Complex Contact-Based Dynamics of Microsphere Monolayers Revealed by Resonant Attenuation of Surface Acoustic Waves.

Contact-based vibrations play an essential role in the dynamics of granular materials. Significant insights into vibrational granular dynamics have previously been obtained with reduced-dimensional systems containing macroscale particles. We study contact-based vibrations of a two-dimensional monolayer of micron-sized spheres on a solid substrate that forms a microscale granular crystal. Measurements of the resonant attenuation of laser-generated surface acoustic waves reveal three collective vibrational modes that involve displacements and rotations of the microspheres, as well as interparticle and particle-substrate interactions. To identify the modes, we tune the interparticle stiffness, which shifts the frequency of the horizontal-rotational resonances while leaving the vertical resonance unaffected. From the measured contact resonance frequencies we determine both particle-substrate and interparticle contact stiffnesses and find that the former is an order of magnitude larger than the latter. This study paves the way for investigating complex contact-based dynamics of microscale granular crystals and yields a new approach to studying micro- to nanoscale contact mechanics in multiparticle networks.

Prosaposin is a novel androgen-regulated gene in prostate cancer cell line LNCaP.

Androgen-regulated genes (ARG) are implicated in normal and neoplastic growth of the prostate. Recently, we reported genomic amplification and/or overexpression of a previously known neurotrophic factor, prosaposin, in androgen-independent (AI) or metastatic prostate cancer (PCa) cells and tissues. Prosaposin and/or its known active molecular derivatives (e.g., saposin C) function as a pluripotent growth factor with diverse biological activities that favor malignant phenotypes in PCa cells. In addition, prosaposin or saposin C upregulates androgen receptor (AR) and AR-target genes (i.e., prostate-specific antigen, Probasin) expression and activity in LNCaP cells. Here, we examined prosaposin as an ARG. We report that DHT treatment of LNCaP cells increases prosaposin expression. In addition, we demonstrate androgen-responsiveness of prosaposin promoter and AR occupancy to a hormone-responsive element located in the proximal region of the prosaposin promoter. Our data for the first time identify prosaposin as an ARG. This observation, together with the pleiotropic growth factor activity of prosaposin, might suggest a role for this molecule in AR-dependent progression of prostate cancer at its early or late AI-state.

Saposins (sap) A and C activate the degradation of galactosylsphingosine.

As previously shown for [(3)H-galactosyl]ceramide, the breakdown of [(3)H-galactosyl]sphingosine was reduced in prosaposin-deficient skin fibroblast homogenates. Galactosylsphingosine hydrolysis was also deficient in cell homogenates from Krabbe's disease (beta-galactocerebrosidase-deficient) patients, but not acid beta-galactosidase-deficient patients. Moreover, hydrolysis of galactosylsphingosine in the prosaposin-deficient cell homogenates could be partially restored by adding pure saposin A or C, thereby identifying these saposins as essential facilitators of galactosylsphingosine hydrolysis. By contrast, saposins B and D had little effect on galactosylsphingosine hydrolysis in the prosaposin-deficient cells. The reduced galactosylsphingosine turnover in prosaposin-deficiency suggests that there could be a pathogenetic cerebral accumulation of galactosylsphingosine in this disorder.

A retro-inverso Prosaptide D5 promotes a myelination process in developing rats.

The myelinotrophic action of Prosaptide D5 was investigated in developing rats. Sulfatide concentrations in brain and sciatic nerve were determined to assess the development of myelination. Subcutaneous D5-injection significantly increased sulfatide concentrations in both brain and sciatic nerve by 250 and 150% over controls, respectively. D5 promoted ERK phosphorylation in iSC Schwann cells similar to prosaposin. The results showed that D5 treatment stimulated a myelination process in developing rat.

Neuroprotective effect of retro-inverso Prosaptide D5 on focal cerebral ischemia in rat.

Prosaposin (the precursor of saposins A-D) has been identified as a neurotrophic factor in vitro and in vivo. In this study, a novel 11-mer retro-inverso peptidomimetic, Prosaptide D5, was injected i.m. to assess its effectiveness in a rat ischemic model produced by reversible total occlusion of the left middle cerebral artery (MCA). Prosaptide (300 microg/kg, i.m.) injected 3 h after reversible occlusion reduced brain infarct area by 56% compared with a saline group (p < 0.01) at 21 h of reperfusion. A similar injection of D5 6h after occlusion produced a 32% decrease.

