The ion-binding characteristics of reconstituted collagen

The ion-binding capacity of highly purified reconstituted calf-skin collagen, and the effects of these ions on the precipitation and solubility of the collagen, were studied with a variety of salt solutions at ionic strength 0.16 and pH7.4. Only a small percentage of the total theoretically available anionic and cationic groups was available for ion-binding. In view of this, it appears that most of the ionizable groups of collagen are involved in intramolecular or intermolecular linkages, or both. Nevertheless, marked differences in the binding of the various ions by collagen were observed. Bivalent cations were bound in extremely small but remarkably similar quantities. In contrast, sodium was bound both in much higher and more variable quantities. Of the anions, pyrophosphate and sulphate were bound in the largest quantities, followed by phosphate, fluoride and chloride, in that order. Despite the minimal uptake by collagen of bivalent cations, they prevented the aggregation of tropocollagen into fibrils, and disaggregated fibrillar collagen. In the presence of multivalent anions, tropocollagen aggregated readily and its fibrillar stability was maintained. On the basis of the imbalance in the binding of ion pairs by the sodium pyrophosphate- and sodium phosphate-treated collagens, it was apparent that a reduced number of side-chain carboxyl groups were dissociated in the presence of these salts.

Effects of 24R,25- and 1α,25-dihydroxyvitamin D3 on mineralizing growth plate chondrocytes

Time- and dosage-dependent effects of 1,25(OH)(2)D(3) and 24,25(OH)(2)D(3) on primary cultures of pre- and post-confluent avian growth plate (GP) chondrocytes were examined. Cultures were grown in either a serum-containing culture medium designed to closely mimic normal GP extracellular fluid (DATP5) or a commercially available serum-free media (HL-1) frequently used for studying skeletal cells. Hoechst DNA, Lowry protein, proteoglycan (PG), lactate dehydrogenase (LDH), and alkaline phosphatase (ALP) activity and calcium and phosphate mineral deposition in the extracellular matrix were measured. In preconfluent cultures grown in DATP5, physiological levels of 24,25(OH)(2)D(3) (0.10-10 nM) increased DNA, protein, and LDH activity significantly more than did 1,25(OH)(2)D(3) (0.01-1.0 nM). However, in HL-1, the reverse was true. Determining ratios of LDH and PG to DNA, protein, and each other, revealed that 1,25(OH)(2)D(3) specifically increased PG, whereas 24,25(OH)(2)D(3) increased LDH. Post-confluent cells were generally less responsive, especially to 24,25(OH)(2)D(3). The positive anabolic effects of 24,25(OH)(2)D(3) required serum-containing GP-fluid-like culture medium. In contrast, effects of 1,25(OH)(2)D(3) were most apparent in serum-free medium, but were still significant in serum-containing media. Administered to preconfluent cells in DATP5, 1,25(OH)(2)D(3) caused rapid, powerful, dosage-dependent inhibition of Ca(2+) and Pi deposition. The lowest level tested (0.01 nM) caused >70% inhibition during the initial stages of mineral deposition; higher levels of 1,25(OH)(2)D(3) caused progressively more profound and persistent reductions. In contrast, 24,25(OH)(2)D(3) increased mineral deposition 20-50%; it required >1 week, but the effects were specific, persistent, and largely dosage-independent. From a physiological perspective, these effects can be explained as follows: 1,25(OH)(2)D(3) levels rise in hypocalcemia; it stimulates gut absorption and releases Ca(2+) from bone to correct this deficiency. We now show that 1,25(OH)(2)D(3) also conserves Ca(2+) by inhibiting mineralization. The slow anabolic effects of 24,25(OH)(2)D(3)are consistent with its production under eucalcemic conditions which enable bone formation. These findings, which implicate serum-binding proteins and accumulation of PG in modulating accessibility of the metabolites to GP chondrocytes, also help explain some discrepancies previously reported in the literature.

Thyroid hormone inhibits growth and stimulates terminal differentiation of epiphyseal growth plate chondrocytes

As a continuation of our studies on mineralization in epiphyseal growth plate (GP) chondrocyte cultures, the effects of tri-iodothyronine (T3) in both beta-glycerophosphate-containing, serum-free (HL-1) and beta-glycerophosphate-free, serum-containing medium (DATP5) were studied. The GP cells responded to T3 in a serum-, stage-, and dosage-dependent manner. Added at graded levels (0.1-10.0 nM) to preconfluent cultures (from day 7) in both HL-1 and DATP5, T3 caused progressive decreases in protein, collagen, and DNA synthesis but increased mineral deposition. In postconfluent cultures, these effects of T3 were generally muted. In preconfluent cultures, proteoglycan (PG) levels were not significantly affected in DATP5, although in HL-1 they were decreased by approximately 50%. In postconfluent cultures, T3 increased PG levels in DATP5 but had no effect in HL-1. In HL-1, alkaline phosphatase (ALP) activity was progressively increased by 200-500% in both pre- and postconfluent cultures. In DATP5 in preconfluent cultures, T3 initially stimulated but later suppressed ALP; in postconfluent cultures, T3 also transiently increased ALP but did not suppress activity upon longer exposure. The inhibitory effects of T3 on protein, PG, and DNA levels of GP chondrocytes suggest that in vivo its effects on bone growth must occur primarily after cellular proliferation. Apparently by binding to the 50 kDa thyroxine-binding globulin, which cannot penetrate the PG barrier, accessibility of T3 to GP chondrocytes is limited until the time of vascular penetration when its stimulatory effects on ALP and mineral deposition become critical for continued bone development.

Inhibition of terminal differentiation and matrix calcification in cultured avian growth plate chondrocytes by Rous sarcoma virus transformation

Endochondral bone formation involves the progression of epiphyseal growth plate chondrocytes through a sequence of developmental stages which include proliferation, differentiation, hypertrophy, and matrix calcification. To study this highly coordinated process, we infected growth plate chondrocytes with Rous sarcoma virus (RSV) and studied the effects of RSV transformation on cell proliferation, differentiation, matrix synthesis, and mineralization. The RSV-transformed chondrocytes exhibited a distinct bipolar, fibroblast-like morphology, while the mock-infected chondrocytes had a typical polygonal morphology. The RSV-transformed chondrocytes actively synthesized extracellular matrix proteins consisting mainly of type I collagen and fibronectin. RSV-transformed cells produced much less type X collagen than was produced by mock-transformed cells. There also was a significant reduction of proteoglycan levels secreted in both the cell-matrix layer and culture media from RSV-transformed chondrocytes. RSV-transformed chondrocytes expressed two- to- threefold more matrix metalloproteinase, while expressing only one-half to one-third of the alkaline phosphatase activity of mock infected cells. Finally, RSV-transformed chondrocytes failed to calcify the extracellular matrix, while mock-transformed cells deposited high levels of calcium and phosphate into their extracellular matrix. These results collectively indicate that RSV transformation disrupts the preprogrammed differentiation pattern of growth plate chondrocytes and inhibit chondrocyte terminal differentiation and mineralization. They also suggest that the expression of extracellular matrix proteins, type II and type X collagens, and the cartilage proteoglycans are important for chondrocyte terminal differentiation and matrix calcification.

