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Sphingolipid hydrolase activator proteins and their precursors
Vol. 165, No. 3, 1989 December
BlOCHEMlCAL
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
29, 1989
Pages
Sphingolipid
Hydrolase
Akira
Sano,
Takashi
Shu-ichi
The Department
Activator
of Neuropsychiatry,
*The Department
Proteins and Their Precursors
Hineno,
Tatsuo
Yasuo
Kakimoto,
Ueno,
1191-1197
Mizuno, and
Keiji Koji
Kondoh,
Inui*
Ehime University School of Medicine, Shigenobu, Onsen-gun, Ehime 791-02, Japan
of Pediatrics, Osaka University School of Medicine, Fukushima, Osaka 553, Japan
Received
October
30,
1989
Activator proteins for sphingolipid hydrolases (saposins) are small acidic, heat-stable glycoproteins that stimulate the hydrolysis of sphingolipids by lysosomal enzymes. The molecular mass of each stimulator is about 10 kDa, but glycosylated forms of higher mass exist too. The distribution and developmental changes in two saposins and their precursor proteins were studied with the aid of monospecific antibodies against saposin-B and saposin-C. They show a wide distribution in rat organs and forms intermediate between saposin and prosaposin (the precursor protein containing four different saposin units) could be seen. The amount of saposin and the degree of processing from prosaposin are quite different in different tissues. The saposins are the dominant forms in spleen, lung, liver, and kidney, while skeletal muscle, heart, and brain contain mainly precursor forms. In human blood, leukocytes contain mainly saposin, while plasma contains mainly precursor forms and platelets show many forms. Their subcellular distribution was studied using rat liver. The saposins of approximately 20 kDa are dominant in the light mitochondrial, mitochondrial, and microsomal fractions, following the distribution of the activity of a lysosomal marker enzyme. The nuclear fraction exhibits bands corresponding to non-glycosylated saposin. The soluble fraction contained much precursor forms. A developmental study of rat brain showed that the concentration of saposin precursors increased with age. 0 1989 AcademicPress, IrIG.
Recently, relatively
small, heat-stable, acidic glycoproteins
hydrolases acting on sphingolipids originally
that stimulate the action of lysosomal
have been described. The existence of some of these proteins was
described by Mehl and Jatzkewitz
(I), Ho and O’Brien (2), Li and Li (3), and Hechtman (4). They
seem to exert a relatively specific interaction with the enzymes or with the substrates, or both and, in some cases, require an acidic lipid for effectiveness. Some of the saposins occur in carbohydrate-free as forms bearing different oligosaccharides; action (5,6). They have been variously
form, as well
the carbohydrate moiety is not essential for the stimulatory
called saposins, cohydrolases, heat-stable factors, sphingolipid
activator proteins, etc. The term saposin (67)
is used here, abbreviated SAI? For recent reviews see ref. 8 and
9.
Abbreviations:
SAC saposin; SDS-PAGE, sodium dodecyl sulfate polyacrylamide
gel electrophoresis. 0006-291x/89
1191
$1.50
Copyright 0 1989 by Academic Press, Inc. All rights of reproduction in any form reserved.
Vol. 165, No. 3, 1989
BIOCHEMICAL
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
More recently it became clear that the saposins are derived by specific proteolytic
cleavage from a
precursor protein, called prosaposin, which consists of four very similar domains, each of which has saposin activity (10-14). Each of the four saposins consists of about 80 amino acids, including six similarly spaced cysteine residues in oxidised form, a glycosylation
site, and specifically located tyrosine and proline
residues. SAP-B is the stimulator of sulfatide, G M1 ganglioside hydrolys’is (15-17). SAPS-C stimulate
and, possibly, trihexosylceramide
the hydrolysis of glucosylceramide
This paper describes the presence of prosaposin and intermediates human blood. Striking differences in distribution
DEAE-Sephacel,
in its proteolysis in rat tissues and
of the different peptides were observed.
MATERIALS Materials-Bovine
and galactosylceramide.
AND METHODS
spleens were obtained from a slaughter house and stored at -80°C before use.
Sephadex G75 (fine), and CNBr-activated
Sepharose were from Pharmacia; acetonitrile,
HPLC grade, acrylamide, sodium dodecyl sulfate, and peroxidase conjugated anti-rabbit Wako Chemical; trifluoroacetic Immobilon
IgG were from
acid, HPLC grade was from Pierce; Freund’s adjuvants were from Difco;
transfer membranes (polyvinylidene
fluoride membranes) were from Millipore.
