Predominant expression of lysosomal N-acylethanolamine-hydrolyzing acid amidase in macrophages revealed by immunochemical studies

Bioactive N-acylethanolamines, including anandamide (an endocannabinoid), N-palmitoylethanolamine (an anti-inflammatory substance), and N-oleoylethanolamine (an anorexic substance) are enzymatically hydrolyzed to fatty acids and ethanolamine. Fatty acid amide hydrolase plays a major role in this reaction. In addition, we cloned cDNA of an isozyme termed "N-acylethanolamine-hydrolyzing acid amidase (NAAA)" [K. Tsuboi, Y.-X. Sun, Y. Okamoto, N. Araki, T. Tonai, N. Ueda, Molecular characterization of N-acylethanolamine-hydrolyzing acid amidase, a novel member of the choloylglycine hydrolase family with structural and functional similarity to acid ceramidase, J. Biol. Chem. 280 (2005) 11082-11092]. Previous biochemical analyses suggested the expression of NAAA in macrophage cells and various rat tissues including lung and brain. To clarify the physiological significance of NAAA, here we immunochemically studied NAAA for the first time. We developed an antibody specific for rat NAAA, and by Western blotting revealed that NAAA is glycosylated and subjected to specific proteolysis. In alveolar macrophages isolated from rat lung, NAAA was immunocytochemically localized in lysosomes. In the whole lung tissue, only alveolar macrophages were immunostained for NAAA. Conformably, the mRNA and protein levels and activity of NAAA in alveolar macrophages were much higher than those in the whole lung tissue. In brain, intraventricular macrophages were positively stained with anti-NAAA antibody, while microglia appeared to be negative. These results strongly suggested the importance of macrophages as an expression site of NAAA in rat tissues.     

Amino acid residues crucial in pH regulation and proteolytic activation of N-acylethanolamine-hydrolyzing acid amidase

N-Acylethanolamine-hydrolyzing acid amidase (NAAA) is a lysosomal enzyme which hydrolyzes bioactive N-acylethanolamines, including anandamide and N-palmitoylethanolamine. NAAA shows acidic pH optimum in terms of both catalytic activity and maturation by specific proteolysis. However, molecular mechanism involved in this characteristic pH dependency remained unclear. Here we report the important role of Glu-195 of human NAAA by analyzing the mutants E195A and E195Q overexpressed in human embryonic kidney 293 cells. Concanamycin A, raising lysosomal pH, inhibited maturation of the wild-type, but not of the Glu-195 mutants. The purified precursors of the mutants, but not the wild-type, were proteolytically cleaved at pH 7.4 during 24-h incubation. Furthermore, when assayed for N-palmitoylethanolamine-hydrolyzing activity at different pH, the mutants did not exhibit a sharp peak around pH 4.5 in the pH-dependent activity profile. Mutants of other seven glutamic acid residues did not show such an abnormality. These results suggested a unique role of Glu-195 in the pH-dependent activity and proteolytic maturation. Moreover, Arg-142, Asp-145, and Asn-287 as well as previously identified Cys-126 were shown to be essential for the proteolytic activation. Since these residues were predicted to be catalytically important, the results strongly suggested that the proteolysis occurs through an autocatalytic mechanism.     

N-acylethanolamine-hydrolyzing acid amidase and fatty acid amide hydrolase inhibition differentially affect N-acylethanolamine levels and macrophage activation

