Immunocytochemical localization of sphingolipid activator protein 2 (SAP-2) in normal and SAP-deficient fibroblasts

The intracellular localization of sphingolipid activator protein 2 (SAP-2) was determined immunocytochemically using an antiserum raised against a SAP-2 preparation from Gaucher spleen. The immunolabeling indicated that SAP-2 was largely localized in the lysosomes of fibroblasts from normal individuals. In some lysosomes the labeling was greatest around the perimeter of the matrix, suggesting an association between the activator and lysosomal membrane components. The labeling technique was also applied to fibroblasts from a patient with a unique sphingolipid storage disorder. Consistent with immunoblotting studies on electrophoretograms, both the patient and his affected fetal sibling were found to be deficient in immunoreactive SAP-2.     

Acid beta-glucosidase: enzymology and molecular biology of Gaucher disease

Human lysosomal beta-glucosidase (D-glucosyl-acylsphingosine glucohydrolase, EC 3.2.1.45) is a membrane-associated enzyme that cleaves the beta-glucosidic linkage of glucosylceramide (glucocerebroside), its natural substrate, as well as synthetic beta-glucosides. Experiments with cultured cells suggest that in vivo this glycoprotein requires interaction with negatively charged lipids and a small acidic protein, SAP-2, for optimal glucosylceramide hydrolytic rates. In vitro, detergents (Triton X-100 or bile acids) or negatively charged ganglioside or phospholipids and one of several "activator proteins" increase hydrolytic rate of lipid and water-soluble substrates. Using such in vitro assay systems and active site-directed covalent inhibitors, kinetic and structural properties of the active site have been elucidated. The defective activity of this enzyme leads to the variants of Gaucher disease, the most prevalent lysosomal storage disease. The nonneuronopathic (type 1) and neuronopathic (types 2 and 3) variants of this inherited (autosomal recessive) disease but panethnic, but type 1 is most prevalent in the Ashkenazi Jewish population. Several missense mutations, identified in the structural gene for lysosomal beta-glucosidase from Gaucher disease patients, are presumably casual to the specifically altered posttranslational oligosaccharide processing or stability of the enzyme as well as the altered in vitro kinetic properties of the residual enzyme from patient tissues.     

Acid β-Glucosidase: Enzymology and Molecular Biology of Gaucher Diseas

Abstract

Human lysosomal β-glucosidase (D-glucosyl-acylsphingo-sine glucohydrolase, EC 3.2.1.45) is a membrane-associated enzyme that cleaves the β-glucosidic linkage of glucosylcer-amide (glucocerebroside), its natural substrate, as well as synthetic β-glumsides. Experiments with cultured cells suggest that in vivo this glycoprotein requires interaction with negatively charged lipids and a small acidic protein, SAP-2, for optimal glucosylceramide hydrolytic rates. In vitro, detergents (Triton? X-100 or bile acids) or negatively charged gangliosides or phos-pholipids and one of several “activator proteins” increase hydrolytic rate of lipid and water-soluble substrates. Using such in vitro assay systems and active site-directed covalent inhibitors, kinetic and structural properties of the active site have been elucidated. The defective activity of this enzyme leads to the variants of Gaucher disease, the most prevalent lysosomal storage disease. The nonneuronopathic (type 1) and neuronopathic (types 2 and 3) variants of this inherited (autosomal recessive) disease but panethnic, but type 1 is most prevalent in the Ashkenazi Jewish population. Several missense mutations, identified in the structural gene for lysosomal β-glucosidase from Gaucher disease patients, are presumably casual to the specifically altered post-translational oligosaccharide processing or stability of the enzyme as well as the alterecA in vitro kinetic properties of the residual enzyme from patient tissues.     

Simultaneous deficiency of sphingolipid activator proteins 1 and 2 is caused by a mutation in the initiation codon of their common gene.

Sphingolipid activator proteins (SAPs) are small, nonenzymic glycoproteins that stimulate lysosomal degradation of various sphingolipids. SAP-1, SAP-2, and two additional potential activator proteins are derived from a common precursor by proteolytic processing. A severe case of sphingolipid storage disease that led to death within 16 weeks was attributed to a possible total deficiency of the SAPs generated by this gene (Harzer, K., Paton, B. C., Poulos, A., Kustermann-Kuhn, B., Roggendorf, W., Grisar, T., and Popp, M. (1989) Eur. J. Pediatr. 149, 31-39). Analysis of the SAP precursor cDNA from the patient and his fetal sibling showed an A to T transversion in the initiation codon. Allele-specific oligonucleotide hybridization revealed that both parents are heterozygous carriers for this mutation. In pulse-chase experiments using antisera raised against SAP-1 or SAP-2, no cross-reacting material could be detected in the patients' fibroblasts.     

