Very low density lipoprotein hematopoiesis inhibitor from rat plasma

Although the stimulatory effect of specific glycoproteins on bone marrow cell proliferation is acknowledged, little attention has been directed toward growth inhibitors. In this report we have explored the role of plasma lipoproteins in regulating the proliferation of hematopoietic cells. Lipoproteins were isolated from the plasma of normal rats and rats with cancer by density gradient ultracentrifugation. Lipoprotein fractions were then added to cell cultures to assess their effect on: 1) erythropoietin (Ep) stimulated rat marrow DNA and protein synthesis, 2) Ep and colony stimulating factor induced marrow colony formation (CFU(E), CFU(C)), and 3) phytohemagglutinin (PHA) stimulated lymphocyte DNA synthesis. The results indicated that very low density lipoproteins (VLDL) completely inhibited CFU(E) and CFU(C) formation. VLDL inhibited (> 80%) the synthesis of DNA by marrow cells cultured with Ep and lymphocytes cultured with PHA. VLDL from rats with Walker-256 cancer had a greater inhibitory effect than normal rat VLDL. Chylomicrons had moderate growth inhibitory effect, and plasma LDL and HDL were inactive. VLDL, however, did not inhibit the proliferation of rat fibroblasts. We conclude that physiologic concentrations of plasma VLDL have a significant inhibitory effect on the proliferation of erythroid, granulocytic and lymphocytic cells. A pathophysiologic role for VLDL in the impairment of erythropoiesis and immune function in cancer is suggested.     

The effect of parathyroid hormone and atrial natriuretic peptide on cyclic nucleotides production and proliferation of avian epiphyseal growth plate chondroprogenitor cells

Cells derived from avian tibia epiphyseal growth plate were cultured in vitro. The cells which exhibited a polygonal phenotype and are termed chondroprogenitor cells, developed in culture as a monolayer with a doubling time of 40-48 h in 5% fetal calf serum. Production of cAMP by the chondroprogenitor cells was stimulated by human and bovine native (1-84) PTH. The effect of PTH on cAMP production could be blocked by the (3-34) PTH analog, suggesting interaction with specific receptors. cAMP production by avian chondroprogenitor cells was also stimulated by cholera toxin, forskolin, and prostaglandin E2 but not by ACTH or prostaglandin F2 alpha. PTH, cholera toxin, and forskolin also stimulated proliferation of the chondroprogenitor cells. In contrast, neither cAMP production nor proliferation of avian skin fibroblasts was affected by PTH. Human (1-28) and rat (5-28) atrial natriuretic peptide stimulated cGMP production by avian chondroprogenitor cells and also by skin fibroblasts. Atrial natriuretic peptide inhibited the basal and PTH-stimulated [3H]thymidine incorporation into DNA of chondroprogenitor cells, but did not affect avian skin fibroblast proliferation. These results suggest that the proliferation of avian epiphyseal growth plate chondroprogenitor cells is modulated by opposing mechanisms induced by PTH and ANP, probably mediated by cAMP and cGMP, respectively.     

The effects of parathyroid hormone on osteoblast-like cells from embryonic chick calvaria

A bone cell fraction was isolated from 16 day old embryonic chick calvaria using a sequential enzymatic digestion procedure. The fraction contained cells, of an osteoblast-like character, which responded to parathyroid hormone (PTH) and prostaglandin E2, but not to calcitonin, in terms of increased production of cyclic AMP. Primary cultures of cells maintained their responsiveness to PTH for at least 2 weeks after reaching confluence. Production of alkaline phosphatase by the bone cells was inhibited when 1,25(OH)2 vitamin D3 was added to cultures at concentrations of 10(-8)M or greater. When cells were cultured in the presence of PTH a biphasic effect was observed; alkaline phosphatase levels were stimulated at low concentrations of this hormone but were decreased at higher concentrations. The latter finding appears consistent with observations that PTH can in vivo exert either anabolic or catabolic effects on bone, depending upon the circulating level of hormone present.     

Procalcitonin''s amino-terminal cleavage peptide is a bone-cell mitogen.

