Two patterns of calcification in primary (physeal) and secondary (epiphyseal) growth cartilage

It is generally stated that the process of cartilage calcification and ossification is the same in the physeal (primary growth center) and epiphyseal (secondary growth center) growth plates. Reexamination of osteophyte growth led to the proposal that these growth plates differ. This proposition was tested by examining rabbit and human material from both sites before and after maceration; both tissue preparations were processed for light microscopy, and the macerated tissues were also studied by scanning electron microscopy (SEM). The physis showed the well-recognized, longitudinal calcified tubal structures in which capillaries make direct contact with and resorb the nonmineralized, transverse septal cartilage. In the epiphysis, the transverse septal cartilage was also mineralized, producing a continuous calcified sheet, perforated only by a limited number of channels and susceptible only to osteoclastic removal. This variation in mineral distribution modifies the way in which the primary spongiosa is formed during growth.

Hydrops-ectopic calcification-moth-eaten skeletal dysplasia (Greenberg dysplasia): prenatal diagnosis and further delineation of a rare genetic disorder

An offspring of consanguineous parents of East-Indian origin was found prenatally to have hydrops fetalis, short limb dwarfism, polydactyly and chondro-osseous changes consistent with Greenberg hydrops-ectopic calcification-moth-eaten skeletal dysplasia (HEM) dysplasia. The radiological changes include platyspondyly with multiple extra ossification centers, extraneous calcification in the ribs, sternum, pelvis, and epiphysis, and moth-eaten long bones. The histopathological changes included chondrocytes with dilated rough endoplasmic reticulum and inclusion bodies with homogeneous material of intermediate electron density. These findings further delineate the spectrum of this rare autosomal recessive skeletal dysplasia.

An inbred line of transgenic mice expressing an internally deleted gene for type II procollagen (COL2A1). Young mice have a variable phenotype of a chondrodysplasia and older mice have osteoarthritic changes in joints

Studies were carried out on a line of transgenic mice that expressed an internally deleted COL2A1 gene and developed a phenotype resembling human chondrodysplasias (Vandenberg et al. 1991. Proc. Natl. Acad. Sci. USA. 88:7640-7644. Marked differences in phenotype were observed with propagation of the mutated gene in an inbred strain of mice in that approximately 15% of the transgenic mice had a cleft palate and a lethal phenotype, whereas the remaining mice were difficult to distinguish from normal littermates. 1-d- and 3-mo-old transgenic mice that were viable showed microscopic signs of chondrodysplasia with reduced amounts of collagen fibrils in the cartilage matrix, dilatation of the rough surfaced endoplasmic reticulum in the chondrocytes, and decrease of optical path difference in polarized light microscopy. The transgenic mice also showed signs of disturbed growth as evidenced by lower body weight, lower length and weight of the femur, decreased bone collagen, decreased bone mineral, and decreased resistance of bone to breakage. Comparisons of mice ranging in age from 1 d to 15 mo demonstrated that there was decreasing evidence of a chondrodysplasia as the mice grew older. Instead, the most striking feature in the 15-mo-old mice were degenerative changes of articular cartilage similar to osteoarthritis.

Electron microscopy of calcification during high-density suspension culture of chondrocytes

Chondrocyte cultures grown in centrifuge tubes with intermittent centrifugation differentiate into hypertrophic chondrocytes and form calcification. We examined chondrocytes cultured in this system electron microscopically. Rat growth-plate chondrocytes were seeded in a plastic centrifuge tube and cultured in the presence of Eagle's minimum essential medium supplemented with 10% fetal bovine serum and 50 micrograms of ascorbic acid per ml. Specimens were examined by using electron microscopy and selected-area electron-diffraction techniques. In the early stage of culture, a few chondrocytes were scattered and extracellular matrices were not observed. In the middle stage of the cultures, the chondrocytes resembled proliferative cells. Matrix vesicles appeared to be budding from the cell surfaces of chondrocytes and were observed sparsely in the extracellular matrices, which were well formed around the chondrocytes. Matrix vesicles increased substantially during the following cultures. In the mature stage of the cultures, crystal formation related to matrix vesicles was observed. In the 33-day cultures, several masses of calcified matrix were formed and it was confirmed to be apatite by selected-area electron diffraction analysis. The chondrocytes appeared hypertrophic during this same stage. The 56-day culture was similar to the 33-day culture. It was concluded that this culture system provides an extracellular-matrix mineralization which is produced by chondrocytes per se.