Effect of metal ions on calcifying growth plate cartilage chondrocytes

The effects of the trace metals zinc (Zn), manganese (Mn), and cadmium (Cd) on the metabolism of growth plate chondrocytes was examined using a mineralizing culture system. Supplementation of serum-free primary cultures of growth plate chondrocytes with 10-100 mu m Zn resulted in an increase in cell protein and greatly increased alkaline phosphatase (AP) activity; however, above 25 mu m Zn mineralization of the cultures was reduced. The effects of Zn on cellular protein and AP activity were enhanced by the addition of the albumin to the culture media. Removal of Zn from basal culture media resulted in recoverable reductions in cellular protein and AP activities. Cadmium was acutely toxic to chondrocyte cell cultures at concentrations above 5 mu m. Even at very low concentrations (0.25 mu m) Cd caused significant reductions in DNA, cellular protein, and matrix protein synthesis. In contrast, Cd had negligible effects on AP activity or culture mineralization. Manganese treatment (50 mu m) resulted in reduced levels of proteoglycan, cell protein, DNA synthesis, and collagen synthesis, although AP specific activity did not change. At 10 mu m, Mn significantly reduced mineralization but had only minor influence on other culture parameters. Both Zn (200 mu m) and Cd (0.1 mu m), but not Mn, induced the synthesis of metallothionein. The physiological and biochemical effects of specific metal ions is largely dependent on their physicochemical properties, especially their ligand affinities. Knowledge of these properties allows predictions to be made regarding whether the organic or the mineral phase are most likely to be affected in a mineralized tissue.

Structural studies of a phosphatidyl serine-amorphous calcium phosphate complex

A phosphatidyl serine-amorphous calcium phosphate complex has been synthesized as a model of the matrix vesicle system that is associated with the induction of mineral deposition in bone, cartilage and dentine. The complex has been studied using a novel technique of subtractive extended X-ray absorption fine structure (EXAFS). This enables spectra of the components of the molecules to be subtracted from the complex so as to identify the sites of interaction. The results suggest there is a movement in the nitrogen atom of the phosphatidyl serine which approaches the calcium atom in the mineral phase. This interpretation would link the membrane structure of the vesicle to the structure of the mineral in a way that could explain some of its roles in biomineralization.

Induction and characterization of metallothionein in chicken epiphyseal growth plate cartilage chondrocytes

Following exposure to cadmium or zinc, chickens were sacrificed and the liver, kidney, and bone epiphyseal growth plates harvested. When cytosolic extracts of the growth plate cartilage were fractionated by gel filtration chromatography, a protein with high metal-binding capacity and low ultraviolet (UV) absorbance eluted in the same position as liver metallothionein (MT) and a MT standard. Cd or Zn treatment resulted in a 25-fold or 5-fold induction in growth plate MT, respectively. In liver the greatest level of MT induction was seen with short-term Cd exposures. In contrast, MT levels in the growth plate increased as the duration of Cd exposure increased. Induction of MT in growth plate chondrocyte cell cultures was observed for media Cd concentrations of > or = 0.1 microM and Zn concentrations of > or = 100 microM. Basal and inducible levels of MT declined through the culture period and were lowest in the terminally differentiated mineralized late stages of the culture. Alkaline phosphatase activity was also lowest in the late-stage cultures, while total cellular protein increased throughout the culture period. Treatment of chondrocytes with Zn prior to Cd exposure resulted in a protective induction of MT. Pre-treatment of chondrocytes with dexamethasone resulted in suppressed synthesis of MT upon Cd exposure and greater Cd toxicity. Both Cd and Zn resulted in significantly increased levels of MT mRNA in chondrocyte cell cultures. Dexamethasone treatment resulted in an approximate 2- to 3-fold increase in MT mRNA. This is contrary to the finding that MT protein levels were decreased by dexamethasone. The findings suggest that an increased rate of MT degradation in dexamethasone-treated and late-stage chondrocyte cultures may be associated with the terminally differentiated phenotype.

Retinoic acid treatment elevates matrix metalloproteinase-2 protein and mRNA levels in avian growth plate chondrocyte cultures

Matrix metalloproteinases (MMPs) play a crucial role in tissue remodeling. In growth plate (GP) cartilage, extensive remodeling occurs at the calcification front. To study the potential involvement of MMPs in retinoic acid (RA) regulation of skeletal development, we studied the effect of all-trans-RA on MMPs levels in mineralizing chicken epiphyseal chondrocyte primary cultures. When treated for 4 day periods on days 10 and 17, RA increased levels of an approximately 70 kDa gelatinase activity. The N-terminal sequence of the first 20 amino acid residues of the purified enzyme was identical to that deduced from chicken MMP-2 cDNA. Time-course studies indicated that RA elevated MMP-2 activity levels in the cultures within 16 h. This increase was inhibited by cycloheximide and was enhanced by forskolin. The increase in MMP-2 activity induced by RA was accompanied by an increase in MMP-2 mRNA levels and was abolished by treatment with cycloheximide. This upregulation of MMP levels by RA in GP chondrocytes is consistent with its effects on osteoblasts and osteosarcoma cells and opposite its inhibitory effects on fibroblasts and endothelial cells. It may well be related to the breakdown of the extracellular matrix in the GP and would be governed by the availability of RA at the calcification front where extensive vascularization also occurs.

Effect of osteogenic protein-1 on the development and mineralization of primary cultures of avian growth plate chondrocytes: modulation by retinoic acid

Osteogenic protein-1 (OP-1), a member of the TGF-beta family of proteins, induces endochondral bone formation. Here we studied the effect of OP-1 on the development of primary cultures of avian growth plate (GP) chondrocytes in either serum-free or serum-containing medium, in the absence or presence of retinoic acid (RA). OP-1 was added on day 7 of culture and continued for 7 days, or until the cultures were harvested, typically on day 21. Alone, OP-1 caused approximately 2-fold increase in proteoglycan synthesis into both the medium and the cell:matrix layer. Additionally, OP-1 caused a dosage-dependent increase in alkaline phosphatase (ALP) activity, and an increase in protein, when given from days 7-14 and examined on day 14. This stimulation was greater in cells grown in serum-free than in serum-containing media (3-5-fold vs. 2-3-fold increase in ALP; approximately 40% vs. approximately 20% increase in protein). Such stimulation of ALP activity and proteoglycan (PG) synthesis in cultured GP cells indicates that OP-1 elicits differentiation of chondrocytes. OP-1 minimally affected cell division (DNA content); however, a slight increase was seen when examined early in the culture. Alone, OP-1 increased mineral (Ca and Pi) content of the cultures by approximately 2-fold in both types of media. As early as day 14, clusters of mineral encircled many of the OP-1 treated cells. Thus, as in vivo, OP-1 strongly promoted mineral formation by the cultured GP chondrocytes. When present together, OP-1 and RA generally blocked the action of the other. Separately OP-1 and RA each stimulated protein synthesis, ALP activity, and Ca2+ deposition; together they were inhibitory to each. Also, RA blocked the stimulation of PG synthesis induced by OP-1; whereas OP-1 decreased cell division engendered by RA. Thus, this GP chondrocyte culture system is a good model for studying factors that influence differentiation and mineral deposition during bone growth in vivo.

Retinoic acid stimulates matrix calcification and initiates type I collagen synthesis in primary cultures of avian weight-bearing growth plate chondrocytes

The effect of retinoic acid (RA) on primary cultures of growth plate chondrocytes obtained from weight-bearing joints was examined, Chondrocytes were isolated from the tibial epiphysis of 6- to 8-week-old broiler-strain chickens and cultured in either serum-containing or serum-free media. RA was administered at low levels either transiently or continuously after the cells had become established in culture. Effects of RA on cellular protein levels, alkaline phosphatase (AP) activity, synthesis of proteoglycan (PG), matrix calcification, cellular morphology, synthesis of tissue-specific types of collagen, and level of matrix metalloproteinase (MMP) activity were explored. RA treatment generally increased AP activity and stimulated mineral deposition, especially if present continuously. RA also caused a shift in cell morphology from spherical/polygonal to spindle-like. This occurred in conjunction with a change in the type of collagen synthesized: type X and II collagens were decreased, while synthesis of type I collagen was increased. There was also a marked increase in the activity of MMP. Contrasting effects of continuous RA treatment on cellular protein levels were seen: they were enhanced in serum-containing media, but decreased in serum-free HL-1 media. Levels of RA as low as 10 nM significantly inhibited PG synthesis and caused depletion in the levels of PG in the medium and cell-matrix layer. Thus, in these appendicular chondrocytes, RA suppressed chondrocytic (PG, cartilage-specific collagens) and enhanced osteoblastic phenotype (cell morphology, type I collagen, alkaline phosphatase, and mineralization).

