Morphogenesis of cartilage canals: experimental approach in the rat tibia.

This paper studies the participation of vessels in the canal morphogenesis. The proximal chondroepiphysis of the left tibia of 44 five-day-old rats was exposed and the vessels of the intercondylar fossae, near the attachment of cruciate ligaments, were cauterized. In addition to the vascular lesion this assay induced a perichondral lesion. However, the canal appeared and joined to the secondary ossification center. 36 tibiae of 4-day-old rats were removed under sterile conditions and cultured in a serum-free chemically defined medium. The cultures were carried out for as long as 15 days. A canal lumen structure was found on the first days of culture, and grew in depth to the central region of the chondroepiphysis during the culture. The secondary ossification center was not found. The vessels and mesenchymal cells observed in the control canal were not found in the culture. We suggest that the presence of vessels, perivascular cells or perichondrium does not appear to be necessary in canal morphogenesis.     

Cartilage canal growth: experimental approach in the rat tibia.

This paper studies the influence of an antimitotic factor (puromycin) and a hormonal factor (thyroid hormone, TH) on canal growth. The tibiae of 15 six-day-old rats were cultured in a serum-free chemically defined medium. The cultures were carried out for as long as 6 days. Our results show: (1) canal growth is not dependent on perichondrium or chondro-epiphysis growth; (2) the canal is greater and has a complex pattern in a triiodothyronine (T3)-treated assay group; (3) round and multinucleated cells are more numerous in the T3-treated assay group than in the other groups. We hypothesize that the canal grows by a physiological phenomenon of programmed cell death and that it is stimulated by TH.     

Regulation of Endochondral Cartilage Growth in the Developing Avian Limb: Cooperative Involvement of Perichondrium and Periosteum

The perichondrium and periosteum have recently been suggested to be involved in the regulation of limb growth, serving as potential sources of signaling molecules that are involved in chondrocyte proliferation, maturation, and hypertrophy. Previously, we observed that removal of the perichondrium and periosteum from tibiotarsi in organ culture resulted in an overall increase in longitudinal cartilage growth, suggesting negative regulation originating from these tissues. To determine if the perichondrium and periosteum regulate growth through the production of diffusible factors, we have tested various conditioned media from these tissues for the ability to modify cartilage growth in tibiotarsal organ cultures from which these tissues have been removed. Both negative and positive regulatory activities were detected. Negative regulation was observed with conditioned medium from (1) cell cultures of the region bordering both the perichondrium and the periosteum, (2) co-cultures of perichondrial and periosteal cells, and (3) a mixture of conditioned media from perichondrial cell cultures and periosteal cell cultures. The requirement for regulatory factors from both the perichondrium and periosteum suggests a novel mechanism of regulation. Positive regulation was observed with conditioned media from several cell types, with the most potent activity being from articular perichondrial cells and hypertrophic chondrocytes.     

Distinguishing the contributions of the perichondrium, cartilage, and vascular endothelium to skeletal development

During the initiation of endochondral ossification three events occur that are inextricably linked in time and space: chondrocytes undergo terminal differentiation and cell death, the skeletal vascular endothelium invades the hypertrophic cartilage matrix, and osteoblasts differentiate and begin to deposit a bony matrix. These developmental programs implicate three tissues, the cartilage, the perichondrium, and the vascular endothelium. Due to their intimate associations, the interactions among these three tissues are exceedingly difficult to distinguish and elucidate. We developed an ex vivo system to unlink the processes initiating endochondral ossification and establish more precisely the cellular and molecular contributions of the three tissues involved. In this ex vivo system, the renal capsule of adult mice was used as a host environment to grow skeletal elements. We first used a genetic strategy to follow the fate of cells derived from the perichondrium and from the vasculature. We found that the perichondrium, but not the host vasculature, is the source of both trabecular and cortical osteoblasts. Endothelial cells residing within the perichondrium are the first cells to participate in the invasion of the hypertrophic cartilage matrix, followed by endothelial cells derived from the host environment. We then combined these lineage analyses with a series of tissue manipulations to address how the absence of the perichondrium or the vascular endothelium affected skeletal development. We show that although the perichondrium influences the rate of chondrocytes maturation and hypertrophy, it is not essential for chondrocytes to undergo late hypertrophy. The perichondrium is crucial for the proper invasion of blood vessels into the hypertrophic cartilage and both the perichondrium and the vasculature are essential for endochondral ossification. Collectively, these studies clarify further the contributions of the cartilage, perichondrium, and vascular endothelium to long bone development.     