The parafollicular-cell (C-cell) hormone calcitonin (CT) can preserve or even augment skeletal mass by inhibiting osteoclast-mediated bone resorption. The possibility of an additional anabolic skeletal influence has also been raised: C cells might, via CT or other secretory products, affect osteoblast-mediated bone formation. The 57-residue amino-terminal procalcitonin cleavage peptide, N-proCT, has recently been identified in human and rat C cells, where it is made and secreted in equimolar amounts with CT. The coelaboration of N-proCT and CT and N-proCT's sequence conservation during evolution prompted us to investigate the potential skeletal bioactivity of N-proCT. We found that synthetic human N-proCT, at nanomolar concentrations, stimulated proliferation of normal and neoplastic human osteoblasts. At maximally effective doses, human N-proCT caused more than a 100% increase above the control rate of DNA synthesis, an effect comparable to the maximal growth effect of insulin, a potent mitogen for osteoblasts. Human N-proCT exerted a similar maximal mitogenic effect in chicken osteoblast cultures but at 1000-fold greater concentrations than in human bone-cell cultures. The bone-cell action of N-proCT was potentiated with insulin with a greater than 200% increase in DNA synthesis at high insulin concentrations. In sharp contrast to these findings for N-proCT, the other bioactive C-cell peptides, CT and somatostatin, showed no mitogenic effects in human or chicken osteoblast cultures. Our results indicate that the action of N-proCT on cultured bone cells is separate from and potentiated by insulin, a known growth factor. Unlike insulin and related growth factors such as insulin-like growth factor I, N-proCT is not mitogenic in skin fibroblast cultures. We propose that N-proCT is a C-cell hormone that promotes bone formation via stimulatory actions on osteoblasts and preosteoblasts.     

Evidence that anabolic effects of PTH on bone require IGF-I in growing mice

Although it has been established that PTH exerts potent anabolic effects on bone in animals and humans, the mechanism of PTH action on bone remains controversial. Based on the previous findings that PTH treatment increased production of IGF-I in bone cells and that PTH effects on bone cells in vitro were blocked by IGF-I-blocking antibodies, we proposed that IGF-I action is required for the stimulatory effects of PTH on bone formation. To test this hypothesis, we evaluated the effects of PTH on bone formation parameters in growing mice lacking functional IGF-I genes. Five-week-old IGF-I(-/-) mice and wild-type littermates were given daily sc injections of 160 microg/kg body weight of PTH (1-34) or vehicle for 10 d. In wild-type animals, PTH caused a significant increase in serum osteocalcin levels (113%), serum alkaline phosphatase activity (48%), and alkaline phosphatase activity in femoral bone extracts (>80%), compared with the vehicle-treated control group. In contrast, in IGF-I(-/-) mice, there was no significant effect of PTH on any bone formation parameters. PTH treatment increased total bone mineral density, as evaluated by peripheral quantitative computer tomography, at the distal metaphysis of the femur by 40% in wild-type mice, but it had no effect on bone mineral density in mice lacking functional IGF-I genes. In vitro studies using osteoblasts derived from control and IGF-I(-/-) mice revealed that PTH treatment increased cell number in osteoblasts derived from IGF-I knockout mice in the presence of exogenously added IGF-I but not without IGF-I. These data to our knowledge provide the first direct evidence that the anabolic effects of PTH on bone formation in vivo require IGF-I action in growing mice.     

Platelet-derived growth factor enhances deoxyribonucleic acid and collagen synthesis in osteoblast-enriched cultures from fetal rat parietal bone