Effects of calcitonin and parathyroid hormone on calcification of primary cultures of chicken growth plate chondrocytes

Few studies have been directed toward elucidating the action of calcitonin (CT) and parathyroid hormone (PTH) on growth plate chondrocytes, cells directly involved in longitudinal bone growth and provisional calcification. In this study, primary cultures of avian growth plate chondrocytes that calcify without the supplement of beta-glycerophosphate were used to investigate the effects of synthetic human CT and 1-34 bovine PTH on (1) cell division and growth; (2) the deposition of Ca2+ and inorganic phosphate (Pi); (3) the activity of alkaline phosphatase (AP), an enzyme long associated with the mineralization process; (4) the levels of proteoglycans; and (5) the synthesis of collagens. Added continually to preconfluent cultures from day 6 until harvest, CT (1-30 nM) and PTH (0.1-1.0 nM) increased mineral deposition; the maximal increase was seen between days 18-21 at 10 nM CT (175-260%) and 0.5 nM PTH (approximately 170-280%), both p < 0.001. CT had no significant effect on cellular protein, or AP-specific activity, whereas PTH increased cellular protein, DNA, proteoglycan, and collagen content of the cultures in a dosage-dependent manner. AP activity and levels of Type II and X collagens and fibronectin in the culture medium showed a biphasic response to PTH; maximal increases were seen at 0.5 nM between days 15-18. Longer exposure (days 21-27) to PTH at higher levels (5-10 nM) caused a marked decreased in AP activity but a lesser decrease in the collagens. These results indicate that CT and PTH can act directly on chondrocytes to stimulate mineralization, but that PTH specifically stimulated cell division and synthesis of cellular and extracellular proteins by growth plate chondrocytes. The implications of these findings with regard to Ca2+ homeostasis and bone formation are discussed.

Physicochemical characterization of the nucleational core of matrix vesicles

While previous studies revealed that matrix vesicles (MV) contain a nucleational core (NC) that converts to apatite when incubated with synthetic cartilage lymph, the initial mineral phase present in MV is not well characterized. This study explored the physicochemical nature of this Ca2+ and Pi-rich NC. MV, isolated from growth plate cartilage, were analyzed directly by solid-state 31P NMR, or incubated with hydrazine or NaOCl to remove organic constituents. Other samples of MV were subjected to sequential treatments with enzymes, salt solutions, and detergents to expose the NC. We examined the NC using transmission electron microscopy, energy-dispersive analysis with x-rays, and electron and x-ray diffraction, Fourier transform-infrared spectroscopy, high performance thin-layer chromatographic analysis, and SDS-polyacrylamide gel electrophoresis. We found that most of the MV proteins and lipids could be removed without destroying the NC; however, NaOCl treatment annihilated its activity. SDS-polyacrylamide gel electrophoresis showed that annexin V, a phosphatidylserine (PS)-dependent Ca2+-binding protein, was the major protein in the NC; high performance thin-layer chromatographic analysis revealed that the detergents removed the majority of the polar lipids, but left significant free cholesterol and fatty acids, and small but critical amounts of PS. Transmission electron microscopy showed that the NC was composed of clusters of approximately 1.0 nm subunits, which energy-dispersive analysis with x-rays revealed contained Ca and Pi with a Ca/P ratio of 1.06 +/- 0. 01. Electron diffraction, x-ray diffraction, and Fourier transform-infrared analysis all indicated that the NC was noncrystalline. 1H-Cross-polarization 31P NMR indicated that the solid phase of MV was an HPO42--rich mixture of amorphous calcium phosphate and a complex of PS, Ca2+, and Pi. Taken together, our findings indicate that the NC of MV is composed of an acid-phosphate-rich amorphous calcium phosphate intermixed with PS-Ca2+-Pi, annexin V, and other proteins and lipids.

In situ levels of intracellular Ca2+ and pH in avian growth plate cartilage

Interactions with the extracellular matrix, accumulation of Ca2+, formation of matrix vesicles, and regulation of tissue pH by growth plate chondrocytes all appear to be vital to endochondral calcification. Thus, the activities of Ca2+ and H+ ions in these cells, while still embedded in their organic matrix, are of great interest. Using laser confocal imaging and sensitive Ca2+ (Indo 1) and pH (BCECF) probes, cellular Ca2+ and pH were analyzed in thin sections of freshly isolated cartilage. Mean values of cytosolic Ca2+ in cells from the various zones of the growth plate were quite similar, but levels in individual cells and subcellular compartments varied significantly. Ca2+ was elevated intensely near the periphery of cells in the zones of maturation and hypertrophy, and many Ca2+ rich particles were seen in the matrix near these cells. Levels of Ca2+ within the cells varied with time. In the proliferative region, cyclical increases and decreases in Ca2+ were seen, but there was little shedding of Ca2+ rich particles. However, after repeated Ca2+ cycling, in the zones of maturation and hypertrophy, Ca2+ rich particles were shed from the cell surface, forming what appeared to be matrix vesicles. Intracellular pH levels also varied significantly within the chondrocytes and between the cells and zones. Numerous focal elevations in pH (> 8.0) were seen in central regions of the maturing and early hypertrophic cells, with lower pH (6.5-7.2) near the cell periphery of the late hypertrophic and calcifying cells. This pattern of cytoplasmic alkalinization and subsequent acidification appears to contribute to loading of Ca2+ and Pi into matrix vesicles during their formation by the chondrocytes.

The influence of trace elements on calcium phosphate formation by matrix vesicles

The effects of two inhibitors, fluoride (F-) and zinc (Zn2+), were studied on the formation of mineral by matrix vesicles (MV) in an in vitro system. Kinetically, mineral formation by MV incubated in a synthetic cartilage lymph (SCL) is characterized by three phases: a lag period, a period of rapid uptake, and finally a period of slow uptake. Zn2+ at > or = 5 microM completely inhibited MV mineralization; at < or = 1 microM, it had little effect on rate of ion uptake, but delayed conversion of an OCP-like intermediate into hydroxyapatite (OHAp). F- at > or = 10 microM reduced the rate of rapid uptake by MV and caused the OCP-like precursor to convert to OHAp. When synthetic OCP was seeded into SCL, mineralization ensued and OHAp became the dominant phase. With Zn2+ present, OCP-like features persisted longer; with F-, the OCP-like features were lost more rapidly. When ACP was seeded into SCL, OHAp formed; Zn2+ at < or = 1 microM caused OCP-like mineral to form. Our findings indicate that Zn2+ stabilizes a noncrystalline precursor in MV regulating the length of the lag period; Zn2+ also favors the formation of an OCP-like intermediate whose growth accounts for the rapid uptake phase. This OCP-like phase appears to nucleate formation of OHAp by MV.

Similarity in calcium channel activity of annexin V and matrix vesicles in planar lipid bilayers

Matrix vesicles (MVs), structures that accumulate Ca2+ during the initiation of mineral formation in growing bone, are rich in annexin V. When MVs are fused with planar phospholipid bilayers, a multiconductance Ca2+ channel is formed, with activity essentially identical to that observed when annexin V is delivered to the bilayer with phosphatidylserine liposomes. Ca2+ currents through this channel, from either MV or annexin V liposomes, are blocked by Zn2+, as is Ca2+ uptake by MV incubated in synthetic cartilage lymph. Blockage by Zn2+ was most effective when applied to the side containing the MV or liposomes. ATP and GTP differentially modulated the activity of this channel: ATP increased the amplitude of the current and the number of conductance states; GTP dramatically reduced the number of events and conductance states, leading to well-defined Ca2+ channel activity from either MV or the annexin V liposomes. In the distinctive effects of ATP, GTP, and Zn2+ on the Ca2+ channel activity observed in both the MV and the liposome systems, the common factor was the presence of annexin V. From this we conclude that Ca2+ entry into MV results from the presence of annexin V in these membrane-enclosed structures.