N-acylethanolamines (NAEs) such as N-palmitoylethanolamine and anandamide are endogenous bioactive lipids having numerous functions, including the control of inflammation. Their levels and therefore actions can be controlled by modulating the activity of two hydrolytic enzymes, N-acylethanolamine-hydrolyzing acid amidase (NAAA) and fatty acid amide hydrolase (FAAH). As macrophages are key to inflammatory processes, we used lipopolysaccharide-activated J774 macrophages, as well as primary mouse alveolar macrophages, to study the effect of FAAH and NAAA inhibition, using PF-3845 and AM9053 respectively, on macrophage activation and NAE levels measured by HPLC-MS. Markers of macrophage activation were measured by qRT-PCR and ELISA. Activation of macrophages decreased NAAA expression and NAE hydrolytic activity. FAAH and NAAA inhibition increased the levels of the different NAEs, although with different magnitudes, whether in control condition or following LPS-induced macrophage activation. Both inhibitors reduced several markers of macrophage activation, such as mRNA expression of inflammatory mediators, as well as cytokine and prostaglandin production, with however some differences between FAAH and NAAA inhibition. Most of the NAEs tested – including N-docosatetraenoylethanolamine and N-docosahexaenoylethanolamine – also reduced LPS-induced mRNA expression of inflammatory mediators, again with differences depending on the marker and the NAE, thus offering a potential explanation for the differential effect of the inhibitors on macrophage activation markers. In conclusion, we show different and complementary effects of NAE on lipopolysaccharide-induced macrophage activation. Our results support an important role for inhibition of NAE hydrolysis and NAAA inhibition in particular in controlling macrophage activation, and thus inflammation.     

Involvement of N-acylethanolamine-hydrolyzing acid amidase in the degradation of anandamide and other N-acylethanolamines in macrophages

Bioactive N-acylethanolamines including the endocannabinoid anandamide are known to be hydrolyzed to fatty acids and ethanolamine by fatty acid amide hydrolase (FAAH). In addition, we recently cloned an isozyme termed "N-acylethanolamine-hydrolyzing acid amidase (NAAA)", which is active only at acidic pH [Tsuboi, Sun, Okamoto, Araki, Tonai, Ueda, J. Biol. Chem. 285 (2005) 11082-11092]. However, physiological roles of NAAA remained unclear. Here, we examined a possible contribution of NAAA to the degradation of various N-acylethanolamines in macrophage cells. NAAA mRNA as well as FAAH mRNA was detected in several macrophage-like cells, including RAW264.7, and mouse peritoneal macrophages. The homogenates of RAW264.7 cells showed both the NAAA and FAAH activities which were confirmed with the aid of their respective specific inhibitors, N-cyclohexanecarbonylpentadecylamine (CCP) and URB597. As analyzed with intact cells, RAW264.7 cells and peritoneal macrophages degraded anandamide, N-palmitoylethanolamine, N-oleoylethanolamine, and N-stearoylethanolamine. Pretreatment of the cells with CCP or URB597 partially inhibited the degradation, and a combination of the two compounds caused more profound inhibition. In contrast, the anandamide hydrolysis in mouse brain appeared to be principally attributable to FAAH despite the expression of NAAA in the brain. These results suggested that NAAA and FAAH cooperatively degraded various N-acylethanolamines in macrophages.     

Molecular characterization of N-acylethanolamine-hydrolyzing acid amidase, a novel member of the choloylglycine hydrolase family with structural and functional similarity to acid ceramidase

Bioactive N-acylethanolamines, including anandamide (an endocannabinoid) and N-palmitoylethanolamine (an anti-inflammatory and neuroprotective substance), are hydrolyzed to fatty acids and ethanolamine by fatty acid amide hydrolase. Moreover, we found another amidohydrolase catalyzing the same reaction only at acidic pH, and we purified it from rat lung (Ueda, N., Yamanaka, K., and Yamamoto, S. (2001) J. Biol. Chem. 276, 35552-35557). Here we report complementary DNA cloning and functional expression of the enzyme termed "N-acylethanolamine-hydrolyzing acid amidase (NAAA)" from human, rat, and mouse. The deduced primary structures revealed that NAAA had no homology to fatty acid amide hydrolase but belonged to the choloylglycine hydrolase family. Human NAAA was essentially identical to a gene product that had been noted to resemble acid ceramidase but lacked ceramide hydrolyzing activity. The recombinant human NAAA overexpressed in HEK293 cells hydrolyzed various N-acylethanolamines with N-palmitoylethanolamine as the most reactive substrate. Most interestingly, a very low ceramide hydrolyzing activity was also detected with NAAA, and N-lauroylethanolamine hydrolyzing activity was observed with acid ceramidase. By the use of tunicamycin and endoglycosidase, NAAA was found to be a glycoprotein. Furthermore, the enzyme was proteolytically processed to a shorter form at pH 4.5 but not at pH 7.4. Expression analysis of a green fluorescent protein-NAAA fusion protein showed a lysosome-like distribution in HEK293 cells. The organ distribution of the messenger RNA in rats revealed its wide distribution with the highest expression in lung. These results demonstrated that NAAA is a novel N-acylethanolamine-hydrolyzing enzyme that shows structural and functional similarity to acid ceramidase.     

