Yasuo Kishimoto

Saposin proteins: structure, function, and role in human lysosomal storage disorders.

Saposins are sphingolipid activator proteins, four of which are derived from a single precursor, prosaposin, by proteolytic processing. These small heat‐stable glycoproteins (12–14 kDa) are required for the lysosomal hydrolysis of a variety of sphingolipids. Characterization of these four activator proteins, two of which were recently discovered, and their importance in human health and disease are reviewed in this article.—OBrien, J. S.; Kishimoto, Y. Saposin proteins: structure, function, and role in human lysosomal storage disorders. FASEB J. 5: 301–308; 1991.

Identification of the neurotrophic factor sequence of prosaposin.

Prosaposin, recently identified as a neurotrophic factor (1), is die precursor of saposins A, B, C, and D. The neurotrophic activity of prosaposin resides in the saposin C domain. We have pinpointed the active sequence to a linear 12‐mer located in the NH2‐terminal sequence of saposin C (LIDNNKTEKEIL). Nanomolar concentrations of a 22‐mer peptide encompassing this region stimulated neurite outgrowth and choline acetyl‐ transferase activity, and prevented cell death in neuroblastoma cells. In primary cerebellar granule cells, the 22‐mer also stimulated neurite outgrowth. Studies of the neuroblastoma line NS20Y using a radiolabeled 18‐mer from the neurotrophic region identified a high‐affinity (Kd = 70 pM) binding site indicative of receptor‐ligand interaction. The 22‐mer stimulated protein phosphorylation of several proteins, some of which were tyrosine‐ phosphorylated after brief exposure similar to saposin C. Circular dichroism studies demonstrated that the 22‐mer was converted from a random to a helical structure by addition of ganglioside GM1. The results are consistent with receptor‐ligand binding by the peptide initiating a signal transduction cascade and resulting in neuronal differentiation.—OBrien, J. S., Carson, G. S., Seo, H‐C., Hiraiwa, M., Weiler, S., Tomich, J. M., Barranger, J. A., Kahn, M., Azuma, N., Kishimoto, Y. Identification of the neurotrophic factor sequence of prosaposin. FASEB J. 9, 681‐685 (1995)

Saposin D: A sphingomyelinase activator

Saposin D, a newly discovered heat-stable, 10 kDa glycoprotein, was isolated from Gaucher spleen and purified to homogeneity. Chemical sequencing from its amino terminus demonstrated colinearity between its amino acid sequence and the deduced amino acid sequence of the fourth domain of prosaposin, the precursor of saposin proteins. Saposin D specifically stimulates acid sphingomyelinase but has no significant effect on the other hydrolases tested.

Occurrence of prosaposin as a neuronal surface membrane component

Prosaposin is a precursor of four saposins that are required for the lysosomal hydrolysis of sphingolipids by specific hydrolases. Besides its precursor role, prosaposin also exists as a secreted protein. The present investigation reveals that prosaposin also exists as an integral component of the surface membranes of neuronal cells. Subcellular fractionation studies demonstrate that the membrane-bound prosaposin occurs specifically in plasma membranes of NS20Y rat neuroblastoma cells. An immunohistochemical study of the neuroblastoma cells using rat prosaposin-specific antibodies also showed that a portion of prosaposin is located on the surface of neurites as well as on cell bodies. Similar histochemical studies with antibodies that specifically recognize human prosaposin revealed the presence of prosaposin in dendrites, axons, and cell bodies of subcortical and spinal cord neurons in both human adult brain and in fetal brain (24-wk gestation). These findings suggest an important role of prosaposin in neuronal development.

Model SV40-transformed fibroblast lines for metabolic studies of human prosaposin and acid ceramidase deficiencies

Skin fibroblasts from patients with Farber disease (acid ceramidase deficiency) and from two siblings of the only known family affected with prosaposin deficiency were transformed by transfection with a plasmid carrying the SV40 large T antigen. The prosaposin-deficient transformed cell lines conserved their original metabolic defects, and in particular they were free of detectable immunoreactivity when using anti-saposin B and anti-saposin C antisera. Ultrastructurally, the cells contained heterogeneous lysosomal storage products. As found for their parental cell lines, the SV40-transformed fibroblasts exhibited deficient in vitro activities of lysosomal ceramidase and beta-galactosylceramidase, but a normal activity of acid sphingomyelinase. As observed for SV40-transformed fibroblasts from Farber disease, degradation of radioactive glucosylceramide or low density lipoprotein-associated radiolabelled sphingomyelin by the prosaposin-deficient cells in situ showed a clear impairment in the turnover of lysosomal ceramide. Ceramide storage in prosaposin-deficient cells was also demonstrated by ceramide mass determination. In contrast to acid ceramidase deficient cells, both the accumulation of ceramide and the reduced in vitro activity of acid ceramidase in cells from prosaposin deficiency could be corrected by addition of purified saposin D. The data confirm that prosaposin is required for lysosomal ceramide degradation, but not for sphingomyelin turnover. The SV40-transformed fibroblasts will be useful for pathophysiological studies on human prosaposin deficiency.

Bone marrow transplantation in canine GM1 gangliosidosis

Allogeneic bone marrow transplantation was carried out in an 81‐day‐old Portuguese water dog with GM1 gangliosidosis using a DLA identical sibling as donor. Engraftment was complete and β‐galactosidase activity in leukocytes of the transplanted dog were similar to those in the donor. Over the next 2.5 months neurological deterioration in the transplanted dog was similar to that in untreated dogs with GM1 gangliosidosis. Cerebral ganglioside GM1 concentrations were not diminished by bone marrow transplantation and cerebral β‐galactosidase activity was negligible. We conclude that allogeneic bone marrow transplantation early in life is ineffective in canine GM1 gangliosidosis.

