Transformation of neutral to alkaline fructose 1,6-bisphosphatase. Converting enzyme activity in the large-particle fraction from rabbit liver

A liver particle fraction containing lysosomes catalyzes the conversion of native rabbit liver fructose 1,6-bisphosphatase (EC 3.1.3.11), having a neutral pH optimum, to a modified form with an alkaline pH optimum. The “converting enzyme” activity is partially recovered with the membranes from disrupted particles, and is also detected in “intact” particles isolated and maintained in isotonic buffered sucrose. The converting enzyme activity associated with the membrane fraction is expressed at pH 6.5, but not at pH 4.5, although activity at the lower pH appears when the enzyme is released from the membranes with Triton X-100. In contrast, proteolytic activity as measured with peptide and protein substrates is maximal at pH 5.0 or below, and is the same for the membrane-bound or solubilized proteases. The results suggest that a specific converting enzyme, at least partially associated with a particle (possibly lysosomal) membrane, is responsible for the modification of fructose bisphosphatase and the change in its catalytic properties.     

Choline acetyltransferase binding to and release from membranes

1. The binding of non-occluded choline acetyltransferase to synaptosome membranes is a reversible process that is primarily dependent on the pH and ionic strength of the suspending medium. 2. The distribution of soluble enzyme bound to synaptosome membranes was studied by density-gradient centrifuging. 3. Choline acetyltransferase shows enzyme activity both in the free and in the membrane-bound form. 4. Varying the temperature or prolonged hypo-osmotic treatment does not release the membrane-bound enzyme. 5. The release of choline acetyltransferase from membranes by different anions, thiols, adenosine nucleotides and enzyme substrates was studied.     

Activation and membrane binding of carboxypeptidase E

Carboxypeptidase E (CPE) is a carboxypeptidase B-like enzyme that is thought to be involved in the processing of peptide hormones and neurotransmitters. Soluble and membrane-associated forms of CPE have been observed in purified secretory granules from various hormone-producing tissues. In this report, the influence of membrane association on CPE activity has been examined. A substantial amount of the membrane-associated CPE activity is solubilized upon extraction of bovine pituitary membranes with either 100 mM sodium acetate buffer (pH 5.6) containing 0.5% Triton X-100 and 1 M NaCl, or by extraction with high pH buffers (pH greater than 8). These treatments also lead to a two- to threefold increase in CPE activity. CPE extracted from membranes with either NaCl/Triton X-100 or high pH buffers hydrolyzes the dansyl-Phe-Ala-Arg substrate with a lower Km than the membrane-associated CPE. The Vmax of CPE present in extracts and membrane fractions after the NaCl/Triton X-100 treatment is twofold higher than in untreated membranes. Treatment of membranes with high pH buffers does not affect the Vmax of CPE in the soluble and particulate fractions. Pretreatment of membranes with bromoacetyl-D-arginine, an active site-directed irreversible inhibitor of CPE, blocks the activation by NaCl/Triton X-100 treatment. Thus the increase in CPE activity upon extraction from membranes is probably not because of the conversion of an inactive form to an active one, but is the result of changes in the conformation of the enzyme that effect the catalytic activity.     

The solubilization of tetrameric alkaline phosphatase from human liver and its conversion into various forms by phosphatidylinositol phospholipase C or proteolysis