Detection of a point mutation in sphingolipid activator protein-1 mRNA in patients with a variant form of metachromatic leukodystrophy

The lysosomal degradation of sulfatide requires the specific enzyme, arylsulfatase A, as well as a heat stable protein called sphingolipid activator protein-1 (SAP-1). While most patients with metachromatic leukodystrophy have defects in arylsulfatase A, some patients have defects in SAP-1. SAP-1 is coded for by a gene on human chromosome 10 that also codes for three other proposed SAP. Examination of the cDNA from two siblings with SAP-1 deficiency revealed a point mutation of nucleotide #650 (counting from the initiation ATG) which is in the SAP-1 coding domain. This C to T transition changed the codon from threonine (ACC) to one coding for isoleucine (ATC). This eliminated the only glycosylation site in mature SAP-1 and could explain the findings made at the protein level.     

Correction of sulfatide metabolism after transfer of prosaposin cDNA to cultured cells from a patient with SAP-1 deficiency.

The lysosomal removal of the sulfate moiety from sulfatide requires the action of two proteins, arylsulfatase A and sphingolipid activator protein-1 (SAP-1). Recently, patients have been identified who have a variant form of metachromatic leukodystrophy which is characterized by mutations in the gene coding for SAP-1, which is also called "prosaposin." All of the mutations characterized in these patients result in (a) deficient mature SAP-1, as determined by immunoblotting after SDS-PAGE of tissue and cell extracts, and (b) decreased ability of cultured skin fibroblasts to metabolize endocytosed [14C]-sulfatide. We now report the insertion of the full-length prosaposin cDNA into the Moloney murine leukemia virus-derived retroviral vector, pLJ, and the infection of cultured skin fibroblasts from a newly diagnosed and molecularly characterized patient with SAP-1 deficiency. The cultured cells infected with the prosaposin cDNA construct now show both production of normal levels of mature SAP-1 and completely normal metabolism of endocytosed [14C]-sulfatide. These studies demonstrate that the virally transferred prosaposin cDNA is processed normally and is localized within lysosomes, where it is needed for interaction between sulfatide and arylsulfatase A. In addition, normal as well as mutant sequences can now be found by allele-specific oligonucleotide hybridization of PCR-amplified genomic DNA by using exonic sequences as primers.     

Immunocytochemical localization of sphingolipid activator protein-1, the sulfatide/GM1 ganglioside activator, to lysosomes in human liver and colon

Sphingolipid activator proteins (SAP) stimulate the enzymatic hydrolysis of sphingolipids. The results of biochemical studies have suggested that SAP are located within lysosomes. In this study we sought immunocytochemical verification of the lysosomal location of SAP-1, a SAP that stimulates the hydrolysis of sulfatide and GM1 ganglioside. We stained adjacent sections of normal adult liver and colon for either SAP-1, by peroxidase-labeled antibodies, or acid phosphatase, by enzyme histochemistry. At the light microscopic level, SAP-1 and acid phosphatase were present in similar cells of the colonic lamina propria and hepatic sinusoids, and in similar supranuclear sites of colonic epithelial cells. By electron microscopy, SAP-1 was present in vesicular structures morphologically similar to those containing acid phosphatase. Thus, SAP-1 is present in lysosomes of several different kinds of cells in the normal human liver and colon.     

Immunocytochemical localization of sphingolipid activator protein-1, the sulfatide/GM1 ganglioside activator,to lysosomes in human liver and colon

Summary Sphingolipid activator proteins (SAP) stimulate the enzymatic hydrolysis of sphingolipids. The results of biochemical studies have suggested that SAP are located within lysosomes. In this study we sought immunocytochemical verification of the lysosomal location of SAP-1, a SAP that stimulates the hydrolysis of sulfatide and G_M1 ganglioside. We stained adjacent sections of normal adult liver and colon for either SAP-1, by peroxidase-labeled antibodies, or acid phosphatase, by enzyme histochemistry. At the light microscopic level, SAP-1 and acid phosphatase were present in similar cells of the colonic lamina propria and hepatic sinusoids, and in similar supranuclear sites of colonic epithelial cells. By electron microscopy, SAP-1 was present in vesicular structures morphologically similar to those containing acid phosphatase. Thus, SAP-1 is present in lysosomes of several different kinds of cells in the normal human liver and colon.     

