwala, F. B. (1991) J. Biol. Chem. 266, 5238-5243). In this study, the glucuronyltransferase activity in rat brain extract was separated into two groups by UDP-glucuronic acid-Sepharose CL-6B column chromatography. The enzyme recovered predominantly in the effluent fraction (GlcAT-L) catalyzed the transfer of glucuronic acid to glycolipid acceptors but not to glycoprotein acceptors, whereas the enzyme recovered in the eluate fraction (GlcAT-P) transferred glucuronic acid most predominantly to glycoprotein acceptors and very little to glycolipid acceptors. GlcAT-P was able to transfer glucuronic acid to oligosaccharide chains on asialoorosomucoid. The enzyme recognized a terminal lactosamine structure, Gal beta 1-4GlcNAc, on glycoproteins. It was localized in the nervous system and was hardly detectable in other tissues, including the thymus, spleen, lung, kidney, and liver. Although GlcAT-L and GlcAT-P shared some properties in common such as tissue distributions and developmental changes, they exhibited marked differences in their phospholipid dependence and in their pH profiles, apart from their respective acceptor preference to glycolipids and glycoproteins. The acceptor specificity and tissue distribution suggest that a novel glucuronyltransferase, GlcAT-P, is involved in the biosynthesis of the sulfoglucuronylgalactose structure in the HNK-1 carbohydrate epitope that is expressed on glycoproteins.     

Uridine diphosphate glucose dehydrogenase from cornea and epiphysial-plate cartilage

1. UDP-glucose dehydrogenase (EC 1.1.1.22) was extracted from epiphysial-plate cartilage of newborn pigs and from whole bovine corneas. 2. Formation of UDP-glucuronic acid was demonstrated by radioautography after separation of the sugar nucleotides by paper chromatography or t.l.c.: in these conditions a radioactive glucuronic acid spot also appears. 3. UDP-xylose prevented the formation in the incubation mixture of both UDP-glucuronic acid and free glucuronic acid. 4. In both tissues the dependence of the enzyme activity on pH and the K(m) values for UDP-glucose and NAD(+) were determined. 5. Inhibition by UDP-xylose with respect to UDP-glucose was investigated. The plots of 1/v versus 1/[UDP-glucose], and of percentage inhibition versus UDP-xylose concentration and the Hill coefficient showed that a co-operative effect existed between UDP-xylose-binding sites. 6. The physiological meaning of the different affinities of cartilage and cornea enzymes for UDP-xylose is discussed and related to the different glycosaminoglycan contents of the two connective tissues studied.     

Detection of essential arginine in bacterial peptidyl dipeptidase-4: arginine is not the anion binding site

Peptidyl dipeptidase-4 from Pseudomonas maltophilia was modified with the arginine reagents p-hydroxyphenylglyoxal and 2,3-butanedione. The enzyme was inactivated in a pseudo-first-order manner by p-hydroxyphenylglyoxal with a half-time of 72 min. Inactivation by 2,3-butanedione was biphasic with a rapid phase followed by a slower inactivation to less than 10% activity within 24h. The competitive inhibitor thiorphan protected against inactivation by phydroxyphenylglyoxal and by 2,3-butanedione also but to a lesser degree. Inhibitory anions chloride and phosphate did not protect against inactivation by either reagent. These data support the conclusion that an active site arginine is essential for substrate hydrolysis. Furthermore, arginine is not the binding site for the inhibitors chloride and phosphate.     

The formation of glucosides of isoflavones and of some other phenols by rabbit liver microsomal fractions

1. Rabbit liver microsomal fractions in vitro effected the transfer of glucuronic acid from UDP-glucuronic acid to biochanin A, formononetin, daidzein, genistein and equol. Only monoglucuronides were formed. 2. The same isoflavones were converted into monoglucosides when UDP-[6-(3)H]glucose was substituted for UDP-glucuronic acid in the incubation medium in vitro. The glucosides were formed in much lesser yield than were the glucuronides. 3. The glucoside of genistein was identified as genistin (genistein 7-glucoside) by Sephadex chromatography and reverse isotope dilution. 4. The specificity of the glucuronyl- and glucosyl-transfer mechanisms was compared for a series of steroids and other phenols in addition to the isoflavones. It was concluded that separate transferases were responsible for the formation of the two types of glycosides.     