Computer modeling of the oxygen supply and demand of cells of the avian growth cartilage

We have used computer modeling studies to investigate the oxygen supply to the prehypertrophic and hypertrophic regions of avian growth plate. We measured experimentally the characteristics of the oxygen consumption of chondrocytes at different oxygen tensions. The oxygen consumption decreases at low oxygen tensions. This relation between oxygen tension and oxygen consumption serves as a protective mechanism that prevents the cells in the prehypertrophic zone from becoming anoxic in the regions farthest from the blood vessels. The results of the calculations, when combined with redox measurements of the cells in the growth plate, indicate that the metabolism of the chondrocytes is not controlled simply by the available oxygen supply.

Composition and organization of the collagen network produced by fetal bovine chondrocytes cultured at high density

Fetal bovine chondrocytes isolated from the resting zone of epiphyseal cartilage were maintained in high-density culture for 4 weeks. From Day 2 in culture, the chondrocytes deposited an extracellular matrix composed of Types II, IX, and XI collagen. Types IX and XI collagen were restricted to the pericellular domain from Day 5. By 2 weeks the entire cell layer stained for antibodies to Type II and IX collagens. Type XI could be demonstrated throughout the cell layer by pepsinization of the sections. Results from both rotary shadowing and immunochemistry showed that the fibrils formed in culture were heterotypic, with Type IX collagen arranged along the surface and with Type XI collagen buried in Type II fibrils. Nonspecific Type VI collagen and the glycoproteins tenascin and fibrillin, previously described in cartilaginous tissue, were identified by their ultrastructural characteristics in the cell layer homogenate. Although the cells presented morphological characteristics of chondrocytes and still expressed cartilage-specific collagens, the appearance of Type I collagen in the culture cell layer after 4 weeks of culture demonstrates a partial dedifferentiation of the chondrocytes. The culture system described in this report provides an interesting tool for maintaining chondrocytes in a cartilage-like matrix to study the influence of different physical and chemical factors on the expression and differentiation of the cells.

Assembly of cartilage collagen fibrils is disrupted by overexpression of normal type II collagen in transgenic mice

Cartilage collagen fibrils, which are characterized by their thin, uniform diameters, are formed of a multicomponent system of three collagen types (II, IX, and XI) and interacting proteoglycans. We have used a genetic approach to test whether the proper assembly of this multiprotein structure was altered by overexpression of one of its normal components. Here we show that in transgenic mice in which the normal mouse alpha 1(II) collagen is overexpressed, thick abnormal collagen fibrils are generated. Mice that showed the highest expression of the transgene also displayed a larger proportion of abnormal fibrils and died at birth. We propose that an imbalance among the constituents of the cartilage collagen fibrils disrupts the mechanism that controls their assembly. The results show the applicability of the transgenic mice system to studies of complex multicomponent protein assemblies in intact animals.