Synthesis of surfactant-associated protein, 35,000 daltons, in fetal lung

The major human pulmonary surfactant-associated protein of 35,000 daltons (Da) (SAP-35), consists of a group of related proteins of 27,000-36,000 Da, with isoelectric points ranging from pH 4.6 to 5.2. SAP-35 precursors were identified by immunoprecipitation of protein products of in vitro translation of normal adult human poly(A)+ mRNA with human SAP-35 antiserum. The translation products nearly comigrated with the most basic components of alveolar SAP-35 (mol mass = 24,500-27,000 Da). Processing of the primary translation products by canine pancreatic microsomal membranes increased their apparent molecular weight to 29,000-30,000-Da forms, which were sensitive to endoglycosidase F, suggesting the addition of asparagine-linked oligosaccharides to the molecules. A smaller protein of 24,500 Da was generated during treatment with canine microsomal membranes likely representing cleavage of a signal peptide. SAP-35 was not detected in explants of [35S]methionine-labeled fetal lung (20-24 wk gestation) after 1 day of culture or immunoprecipitates of in vitro translated poly(A)+ mRNA isolated from fetal human lung. However, after 3-5 days of organ culture, synthesis of SAP-35 was readily detected by immunoprecipitation of [35S] methionine-labeled tissue. Fully sialylated (neuraminidase-sensitive forms) comigrated with fully glycosylated SAP-35 isolated from human surfactant. High mannose (endoglycosidase H-sensitive precursors) were also synthesized by the organ cultures and were distinct from the secreted form in surfactant. Synthesis of surfactant-associated SAP-35 and its precursors was induced in association with morphological maturation of the type II epithelial cell during organ culture of human fetal lung.     

Heterogeneity in human acid beta-glucosidase revealed by cellulose-acetate electrophoresis

Cellulose-acetate gel electrophoresis, a technique commonly used for the separation of human acid hydrolases, was applied to study heterogeneity in acid beta-glucosidase (EC 3.2.1.45). With this technique, three forms of beta-glucosidase were distinguishable in extracts of several tissues. The most anodic beta-glucosidase activity (band 3) represents the broad-specificity beta-glucosidase that is not deficient in Gaucher disease and is not inhibited by conduritol B-epoxide (CBE). The beta-glucosidase activity was deficient in Gaucher disease. A third beta-glucosidase activity with an intermediate mobility (band 2) was also inhibited by CBE and deficient in Gaucher disease. Band 1 and band 2 beta-glucosidase thus represent different forms of glucocerebrosidase. By adding phosphatidylserine and sphingolipid activator protein (SAP-2), monomeric glucocerebrosidase could be completely converted into a form that comigrated with band 2 beta-glucosidase of tissue extracts. The addition of phosphatidylserine only also resulted in a changed mobility of the monomeric enzyme, but the migration in this case differed from that of band 2 beta-glucosidase of tissue extracts. The electrophoretic profile of beta-glucosidase activity of tissue extracts changed upon ethanol/chloroform extraction: the two glucocerebrosidase forms were converted into a band with a mobility identical to that of band 1 beta-glucosidase. Our findings indicate that the interaction of glucocerebrosidase with phospholipid and SAP-2 has major effects on the mobility of the enzyme in the cellulose-acetate gel electrophoresis system. The findings with the cellulose-acetate gel electrophoretic system are discussed in relation to the heterogeneity in glucocerebrosidase observed with sucrose density gradient analysis, immunochemical methods and isoelectric focussing studies.     