Preparation of saposin-C from bovine spleen and antibody against SAP-C-The
isolation procedure of
SAP-C was generally the same as the method described by Sano et al. (12). A hot-water spleen was purified by ammonium
sulfate precipitation,
DEAE-Sephacel
extract from bovine
ion exchange, Sephadex G-75 gel
permeation, and reverse phase HPLC with a C, column (Con A-Sepharose column chromatography omitted.). Amino acid sequencing and amino acid compositional significant
contamination
analysis of this preparation
was
showed no
with other proteins.’ Each of two young male rabbits was injected subcutaneously
with 100 pg of purified bovine SAP-C in Freund’s incomplete adjuvant. After 17 days another 100 pg in Freund’s incomplete adjuvant was injected subcutaneously. By four weeks after the initial injection, the plasma produced precipitin
lines in the Ouchterlony
double immunodiffusion
procedure. Two weeks after the
second injection blood was collected and an IgG fraction was isolated using ammonium sulfate precipitation and DEAE-Sephacel
column chromatography.
affinity chromatography,
The antibody was further purified to be monospeciflc by
using bovine SAP-C attached to CNBr-activated
was used in all experiments. Monospecific anti-human Tests with immunoblot
procedure showed there were no crossreactivity between our different monospecific
antibodies and antigens. The anti-human C, and the anti-bovine
SAP-B Ig G was reactive neither to pure guinea pig nor bovine SAP-
SAP-C Ig G was reactive neither to partially purified guinea pig nor bovine SAP-B.
SDS-PAGE and immunoblots-SDS-PAGE acrylamide (18). After electrophoresis detected indirectly
Sepharose. This preparation
SAP-B IgG was prepared as previously described (15).
was performed by the method of Laemmfi with 15%
the samples were electroblotted
to Immobilon
with the antibodies described above and peroxidase-conjugated
membranes and anti-rabbit
IgG and with
a peroxidase reactant, diaminobenzidine. RESULTS Organ distribution
of saposins
and
their precursors-An
anesthetized Wistar male rat was perfused
well with saline from the left ventricle of the heart after cutting femoral veins. Organs were taken out
lA. Sano, T. Mizuno, Z Hineno, K Kondoh, S. Ueno, Y Kakimoto, and N. Morita, unpublished 1192
work
BIOCHEMICAL
Vol. 165, No. 3, 1989
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
m Organ distribution of sqosins and their precursor form. Organ extracts (50 M of protein) were electrophoresed by SDS-PAGE, then immunoblotted as described in the text. 1A: detected with anti-SAP-B IgG, 1B: detected with anti-SAP-C. The arrow heads on the right sides are the positions of the molecular weight standards.
quickly and homogenized
in five volumes of iced 10 mM Na-phosphate,
pH 7.0, and centrifuged at 10,000 x g
for 10 min. The resultant supernatants were used as samples for SDS-PAGE. While immunoreactive
bands
could be seen with whole homogenates, the amount of tissue needed to get good reactivity was so large that the bands were distorted. The 10,000 x g supematant produced satisfactory bands and was therefore used for most of this study Immunoreactive
bands of a wide range in molecular weights were seen with the antibodies to both
SAP-B and SAP-C in all organs examined (Fig. I). The patterns of the bands were quite similar with both and kidney, while precursor
antibodies. The smaller forms were markedly dominant in spleen, lung, liver, forms were the major forms in skeletal muscle, heart, and brain.
The cellular components and plasma of human blood were separated by centrifugation
and washed
well with isotonic buffer, then examined as above (Fig. 2). Leukocytes contained a high level of saposins. Plasma contained precursor forms exclusively. Platelets showed many bands corresponding intermediate
precursor polypeptides. Red cells showed a single band corresponding
anhydrase, which reacts with diaminobenzidine Subcellular distribution homogenized
of sapsins
the position of carbonic
in peroxidase reaction.
and their precursor
in rut
in sucrose solution and fractionated by differential
liuer-Rat
liver perfused as above was
centrifugation.