Prosaptide D5 reverses hyperalgesia: inhibition of calcium channels through a pertussis toxin-sensitive G-protein mechanism in the rat.

A retro-inverso 11-mer peptidomimetic of prosaposin, Prosaptide D5, induced neurite outgrowth in NS20Y neuroblastoma cells and enhanced [35S]GTPgammaS binding to rat synaptosomal membrane at low nanomolar concentrations similar to prosaposin. Intramuscular injection of D5 ameliorated thermal hyperalgesia in the Seltzer rat model of neuropathic pain, returning paw withdrawal latency to control levels within 3 h after treatment. The effect was sustained for at least 48 h after injection. Prosaposin and D5 inhibited K+-stimulated synaptosomal 45Ca2+ uptake similar to omega-conotoxin MVIIC, demonstrating that both effectors modulated voltage-dependent calcium channels (VDCC); inhibition was largely abolished by pretreatment with pertussis toxin before D5 treatment. The results suggest a mechanism whereby VDCC are modulated by a pertussis toxin-sensitive G-protein coupled receptor; D5 binds to this receptor and thereby ameliorates hyperalgesia in the Seltzer model of neuropathic pain.

Administration of prosaposin ameliorates spatial learning disturbance and reduces cavity formation following stab wounds in rat brain.

The effectiveness of prosaposin as a neurotrophic factor was investigated using rats with bilateral stab wounds, injecting 240 ng per day of prosaposin for 3 days. In Morris water maze task, after 3 weeks postoperation, the stab-wounds rats show significant impairment in acquisition compared with the sham-operated rats. In the transfer test the mean number of crossings of the platform place in stab-wounds was significantly lower than that in sham-operated rats (P < 0.01). The stab-wounds rats treated with prosaposin showed significant improvement (P < 0.05). The cavities following stab wounds in the rats treated with prosaposin were significantly smaller than those in the rats treated with (P < 0.05). Our data support that prosaposin is likely to be a new agent for brain injury.

Prosaposin: a myelinotrophic protein that promotes expression of myelin constituents and is secreted after nerve injury.

Recently, we demonstrated that prosaposin and prosaptides (peptides encompassing the neurotrophic sequence in prosaposin) prevent cell death and increase extracellular regulated kinase (ERK) phosphorylation and sulfatide content in primary Schwann cells or oligodendrocytes (Hiraiwa et al., 1997a). Here, we examine the effect of prosaptide on other myelin constituents, on Schwann cell morphology and proliferation, and characterize the time course of expression of prosaposin protein after sciatic nerve injury. After 24 h of treatment with 10 nM TX14(A), a 14-mer prosaptide, the specific activity of UDP-galactose:ceramide galactosyltransferase (GalT) in primary Schwann cells was increased by 150% over controls. Under the same conditions, the maximum content of sulfatide increased 3-fold over controls after 48 h of treatment. Northern blot analysis, probed with oligonucleotide sequences from the GalT and P0 cDNAs, revealed that the mRNA levels of GalT and P0 protein were elevated about 30 and 200%, respectively, over controls after 24 h of treatment with TX14(A). Treatment of primary Schwann cells with TX14(A) also induced a morphological change at 10 nM; the peptide-treated cells had a bipolar (spindle-shaped) appearance after 48 h of treatment, compared to control cells which were irregular and multipolar. TX14(A) did not induce cell proliferation, indicating that TX14(A), unlike IGF-I, is not mitogenic. After sciatic nerve transection, Western blot analysis demonstrated the presence of intact prosaposin in tubular fluid in a silicon chamber into which the proximal and distal nerve stumps were sutured. The concentration of prosaposin in the fluid was maximum after 9 days post-surgery and returned to normal after 28 days post-surgery. In uninjured and injured nerve, prosaposin immunolocalized to the smooth muscle of epineurial and endoneurial vessels. These findings indicated that sciatic nerve secreted prosaposin after injury and that prosaposin is a naturally occurring injury-repair protein which acts to prevent degeneration and to promote regeneration of peripheral nerves.