Characterization and reconstitution of the nucleational complex responsible for mineral formation by growth plate cartilage matrix vesicles

Previous studies revealed that matrix vesicles (MV) have an acid-labile nucleationally active core (ALNAC) essential for mineral formation; current studies were aimed at characterizing and reconstituting ALNAC. SDS-PAGE and FTIR analyses revealed the presence of lipids, proteins and amorphous calcium phosphate (ACP) in ALNAC. Extraction with chloroform-methanol reduced, but did not destroy MV calcification; treatment with chloroform-methanol-HCl destroyed all activity. This acidic solvent extracted the annexins, (phosphatidylserine (PS)-dependent Ca(2+)-binding proteins), and dissociated PS-Ca(2+)-Pi complexes present in the MV. Attempts to reconstitute ALNAC, centered on the Ca(2+)-PS-Pi complex. Various pure lipids, electrolytes and proteins were combined to form a synthetic nucleationally active complex (SNAC), analyzing the rate of Ca2+ uptake. Inclusion of phosphatidylethanolamine (PE) or sphingomyelin (SM) with PS, or Mg2+ or Zn2+ with Ca2+, strongly inhibited activity; incorporation of annexin V increased SNAC activity. Thus, approaching from either deconstruction or reconstruction, it appears that ALNAC is composed of ACP complexed with PS and the annexins. Other lipids, proteins and electrolytes modulate its activity. These findings also indicate how ALNAC must be formed in vivo.

Defect in formation of functional matrix vesicles by growth plate chondrocytes in avian tibial dyschondroplasia: evidence of defective tissue vascularization

Avian tibial dyschondroplasia (ATD), a disease characterized by an almost total lack of mineralization in affected areas of growth plate cartilage, may involve defective matrix vesicle (MV) mineralization. To explore the biochemical defect in ATD, both normal and diseased tissue were analyzed for the amount of isolatable MVs, their chemical composition, and their ability to induce mineral formation. We found significantly fewer MVs in ATD tissue, and in contrast to normal MVs, which rapidly mineralized when incubated in synthetic cartilage lymph, those isolated from ATD lesions induced only limited mineralization even after prolonged incubation. Analysis by detergent extraction revealed a nearly dysfunctional nucleational core in ATD MVs. Thus, in ATD tissue, there is a defect in the formation of MVs, and those that form are nearly inactive. There were also alterations in the lipid-dependent Ca2+(-)binding proteins (annexins) in ATD MVs. There were lower levels of annexins II and VI in endogenously produced collagenase-released matrix vesicles (CRMVs), but not in matrix vesicle-enriched microsomes (MVEMs) produced by tissue homogenization. These findings indicate that there is insufficient Ca2+ in ATD cells to enable incorporation of the annexins into MVs. Finally, there was evidence of phospholipid breakdown in ATD MVs, as well as in ATD tissue generally. This indicated that the ATD lesions were becoming necrotic. Taken together, these findings indicate that there is a defect in tissue vascularization such that the supply of mineral ions and nutrients to ATD cartilage is inadequate to support normal MV formation and subsequent mineralization.

Morphological and biochemical characterization of mineralizing primary cultures of avian growth plate chondrocytes: evidence for cellular processing of Ca2+ and Pi prior to matrix mineralization

Advances in the culture of mineralizing growth plate chondrocytes provided an opportunity to study endochondral calcification under controlled conditions. Here we report that these cultures synthesize large amounts of proteins characteristically associated with mineralization: type II and X collagens, sulfated proteoglycans, alkaline phosphatase, and the bone-related proteins, osteonectin and osteopontin. Certain chondrocytes appeared to accumulate large amounts of Ca2+ and Pi during the mineralization process: laser confocal imaging revealed high levels of intracellular Ca2+ in their periphery and X-ray microanalytical mapping revealed the presence of many Ca(2+)- and Pi-rich cell surface structures ranging from filamentous processes 0.14 +/- 0.02 microns by 0.5-2.0 microns, to spherical globules 0.70 +/- 0.27 microns in diameter. Removal of organic matter with alkaline sodium hypochlorite revealed numerous deposits of globular (0.77 +/- 0.19 micron) mineral (calcospherites) in the lacunae around these cells. The size and spatial distribution of these mineral deposits closely corresponded to the Ca(2+)-rich cell surface blebs. The globular mineral progressively transformed into clusters of crystallites. Taken with earlier studies, these findings indicate that cellular uptake of Ca2+ and Pi leads to formation of complexes of amorphous calcium phosphate, membrane lipids, and proteins that are released as cell surface blebs analogous to matrix vesicles. These structures initiate development of crystalline mineral. Thus, the current findings support the concept that the peripheral intracellular accumulation of Ca2+ and Pi is directly involved in endochondral calcification.

Roles of the nucleational core complex and collagens (types II and X) in calcification of growth plate cartilage matrix vesicles

Matrix vesicles (MV) were shown to initiate mineralization in cartilage and other vertebrate tissues. However, the factors that drive this process remain to be fully elucidated. Recent studies have shown that a preformed nucleational core consisting mainly of a Ca(2+)-phosphatidylserine-Pi complex, is necessary for the accumulation of Ca2+ by MV. In addition, the collagens attached to the MV surface were shown to play an important role in stimulating Ca2+ uptake. In this study, we extend this knowledge by showing that both, the nucleational core and the collagens (types II and X), are co-requirements for rapid influx of Ca2+ into intact MV. MV to which collagen fragments were attached were released from hypertrophic chicken cartilage by trypsin and collagenase digestion (trypsin/collagenase-released MV (TCRMV), while "collagen-free" MV were released by hyaluronidase and collagenase digestion (hyaluronidase/collagenase-released MV (HCRMV). In contrast to TCRMV which showed active uptake of Ca2+, HCRMV showed only little uptake. However, binding of native type II collagen to HCRMV stimulated uptake of Ca2+. Sucrose gradients separated TCRMV and HCRMV into three different density fractions: a low density top fraction (SI), an intermediate density middle fraction (SII), and a high density pellet fraction (SIII). The SIII fractions of TCRMV and HCRMV contained significantly higher levels of mineral ions than did the SI and SII fractions. Only the SIII fraction of TCRMV which contained a stable nucleational core and surface-attached collagens, showed active Ca2+ uptake; all other sucrose fractions of TCRMV and HCRMV showed little or no uptake. Detergent treatment to purposely rupture the membrane greatly enhanced Ca2+ uptake by the SIII fraction of HCRMV, presumably by exposing the internal nucleational core. Addition of either native type II or type X collagen to the intact SIII fraction of HCRMV stimulated Ca2+ uptake to a level similar to that of the SIII fraction of TCRMV; however, incubation of the SI and SII fractions of either TCRMV or HCRMV with type II or X collagen did not activate Ca2+ uptake. These findings indicate that both a functional nucleational core and surface-attached collagens need to be present to support active mineralization of MV.

