Perlecan, the multidomain heparan sulfate proteoglycan of basement membranes, is also a prominent component of the cartilaginous primordia in the developing human fetal spine.

The aim of this study was to localize perlecan in human fetal spine tissues. Human fetal spines (12-20 weeks; n=6) were fixed in either Histochoice or 10% neutral buffered formalin, routinely processed, paraffin-embedded, and 4-microm sagittal sections were cut and stained with toluidine blue, H&E, and von Kossa. Perlecan, types I, II, IV, and X collagen, CD-31, aggrecan core protein, and native and delta-HS 4, 5 hexuronate stub epitopes were immunolocalized. Toluidine blue staining visualized the cartilaginous vertebral body (VB) rudiments and annular lamellae encompassing the nucleus pulposus (NP). Von Kossa staining identified the VB primary center of ossification. Immunolocalization of type IV collagen, CD-31, and perlecan delineated small blood vessels in the outer annulus fibrosus (AF) and large canals deep within the VBs. Perlecan and type X collagen were also prominently expressed by the hypertrophic vertebral growth plate chondrocytes. Aggrecan was extracellularly distributed in the intervertebral disk (IVD) with intense staining in the posterior AF. Notochordal tissue stained strongly for aggrecan but negatively for perlecan and types I and II collagen. Type I collagen was prominent in the outer AF and less abundant in the NP, while type II collagen was localized throughout the IVD and VB. The immunolocalization patterns observed indicated key roles for perlecan in vasculogenic, chondrogenic, and endochondral ossification processes associated with spinal development.     

Perlecan,the multidomain HS-proteoglycan of basement membranes,is a prominent pericellular component of ovine hypertrophic vertebral growth plate and cartilaginous endplate chondrocytes

The aim of this study was to immunolocalise perlecan in ovine vertebral growth plate (VGP) and cartilaginous endplate (CEP) cartilages using a monoclonal antibody (MAb A76) directed to a core protein epitope in perlecan domain-I, and to compare and contrast its localisation patterns with known cartilage matrix components. Perlecan was a prominent pericellular component of mature hypertrophic chondrocytes in the VGP and CEP in newborn 2- to 5-day-old sheep. Type I, II, VI and X collagen, chondroitin-4 and 6-sulphate, 7-D-4 chondroitin sulphate isomer proteoglycan epitope, keratan sulphate, aggrecan core protein, hyaluronan (HA) and hyaluronan binding proteins (HABPs) each had distinct localisation patterns in the VGP and CEP. Type X collagen was a prominent component of the VGP but was undetectable in the CEP. Aggrecan was strongly localised extracellularly throughout the VGP and CEP but increased cell-associated staining was also evident. In contrast to the aforementioned matrix components, HA, HABPs and perlecan were localised strongly to the pericellular matrices of the hypertrophic VGP and CEP chondrocytes apparently indicating an important role for these components in terminal chondrocyte differentiation.     

Comparative immunolocalisation of perlecan with collagen II and aggrecan in human foetal, newborn and adult ovine joint tissues demonstrates perlecan as an early developmental chondrogenic marker