Each fraction was assayed
for marker substances and enzymes (19). As shown in Fig. 3, a relatively high concentration forms was found in the nuclear fraction (N). In this experiment, the relative specific activities of the mitochondrial, showed the expected distribution
to prosaposin and
DNA
was
of the smaller
concentrated in the N fraction, and
lysosomal, microsomal,
and cytosolic marker enzymes
patterns (Fig. 4). The intensities of the saposin bands in the the nuclear
fraction increased when the particles were further purified according to the method of Chauveau et al.(ZO) (data not shown). 1193
Vol. 165, No. 3, 1989
BIOCHEMICAL
-7
.“--
--
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
-3
B
A
;
NMLPS
m Distribution of immunoblotting were with anti-SAP-B IgG, the molecular weight
N
ML
PS
saposins and their precursor forms in human blood. Electrophoresis and performed as in Fig. I. The amount of samples were each 50 ccg of protein. 2A: detected 28: detected with anti-SAP-C. The arrow heads on the right sides are the positions of standards.
F&J. Subcellular distribution of saposins and their pwcursor forms in rut liver. Each 50 pg protein of the fractions was analysed. 3A: detected with anti-SAP-B IgG, 3B: detected with anti-SAP-C. The abbreviation above each lane is defined as follows: N, nuclear fraction; M, mitochondrial fraction; L, light mitochondrial fraction (lysosomal fraction); c microsomal fraction; S; cytosol.
Dezwlopfnentul changes in saposins and their precursors in raf brain-As
shown in Fig. 5, the saposins
and the precursor forms were already seen at birth. The concentrations of the precursor forms increased gradually from the 10th day after birth up to the last age point tested, 50 days.
N
M
Subcellular
L
P
Fractions
s
n q
DNA Cytochrome Oxidase Acid Phosphatase Glucose-6-phosphatase IJM
Fi11.4 Subcellular distribution of DNA and marker enzymes. The relative concentrations of DNA and relative specific activities of marker enzymes in the subcellular fractions (see legend for Fig. 3) are shown.
1194
BIOCHEMICAL
Vol. 165, No. 3, 1989
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
494K
467K 443K 430K 420K 414K
4 6.5K
m Deoelo~nz,mental changes of saposins and their precursor forlns in rat brain. Brain extracts (50 gof protein) were analyzed. 5A: detected with anti-SAP-8 IgG, 58: detected with anti-SAP-C. The arrow heads on the right sides indicate the molecular weight standards.
DISCUSSION The many bands for the different saposins obtained by SDS-PAGE are mostly the result of carbohydrate heterogeneity
in the side chains as we demonstrated
the existence of prosaposin and its intermediates the length microheterogeneity demonstrated
of the polypeptide
in proteolytic
in the case of pure SAP-C (5), as well as
conversion, and are partially the result of
chains such as the N-terminal
microheterogeneity
in SAP-C (11),(12). According to the sequence analysis of cDNA for prosaposin (13),(14), it has
five N-glycosylation
sites in it. The four saposins occur in a single chain in prosaposin in the sequence A-B-C-
D (6), and one could expect that an antibody reactive to SAP-C would visualize trisaposins ABC and BCD and disaposins BC and CD. The immunoblot
results obtained with the preimmune serum showed no
significant bands, and the antibodies in this study are highly specific. It is interesting
that the antibodies
are reactive to the antigens of the different spieces but not to the different SAPS in spite of the structural similarity. The small saposins (-6 kDa) that are seen in submandibular
gland might be the dialyzable
activator
of glucosidase reported to occur in saliva (21). Its reactivity with antibodies (Fig. 1) indicates that it is structurally very is evidently
similar to the other saposins but lacks a significant portion of the usual form. This portion
unessential for stimulatory
activity.