Fourier transform Raman spectroscopy of synthetic and biological calcium phosphates

Fourier-transform (FT) Raman spectroscopy was used to characterize the organic and mineral components of biological and synthetic calcium phosphate minerals. Raman spectroscopy provides information on biological minerals that is complimentary to more widely used infrared methodologies as some infrared-inactive vibrational modes are Raman-active. The application of FT-Raman technology has, for the first time, enabled the problems of high sample fluorescence and low signal-to-noise that are inherent in calcified tissues to be overcome. Raman spectra of calcium phosphates are dominated by a very strong band near 960 cm-1 that arises from the symmetric stretching mode (v1) of the phosphate group. Other Raman-active phosphate vibrational bands are seen at approximately 1075 (v3), 590 (v4), and 435 cm-1 (v2). Minerals containing acidic phosphate groups show additional vibrational modes. The different calcium phosphate mineral phases can be distinguished from one another by the relative positions and shapes of these bands in the Raman spectra. FT-Raman spectra of nascent, nonmineralized matrix vesicles (MV) show a distinct absence of the phosphate v1 band even though these structures are rich in calcium and phosphate. Similar results were seen with milk casein and synthetic Ca-phosphatidyl-serine-PO4 complexes. Hence, the phosphate and/or acidic phosphate ions in these noncrystalline biological calcium phosphates is in a molecular environment that differs from that in synthetic amorphous calcium phosphate. In MV, the first distinct mineral phase to form contained acidic phosphate bands similar to those seen in octacalcium phosphate. The mineral phase present in fully mineralized MV was much more apatitic, resembling that found in bones and teeth.(ABSTRACT TRUNCATED AT 250 WORDS)

Stimulation of calcification of growth plate cartilage matrix vesicles by binding to type II and X collagens

Matrix vesicles (MV), microstructures which rapidly accumulate Ca2+ and induce mineral formation in vitro, are linked to type II and X collagens and proteoglycans in the hypertrophic cartilage. However, the roles of these matrix proteins on MV function are not known. This led us to investigate the influence of type II and X collagen binding on Ca2+ uptake by MV. MV isolated from chicken growth plate cartilage were treated with pure bacterial collagenase and 1 M NaCl in synthetic cartilage lymph to selectively and completely remove associated type II and X collagens. Uptake of 45Ca2+ by these collagen-depleted vesicles was markedly reduced. Further treatment with detergent, which disrupted the membrane, restored Ca2+ uptake, indicating that the vesicle membrane structure and the nucleational core inside the vesicle lumen were still intact after the collagenase and 1 M NaCl treatments. Readdition of either native type II or X collagen to the collagenase, 1 M NaCl-treated MV stimulated their Ca2+ uptake to levels similar to those of untreated vesicles. Pepsin-treated type II and X collagens were less effective in stimulating Ca2+ uptake, indicating that non-triple helical domains of these collagens were involved. The pepsin treatment of these collagens also decreased their binding to annexin V (anchorin CII), one of three annexins found in MV, suggesting that annexin V is involved in mediating the binding of type II and X collagens to the MV surface. Furthermore, treatment of collagenase, 1 M NaCl-treated MV with chymotrypsin, which damaged annexin V as well as many other MV proteins, prevented the stimulation of Ca2+ uptake by these collagens. Thus, the interaction between type II and X collagens with MV activates the influx of Ca2+ into MV and may play an important role in calcification of the vesicles.

Characterization, cloning and expression of the 67-kDA annexin from chicken growth plate cartilage matrix vesicles

Analysis of a 67 kDa lipid-dependent Ca(2+)-binding protein from avian matrix vesicles revealed amino acid sequences homologous to mammalian annexin VI. PCR methods were used to identify a clone from an avian cDNA library that contained a full length copy of the 67-kDa annexin cDNA. This was restriction mapped, subcloned and sequenced. The cDNA sequence of the open reading frame showed 70 percent identity to that of murine annexin VI; the predicted amino acid sequence, 78 percent identity. There was no homology in the 5'- and 3'-untranslated regions. A plasmid was constructed that overexpresses the intact chicken 67-kDa matrix vesicle annexin in E. coli DH5 alpha in high yield; the physicochemical properties and the amino terminal sequence of the expressed protein exactly matched those of the native protein.

Characterization of the nucleational core complex responsible for mineral induction by growth plate cartilage matrix vesicles

The factors that drive mineralization of matrix vesicles (MV) have proven difficult to elucidate; in the present studies, various detergent, chemical, and enzyme treatments were used to reveal the nature of the nucleational core. Incubation with detergents that permeabilized the membrane enhanced calcification of treated MV incubated in synthetic cartilage lymph. While detergents removed most of the membrane lipid, they left significant amounts of the MV annexins and nearly all of the Ca2+, Pi, and Zn2+. Extraction with 1 M NaCl removed much of the Ca2+ and Pi present in MV, markedly reducing Ca2+ accumulation; these effects could be prevented by low levels of Ca2+ and Pi in the NaCl extractant. Treatment with chymotrypsin appeared to damage proteins required for MV mineralization; further treatment with detergents to bypass the membrane reactivated MV mineralization. Treatment of MV with pH 6 citrate removed Ca2+ and Pi, destroying their ability to mineralize; subsequent treatment with detergents did not reactivate these MV. Incubation of the detergent-resistant core with o-phenanthroline complexed Zn2+ and stimulated mineralization; addition of Zn2+ to synthetic cartilage lymph blocked the ability of the core to mineralize. These studies show that once the nucleational core complex is formed, the membrane-enclosed domain is no longer essential for MV calcification. Our findings indicate that the MV core contains two main components as follows: a smaller membrane-associated complex of Ca2+, Pi, phosphatidylserine, and the annexins that nucleates crystalline mineral formation, and a larger pool of Ca2+ and Pi bound to lumenal proteins. These proteins appear to bind large amounts of mineral ions, stabilize the nucleational complex, and aid its transformation to the first crystalline phase. Once nucleated, the crystalline phase appears to feed on protein-bound mineral ions until external ions enter through the MV ion channels. Zn2+ appears to regulate gating of the ion channels and conversion of the nucleational complex to the crystalline state.

Involvement of cellular metabolism of calcium and phosphate in calcification of avian growth plate cartilage

Past work established that matrix vesicles (MV) are primary initiators of extracellular mineral deposition in endochondral calcification. Reviewed here are studies on how direct cellular metabolism of Ca2+ and inorganic phosphate (Pi), and cellular interaction with the matrix, are involved in the formation of calcifiable MV. Presented is a working model of how chondrocytes in growth plate (GP) cartilage are envisioned to induce the formation of calcifiable MV. In part, this model is based on recent laser confocal imaging of living cartilage tissue sections with Indo-I AM, a fluorescent permeant Ca2+ probe. These studies indicate that GP chondrocytes actively acquire Ca2+, concentrate it to the cell periphery and exfoliate it as Ca(2+)-rich MV. Data from direct chemical analysis and 31P-NMR studies on freshly isolated cells show that GP chondrocytes are depleted of ATP and have elevated cytosolic Pi, a condition prerequisite to formation of Ca(2+)-acidic phospholipid (APL)-Pi complex-primed MV. Chondrocyte cell membrane processes from which MV arise have been found to be tightly linked to the cartilage-specific extracellular matrix collagens and proteoglycans. Annexins V and VI, APL-dependent Ca(2+)-binding proteins that form Ca2+ channels in chondrocytes and MV membranes, also bind to the matrix collagens and may serve as mechano-transducers in GP cartilage, gating Ca2+ entrance into the cells and MV. This interaction between the extracellular matrix and chondrocytes appears to facilitate Ca2+ loading of chondrocytes, formation of Ca2+ and Pi-primed MV and rapid induction of mineralization in GP cartilage.