We undertook a comparative immunolocalisation study on type II collagen, aggrecan and perlecan in a number of 12- to 14-week-old human foetal and postnatal (7–19 months) ovine joints including finger, toe, knee, elbow, hip and shoulder. This demonstrated that perlecan followed a virtually identical immunolocalisation pattern to that of type II collagen in the foetal tissues, but a slightly divergent localisation pattern in adult tissues. Aggrecan was also localised in the cartilaginous joint tissues, which were clearly delineated by toluidine blue staining and the type II collagen immunolocalisations. It was also present in the capsular joint tissues and in ligaments and tendons in the joint, which stained poorly or not at all with toluidine blue. In higher power microscopic views, antibodies to perlecan also stained small blood vessels in the synovial lining tissues of the joint capsule; however, this was not discernable in low power macroscopic views where the immunolocalisation of perlecan to pericellular regions of cells within the cartilaginous rudiments was a predominant feature. Perlecan was also evident in small blood vessels in stromal connective tissues associated with the cartilage rudiments and with occasional nerves in the vicinity of the joint tissues. Perlecan was expressed by rounded cells in the enthesis attachment points of tendons to bone and in rounded cells in the inner third of the meniscus, which stained prominently with type II collagen and aggrecan identifying the chondrogenic background of these cells and local compressive loads. Flattened cells within the tendon and in the surface laminas of articular cartilages and the meniscus did not express perlecan. Collected evidence presented herein, therefore, indicates that besides being a basement membrane component, perlecan is also a marker of chondrogenic cells in prenatal cartilages. In postnatal cartilages, perlecan displayed a pericellular localisation pattern rather than the territorial or interterritorial localisation it displayed in foetal cartilages. This may reflect processing of extracellular perlecan presumably as a consequence of intrinsic biomechanical loading on these tissues or to divergent functions for perlecan and type II collagen in adult compared to prenatal tissues.     

The ovine newborn and human foetal intervertebral disc contain perlecan and aggrecan variably substituted with native 7D4 CS sulphation motif: spatiotemporal immunolocalisation and co-distribution with Notch-1 in the human foetal disc

Composite agarose (1.2 %) polyacrylamide (0.6 %) gel electrophoresis was used to separate discrete populations of native aggrecan and perlecan in newborn to 10 year old ovine intervertebral discs (IVDs). Semi-dry immunoblotting using core-protein and glycosaminoglycan (GAG) side chain specific monoclonal antibodies in combination with chondroitin ABC lyase demonstrated intra-chain native 7-D-4 chondroitin sulphate (CS) sulphation motifs and variable proportions of non-reducing terminal Δ4,5-unsaturated uronate-N-acetylgalactosamine-4-sulphate [2B6(+)] and Δ4,5-unsaturated glucuronate-N-acetylgalactosamine-6-sulphate [3B3(+)] disaccharides. The relative abundance of 2-B-6(+) aggrecan increased with advancing age of the IVD samples while the converse was true for the 3-B-3(+) aggrecan population. Relative 7D4 levels in aggrecan and perlecan were highest in the newborn IVD and significantly lower in the older IVD and other cartilage samples. Quantitation of 7D4 proteoglycan by enzyme linked immunosorbent inhibition assay confirmed the newborn ovine nucleus pulposus (NP) and inner annulus fibrosus (AF) contained higher levels (1.2-1.32 μg 7-D-4-proteoglycan/mg tissue wet weight) than the 2 (0.35-0.42 μg/mg wet weight tissue) and 10 year old IVD samples (0.16-0.22 μg/mg tissue wet weight) with the outer AF zones consistently containing lower levels of 7-D-4 epitope in all cases (P?<?0.001). Cell populations on the margins of the AF and cartilaginous vertebral rudiments in newborn ovine and human foetal IVD strongly expressed 7-D-4 CS epitope and perlecan, This was co-distributed with Notch-1 expression in human foetal IVDs consistent with the 7-D-4 CS sulphation motif representing a marker of tissue development expressed by disc progenitor cell populations.     

Radial fibre proportions in human knee joint menisci. Measurement by scanning optical microscopy

The proportions of medial and lateral knee joint menisci represented by radially orientated collagen (COL) were measured in 42 specimens from 24 hospital patients examined post-mortem. Images of the fibre bundles were obtained by the 488-nm laser confocal scanning of hydrated, fixed radial blocks taken from the anterior, middle and posterior regions of the menisci after staining with picro-Sirius red. Measurements of the percentage of each image occupied by fluorescent, doubly refractile COL were made by means of a Kontron IBAS image analyser, after interactive segmentation. In areas adjoining the outer, lateral parts of both the medial and lateral menisci, the proportion of all samples identified as radial COL was 7.56 +/- 0.28%. The corresponding figure for areas near the inner, medial edges of the menisci was 17.80 +/- 0.80%. However, no relationship was demonstrable between age and sex and meniscal radial fibre optical density, and there was no difference between the proportion of radial fibres in the anterior, middle or posterior regions.     

