Regulation by Lipids of Plant Microsomal Enzymes: III. Phospholipid Dependence of the Cytidine-Diphospho-Choline Phosphotransferase of Potato Microsomes

Cytidine-diphospho-choline diacyl-glycerol phosphorylcholine phosphotransferase activity was demonstrated in potato (Solanum tuberosum L.) microsomes and the incorporation of cytidine-diphospho[¹⁴C]choline into phosphatidylcholine was characterized by the time course of ¹⁴C incorporation and the effect of microsomal protein concentration on choline incorporation.

Potato microsomes were progressively delipidated by treatments (2 min at 0°C) with increasing amounts of phospholipase C from Bacillus cereus. A decrease in choline phosphotransferase activity was observed in parallel with the progressive hydrolysis of membrane phospholipids. A 70% (or more) phospholipid hydrolysis provoked the total inactivation of the enzyme.

Adding back exogenous phospholipids (in the form of liposomes) to phospholipase C-treated membranes restored the enzymic activity. Restoration could be obtained with egg yolk phospholipids as well as with potato phospholipids. Restoration was time dependent and completed after 10 minutes; restoration was also dependent on the quantity of liposomes added to lipid-depleted membranes: the best restorations were obtained with 1 to 2.5 milligrams of phospholipid per mg of microsomal protein; higher phospholipid to protein ratios were less efficient or inhibitory.

These results clearly demonstrate the phospholipid dependence of the cytidine-diphospho-choline phosphotransferase from potato microsomes.

     

A phospholipid requirement for dolichol pyrophosphate N-acetylglucosamine synthesis in phospholipase A2-treated rat lung microsomes

The role of phospholipids in the activity of UDP-Glc-NAc:dolichol phosphate GlcNAc-1-phosphate transferase of rat lung microsomes has been investigated. Treatment of microsomes with phospholipase A2 in the presence of delipidated bovine serum albumin resulted in a time-dependent loss of 65 to 75% of the enzyme activity and approximately 30% of the phospholipids. Addition of phosphatidylglycerol to the enzyme assay system containing phospholipase A2-treated microsomes restored activity to that obtained with native microsomes and phosphatidylglycerol. Addition of phosphatidylinositol, phosphatidylcholine, or cardiolipin resulted in only partial restoration of activity, whereas phosphatidylserine and phosphatidylethanolamine were without effect. Triton X-100 was not by itself capable of restoring activity, but was required for the phospholipid effect. Measurements of the phospholipase A2 hydrolysis products released from the microsomes during digestion, and other control experiments of adding fatty acids and lysophospholipids to the enzyme assay system, indicated that the loss of UDP-GlcNAc:dolichol phosphate GlcNAc-1-phosphate transferase activity was not due to product inhibition.     

Studies on the interactions between phospholipids and membrane-bound enzymes in microsomes. Effects of phospholipases C on the glucose-6-phosphatase system of rat liver microsomes

The role of phospholipids in the glucose-6-phosphatase system, including glucose-6-P phosphohydrolase and glucose-6-P translocase, was studied in rat liver microsomes by using phospholipases C and detergents. In the time course experiments on detergent exposure, the maximal activation of glucose-6-P phosphohydrolase varied according to the nature of the detergent used. On treatment of microsomes with phospholipase C of C. perfringens, the activity of glucose-6-P phosphohydrolase without detergent (i.e. without rupture of translocase activity) was gradually decreased with the progressive hydrolysis of phosphatidylcholine and phosphatidylethanolamine on the microsomal membrane, and was restored by incubation of these microsomes with egg yolk phospholipids. The extent of decrease in this phosphohydrolase activity in the detergent-exposed microsomes (with rupture of translocase activity) also varied depending on the detergent used (Triton X-114 or taurocholate). When 66% of the phosphatidylinositol on the membrane was hydrolyzed by phosphatidylinositol-specific phospholipase C of B. thuringiensis, the inhibition of glucose-6-P phosphohydrolase activity without detergent was very small. Although the inhibition of enzyme activity with detergent was apparently greater than that without detergent, the enzyme activity was stimulated by the breakdown of phosphatidylinositol when the enzyme activity was measured at lower concentration (0.5 mM) of substrate, glucose-6-P. The latency of mannose-6-P phosphohydrolase, a plausible index of microsomal integrity, remained above 70% after the hydrolysis of phosphatidylcholine, phosphatidylethanolamine, or phosphatidylinositol. The results show that the glucose-6-phosphatase system requires microsomal phospholipids for its integrity, suggesting that there exists a close relation between phosphatidylinositol and glucose-6-P translocase.     