Angiogenesis after administration of basic fibroblast growth factor induces proliferation and differentiation of mesenchymal stem cells in elastic perichondrium in an in vivo model: mini review of three sequential republication-abridged reports

To date, studies on mesenchymal tissue stem cells (MSCs) in the perichondrium have focused on in vitro analysis, and the dynamics of cartilage regeneration from the perichondrium in vivo remain largely unknown. We have attempted to apply cell and tissue engineering methodology for ear reconstruction using cultured chondrocytes. We hypothesized that by inducing angiogenesis with basic fibroblast growth factor (bFGF), MSCs or cartilage precursor cells would proliferate and differentiate into cartilage in vivo and that the regenerated cartilage would maintain its morphology over an extended period. As a result of a single administration of bFGF to the perichondrium, cartilage tissue formed and proliferated while maintaining its morphology for at least 3 months. By day 3 post bFGF treatment, inflammatory cells, primarily comprising mononuclear cells, migrated to the perichondrial region, and the proliferation of matrix metalloproteinase 1 positive cells peaked. During week 1, the perichondrium thickened and proliferation of vascular endothelial cells was noted, along with an increase in the number of CD44-positive and CD90-positive cartilage MSCs/progenitor cells. Neocartilage was formed after 2 weeks, and hypertrophied mature cartilage was formed and maintained after 3 months. Proliferation of the perichondrium and cartilage was bFGF concentration-dependent and was inhibited by neutralizing antibodies. Angiogenesis induction by bFGF was blocked by the administration of an angiogenesis inhibitor, preventing perichondrium proliferation and neocartilage formation. These results suggested that angiogenesis may be important for the induction and differentiation of MSCs/cartilage precursor cells in vivo, and that morphological changes, once occurring, are maintained.     

The dual role of perichondrium in cartilage wound healing

Cartilage structures from the head and neck possess a certain but limited capacity to heal after injury. This capacity is accredited to the perichondrium. In this study, the role of the inner (cambium) and the outer (fibrous) layers of the perichondrium in cartilage wound healing in vitro is investigated. For the first time, the possibility of selectively removing the outer perichondrium layer is presented. Using rabbit ears, three different conditions were created: cartilage explants with both perichondrium layers intact, cartilage explants with only the outer perichondrium layer dissected, and cartilage explants with both perichondrium layers removed. The explants were studied after 0, 3, 7, 14, and 21 days of in vitro culturing using histochemistry and immunohistochemistry for Ki-67, collagen type II, transforming growth factor beta 1 (TGFbeta1), and fibroblast growth factor 2 (FGF2). When both perichondrium layers were not disturbed, fibrous cells grew over the cut edges of the explants from day 3 of culture on. New cartilage formation was never observed in this condition. When only the outer perichondrium layer was dissected from the cartilage explants, new cartilage formation was observed around the whole explant at day 21. When both perichondrium layers were removed, no alterations were observed at the wound surfaces. The growth factors TGFbeta1 and FGF2 were expressed in the entire perichondrium immediately after explantation. The expression gradually decreased with time in culture. However, the expression of TGFbeta1 remained high in the outer perichondrium layer and the layer of cells growing over the explant. This indicates a role for TGFbeta1 in the enhancement of fibrous overgrowth during the cartilage wound-healing process. The results of this experimental in vitro study demonstrate the dual role of perichondrium in cartilage wound healing. On the one hand, the inner layer of the perichondrium, adjacent to the cartilage, provides (in time) cells for new cartilage formation. On the other hand, the outer layer rapidly produces fibrous overgrowth, preventing the good cartilage-to-cartilage connection necessary to restore the mechanical function of the structure.     

Interaction of Ihh and BMP/Noggin signaling during cartilage differentiation.