Immunoelectron microscopic localization of collagens type I, V, VI and of procollagen type III in human periodontal ligament and cementum

We examined the ultrastructural localization of collagens Type I, V, VI and of procollagen Type III in decalcified and prefixed specimens of the periodontal ligament and cementum, by immunoelectron microscopy using ultra-thin cryostat sections. Immunostaining for collagen Type I was pronounced on the major cross-striated fibrils entering cementum and in cementum proper, whereas staining for procollagen Type III was almost exclusively observed on the major fibrils in the periodontal ligament situated more remote from cementum. Reactivity for collagen Type V was limited to aggregated, unbanded filamentous material of about 12 nm diameter that was found mainly in larger spaces between bundles of cross-striated collagen fibrils and occasionally on single microfibrils that apparently originated from the ends of the major collagen fibrils, which may support the concept of this collagen as a component of core fibrils. Collagen Type VI was present as microfilaments appearing to interconnect single cross-striated fibrils. In the densely packed fibril bundles of the periodontal ligament, no collagen type VI was detected. Neither Type V or Type VI collagen was observed in cementum.     

Extracellular matrix in development of the intervertebral disc.

Intervertebral discs allow bending and twisting of the spine whilst resisting compression from gravity and muscle action, and are composite structures of the peripheral annulus fibrosus enclosing the nucleus pulposus. Their development is complex, involving several different connective tissue types, yet little is known of the developing extracellular matrix (ECM). We report the ECM composition of foetal rat discs from their first appearance to birth. The earliest collagen detected was type III, which was subsequently replaced by type II in the cartilaginous inner annulus and joined by type I in the fibrous outer annulus. Type IV collagen appeared in outer annulus, associated with myofibroblast-like cells of the orienting collagenous lamellae. Laminin and fibronectin co-distributed here in later stages, although overall they had a wider distribution. Aggrecan occurred in early nucleus pulposus and then appeared in the inner annulus, in association with cartilage differentiation. Versican appeared later in the inner annulus, and also in the dorsal region of the outer annulus. Comparisons of glycosaminoglycan and proteoglycan label allowed extrapolations to be made as to likely glycosaminoglycan components of the large proteoglycans, and of other proteoglycans that may be present - thus differential distribution of aggrecan and keratan sulfate label suggested the presence of fibromodulin and/or lumican. Functionally aggrecan would confer compression resistance to cartilaginous structures. Versican may also contribute, but along with the small proteoglycans is likely to be associated with various stages of control of cell differentiation, tissue morphogenesis and collagen fibre formation in the assembly of the annulus fibrosus.     

Meniscus maturation in the swine model: changes occurring along with anterior to posterior and medial to lateral aspect during growth

The meniscus plays important roles in knee function and mechanics and is characterized by a heterogeneous matrix composition. The changes in meniscus vascularization observed during growth suggest that the tissue‐specific composition may be the result of a maturation process. This study has the aim to characterize the structural and biochemical variations that occur in the swine meniscus with age. To this purpose, menisci were collected from young and adult pigs and divided into different zones. In study 1, both lateral and medial menisci were divided into the anterior horn, the body and the posterior horn for the evaluation of glycosaminoglycans (GAGs), collagen 1 and 2 content. In study 2, the menisci were sectioned into the inner, the intermediate and the outer zones to determine the variations in the cell phenotype along with the inner–outer direction, through gene expression analysis. According to the results, the swine meniscus is characterized by an increasing enrichment in the cartilaginous component with age, with an increasing deposition in the anterior horn (GAGs and collagen 2; P < 0.01 both); moreover, this cartilaginous matrix strongly increases in the inner avascular and intermediate zone, as a consequence of a specific differentiation of meniscal cells towards a cartilaginous phenotype (collagen 2, P < 0.01). The obtained data add new information on the changes that accompany meniscus maturation, suggesting a specific response of meniscal cells to the regional mechanical stimuli in the knee joint.     

