Extracellular matrix degrading enzymes at the prostasome surface.

Prostasomes, prostatic secretory vesicles found in human ejaculates, were analyzed to verify the existence at their surfaces of enzymes involved in the degradation of the extracellular matrix. Findings were compared with those of prostasomes isolated from two human adenocarcinoma cell lines that reflect clinical features and molecular pathways of androgen-insensitive and hormone-responsive prostate cancer. Our aim was to determine whether neoplastic transformation is accompanied by changes of glycosidase and protease activities. Our results show that decreases of dipeptidyl peptidase IV and increases of urokinase plasminogen activator and cathepsin B are consistent with the clinical features of the cell lines, whereas increases of glycosidase activities seem to be of scarce biological significance.

Promoter characterization and expression of the gene coding for the human GM2 activator protein.

Genomic clones of the human GM2 activator protein have been isolated and analyzed. The 5' region of the gene demonstrated promoter activity as ascertained by its ability to drive luciferase gene expression in transfected COS cells. This sequence contains GC rich region and several putative promoter elements were present, including Sp1, AP2, cAMP-responsive element, and B-cell-specific activating protein. Analysis of tissue distribution of the GM2 activator protein gene revealed tissue-specific variations in transcript levels. Placenta, bone marrow, mammary gland, bladder, lymph node, and spleen had the highest mRNA levels.

beta-hexosaminidase, alpha-D-mannosidase, and beta-mannosidase expression in serum from patients with carbohydrate-deficient glycoprotein syndrome type I.

The activity of beta-hexosaminidase, determined with 4-methylumbelliferyl-beta-N-acetylglucopyranoside substrate, and of beta-D-mannosidase was significantly higher in the serum of patients with carbohydrate-deficient glycoprotein (CDG) syndrome type IA (phosphomannomutase deficiency) than in controls. No significant differences were observed in the activity of beta-hexosaminidase, determined using 4-methylumbelliferyl-beta-N-acetylglucopyranoside-6-sulphate as substrate, and the activity of alpha-D-mannosidase. Using DEAE-cellulose chromatography, a greater amount of hexosaminidase B than hexosaminidase A was detected in CDG serum. In CDG serum, hexosaminidase A was eluted in a more basic position in the salt gradient. An isoenzyme of alpha-D-mannosidase and beta-D-mannosidase was identified in control and CDG sera. alpha-D-Mannosidase isoenzyme was eluted in a slightly more basic position in CDG serum than in control serum, whereas beta-D-mannosidase isoenzyme was eluted in the same position.

M-CSF neutralization and egr-1 deficiency prevent ovariectomy-induced bone loss.

Increased stromal cell production of M-CSF, an event caused by enhanced phosphorylation of the nuclear protein Egr-1, is central to the mechanism by which estrogen (E2) deficiency upregulates osteoclast (OC) formation. However, the contribution of enhanced M-CSF production to the bone loss induced by E2 deficiency remains to be determined. We found that treatment with an Ab that neutralizes M-CSF in vivo completely prevents the rise in OC number, the increase in bone resorption, and the resulting bone loss induced by ovariectomy (ovx). We also found that adult, intact Egr-1-deficient mice, a strain characterized by maximally stimulated stromal cell production of M-CSF, exhibit increased bone resorption and decreased bone mass. In these mice, treatment with anti-M-CSF Ab restored normal levels of bone resorption, thus confirming that increased M-CSF production accounts for the remodeling abnormalities of Egr-1-deficient mice. Consistent with the failure of ovx to further increase M-CSF production in Egr-1-deficient mice, ovx neither increased bone resorption further, nor caused bone loss in these animals. In summary, the data demonstrate that E2 deficiency induces M-CSF production via an Egr-1-dependent mechanism that is central to the pathogenesis of ovx-induced bone loss. Thus, Egr-1 and M-CSF are critical mediators of the bone sparing effects of E2 in vivo.

Age-related cortical bone loss at the metacarpal.