Inactivation of N-type calcium current in chick sensory neurons: calcium and voltage dependence

We have studied the inactivation of high-voltage-activated (HVA), omega- conotoxin-sensitive, N-type Ca2+ current in embryonic chick dorsal root ganglion (DRG) neurons. Voltage steps from -80 to 0 mV produced inward Ca2+ currents that inactivated in a biphasic manner and were fit well with the sum of two exponentials (with time constants of approximately 100 ms and > 1 s). As reported previously, upon depolarization of the holding potential to -40 mV, N current amplitude was significantly reduced and the rapid phase of inactivation all but eliminated (Nowycky, M. C., A. P. Fox, and R. W. Tsien. 1985. Nature. 316:440-443; Fox, A. P., M. C. Nowycky, and R. W. Tsien. 1987a. Journal of Physiology. 394:149-172; Swandulla, D., and C. M. Armstrong. 1988. Journal of General Physiology. 92:197-218; Plummer, M. R., D. E. Logothetis, and P. Hess. 1989. Neuron. 2:1453-1463; Regan, L. J., D. W. Sah, and B. P. Bean. 1991. Neuron. 6:269-280; Cox, D. H., and K. Dunlap. 1992. Journal of Neuroscience. 12:906-914). Such kinetic properties might be explained by a model in which N channels inactivate by both fast and slow voltage-dependent processes. Alternatively, kinetic models of Ca-dependent inactivation suggest that the biphasic kinetics and holding-potential-dependence of N current inactivation could be due to a combination of Ca-dependent and slow voltage- dependent inactivation mechanisms. To distinguish between these possibilities we have performed several experiments to test for the presence of Ca-dependent inactivation. Three lines of evidence suggest that N channels inactivate in a Ca-dependent manner. (a) The total extent of inactivation increased 50%, and the ratio of rapid to slow inactivation increased approximately twofold when the concentration of the Ca2+ buffer, EGTA, in the patch pipette was reduced from 10 to 0.1 mM. (b) With low intracellular EGTA concentrations (0.1 mM), the ratio of rapid to slow inactivation was additionally increased when the extracellular Ca2+ concentration was raised from 0.5 to 5 mM. (c) Substituting Na+ for Ca2+ as the permeant ion eliminated the rapid phase of inactivation. Other results do not support the notion of current-dependent inactivation, however. Although high intracellular EGTA (10 mM) or BAPTA (5 mM) concentrations suppressed the rapid phase inactivation, they did not eliminate it. Increasing the extracellular Ca2+ from 0.5 to 5 mM had little effect on this residual fast inactivation, indicating that it is not appreciably sensitive to Ca2+ influx under these conditions.(ABSTRACT TRUNCATED AT 400 WORDS)     

Degradation of uric acid during autocatalytic oxidation of oxyhemoglobin induced by sodium nitrite.

The oxidation of oxyhemoglobin produced by sodium nitrite occurs in two stages: 1) an initial slow phase followed by 2) a rapid autocatalytic phase that carries the reaction to completion. The length of the slow phase is extended when uric acid is added to the reaction mixture. As the concentration of uric acid increases, the length of the slow phase increases until a concentration is reached at which the rate of methemoglobin formation is nearly linear until the reaction is complete. Further increases in the concentration of uric acid do not affect the rate of the reaction in the slow phase. At low concentrations of uric acid, where an autocatalytic phase is reached, uric acid is degraded during the reaction. At concentrations of uric acid that keep the reaction in the linear phase, the uric acid is not degraded. It is concluded that uric acid may protect oxyhemoglobin by reacting with HbO2H to yield [HbOH]+ and the urate radical. The urate radical may react with a second molecule of HbO2H and become oxidized. At higher concentrations, the radical may undergo electron transfer with oxyhemoglobin to regenerate the uric acid and form methemoglobin.     