Confocal microscopy demonstrates association of LTBP-2 in fibrillin-1 microfibrils and colocalisation with perlecan in the disc cell pericellular matrix

Comparative immunolocalisations of latent transforming growth factor-beta-1 binding protein (LTBP)-2, fibrillin-1, versican and perlecan were undertaken in foetal human and wild type C57BL/6 mouse and Hspg2 exon 3 null HS deficient mouse intervertebral discs (IVDs). LTBP-2 was a prominent pericellular component of annular fibrochondrocytes in the posterior annulus fibrosus (AF), interstitial matrix adjacent to nucleus pulposus (NP) cells and to fibrillar and cell associated material in the anterior AF of the human foetal IVD and also displayed a pericellular localisation pattern in murine IVDs. Perlecan and LTBP-2 displayed strong pericellular colocalisation patterns in the posterior AF and to fibrillar material in the outer anterior AF in the foetal human IVD. Versican was a prominent fibril-associated component in the posterior and anterior AF, localised in close proximity to fibrillin-1 in fibrillar arrangements in the cartilaginous vertebral rudiments around paraspinal blood vessels, to major collagen fibre bundles in the anterior and posterior AF and shorter fibres in the NP. Fibrillin-1 was prominent in the outer anterior AF of the human foetal IVD and in fibres extending from the AF into the cartilaginous vertebral rudiments. LTBP-2 was prominently associated with annular fibrils containing fibrillin-1, versican was localised in close proximity to these but not specifically with LTBP-2. The similar deposition levels of LTBP-2 observed in the AF of the Hspg2 exon 3 null and wild type murine IVDs indicated that perlecan HS was not essential for LTBP-2 deposition but colocalisation of LTBP-2 with perlecan in the foetal human IVD was consistent with HS mediated interactions which have already been demonstrated in-vitro.     

Histologic, morphometric, and immunocytochemical analysis of myometrial development in rats and mice: I. Normal development

Myometrial development from the prenatal to adult period was examined in rats and mice 1) by histologic and immunocytochemical methods with anti-actin, -vimentin, and -laminin to assess cytodifferentiation of smooth muscle and fibroblastic cells; and 2) by morphometric procedures to assess quantitatively the expression of cellular orientation in the emerging inner circular myometrial layer. Uterine mesenchymal cells initially were uniformly vimentin-positive, undifferentiated, and randomly oriented during the late fetal period. By the early neonatal period, three mesenchymal layers became recognizable histologically, the middle one of which (prospective circular myometrium) developed distinct circular orientation and differentiated into a layer composed of actin-positive smooth muscle cells. The cells of the inner mesenchymal layer initially exhibited radial orientation. By 10 days postpartum, the outer longitudinal mesenchymal layer differentiated into bundles of smooth muscle cells representing the longitudinal myometrium. The inner mesenchymal layer remained vimentin-positive and differentiated into the randomly ordered endometrial stroma. The cells of the middle and outer mesenchymal layers that were destined to form myometrium initially expressed vimentin throughout and then coexpressed vimentin and actin, but with time vimentin staining disappeared in the maturing smooth muscle cells as they expressed actin.     