Establishment of the primary structure of the major lipid-dependent Ca2+ binding proteins of chicken growth plate cartilage matrix vesicles: identity with anchorin CII (annexin V) and annexin II

Electron microscopic studies of calcifying vertebrate tissues reveal the locus of de novo mineral formation within matrix vesicles (MV). The direct involvement of MV in the initiation of mineral formation is supported by the fact that MV isolated from avian growth plate cartilage rapidly accumulate large amounts of Ca2+ and P(i) and induce mineral formation. Exploration of the constituents of MV has revealed two major protein components, a 33 and a 36 kD protein, the former of which binds to cartilage-specific collagens. These annexin-like proteins bind to acidic phospholipids in the presence of submicromolar levels of Ca2+. Antibodies raised against both the purified 33 and the 36 kD MV annexin do not cross-react with the other, indicating that they are distinct proteins. Reported here are studies elucidating the primary structure of both MV proteins using both conventional protein and molecular biologic methods. These studies establish that the 33 kD protein is nearly identical to anchorin CII (annexin V) and that the 36 kD protein is identical to avian annexin II. Immunolocalization studies show that hypertrophic chondrocytes at the calcification front of avian growth plate contain the highest level of these annexins. Further, immunogold labeling indicates that the annexins are localized within MV isolated from the growth plate. Recent studies indicate that annexin V is a new type of ion-selective Ca2+ channel protein that possesses selective collagen binding properties. Since MV are tightly associated with the collagen- and proteoglycan-rich matrix, it is tempting to speculate that this MV protein may be a component of stretch-activated ion channels that enhance Ca2+ uptake during mechanical stress.

Modulation of cultured chicken growth plate chondrocytes by transforming growth factor-beta 1 and basic fibroblast growth factor

Expression of several cellular and matrix proteins which increase significantly during the maturation of growth plate cartilage has been shown to be affected by various endocrine and autocrine factors. In the studies reported here, transforming growth factor-beta (TGF-beta 1) and basic fibroblast growth factor (bFGF) were administered to primary cultures of avian growth plate chondrocytes at pre- or post-confluent stages to study the interplay that occurs between these factors in modulating chondrocytic phenotype. Added continuously to pre-confluent chondrocytes, TGF-beta 1 stimulated the cells to produce abundant extracellular matrix and multilayered cell growth; cell morphology was altered to a more spherical configuration. These effects were generally mimicked by bFGF, but cell shape was not affected. Administered together with TGF-beta 1, bFGF caused additive stimulation of protein synthesis, and alkaline phosphatase (AP) activity was markedly, but transiently enhanced. During this pre-confluent stage, TGF-beta 1 also increased fibronectin secretion into the culture medium. Added to post-confluent cells, TGF-beta 1 alone caused a dosage-dependent suppression of AP activity, but bFGF alone did not. Under these conditions, TGF-beta 1 and bFGF had little effect on general protein synthesis, but TGF-beta 1 alone caused large, dosage-dependent increases in synthesis of fibronectin, and to some extent type II and X collagens. Given together with bFGF, TGF-beta 1 synergistically increased secretion of fibronectin. These findings reveal that regulation of phenotypic expression in maturing growth plate chondrocytes involves complex interactions between growth factors that are determined by timing, level, continuity, and length of exposure.

Characterization of a delayed rectifier potassium current in chicken growth plate chondrocytes

With the use of the whole cell arrangement of the patch-clamp technique, an outward-directed time-dependent potassium current was identified in cultured chicken growth plate chondrocytes. This delayed rectifier potassium current (IK) activated with a sigmoidal time course during voltage steps to potentials positive to -40 mV. The half-maximal voltage required for current activation was determined to be -8 mV. The reversal potential (Erev) for IK, measured using deactivating tail currents, was -72 mV in the presence of 140 mM internal and 5 mM external [K+] solutions. Changes in external [K+] caused Erev to shift in a manner expected for a potassium-selective channel. In addition, increasing external [K+] from 5 to 50 mM caused the slope conductance of the tail currents to increase twofold. The chondrocyte IK was inhibited by the potassium-channel blocker 4-aminopyridine (4-AP) at concentrations of 0.5-4 mM and by the scorpion venom toxin charybdotoxin (CTX; 10 nM) but was unaffected by 10 mM tetraethylammonium (TEA). Addition of 20 microM ZnCl2 reduced IK in a voltage-dependent manner with the greatest inhibition found to occur at potentials near the threshold for current activation. Reduction of IK by ZnCl2 was accompanied by a slowing in the kinetics of IK activation. On the basis of the gating and pharmacological properties of this current, it is suggested that the chondrocyte channel belongs to a superfamily of K+ channels found in bone and immune system cells. The chondrocyte K+ channel may contribute to the unusually high [K+] found in the extracellular fluid of growth plate cartilage.

Fetuin and alpha-2HS glycoprotein induce alkaline phosphatase in epiphyseal growth plate chondrocytes

A previously described chondrocyte alkaline phosphatase induction factor (CAP-IF) for chicken epiphyseal growth plate chondrocytes has been purified to SDS-PAGE homogeneity from fetal bovine serum by ammonium sulfate precipitation and by dye-ligand affinity (Affi-Gel Blue and Reactive Green-19 agarose) and hydroxyapatite column chromatographies. As determined by immunoprecipitation of [35S]methionine-labeled cellular proteins after 3 day treatment, this highly purified CAP-IF increases the level of AP and certain other membrane proteins 2- to 3-fold over control values. The pure protein of apparent 64.5 kDa molecular weight has been identified as fetuin by N-terminal amino acid sequencing. This was confirmed by the finding that high alkaline phosphatase (AP)-inducing activity is present in fetuin prepared by the Spiro method. However, fetuins prepared by the Pedersen or Deutsch procedures are inactive. At least half of the CAP-IF activity of fetuin was irreversibly destroyed by treatment with EDTA and addition of Zn2+ did not reactivate the EDTA-treated fetuin. Ascorbate synergistically enhanced the effect of fetuin on chondrocyte AP activity by over 8-fold during 3 day exposure. Because of the very high homology between fetuin and the A-chain of alpha 2-HS glycoprotein, we also tested and found that alpha 2HS glycoproteins from human serum and bovine bone are both strong AP inducers. Our findings suggest that the AP-inducing activity resides in a labile, cystatin/Zn(2+)-binding domain common to these related serum glycoproteins. These proteins appear to play a role in enhancing AP expression in normal growth plate cartilage differentiation.

Matrix vesicle annexins exhibit proteolipid-like properties. Selective partitioning into lipophilic solvents under acidic conditions

Calcifiable proteolipids present in mineralizing tissues have been postulated to enhance apatite deposition by structuring membrane phosphatidylserine molecules into a conformation conducive to mineral formation. To examine whether proteolipid-like molecules are present in mineralizable matrix vesicles (MV), the vesicles were first extracted with chloroform/methanol (2:1, v/v), and then with chloroform/methanol/HCl (200:100:1, v/v) and the organic-soluble proteins subjected to sodium dodecyl sulfate-polyacrylamide gel electrophoresis analysis. Protein fractions were analyzed by Coomassie Blue staining and by immunoblot analysis of electrophoretically transferred MV protein with antisera to the 33- and 36-kDa annexins. We found that several MV proteins selectively partitioned into the lipophilic milieu under acidic conditions; however, very little protein did so at neutral pH. The principal organic-soluble MV proteins had molecular masses of 14, 33, and 36 kDa, with lesser bands at 28, 30, and 68 kDa. Immunological analyses revealed that the 33- and 36-kDa proteins were the MV annexins; the 14-kDa protein appeared to be hemoglobin, based on NH2-terminal sequencing. Our findings indicate that under acidic conditions the 33- and 36-kDa MV annexins undergo a conformational change which imparts a marked increase in the hydrophobicity of the proteins. While these observations reveal that the annexins possess proteolipid-like properties, radiolabeling and immunoprecipitation studies using [3H]myristic acid in chondrocyte cultures indicate that the MV annexins are not myristylated. Amino-terminal sequence analysis of the peptides generated by site-specific cleavage of the 33- and the 36-kDa MV annexins at tryptophan residues indicate that the 33 kDa is highly homologous to anchorin CII, a protein known to bind type II collagen, while the 36-kDa protein shares close homology with endonexin II, a tyrosine kinase substrate.

