Notochordal stimulation of in vitro somite chondrogenesis before and after enzymatic removal of perinotochordal materials

Notochord-gut failure of detachment and intestinal atresia

A spectrum of congenital anomalies have been described in an adriamycin-treated model with common features to the human pattern. Multiple intestinal atresias was part of this spectrum occurring in 25% of full-term experimental rat fetuses. The aim of this study was to examine the underlying developmental mechanism that results in intestinal atresia. Virgin timed-pregnant Sprague-Dawley rats were injected with Adriamycin i.p. at a dose of 2 mg/kg on days 6-9 of gestation. Embryos were removed on different gestational days during organogenesis and serial transverse histologic sections were examined and compared with control specimens. In experimental embryos, hindgut atresia was seen in day 12 embryos. Attachment of the intestine with the notochord was obvious observation resulting in abnormal position of the intestine. In some specimens the atretic intestine was splitting the dorsal aorta or even located behind the dorsal aorta. It is concluded that in the adriamycin-animal model, notochord-intestinal failure of detachment resulted in intestinal atresia during the beginning of organogenesis period. The possible underlying mechanisms are pinching of some endodermal cells as well as interference with normal intestinal circulation resulting in ischemic necrosis.

Sclerotome induction and differentiation

Inductive events in the development of the sclerotome and their possible underlying mechanisms were reviewed from the primary literature. A brief review of morphological and anatomical aspects of sclerotome development was given. The importance of the notochord and neural tube in sclerotome induction and somite chondrogenesis in vivo and in vitro was established. The functions and patterns of expression of different sclerotome markers were discussed. Shh and Noggin were discussed as two molecules produced by the neural tube and notochord that appear to maintain and initiate the sclerotome, respectively. While the abilities of the axial organs and Shh and Noggin to induce sclerotome marker expression in the somite was not disputed, the exact nature of these inductions was discussed with regard to possible effects on gene expression, effects on cell survival, and physical effects on the cells and it was argued that the fundamental nature of inductive events in the sclerotome is still unknown.

Notochordal cells interact with nucleus pulposus cells: regulation of proteoglycan synthesis

The disappearance of notochordal cells is correlated with early degenerative changes in the intervertebral disc. With increased disc degeneration there is a marked decrease in proteoglycan synthesis, resulting in loss of mechanical function. One possible mechanism for the decrease in proteoglycan synthesis is the loss of notochordal cells from the tissue. In this study, nucleus pulposus cells cocultured with notochordal cells exhibit an increase in proteoglycan synthesis. Interestingly, purified notochordal cells synthesize little proteoglycan as observed by [35S]sulfate incorporation into proteoglycans. The observed increase in proteoglycan synthesis does not appear to be dependent on cell-cell contact; rather it is the result of soluble factor(s) produced by notochordal cells. Finally, no difference in chondroitin sulfate chain size in notochordal-stimulated nucleus pulposus cells was observed which is consistent with an up-regulation in aggrecan core protein synthesis. These results are consistent with canine breeds where notochordal cells persist into adult age and disc degeneration is not observed. This suggests notochordal cells play a vital role in maintaining disc integrity.

Inhibition of chondrogenesis by integrin antibody in vitro

Integrins mediate cell attachment to a variety of extracellular matrix proteins. These interactions play an important role in morphogenesis and differentiation. The mediating functions of integrins during chondrogenesis in vitro were investigated by using mesenchymal cells from limb buds of day 12 mouse embryos. The cells were treated with anti-beta 1, -alpha 1, and -alpha 5 integrin antibodies (a) from day 1 to day 3 and (b) from day 3 to day 7 of cultivation. The total culture period was 7 days. The presence of exogenous anti-beta 1, but not -alpha 1 and -alpha 5 integrin antibodies, from day 1 to 3 completely inhibited the differentiation of blastemal cells to chondroblasts and the formation of cartilage matrix. On the other hand, the presence of exogenous anti-beta 1, -alpha 1, and -alpha 5 integrin antibodies from day 3 of cultivation onwards had no effect. Immunoblotting and immunomorphological findings in the cultures treated with anti-beta 1 antibody from day 1 to day 3 revealed a pattern of integrins and collagen composed of beta 1, alpha 1, alpha 5 beta 1 integrins and collagen type I. The cartilage-specific chondroitin sulfate proteoglycan (CSPG) could not be demonstrated in these cultures. The cultures treated later (day 3 to day 7) showed a pattern of beta 1, alpha 3, alpha 5 beta 1, and alpha v beta 3 integrins, collagen types I and II, and CSPG identical to that of the untreated controls. These findings indicate that beta 1-integrins play a crucial role in early cartilage differentiation and point to a possible important cell-matrix interaction in the induction of chondrogenesis.