Platelet-derived growth factor (PDGF) or closely related proteins are found in bone matrix and are produced by cultured osteosarcoma cells. In serum-deprived osteoblast-enriched (ob) cultures from fetal rat bone, recombinant human PDGF (composed of a B chain homodimer) at 0.1-3 nM enhanced the rate of DNA synthesis by 2- to 8-fold within 24 h of treatment, and 0.3-3 nM PDGF increased cell number by 1.3- to 1.6-fold. Unlike results with rat kidney fibroblast cultures, the mitogenic effect of PDGF in ob cultures was not synergistic with that of insulin-like growth factor I. PDGF at 0.3-10 nM also enhanced the rates of collagen and noncollagen protein synthesis in ob cultures by 1.5- to 4.0-fold, and these increases were blocked when DNA synthesis was prevented. The stimulatory effects of PDGF did not appear specific to ob cultures from fetal rat bone, since similar increases were found in bone cell cultures containing fibroblasts and osteoblast precursors. PDGF binding at 4 C to ob cultures indicated a single class of receptors with a Kd of 0.16 nM and approximately 60,000 sites/cell. Polyacrylamide gel of 125I-PDGF bound and cross-linked to ob cultures revealed a single radioactive band at approximately 180,000-190,000 mol wt. The present studies, therefore, indicate that PDGF can directly increase replication and matrix protein synthesis by both differentiated and undifferentiated bone cells, and that bone- or platelet-derived PDGF may have an important anabolic role in bone remodeling or fracture repair.     

Inhibitory effect of alcohol on osteogenic differentiation in human bone marrow-derived mesenchymal stem cells

BACKGROUND: Alcohol-induced osteoporosis is characterized by a considerable suppression of osteogenesis. The objective of this investigation was to determine the effect of alcohol on gene expression, protein synthesis, and mineralization in human bone marrow-derived mesenchymal stem cells induced toward osteogenic differentiation in vitro. METHODS: Human bone marrow-derived mesenchymal stem cells induced toward osteogenesis were cultured in the presence or absence of 50 mM alcohol. Stem cells were characterized by using SH2 antibody to the cell-surface antigen CD105/endoglin, and their proliferation in the presence of alcohol was quantified. The expression of genes for early, middle, and late markers of the osteogenic lineage was quantified by Northern analysis, and bone matrix protein synthesis was assayed. The effect of alcohol on cell-mediated matrix mineralization in terminally differentiated cultures was determined by von Kossa staining. RESULTS: Fluorescence-activated cell sorting analysis of human mesenchymal stem cells separated with a Percoll gradient proved 99% homogeneity by using SH2 antibody to the surface antigen CD105. Dose-dependent inhibition of proliferation of these stem cells occurred at concentrations greater than 50 mM alcohol. Gene expression of osteoblast-specific factor 2/core binding factor a1 (Osf2/Cbfa1), type I collagen, alkaline phosphatase, and osteocalcin (early, middle, and late markers for osteogenesis, respectively) was analyzed with and without osteogenic induction and treatment with 50 mM alcohol. After induction, Osf2/Cbfa1 levels were unresponsive to alcohol. To determine the effect of alcohol on human mesenchymal stem cell progression along the osteogenic pathway, messenger RNA (mRNA) levels for type I collagen, alkaline phosphatase, and osteocalcin were examined after osteogenic induction. After osteogenic induction, alcohol down-regulated the gene expression of type I collagen and significantly reduced its synthesis. Alcohol did not alter mRNA expression of alkaline phosphatase, a midstage marker for osteogenesis, but significantly decreased its activity compared with osteogenic induction alone. After induction, osteocalcin remained unchanged by alcohol at both the mRNA and protein levels. Histochemistry revealed decreased alkaline phosphatase staining and fewer alkaline phosphatase-positive cells in alcohol-treated human mesenchymal stem cell cultures. von Kossa staining revealed a reduction in the number of mineralizing nodules in stem cell cultures after alcohol treatment. CONCLUSIONS: Collectively, the data suggest that alcohol alters osteogenic differentiation in human bone marrow-derived mesenchymal stem cell cultures during lineage progression and provide further insight into alcohol-induced reduced bone formation.     