When membrane-bound human liver alkaline phosphatase was treated with a phosphatidylinositol (PI) phospholipase C obtained from Bacillus cereus, or with the proteases ficin and bromelain, the enzyme released was dimeric. Butanol extraction of the plasma membranes at pH 7.6 yielded a water-soluble, aggregated form that PI phospholipase C could also convert to dimers. When the membrane-bound enzyme was solubilized with a non-ionic detergent (Nonidet P-40), it had the Mr of a tetramer; this, too, was convertible to dimers with PI phospholipase C or a protease. Butanol extraction of whole liver tissue at pH 6.6 and subsequent purification yielded a dimeric enzyme on electrophoresis under nondenaturing conditions, whereas butanol extraction at pH values of 7.6 or above and subsequent purification by immunoaffinity chromatography yielded an enzyme with a native Mr twice that of the dimeric form. This high molecular weight form showed a single Coomassie-stained band (Mr = 83,000) on electrophoresis under denaturing conditions in sodium dodecyl sulfate, as did its PI phospholipase C cleaved product; this Mr was the same as that obtained with the enzyme purified from whole liver using butanol extraction at pH 6.6. These results are highly suggestive of the presence of a butanol-activated endogenous enzyme activity (possibly a phospholipase) that is optimally active at an acidic pH. Inhibition of this activity by maintaining an alkaline pH during extraction and purification results in a tetrameric enzyme. Alkaline phosphatase, whether released by phosphatidylinositol (PI) phospholipase C or protease treatment of intact plasma membranes, or purified in a dimeric form, would not adsorb to a hydrophobic medium. PI phospholipase C treatment of alkaline phosphatase solubilized from plasma membranes by either detergent or butanol at pH 7.6 yielded a dimeric enzyme that did not absorb to the hydrophobic medium, whereas the untreated preparations did. This adsorbed activity was readily released by detergent. Likewise, alkaline phosphatase solubilized from plasma membranes by butanol extraction at pH 7.6 would incorporate into phosphatidylcholine liposomes, whereas the enzyme released from the membranes by PI phospholipase C would not incorporate. The dimeric enzyme purified from a butanol extract of whole liver tissue carried out at pH 6.6 did not incorporate. We conclude that PI phospholipase C converts a hydrophobic tetramer of alkaline phosphatase into hydrophilic dimers through removal of the 1,2-diacylglycerol moiety of phosphatidylinositol. Based on these and others' findings, we devised a model of alkaline phosphatase's conversion into its various forms.     

Heparan sulphate-degrading endoglycosidase in liver plasma membranes.

An endoglycosidase is described in isolated liver plasma membranes that brings about a rapid and selective degradation of membrane-associated heparan sulphate, pre-labelled biosynthetically with Na2(35)SO4. The enzyme attacked mainly the polysaccharide chains of a hydrophobic membrane proteoglycan and it had little effect on a proteoglycan that could be displaced from the membranes with 1.0 M-NaCl. The highest activity was measured in the pH range 7.5-8.0, and the enzyme was almost completely inhibited below pH 5.5. Breakdown of susceptible polysaccharide chains was fast, being complete in 20-30 min. The major oligosaccharide fraction (Mr approx. 6000) produced by the enzyme was considerably smaller than the intact heparan sulphate chains. Enzyme activity was retained in membranes solubilized in 1% (v/v) Triton X-100. The high pH optimum and plasma-membrane association distinguish this enzyme from other heparan sulphate-degrading endoglycosidases that have acid pH optima and may be of lysosomal origin. A plasma-membrane endoglycosidase could modulate cellular interactions mediated by heparan sulphate, and/or release biologically active fragments of the polysaccharide from the cell periphery.     

The distribution and properties of the Mg2(+)-ATPase in the membranes of functionally different muscles in the hen]

From striated (m. pectoralis and myocardium) and smooth (myometrium) muscle tissues of hen, by means of differential centrifugation with Ca-oxalate loading, membrane preparations were obtained with high activity of Mg(2+)-ATPase, i.e. a marker enzyme of tubular membranes of T-system of skeletal muscles. Some properties (pH and temperature optima) of this enzyme were investigated and compared to those of Ca(2+)-ATPase from membranes of the sarcoplasmic reticulum. It was shown that in all the investigated muscles, Mg(2+)-ATPase is associated with membrane fraction which in its density corresponds to tubular membranes of T-system. Activation of this enzyme is characterized by similar optimal levels of pH (7.2) and temperature (25 degrees C). The activity of Ca(2+)-ATPase in the membranes of the sarcoplasmic reticulum, in contrast to that of Mg(2+)-ATPase, is observed in more narrow bands of pH and temperature, exhibiting tissue specificity. The data obtained, indicating a possibility of chromatographic separation of these enzymes, confirm their biochemical individuality.     

The role of free calmodulin in the regulation of calcium-pump activity in erythrocytes