In order to evaluate in vivo the entity of endosteal and periosteal changes with age in the two sexes, and their relative contribution to age-related cortical bone loss, we undertook a cross-sectional study on a population of normal Caucasian subjects. The group included 189 women and 107 men who were studied by photodensitometry and radiogrammetry of the second metacarpal bone, derived from the same standard hand X-ray. Of the subjects, 134 were 65 years of age or older (75 women and 59 men). Metacarpal bone mineral density (BMD) correlated with age in both sexes, with an annual bone loss rate of 0.5% in women and 0.15% in men. In the over 65 group, correlation was significant only in women, who underwent an acceleration in the rate of bone loss (1% per year). Marrow cavity width (M), cortical index at the second metacarpal shaft (MI) and external width (W) all correlated with age in both sexes, although generally better in the female than in the male sex. M almost doubled from the fourth to the ninth decade in women and increased 50% in men. In the same age interval, MI showed an annual decrease of 0.49% in females and 0.33% in males. In the over 65 group, cortical thinning rate was significant in women (0.39% per annum) but not in men (0.14% per annum), whereas correlation of W was not significant in either sex. Finally, MI correlated with BMD in the whole study population and in the over 65, with a female prevalence in correlation strength maintained throughout life. The following conclusions can be derived for metacarpal aging: (1) an acceleration in cortical bone loss occurs in females after age 65; (2) age-related growth in periosteal diameter, although significant in the whole population, is negligible in the elderly of both sexes; (3) age-related cortical bone loss is generally more dependent on cortical thinning in women than in men.

Cathepsin B activity in normal human osteoblast-like cells and human osteoblastic osteosarcoma cells (MG-63): regulation by interleukin-1 beta and parathyroid hormone.

Cathepsin B activity and its regulation by interleukin 1 beta (IL-1 beta) and parathyroid hormone (PTH) was investigated in normal human osteoblast-like cells (hOB) and in the human osteoblastic osteosarcoma cell line MG-63. Cathepsin B activity was measured using a fluorescent synthetic substrate, 7-N-benzyloxycarbonyl-L-arginyl-L-arginylamide-4-methylcoumarin, and its specificity was checked with E-64, a specific inhibitor of cysteine proteinases and CA074, a specific inhibitor of the enzyme. Cathepsin B activity was detected in crude extracts of cell monolayers and in conditioned media. In both cell types, basal activity was detected essentially in cell extracts, since in media only approximately 1.2% (hOB) and approximately 6% (MG-63) of the total activity was released. IL-1 beta (1-100 U/ml) and PTH (10(-9) M-10(-6) M) significantly stimulated cathepsin B activity in cell extracts and in conditioned media. In both cell types, the increase in proteolytic activity appeared to require RNA and protein synthesis after adding IL-1 beta or PTH. Using the above substrate, we also evaluated some biochemical properties of the enzyme, and its pH-stability and pH-optimum. In both cell types, intracellular cathepsin B activity was not resistant to neutral or slightly alkaline pH, whereas extracellular cathepsin B activity was stable. This study provides evidence that osteoblast-like cells produce and secrete active cathepsin B. The production and secretion was stimulated by IL-1 beta and PTH. The physiological role of cathepsin B produced by osteoblasts and stimulated by the bone resorbing agents remains to be elucidated. Since extracellular activity is stable under relatively physiological conditions, it is possible that the extracellular as well as intracellular form of the enzyme may play a role in matrix turnover.

Appendicular cortical bone loss after age 65: sex-dependent event?

Distal radius photodensitometric and second metacarpal radiogrammetric measurements were obtained from computerized analyses of standard hand X-Ray films of 296 Caucasian subjects (189 women and 107 men). This sample included 134 subjects > or = 65 years old (75 women and 59 men). Distal radius bone density and metacarpal index showed a significant linear decrease with age in both sexes. Rates of bone loss, calculated from the regression curves, were -0.7% per year in women and -0.5% per year in men by distal radial photodensitometry, and -0.49% per year in women and -0.33% per year in men by metacarpal radiogrammetry. In the elderly subgroup, women > or = 65 years of age showed an even faster bone loss, with an annual decrease of -1.4% by distal radial photodensitometry. Conversely, men > or = 65 years of age had no significant bone loss, not even by metacarpal radiogrammetry. In conclusion, these data suggest that appendicular cortical bone loss occurs at a higher rate in elderly females than in the elderly males, both at the distal radial and at the metacarpal site.

Immunocytochemical localization of S-100 beta beta protein in olfactory and supporting cells of lamb olfactory epithelium.

By immunocytochemistry, we have identified two novel cell types, olfactory and supporting cells of lamb olfactory epithelium, expressing S-100 beta beta protein. S-100 immune reaction product was observed on ciliary and plasma membranes, on axonemes and in the cytoplasm adjacent to plasma membranes and to basal bodies of olfactory vesicles. A brief treatment of olfactory mucosae with Triton X-100 before fixation is necessary for detection of S-100 beta beta protein within olfactory vesicles. In the absence of such a treatment, the immune reaction product is restricted to ciliary and plasma membranes. On the other hand, irrespective of pre-treatment of olfactory mucosae, S-100 beta immune reaction product in supporting cells is restricted to microvillar and plasma membranes. The anti-S-100 beta antiserum used in these studies does not bind to basal cells of the olfactory epithelium or to cells of the olfactory glands, whereas it binds to Schwann cells of the olfactory nerve. An anti-S-100 alpha antiserum does not bind to cellular elements of the olfactory mucosa, Schwann cells, or axons of the olfactory nerve. The present data provide, for the first time, evidence for the presence of S-100 beta beta protein in mammalian neurons (olfactory cells).