Secretion of prosaposin, a multifunctional protein, by breast cancer cells.

Western blotting and immunodetection with three antibodies were used to probe conditioned media of breast cancer cells (MDA231, MDA435, MCF-7) for prosaposin, a lysosomal protein that occurs in milk. It was readily detected in media from these cells, and from that of an sv40-transformed mammary epithelial cell, HBL100, but not from medium of human neural tumor cells (SK-N-MC). In cultures of MCF-7 cells, the prosaposin pattern of secretion over time closely resembled that of procathepsin D, another lysosomal protein occurring in milk. Supplementing medium with 17beta-estradiol (0. 1-100 nM) dose dependently increased secretion of both proteins after 48 h without changes in cell viability. The influence of 17beta-estradiol on secretion could play a role in the trophic activity of prosaposin in cellular differentiation and cell death protection. In concert with other lysosomal proteins in the tumor environment, such as procathepsin D, prosaposin may be a factor in eliminating barriers to tumor metastasis by facilitating hydrolysis of membrane glycolipids. The number of milk proteins known to be secreted by breast cancer cells is growing. There is evidence that at least some of these may be secreted in an endocrine manner in the normal, non-lactating breast.

Cathepsin A/protective protein: an unusual lysosomal multifunctional protein.

Cathepsin A/protective protein [3.4.16.5], carboxypeptidase A, is a lysosomal serine protease with structural homology to yeast (Saccharomyces cerevisiae) carboxypeptidase Y. Cathepsin A is a member of the alpha/beta hydrolase fold family and has been suggested to share a common ancestral relationship with other alpha/beta hydrolase fold enzymes, such as cholinesterases. Several lines of evidence indicate that cathepsin A is a multicatalytic enzyme with deamidase and esterase in addition to carboxypeptidase activities. Cathepsin A was recently identified in human platelets as deamidase. In vitro, it hydrolyzes a variety of bioactive peptide hormones including tachykinins, suggesting that extralysosomal cathepsin A plays a role in regulation of bioactive peptide functions. Recent reports emphasize the lysosomal protective function of cathepsin A rather than its protease function. The protective function of cathepsin A is distinct from its catalytic function. Human lysosomal beta-galactosidase and neuraminidase exist as a high molecular weight enzyme complex, in which there is a 54-kDa glycoprotein termed 'lysosomal protective protein'. Based on cell culture studies, protective protein was found to protect both beta-galactosidase and neuraminidase from intralysosomal proteolysis by forming a multienzyme complex and was shown to be deficient in patients with galactosialidosis, a combined deficiency of beta-galactosidase and neuraminidase. Molecular cloning and gene expression studies have disclosed that protective protein is cathepsin A. The cathepsin A precursor has the potential to restore both beta-galactosidase and neuraminidase activities in fibroblasts from patients with galactosialidosis. Cathepsin A knockout mice showed a phenotype similar to human galactosialidosis and the deficient phenotype found in the mutant mice was corrected by transplanting erythroid precursor cells overexpressing cathepsin A. Collectively, these findings demonstrate the significance of cathepsin A as a key molecule in the onset of galactosialidosis and also highlight the therapeutic potential of the cathepsin A precursor for patients with galactosialidosis.

Colocalization and complex formation between prosaposin and monosialoganglioside GM3 in neural cells.

Prosaposin, the precursor of saposins A, B, C, and D, was recently identified as a neurotrophic factor in vitro as well as in vivo. Its neurotrophic activity has been localized to a linear 12-amino acid sequence located in the NH2-terminal portion of the saposin C domain. In this study, we show the colocalization of prosaposin and ganglioside GM3 on NS20Y cell plasma membrane by scanning confocal microscopy. Also, TLC and western blot analyses showed that GM3 was specifically associated with prosaposin in immunoprecipitates; this binding was Ca2+-independent and not disassociated during sodium dodecyl sulfate-polyacrylamide gel electrophoresis. The association of prosaposin-GM3 complexes on the cell surface appeared to be functionally important, as determined by differentiation assays. Neurite sprouting, induced by GM3, was inhibited by antibodies raised against a 22-mer peptide, prosaptide 769, containing the neurotrophic sequence of prosaposin. In addition, pertussis toxin inhibited prosaptide-induced neurite outgrowth, as well as prosaptide-enhanced ganglioside concentrations in NS20Y cells, suggesting that prosaposin acted via a G protein-mediated pathway, affecting both ganglioside content and neuronal differentiation. Our findings revealed a direct and tight GM3-prosaposin association on NS20Y plasma membranes. We suggest that ganglioside-protein complexes are structural components of the prosaposin receptor involved in cell differentiation.