Functional Differentiation of the Glycosyltransferases That Contribute to the Chemical Diversity of Bioactive Flavonol Glycosides in Grapevines (Vitis vinifera)

We identified two glycosyltransferases that contribute to the structural diversification of flavonol glycosides in grapevine (Vitis vinifera): glycosyltransferase 5 (Vv GT5) and Vv GT6. Biochemical analyses showed that Vv GT5 is a UDP-glucuronic acid:flavonol-3-O-glucuronosyltransferase (GAT), and Vv GT6 is a bifunctional UDP-glucose/UDP-galactose:flavonol-3-O-glucosyltransferase/galactosyltransferase. The Vv GT5 and Vv GT6 genes have very high sequence similarity (91%) and are located in tandem on chromosome 11, suggesting that one of these genes arose from the other by gene duplication. Both of these enzymes were expressed in accordance with flavonol synthase gene expression and flavonoid distribution patterns in this plant, corroborating their significance in flavonol glycoside biosynthesis. The determinant of the specificity of Vv GT5 for UDP-glucuronic acid was found to be Arg-140, which corresponded to none of the determinants previously identified for other plant GATs in primary structures, providing another example of convergent evolution of plant GAT. We also analyzed the determinants of the sugar donor specificity of Vv GT6. Gln-373 and Pro-19 were found to play important roles in the bifunctional specificity of the enzyme. The results presented here suggest that the sugar donor specificities of these Vv GTs could be determined by a limited number of amino acid substitutions in the primary structures of protein duplicates, illustrating the plasticity of plant glycosyltransferases in acquiring new sugar donor specificities.     

Alcohol-induced biphasic inhibition of myosin subfragment 1 K-EDTA-ATPase

Butanol-induced inhibition of K-EDTA-ATPase of myosin subfragment 1 proceeded by biphasic kinetics, consisting of rapid and slow inactivations. The extent of the rapid inactivation, which was estimated by extrapolating the process of slow inactivation to zero time of the incubation period, was saturated with butanol concentration. Recovery of activity by dilution in the rapid phase indicates that the rapid process is reversible. The slow inactivation was concomitant with a partial denaturation of the 50 kDa domain of S1, which was detected by limited tryptic digestion. Other alcohols (methanol, ethanol, propanol and hexanol) also inhibited the K-EDTA-ATPase in the rapid phase. The Ki decreased with an increase in the number of methylene groups of alcohol. When K-EDTA-ATPase activity in the rapid phase was plotted against viscosity, surface tension or dielectric constant, the curves were different for each of the various alcohol solutions. The rapid inactivation appears to be caused by a binding of the alkyl group to S1, rather than by solvent effects. The kinetics of rapid butanol inhibitions indicate that butanol reduces the maximum activity of ATPase but enhances an apparent affinity of S1 with ATP. These indications suggest that alcohol stabilizes S1.KATP intermediate. The rapid K-EDTA-ATPase inhibition was observed at the same alcohol concentration where S1 Mg-ATPase was activated.     

The reaction of choline acetyltransferase with sulfhydryl reagents. Methoxycarbonyl-CoA disulfide as an active site-directed reagent.