Proteolytic processing of the alpha-chain of the lysosomal enzyme, beta-hexosaminidase, in normal human fibroblasts

The two subunits of beta-hexosaminidase undergo many post-translational modifications characteristic of lysosomal proteins, including limited proteolysis. To identify proteolytic cleavage sites in the alpha-chain, we have biosynthetically radiolabeled the transient forms, isolated these by immunoprecipitation, gel electrophoresis, and electroelution, and subjected them to automated Edman degradation. The position of the NH2-terminal amino acid was inferred from the elution cycle of the radioactive amino acid and the primary sequence encoded in the alpha-chain cDNA. The amino terminus of the precursor obtained by in vitro translation of SP6 alpha-chain mRNA in the presence of microsomes was leucine 23. The same amino terminus was found in precursor alpha-chain synthesized by normal human fibroblasts (IMR90) in a 1- or 3-h pulse or secreted by these cells in the presence of NH4Cl. The alpha-chain isolated after a 3-h pulse followed by a 5-h chase (intermediate form) included a mixture of molecular species of which the amino terminus was arginine 87 (most abundant), histidine 88, or leucine 90. After a 20-h chase (mature form) the latter species predominated. This mature form of the alpha-chain remained fully reactive with antibody raised against the carboxyl-terminal 15 amino acids, indicating little if any proteolysis at the carboxyl terminus. Thus synthesis and maturation of the alpha-chain of beta-hexosaminidase includes two major proteolytic cleavages: the first, between alanine 22 and leucine 23, removes the signal peptide to generate the precursor form, whereas the second occurs between the dibasic amino acids, lysine 86 and arginine 87. The second cleavage is followed by trimming of 3 additional amino acids to give the mature form of the alpha-chain.     

Proteolytic processing of the beta-subunit of the lysosomal enzyme, beta-hexosaminidase, in normal human fibroblasts

We have characterized the proteolytic processing of the beta-subunit of beta-hexosaminidase by identifying the amino termini of the various forms synthesized in cell-free translation and in cultured human fibroblasts. The procedures used had been developed for similar studies of the alpha-subunit (Little, L. E., Lau, M. M. H., Quon, D. V. K., Fowler, A. V., and Neufeld, E. F. (1988) J. Biol. Chem. 263, 4288-4292). Radioactive amino acids were incorporated biosynthetically into the different forms of the beta-subunit, which were isolated by immunoprecipitation, gel electrophoresis, and electroelution, and analyzed by automated Edman degradation. Translation by reticulocyte lysate in the presence of canine pancreas microsomes gave a product with alanine 43 at the amino terminus. The lysate could initiate translation at methionine 1 or methionine 13, depending on the SP6 mRNA provided. The product of signal peptidase action, the precursor form of the beta-subunit with amino-terminal alanine 43, was found in NH4+-induced secretions of cultured fibroblasts; intracellularly, this form was trimmed of two additional amino acids. The mature form was found to consist of three polypeptides joined by disulfide bonds; the amino termini were found to be valine 48, threonine 122, and lysine 315. Thus, in contrast to the alpha-subunit, the mature form of the beta-subunit of beta-hexosaminidase is derived from the precursor by internal proteolytic nicking rather than by removal of a large amino-terminal peptide segment.     