Bone morphogenetic proteins (BMPs) have been implicated in regulating multiple stages of bone development. Recently it has been shown that constitutive activation of the BMP receptor-IA blocks chondrocyte differentiation in a similar manner as misexpression of Indian hedgehog. In this paper we analyze the role of BMPs as possible mediators of Indian hedgehog signaling and use Noggin misexpression to gain insight into additional roles of BMPs during cartilage differentiation. We show by comparative analysis of BMP and Ihh expression domains that the borders of Indian hedgehog expression in the chondrocytes are reflected in changes of the expression level of several BMP genes in the adjacent perichondrium. We further demonstrate that misexpression of Indian hedgehog appears to directly upregulate BMP2 and BMP4 expression, independent of the differentiation state of the flanking chondrocytes. In contrast, changes in BMP5 and BMP7 expression in the perichondrium correspond to altered differentiation states of the flanking chondrocytes. In addition, Noggin and Chordin, which are both expressed in the developing cartilage elements, also change their expression pattern after Ihh misexpression. Finally, we use retroviral misexpression of Noggin, a potent antagonist of BMP signaling, to gain insight into additional roles of BMP signaling during cartilage differentiation. We find that BMP signaling is necessary for the growth and differentiation of the cartilage elements. In addition, this analysis revealed that the members of the BMP/Noggin signaling pathway are linked in a complex autoregulatory network.     

Parathyroid hormone-related peptide expression in the epiphyseal growth plate of the juvenile chicken: evidence for the origin of the parathyroid hormone-related peptide found in the epiphyseal growth plate

Parathyroid hormone-related peptide (PTHrP) has been shown to be essential for normal endochondral bone formation. Along with Indian hedgehog (Ihh), it forms a paracrine regulatory loop that governs the pace of chondrocyte differentiation. However, the source of PTHrP for this regulatory loop is not clear. While one hypothesis has suggested the periarticular perichondrium as the source of PTHrP for growth plate regulation, other data utilizing immunohistochemistry and in situ hybridization would indicate that growth plate chondrocytes themselves are the source of this peptide. The data described in this report supports the view that postnatal growth plate chondrocytes have the ability to synthesize this important regulatory peptide. Immunohistochemistry of tissue sections showed that PTHrP protein was evident throughout the chick epiphysis. PTHrP was seen in chondrocytes in the periarticular perichondrium, the perichondrium adjacent to the growth plate, the prehypertrophic zone of the growth plate, and the hypertrophic zone of the growth plate. However, cells in the proliferative zone, as well as some chondrocytes in the deeper layers of articular cartilage were predominantly negative for PTHrP. PTHrP was detected by Western blotting as a band of 16,400 Da in extracts from hypertrophic chondrocytes, but not from proliferative cells. RT-PCR detected PTHrP mRNA in both proliferative and hypertrophic growth plate chondrocytes, as well as in articular chondrocytes. PTH/PTHrP receptor mRNA was detected by Northern blotting in growth plate, but not articular chondrocytes. Thus, we conclude that most of the PTHrP present in the epiphyseal growth plate of the juvenile chick originates in the growth plate itself. Furthermore, the presence of large amounts of PTHrP protein in the hypertrophic zone supports the concept that PTHrP has other functions in addition to regulating chondrocyte differentiation.     

Developmentally regulated expression of the murine ortholog of the potassium channel KIR4.2 (KCNJ15)

The gene KIR4.2 (K(+) inwardly rectifying channel 4.2) has been recently identified in the Down syndrome Chromosome Region 1. We have cloned the mouse ortholog of KIR4.2 and characterized its expression pattern. In situ hybridization showed a restricted and developmentally regulated pattern of expression. The expression is starting at E12.5 and expands at E14.5 in different tissues and organs, which may be affected in Down syndrome: heart, thymus, thyroid gland, and perichondrium. At E17.5, additional epithelia (kidney, bladder, stomach, lung) expressed also strongly the gene.     