Analysis of human blood revealed that plasma contains a considerable amount of prosaposin. Since plasma is a typical extracellular
fluid, it is likely that the precursor protein is secreted by certain cells into
the extracellular spaces. Newly formed molecules of sulfated glycoprotein, SGP-1, were found to be largely secreted into the cell medium by Sertoli cells (22) while human fibroblasts were found to process most of the newly formed saposin by proteolysis (23). Some kinds of leukocytes have the function of phagocytosis and have well differentiated
lysosomes, so it is reasonable to see much mature saposins there (Fig. 2). Spleen,
which also has hydrolysis as a major function, also has most of its saposin in the active, monomeric form (Fig. 1). It is possible that the precursor forms serve in other tissues as storage forms, to be rapidly converted to the active form when needed for a surge in hydrolytic workload. 1195
Vol. 165, No. 3, 1989
In the developmental differentiation
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AND BIOPHYSICAL RESEARCH COMMUNICATIONS
growth of rat brain , neuronal division is largely prenatal, and neuronal
such as synaptogenesis occurs mostly during the first 2 to 3 weeks of postnatal life. A peak in
the level of saposin appears at -15 days, an age at which the levels of ceramidase, sulfatase, and Bglucosidase are maximal in mouse brain (24). However, the ratio of precursor to mature form increases during rat brain development. Several species of prosaposin appear at all ages, increasing gradually
after day 10
(Fig. 4). This pattern of increase correlates with the steady rise seen in rat brain sphingolipids detected prosaposin in human cerebrospinal A number of biological
and pathological
fluid.2 functions are attributed
expression on cell surfaces has been correlated with cell transformation, and tumor progression. Glycolipids
also serve as differentiation
to different sphingolipids
markers and are thought to participate
hydrolases activator. If prosaposin or SGP-I has such a biological
extracellular
in
the binding of exogenous
factors, and cell recognition. It is not known yet whether prosaposin or SGP-1 has a biological sphingolipid
(26). Their
adhesion of cells to matrix proteins,
various cell regulatory functions, such as cell contact response, contact inhibition,
possibility that it controls building
(25). We also
activity as a
activity, there is a
and scrapping the sugar moieties of membranous
sphingolipids
from the
space.
Our finding that nuclei contain a relatively high level of SAPS-B and -C raises the possibility these proteins exert a modulatory
influence on the gene regulation
and cell proliferation.
that
The level of SAEs-
A, -C, and -D are very high in the spleens of Gaucher patients (6), which are distinctive for their greatly increased size and accumulation of glucosylceramide. glucosylceramide
together with an inhibitor
This condition can be mimicked by injecting mice with
of glucosidase; the level of SAP-C rises rapidly (27), as does
the size and DNA content of the liver (28).
Acknowledgments -This study was partly supported by Grant 01770180 from the Ministry of Education, Science and Culture, Japan, and by ON0 Medical Research Foundation (A. S.). We thank Dr. N. S. Radin of the Mental Health Research Institute, University of Michigan, U. S. A., for reviewing this manuscript.
REFERENCES 1. 2. 3. 4. 5. 6. 7. 8. 9. 10. 11. 12.
Mehl, E. and Jatzkewitz, H. (1964) Hoppe-Seyler’s Z. Physiol. Chem. 339, 260-276 Ho, M. W. and O’Brien, J. S. (1971) Proc. Natl. Acad. Sci. U. S. A. 68,2810-2813 Li, S.-C. and Li, Y-T (1976) J. Biol. Chem. 251, 1159-1163 Hechtman, I? (1977) Can, J. Biochem. 55, 315-324 Sano, A. and Radin, N. S. (1988) Biochem. Biophys Res. Commun. 154, 1197-1203 Morimoto, S, Martin, B. M., Yamamoto, Y., Kretz, K. A., O’Brien, J. S., Kishimoto, Y (1989) Eroc. Nat1 Acad. Sci. U. S. A. 86, 3389-3393 Morimoto,.S, Martin, B. M., Kishimoto, Y., and O’Brien, J. S. (1988) Biochem. Biophys. Res. Comm. 56, 403-410 Conzelmann, E. and Sandhoff, K (1987) Adv. Enzymol. 60, 90-197 Conzelmann, E. and Sandhoff, K. (1986) Meth. Biochem. Anal. 32, l-23 Kleinschmidt, ‘lI, Christomanou, H., and Braunitzer (1988) Biol. Chem. Hoppe-Seyler 369, 1361-1365 Kleinschmidt, T, Christomanou, H., and Braunitzer (1987) Biol. Chem. Hoppe-Seyler 368, 1571-1578 Sano, A., Radin, N. S., Johnson, L. L., and Tarr, G. E. (1988) J. Biol. Chem. 263, 19597-19681
% Hineno, A. Sano, T Mizuno, K Kondoh, S. Ueno, Y. Kakimoto, and K. Inui, unpublished 1196
work
Vol.
13. 14. 15. 16. 17. 18. 19 20. 21. 22. 23. 24. 25. 26. 27. 28.