Immunoelectronmicroscopic localization of extracellular matrix components produced by bovine corneal endothelial cells in vitro

Bovine corneal endothelial cells deposit an extracellular matrix in short-term cultures, which contains various morphologically distinct structures when analysed by electron microscopy after negative staining. Amongst these were long-spacing fibers with a 150 nm periodicity, which appeared also to be assembled into more complex hexagonal lattices. Another structure was fine filaments, 10-40 nm in diameter, which occasionally exhibited 67 nm periodic cross-striation. Non-striated 10-20 nm filaments sometimes formed radially oriented bundles arranged in networks and fuzzy granular material was associated with the filaments in the bundles. Often, these bundles extended into solitary filaments, 10-20 nm in diameter, with a smooth surface. In addition, amorphous patches were seen, which contained dense aggregates of fibrillar and granular material. In longer-term cultures, some of the structures coalesced to form large fibrillar bundles. By using specific antibodies to various extracellular matrix components and immunolabeling with gold some of these structures could be identified as to their protein composition. Whereas fibronectin antibodies labeled a variety of structures--fine filaments with granular materials, radially oriented bundles, patchy amorphous aggregates and small granular material scattered throughout the background--type III collagen antibody predominantly labeled filaments with periodic banding (10-40 nm in diameter). A small amount of type III specific labeling was also observed over the networks of radially oriented fibrils and fine filaments associated with granular material. Type IV collagen and laminin antibodies localized in areas of the patchy amorphous aggregates. Type VI collagen antibodies, on the other hand, labeled fine filaments and the gold particles showed a pattern of 100 nm periodicity. Many of the fine 10-20 nm filaments exhibited a tubular appearance on cross-section, but they were not reactive with any of the antibodies used. Also negative were the long-spacing fibers and assemblies--including hexagonal lattices--containing this structural element.     

Structure of the periodontal ligament during tooth eruption in the dog: descriptive aspects

Serially stained uncalcified sections of young dog mandibles were examined to study the structure of the periodontal ligament of the erupting first right molar. The periodontal ligament around tooth crown presents three zones. The first, near the dental follicle, is a tick layer of parallel collagen bundles with numerous flattened fibroblasts. The second, intermediate, contains a blood vessels network, particularly veins and capillaries. The third, outer, is occupied by a continuous layer of osteoclasts and osteoblasts. Also the periodontal ligament around the tooth presents three layers, the outer and the intermediate rich of cells more than the inner. Particularly, the outer layer shows numerous osteoblasts surrounding the developing trabeculae of the alveolar bone and the collagen fiber bundles of the periodontal ligament. These penetrate into the trabeculae and appear similar to the osteoid layer. These results indicate that the alveolar bone increases by ossification of the connective tissue of the periodontal ligament.     

Distribution of connective tissue proteins in chick muscle spindles as revealed by monoclonal antibodies: a unique distribution of brachionectin/tenascin

The distribution of chick muscle spindles of eight connective tissue proteins (collagen types I, IV, V, and VI, laminin, heparan sulfate, fibronectin, and brachionectin/tenascin) was examined by immunofluorescent histochemistry. Intrafusal fibers were surrounded by layers of collagen type VI and fibronectin, and by an external lamina containing collagen type IV, laminin, and heparan sulfate. Most of these layers displayed a different pattern of staining at the sensory region of the equator than at the polar region. The crescent-like sheath that caps each intrafusal fiber and sensory terminal at the equator was strongly positive for collagen type I and weakly positive for collagen type V. The outer spindle capsule contained laminin, heparan sulfate, collagen types IV and VI, brachionectin/tenascin, fibronectin, and to a lesser degree also collagen types I and V. Brachionectin/tenascin had the narrowest distribution of any of the connective tissue macromolecules studied. It was found only in the outer capsule and in the coverings of blood vessels and nerves associated with the outer capsule.     

Morphology of lymphoid organs in a cichlid teleost, Tilapia mossambica (Peters).

In Tilapia mossambica organized lymphoid tissues are present in the thymus, head-kidney and spleen, whereas they are lacking in pericardial tissue, liver, mesonephros, intestine and rectum. No lymphoid tissue was observed in the chondrocranium and cartilaginous viscerocranium of young adults. The thymus in Tilapia is encapsulated by thin strands of collagen fibers and consists of outer, middle and inner zones. While middle and inner zones are comparable to the thymic cortex and medulla of higher vertebrates, the homology of the outer zone is not clear. At the anterior end of the thymus, a loose aggregation of lymphocytes without a definite boundary has been observed. The head-kidney is characterized by the presence of lymphoid follicles, a subcapsular sinus, a hilus-like area and lymphatic vessels. The spleen is grossly divisible into white pulp and red pulp; the white pulp contains only a reticular area without definite lymphoid centers and the latter contains predominantly erythrocytes. Morphological changes in the lymphoid organs associated with immune response have been discussed.     