Proteolytic activation of a galactosyl transferase involved in osmotic regulation

Osmotic regulation in the flagellate Ochromonas malhamensis Pringsheim is mainly mediated by changes in the pool size of α-galactosyl-(1 → 1)-glycerol (isofloridoside). Isofloridoside phosphate synthase, a regulated key enzyme responsible for the formation of isofloridoside phosphate, appears to exist as an inactive proenzyme which can be activated by incubation of crude cell extracts with endogenous or exogenous proteases.     

Parallel inhibition of neutrophil arachidonic acid metabolism and lysosomal enzyme secretion by nordihydroguaiaretic acid

Arachidonic acid at concentrations from 0.2 to 2.0 × 10?⁶M induces the secretion of lysosomal enzymes from cytochalasin B-treated rabbit neutrophils. These concentrations of arachidonic acid are metabolized primarily to hydroxyeicosatetraenic acids rather than to cyclooxygenase products. A good correlation is observed between the extent of arachidonic acid metabolism and the secretion of lysosomal enzymes. Nordihydroguaiaretic acid (1?10μM) inhibits both lysosomal enzyme secretion and the production of lipoxygenase products by neutrophils.     

Human acid ceramidase: processing, glycosylation, and lysosomal targeting.

The biosynthesis of human acid ceramidase (hAC) starts with the expression of a single precursor polypeptide of approximately 53-55 kDa, which is subsequently processed to the mature, heterodimeric enzyme (40 + 13 kDa) in the endosomes/lysosomes. Secretion of hAC by either fibroblasts or acid ceramidase cDNA-transfected COS cells is extraordinarily low. Both lysosomal targeting and endocytosis critically depend on a functional mannose 6-phosphate receptor as judged by the following criteria: (i) hAC-precursor secretion by NH(4)Cl-treated fibroblasts and I-cell disease fibroblasts, (ii) inhibition of the formation of mature heterodimeric hAC in NH(4)Cl-treated fibroblasts or in I-cell disease fibroblasts, and (iii) blocked endocytosis of hAC precursor by mannose 6-phosphate receptor-deficient fibroblasts or the addition of mannose 6-phosphate. The influence of the six individual potential N-glycosylation sites of human acid ceramidase on targeting, processing, and catalytic activity was determined by site-directed mutagenesis. Five glycosylation sites (sites 1-5 from the N terminus) are used. The elimination of sites 2, 4, and 6 has no influence on lysosomal processing or enzymatic activity of recombinant ceramidase. The removal of sites 1, 3, and 5 inhibits the formation of the heterodimeric enzyme form. None of the mutant ceramidases gave rise to an increased rate of secretion, suggesting that lysosomal targeting does not depend on one single carbohydrate chain.     

Analysis of the glycosylation and phosphorylation of the lysosomal enzyme, beta-hexosaminidase B, by site-directed mutagenesis

Lysosomal enzymes require a mannose 6-phosphate recognition marker, constructed on asparagine-linked oligosaccharide chains, for targeting to lysosomes. We have identified the glycosylation sites of human beta-hexosaminidase B and have determined the influence of individual oligosaccharides on the phosphorylation, lysosomal targeting, and catalytic activity of the enzyme. The five potential glycosylation sites of the hexosaminidase beta-chain were modified individually by site-directed mutagenesis, and the constructs were expressed in COS 1 cells. By this analysis, we determined that four of the five potential sites were glycosylated. Two of the four oligosaccharides were preferentially phosphorylated. The absence of these two preferentially phosphorylated oligosaccharides resulted in greatly reduced amounts of the lysosomal form of the enzyme with increased secretion into the medium. The catalytic activity of beta-hexosaminidase B was not significantly altered by the absence of individual oligosaccharides suggesting the folding and assembly of the enzyme was not disrupted.     