Synthesis and processing of sphingolipid activator protein-2 (SAP-2) in cultured human fibroblasts

Sphingolipid activator proteins (SAP) are relatively small molecular weight proteins that stimulate the enzymatic hydrolysis of sphingolipids in the presence of specific lysosomal hydrolases. SAP-2 has previously been demonstrated to activate the hydrolysis of glucosylceramide, galactosylceramide, and, possibly, sphingomyelin. Using monospecific rabbit antibodies against human spleen SAP-2, the synthesis and processing of SAP-2 were studied in cultured human fibroblasts. When [35S]methionine was presented in the medium to control human cells for 4 h, five major areas of radiolabeling were found. These had apparent molecular weights of 73,000, 68,000, 50,000, 12,000, and 9,000. Further studies indicated that the major extracellular product in normal cells given NH4Cl along with the [35S]methionine and in medium from cultures from patients with I cell disease had an apparent molecular weight of 73,000. The Mr = 68,000 and 73,000 species can be converted to a species with an apparent molecular weight of 50,000 by the action of endoglycosidase F. After labeling cells for 1 h followed by a 1-h chase, the Mr = 12,000 and 9,000 species appear. Treatment of the immunoprecipitated mixture with endoglycosidase F resulted in conversion of these species to one band with an apparent molecular weight of 7,600. These studies indicate that this relatively low molecular weight protein is rapidly synthesized from a relatively large molecular weight highly glycosylated precursor.     

Structure of the lysosomal sphingolipid activator protein 1 by homology with influenza virus neuraminidase

The sphingolipid activator protein 1 (SAP-1) increases the rate of hydrolysis of sphingolipids in the lysosome by apparently bringing together the substrate and the corresponding hydrolytic enzyme. This implies specific recognition of both the substrate and enzyme by SAP-1. However, binding domains in SAP-1 and recognition mechanisms involved are unknown. Amino acid sequence comparison of SAP-1 with influenza virus neuraminidase (EC 3.2.1.18, FLU NA) indicates that functional amino acid residues in or near the sialic acid binding site of FLU NA are also found at equivalent positions in the first 48 N-terminal amino acids of SAP-1. This region of homology allows to propose folding of the SAP-1 polypeptide chain by comparison with known crystallographic structure of FLU NA and identify a potential domain for lysosomal enzyme recognition through sialic acid binding. There is also a region of 10 amino acid residues near the C-terminal end of SAP-1 which has a strong propensity to form an alpha-helix with amphiphilic properties of lipid-binding helices. This domain in SAP-1 is probably responsible for the lipid(substrate)-binding function of SAP-1.     

The fate of glucosylceramide (glucocerebroside) in genetically impaired (lysosomal beta-glucosidase deficient) Gaucher disease diploid human fibroblasts

Diploid human infant skin fibroblasts cultured from normal infants and Gaucher disease infants, with genetically defective lysosomal glucosylceramide:beta-glucohydrolase activity, had a full range of homologous glycosphingolipids from the simplest (glucosylceramide) to higher neutral derivatives (lactosyl-, trihexosyl- and tetrahexosylceramide) and anionic sialo derivatives (gangliosides) (sialosyllactosyl-, disialosyllactosyl-, sialosylgangliotriaosyl-, and mono- and disialosylgangliotetraosylceramide). Although excessive storage of glucosylceramide in histiocytes is pathognomonic for Gaucher disease, we found that Gaucher disease fibroblasts contained 1.23 +/- 0.08 nmol of glucosylceramide/mg cell protein; normal infant cells, 1.11 +/- 0.48. When we aged infantile Gaucher disease fibroblasts for 20 days beyond their confluency state, we found no increased accumulation of glucosylceramide, but a 1.5-2-fold increase in trihexosylceramide, sialosylgangliotetraosylceramide, and disialosyllactosylceramide. Gaucher disease fibroblasts took up and could not degrade but, instead, effectively converted pulse-chase 3-O-[3H]glucosylceramide supplied in the growth medium in liposomes into higher glycosphingolipids, especially the plasma membrane ganglioside, sialosyllactosylceramide. When grown with extracellular particulate [3H]glucosylceramide, infantile Gaucher fibroblasts localized it and higher labeled homologues in the plasma membrane; glucosylceramide did not accumulate in the lysosomes. These findings indicate that fibroblasts that are genetically deficient in lysosomal glucosylceramide:beta-glucosidase avoid pathological lysosomal accumulation by relegating undegradable glucosylceramide to an anabolic compartment where glucosylceramide is converted into more highly glycosylated glycosphingolipids.     

Gaucher disease

Although Gaucher disease is a rare disorder, recent developments in novel means for therapeutic intervention have invigorated both academic research and pharmaceutical industry discovery programmes. The common mutations found in the lysosomal enzyme deficient in Gaucher disease, beta-glucocerebrosidase, earmark these proteins for destruction by the endoplasmic reticulum-localised protein folding machinery, resulting in enzyme insufficiency, lysosomal glycolipid storage and subsequent pathology. However, many of these mutants can be rescued from global misfolding to preserve glycolipid substrate binding and eventual catalysis in the lysosome, by the addition of subinhibitory concentrations of pharmacologically active small molecules. This novel, chaperon-mediated approach has benefited from insights into the molecular understanding of beta-glucocerebrosidase structure, drug design and development in cellular models for disease.     