The activity of Ca-pump in inside-out oriented vesicles obtained from erythrocyte membranes after their 30 min treatment with EGTA at 20 degrees C (membranes A) and 37 degrees C (membranes B) was investigated. It was shown that in membranes A placed into an incubation medium containing 0.1 mM EGTA (pH 7.4) the overall effect of exogenous calmodulin is due to the increase in the maximal activity of the enzyme, its affinity for Ca2+ being unaffected thereby. In membranes B placed into the same medium (pH 6.75) the activation of the Ca-pump by calmodulin is due to the increased affinity for Ca2+ at a constant maximal activity of the enzyme. The dependencies of the value of the calmodulin-stimulated component of membranes A and the Ca2+-binding capacity of calmodulin measured by the intensity of N-phenyl-1-naphthylamine fluorescence on the concentration of free Ca2+ are coincident. In the case of membranes B, the stimulation of Ca-pump by calmodulin occurs at much lower Ca2+ concentrations than the Ca2+ binding-induced conformational shifts in calmodulin. The experimental results suggest that the affinity of the Ca-pump for Ca2+ may affect calmodulin existing in a Ca2+-independent state. The hydrophobic interactions between the Ca-calmodulin complex and the Ca-ATPase molecule are apparently essential for the regulation of the maximal enzyme activity.     

Kinetic characterization of cytochrome c oxidase from Bacillus subtilis

Bacillus subtilis aa3-type cytochrome c oxidase is capable of oxidizing cytochrome c from different origins. The kinetic properties of the enzyme are influenced by ionic strength. The affinity for Saccharomyces cerevisiae cytochrome c declines with increasing ionic strength whereas the Vmax remains almost constant. An increase of Vmax is observed when the enzyme is incorporated in artificial membranes. Negatively charged phospholipids allow high turnover rates of the aa3-type oxidase. The effect of ionic strength on oxidation of horse heart cytochrome c results in significant changes of both Km and Vmax. These effects can be explained by disturbances of enzyme-substrate interactions and are not related to changes in the aggregation state of the enzyme. The respiration control index of the enzyme reconstituted in artificial membranes appeared to be dependent on phospholipid composition, protein/lipid ratios and also on the external pH. The action of the ionophores nigericin and valinomycin, at various pH values, on the enzyme activity and proton-permeability measurements of the membranes indicate that both components of the proton-motive force, the membrane potential and the pH gradient, can in principle regulate enzyme activity in the reconstituted state.     

The role of a cathepsin D-like activity in the release of Gal beta 1-4GlcNAc alpha 2-6-sialyltransferase from rat liver Golgi membranes during the acute-phase response.

Golgi-membrane-bound Gal beta 1-4GlcNAc alpha 2-6-sialyltransferase (CMP-N-acetylneuraminate:beta-galactoside alpha 2-6-sialyltransferase, EC 2.4.99.1) behaves as an acute-phase reactant increasing about 5-fold in serum in rats suffering from inflammation. The mechanism of release from the Golgi membrane is not understood. In the present study it was found that sialyltransferase could be released from the membrane by treatment with ultrasonic vibration (sonication) followed by incubation at reduced pH. Maximum release occurred at pH 5.6, and membranes from inflamed rats released more enzyme than did membranes from controls. Galactosyltransferase (UDP-galactose:N-acetylglucosamine galactosyltransferase; EC 2.4.1.38), another Golgi-located enzyme, which does not behave as an acute-phase reactant, remained bound to the membranes under the same conditions. Release of the alpha 2-6-sialyltransferase from Golgi membranes was substantially inhibited by pepstatin A, a potent inhibitor of cathepsin D-like proteinases. Inhibition of release of the sialyltransferase also occurred after preincubation of sonicated Golgi membranes with antiserum raised against rat liver lysosomal cathepsin D. Addition of bovine spleen cathepsin D to incubation mixtures of sonicated Golgi membranes caused enhanced release of the sialyltransferase. Intact Golgi membranes were incubated at lowered pH in presence of pepstatin A to inhibit any proteinase activity at the cytosolic face; subsequent sonication showed that the sialyltransferase had been released, suggesting that the proteinase was active at the luminal face of the Golgi. Golgi membranes contained a low level of cathepsin D activity (EC 3.4.23.5); the enzyme was mainly membrane-bound, since it could only be released by extraction with Triton X-100 or incubation of sonicated Golgi membranes with 5 mM-mannose 6-phosphate. Immunoblot analysis showed that the transferase released from sonicated Golgi membranes at lowered pH had an apparent Mr of about 42,000 compared with one of about 49,000 for the membrane-bound enzyme. Values of Km for the bound and released enzyme activities were comparable and were similar to values reported previously for liver and serum enzymes. The work suggests that a major portion of sialyltransferase containing the catalytic site is released from a membrane anchor by a cathepsin D-like proteinase located at the luminal face of the Golgi and that this explains the acute-phase behaviour of this enzyme.     