Phospholipid requirement of the vanadate-sensitive ATPase from maize roots evaluated by two methods

The activation of the vanadate-sensitive ATPase from maize (Zea mays L.) root microsomes by phospholipids was assessed by two different methods. First, the vanadate-sensitive ATPase was partially purified and substantially delipidated by treating microsomes with 0.6% deoxycholate (DOC) at a protein concentration of 1 milligram per milliliter. Vanadate-sensitive ATP hydrolysis by the DOC-extracted microsomes was stimulated up to 100% by the addition of asolectin. Of the individual phospholipids tested, phosphatidylserine and phosphatidylglycerol stimulated activity as much as asolectin, whereas phosphatidylcholine did not. Second, phospholipid dependence of the ATPase was also assessed by reconstituting the enzyme into proteoliposomes of differing phospholipid composition. In these experiments, the rate of proton transport and ATP hydrolysis was only slightly affected by phospholipid composition. DOC-extracted microsomes reconstituted with dioleoylphosphatidylcholine had rates of proton transport similar to those found with microsomes reconstituted with asolectin. The difference between the two types of assays is discussed in terms of factors contributing to the interaction between proteins and lipids.     

Use of protein-mediated lipid exchange in the study of membrane-bound enzymes. The lipid dependence of glucose-6-phosphatase.

The ability of liver lipid-exchange proteins to introduce foreign phospholipids into microsomes was used in a study of the lipid dependence of glucose-6-phosphatase. Supplementation of intact rat liver and hepatoma microsomes with exogeneous aminophospholipids prevents the decline of glucose-6-phosphatase activity during incubation, whereas the introduction of exogeneous phosphatidylcholine has no protective effect. On the contrary with deoxycholate-disrupted hepatoma microsomes, introduction of additional phosphatidylcholine causes activation while phosphatidylethanolamine has only little effect. The results are explained by assuming that the transport unit and the catalytic moiety of the glucose-6-phosphatase system have different lipid requirements, the activity of the former protein depending mainly on phosphatidylethanolamine and phosphatidylserine and that of the catalytic protein depending on phosphatidylcholine. In deoxycholate-disrupted liver microsomes (in which both the glucose-6-phosphatase activity and the phosphatidylcholine content are much higher than in hepatoma microsomes) incubation with phosphatidylcholine and lipid-exchange proteins alters neither the phospholipid composition nor the enzyme activity. THis suggests that the diminished activity of glucose-6-phosphatase in hepatomas may be partly due to a low level of phosphatidylcholine.     

Lipid dependence of the pyrophosphatase activity of microsomes from rat liver and hepatoma

The lipid dependence of the pyrophosphatase activity of microsomes from rat liver and hepatoma was studied. Two methods were used for modification of the lipid composition of the microsomes: delipidation with organic solvents followed by relipidation with phospholipid vesicles and transformation of the microsomal lipid composition by lipid exchange proteins. In contrast to glucose 6-phosphatase, microsomal pyrophosphatase activity was found to be insensitive to modification of the membrane lipid composition by the above method. Possible causes of the different lipid dependence of various activities of microsomal glucose 6-phosphatase are discussed.     

Phospholipid dependence of UDP-glucuronyltransferase.

Very extensive hydrolysis of phospholipids with pure Bacillus cereus phospholipase C at 5 degrees C greatly inhibited the maximum demonstrable rate of glucuronidation of p-nitrophenol by UDPglucuronyltransferase in guinea pig liver microsomes. Lysophosphatidylcholine restored much of the inhibited activity but non-phospholipid surfactants or hydrolysis of diglycerides failed to reactivate. Phospholipid depletion likewise inhibited o-aminophenol glucuronidation and phospholipids restored activity. It is concluded that glucuronyltransferase specifically requires phospholipids for optimal activity. It seems unlikely that these phospholipids only serve to dissolve aglycones, or that they are direct physiological regulators of the transferase. Instead, a permissive role is ascribed to phospholipids, allowing glucuronyltransferase to be regulated by other means.     