Impact of freeze substitution on biological electron microscopy

Considering the increasing necessity for improved preparation techniques in biological electron microscopy as a basis for the identification and localization of cellular substances within the compartments of the cell, this review is focussed on the method of freeze substitution as an important link between the cryofixation (ultrarapid freezing) and resin embedding of biological specimens. The theory and practice of freeze substitution is summarized with particular interest in the physical and thermodynamic as well as in the chemical basis of this technique. A survey of practical aspects of the technical process of freeze substitution concerning the equipment and various protocols successfully applied in biological systems is also given. The main advantage of freeze substitution versus conventional chemical fixation is seen in the maintenance of the hydration shell of molecules and macromolecular structures. This results in an improved fine structural preservation, superior retention of the antigenicity of proteins and decreased loss of unbound, diffusible cellular components. Examples of excellent visualization of the ultrastructure of macromolecular complexes (nucleic acids, extracellular material, membranes etc.), small organisms (bacteria, algae, cyanobacteria and fungi) and large biological samples such as plant and animal tissue as well as the plant-pathogen (fungus) interface and infection structures are presented. Recent data on the molecular characterization of freeze-substituted biological tissue are exemplified with special emphasis on the subcellular detection of soluble components (elements, lipids, proteins and drugs) and the inter-/intracellular localization of proteins including foreign proteins in transgenic plants. The molecular analysis of freeze-substituted specimens is achieved by the combination of low temperature preparation techniques in biological electron microscopy with various detection methods such as X-ray microanalysis, immunocytochemistry and high resolution autoradiography.

Characterization of the mineralization process in cultures of rabbit growth plate chondrocytes

The present study was undertaken to investigate the mineralization process in chondrocyte cultures. Chondrocytes were isolated from the growth plate of ribs of 4-week-old rabbits. The nature and properties of mineral crystals precipitated in chondrocyte cultures were compared with those of crystals formed in the hypertrophic zone and bone of rabbit rib growth plates in vivo. The chondrocytes were maintained at high density on type II collagen-coated dishes in Eagle's medium, alpha-modification, with 10% fetal bovine serum and 50 micrograms/ml of ascorbic acid. These cells differentiated into hypertrophic cells 10 days after seeding and produced alkaline phosphatase and 1,25-dihydroxyvitamin D3 receptors on Days 30-70 at levels as high as those in the lower hypertrophic zone in vivo. Mineralization was initiated between Days 20 and 30 and advanced progressively throughout the culture period. However, mineralization was suppressed by the addition of parathyroid hormone (2 x 10(-8) M) or by the presence of fibroblasts. Examination by electron microscopy and Fourier transform infrared (FTIR) spectroscopy verified that mineralized nodules formed in vitro were composed of small apatite crystals. Importantly, FTIR spectral features of the apatite crystals (e.g., the prominent PO4 bands at 1125 and 1032 cm-1) were similar to those of cartilage apatites formed in vivo and differed markedly from those of carbonated bone apatites. These results suggest that growth plate chondrocytes cultured on collagen-coated dishes are an appropriate model for studies on cartilage mineralization.

Ultrastructure and X-ray microanalysis of epiphyseal growth cartilage of femoral head processed by rapid-freezing and freeze-substitution

Epiphyseal growth cartilage of the femoral head obtained from Wistar rats was investigated after fixation by a rapid-freezing and freeze-substitution. Liquid helium was used in order to achieve a fast cooling rate without ice-crystal damage during the rapid freezing. Use of the rapid-freezing and freeze-substitution procedure provided better ultrastructural preservation of the chondrocyte than conventional chemical fixation methods. This procedure allowed a more reliable approach to electron probe analysis. X-ray microanalysis of the specimens confirmed that calcium is not detected in the initial matrix vesicles as a result of the freezing process. The results suggest that calcium release from precipitates occurs in the free state without any detectable formation of hydroxyapatite at the initial stage of calcification and that calcium is not tightly bound to the matrix vesicles.

Strontium, a tracer to study the transport of calcium in mineralizing tissues by electron probe microanalysis