Histochemistry defines a proteoglycan-rich layer in bovine flexor tendon subjected to bending

Mid-substance fibrocartilage develops in bovine deep flexor tendon at the point where the tendon wraps under sesamoid bones of the foot and receives transverse compressive loading during locomotion. Fibrocartilage extends several millimeters into the tendon at this location and the proteoglycan-rich tissue stains intensely with Alcian blue. Using histochemical techniques we demonstrate the presence of aggrecan, type VI collagen, and hyaluronic acid in the extracellular matrix of this region of tendon. Biglycan staining was localized to the cells, however. Adjacent to the fibrocartilage, at the outer curvature of the tendon as it bends, the tissue resembles typical tensile tendon with dense bundles of linearly arranged collagen. Longitudinal sections revealed discrete layers of Alcian blue-stained material between the collagen bundles. We demonstrate that these layers of loose matrix also contain aggrecan, type VI collagen, and hyaluronic acid. However, the dense collagen bundles of this region are negative for these components. Transverse sections of tendon in the area adjacent to fibrocartilage show a distinct Alcian blue-stained structure surrounding vascular elements at the point where several fiber bundles come together. This is concluded to be the same structure as the Alcian blue-stained layers seen in longitudinal sections. These observations suggest that proteoglycan-rich matrices in tendon subjected to mechanical loading other than pure tension may serve multiple roles. Such matrices can not only provide compressive stiffness and separate and lubricate collagen bundles that move relative to each other, but may also protect the integrity of vasculature in tendon subjected to bending and shear.     

Immunohistochemical distribution of collagens types IV, V, and VI and of pro-collagens types I and III in human alveolar bone and dentine

The aim of the present study was to characterize the composition of the organic matrix in alveolar jaw bone and dentine using antibodies against pro-collagens Types I and III and collagens Types IV, V, and VI. After demineralization of oral hard tissues in 0.2 N HCl, antigenicity was well preserved and the distribution of the pro-collagens and collagens could be demonstrated. Staining for pro-collagen Type I was prominent around osteoblasts and in pre-dentine, indicating active de novo synthesis of Type I pro-collagen. Pro-collagen Type I was ubiquitous but was less abundant in bone and dentine, whereas pro-collagen Type III was seen only in areas of bone remodeling, in peritubular spaces, and in pre-dentine. Type IV collagen was limited to the basement membranes of vessels in osteons and bone marrow. Type V collagen was detected neither in pre-dentine nor in bone. In contrast, Type VI collagen was found in dentine and bone, showing a faint but homogeneous staining which, similarly to pro-collagen Type III, was pronounced around osteoblasts and in pre-dentine, areas of active bone and dentine formation. This study showed that the organic matrix of dentine and bone contains Type VI as well as Type I collagen. Pro-collagen Type III (and to a lesser extent collagen Type VI) is transiently produced during new formation and remodeling of oral hard tissues, and disappears once the matrix calcifies. Type I pro-collagen qualifies as a general marker protein for increased osteoblastic activity. We conclude that immunostaining for the different collagen/pro-collagen types can be used to assess normal or abnormal stages of bone/dentine formation.     

Immunohistochemical study of basement membrane reconstruction by an epidermis-dermis recombination experiment using cultured chick embryonic skin: induction of tenascin.