Inhibition of glucose 6-phosphatase by pure and impure C-type phospholipases. Reactivation by phospholipid dispersions and protection by serum albumin.

1. Pure or impure C-type phospholipases hydrolysed rat liver microsomal phosphatides in situ at 5 degrees or 37 degrees C. At 5 degrees C mean hydrolysis of total phospholipids was 90% by Bacillus cereus and 75% by Clostridium perfringens (Clostridium welchii) C-type phospholipases. 2. Four degrees of inhibition of glucose 6-phosphatase (D-glucose 6-phosphate phosphohydrolase; EC 3.1.3.9) resulted. (a) At 37 degrees C inhibition was virtually complete and apparently irreversible. (b) At 5 degrees C phospholipase C inhibited 50-87% of the activity expressed by intact control microsomal fractions. (c) Bovine serum albumin present during delipidation alleviated most of this inhibition: at 5 degrees C phospholipase C plus bovine serum albumin inhibited by 0-35% (mean 18%):simultaneous stimulation by the destruction of its latency seems to offset glucose 6-phosphatase inhibition, sometimes completely. (d) If latency was first destroyed, phospholipase C plus bovine serum albumin inhibited 30-50% of total glucose 6-phosphatase activity at 5 degrees C. Only this inhibition is likely largely to reflect the lower availability of phospholipids, essential for maximal enzyme activity, as it is virtually completely reversed by added phospholipid dispersions. Co-dispersions of phosphatidylserine plus phosphatidylcholine (1:1, w/w) were especially effective but Triton X-100 was unable effectively to restore activity. 3. Considerable glucose 6-phosphatase activity survived 240min of treatment with phospholipase C at 5 degrees C, but in the absence of substrate or at physiological glucose 6-phosphate concentrations the delipidated enzyme was completely inactivated within 10min at 37 degrees C. However, 80mM-glucose 6-phosphate stabilized it and phospholipid dispersions substantially restored thermal stability. 4. It is concluded that glucose 6-phosphatase is at least partly phospholipid-dependent, and complete dependence is not excluded. For reasons discussed it is impossible yet to be certain which phospholipid class(es) the enzyme requires for activity.     

Subcellular localization of rat gastric phospholipase A2

In the present study, we have performed experiments to gain some insight into the subcellular localization and biochemical properties of gastric mucosal phospholipase A2. After classical subcellular fractionation of whole glandular stomach mucosa, we found that gastric phospholipase A2 was essentially enriched in the 105,000 x g pellet that contains microsomes and plasma membranes. Except for the cytosol, all the subcellular fractions exhibited similar phospholipase A2 activity (i.e., optimum of pH, calcium dependence, apparent Km and positional specificity). The high-speed pellet was further characterized by ultracentrifugation on a sucrose gradient. Data showed that the sedimentation profile of phospholipase A2 was quite similar to those of plasma membrane markers and more specifically to an apical membrane marker. These results, taken together, showed that a gastric phospholipase A2 is distributed among the various subcellular fractions (as a result of cross-contamination) together with the membrane fraction on which it is associated. It is proposed that this fraction is the apical plasma membrane which would be the main site of phospholipase A2 action for arachidonic acid release. Lysophospholipase showed the same sedimentation profile as phospholipase A2, whereas acyl CoA-lysophosphatidylcholine: acyltransferase mainly sedimented with heavy microsomes. The substrate specificity of the enzyme was assessed by endogenous hydrolysis of gastric mucosal phospholipids. We were able to show that the enzyme acts at nearly the same rate on two major gastric membrane phospholipids, namely phosphatidylcholine and phosphatidylethanolamine.     

Properties of microsomal phospholipases in rat liver and hepatoma.