In growth plate cartilage the mineralization starts extracellularly in the lower hypertrophic zone. The mineral formed is the calcium phosphate apatite. Enough calcium and phosphate must be available at the mineralization front as well as in regions with proceeding mineralization. There must be a transport of Ca (and phosphate) to these sites. Electron probe X-ray microanalysis is a well established method to analyze element concentrations in small volumes, but it cannot discriminate isotopes. Strontium is similar to Ca in its chemical and biological behaviour and is therefore a suitable tracer to investigate the transport of Ca. Small amounts of Sr (0.1 g per kg body weight) were administered intraperitoneally to young rats. After definite intervals of time ranging from 10 to 120 min, 2-4 rats were killed. On freeze dried cryosections the Sr/Ca ratio of the serum and of the intra- and extracellular space of the growth plate were measured. The Sr/Ca ratio reaches its maximum after about 10 min in the serum and after 20 min in the extracellular space of growth plate cartilage. The intracellular Sr/Ca ratio shows large variations because of the low intracellular Ca and Sr concentration, and is lower than the extracellular ratio for times shorter than 30 min. No significant differences were found between the different cell zones of the unmineralized growth plate cartilage. The results demonstrate that the transport of Ca to the growth plate cartilage is relatively fast and that in growth plate cartilage, Ca is transported extracellularly, not intracellularly.

An ultrastructural study of mitotic chondrocytes in the Swarm rat chondrosarcoma

The Swarm rat chondrosarcoma is a well established model system for the biochemical studies of cartilage proteoglycans. In this study, we observed the ultrastructure of mitotic chondrocytes in this tumor to confirm whether it is also useful as a morphological model system to examine the mitosis of chondrocytes. As a result, the mitotic chondrocytes in this tumor contained fairly prominent cell organelles, and the endoplasmic reticulum was mainly vacuolized and the Golgi stacks were replaced by the cluster of small vesicles during the later stage of the mitotic cycle. Although the cytoplasmic division began at the telophase, the cytoplasmic cleavage furrow was so narrow that dividing chondrocytes looked as if they were partitioned by a slit. These findings are almost consistent with the changes that occurred in the mitotic chondrocytes of the tibial growth plate, although the degree of disorganization in the Golgi apparatus is slightly different. Therefore, this tumor is useful as a convenient morphological model system to examine the mitosis of chondrocytes because of the facility for taking specimens.

An ultrastructural study of mitotic chondrocytes in the proliferative zone of the rat tibial growth plate

Mitotic chondrocytes containing fairly prominent cell organelles were observed in the proliferative zone of the rat tibial growth plate by electron microscopy. During the later stage of mitosis, the endoplasmic reticulum was mostly vacuolated, and the Golgi stacks were replaced by spherical and cylindrical vacuoles and small vesicles. The cytoplasmic division began at early telophase. However, the cytoplasmic cleavage furrow was so narrow that dividing chondrocytes looked as if they were partitioned by a slit. This is probably one reason for the appearance of the binuclear cells that are occasionally observed in the tibial growth plate.

High-resolution immunolocalization of osteopontin and osteocalcin in bone and cartilage during endochondral ossification in the chicken tibia

The ultrastructural distribution of two noncollagenous proteins, osteopontin (OPN) and osteocalcin (OC), originally extracted from bone matrix and proposed to play an important role in bone formation, was examined in the matrices of bone and cartilage from embryonic and postnatal chicken tibial growth plates by high-resolution immunocytochemistry using the colloidal gold technique. In bone, immunolabeling patterns using polyclonal antibodies against chicken OPN and OC were generally similar in that both showed an intense, but regionally variable, labeling of mineralized bone matrix and small mineralization loci dispersed throughout the osteoid and containing prominent condensed organic material. Unmineralized osteoid showed weak-to-moderate labeling. In the mineralized bone matrix proper, labeling was predominantly associated with amorphous, electron-dense patches of organic material among the collagen fibrils. In growth plate cartilage, both proteins first appeared related to calcified cartilage in the hypertrophic zone, although the labeling patterns were somewhat different. For OPN, gold particles were mostly associated with an organic lamina limitans-like density containing condensed, filamentous organic matrix at the periphery of small nodules and large masses of calcified cartilage, with additional moderate labeling throughout the interior of the calcified cartilage. For OC, labeling was observed over filamentous structures throughout the calcified cartilage matrix, with some, but less, labeling at the periphery. In the lowermost zones of the growth plate, the major reaction using both antibodies was found over a layer of dense, amorphous organic material at the periphery of the calcified cartilage at the future bone/calcified cartilage interface, a labeling pattern that persisted following bone deposition at these sites. OPN and to a lesser extent OC were also concentrated in cement (resting, reversal) lines. Throughout the bone and cartilage of the tibia, cells of both the osteoblastic and the osteoclastic lineages were found directly apposed to labeled surfaces and lamina limitans of organic matrix containing OPN and OC. In summary, it is concluded from the immunocytochemical data presented here that the association of OPN and OC with mineralized regions of the extracellular matrices of bone and cartilage and the accumulation of these proteins at tissue surfaces and interfaces are consistent with the hypotheses that they play a role in the extracellular mineralization process per se and/or that they may mediate cell adhesion and dynamics.