Immobilization of urease onto chemically modified acrylonitrile copolymer membranes

Poly (acrylonitrile-methylmethacrylate-sodium vinylsulfonate) membranes were subjected to seven different chemical modifications. The amounts of new groups incorporated in the membranes with the modifications were determined. Urease was covalently immobilized on the modified membranes. Both the amount of bound protein and relative activity of immobilized urease were measured. The highest activity was found for urease bound to membranes modified with hydroxylammonium sulfate (68%) and hydrazinium sulfate (67%). Optimum pH of free urease was determined to be 5.8. For positively charged membranes, pH optimum was shifted to higher values, while for negatively charged membranes-to lower pH. The charge of the matrix affected also the rate of the enzyme reaction. The highest rate was measured with urease immobilized on membranes modified with hydroxylammonium sulfate and hydrazinium sulfate. The major part of the immobilized enzyme on different modified membranes remained stable-only ca. 20% of enzyme activity was lost for 4 h at 70 degrees C while the free enzyme was totally inactivated.     

Neuropeptide-degrading endopeptidase activity of locust (Schistocerca gregaria) synaptic membranes.

Locust adipokinetic hormone (AKH, pGlu-Leu-Asn-Phe-Thr-Pro-Asn-Trp-Gly-Thr-NH2) was used as the substrate to measure neuropeptide-degrading endopeptidase activity in neutral membranes from ganglia of the locust Schistocerca gregaria. Initial hydrolysis of AKH at neural pH by peptidases of washed neural membranes generated pGlu-Leu-Asn and Phe-Thr-Pro-Asn-Trp-Gly-Thr-NH2 as primary metabolites, demonstrating that degradation was initiated by cleavage of the Asn-Phe bond. Amastatin protected the C-terminal fragment from further metabolism by aminopeptidase activity without inhibiting AKH degradation. The same fragments were generated on incubation of AKH with purified pig kidney endopeptidase 24.11, and enzyme known to cleave peptide bonds that involve the amino group of hydrophobic amino acids. Phosphoramidon (10 microM), a selective inhibitor of mammalian endopeptidase 24.11, partially inhibited the endopeptidase activity of locust neural membranes. This phosphoramidon-sensitive activity was shown to enriched in a synaptic membrane preparation with around 80% of the activity being inhibited by 10 microM-phosphoramidon (IC50 = 0.2 microM). The synaptic endopeptidase was also inhibited by 1 mM-EDTA, 1 mM-1,10-phenanthroline and 1 microM-thiorphan, and the activity was maximal between pH 7.3 and 8.0. Localization of the phosphoramidon-sensitive enzyme in synaptic membranes is consistent with a physiological role for this endopeptidase in the metabolism of insect peptides at the synapse.     

Isoelectrically trapped enzymatic bioreactors in a multimembrane cell coupled to an electric field: theoretical modeling and experimental validation with urease

A novel type of immobilized enzyme reactor operating under an electric field is here reported: a multicompartment immobilized enzyme reactor (MIER). In this experimental set-up, the enzyme and zwitterionic buffering ions are trapped in between two isoelectric membranes, having isoelectric point (pl) values so far apart as to trap the enzyme by an isoelectric mechanism, while allowing operation at pH optima, even when the latter pH value is quite removed from the enzyme pl. As an example, urease (pl 4.9) is trapped between a pl 4.0 and a pl 8.0 membranes, thus permitting operation (via suitable amphoteric ions buffering at pH 7.5) at the pH of optimum of activity (pH 7.5). The charged product (ammonium ions) quickly leaves the enzyme chamber under the influence of the electric field, thus allowing sustained activity for much longer time periods than in conventional reactors. As an example, while in a batch reactor 90% of original enzyme activity is lost in 200 min, only 2% activity is lost in the same period in the MIER reactor. As an additional bonus, the MIER reactor allows conversion rates of approximately 95% in a wide range of substrate concentrations, whereas batch-type reactors rarely achieve better than 50% conversion under comparable experimental conditions. (c) 1997 John Wiley & Sons, Inc.     