Relationship between the cartilage canal and the perichondrium in the rat proximal tibial epiphysis

One of the most widespread hypotheses for chondral canal morphogenesis suggests that the canal is an extension of the perichondrium. To study the possible relation between perichondrium and chondral canal morphology, the proximal epiphyses in the tibias of 42 rats were studied from birth to their 29th day. The study was divided into three periods: from birth to the 4th day before canal appearance; from the 5th day, the moment of canal appearance, until the appearance of the secondary ossification center of the epiphysis on the 9th day; the 3rd ran from this point on the 10th day until its full development. We have also divided the canal into three regions: entrance, neck and bottom. The central portion (lumen) and canal wall were analyzed in each region. Our results show the perichondrium to be a complex structure, composed of a series of cellular layers in a biphasic extracellular matrix (eosinophil and basophil). The canal walls are lined by a layer of elongated cells. In the lumen there are many different cell types: fibroblasts, histiocytes, multinuclear giant cells and multivacuolated cells. Our study of the canal, its walls and lumen show no morphological structure that is reminiscent of the perichondrium. These results suggest that the canal is not itself a continuation of the perichondrium.     

Expression of Regeneration-Associated Antigens in Normal and Retinoid-Treated Regenerating Limbs of Ambystoma mexicanum

The expression of two regeneration-associated antigens in the blastemas of normal and retinoid-treated regenerating limbs of axolotl ( Ambystoma mexicanum ) was examined.
One antigen, 55C12, which was similar to tenascin in expression pattern and molecular weight profile, was weakly expressed in the perichondrium and tendon of normal limbs. In the regenerating limbs, the amount of 55C12 antigen increased near the amputation site within 7 days and almost all cells of the blastema mesenchyme came to be positive to the antigen at 20 days, although those of epidermis and most stump tissues were negative. When the regenerating limbs were treated with Am80, a synthetic retinoid, which induced proximo-distal duplication, the expression of 55C12 antigen in the blastema became weak temporarily and was reactivated in the anterior region of the blastema. This expression pattern suggests that the duplicated limb is formed by the preferential growth of this 55C12-positive anterior blastema region.
The other antigen, 117C1, was faintly expressed in the epidermis, dermis, muscle, perichondrium and cartilage of normal limbs, and intensely expressed in the blastema mesenchyme and wound epidermis. The Am80 treatment, however, induced no changes in the expression pattern of 117C1.
These results suggest that these antigens may distinguish two different regions of the blastema in normal regeneration and retinoid-induced duplication.     

Hedgehog signalling is required for perichondral osteoblast differentiation in zebrafish

In tetrapod long bones, Hedgehog signalling is required for osteoblast differentiation in the perichondrium. In this work we analyse skeletogenesis in zebrafish larvae treated with the Hedgehog signalling inhibitor cyclopamine. We show that cyclopamine treatment leads to the loss of perichondral ossification of two bones in the head. We find that the Hedgehog co-receptors patched1 and patched2 are expressed in regions of the perichondrium that will form bone before the onset of ossification. We also show that cyclopamine treatment strongly reduces the expression of osteoblast markers in the perichondrium and that perichondral ossification is enhanced in patched1 mutant fish. This data suggests a conserved role for Hedgehog signalling in promoting perichondral osteoblast differentiation during vertebrate skeletal development. However, unlike what is seen during long bone development, we did not observe ectopic chondrocytes in the perichondrium when Hedgehog signalling is blocked. This result may point to subtle differences between the development of the skeleton in the skull and limb.     

A cellular lineage analysis of the chick limb bud

The chick limb bud has been used as a model system for studying pattern formation and tissue development for more than 50 years. However, the lineal relationships among the different cell types and the migrational boundaries of individual cells within the limb mesenchyme have not been explored. We have used a retroviral lineage analysis system to track the fate of single limb bud mesenchymal cells at different times in early limb development. We find that progenitor cells labeled at stage 19-22 can give rise to multiple cell types including clones containing cells of all five of the major lateral plate mesoderm-derived tissues (cartilage, perichondrium, tendon, muscle connective tissue, and dermis). There is a bias, however, such that clones are more likely to contain the cell types of spatially adjacent tissues such as cartilage/perichondrium and tendon/muscle connective tissue. It has been recently proposed that distinct proximodistal segments are established early in limb development; however our analysis suggests that there is not a strict barrier to cellular migration along the proximodistal axis in the early stage 19-22 limb buds. Finally, our data indicate the presence of a dorsal/ventral boundary established by stage 16 that is inhibitory to cellular mixing. This boundary is demarcated by the expression of the LIM-homeodomain factor lmx1b.     