Characterization of collagen types XII and XIV from fetal bovine cartilage

The structurally related type XII-like collagen molecules TL-A and TL-B were recently identified in fetal bovine epiphyseal cartilage and subsequently shown to be collagen types XII and XIV, respectively. By indirect immunofluorescent staining of cartilage using monoclonal antibodies to the NC3 domains of each molecule, it was shown that type XII collagen was present predominantly around cartilage canals, the articular surface, subperichondrial margins, and the perichondrium, was less so in the remaining cartilage matrix, and was absent from the growth plate region. In the permanent cartilage of trachea, type XII stained somewhat more intensely in the margins beneath the loose connective tissue. Type XIV collagen localized more uniformly throughout the articular cartilage and was also absent from the growth plate region, whereas in tracheal cartilage, its distribution was similar to type XII. We have characterized the structure of these cartilage molecules and compared them with those from fetal bovine skin. Extraction of cartilage with 1 M NaCl and differential NaCl precipitation yields a fraction enriched for these two collagens. Analysis by sodium dodecyl sulfate-polyacrylamide gel electrophoresis and immunoblotting with monoclonal antibodies to the large amino-terminal non-triple-helical domain, NC3, revealed the presence in cartilage of two forms of type XII collagen: type XIIB, the molecule previously identified in chick and bovine tissues, and type XIIA, a much larger form equivalent to the molecule recently identified in WISH-transformed epithelial cell culture medium (Lunstrum, G. P., McDonough, A. M., Marinkovich, M. P., Keene, D. R., Morris, N. P., and Burgeson, R. E. (1992) J. Biol. Chem. 267, 20087-20092). Digestion with bacterial collagenase shows that the increased mass is present in the NC3A domain. Additional purification by velocity sedimentation and observation of rotary-shadowed images demonstrates molecules with extended non-triple-helical arms approximately 80 nm in length analogous to the WISH cell molecules. Electrophoretic mobilities of bands corresponding to type XIIA, but not type XIIB, are sensitive to chondroitinase ABC, indicating that type XIIA is a chondroitin sulfate proteoglycan and that modification occurs predominantly within the NC3A domain distal to NC3B. Neither type XIIB from skin nor type XIIA from WISH cells are chondroitinase-sensitive. By similar analysis, a portion of the type XIV collagen chains in cartilage was also sensitive to chondroitinase digestion. Chondroitin sulfate is apparently not located on its NC3 domain. As in skin, collagen types XII and XIV have subtly different distributions within cartilage and type XII may have a tissue-specific structure.

Changes in growth-plate morphology associated with rejection of rat-limb allografts