165,
No.
3, 1989
BIOCHEMICAL
AND
BIOPHYSICAL
RESEARCH
COMMUNICATIONS
O’Brien, J. S., Kretz, K, Dewji, N., Wenger, D. A., Esch, E, and Fluharty, A. L. (1988) Science 241, 1098-1101 Nakano, T, Sandhoff, K., Stumper, Christomanou, and Suzuki, K. (1989) J. Biochem. (Tokyo) 105,152154 Inui, K., Emmett, M., and Wenger, D. A. (1983) Proc. Nat]. Acad. Sci. U. S. A. 80, 3074-3077 Gartner, S., Conzelmann, E., and Sandhoff, K. (1983) J. Biol. Chem. 258, 12378-12385 Li, S.-C., Kihara, H. Serizawa, S., Li, Y.-T, Fluharty, A. L., Mayes, J. S., and Shapiro, L. J. (1985) J. Biol. Chem. 260, 1867-1871 Laemmh, U. K. (1979) Nature 227, 680-685 De Duve, C., Pressman, B. C., Gianetto, R., Wattlaux, R., and Appelmans, F. (1955) Biochem. J. 60, 604. 617 Chauveau, J., Moule, Y., and Rouiller, C. H. (1956) Exp. Cell Res. 11, 317-321 Cherian, R., and Balasubramanian, AS. (1981) Clin. Chim. Acta 110, 169-176 Collard, M. W., Sylvester, S. R., Tsuruta, J, K, and Griswold, M. D. (1988) Biochemistry 27, 4557-4564 Fujibayashi, S. and Wenger D. A. (1986) J. Biol. Chem. 261, 15339-15343 Bowen, D.M. and Radin, N.S. (1969) J. Neurochem. 16,501-511 Kishimoto, Y., Davies, W.E. and Radin, N.S. (1965) J. Lipid Res. 6, 532-536 Hunnun, Y., A. and Bell, R. M. (1989) Science 243,500-507 Datta, S.C. and Radin, N.S. (1986) Lipids, 21, 702-709 Datta, S. C. and N. S. Radin. (1988) Lipids 23,508-510
1197
BlOCHEMlCAL
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
29, 1989
Pages
Sphingolipid
Hydrolase
Akira
Sano,
Takashi
Shu-ichi
The Department
Activator
of Neuropsychiatry,
*The Department
Proteins and Their Precursors
Hineno,
Tatsuo
Yasuo
Kakimoto,
Ueno,
1191-1197
Mizuno, and
Keiji Koji
Kondoh,
Inui*
Ehime University School of Medicine, Shigenobu, Onsen-gun, Ehime 791-02, Japan
of Pediatrics, Osaka University School of Medicine, Fukushima, Osaka 553, Japan
Received
October
30,
1989
Activator proteins for sphingolipid hydrolases (saposins) are small acidic, heat-stable glycoproteins that stimulate the hydrolysis of sphingolipids by lysosomal enzymes. The molecular mass of each stimulator is about 10 kDa, but glycosylated forms of higher mass exist too. The distribution and developmental changes in two saposins and their precursor proteins were studied with the aid of monospecific antibodies against saposin-B and saposin-C. They show a wide distribution in rat organs and forms intermediate between saposin and prosaposin (the precursor protein containing four different saposin units) could be seen. The amount of saposin and the degree of processing from prosaposin are quite different in different tissues. The saposins are the dominant forms in spleen, lung, liver, and kidney, while skeletal muscle, heart, and brain contain mainly precursor forms. In human blood, leukocytes contain mainly saposin, while plasma contains mainly precursor forms and platelets show many forms. Their subcellular distribution was studied using rat liver. The saposins of approximately 20 kDa are dominant in the light mitochondrial, mitochondrial, and microsomal fractions, following the distribution of the activity of a lysosomal marker enzyme. The nuclear fraction exhibits bands corresponding to non-glycosylated saposin. The soluble fraction contained much precursor forms. A developmental study of rat brain showed that the concentration of saposin precursors increased with age. 0 1989 AcademicPress, IrIG.