The production of extracellular matrix components such as laminin, Type IV collagen, fibronectin, and tenascin during the formation of basement membrane in cultured epidermis-dermis recombinant skin of 13-day-old chick embryo was analyzed immunohistochemically. The epidermis and dermis were separated from each other by treatment with EDTA and/or dispase. The basal lamina of the basement membrane was thus removed from both epidermis and dermis. The isolated epidermis was overlaid onto the isolated dermis, i.e., recombined, and then cultured for 1-7 days in a chemically defined medium (BGJb) on a Millipore filter. Immunofluorescence labeling was used for light microscopy and HRP or colloidal gold labeling for electron microscopy. In specimens from 2-day cultures, positive sites of anti-laminin and anti-fibronectin reaction were observed light microscopically as patches which, at the electron microscopic level, corresponded to fragments of the basal lamina located immediately beneath and in the vicinity of the attachment plaques of the hemidesmosomes. The staining pattern became continuous 7 days after recombination. Fluorescence labeling of laminin and fibronectin appeared somewhat earlier than that of Type IV collagen and tenascin. All of the four components were found localized primarily in the basal lamina. Furthermore, fibronectin and tenascin were also distributed in the extracellular matrix of the dermis. The expression of tenascin, which does not exist in the basement membrane of 13-day-old intact embryonic skin, was induced in vitro. These results suggest that hemidesmosomes may play an important role in the reconstruction of the basement membrane and that various components of the basement membrane appeared at different times during the reconstruction.     

The structure, location, and function of perlecan, a prominent pericellular proteoglycan of fetal, postnatal, and mature hyaline cartilages

The aim of this study was to immunolocalize perlecan in human fetal, postnatal, and mature hyaline cartilages and to determine information on the structure and function of chondrocyte perlecan. Perlecan is a prominent component of human fetal (12-14 week) finger, toe, knee, and elbow cartilages; it was localized diffusely in the interterritorial extracellular matrix, densely in the pericellular matrix around chondrocytes, and to small blood vessels in the joint capsules and perichondrium. Aggrecan had a more intense distribution in the marginal regions of the joint rudiments and in para-articular structures. Perlecan also had a strong pericellular localization pattern in postnatal (2-7 month) and mature (55-64 year) femoral cartilages, whereas aggrecan had a prominent extracellular matrix distribution in these tissues. Western blotting identified multiple perlecan core protein species in extracts of the postnatal and mature cartilages, some of which were substituted with heparan sulfate and/or chondroitin sulfate and some were devoid of glycosaminoglycan substitution. Some perlecan core proteins were smaller than intact perlecan, suggesting that proteolytic processing or alternative splicing had occurred. Surface plasmon resonance and quartz crystal microbalance with dissipation experiments demonstrated that chondrocyte perlecan bound fibroblast growth factor (FGF)-1 and -9 less efficiently than endothelial cell perlecan. The latter perlecan supported the proliferation of Baf-32 cells transfected with FGFR3c equally well with FGF-1 and -9, whereas chondrocyte perlecan only supported Baf-32 cell proliferation with FGF-9. The function of perlecan therefore may not be universal but may vary with its cellular origin and presumably its structure.     

Human bone contains type III collagen, type VI collagen, and fibrillin: type III collagen is present on specific fibers that may mediate attachment of tendons, ligaments, and periosteum to calcified bone cortex

We evaluated the distribution of Type III collagen, Type VI collagen, and fibrillin in human bone, using monoclonal antibodies (MAb) of proven specificity. All three molecules are present in developing and remodeling bone. Type III collagen is present in discrete fiber bundles throughout the bone cortex but is concentrated at the Haversian canal surface and in the fibers at the bone-periosteal interface. The collagen fibrils in these bundles are of uniform diameter. Type III-containing collagen fibers are detected at all ages examined, from 30 fetal weeks to 80 years. Type VI collagen is present in fetal bone in discrete fibrils separate from Type III collagen, and becomes restricted to the margins of bone cells and the bone surface by 7 years. The distribution of fibrillin resembles that of Type III collagen in the fetus, but at 7 years is absent from the interior of the cortex except for the canaliculi and cement lines, and remains concentrated in discrete fibers at the bone surface.