Histological and electron microscopic studies were performed to demonstrate the changes in the morphology of the growth plate that occur in allografts obtained from the limbs of growing rats. A genetically defined model was used in which the right hindlimbs of Lewis rats were orthotopically transplanted into Fischer-344 recipient rats. These strains are matched for major histocompatibility antigens but mismatched for minor histocompatibility antigens. The disparity at the minor histocompatibility complex between the Lewis donors and the Fischer recipients creates a weak histocompatibility barrier to transplantation. Lewis-to-Lewis syngeneic limb grafts were used as controls. The proximal parts of the transplanted tibiae were excised during acute rejection of the allograft on days 1, 5, 8, 11, 14, and 28 postoperatively. During rejection, a widened zone of calcified cartilage in the growth plate was observed at eleven days; this zone increased progressively thereafter. The number of chondroclasts in the primary spongiosa of the metaphysis had decreased significantly at eleven days, and chondroclasts had disappeared completely at fourteen days, in association with mononuclear cell infiltration. Electron microscopic examination revealed inactive morphology in some chondroclasts at eight days, and the number of inactive chondroclasts had increased significantly on day 11. At fourteen days, there were no viable chondroclasts in the primary spongiosa, and only remnants of degenerated chondroclasts were present. These findings suggest that the chondroclasts were early targets of rejection and their loss resulted in the cessation of resorption of the calcified cartilage. However, the proliferation and maturation of chondrocytes in the growth plate and the calcification of the matrix continued, despite progression of rejection in the metaphysis. Thus, survival of the chondrocytes and rejection of the chondroclasts apparently led to the formation of a widened calcifying zone in the growth plate.

Light and electron microscopic abnormalities in diastrophic dysplasia growth cartilage

Light and electron microscopic studies of diastrophic dysplasia iliac crest growth cartilage performed on five occasions in two patients from 1 to 10 years of age reveal extensive cell and matrix abnormalities at each time period. Light microscopy shows atypical chondrocytes with extreme variation in size and shape, and premature cytoplasmic degeneration, and formation of target ghost cells. Prominent, densely staining fibrotic foci are present throughout the cartilage. Ultrastructure reveals some structurally intact chondrocytes with a single large fat inclusion, slightly dilated rough endoplasmic reticulum, and abundant glycogen. As early as 1 year of age cystic degeneration of chondrocyte cytoplasm is evident with indistinct organelles seen. The cartilage matrix demonstrates a general increase in fibrous tissue as well as the fibrotic foci. The collagen in these foci is remarkably abnormal. It is composed of short, extremely broad fibrils ranging from 150 to 950 nm in width which are separated at their terminal ends but fused to each other centrally in random fashion. On cross-section there are very few round fibrils but rather a marked irregularity in shape giving the appearance of having fibrils randomly added to others to form enlarged nonuniform fibril aggregates. On longitudinal sectioning, regular cross-banding across the entire fibril width is seen but fibril splitting and aggregation are highly irregular.(ABSTRACT TRUNCATED AT 250 WORDS)

Immunoelectron microscopic studies of glycosaminoglycans in the metaphyseal bone trabeculae of growing rats

The types and distribution of glycosaminoglycans (GAGs) were studied immunocytochemically in osteoid, mineralized bone matrix, and cartilage matrix of growing rat metaphyseal bone after aldehyde fixation and EDTA demineralization, using four monoclonal antibodies (mAbs 1-B-5, 2-B-6, 3-B-3 and 5-D-4). These mAbs specifically recognize epitopes in non-sulphated chondroitin (C0-S); chondroitin 4-sulphate (C4-S) and dermatan sulphate (DS); chondroitin 6-sulphate (C6-S) and C0-S; and keratan sulphate (KS) respectively. In osteoid, all mAbs except 1-B-5 weakly stained matrix material on and between collagen fibrils, and moderately stained organic material corresponding to bone nodules, which are known sites of mineralization. However, the staining of osteoid abruptly decreased at the mineralization front; weak staining was confined mostly to the organic material of bone nodules in mineralized bone matrix, with very weak or no staining of the rest of the bone matrix. This staining progressively decreased toward the mineralized cartilage matrix and became negative. The mineralized cartilage matrix and lamina limitans reacted strongly with all mAbs except 5-D-4. These results indicate that osteoid contains sulphated proteoglycans containing C4-S and/or DS, C6-S and KS, and subsequent bone matrix mineralization appears to require accumulation of these macromolecules within bone nodules and eventual loss of these substances for complete mineralization, whereas proteoglycans containing C0-S, C4-S and/or DS, and C6-S still exist in mineralized cartilage matrix and lamina limitans.