Unique fatty acid composition of normal cartilage: discovery of high levels of n-9 eicosatrienoic acid and low levels of n-6 polyunsaturated fatty acids

We report here the finding that normal, young cartilages, in distinction from all other tissues examined, have unusually high levels of n-9 eicosatrienoic (20:3 cis-delta 5,8,11) acid and low levels of n-6 polyunsaturated fatty acids (n-6 PUFA). This pattern is identical to that found in tissues of animals subjected to prolonged depletion of nutritionally essential n-6 polyunsaturated fatty acids (EFA). This apparent deficiency is consistently observed in cartilage of all species so far studied (young chicken, fetal calf, newborn pig, rabbit, and human), even though levels of n-6 PUFA in blood and all other tissues is normal. The n-9 20:3 acid is particularly abundant in phosphatidylethanolamine, phosphatidylinositol, and the free fatty acid fractions from the young cartilage. Several factors appear to contribute to the reduction in n-6 PUFA and the appearance of high levels of the n-9 20:3 acid in cartilage: 1) limited access to nutritional sources of EFA due to the impermeability and avascularity of cartilage, 2) rapid metabolism of n-6 PUFA to prostanoids by chondrocytes, and 3) a unique fatty acid metabolism by cartilage. Evidence is presented that each of these factors contributes. Previously, EFA deficiency has been shown to greatly suppress the inflammatory response of leukocytes and rejection of tissues transplanted into allogeneic recipients. Because eicosanoids, which are derived from EFA, have been implicated in the inflammatory responses associated with arthritic disease, reduction of n-6 PUFA and accumulation of the n-9 20:3 acid in cartilage may be important for maintaining normal cartilage structure.

Association between proteoglycans and matrix vesicles in the extracellular matrix of growth plate cartilage

Matrix vesicles (MV) are microstructures localized to the extracellular matrix of developing hard tissues that induce mineral formation. MV proteins are not well characterized, and little is known of how they interact with the surrounding matrix. However, recent electron microscopic studies indicate that MV interact with matrix proteins in growth plate cartilage. In the studies now reported, procedures developed for dissecting various components from isolated MV led to the discovery that two major vesicle proteins (38 and 46 kDa) are readily released from MV by low ionic strength solutions. These low ionic strength-soluble proteins (LISSP) were shown to be major fragments of the link protein (LP) and hyaluronic acid-binding region (HABR) of matrix proteoglycans: they react immunologically with highly specific monoclonal antibodies to LP and HABR, and the NH2-terminal sequence of the 38-kDa LISSP is essentially identical to residues 40-78 of chicken cartilage LP and that the 46-kDa LISSP represents HABR. Release of both LISSP is enhanced by hyaluronidase treatment, indicating anchorage by a hyaluronate-mediated mechanism. Both LP and HABR are firmly attached to MV in either isotonic or hypertonic solutions. In contrast, our other studies show that dissociation of type II collagen from MV occurs only with hypertonic salts which do not release the LISSP. Thus, strong interactions occur under physiological conditions between MV and both the proteoglycans and collagens, but these take place by different mechanisms.

Collagen-binding proteins in collagenase-released matrix vesicles from cartilage. Interaction between matrix vesicle proteins and different types of collagen

Recent evidence indicates that matrix vesicles (MV) interact with cartilage-specific collagens and other matrix proteins. Both type II and X collagens bind to and cosediment with MV. Our companion study shows that MV also are tightly coupled to proteoglycan link proteins (LP) and hyaluronic acid-binding region (HABR) in cartilage matrix. Here we sought to identify proteins responsible for the nexus between MV and matrix collagens using affinity chromatography with types I, II, and X collagen-Sepharose columns. Elution with NaCl step-gradients in the presence of nonionic detergent was used to assess the affinity between the MV proteins and the covalently attached collagens. Several MV proteins were found to bind to native type I, II, and X collagens but none bound to denatured type I collagen. Alkaline phosphatase, proteoglycan LP and HABR, and the 33- and 67-kDa annexins, bound with varying affinities to the native type I, II and X columns. In particular, LP and HABR, the 67-kDa annexin, and alkaline phosphatase bound with high affinity to the cartilage-specific collagens, although LP, HABR, and a 37-kDa protein also bound less tightly to native type I collagen. Thus, several MV proteins bind specifically to native type II and X collagens and should promote interaction between MV and the extracellular matrix. Such interactions may be important in MV formation, or in MV-mediated mineralization.

Differential fractionation of matrix vesicle proteins. Further characterization of the acidic phospholipid-dependent Ca2(+)-binding proteins

Matrix vesicles (MV) initiate de novo mineralization in a variety of vertebrate-calcifying tissues. In recent studies, a quantitatively major group of MV proteins, the acidic phospholipid-dependent Ca2(+)-binding proteins (APD-CaBP) were found to be immunologically related to the annexin family of proteins that possess phospholipase A2 inhibitory activity. This finding helped explain the enrichment of phosphatidylserine as well as the presence of large amounts of complexed Ca2+ noted previously in these structures. To characterize further these annexin-like proteins, preparations of both collagenase-released MV and MV-enriched microsomes were subjected to a differential fractionation process that led to the isolation and purification to homogeneity of two of the MV APD-CaBP, a 33-kDa protein and a 36-kDa calpactin II-like protein. Polyclonal antibodies raised to each pure protein were found not to cross-react with the other, thus indicating two distinctive proteins. Measurement of the phosphatidylserine-dependent Ca2(+)-binding properties of the proteins revealed apparent Kd values of 2.5 x 10(-7) and 5.0 x 10(-7) M for the 36- and 33-kDa proteins, respectively. Such high affinities indicate that both proteins would be normally bound to the membrane of MV. Immunological studies revealed the presence of both APD-CaBP in cultured growth plate chondrocytes but not in vesicles released into the culture medium. The finding of the 33-kDa but not the 36-kDa protein in vesicles released from the calcifying matrix of the chondrocyte cultures by collagenase digestion may indicate a role for this protein in MV mineralization.

Effects of Ca/Pi ratio, Ca2+ x Pi ion product, and pH of incubation fluid on accumulation of 45Ca2+ by matrix vesicles in vitro

The capacity of matrix vesicles (MV) to induce mineralization under various electrolyte conditions has not been explored. Accordingly, we examined the ability of isolated MV to induce calcification using synthetic lymphs with ranges of Ca/Pi ratio, Ca2+ x Pi ion product, and pH relevant to both normal and pathological conditions. At a fixed ion product of 2.84 mM2, 45Ca2+ uptake was supported at all Ca/Pi ratios tested, with ratios of 1.3-1.4 being optimal. Rapid ion uptake became saturated at levels greater than 2.7 mM2 when studied at a fixed Ca/Pi = 1.3, indicating a rate-limiting membrane ion porter. However, treatment of MV with non-ionic detergent did not destroy their ability to induce mineralization. At constant Ca/Pi of 1.3 and Ca2+ x Pi of 2.63 mM2, maximal uptake rates occurred at pH 7.6-7.8 over a pH range of 7.0-8.0, with significant uptake being supported only over the narrow range of pH 7.4-7.8. Studies showing that the effects of pH on amorphous calcium phosphate (ACP)-mediated calcification were very similar to those of MV, indicate that a stabilized form of internal ACP may induce crystalline mineral formation during MV-mediated calcification.