Prosaposin prevents programmed cell death of rat cerebellar granule neurons in culture.

Prosaposin, the precursor of sphingolipid activator proteins (saposin A-D), has been reported to be a neurotrophic factor in vitro and in vivo. Prosaposin mRNA is transiently expressed at a high level in developing cerebellum during the period of granule cell proliferation and maturation, suggesting its significance during development of cerebellum. Here we investigated the neuroprotective effect of prosaposin on cerebellar granule neurons, exposing primary cerebellar granule cells to low K+ which induced programmed cell death. Prosaposin rescued mature cerebellar granule neurons in a bimodal manner. A similar neuroprotective effect was obtained using TX14(A), a 14-mer neurotrophic peptide derivative of prosaposin. An additive neuroprotective effect was observed between BDNF and TX14(A), but not between IGF-1 and TX14(A). Prosaposin rescued 60% of nifedipine sensitive cerebellar granule neurons as well as IGF-1, while BDNF did not. Furthermore, the neuroprotective action of prosaposin was inhibited by LY294002, a specific inhibitor of PI 3-kinase. These findings indicated that prosaposin had a trophic effect upon newborn cerebellar granule cells and that the neuroprotective action was similar to that of IGF-1 rather than BDNF. Prosaposin may play a role in cerebellar development during programmed cell death of cerebellar neurons.

Gene expression of fucosyl- and sialyl-transferases which synthesize sialyl Lewisx, the carbohydrate ligands for E-selectin, in human breast cancer.

The adhesion of circulating cancer cells to vascular endothelium is an important step in the hematogenous metastasis of cancer. Until recently, it has been believed that carbohydrate antigens are expressed on cancer cells, and E-selectin is expressed on endothelial cells to effect this adhesion. We investigated the gene expression of fucosyl-transferase (Fuc-T) and sialyltransferase (ST), which are involved in the synthesis of sialyl Lewisx (s-Lex) in breast cancer by using Northern blot analysis. The concentration of s-Lex in the cancerous portion was increased, compared to that in the adjacent non-cancerous portion. A correlation was found between the concentration of s-Lex and the amount of Fuc-T VI message in 9 cases of breast cancer tissue. Expression of the Fuc-T III message was found in only one case who expressed s-Lea. No expression of the Fuc-T V or VII message was observed. There was no relationship between the concentration of s-Lex and the amount of ST3N and ST4 transcripts. Similar findings were obtained from an analysis using cell lines derived from human breast cancer. When Fuc-T VI gene was transfected to MCF-7 cells, the expression of s-Lex was markedly induced on MCF-7 cells, and the attachment of cancer cells to endothelial cells was enhanced. These findings suggest that Fuc-T VI is chiefly involved in the synthesis of s-Lex on breast cancer cells.

Cloning, expression and map assignment of chicken prosaposin.

Prosaposin is the precursor of four small glycoproteins, saposins A-D, that activate lysosomal sphingolipid hydrolysis. A full-length cDNA encoding prosaposin from chicken brain was isolated by PCR. The deduced amino acid sequence predicted that, similarly to human and other mammalian species studied, chicken prosaposin contains 518 residues, including four domains that correspond to saposins A-D. There was 59% identity and 76% similarity of human and chicken prosaposin amino acid sequences. The basic three-dimensional structures of these saposins is predicted to be similar on the basis of the conservation of six cysteine residues and an N-glycosylation site. Identity of amino acid sequences was higher among saposins A, B and D than in saposin C. The predicted amino acid sequence of saposin B matched exactly that of purified chicken saposin B protein. The chicken prosaposin gene was mapped to a single locus, PSAP, in chicken linkage group E11C10 and is closely linked to the ACTA2 locus. This confirms the homology between chicken and human prosaposins and defines a new conserved segment with human chromosome 10q21-q24.