Fetal rat chondrocytes sequentially elaborate separate growth- and differentiation-promoting peptides during their development in vitro

Chondrocytes isolated from the calvaria of rat fetuses proliferate and form cartilage when cultured in a chemically defined, serum-free medium, suggesting that they may elaborate self-regulatory factors. Conditioned media obtained from these chondrocytes stimulated DNA synthesis and proliferation when added to separate cultures of chondrocytes and the closely related osteoblast-like cells, but were not very effective in skin fibroblasts isolated from the same fetuses, as judged by [3H]thymidine incorporation and cell proliferation. Chondrocyte-conditioned medium also promoted chondrocyte differentiation, augmenting 35SO4 incorporation, and the accumulation of type II collagen and cartilage-specific proteoglycan. Stimulation of growth and differentiation appears to be attributable to separate activities, released into the medium sequentially by the cultured chondrocytes during their proliferation and maturation phases. Media obtained from growing chondrocytes stimulated growth, but had little effect on 35SO4 incorporation. Media obtained from mature cultures promoted growth as well as 35SO4 incorporation. The mitogenic and sulfation activities were trypsin inhibitable, but exhibited different solubility characteristics and striking differences in their patterns of elution from gel filtration columns. These results suggest that chondrocytes elaborate autostimulatory peptides, the biological activities of which mirror, at least in part, the developmental stage of the donor cells.     

Aging of trabecular meshwork cells of the human eye in vitro

A monolayer cell line established from the trabecular meshwork of a human eye exhibited a limited proliferation potential with about 18 population doublings (PD). There was a gradual increase of the average PD time with increasing PD level. Finally, there was complete growth cessation. These non-replicating cells were larger and more flattened (decrease of the saturation density); they became granulated and finally died off in the course of several months. This growth pattern resembled the senescence phenomenon, as originally described by Hayflick and Moorhead for cultured human fibroblasts. In comparison to proliferating phase-II cultures, senescent cultures revealed reduced glycosaminoglycan synthesis rates with a relative decrease of hyaluronic acid and increase of heparan sulfate. Exogenous (medium-supplied) hyaluronic acid or ascorbic acid stimulated hyaluronic acid synthesis of phase-II cultures.     

Comparison of the bone-resorbing activity in the supernatants from phytohemagglutinin-stimulated human peripheral blood mononuclear cells with that of cytokines through the use of an antiserum to interleukin 1

We compared the bone-resorbing activity in the conditioned medium from phytohemagglutinin (PHA)-stimulated human peripheral blood mononuclear cell cultures with that of partially purified human monocyte-derived interleukin 1 (IL-1), human recombinant IL-1 alpha (pI 5) and IL-1 beta (pI 7), human recombinant tumor necrosis factor-alpha (TNF alpha), and PTH in fetal rat long bone cultures. An antiserum to the products of activated human mononuclear cells, including IL-1, completely blocked the bone-resorbing activity of all three forms of IL-1 and of unfractionated PHA-stimulated human peripheral blood mononuclear cell supernatants, but did not inhibit resorption stimulated by recombinant human TNF alpha. This antiserum also had no effect on the resorptive response to 3 nM PTH, but did decrease the response to 1 nM PTH slightly. These results imply that IL-1, but not TNF alpha, mediates the bone-resorbing activity found in the supernatants of PHA-stimulated human peripheral blood mononuclear cell cultures. It is not known whether the small inhibitory effect that the antiserum to IL-1 had on the response to 1 nM PTH resulted from a nonspecific action or an effect of PTH on local IL-1 synthesis in bone. Since cytokines are found in the circulation of normal individuals and are produced at local sites of pathology, these results suggest that they can influence both normal and abnormal skeletal metabolism.     

Role of advanced glycation endproducts in adynamic bone disease

To clarify the role of AGEs in adynamic bone disease, we investigated the effect of these substances on cultured human osteoblasts and parathyroid cells. AGEs-BSA significantly inhibited parathyroid hormone secretion in response to the low calcium concentration. In HEK-293 cells, expressing calcium-sensing receptors, the same AGE concentration caused a significant potentiation of the extracellular Ca(2+) induced-intracellular calcium concentration. AGEs significantly inhibited the synthesis of type I collagen and osteocalcin in response to stimulation with 1,25(OH)(2)D(3). These data suggest that AGEs are involved in the pathogenesis of adynamic bone disease by inhibiting PTH secretion in response to hypocalcemia and by inhibiting osteoblastic activity.     

Osteo-anabolic effects of human growth hormone with 22K- and 20K Daltons on human osteoblast-like cells.