Phospholipase A1, A2 and lysophospholipase activities in microsomes of Novikoff hepatoma host rat liver and regenerating rat liver were compared using 1-[9', 10'-3H2]palmitoyl-2-[1'-14C] linoleoyl-sn-glycero-3-phosphoethanolamine, 1-[1' -3H-]hexadecyl-2-acyl-sn-glycero-3-phosphoethanolamine, and 1-[9', 10'-3H2]palmitoyl-sn-glycero-3-phosphoethanolamine as substrates. 1. Microsomes of all three tissues showed two pH dependent peaks of hydrolytic activity, one at pH 7.5 and another at pH 9.5. 2. Phospholipid hydrolytic activity in microsomes from host liver and regenerating liver require Ca2+ for hydrolysis at pH 9.5, but not at pH 7.5. Hepatoma microsomes require Ca2+ for activity at both pH values. 3. Phospholipase A1 activity, stimulated by addition of Triton X-100 to the incubation mixtures, was detected in both host liver and regenerating liver microsomes. There was no evidence of phospholipase A1 activity in hepatoma microsomes. 4. Phospholipase A2 was detected in microsomes of all three tissues using 1-[1'-3H] hexadecyl-2-acyl-sn-glycero-3-phosphoethanolamine as a substrate. The activity required calcium and was inhibited by Triton X-100. 5. Lysophospholipase activity was evident in the microsomes from all three tissues. The activity was inhibited by both Ca2+ and Triton X-100. 6. Differences were also detected between host liver and hepatoma microsomal phospholipid hydrolase activities with respect to the effect of increasing protein concentration, apparent Michaelis-Menten constants, and time course of the reaction.     

Regulation by Lipids of Plant Microsomal Enzymes: II. LIPID DEPENDENCE OF THE NADH-CYTOCHROME c REDUCTASE OF POTATO TUBERS

Microsomal membranes from potato tubers were treated with a phospholipase C extracted from Bacillus cereus. A positive correlation could be observed between the hydrolysis of membranous phospholipids and the decrease of the NADH-cytochrome c reductase activity. Addition of total lipid or phospholipid micelles to phospholipase C-treated microsomes partially restored the NADH-cytochrome c reductase activity, thus proving the lipid-dependence of this enzyme.     

The chemical carcinogen-induced enzyme, GDP-fucose: GM1 alpha 1----2 fucosyltransferase in rat liver and hepatoma: modulation by and association with phospholipids

The enzyme GDPFuc:GM1 alpha 1----2 fucosyltransferase, induced by chemical carcinogens in precancerous rat liver as well as rat hepatoma cells, was found previously to be membrane bound, and was inactivated by various detergents, while the activities of many other transferases are generally enhanced by detergents (Holmes, E.H. & Hakomori, S. (1983) J. Biol. Chem. 258, 3706-3717). The effects of phospholipids and detergents on rat hepatoma H35 cells, the conditions of solubilization and subsequent affinity chromatography of the enzyme, and a possible association of phospholipids with the enzyme have been studied with the following major results: The alpha 1----2 fucosyltransferase activity in Golgi membrane was diminished on treatment of membranes with phospholipase A1 or phospholipase C. The enzyme activity was stimulated 7-fold in the presence of cardiolipin or phosphatidylglycerol (and 3-fold by phosphatidylethanolamine) but not other phospholipids. The stimulatory effect of phosphatidylglycerol was eliminated when a variety of ionic or non-ionic detergents were added to the reaction mixture, with the exception of the cationic detergent G-3634-A, which provided a 10-fold total stimulation in the presence of phosphatidylglycerol. The kinetic analysis indicated that addition of phosphatidylglycerol has a negligible effect on apparent Km values but increases the Vmax of the enzyme 5- to 6-fold. The enzyme activity was solubilized by the dialyzable detergent CHAPSO without inhibition of the enzyme activity, and the solubilized enzyme in the presence of 0.4% CHAPSO is partially purified by chromatography on GDP-hexanolamine-Sepharose. Removal of CHAPSO from the affinity purified enzyme by dialysis resulted in a 66% loss of the original activity, which was restored by addition of phosphatidylglycerol. Chromatography of the affinity-purified enzyme with 3H-labeled phosphatidylglycerol on a Biogel A0.5 column indicated an association of the enzyme with the phospholipid that occurred only in the absence of detergent. These results suggest that phospholipid has a direct effect on the enzyme and that the inhibitory effect of detergents can be ascribable to disturbing interaction between phospholipids and the enzyme. A possible role of specific phospholipids on in vivo transferase activity for glycolipids is discussed.     