The reaction of choline acetyltransferase with methoxycarbonyl alkyl disulfides leads to a progressive loss in enzyme activity as the size of the alkyl group increases from methyl to n-butyl. Reaction with 5,5'-dithiobis(2-nitrobenzoic acid) (DTNB) or methoxycarbonyl coenzyme A (CoA) disulfide, leads to a total loss of enzyme activity. DTNB inactivation is biphasic (k1 = approximately 9 x 10(2) M-1 s-1, k2 = approximately 6 x 10(1) M-1 s-1) with the slow phase being diminished by acetyl-CoA. Methoxycarbonyl-CoA disulfide inactivation is also biphasic (k1 = approximately 2.1 x 10(3) M-1 s-1, k2 = approximately 6 x 10(1) M-1 s-1), with the rapid phase being diminished in the presence of acetyl-CoA. Inactivation by methoxycarbonyl methyl disulfide, ethyl disulfide, or hydroxyethyl disulfide, or by methyl methanethiosulfonate is not biphasic. Pretreatment of the enzyme with methyl methanethiosulfonate, which leads to a 25% loss in enzyme activity, abolishes the fast phase of DTNB inactivation, the slow phase of methoxycarbonyl-CoA disulfide inactivation, and any further inactivation by methoxycarbonyl ethyl disulfide. These results are interpreted to suggest that choline acetyltransferase contains two classes of reactive sulfhydryl groups, neither of which are required for enzyme activity.     

Reconstitution into proteoliposomes and partial purification of the Golgi apparatus membrane UDP-galactose, UDP-xylose, and UDP-glucuronic acid transport activities.

Previous studies in vitro on proteoglycan biosynthesis from our laboratory have shown that nucleotide sugar precursors of all the sugars of the linkage oligosaccharides (xylose, galactose, and glucuronic acid) and of the glycosaminoglycans (N-acetylglucosamine, N-galactosamine, and glucuronic acid) are transported by specific carriers into the lumen of Golgi vesicles. More recently, we also reported the reconstitution in phosphatidylcholine liposomes of detergent-solubilized Golgi membrane proteins containing transport activities of CMP-sialic acid and adenosine-3'-phosphate-5'-phosphosulfate. We have now completed the successful reconstitution into liposomes of the Golgi membrane transport activities of UDP-galactose, UDP-xylose, and UDP-glucuronic acid. Transport of these nucleotide sugars into Golgi protein proteoliposomes occurred with the same affinity, temperature dependence, and sensitivity to inhibitors as observed with intact Golgi vesicles. Preloading of proteoliposomes with UMP, the putative antiporter for Golgi vesicle transport of these nucleotide sugars, stimulated transport of the nucleotide sugars by 2-3-fold. Transport of UDP-xylose into Golgi protein proteoliposomes was dependent on the presence of endogenous Golgi membrane lipids while that of UDP-galactose and UDP-glucuronic acid was not. This suggests a possible stabilizing or regulatory role for Golgi lipids on the UDP-xylose translocator. Finally, we have also shown that detergent-solubilized Golgi membrane translocator proteins can be partially purified by an ion-exchange chromatographic step before successful reconstitution into liposomes, demonstrating that this reconstitution approach can be used for the biochemical purification of these transporters.     

Structural changes in (Na+ + K+)-ATPase accompanying detergent inactivation

Structural changes in the purified (Na+ + K+)-ATPase accompanying detergent inactivation were investigated by monitoring changes in light scattering, intrinsic protein fluorescence, and tryptophan to beta-parinaric acid fluorescence resonance energy transfer. Two phases of inactivation were observed using the non-ionic detergents, digitonin, Lubrol WX and Triton X-100. The rapid phase involves detergent monomer insertion but little change in protein structure or little displacement of closely associated lipids as judged by intrinsic protein fluorescence and fluorescence resonance energy transfer. Lubrol WX and Triton X-100 also caused membrane fragmentation during the rapid phase. The slower phase of inactivation results in a completely inactive enzyme in a particle of 400 000 daltons with 20 mol/mol of associated phospholipid. Fluorescence changes during the course of the slow phase indicate some dissociation of protein-associated lipids and an accompanying protein conformational change. It is concluded that non-parallel inhibition of (Na+ + K+)-ATPase and p-nitrophenylphosphate activity by digitonin (which occurs during the rapid phase of inactivation) is unlikey to require a change in the oligomeric state of the enzyme. It is also concluded that at least 20 mol/mol of tightly associated lipid are necessary for either (Na+ + K+)-ATPase or p-nitrophenylphosphatase activity and that the rate-limiting step in the slow inactivation phase involves dissociation of an essential lipid.