Induction of mineral deposition by primary cultures of chicken growth plate chondrocytes in ascorbate-containing media. Evidence of an association between matrix vesicles and collagen

A serum-free primary culture system for chicken growth plate chondrocytes has been developed which consistently undergoes mineral deposition. Upon attainment of confluency, the chondrocytes develop locally into multilayer cellular nodules leading to matrix calcification. Mineralization first occurs in matrix vesicles (MV) that are abundant in the extraterritorial matrix between the hypertrophic cells. Studies with 45Ca reveal that significant accumulation of Ca2+ occurs as early as day 12, continuing progressively throughout the culture period. By day 24, the nodules become densely calcified. Fourier transform infrared spectroscopy reveals the mineral to be similar to apatite, with features essentially identical to those of mineral formed by MV in vitro. The presence of ascorbate is critical to the culture system; in its absence, calcification is rarely observed. Ascorbate stimulates MV formation and synthesis of cellular protein, alkaline phosphatase, and especially types II and X collagens. In addition, there is strong evidence that the types II and X collagens are associated with MV. 1) Electron microscopy reveals MV embedded in a type II collagenous network; 2) Western blots of sodium dodecyl sulfate-polyacrylamide gel electrophoresis of MV using monospecific antibodies to types X and II collagen indicate that both collagens are present in specific MV fractions; 3) sucrose gradient purification of MV does not remove associated collagens; 4) graded salt extraction selectively releases type II collagen from MV; and 5) incubation of radiolabeled types II and X collagens with MV leads to their cosedimentation upon subsequent centrifugation. Taken together, the data suggest that coordinated synthesis of the collagens, alkaline phosphatase, MV formation, and Ca2+ accumulation by the cultures combine to induce mineral deposition in the multilayer nodules.

Regulatory effect of endogenous zinc and inhibitory action of toxic metal ions on calcium accumulation by matrix vesicles in vitro

Matrix vesicles (MV) isolated from chicken growth plate by collagenase digestion and incubated in 45Ca-labelled synthetic cartilage lymph (SCL) rapidly induce mineral formation. 45Ca uptake occurs in three distinct stages: (1) an initial lag period of limited accumulation, (2) a period of rapid ion uptake and (3) an extended period of slower uptake. Treatment of MV with buffered aqueous 1,10-phenanthroline (OP), a metal ion chelator, eliminated the lag period, promoting immediate, enhanced Ca2+ uptake. Analysis of MV for trace metals showed them to contain relatively high concentrations of Zn (1.58 mumol/g MV) and lesser amounts of Cu (0.07 mumol/g MV). At least 30-40% of the Zn was readily extractable in isosmotic buffers. Addition of Zn to SCL at levels as low as 5 microM completely inhibited MV mineralization; addition of OP to Zn-inhibited MV restored their ability to mineralize. The findings suggest that Zn2+ ions act as an endogenous regulator of MV Ca2+ uptake and that the normal lag period results from a competition between Zn2+ and Ca2+ for high affinity Ca2+ binding sites in the MV membrane or within the MV lumen. Other metals tested included Cu2+, Pb2+ and Cd2+ which had little or no effect on MV mineralization, Mn2+, which had an intermediate effect, and Al3+, which was found to be almost as inhibitory as Zn2+. This finding may have implications for aluminum-associated osteomalacia.

Isolation of two glycosylated forms of membrane-bound alkaline phosphatase from avian growth plate cartilage matrix vesicle-enriched microsomes

Isolation of two membrane-bound alkaline phosphatase (AP) species from avian growth plate cartilage matrix vesicle (MV) fractions is described. AP was first released from the membranes by phosphatidylinositol-specific phospholipase C (PIase C), followed by chromatography on DEAE-Bio-Gel A and Reactive-Red agarose. Two AP species having apparent Mr of 81.5 and 77 kDa by SDS-PAGE were purified in high yield and specific activity by this simple method. Treatment with neuraminidase to remove sialic acid residues reduced their size slightly, but did not diminish the difference in Mr between the two species. Digestion with N-glycanase, however, decreased both AP species to a common size of 59 kDa. This reveals that both enzymes are highly glycosylated and suggests that the two forms may result from differences in degree of glycation. The amino acid compositions of the two avian enzyme forms are very similar, but are markedly enriched in serine, glycine and glutamate when compared to those reported for mammalian liver-kidney-bone AP. Possible differences in amino acid sequence between the two avian forms have not been excluded. The cross-reactivity of polyclonal antibodies to these enzymes with bovine kidney, but not intestinal AP, indicate that the avian cartilage APs are of the liver-kidney-bone isozyme type.

Identification of phospholipid-dependent calcium-binding proteins as constituents of matrix vesicles

Uptake of mineral ions by isolated matrix vesicles (MV) incubated in synthetic cartilage lymph follows a consistent pattern. After an initial lag period, MV rapidly accumulate large amounts of Ca2+ and Pi before the appearance of crystalline mineral. The ability of MV to accumulate Ca2+ is readily destroyed by proteases, indicating that proteins are important in Ca2+ accumulation. Since MV contain significant amounts of phosphatidylserine (PS), an acidic phospholipid with affinity for Ca2+, it seemed probable that this lipid might also contribute to Ca2+ binding. The development of methods for reproducible isolation of pure active MV enabled us to search for factors responsible for the rapid accumulation of Ca2+. Reported here are studies which reveal that a set of intensely staining MV proteins, extractable with EGTA, selectively bind to Ca2+, but only in the presence of acidic phospholipids. These 30-36-kDa proteins form readily sedimentable insoluble ternary complexes of protein, Ca2+, and lipid in the presence of low levels of Ca2+. With liposomes composed of PS, alone or in combination with phosphatidylethanolamine, submicromolar levels of Ca2+ or certain other divalent cations, but not Mg2+, are sufficient to form the complexes. The physical and chemical properties of these MV proteins appear to be like those of the calpactin family of membrane-associated proteins. In fact, these MV proteins were found to cross-react with antibodies to calpactin II. Thus, calpactins appear to be important protein constituents of avian growth plate MV. This finding helps explain the enrichment in PS previously noted in MV and may also point to the mechanism by which MV rapidly accumulate Ca2+.

Mechanism of de novo mineral formation by matrix vesicles

Matrix vesicles (MV) induce mineralization by compartmentalization of ion accumulation and crystal nucleation within membrane-enclosed extracellular microstructures. MV derive from cell surface microvilli by processes that cause selective enrichment of specific proteins, enzymes, lipids, and electrolytes. Incubated in synthetic cartilage lymph (SCL), MV accumulate Ca2+ and Pi, inducing mineral formation in a sequence of stages that can be altered by specific affectors. Rapid uptake of mineral ions by MV precedes formation of the first crystalline phase, octacalcium phosphate (OCP), which later converts to apatite (HAP). Early uptake of Ca2+ and Pi by MV is pH and protease sensitive, and is stimulated by o-phenanthroline (OP), a Zn2+ chelator. Recent studies reveal that a quantitatively major group of MV proteins bind to Ca2+ with high affinity in a lipid-dependent manner. These MV proteins appear to be involved in transport and accumulation of Ca2+ and Pi by MV, and may catalyze nucleation of the first mineral phase.

Correlation between loss of alkaline phosphatase activity and accumulation of calcium during matrix vesicle-mediated mineralization

Activity of the bone/liver/kidney isozyme of alkaline phosphatase (AP) is known to be critical for mineralization in developing bone, although its role is unclear. The work now reported explores changes in the activity of this Zn2+-containing enzyme that occur during Ca2+ accumulation by matrix vesicles (MV). A marked loss (up to 65-70%) in AP activity was found to accompany Ca2+ accumulation by MV. These two events were highly correlated, both temporally and quantitatively. Investigation into possible causes revealed that the decline in AP activity during Ca2+ uptake was not due to action of proteases but rather resulted from interaction with the developing mineral phase, loss of metal ions (Zn2+ and Mg2+) from the active site of the enzyme, and concomitant irreversible denaturation of the enzyme. Protease inhibitors did not protect AP from loss of activity during mineralization; in contrast, protease treatments, which progressively destroyed the ability of MV to accumulate Ca2+ actually reduced loss of AP activity. These findings clearly demonstrate that AP is present at the site of MV mineralization and that its catalytic activity is profoundly reduced by the mineralization process.