Prosaptide activates the MAPK pathway by a G-protein-dependent mechanism essential for enhanced sulfatide synthesis by Schwann cells.

Prosaposin, the precursor of saposins A, B, C, and D, was recently reported to be a neurotrophic factor in vivo and in vitro. The neurotrophic region of prosaposin has been localized to a 12-amino acid sequence within the saposin C domain and has been used to derive biologically active synthetic peptides (14-22 residues), called prosaptides. Treatment of primary Schwann cells and an immortalized Schwann cell line, iSC, with a 14-mer prosaptide, TX14(A) (10 nM), enhanced phosphorylation of mitogen-activated kinases ERK1 (p44 MAPK) and ERK2 (p42 MAPK) within 5 min, which was blocked by 4 h pretreatment with pertussis toxin. Furthermore, incubation of Schwann cells with the nonhydrolyzable GDP analog GDP-betaS inhibited TX14(A)-induced ERK phosphorylation. TX14(A) enhanced the sulfatide content of primary Schwann cells by 2.5-fold, which was inhibited by pretreatment with pertussis toxin or the synthetic MAP kinase kinase inhibitor PD098059. In addition, TX14(A) increased the tyrosine phosphorylation of all three isoforms of the adapter molecule, Shc, which coincided with the association of p60Src and PI(3)K. Inhibition of PI3(K) by wortmannin blocked TX14(A)-induced ERK phosphorylation. These data demonstrate that TX14(A) uses a pertussis toxin-sensitive G-protein pathway to activate ERKs, which is essential for enhanced sulfatide synthesis in Schwann cells.

Prosaposin receptor: evidence for a G-protein-associated receptor.

Prosaposin, the precursor of sphingolipid activator protein (saposins A-D), has been identified as a neurotrophic factor capable of inducing neural differentiation and preventing cell death. The putative prosaposin receptor was partially purified from baboon brain membranes by affinity chromatography using a saposin C-column. The purified preparation gave a single major protein band with an apparent molecular weight of 54 kDa on SDS-PAGE. Affinity cross-linking of 11 kDa 125I-saposin C demonstrated the presence of a 66 kDa product, indicative of an apparent molecular weight of 55 kDa for the receptor. A GTP gamma S-binding assay using cell membranes from SHSY5Y neural cells demonstrated agonist stimulated binding of [35S]-GTP gamma S upon treatment with prosaptide TX14(A) a peptide from the neurotrophic region; maximal binding was obtained at 2 nM. TX14(A) stimulated binding was abolished by prior treatment of SHSY5Y cells with pertussis toxin and by a scrambled and an all D-amino acid-derivative of the 14-mer. A 14-mer mutant prosaptide (6N-->6D) competed with TX14(A) with a Ki of 0.7 nM. Immunoblot analysis using an antibody against the G0 alpha subunit demonstrated that the purified receptor preparation contained a 40 kDa reactive band consistent with association of G0 alpha and the receptor. These findings indicate that the signaling induced by prosaposin and TX14(A) is generated by binding to a G0-protein associated receptor.

Saposins (sap) A and C activate the degradation of galactosylceramide in living cells.

In loading tests using galactosylceramide which had been labelled with tritium in the ceramide moiety, living skin fibroblast lines derived from the original prosaposin-deficient patients had a markedly reduced capacity to degrade galactosylceramide. The hydrolysis of galactosylceramide could be partially restored in these cells, up to about half the normal rate, by adding pure saposin A, pure saposin C, or a mixture of these saposins to the culture medium. By contrast, saposins B and D had little effect on galactosylceramide hydrolysis in the prosaposin-deficient cells. Cells from beta-galactocerebrosidase-deficient (Krabbe) patients had a relatively high residual galactosylceramide degradation, which was similar to the rate observed for prosaposin-deficient cells in the presence of saposin A or C. An SV40-transformed fibroblast line from the original saposin C-deficient patient, where saposin A is not affected, showed normal degradation of galactosylceramide. The findings support the hypothesis, which was deduced originally from in vitro experiments, that saposins A and C are the in vivo activators of galactosylceramide degradation. Although the results with saposin C-deficient fibroblasts suggest that the presence of only saposin A allows galactosylceramide breakdown to proceed at a normal rate in fibroblasts, it remains to be determined whether saposins A and C can substitute for each other with respect to their effects on galactosylceramide metabolism in the whole organism.