Characterization of beta-glucosidase as a peripheral enzyme of lysosomal membranes from mouse liver and purification

Lysosomal membrane fractions were prepared from lysosomes of mouse liver by freeze-thawing in a hypotonic buffer: 54% of beta-glucosidase [EC 3.2.1.45] in lysosomes was associated with the membrane fractions, whereas 96% of beta-glucuronidase [EC 3.2.1.31] was recovered in the soluble fractions of lysosomes. beta-glucosidase was solubilized by pH 9.5 treatment or by Triton treatment of membranes. The enzyme solubilized with alkali and concentrated with (NH4)2SO4 was rapidly inactivated in a solution of pH 9.5, but could be protected against inactivation by acidic detergent. Gel filtration analysis indicated that beta-glucosidase was in an aggregated form at neutral pH and could be disaggregated by alkali and detergents. The enzyme dissociated with detergents also showed a higher activity than the alkali-treated enzyme. These results suggested that beta-glucosidase is a peripheral enzyme bound to acidic lipids in membranes. beta-Glucosidase was purified to apparent homogeneity by (NH4)2SO4 fractionation and chromatographies with Sephacryl S-300, hydroxylapatite and cation exchangers in the presence of detergents. The catalytic activity of the purified enzyme was maximally stimulated by phosphatidylserine and heat-stable protein in the presence of a low concentration of Triton X-100. The stimulation was mainly due to an increase in Vmax.     

Correlation of energy-dependent cell cohesion with social motility in Myxococcus xanthus.

Membrane-bound ATPase was found in membranes of the archaebacterium Methanosarcina barkeri. The ATPase activity required divalent cations, Mg2+ or Mn2+, and maximum activity was obtained at pH 5.2. The activity was specifically stimulated by HSO3- with a shift of optimal pH to 5.8, and N,N'-dicyclohexylcarbodiimide inhibited ATP hydrolysis. The enzyme could be solubilized from membranes by incubation in 1 mM Tris-maleate buffer (pH 6.9) containing 0.5 mM EDTA. The solubilized ATPase was purified by DEAE-Sepharose and Sephacryl S-300 chromatography. The molecular weight of the purified enzyme was estimated to be 420,000 by gel filtration through Sephacryl S-300. Polyacrylamide gel electrophoresis in sodium dodecyl sulfate revealed two classes of subunit, Mr 62,000 (alpha) and 49,000 (beta) associated in the molar ratio 1:1. These results suggest that the ATPase of M. barkeri is similar to the F0F1 type ATPase found in many eubacteria.     

Partial characterization and inactivation of membrane-bound phosphofructokinase from Tetrahymena pyriformis

In Tetrahymena pyriformis, 6-phosphofructokinase (ATP:D-fructose-6-phosphate 1-phosphotransferase, EC 2.7.1.11) is membrane-bound. Enzyme activity is solubilized by treatment of membranes with Triton X-100 or by high ionic strength in the presence of a chelator. The solubilized enzyme has an approximate molecular weight of 300 000. Both the membrane-bound enzyme and the solubilized enzyme exhibit maximum activity over a wide pH range. At low pH, the membrane-bound form of the enzyme is irreversibly inactivated, whereas the solubilized enzyme is not. The membrane-bound enzyme is inactivated by incubation with Mg2+, ATP, fluoride and a soluble factor that is heat labile, nondialysis, (NH4)2SO4 precipitable and sensitive to trypsin. The solubilized enzyme is not inactivated under similar conditions.     

Chromogranin A-processing proteinases in purified chromaffin granules: contaminants or endogenous enzymes?

It was the purpose of this study to define the chromogranin A-processing proteinases present in highly purified preparations of bovine chromaffin granules. The most active enzyme had a pH optimum of 5.0 and was inhibited by pepstatin. It could be identified immunologically as a cathepsin D-like enzyme and subcellular fractionation established its lysosomal origin. After removal of this enzyme the remaining activity at pH 5.0 was mainly due to a cathepsin B-like proteinase. The presence of this enzyme could also be attributed to lysosomal contamination. In the presence of calcium, a further proteolytic activity became apparent at pH 5.0. This enzyme which was inhibited by rho-chloromercuriphenylsulfonic acid was localized in chromaffin granules. A trypsin-like peptidase, most active at pH 8.2, was enriched in a membrane wash of chromaffin granules. Subcellular fractionation indicated that this enzyme is preferentially bound to the membranes of very dense particles probably representing a subpopulation of chromaffin granules. This study establishes that the most active chromogranin A-degrading proteinases present in highly purified chromaffin granules are attributable to lysosomal contamination. Two enzymes with low activity (a Ca2+ activated proteinase and a trypsin-like enzyme) are, apparently, true constituents of chromaffin granules.     