Determination of saposin proteins (sphingolipid activator proteins) in human tissues.

Saposins are small glycoproteins which are required for sphingolipid hydrolysis by lysosomal hydrolases. Each saposin (A, B, C, and D) stimulates a different enzymatic activity. A new simple HPLC method to determine the levels of saposins A, C, and D in tissue was developed. Tissues were homogenized in 20 vol of water, boiled, and centrifuged. The supernatant was lyophilized and redissolved in 5 ml of water. A 1.5-ml sample of the solution was applied to a reverse-phase HPLC column (C4 column) and eluted with an acetonitrile gradient. Most contaminants eluted from the column prior to the saposins, which were eluted later as a cluster of peaks. This cluster was collected and then analyzed by another HPLC system equipped with an AX-300 anion-exchange column using a NaCl gradient. Saposins D, A, and C eluted from the AX-300 column separately and in that order. Quantitation of the saposins was made by measuring the sizes of each peak. Standard curves made from pure saposins showed that quantification was linear over a range from 1 to 5 micrograms. Saposin B was measured by its stimulation activity on pure human liver GM1 ganglioside beta-galactosidase. Stimulation was linear up to 80 micrograms of saposin B. Application of this method to analysis of human tissues for their saposin content is presented.

Synthesis and characterization of a bioactive 82-residue sphingolipid activator protein, saposin C

The sphingolipid activator protein, saposin C (also termed SAP 2), was chemically synthesized, purified, and characterized. The fully protected 82-residue protein was synthesized by automated solid-phase methods, with multiple recoupling steps resulting in a high average coupling efficiency of 98.8%. The overall yield was estimated to be approx 40%. Deprotection and cleavage of the peptide from the resin was followed by folding in the absence of chaotropic agents at pH 8.5. The protein was purified by reversed-phase high pressure liquid chromatography (HPLC) and its purity determined by capillary electrophoresis and sodium dodecyl sulfate polyacrylamide gel electrophoresis (SDS-PAGE). The composition of the synthetic saposin C was determined by amino acid analysis. Its sequence was verified by Edman sequence analysis of overlapping peptide fragments generated by chymotryptic andStaphylococcus aureus V8 digestions. The sequence at the C-terminus was determined by digestion with carboxypeptidase P, followed by phenylthiohydantoin (PTH) derivitization and HPLC analysis of the released amino acid residues. Deglycosylated native saposin C appeared as a lower molecular-weight species than synthetic saposin C on SDS-PAGE. This has been explained by amino acid and C-terminal analysis showing native saposin C to be two amino acids shorter at the C terminus than a deduced sequence (from cDNA) previously published. Synthetic saposin C displayed 85% of full biological activity as determined by its ability to stimulate glucocerebrosidase activity in vitro: Synthetic and native saposin C increased glucocerebrosidase catalyzed hydrolysis of 4-methylumbelliferyl β-D-glucoside by factors of 6.0 and 7.1, respectively. Furthermore, synthetic and native saposin C share similar Kact values (0.5 and 1.5 μM respectively) indicating that they bind to glucocerebrosidase with similar affinities.

Human placental sialidase complex: Characterization of the 60 kDa protein that cross-reacts with anti-saposin antibodies

Sialidase isolated from human placenta is associated with several proteins including acid beta-galactosidase, carboxypeptidase, N-acetyl-alpha-galactosaminidase, and others. These proteins are thought to form an aggregated complex during isolation of sialidase. One of the proteins of 60 kDa was recently identified by Potier et al. (Biochem. Biophys. Res. Comm. 173, 449-456, 1990) as a sialidase protein: this protein also cross-reacted with anti-prosaposin antibodies. We have isolated this protein and from the following evidence identified it as a heavy chain component of immunoglobulin G and not sialidase or a derivative of prosaposin. On gel filtration HPLC, sialidase activity and the 60 kDa protein were clearly separated from one another. The 60 kDa protein cross-reacted not only with antibodies raised against human saposins A, C, and D, but also with second antibody (goat anti-rabbit immunoglobulin G antibody) alone. This 60 kDa protein strongly cross-reacted with anti-human immunoglobulin G antibodies. The sequence of the initial 15 amino acids from the N-terminus of the 60 kDa protein was identical to the sequence of an immunoglobulin G heavy chain protein Tie (gamma 1).

A sialidase complex from chicken liver: Characterization of a multienzyme complex with β-galactosidase and carboxypeptidase

Abstract Mammalian lysosomal sialidase exists as an enzyme complex with β-galactosidase and carboxypeptidase, so-called “protective protein.” In this article, we report that chicken sialidase also occurs as a complex with β-galactosidase and protective protein. The purified sialidase complex had a molecular weight > 700 kDa on gel filtration and showed four protein components of 76, 65, 54 and 48 kDa on SDS-PAGE under nonreducing conditions. N -Terminal sequences of the 65- and 48-kDa proteins were homologous to human lysosomal β-galactosidase and protective protein precursor, respectively. The purified sialidase complex also had carboxypeptidase activity. Both sialidase and carboxypeptidase activities were precipitated together by an antibody against chicken β-galactosidase. The complex reversibly dissociated into 120-kDa β-galactosidase dimer and 100-kDa carboxypeptidase dimer at pH 7.5, but the sialidase irreversibly inactivated during the depolymerization. These findings indicate that chicken sialidase exists as a multienzyme complex, by which the sialidase activity appears to be stabilized.