Stimulation and inhibition of pancreatic phospholipase A2 by local anesthetics as a result of their interaction with the substrate.

1. At low concentrations the local anesthetic dibucaine stimulates hydrolysis by pancreatic phospholipase A2 of phospholipids extracted from rat liver mitochondria or microsomes, whereas at higher concentrations it inhibits. The action of this enzyme towards membrane-bound substrates is barely influenced by low, but inhibited by high concentrations of dibucaine. 2. Butacaine, which is a weaker anesthetic, stimulates hydrolysis of extracted phospholipids and inhibits that of membrane-bound substrates, both actions being concentration dependent. 3. The inhibitory potency of dibucaine is several times higher in NaCl than in sucrose solutions and strongly increases with decreasing pH. Neither one of these two effects is the result of a change in binding efficiency of the anesthetic to the substrates. 4. Extracted total membrane lipids bind considerably less anesthetic than an equivalent amount of native membrane. Liver phosphatidylethanolamine is more effective in binding of dibucaine than liver phosphatidylcholine. 5. Binding of dibucaine to the phospholipase, as studied by equilibrium dialysis is at the lower level of detectability. According to the same method dibucaine is unable to displace 45Ca2+ bound to the enzyme. 6. These results are interpreted as to support the view that local anesthetics interfere with pancreatic phospholipase activity by means of interaction with the substrate rather than with the enzyme.     

Biosynthesis of mitochondrial phospholipids using endogenously generated diglycerides.

When isolated mitochondria or microsomes from rat liver were treated with phospholipase C, the incorporation of radioactive phospholipid precursors was markedly enhanced, presumably as a result of production of diglycerides by hydrolysis of endogenous phospholipids. Incorporation of CDP[14C]choline into lecithin in rat liver or BHK-21 mitochondria could be attributed to residual contamination from elements of the endoplasmic reticulum, with added diglycerides or with endogenous diglycerides produced by the phospholipase C treatment. A similar stimulation of [gamma32P]ATP incorporation into phospholipids was observed with exogenous or endogenous diglycerides, but the mitochondrial diglyceride kinase in either case was also related to the degree of microsomal contaminants. It was concluded that previous studies showing negligible capacity of mitochondria for lecithin biosynthesis de novo were not explainable on the basis of limited accessibility of added diglycerides, and that formation of phosphatidic acid by diglyceride kinase was not of significance in rat liver mitochondria.     

Effect of phospholipase on cation-induced transmembrane transport of DNA in Escherichia coli

Incubation of bacterial cells in 0.1 M CaCl2 at 0 degrees C considerably increases the amount of phospholipids susceptible to action of a specific enzyme of phospholipid metabolism phospholipase C (hydrolysis to diacylglycerides). In process of incubation in CaCl2 solutions at 0 degrees C the expressed activity of an endogenous enzyme phospholipase A has been registered in cellular samples. Binding of the enzyme by the cells under conditions unfavourable for phospholipids hydrolysis (0 degrees C) suppresses strongly and reversibly cellular ability to DNA transformation without affecting cellular survival. As calculated, the enzyme molecules cover about 10% of cellular surface while inhibiting 90% of transmembrane transfer. The obtained data are considered to be a solid argument supporting the important role of the membrane phospholipids in the mechanism of cation-induced DNA transfer into the cell.     