Human growth hormone with 22,000 Dal (22K-hGH) stimulates proliferation and differentiation of osteoblasts as well as production of interleukin-6 in vitro and bone formation and remodeling in vivo. To investigate whether hGH isoform with 20Kd (20K-hGH), which accounts for 10% of circulating hGH, elicits similar metabolic effects on skeletal tissues, we studied the biological effects of 20K-hGH in cultured human osteoblast-like cells (HOB). HOB were obtained from trabecular bone explants and cultured in alpha-MEM supplemented with 10% FCS. In subconfluent cultures, 22K- and 20K-hGH stimulated [3H]thymidine incorporation by 62 +/- 27% and 63 +/- 23%, respectively (mean +/- SD, n=8, P>0.1). In confluent cultures, 22K- and 20K-hGH increased alkaline phosphatase activity by 38 +/- 23% and 41 +/- 23% (P>0.1), respectively, and increased the osteocalcin concentration in the presence of 10(-9) M 1,25-(OH)2D3 by 50% and 47% (P>0.1), respectively. Furthermore, both hGHs doubled the interleukin-6 (IL-6) concentration in the conditioned medium. RT-PCR analysis revealed that 22K- and 20K- hGH increased IL-6 gene expression 2.2 +/- 0.6 and 2.4 +/- 0.7 -fold, respectively. In summary, we have demonstrated that 20K-hGH elicits equipotent anabolic effects on HOB and stimulates to the same extent the production of IL-6, a cytokine which initiates osteoclastogenesis. These in vitro findings suggest that 22K- and 20K-hGH may equipotently stimulate bone remodeling and elicit anabolic effects on skeletal tissue when administered in vivo.     

Effects of physiological concentrations of parathyroid hormone on acid phosphatase activity in cultured rat bone cells

The mechanism by which parathyroid hormone (PTH) induces osteoclastic bone resorption is still incompletely understood. Recent evidence suggests that the hormone exerts its effects indirectly, via the osteoblasts. Bone cells isolated from fetal rat calvaria by enzymatic digestion were used. Two heterogeneous cell populations were isolated by equilibrium density centrifugation on Percoll gradients and maintained by differential culture conditions. These two populations, which are morphologically distinguishable from one another by light and electron microscopy, have been characterized previously both biochemically and with regard to their hormonal (PTH and calcitonin) responses. We have called them type C cells (containing cells with some of the properties of osteoclasts) and type B cells (containing osteoblast-like cells, as well as fibroblasts, chondrocytes and other stromal cells). In the present study, we have further characterized the functional relationship between the two cell populations, with particular regard to the hormonal responses of type C cultures. Acid phosphatase, measured cytochemically in individual cells, was used as a marker for C cell responses. C cells had significantly higher levels of acid phosphatase activity than either B cells or spleen macrophages. Calcitonin (0-10 pg/ml) decreased C cell acid phosphatase activity but was without effect on B cells or spleen macrophages. Co-culture of C cells with B cells produced increased enzyme activity only in the former; this effect could be mimicked if fibroblasts replaced B cells and cell contact was essential for this response. PTH (0-10 pg/ml) raised enzyme activity further in C cells only when they were cultured with B cells. When C cells were cultured so that they shared medium, but were not in contact, with B cells, PTH (2 pg/ml) still increased enzyme activity in the former. Fibroblasts were ineffective in this system. Spleen macrophages were also unresponsive to PTH when substituted for C cells. Calcitonin (10 pg/ml) blocked the effects of PTH on C cells. These results indicate that macrophages are probably not a significant proportion of the C cell population, and that PTH may produce increased acid phosphatase activity in C cells via a humoral factor produced by cells present in B cell cultures.     