S-100a0 protein stimulates Ca2+-induced Ca2+ release from isolated sarcoplasmic reticulum vesicles.

S-100a0 protein, the alpha alpha-isoform of the S-100 family, stimulates Ca2+-induced Ca2+ release from terminal cisternae isolated from rat skeletal muscle cells. The stimulatory effect of S-100a0 is maximal at approximately 5 microM S-100a0 and half maximal at approximately 0.1 microM S-100a0, at 1.8 microM free Ca2+ in the presence of 5 mM Mg2+ plus 0.1 M KCl. The effect of the protein on Ca2+-induced Ca2+ release is completely inhibited by the calcium release blocker, ruthenium red.

Molecular interaction of S-100 proteins with microtubule proteins in vitro.

Several procedures were employed to examine the in vitro interaction between S-100 proteins and microtubule proteins. Binding of S-100 to tau factors was observed under all experimental conditions. S-100 binding to microtubule-associated protein 2 (MAP2) was best detected by exposing nitrocellulose-immobilized MAP2 or MAPs to either 125I-labeled S-100 or biotinylated S-100. S-100 binding to tubulin was detected when the two protein fractions were first incubated with each other followed by exposure to the bifunctional cross-linker disuccinimidylsuberate, and then separated by sodium dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE) and transfered onto nitrocellulose paper. By this procedure, complex formation between S-100 and tubulin, as well as between S-100 and a relatively low-molecular-weight MAP, was evidenced by immunoblotting using an anti-S-100 antiserum. Alternatively, complex formation between biotinylated S-100 and either tubulin or MAPs was visualized by means of avidin-peroxidase, after SDS-PAGE of the complex mixtures and transfer of the separated proteins onto nitrocellulose. The interaction between S-100 and tubulin was strictly Ca2+ dependent, and resistant to high concentrations of KCl, colchicine, or vinblastine.

S-100a0 protein stimulates the basal (Mg2+-activated) adenylate cyclase activity associated with skeletal muscle membranes.

S-100a0 protein, the alpha alpha isoform of the S-100 family, stimulates basal (Mg2+-activated) adenylate cyclase (AC) activity associated with the sarcolemma, longitudinal tubules and terminal cisternae of rat skeletal muscle cells. The stimulatory effect of S-100a0 on AC activity is maximal around 5 microM S-100a0 and half-maximal around 0.2 microM S-100a0. Also, the stimulatory effect is greatest on the AC activity associated with the terminal cisternae than on the other membrane fractions studied. These data are discussed in relation to the subcellular localization of S-100a0 in muscle cells.

Identification of S-100 proteins and S-100-binding proteins in a detergent-resistant EDTA/KCl-extractable fraction from bovine brain membranes.

The Triton X-100-resistant residue of brain membranes contains appreciable amounts of S-100 proteins. This fraction of S-100 can be solubilized by high concentrations of EDTA plus or minus high concentrations of KCl. Whereas KCl (0.6 M) extracts the detergent-resistant S-100, NaCl (1 M) does not. Endogenous Ca2+ is required and is sufficient for S-100 to remain associated with the detergent-resistant residue. However, 0.6 M KCl extracts a further fraction of Triton X-100-resistant S-100. In contrast, the Triton X-100-extractable fraction of S-100 resists the action of EDTA. These data suggest that Ca2+ regulates the extent of association of S-100 with Triton X-100-resistant components in brain membranes, whereas the association of S-100 with the lipid bilayer of brain membranes and/or with some intrinsic membrane proteins is less Ca2+-regulated. Several S-100-binding proteins are identified in the detergent-resistant residue of brain membranes by an overlay procedure.

Immunocytochemical localization of S-100b protein in degenerating and regenerating rat sciatic nerves.