Ultrastructure of calcified cartilage in the endoskeletal tesserae of sharks

The tesserate pattern of endoskeletal calcification has been investigated in jaws, gill arches, vertebral arches and fins of the sharks Carcharhinus menisorrah, Triaenodon obesus and Negaprion brevirostris by techniques of light and electron microscopy. Individual tesserae develop peripherally at the boundary between cartilage and perichondrium. An inner zone, the body, is composed of calcified cartilage containing viable chondrocytes separated by basophilic contour lines which have been called Liesegang waves or rings. The outer zone of tesserae, the cap, is composed of calcified tissue which appears to be produced by perichondrial fibroblasts more directly, i.e., without first differentiating as chondroblasts. Furthermore, the cap zone is penetrated by acidophilic Sharpey fibers of collagen. It is suggested that scleroblasts of the cap zone could be classified as osteoblasts. If so, the cap could be considered a thin veneer of bone atop the calcified cartilage of the body of a tessera. By scanning electron microscopy it was observed that outer and inner surfaces of tesserae differ in appearance. Calcospherites and hydroxyapatite crystals similar to those commonly seen on the surface of bone are present on the outer surface of the tessera adjacent to the perichondrium. On the inner surface adjoining hyaline cartilage, however, calcospherites of variable size are the predominant surface feature. Transmission electron microscopy shows calcification in close association with coarse collagen fibrils on the outer side of a tessera, but such fibrils are absent from the cartilaginous matrix along the under side of tesserae. Calcified cartilage as a tissue type in the endoskeleton of sharks is a primitive vertebrate characteristic. Calcification in the tesserate pattern occurring in modern Chondrichthyes may be derived from an ancestral pattern of a continuous bed of calcified cartilage underlying a layer of perichondral bone, as theorized by Ørvig (1951); or the tesserate pattern in these fish may itself be primitive.     

Critical roles of the TGF-β type I receptor ALK5 in perichondrial formation and function, cartilage integrity, and osteoblast differentiation during growth plate development

TGF-β has been implicated in the proliferation and differentiation of chondrocytes and osteoblasts. However, the in vivo function of TGF-β in skeletal development is unclear. In this study, we investigated the role of TGF-β signaling in growth plate development by creating mice with a conditional knockout of the TGF-β type I receptor ALK5 (ALK5^CKO) in skeletal progenitor cells using Dermo1-Cre mice. ALK5^CKO mice had short and wide long bones, reduced bone collars, and trabecular bones. In ALK5^CKO growth plates, chondrocytes proliferated and differentiated, but ectopic cartilaginous tissues protruded into the perichondrium. In normal growth plates, ALK5 protein was strongly expressed in perichondrial progenitor cells for osteoblasts, and in a thin chondrocyte layer located adjacent to the perichondrium in the peripheral cartilage. ALK5^CKO growth plates had an abnormally thin perichondrial cell layer and reduced proliferation and differentiation of osteoblasts. These defects in the perichondrium likely caused the short bones and ectopic cartilaginous protrusions. Using tamoxifen-inducible Cre-ER™-mediated ALK5-deficient primary calvarial cell cultures, we found that TGF-β signaling promoted osteoprogenitor proliferation, early differentiation, and commitment to the osteoblastic lineage through the selective MAPKs and Smad2/3 pathways. These results demonstrate the important roles of TGF-β signaling in perichondrium formation and differentiation, as well as in growth plate integrity during skeletal development.     

The developmental patterns of the cartilaginous elements in vertebrate ontogeny]

Comparative embryological data presented in the paper support an idea that chondrification of the mesenchyme does not begin until the latter becomes condensated. Size and density of the skeletogenous rudiments are not the same in different vertebrates. As a rule, in animals with much of the mesenchyme (chondrichthyans, amniotes), the prochondral condensations contain more cells and have both greater mass and density. The distribution pattern of the mesenchyme is also significant for the future development of the cartilaginous elements which at the earlier stages grow largely by the recruitment of surrounding mesenchymal cells. Such kind of the growth mode is probably most similar to the cartilage fusion mode: both processed take place in the absence of the perichondrium. The non-skeletal dense structures influence on the development of the cartilaginous skeleton primarily by determining distribution pattern of the mesenchyme, particularly the condensation of skeletogenous cells. THe growing cartilages themselves can influence mechanically on the surrounding organs.     