Inhibition of fatty acid amidohydrolase, the enzyme responsible for the metabolism of the endocannabinoid anandamide, by analogues of arachidonoyl-serotonin

Arachidonoyl-serotonin inhibits in a mixed-type manner the metabolism of the endocannabinoid anandamide by the enzyme fatty acid amidohydrolase. In the present study, compounds related to arachidonoyl-serotonin have been synthesised and investigated for their ability to inhibit anandamide hydrolysis by this enzyme in rat brain homogenates. Removal of the 5-hydroxy from the serotonin head group of arachidonoyl-serotonin produced a compound (N-arachidonoyltryptamine) that was a 2.3-fold weaker inhibitor of anandamide hydrolysis, but which also produced its inhibition by a mixed-type manner (Ki(slope) 1.3 microM; Ki(intercept) 44 microM). Replacement of the amide linkage in this compound by an ester group further reduced the potency. In contrast, replacement of the arachidonoyl side chain by a linolenoyl side chain did not affect the observed potency. N-(Fur-3-ylmethyl) arachidonamide (UCM707), N-(fur-3-ylmethyl)linolenamide and N-(fur-3-ylmethyl)oleamide inhibited anandamide hydrolysis with pI50 values of 4.53, 5.36 and 5.25, respectively. The linolenamide derivative was also found to be a mixed-type inhibitor. It is concluded that the 5-hydroxy group of arachidonoyl-serotonin contributes to, but is not essential for, inhibitory potency at fatty acid amidohydrolase.     

Pathways involved in targeting and secretion of a lysosomal enzyme in Dictyostelium discoideum

In Dictyostelium discoideum, the lysosomal enzyme alpha-mannosidase is first synthesized as an N-glycosylated precursor of Mr 140,000. After a 20-30-min lag period, up to 30% of the precursor molecules are rapidly secreted, whereas the rest remain cellular and are proteolytically processed (t 1/2 = 8 min) to mature subunits of Mr 58,000 and 60,000. The secreted precursor is modified more extensively than the cellular form, as is revealed by differences in size, charge, and sensitivity to endoglycosidase H. Subcellular fractionation has shown that, following synthesis in the rough endoplasmic reticulum, the precursor is transported to a low density membrane fraction that contains Golgi membranes. Proteolytic processing takes place in these vesicles, since newly cleaved mature enzyme, but no precursor, co-fractionates with lysosomes. Under conditions that disrupt vesicular membranes, the precursor remains associated with the membrane fraction, whereas the newly processed mature enzyme is soluble. Proteolytic cleavage of the precursor thus coincides with the release of the mature enzyme into the lumen of a lysosomal compartment. These findings suggest a possible mechanism for lysosomal targeting that involves the specific association of enzyme precursors with Golgi membranes.     

Processing, transport, and secretion of the lysosomal enzyme acid phosphatase in Dictyostelium discoideum

To explain the different secretion kinetics of lysosomal enzymes in Dictyostelium discoideum, previous investigators have hypothesized the existence of a heterogeneous population of lysosomes containing either the enzyme acid phosphatase or other hydrolase enzymes. This proposal predicts that at least two targeting mechanisms exist for lysosomal enzymes in this organism. To begin to investigate this possibility, the transport, processing, and targeting of acid phosphatase was studied by using a combination of radiolabel pulse-chase procedures, subcellular fractionations, and indirect immunofluorescence microscopy. Acid phosphatase was initially synthesized in axenically growing cells as a 56-kDa precursor polypeptide that was proteolytically processed after 20 min to a 55-kDa mature protein. This enzyme was rapidly transported from the endoplasmic reticulum to Golgi complex (halftime of 3 min) as measured by the acquisition of resistance to the enzyme endoglycosidase H. Furthermore, Percoll gradient fractionations indicated that radiolabeled forms of acid phosphatase reached dense lysosomal vesicles at about the same time as final processing was occurring. Proper sorting of acid phosphatase in D. discoideum apparently was not critically dependent on low intravacuolar pH since the addition of ammonium chloride did not stimulate the missorting and secretion of acid phosphatase. These results are very similar to previous observations concerning other Dictyostelium lysosomal enzymes. Consistent with the existence of a heterogeneus population of lysosomes, the percentage of radiolabeled acid phosphatase secreted 4 h into a chase period was 15-fold lower as compared with another lysosomal enzyme, beta-glucosidase. However, acid phosphatase, alpha-mannosidase, and beta-glucosidase were all predominantly colocalized as determined by indirect immunofluorescence, which for the first time demonstrates the homogeneous nature of the lysosomal system in D. discoideum. Taken together these results suggest that the processing and transport of acid phosphatase may be similar in nature to the glycosidases. However, the different kinetics of secretion of acid phosphatase versus the colocalized glycosidase enzymes suggests that an undefined mechanism operates to distinguish these classes of enzymes at a step after localization to lysosomes but prior to secretion.     