Protective protein in the bovine lysosomal beta-galactosidase complex.

Cathepsin A [EC 3.4.16.1], so called protective protein, occurs as an enzyme complex with lysosomal beta-galactosidase [3.2.1.23] and is involved in the stable enzymic expression of lysosomal sialidase [3.2.1.18]. In this study we investigated the enzymatic properties of cathepsin A in the bovine beta-galactosidase complex and how it is involved in the molecular multiplicities of the beta-galactosidase and sialidase complexes. Bovine protective protein homologous to the human protein had a molecular weight of 48 kDa on SDS-PAGE and cathepsin A activity optimum around pH 6.0. It hydrolyzed dipeptide substrates composed of hydrophobic amino acids much faster than any other type of substrate tested. This specificity was found to be conserved from human to a non-mammal, chicken. Immunoprecipitation using an anti beta-galactosidase antibody demonstrated that cathepsin A is a component of both the sialidase and beta-galactosidase complexes. The over 700 kDa sialidase complex depolymerized by a brief incubation at pH 7.5 and the sialidase was inactivated irreversibly via formation of an enzyme active smaller species of sialidase. The 669 kDa beta-galactosidase complex dissociated reversibly into a 120 kDa beta-galactosidase and a 170 kDa cathepsin A, but the 120 kDa beta-galactosidase, free from the cathepsin A, formed a 260 kDa aggregate under the same conditions. Inactivation of cathepsin A by heat treatment did not affect its complex forming activity. The 170 kDa protective protein dissociated into a 50 kDa one at pH 7.5, which no longer formed the complex. These findings indicate that the 170 kDa protective protein could be the minimum unit required for in vitro reconstitution of the complex, and that its complex forming activity is carried in a heat-stable domain. Both beta-galactosidase and cathepsin A activities were labile under the dissociated condition, indicating that it physiologically stabilizes not only beta-galactosidase but also itself by forming the complex.

Lysosomal proteolysis of prosaposin, the precursor of saposins (sphingolipid activator proteins): its mechanism and inhibition by ganglioside.

Saposins A, B, C, and D, which are required for the enzymatic hydrolysis of sphingolipids by specific lysosomal hydrolases, are produced by proteolytic processing of their common precursor protein, prosaposin. Our previous observation suggested that lysosomal cathepsin D may be involved in the proteolysis of prosaposin. Herein we report the involvement of cathepsin D in the proteolytic processing of prosaposin. An antibody against human placental cathepsin D blocked the proteolytic activity toward prosaposin in a human testicular lysosomal protease mixture (glycoprotein fraction). On immunoblot analysis using a monoclonal antibody against human saposin C, cathepsin D showed a similar proteolytic pattern as that of a human testicular glycoprotein fraction and hydrolyzed prosaposin into products of 48 and 29 kDa. The Km and Vmax values were 0.9 microM and 167 nmol/h/mg, respectively. N-Terminal sequence analysis indicated that the 48-kDa band was a mixture of two trisaposins, including domains for saposins A, B, and C and saposins B, C, and D, respectively. A similar study also showed that the 29-kDa band contained two disaposins, including domains for saposins A and B and saposins C and D, respectively. By longer treatment with cathepsin D, disaposins were further processed into mature saposin A and small fragments (14.5-17.5 kDa) containing individual saposins and portions of interdomain sequences. These small fragments were no longer processed by cathepsin D, but trimmed to fragments having similar molecular sizes (10.5-11.5 kDa) to those of mature saposins by a rat lysosome preparation. These findings indicated that cathepsin D is involved in the maturation of saposins but that, in addition to cathepsin D, other proteases appear to be involved in the maturation of saposin B, C, and D in lysosomes. Gangliosides, which specifically form complexes with prosaposin and saposins, inhibit proteolysis of prosaposin by cathepsin D. This finding indicates that prosaposin may be protected from lysosomal proteolysis by forming a complex with gangliosides in vivo.