Identification of Ca2+-stimulated polyphosphoinositide phospholipase C in isolated plant plasma membranes

A polyphosphoinositide phospholipase C has been identified in highly purified plasma membranes from shoots and roots of wheat seedlings. The enzyme preferentially hydrolysed phosphatidylinositol 4-phosphate and phosphatidylinositol 4,5-bisphosphate and had a different phosphoinositide substrate profile from soluble phospholipase C. The enzyme activity was lower in plasma membranes isolated from light-grown shoots than from dark-grown ones, whereas no differences in activity between plasma membranes from light- and dark-grown roots were seen. Maximum activity of the membrane-bound enzyme was observed around pH 6. It was activated by micromolar concentrations of Ca2+, but not by GTP or GTP analogues. The enzyme may participate in signal transduction over the plant plasma membrane.     

Identification and solubilization of a cAMP-independent protein kinase from mouse L-cell smooth membranes

1. Smooth membranes have been prepared from mouse L-cells and found to contain an endogenous protein kinase activity. 2. The enzyme(s) responsible for this activity use ATP, but no other nucleoside triphosphates, to phosphorylate endogenous membrane proteins as well as exogenously-added protein substrates such as phosvitin and casein. 3. Mg2+ is required for enzyme activity, maximal activity is observed at pH 7.5-8.0 and the kinase is not dependent on, or stimulated by, cyclic 3'-5' AMP. 4. The kinase activity is not decreased by the Walsh heat-stable inhibitor of cyclic 3'-5' AMP-dependent protein kinases. 5. Fifty percent or more of the membrane-associated kinase activity can be solubilized by extracting membranes with buffer containing 0.6 M NaCl. 6. The solubilized enzyme resembles the membrane-associated activity in its Mg2+ requirement, pH optimum and independence of cyclic 3'-5' AMP. 7. Phosvitin and casein are better exogenous substrates than histones or protamine for phosphorylation by the enzyme in either the membrane-associated or solubilized state.     

pH dependent inactivation of solubilized F1F0 ATP synthase by dicyclohexylcarbodiimide: pK(a) of detergent unmasked aspartyl-61 in Escherichia coli subunit c

The pH dependence of the reaction of dicyclohexylcarbodiimide with the essential aspartyl-61 residue in subunit c of Escherichia coli ATP synthase was compared in membranes and in a detergent dispersed preparation of the enzyme. The rate of reaction was estimated by measuring the inactivation of ATPase activity. The reaction with the detergent dispersed form of the enzyme proved to be pH sensitive with the essential aspartyl group titrating with a pK(a)=8. However, when measured with E. coli membranes, the reaction proved to be pH insensitive. The results suggest that the reacting aspartyl-61 residues are shielded from the bulk aqueous solvent when in the membrane, but then become aqueous-accessible following detergent solubilization.     

Acetyl coenzyme A: alpha-glucosaminide N-acetyltransferase. Evidence for a transmembrane acetylation mechanism

The lysosomal membrane enzyme acetyl-CoA: alpha-glucosaminide N-acetyltransferase catalyzes the transfer of an acetyl group from acetyl-CoA to terminal alpha-linked glucosamine residues of heparan sulfate. The reaction mechanism was examined using highly purified lysosomal membranes from rat liver. The reaction was followed by measuring the acetylation of a monosaccharide acetyl acceptor, glucosamine. The enzyme reaction was optimal above pH 5.5, and a 2-3-fold stimulation of activity was observed when the membranes were assayed in the presence of 0.1% taurodeoxycholate. Double reciprocal analysis and product inhibition studies indicated that the enzyme works by a Di-Iso Ping Pong Bi Bi mechanism. Further evidence to support this mechanism was provided by characterization of the enzyme half-reactions. Membranes incubated with acetyl-CoA and [3H]CoA were found to produce acetyl-[3H]CoA. This exchange was optimal at pH values above 7.0. Treating membranes with [3H] acetyl-CoA resulted in the formation of an acetyl-enzyme intermediate. The acetyl group could then be transferred to glucosamine, forming [3H]N-acetylglucosamine. The transfer of the acetyl group from the enzyme to glucosamine was optimal between pH 4 and 5. The results suggest that acetyl-CoA does not cross the lysosomal membrane. Instead, the enzyme is acetylated on the cytoplasmic side of the lysosome and the acetyl group is then transferred to the inside where it is used to acetylate heparan sulfate.