Analysis of the glycosylation and phosphorylation of the alpha-subunit of the lysosomal enzyme, beta-hexosaminidase A, by site-directed mutagenesis.

The glycosylation and subsequent phosphorylation of mannose residues is a pivotal modification during the biosynthesis of lysosomal enzymes. We have identified the sites of N-linked glycosylation and oligosaccharide phosphorylation on the alpha-subunit of beta-hexosaminidase and have determined the influence of the oligosaccharides on the folding and transport of the enzyme. The potential glycosylation sequences, either singly or in combination, were eliminated through site-directed mutagenesis of the cDNA. By expression of the mutant cDNAs in COS-1 cells, each of the three glycosylation sites on the alpha-subunit was found to be modified by an oligosaccharide. One of the three oligosaccharides was the preferred site of phosphorylation. The absence of any individual oligosaccharide did not diminish the expression of the catalytic activity associated with the alpha-chain, implying proper folding and assembly of subunits. A profound effect was observed, however, when all three oligosaccharides were absent. The unglycosylated alpha-subunit, resulting from genetic alteration of all three glycosylation sites or synthesis of the wild-type protein in the presence of tunicamycin, was catalytically inactive. It was found to be improperly folded into an insoluble aggregate, linked through inappropriate disulfide bonds. The unglycosylated protein was trapped in the lumen of the endoplasmic reticulum and was found in a complex with the Ig heavy chain-binding protein, BiP. The properties of the nonglycosylated, misfolded alpha-subunit were similar to some mutant alpha-subunits in Tay-Sachs disease patients. The results indicate that the oligosaccharides are essential, although not in a site-specific manner, for proper folding and cellular transport of the alpha-subunit.     

Initial events involved in the synthesis of the lysosomal enzyme alpha-mannosidase in Dictyostelium discoideum

In Dictyostelium discoideum the lysosomal enzyme alpha-mannosidase is initially synthesized in vivo as a 140,000 Mr protein which is subsequently processed into two mature acidic glycoproteins of 60,000 and 58,000 Mr. To investigate the initial events involved in the synthesis of this protein, mRNA isolated from growing cells was translated in vitro and the resulting protein products were immunoprecipitated with antibodies prepared against the purified enzyme. Messenger RNA prepared from membrane-bound but not free polysomes directed the synthesis of an immunoprecipitable 120K protein that was identified as the alpha-mannosidase primary translation product by a variety of criteria. Translation in vitro in the presence of dog pancreas microsomes resulted in the conversion of the 120K primary translation product to a 140K form. This 140K species was not accessible to added trypsin under conditions preserving membrane integrity, suggesting it is sequestered in the lumen of the endoplasmic reticulum following synthesis. Treatment of either the in vitro modified or cellular 140K alpha-mannosidase precursors with endoglycosidase H resulted in the appearance of proteins 2K larger than the primary translation product. The pulse-labeled cellular precursor and the in vitro processed form have similar isoelectric points as revealed by two-dimensional gel electrophoresis. These results imply that the precursor is N-glycosylated in the endoplasmic reticulum possibly without removal of the signal sequence and that the majority of acidic modifications are added late in the post-translational pathway.     