Androgens directly stimulate proliferation of bone cells in vitro

This report describes the first observation of a direct mitogenic effect of androgens on isolated osteoblastic cells in serum-free culture. [3H]thymidine incorporation into DNA and cell counts were used as measures of cell proliferation. The percentage of cells that stained for alkaline phosphatase was used as a measure of differentiation. Dihydrotestosterone (DHT) enhanced mouse osteoblastic cell proliferation in a dose dependent manner over a wide range of doses (10(-8) to 10(-11) molar), and was maximally active at 10(-9) M. DHT also stimulated proliferation in human osteoblast cell cultures and in cultures of the human osteosarcoma cell line, TE89. Testosterone, fluoxymesterone (a synthetic androgenic steroid) and methenolone (an anabolic steroid) were also mitogenic in the mouse bone cell system. The mitogenic effect of DHT on bone cells was inhibited by antiandrogens (hydroxyflutamide and cyproterone acetate) which compete for binding to the androgen receptor. In addition to effects on cell proliferation, DHT increased the percentage of alkaline phosphatase (ALP) positive cells in all three bone cell systems tested, and this effect was inhibited by antiandrogens. We conclude that androgens can stimulate human and murine osteoblastic cell proliferation in vitro, and induce expression of the osteoblast-line differentiation marker ALP, presumably by an androgen receptor mediated mechanism.     

Parathyroid hormone stimulates release of insulin-like growth factor-I (IGF-I) and IGF-II from neonatal mouse calvaria in organ culture

Effects of increased bone resorption on release of insulin-like growth factor-I (IGF-I) and IGF-II into the osteoblast microenvironment were investigated using neonatal mouse calvaria organ cultures. Release of these growth factors from calvaria into serum-free medium was quantitated using a human IGF-I RIA and human IGF-II RRA. Untreated calvaria released several-fold more IGF-II than IGF-I. PTH (from 1-12 nM) stimulated a dose-dependent increase in the release of both growth factors that correlated with increased calcium release and was sustained for up to 6 days. IGF-I and IGF-II release were maximally stimulated 5- to 10-fold and 1.5- to 2-fold, respectively, compared to untreated control values. Calcitonin inhibited PTH-stimulated resorption, but had no effect on PTH stimulation of IGF-I and IGF-II release, suggesting that PTH effects on IGF-I and IGF-II release were not dependent on resorption. Furthermore, the amounts of IGF-I and IGF-II released from calvaria during 6 days of culture were 5-fold more than the amounts of IGF-I and IGF-II present in the calvaria (bone plus cells) at the beginning of culture, suggesting that much of the IGF-I and IGF-II released was newly produced by calvaria cells. The results suggest that PTH directly stimulated calvarial osteoblasts to release IGF-I and IGF-II. Since IGF-I and IGF-II stimulate osteoblastic cell proliferation, the effect of PTH on the release of these and other growth factors may mediate coupling of bone formation to bone resorption.     

Actions of recombinant human gamma-interferon and tumor necrosis factor alpha on the proliferation and osteoblastic characteristics of human trabecular bone cells in vitro

Using cultured human osteoblast-like cells, we studied the effects of tumor necrosis factor (TNF) and recombinant human gamma-interferon (gamma-IFN) on osteoblast growth and function, and demonstrated that TNF stimulated bone cell proliferation and prostaglandin production while inhibiting 1,25-(OH)2D3-stimulated alkaline phosphatase activity and osteocalcin release. In contrast, gamma-IFN inhibited proliferation and stimulated alkaline phosphatase activity of the cells, while inhibiting 1,25-(OH)2D3-stimulated osteocalcin production and having variable effects on the release of prostaglandins, depending on the presence of other factors. Our results suggest that TNF and gamma-IFN can act directly on bone-forming cells to affect both their proliferation and their differentiated function, and that changes in the ability of cells to produce these factors in disease states may contribute to alterations in the integrity of connective tissue matrices.     

Heteroploid conversion of human skin cells by methylcholanthrene.

Cultured epithelial cells from human skin generally had 3- to 30-fold more hydrocarbon-metabolizing activity than fibroblasts from skin of the same donor. This activity was constant for up to 55 days in primary culture but was lost rapidly upon physical subdivision of the cultures. Treatment of primary mixed fibroblasts and epithelial cell cultures with methylcholanthrene, but not phenanthrene, led to development of actively growing fibroblastic cultures with many heteroploid cells. Unique marker chromosomes, stable over a number of cell population doublings, were identified in several of the heteroploid cell strains. Pure cultures of fibroblasts from the same donors did not undergo heteroploid conversion in response to methylcholanthrene. Spontaneously occurring heteroploidy in logarithmic phase human fibroblasts is a rare event; thus, heteroploid conversion may be a useful marker for chemical transformation of human cells. Because methylcholanthrene seems to have little transforming effect on human skin fibroblasts, human skin epithelial cells, because of their hydrocarbon-metabolizing activity, may serve to convert methylcholanthrene from a distal to an ultimate carcinogenic form.     