Recently, relatively
small, heat-stable, acidic glycoproteins
hydrolases acting on sphingolipids originally
that stimulate the action of lysosomal
have been described. The existence of some of these proteins was
described by Mehl and Jatzkewitz
(I), Ho and O’Brien (2), Li and Li (3), and Hechtman (4). They
seem to exert a relatively specific interaction with the enzymes or with the substrates, or both and, in some cases, require an acidic lipid for effectiveness. Some of the saposins occur in carbohydrate-free as forms bearing different oligosaccharides; action (5,6). They have been variously
form, as well
the carbohydrate moiety is not essential for the stimulatory
called saposins, cohydrolases, heat-stable factors, sphingolipid
activator proteins, etc. The term saposin (67)
is used here, abbreviated SAI? For recent reviews see ref. 8 and
9.
Abbreviations:
SAC saposin; SDS-PAGE, sodium dodecyl sulfate polyacrylamide
gel electrophoresis. 0006-291x/89
1191
$1.50
Copyright 0 1989 by Academic Press, Inc. All rights of reproduction in any form reserved.
Vol. 165, No. 3, 1989
BIOCHEMICAL
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
More recently it became clear that the saposins are derived by specific proteolytic
cleavage from a
precursor protein, called prosaposin, which consists of four very similar domains, each of which has saposin activity (10-14). Each of the four saposins consists of about 80 amino acids, including six similarly spaced cysteine residues in oxidised form, a glycosylation
site, and specifically located tyrosine and proline
residues. SAP-B is the stimulator of sulfatide, G M1 ganglioside hydrolys’is (15-17). SAPS-C stimulate
and, possibly, trihexosylceramide
the hydrolysis of glucosylceramide
This paper describes the presence of prosaposin and intermediates human blood. Striking differences in distribution
DEAE-Sephacel,
in its proteolysis in rat tissues and
of the different peptides were observed.
MATERIALS Materials-Bovine
and galactosylceramide.
AND METHODS
spleens were obtained from a slaughter house and stored at -80°C before use.
Sephadex G75 (fine), and CNBr-activated
Sepharose were from Pharmacia; acetonitrile,
HPLC grade, acrylamide, sodium dodecyl sulfate, and peroxidase conjugated anti-rabbit Wako Chemical; trifluoroacetic Immobilon
IgG were from
acid, HPLC grade was from Pierce; Freund’s adjuvants were from Difco;
transfer membranes (polyvinylidene
fluoride membranes) were from Millipore.
Preparation of saposin-C from bovine spleen and antibody against SAP-C-The
isolation procedure of
SAP-C was generally the same as the method described by Sano et al. (12). A hot-water spleen was purified by ammonium
sulfate precipitation,
DEAE-Sephacel
extract from bovine
ion exchange, Sephadex G-75 gel
permeation, and reverse phase HPLC with a C, column (Con A-Sepharose column chromatography omitted.). Amino acid sequencing and amino acid compositional significant
contamination
analysis of this preparation
was
showed no
with other proteins.’ Each of two young male rabbits was injected subcutaneously
with 100 pg of purified bovine SAP-C in Freund’s incomplete adjuvant. After 17 days another 100 pg in Freund’s incomplete adjuvant was injected subcutaneously. By four weeks after the initial injection, the plasma produced precipitin
lines in the Ouchterlony
double immunodiffusion
procedure. Two weeks after the
second injection blood was collected and an IgG fraction was isolated using ammonium sulfate precipitation and DEAE-Sephacel
column chromatography.
affinity chromatography,
The antibody was further purified to be monospeciflc by
using bovine SAP-C attached to CNBr-activated
was used in all experiments. Monospecific anti-human Tests with immunoblot
procedure showed there were no crossreactivity between our different monospecific
antibodies and antigens. The anti-human C, and the anti-bovine
SAP-B Ig G was reactive neither to pure guinea pig nor bovine SAP-
SAP-C Ig G was reactive neither to partially purified guinea pig nor bovine SAP-B.