Interaction of basic fibroblast growth factor with bovine growth plate chondrocytes

The basic fibroblast growth factor (bFGF) family of peptides influences a wide range of cellular actions. To better understand the possible role of bFGF in the growth plate, we have characterized the interaction of this growth factor with isolated bovine growth plate chondrocytes. Basic FGF interacts with two classes of binding sites on these cells. One is consistent with high-affinity bFGF receptors and the other with low-affinity heparin-like binding sites on the chondrocyte surface. Radiolabeled bFGF binding studies revealed approximately 4 x 10(6) binding sites per cell, with a Kd of approximately 42 nM. Graded concentrations of heparin or NaCl competed with [125I]-labeled bFGF in a dose-dependent fashion, reducing [125I]-labeled bFGF binding by 75 and 97%, respectively. The data suggest the presence of a high-capacity, low-affinity class of binding sites with the properties of a heparin-like moiety. Affinity cross-linking of [125I]-labeled bFGF to chondrocytes labeled two principal species with apparent molecular masses of 135 and 160 kDa. Labeled bFGF was specifically displaced from both species by subnanomolar concentrations of unlabeled bFGF. These high-affinity, low-capacity binding sites are characteristic of classical bFGF receptors. Binding of [125I]-labeled bFGF to these sites was also influenced by heparin, consistent with coregulation of binding to the two classes of binding sites. The data suggest that bFGF participates in the regulation of skeletal growth at the growth plate and that this regulation may involve bFGF interaction with at least two distinct classes of binding sites.

Innervation of bone from healthy and arthritic rats by substance P and calcitonin gene related peptide containing sensory fibers

Mechanical stress causes remodelling of bone, a transformation of bone structure by physical forces through an unknown mechanism. Inflammation also affects bone structure, through altered use and the production of various inflammatory mediators. The peripheral nervous system may play both a sensory and an efferent role in the mechanical and inflammatory influences on bone structure. We studied the occurrence of substance P and calcitonin gene related peptide (CGRP) containing nerves in periosteal tissue, bone marrow, diaphysis and epiphysis of the ankle and knee joints of healthy and adjuvant arthritic rats. In arthritic animals, only ankle joints were affected by the inflammation. The periosteum was richly innervated both in healthy and arthritic animals. In arthritic rats few nerve fibers penetrated the woven, callous bone underlying the periosteum. Also bone marrow contained substance P and CGRP immunoreactive nerves in normal bone, whereas the hypercellular bone marrow of arthritic rats showed a decrease in the density of substance P and CGRP containing fibers. Epiphysis had a dense innervation compared to diaphysis. In contrast to large erosions, small peripheral erosions contained some CGRP immunoreactive fibers, perhaps as a sign of attempts of reactive repair. Our results suggest a local delivery system of potent peptide regulatory factors in bone, a system also affected by the pathophysiology of arthritis.

Spaceflight and age affect tibial epiphyseal growth plate histomorphometry

Growth plate histomorphometry of rats flown aboard the Soviet biosatellite COSMOS 2044, a 14-day spaceflight, was compared with that of control groups. In growth plates of flight animals, there was a significant increase in cell number per column and height of the proliferative zone and a reduction in height and cell number in the hypertrophy/calcification zone. No significant differences were found in matrix organization at the ultrastructural level of flight animals, indicating that although spaceflight continues to affect bone growth of 15-wk-old rats, extracellular matrix is not altered in the same manner as seen previously in younger animals. All groups showed growth plate characteristics attributed to aging: lack of calcification zone, reduced hypertrophy zone, and unraveling of collagen fibrils. Tail-suspended controls did not differ from other controls in any of the parameters measured. Our results suggest that growth plates of older rats are less responsive to unloading by spaceflight or suspension than those of younger rats and provide new evidence about the modifying effect of spaceflight on the growth plate.