Parathyroid hormone-related protein modulates the effect of transforming growth factor-beta on deoxyribonucleic acid and collagen synthesis in fetal rat bone cells

Proteins with biochemical function and sequence similarity to PTH are produced by many tumors associated with hypercalcemia and may have a role in pathological bone remodeling. Synthetic polypeptides comprising the amino-terminus of human PTH-related protein (PTH-rp) were examined for effects in intact fetal rat calvariae, and in osteoblast-enriched (ob) cultures isolated from fetal rat parietal bone. In cultured calvariae, 0.5-5 nM PTH-rp stimulated [3H]thymidine incorporation into DNA by 25-70% after 24 h of treatment and decreased relative [3H]proline incorporation into collagen by 50%; the inhibitory effect on collagen production was not altered by hydroxyurea, which decreased DNA synthesis by 85%. PTH-rp also increased [3H]hydroxyproline levels by 100% in culture medium from bones prelabeled with [3H]proline, indicating accelerated matrix turnover. In contrast to results in intact calvariae, PTH-rp had little effect on basal DNA and collagen synthesis in serum-deprived ob cultures. However, when ob cultures were treated with transforming growth factor type beta at concentrations similar to those found in calvarial culture medium, 0.02-2 nM PTH-rp enhanced DNA synthesis and decreased collagen production. Furthermore, equimolar PTH-rp and PTH concentrations similarly displaced 125I-PTH-rp binding and enhanced cAMP synthesis in ob cultures. These studies suggest that PTH-rp regulates osteoblastic cell activity primarily through PTH-related pathways and may act in part by modulating the effects of locally produced transforming growth factor-beta in bone.     

Actions of recombinant human γ-interferon and tumor necrosis factor α on the proliferation and osteoblastic characteristics of human trabecular bone cells in vitro

Using cultured human osteoblast-like cells, we studied the effects of tumor necrosis factor (TNF) and recombinant human γ-interferon (γ-IFN) on osteoblast growth and function, and demonstrated that TNF stimulated bone cell proliferation and prostaglandin production while inhibiting 1,25-(OH)₂D₃—stimulated alkaline phosphatase activity and osteocalcin release. In contrast, γ-IFN inhibited proliferation and stimulated alkaline phosphatase activity of the cells, while inhibiting 1,25-(OH)₂D₃—stimulated osteocalcin production and having variable effects on the release of prostaglandins, depending on the presence of other factors. Our results suggest that TNF and γ-IFN can act directly on bone-forming cells to affect both their proliferation and their differentiated function, and that changes in the ability of cells to produce these factors in disease states may contribute to alterations in the integrity of connective tissue matrices.     

Endothelial cells stimulate proliferation of human thyroid epithelial cells

The present study was undertaken to investigate cellular interactions between human thyroid epithelial cells (thyrocytes) and endothelial cells. Normal thyrocytes were cultured with either mitomycin C-treated endothelial cells or mitomycin C-treated human foreskin fibroblasts. The proliferative responses of thyrocytes were markedly stimulated by endothelial cells, but not by skin fibroblasts. The proliferative response of the thyrocytes obtained from patients with Graves' disease were similar to that of normal thyrocytes. Furthermore, the cell number of thyrocytes in endothelial cell-thyrocyte co-culture was markedly increased as compared with that in thyrocytes alone. The culture medium of endothelial cells only partly had any effect in the endothelial cell-thyrocyte co-culture experiment. Indomethacin, a cyclooxygenase inhibitor, did not increase the endothelial cells-induced thyrocyte proliferation. Furthermore, the increased proliferative response of thyrocytes stimulated by endothelial cells was not suppressed by heparin. These results suggest that endothelial cells increase thyrocyte proliferation, and that cell contact or extracellular matrix production by endothelial cells may play an important role in the proliferation of thyrocytes.