Growth Plate Cartilage Matrix Research Articles

Structural Features of Heparan Sulfate from Multiple Osteochondromas and Chondrosarcomas.

Multiple osteochondromas (MO) is a hereditary disorder associated with benign cartilaginous tumors, known to be characterized by absence or highly reduced amount of heparan sulfate (HS) in the extracellular matrix of growth plate cartilage, which alters proper signaling networks leading to improper bone growth. Although recent studies demonstrated accumulation of HS in the cytoplasm of MO chondrocytes, nothing is known on the structural alterations which prevent HS from undergoing its physiologic pathway. In this work, osteochondroma (OC), peripheral chondrosarcoma, and healthy cartilaginous human samples were processed following a procedure previously set up to structurally characterize and compare HS from pathologic and physiologic conditions, and to examine the phenotypic differences that arise in the presence of either exostosin 1 or 2 (EXT1 or EXT2) mutations. Our data suggest that HS chains from OCs are prevalently below 10 kDa and slightly more sulfated than healthy ones, whereas HS chains from peripheral chondrosarcomas (PCSs) are mostly higher than 10 kDa and remarkably more sulfated than all the other samples. Although deeper investigation is still necessary, the approach here applied pointed out, for the first time, structural differences among OC, PCS, and healthy HS chains extracted from human cartilaginous excisions, and could help in understanding how the structural features of HS are modulated in the presence of pathological situations also involving different tissues.

Accelerated Growth Plate Mineralization and Foreshortened Proximal Limb Bones in Fetuin-A Knockout Mice

The plasma protein fetuin-A/alpha2-HS-glycoprotein (genetic symbol Ahsg) is a systemic inhibitor of extraskeletal mineralization, which is best underscored by the excessive mineral deposition found in various tissues of fetuin-A deficient mice on the calcification-prone genetic background DBA/2. Fetuin-A is known to accumulate in the bone matrix thus an effect of fetuin-A on skeletal mineralization is expected. We examined the bones of fetuin-A deficient mice maintained on a C57BL/6 genetic background to avoid bone disease secondary to renal calcification. Here, we show that fetuin-A deficient mice display normal trabecular bone mass in the spine, but increased cortical thickness in the femur. Bone material properties, as well as mineral and collagen characteristics of cortical bone were unaffected by the absence of fetuin-A. In contrast, the long bones especially proximal limb bones were severely stunted in fetuin-A deficient mice compared to wildtype littermates, resulting in increased biomechanical stability of fetuin-A deficient femora in three-point-bending tests. Elevated backscattered electron signal intensities reflected an increased mineral content in the growth plates of fetuin-A deficient long bones, corroborating its physiological role as an inhibitor of excessive mineralization in the growth plate cartilage matrix - a site of vigorous physiological mineralization. We show that in the case of fetuin-A deficiency, active mineralization inhibition is a necessity for proper long bone growth.

Zone-specific micromechanical properties of the extracellular matrices of growth plate cartilage.

Growth plate cartilage demonstrates a unique capacity for cell proliferation and matrix synthesis while sustaining mechanical stresses. To test the hypothesis that the extracellular matrices along various depth of growth plate cartilage have different elastic properties, microindentation by atomic force microscopy was applied to en bloc dissected rabbit cranial base growth plate samples from the reserve zone to mineralizing zone in 50-microm increments. The average elastic modulus upon transverse indentation orthogonal to the long axis of the growth plate showed a gradient distribution, increasing significantly from the reserve zone (0.57 +/- 0.05 MPa) to mineralizing zone (1.41 +/- 0.19 MPa). Longitudinal indentation of the reserve zone along the long axis of the growth plate revealed an average elastic modulus of 0.77 +/- 0.12 MPa, significantly different from the same zone upon transverse indentation. Thus, the extracellular matrix of growth plate cartilage seems to be inhomogenous in its capacity to withstand mechanical stresses.

Separation and quantification of chicken and bovine growth plate cartilage matrix vesicle lipids by high-performance liquid chromatography using evaporative light scattering detection

Matrix vesicles (MV) are lipid bilayer-enclosed nanoscale structures that initiate extracellular mineral formation in most vertebrate species. Little attention has been given to differences between species in membrane lipid composition or to how new mineral is formed in MV. To explore more precisely the lipids of MV isolated from avian and bovine species, we developed a new high-performance liquid chromatography (HPLC) method used in combination with evaporative light scattering detection (ELSD) to quantify their lipid composition. HPLC analyses were performed on a Lichrosorb silica column using separate binary gradient elution systems for analyzing polar and nonpolar lipids. Standard mixtures of both phospholipids and nonpolar lipids were used to prepare calibration curves for each lipid, which were analyzed mathematically by polynomial regression for accurate quantitation. This new methodology provides high-resolution separations and quantitation of both the polar and the nonpolar lipids typically present in biological membranes, including lyso- (monoacyl-) phospholipids. We have applied this method to quantitate the phospholipid and nonpolar lipid composition of MV isolated from chicken and bovine growth plate cartilage. We also compared the ability of these MV to induce mineral formation. While the ability to induce mineralization and the lipid composition were generally similar, some significant differences between MV from these two disparate species were seen.

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.

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.

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 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.

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.

Articular Cartilage Vesicles Generate Calcium Pyrophosphate Dihydrate‐Like Crystals in Vitro

To identify the morphology of a mineral-forming of adult porcine hyaline articular cartilage digest and characterize the mineral it forms. Electron microscopy, Fourier transform infrared (FTIR) spectroscopy, x-ray microanalysis, compensated polarized light microscopy, and biochemical studies including 14C-labeled UDPG pyrophosphohydrolase radiometric assay. This fraction of articular cartilage digest contained membrane-limited vesicles resembling growth plate cartilage matrix vesicles and formed mineral after only 24 hours in physiologic salt solution containing 1 mM ATP: The mineral contained inorganic pyrophosphate, 95% of which derived from ATP, and phosphate, 93% of which derived from inorganic phosphate in the medium. The FTIR spectrum of this mineral closely resembled the spectrum of standard calcium pyrophosphate dihydrate (CPPD) crystals. Compensated polarized light microscopy showed positively birefringent, rod-shaped crystals morphologically identical to CPPD. Ca:P ratios, defined by energy-dispersive microanalysis, were also consistent with CPPD. The articular cartilage vesicle fraction of porcine hyaline cartilage is capable of generating mineral that strongly resembles CPPD.

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.

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 phosphatidyl-inositol-specific phospholipase C (PIasc C), followed by chromatography on DEAE-Bio-Gel A and Reactive-Red agarose. Two AP species having apparent M r 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 M r 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.

The Ultrastructure of Mature and Mineralizing Cartilaginous Matrix in Deer Antler (Odocoileus Hemionus Hemionus)

Core biopsies of mature and mineralized cartilage were removed from the main beams and tines of deer antler at various times throughout the growing season and were examined with an electron microscope (Hitachi, HS-8; Zeiss, EM-9A). Certain morphological characteristics were identical with those features reported for matrices of mature and mineralizing somatic cartilage .The lacunae (L) of the mature cartilage cells were not devoid of matrix components. Although the lacunae lacked any banded collagen fibers (Fig. 1), they did contain many interconnected fibrils (F) which were associated with lead-stained granules (arrows). The lead binding coincided with matrix granules described in the lacunae and general matrix of growth plate cartilage.