Immunochemical characterization of two activator proteins stimulating enzymic sphingomyelin degradation in vitro. Absence of one of them in a human Gaucher disease variant

Two nonenzymic activator proteins shown previously to strongly stimulate enzymic sphingomyelin degradation in vitro were purified from human Gaucher type 1 and control spleen. Activator A1 (molecular mass 6,500 Da) had affinity for ConA-Sepharose, while activator A2 (molecular mass 3,500 Da) did not. Monospecific antibodies to each activator protein were prepared in rabbits by immunization with protein purified from type 1 Gaucher spleen. A1 and A2 activators from Gaucher type 1 spleen were shown to be immunochemically identical to A1 and A2 activators from control spleen. However, A1 and A2 activators, whether isolated from Gaucher type 1 or control spleen, were shown to be distinct proteins. Immunochemical examination of all collected fractions during the purification revealed the existence of a third activator (molecular mass 6,000 Da), which was antigenically identical to A1 activator but had no affinity for ConA-Sepharose. The two forms of A1 activator showed similar mobility on immunoelectrophoresis differing from that of A2 activator. Fibroblast extracts from controls and patients with different variants of Gaucher disease were investigated using immunodiffusion against antisera to A1 or A2 activator. In contrast to normal and Gaucher (types 1, 2 and 3) cell extracts, those of a Gaucher patient with normal glucosylceramidase activity had no visible precipitin line towards the antiserum against the two forms of A1 activator. The lack of crossreacting material to antibodies against A1 activator was confirmed by radial immunodiffusion and rocket immunoelectrophoresis. A1 activator stimulated the basal glucosylceramidase activity 5-6 fold in fibroblasts from this patient, whereas the normal effect was only a 1.2-1.5-fold stimulation. The immunological results together with the biochemical data provide evidence for the lack of an activator protein in a variant form of human Gaucher disease for the first time.     

In vitro detergent activation of lysosomal acid beta-glucosidase in the spleen of normal and type 1 Gaucher patients is not accompanied by change in aggregation state

The genetic defect in Gaucher disease consists in a deficiency of a membrane-bound lysosomal acid beta-glucosidase. Using the radiation inactivation method, we have previously reported a subunit coupling of the mutated acid beta-glucosidase from Gaucher type 1 spleen in contrast to the normal one (Maret, A., Potier, M., Salvayre, R. and Douste-Blazy, L. (1983) FEBS Lett. 160, 93-97). We have used the same method to determine the effect of detergents on subunit coupling or uncoupling of acid beta-glucosidase in normal and Gaucher spleens. The hypothesis that detergent activation of beta-glucosidase could be due to subunit association or dissociation has been tested. The radiation inactivation size of beta-glucosidase in absence of detergent was 71,000 and 135,500 for normal and Gaucher spleen, respectively, whereas the corresponding values in presence of detergent were 84,000 and 169,000. The higher values obtained in the presence of detergent are incompatible with association or dissociation of subunits but correspond to the increase generally observed for proteins irradiated in the presence of Triton X-100.     

Characterization of SAP-1, a protein recruited by serum response factor to the c-fos serum response element.

We used a yeast genetic screen to isolate cDNAs that encode a protein, SRF accessory protein-1 (SAP-1), that is recruited to the c-fos serum response element (SRE) as part of a ternary complex that includes serum response factor (SRF). SAP-1 requires DNA-bound SRF for ternary complex formation and makes extensive DNA contacts to the 5' side of SRF, but does not bind DNA autonomously. Ternary complex formation by SAP-1 requires only the DNA-binding domain of SRF, which can be replaced by that of the related yeast protein MCM1. We isolated cDNAs encoding two forms of SAP-1 protein, SAP-1a and SAP-1b, which differ at their C termini. Both SAP-1 proteins contain three regions of striking homology with the elk-1 protein, including an N-terminal ets domain. Ternary complex formation by SAP-1 requires both the ets domain and a second conserved region 50 amino acids to its C-terminal side. SAP-1 has similar DNA binding properties to the previously characterized HeLa cell protein p62/TCF.