Effects of repetitive strains on vertebral end plates in young rats

A histologic study of vertebral end plates was performed on young rats' tails subjected to intensive passive motion. Seven six-week-old rats had two-hour motion cycles daily, for two months. Histologic changes of proximal caudal vertebrae in the experimental group were compared with those of a control group of seven rats of the same litter which were allowed to grow freely without mechanical stress. The main findings were three striking protrusions of disk tissue into end plates, not observed in the control animals. End plate axial bulges lacking spindle-shaped cells and an increase in chondrocytes in the adjacent articular cartilage were observed. The growth-plate thickness was uneven and was absent in some areas, with disorganization of chondrocyte columns. All of these findings were present to a lesser degree in the control group and appeared to be similar to histologic changes observed in Scheuermann's disease.

Ocular-chondrodysplasia in labrador retriever dogs: a morphometric and electron microscopical analysis

Ocular-chondrodysplasia in Labrador Retriever dogs is characterized by short-limbed dwarfism and ocular abnormalities. The purposes of the present study were to develop morphological criteria to define the matrix and/or chondrocytic abnormalities associated with this chondrodysplasia, and to test the hypothesis that ineffective matrix-directed cellular swelling was associated with the decreased longitudinal bone growth in these animals. The proximal and distal radial growth plates were collected from four affected animals of the same litter. Stereological techniques were used to analyze both cellular shapes and cellular volume changes in the hypertrophic zone. The pathological changes seen in these growth plates varied between animals and included disorganization of cellular columns with abnormal extent of calcification. Chondrocytes of all zones contained two types of abnormal cellular inclusions classified as light and dark, based on the intensity of eosinophilic staining. Both types of inclusions contained material that resembled the surrounding extracellular matrix, varying only in the apparent hydration of the contents. It could be demonstrated that light inclusions were located in the peripheral cytoplasm and connected to the extracellular matrix through narrow channels. By contrast, dark inclusions were membrane bound and perinuclear. Chondrocytes with multiple, large inclusions appeared to be undergoing degenerative changes. Although the final volume achieved by hypertrophic chondrocytes was consistent with that of normal growth plates, there was a high level of variability of chondrocytic shape and evidence of premature cellular condensation in the maturation zone. The severity of the dwarfism correlated both with the extent of chondrocytic changes and the severity of the ocular lesions.(ABSTRACT TRUNCATED AT 250 WORDS)

Lactate dehydrogenase isoenzymes in matrix vesicles (review)

Matrix vesicles (MV) isolated from mineralizing tissues contain high alkaline phosphatase (ALPase) activities associated with the membrane; this may be because MV originate from the plasma membrane of chondrocytes. Previous studies in our laboratory demonstrated that lactate dehydrogenase (LDH) isoenzymes, which appeared to be derived from chondrocytes cytosol, were located in MV of the epiphyseal growth plate of young-rabbit leg bones [1]. In the epiphyseal cartilage, alkaline phosphatase (ALPase) is enriched in the growth zone, whereas it is rarely detected in the resting zone, suggesting that MV containing ALPase are not present in the resting zone. In recent study, we divided the epiphyseal cartilages of young-rat rib bones into the growth zone and the resting zone, followed by the isolation of MV after collagenase digestion. MV containing ALPase and LDH were found in the growth zone, and surprisingly, vesicles containing LDH without ALPase were found in the resting zone [2]. The function of LDH-containing vesicles without ALPase is unknown at the present. However, these findings might accelerate the studies on cell-mediated calcification, because (1) LDH could be a marker enzyme of these vesicles, (2) LDH is found to be a specific cytosolic enzyme which is enfolded in these vesicles, suggesting that an unknown mechanism for the specific uptake of the cytosolic enzyme might be present.

Presence and specific concentration of carbonic anhydrase II in matrix vesicles

Matrix vesicles were isolated from the epiphyseal growth plates of normal weanling rats, and the presence of carbonic anhydrase II was demonstrated by Western blotting and ultrastructural immunolocalization using the immunogold technique. Total carbonic anhydrase activity was assayed and showed a statistically significant increase in matrix vesicles as compared to normal rat chondrocytes derived from the same growth plates. These results are the first to establish the presence of carbonic anhydrase in matrix vesicles.