SDS-PAGE and immunoblots-SDS-PAGE acrylamide (18). After electrophoresis detected indirectly
Sepharose. This preparation
SAP-B IgG was prepared as previously described (15).
was performed by the method of Laemmfi with 15%
the samples were electroblotted
to Immobilon
with the antibodies described above and peroxidase-conjugated
membranes and anti-rabbit
IgG and with
a peroxidase reactant, diaminobenzidine. RESULTS Organ distribution
of saposins
and
their precursors-An
anesthetized Wistar male rat was perfused
well with saline from the left ventricle of the heart after cutting femoral veins. Organs were taken out
lA. Sano, T. Mizuno, Z Hineno, K Kondoh, S. Ueno, Y Kakimoto, and N. Morita, unpublished 1192
work
BIOCHEMICAL
Vol. 165, No. 3, 1989
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
m Organ distribution of sqosins and their precursor form. Organ extracts (50 M of protein) were electrophoresed by SDS-PAGE, then immunoblotted as described in the text. 1A: detected with anti-SAP-B IgG, 1B: detected with anti-SAP-C. The arrow heads on the right sides are the positions of the molecular weight standards.
quickly and homogenized
in five volumes of iced 10 mM Na-phosphate,
pH 7.0, and centrifuged at 10,000 x g
for 10 min. The resultant supernatants were used as samples for SDS-PAGE. While immunoreactive
bands
could be seen with whole homogenates, the amount of tissue needed to get good reactivity was so large that the bands were distorted. The 10,000 x g supematant produced satisfactory bands and was therefore used for most of this study Immunoreactive
bands of a wide range in molecular weights were seen with the antibodies to both
SAP-B and SAP-C in all organs examined (Fig. I). The patterns of the bands were quite similar with both and kidney, while precursor
antibodies. The smaller forms were markedly dominant in spleen, lung, liver, forms were the major forms in skeletal muscle, heart, and brain.
The cellular components and plasma of human blood were separated by centrifugation
and washed
well with isotonic buffer, then examined as above (Fig. 2). Leukocytes contained a high level of saposins. Plasma contained precursor forms exclusively. Platelets showed many bands corresponding intermediate
precursor polypeptides. Red cells showed a single band corresponding
anhydrase, which reacts with diaminobenzidine Subcellular distribution homogenized
of sapsins
the position of carbonic
in peroxidase reaction.
and their precursor
in rut
in sucrose solution and fractionated by differential
liuer-Rat
liver perfused as above was
centrifugation.
Each fraction was assayed
for marker substances and enzymes (19). As shown in Fig. 3, a relatively high concentration forms was found in the nuclear fraction (N). In this experiment, the relative specific activities of the mitochondrial, showed the expected distribution
to prosaposin and
DNA
was
of the smaller
concentrated in the N fraction, and
lysosomal, microsomal,
and cytosolic marker enzymes
patterns (Fig. 4). The intensities of the saposin bands in the the nuclear
fraction increased when the particles were further purified according to the method of Chauveau et al.(ZO) (data not shown). 1193
Vol. 165, No. 3, 1989
BIOCHEMICAL
-7
.“--
--
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
-3
B
A
;
NMLPS
m Distribution of immunoblotting were with anti-SAP-B IgG, the molecular weight
N
ML
PS
saposins and their precursor forms in human blood. Electrophoresis and performed as in Fig. I. The amount of samples were each 50 ccg of protein. 2A: detected 28: detected with anti-SAP-C. The arrow heads on the right sides are the positions of standards.
F&J. Subcellular distribution of saposins and their pwcursor forms in rut liver. Each 50 pg protein of the fractions was analysed. 3A: detected with anti-SAP-B IgG, 3B: detected with anti-SAP-C. The abbreviation above each lane is defined as follows: N, nuclear fraction; M, mitochondrial fraction; L, light mitochondrial fraction (lysosomal fraction); c microsomal fraction; S; cytosol.
Dezwlopfnentul changes in saposins and their precursors in raf brain-As
shown in Fig. 5, the saposins
and the precursor forms were already seen at birth. The concentrations of the precursor forms increased gradually from the 10th day after birth up to the last age point tested, 50 days.
N
M
Subcellular
L
P
Fractions
s
n q
DNA Cytochrome Oxidase Acid Phosphatase Glucose-6-phosphatase IJM
Fi11.4 Subcellular distribution of DNA and marker enzymes. The relative concentrations of DNA and relative specific activities of marker enzymes in the subcellular fractions (see legend for Fig. 3) are shown.
1194
BIOCHEMICAL
Vol. 165, No. 3, 1989
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
494K
467K 443K 430K 420K 414K
4 6.5K
m Deoelo~nz,mental changes of saposins and their precursor forlns in rat brain. Brain extracts (50 gof protein) were analyzed. 5A: detected with anti-SAP-8 IgG, 58: detected with anti-SAP-C. The arrow heads on the right sides indicate the molecular weight standards.