Phospholipase A2 inactivation of microsomal 17β-hydroxysteroid oxidoreductase: Rates of phospholipid hydrolysis and enzyme inactivation,effects of hydrolysis products and properties of the phospholipase A2-treated enzyme

Exposure of guinea pig liver microsomes to phospholipase A₂ resulted in the nearly complete loss of 17β-hydroxy-steroid oxidoreductase (17β-HSD) activity, the time course of which correlated with phospholipid hydrolysis and lysolecithin formation. Lysolecithin and unsaturated fatty acids added to microsomes also inactivated 17β-HSD indicating that they may contribute to the inactivation by phospholipase A₂.If exposure to lysolecithin and fatty acids was minimized by including serum albumin in the reaction mixture, phospholipids were rapidly hydrolyzed; but in this case the extent of 17β-HSD inactivation was less and the rate of loss was significantly slower. The data suggest that phospholipid hydrolysis $\text{per se}$ results in a destabilization of 17β-HSD resulting in the subsequent activity loss.The inactivation of 17β-HSD by lysolecithin and fatty acids has not been reported previously and is suggestive of a possible control mechanism $\text{in vivo}$.     

Atomic force microscope imaging of phospholipid bilayer degradation by phospholipase A2.

We have investigated the time course of the degradation of a supported dipalmitoylphosphatidylcholine bilayer by phospholipase A2 in aqueous buffer with an atomic force microscope. Contact mode imaging allows visualization of enzyme activity on the substrate with a lateral resolution of less than 10 nm. Detailed analysis of the micrographs reveals a dependence of enzyme activity on the phospholipid organization and orientation in the bilayer. These experiments suggest that it is possible to observe single enzymes at work in small channels, which are created by the hydrolysis of membrane phospholipids. Indeed, the measured rate of hydrolysis of phospholipids corresponds very well with the enzyme activity found in kinetic studies. It was also possible to correlate the number of enzymes at the surface, as calculated from the binding constant to the number of starting points of the hydrolysis. In addition, the width of the channels was found to be comparable to the diameter of a single phospholipase A2 and thus further supports the single-enzyme hypothesis.     

The action of phosphatidylinositol-specific phospholipases C on membranes.

A phospholipase C prepared from lymphocytes readily hydrolysed pure phosphatidyl-inositol but was relatively ineffective against phosphatidylinositol in erythrocyte "ghosts" and rat liver microsomal fraction and also against sonicated lipid extracts from these membranes. In contrast, a phospholipase C prepared from Staphylcoccus aureus readily hydrolysed phosphatidylinositol in sonicated lipid extracts but had only low activity against purified phosphatidylinositol. Unlike the enzyme from lymphocytes, the S. aureus phospholipase C did not require Ca2+ for its activity and was inhibited by cations. The previously reported specificity of this enzyme was confirmed by our observation of hydrolysis of approx. 75% of the phosphatidylinositol in ox, sheep and cat erythrocyte "ghosts" together with no detectable effect on the major erythrocyte membrane phospholipids. The phosphatidylinositol of rat liver microsomal fraction was hydrolysed only to a maximum of 15%. Some preliminary experiments showed that approx. 60% of the phosphatidylinositol of ox or sheep erythrocytes could be hydrolysed without causing substantial haemolysis.     

Studies on enzymes related to diacylglycerol production in activated platelets: I. phosphatidylinositol-specific phospholipasec: Further characterization using a simple method for determination of activity

A simple method of determination of phosphatidylinositol-specific phospholipase C activity in soluble platelet extracts has been devised. It is based on the use of a total lipid extract from rat liver microsomes incubated with [³H]inositol in the presence of MnCl₂. Phosphatidylinositol hydrolysis can thus be detected by determining hydrosoluble radioactivity formed upon incubation with enzyme fractions. Owing to the presence of other phospholipids in the assay system, phospholipase C was inhibited. However, activity was restored by sodium deoxycholate (0.1%, w/v). Optimal conditions also included calcium (1–10 mM) and a pH between 5 and 7, allowing the detection of phospholipase C without the need for purifying the substrate. Using this simplified procedure, platelet phospholipase C was submitted to preparative electrofocusing and to gel filtration chromatography on Sephacryl S-200. Phospholipase C focused in one single peak at pH 6.1. An M_r of 86000 was found upon gel chromatography of a crude extract, against 68 000 when phospholipase C had been previously purified by electrofocusing. These data indicate that phospholipase C might be associated with lipids or with an M_r 20 000 protein, the significance of which is discussed.     

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.