Co-ordination of TGF-beta and FGF signaling pathways in bone organ cultures

Transforming growth factor-beta (TGF-beta) is known to regulate chondrocyte proliferation and hypertrophic differentiation in embryonic bone cultures by a perichondrium dependent mechanism. To begin to determine which factors in the perichondrium mediate the effects of TGF-beta, we studied the effect of Insulin-like Growth Factor-1 (IGF-I) and Fibroblast Growth Factors-2 and -18 (FGF2, FGF18) on metatarsal organ cultures. An increase in chondrocyte proliferation and hypertrophic differentiation was observed after treatment with IGF-I. A similar effect was seen after the perichondrium was stripped from the metatarsals suggesting IGF-I acts directly on the chondrocytes. Treatment with FGF-2 or FGF-18 resulted in a decrease in bone elongation as well as hypertrophic differentiation. Treatment also resulted in a decrease in BrdU incorporation into chondrocytes and an increase in BrdU incorporation in perichondrial cells, similar to what is seen after treatment with TGF-beta1. A similar effect was seen with FGF2 after the perichondrium was stripped suggesting that, unlike TGF-beta, FGF2 acts directly on chondrocytes to regulate proliferation and hypertrophic differentiation. To test the hypothesis that TGF-beta regulates IGF or FGF signaling, activation of the receptors was characterized after treatment with TGF-beta. Activation was measured as the level of tyrosine phosphorylation on the receptor. Treatment with TGF-beta for 24h did not alter the level of IGFR-I tyrosine phosphorylation. In contrast, treatment with TGF-beta resulted in and increase in tyrosine phosphorylation on FGFR3 without alterations in total FGFR3 levels. TGF-beta also stimulated expression of FGF18 mRNA in the cultures and the effects of TGF-beta on metatarsal development were blocked or partially blocked by pretreatment with FGF signaling inhibitors. The results suggest a model in which FGF through FGFR3 mediates some of the effects of TGF-beta on embryonic bone formation.     

Solute transport in growth plate cartilage: in vitro and in vivo

Bone elongation originates from cartilaginous discs (growth plates) at both ends of a growing bone. Here chondrocytes proliferate and subsequently enlarge (hypertrophy), laying down a matrix that serves as the scaffolding for subsequent bone matrix deposition. Because cartilage is generally avascular, all nutrients, oxygen, signaling molecules, and waste must be transported relatively long distances through the tissue for it to survive and function. Here we examine the transport properties of growth plate cartilage. Ex vivo, fluorescence photobleaching recovery methods are used in tissue explants. In vivo, multiphoton microscopy is used to image through an intact perichondrium and into the cartilage of anesthetized mice. Systemically introduced fluorescent tracers are monitored directly as they move from the vasculature into the cartilage. We demonstrate the existence of a relatively permissive region at the midplane of the growth plate, where chondrocytes transition from late proliferative to early hypertrophic stages and where paracrine communication is known to occur between chondrocytes and cells in the surrounding perichondrium. Transport in the living mouse is also significantly affected by fluid flow from the two chondro-osseus junctions, presumably resulting from a pressure difference between the bone vasculature and the cartilage.     

Reconstruction of a three-dimensional structure using cartilage regenerated from the perichondrium of rabbits

Human tissues such as those found in the ear, nose, eyelid, lip, and larynx have complicated and delicate three-dimensional structures, which are difficult to reconstruct and restore to normal function following damage by tumor, congenital disease, or trauma. We devised a new reconstructive technique for the lost tissues by using cartilage regenerated from the perichondrium. In 12 ears of 12 rabbits, the layer between the perichondrium and the cartilage was stripped off. The exposed cartilage was punched out in large amounts to resemble a flexible, honeycomb-like structure. Then, we sandwiched the rabbit ears with two thermoplastic plates, which maintained a structure of the anterior surface of the human ear for 8 weeks. Structural change was studied in all cases, and some parts of the remodeled tissue were studied pathologically. Out of 12 ears, 8 had a rigid structure with a shape like a human ear using regenerated cartilage from the perichondrium of rabbits, 2 were infected, and 2 had a decubitus ulcer on the conchal surface as a result of compression from the plate. This study suggests that the use of the cartilage regenerated from the perichondrium may lead to a successful treatment also in humans for a variety of three-dimensional structures that have been damaged.