Cytoplasmic enzyme activities involved in energy and amino acid metabolism in pathological human renal cortex

Enzyme levels of lactate dehydrogenase (LDH), alpha-hydroxybutyrate dehydrogenase (HBDH), aspartate aminotransferase (AST) and alanine aminotransferase (ALT) were measured in the cytosol of renal cortex samples from either normal and pathologic kidney tissue. The mean enzyme activity values, expressed in Units per gram of cytosolic protein decreased in the following order: normal cortex (LDH = 4,299 +/- 654; AST = 522 +/- 101; ALT = 197 +/- 44). chronic pyelonephritis (LDH = 2,360 +/- 876; AST = 297 +/- 117; ALT = 90 +/- 48), hydronephrosis (LDH = 2,208 +/- 1,264; AST = 279 +/- 165; ALT = 82 +/- 61), pyonephrosis (LDH = 1,410 +/- 596; AST = 158 +/- 69; ALT = 23.4 +/- 16.4) and renal tuberculosis (LDH = 1,149 +/- 481; AST = 93 +/- 34; ALT = 5.6 +/- 2.8). The decrease in the enzyme activities paralleled tissue damage and it was shown to affect cellular functionality in relation with energy and amino acid metabolism.     

A novel amidase (half-amidase) for half-amide hydrolysis involved in the bacterial metabolism of cyclic imides

A novel amidase involved in bacterial cyclic imide metabolism was purified from Blastobacter sp. strain A17p-4. The enzyme physiologically functions in the second step of cyclic imide degradation, i.e., the hydrolysis of monoamidated dicarboxylates (half-amides) to dicarboxylates and ammonia. Enzyme production was enhanced by cyclic imides such as succinimide and glutarimide but not by amide compounds which are conventional substrates and inducers of known amidases. The purified amidase showed high catalytic efficiency toward half-amides such as succinamic acid (K(m) = 6.2 mM; k(cat) = 5.76 s(-1)) and glutaramic acid (K(m) = 2.8 mM; k(cat) = 2.23 s(-1)). However, the substrates of known amidases such as short-chain (C(2) to C(4)) aliphatic amides, long-chain (above C(16)) aliphatic amides, amino acid amides, aliphatic diamides, alpha-keto acid amides, N-carbamoyl amino acids, and aliphatic ureides were not substrates for the enzyme. Based on its high specificity toward half-amides, the enzyme was named half-amidase. This half-amidase exists as a monomer with an M(r) of 48,000 and was strongly inhibited by heavy metal ions and sulfhydryl reagents.     

Proteomic analysis of lysosomal acid hydrolases secreted by osteoclasts: implications for lytic enzyme transport and bone metabolism

Osteoclasts, the bone-digesting cells, are polarized cells that secrete acid hydrolases into a resorption lacuna where bone degradation takes place. The molecular mechanisms underlying this process are poorly understood. To analyze the nature of acid hydrolases secreted by osteoclasts, we used the mouse myeloid Raw 264.7 cell line that differentiates in vitro into mature osteoclasts in the presence of the receptor activator of NF-kappaB ligand. Upon differentiation, we observed a strong increase in the secretion of mannose 6-phosphate-containing acid hydrolases. A proteomic analysis of the secreted proteins captured on a mannose 6-phosphate receptor affinity column revealed 58 different proteins belonging to several families of acid hydrolases of which 16 are clearly involved in bone homeostasis. Moreover these acid hydrolases were secreted as proproteins. The expression of most of the identified acid hydrolases is unchanged during osteoclastogenesis. Thus, our data strongly support the notion that the polarized secretion of acid hydrolases by osteoclasts results from a reorganization of key steps of membrane traffic along the lysosomal pathway rather than from a fusion of lysosomes with the membrane facing the resorption lacuna.