We studied the cellular and subcellular distribution of S-100b protein in normal, crushed, and transected rat sciatic nerves by an immunocytochemical procedure. In uninjured nerves, S-100b protein was restricted to the cytoplasm and membranes of Schwann cells, with no reaction product present in the nucleus or in axons. Similar images were seen from the first to the thirtieth day after the crush in activated Schwann cells during the degeneration period, i.e., up to the seventh post-lesion day, and in normal Schwann cells reappearing during the regeneration period, i.e., after the seventh post-lesion day, in the zone of the crush and proximal and distal to it. By the technique employed, there seemed to be no differences in the intensity of the immune reaction product in normal and activated Schwann cells. Also, similar images were seen in the proximal stump of transected nerves. Only a slight S-100b protein immune reaction product could be observed in the rare activated Schwann cells present in the distal stump around the seventh post-lesion day, the majority of cell types being represented by fibroblasts and elongated cells at this stage and thereafter. By immunochemical assays, similar results as those presented here have been reported and interpreted as indicative of the presence of S-100 protein in axons or, alternatively, of axonal control over expression of S-100 protein in Schwann cells. Our immunocytochemical data clearly show that the strong reduction in the S-100 protein content of the distal stump of transected nerves is owing to the paucity of Schwann cells and to the decrease in the S-100 protein content of these cells, rather than to degeneration of axons.

Cardiac S-100a0 protein: purification by a simple procedure and related immunocytochemical and immunochemical studies.

A simple procedure is described for the purification of the alpha alpha isoform of S-100 proteins (S-100a0) from porcine heart. Purification steps include the following: i) extraction of the tissue with a hypotonic medium containing EDTA; ii) ammonium sulfate fractionation (0-50%) of the extract; iii) Ca2+-dependent affinity chromatography of the supernatant obtained through the preceding step on phenyl-sepharose and elution of absorbed proteins through a two-chamber gradient of 1.0-0.0 mM CaCl2 and 0.0--1.0 mM EGTA, respectively; and iv) chromatography of the resultant S-100-containing fractions on Sephadex G-200. The yield is 20 mg S-100a0/kg porcine heart. The whole procedure takes five days and is highly reproducible. Data obtained from the phenyl-sepharose step suggest that the affinity of Ca2+ for S-100a0 increases by several orders of magnitude once the protein had interacted with that matrix. This observation is discussed in relation to the role of S-100 proteins in amplification of the Ca2+ signal. Immunocytochemical and immunoblotting analyses indicate that S-100a0 is exclusively found at the level of the sarcolemmal membranes, the membranes of the sarcoplasmic reticulum, the external mitochondrial membranes, and in the adjacent sarcoplasm. No evidence of S-100a0 being associated with the nuclei or with myofibrils has been obtained. Finally, the cardiac tissue does not contain the Triton X-100-extractable fraction of S-100 normally detected in the brain and in adipocytes. Our data suggest that S-100a0 behaves as a peripheral membrane protein in cardiac tissue.

S-100b protein regulates the activity of skeletal muscle adenylate cyclase in vitro.

We have investigated the effect of the b isoform of S-100 proteins on adenylate cyclase activity of rat skeletal muscle. S-100b inhibits the adenylate cyclase activity in the presence of Mg2+ (5.0-50 mM), while it activates the same enzyme in the presence of Ca2+ (0.1-1.0 mM) dose-dependently in both cases. S-100b counteracts the stimulatory effect of NaF on adenylate cyclase in the presence of Mg2+ and the inhibitory effect of RMI 12330 A in the presence of Ca2+.

Purification and characterization of four different alkaline phosphatases from Spirographis spallanzanii.

Alkaline phosphatases (APs) present in Spirographis spallanzanii were extracted by water homogenization of butanol treatment. The enzymes solubilized as above were purified by acetone fractionation and then by DEAE-cellulose and Sephadex G-200 chromatography; separation of four AP forms was achieved, which were characterized by studying their molecular and catalytic properties. The various APs differ in molecular weight, electrophoretic mobility, optimum pH, but show similar Km values and substrate inhibition pattern. Kinetic studies carried out with several inhibitors show, in particular, the existence in these APs of a second binding site and suggest a possible role for them in the metabolism of phosphoric esters of the sugars.

Partial purification and characterization of an alkaline phosphatase in Helix nemoralis and in Octopus vulgaris.

1. Alkaline phosphatase (AP) present in the liver of Helix nemoralis and of Octopus vulgaris; enzyme was purified by homogenization, ultracentrifugation, n-butanol treatment, acetone fractionation and Sephadex G-200 chromatography. 2. The two enzymes show a similar enzyme-substrate affinity, but differ in several properties (molecular weight, electrophoretic mobility, optimum pH, substrate inhibition); a possible correlation of them with different evolutionary adaptations is suggested. 3. Possible roles of AP in Mollusca are discussed.