DISCUSSION The many bands for the different saposins obtained by SDS-PAGE are mostly the result of carbohydrate heterogeneity
in the side chains as we demonstrated
the existence of prosaposin and its intermediates the length microheterogeneity demonstrated
of the polypeptide
in proteolytic
in the case of pure SAP-C (5), as well as
conversion, and are partially the result of
chains such as the N-terminal
microheterogeneity
in SAP-C (11),(12). According to the sequence analysis of cDNA for prosaposin (13),(14), it has
five N-glycosylation
sites in it. The four saposins occur in a single chain in prosaposin in the sequence A-B-C-
D (6), and one could expect that an antibody reactive to SAP-C would visualize trisaposins ABC and BCD and disaposins BC and CD. The immunoblot
results obtained with the preimmune serum showed no
significant bands, and the antibodies in this study are highly specific. It is interesting
that the antibodies
are reactive to the antigens of the different spieces but not to the different SAPS in spite of the structural similarity. The small saposins (-6 kDa) that are seen in submandibular
gland might be the dialyzable
activator
of glucosidase reported to occur in saliva (21). Its reactivity with antibodies (Fig. 1) indicates that it is structurally very is evidently
similar to the other saposins but lacks a significant portion of the usual form. This portion
unessential for stimulatory
activity.
Analysis of human blood revealed that plasma contains a considerable amount of prosaposin. Since plasma is a typical extracellular
fluid, it is likely that the precursor protein is secreted by certain cells into
the extracellular spaces. Newly formed molecules of sulfated glycoprotein, SGP-1, were found to be largely secreted into the cell medium by Sertoli cells (22) while human fibroblasts were found to process most of the newly formed saposin by proteolysis (23). Some kinds of leukocytes have the function of phagocytosis and have well differentiated
lysosomes, so it is reasonable to see much mature saposins there (Fig. 2). Spleen,
which also has hydrolysis as a major function, also has most of its saposin in the active, monomeric form (Fig. 1). It is possible that the precursor forms serve in other tissues as storage forms, to be rapidly converted to the active form when needed for a surge in hydrolytic workload. 1195
Vol. 165, No. 3, 1989
In the developmental differentiation
BIOCHEMICAL
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
growth of rat brain , neuronal division is largely prenatal, and neuronal
such as synaptogenesis occurs mostly during the first 2 to 3 weeks of postnatal life. A peak in
the level of saposin appears at -15 days, an age at which the levels of ceramidase, sulfatase, and Bglucosidase are maximal in mouse brain (24). However, the ratio of precursor to mature form increases during rat brain development. Several species of prosaposin appear at all ages, increasing gradually
after day 10
(Fig. 4). This pattern of increase correlates with the steady rise seen in rat brain sphingolipids detected prosaposin in human cerebrospinal A number of biological
and pathological
fluid.2 functions are attributed
expression on cell surfaces has been correlated with cell transformation, and tumor progression. Glycolipids
also serve as differentiation
to different sphingolipids
markers and are thought to participate
hydrolases activator. If prosaposin or SGP-I has such a biological
extracellular
in
the binding of exogenous
factors, and cell recognition. It is not known yet whether prosaposin or SGP-1 has a biological sphingolipid
(26). Their
adhesion of cells to matrix proteins,
various cell regulatory functions, such as cell contact response, contact inhibition,
possibility that it controls building
(25). We also
activity as a
activity, there is a
and scrapping the sugar moieties of membranous
sphingolipids
from the
space.
Our finding that nuclei contain a relatively high level of SAPS-B and -C raises the possibility these proteins exert a modulatory
influence on the gene regulation
and cell proliferation.
that
The level of SAEs-
A, -C, and -D are very high in the spleens of Gaucher patients (6), which are distinctive for their greatly increased size and accumulation of glucosylceramide. glucosylceramide
together with an inhibitor
This condition can be mimicked by injecting mice with
of glucosidase; the level of SAP-C rises rapidly (27), as does
the size and DNA content of the liver (28).
Acknowledgments -This study was partly supported by Grant 01770180 from the Ministry of Education, Science and Culture, Japan, and by ON0 Medical Research Foundation (A. S.). We thank Dr. N. S. Radin of the Mental Health Research Institute, University of Michigan, U. S. A., for reviewing this manuscript.
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