Olfaction: transient expression of a putative odorant receptor in the avian notochord

In vertebrates, odors are thought to be detected by a multigene family encoding several hundreds of seven-transmembrane-domain G-protein-coupled receptors found in fish, rat, mouse, dog, and human. Recently, the putative odorant receptor (OR) gene family in the chicken has been characterized. Twelve members have been isolated and subdivided into six subfamilies. Herein, we have further characterized the chicken olfactory receptor subfamily 7 (COR7) composed of two highly related genes (named COR7a and COR7b) which are 98.5% identical. By in situ hybridization experiments, both COR7a and COR7b transcripts were detected in the olfactory epithelium from embryonic day 6 (E6) to the new born stage. Within the olfactory epithelium, the spatial distribution of COR7a and COR7b labeled cells was random. We also observed that every individual positive cell did not coexpress the COR7a and COR7b genes. Interestingly, the COR7b gene was found to be transiently expressed in the notochord from E2 to E6, whereas COR7a or any of the other known members of the COR gene family were not detected in this mesodermal tissue. These data suggest that, in addition to its potential role as an OR in the olfactory system, COR7b may also have a function in the notochord that is essential for the dorsoventral organization of the neural tube and of the somitic mesoderm. We also discuss the possible role(s) of a putative OR present in both the notochord and the sensory olfactory epithelium.

Preferential expression of alternatively spliced transcript of type II procollagen in the rabbit notochordal remnant and developing fibrocartilages

Expression patterns for the two isoforms of alpha 1(II) mRNA in various cartilaginous tissues were examined using newly isolated cDNA clones encoding rabbit type II procollagen amino- and carboxy-terminal propeptide regions. In nonchondrogenic nucleus pulposus, the switching of the mRNA from the long form to the short form was accompanied by disc maturation after birth. Interestingly, the short transcript was also expressed preferentially in human chordoma tissues as aberrant chordal vestiges. These results suggest an abundance of the differentiated chondrocyte-like phenotype in the heterogeneous notochordal remnants.

The dorsal neural tube organizes the dermamyotome and induces axial myocytes in the avian embryo

Somites, like all axial structures, display dorsoventral polarity. The dorsal portion of the somite forms the dermamyotome, which gives rise to the dermis and axial musculature, whereas the ventromedial somite disperses to generate the sclerotome, which later comprises the vertebrae and intervertebral discs. Although the neural tube and notochord are known to regulate some aspects of this dorsoventral pattern, the precise tissues that initially specify the dermamyotome, and later the myotome from it, have been controversial. Indeed, dorsal and ventral neural tube, notochord, ectoderm and neural crest cells have all been proposed to influence dermamyotome formation or to regulate myocyte differentiation. In this report we describe a series of experimental manipulations in the chick embryo to show that dermamyotome formation is regulated by interactions with the dorsal neural tube. First, we demonstrate that when a neural tube is rotated 180 degrees around its dorsoventral axis, a secondary dermamyotome is induced from what would normally have developed as sclerotome. Second, if we ablate the dorsal neural tube, dermamyotomes are absent in the majority of embryos. Third, if we graft pieces of dorsal neural tube into a ventral position between the notochord and ventral somite, a dermamyotome develops from the sclerotome that is proximate to the graft, and myocytes differentiate. In addition, we also show that myogenesis can be regulated by the dorsal neural tube because when pieces of dorsal neural tube and unsegmented paraxial mesoderm are combined in tissue culture, myocytes differentiate, whereas mesoderm cultures alone do not produce myocytes autonomously. In all of the experimental perturbations in vivo, the dorsal neural tube induced dorsal structures from the mesoderm in the presence of notochord and floorplate, which have been reported previously to induce sclerotome. Thus, we have demonstrated that in the context of the embryonic environment, a dorsalizing signal from the dorsal neural tube can compete with the diffusible ventralizing signal from the notochord. In contrast to dorsal neural tube, pieces of ventral neural tube, dorsal ectoderm or neural crest cells, all of which have been postulated to control dermamyotome formation or to induce myogenesis, either fail to do so or provoke only minimal inductive responses in any of our assays. However, complicating the issue, we find consistent with previous studies that following ablation of the entire neural tube, dermamyotome formation still proceeds adjacent to the dorsal ectoderm. Together these results suggest that, although dorsal ectoderm may be less potent than the dorsal neural tube in inducing dermamyotome, it does nonetheless possess some dermamyotomal-inducing activity. Based on our data and that of others, we propose a model for somite dorsoventral patterning in which competing diffusible signals from the dorsal neural tube and from the notochord/floorplate specify dermamyotome and sclerotome, respectively. In our model, the positioning of the dermamyotome dorsally is due to the absence or reduced levels of the notochord-derived ventralizing signals, as well as to the presence of dominant dorsalizing signals. These dorsal signals are possibly localized and amplified by binding to the basal lamina of the ectoderm, where they can signal the underlying somite, and may also be produced by the ectoderm as well.

Dextran sulfate promotes the rapid aggregation of porcine bone-marrow stromal cells

Despite the fact that cells of the mammalian stromal compartment of bone marrow have been shown to contain multipotential stem cells when studied in diffusion chambers it is notable that the same range of possible phenotypes (e.g., chondrocytic) has not been induced in freshly isolated marrow stromal cells in vitro. To investigate the possible role of glycoconjugates on phenotype expression, the effects of chondroitin sulfate, dermatan sulfate, dextran 500, and dextran sulfate on the cell morphology and differentiation of confluent porcine bone-marrow stromal-cell monolayers were studied. Of these glycosaminoglycan molecules only dextran sulfate induced confluent porcine bone-marrow stromal-cell monolayers to retract into tight, circular cell aggregates. Retraction began within 6 h, was complete after 3-5 days, and was dose dependent. Subsequent removal of dextran sulfate from the culture medium resulted in a return to a monolayer culture. Aggregated cells were essentially nonmitotic but dye exclusion indicated high cell viability. Dexamethasone, ascorbate, and beta-glycerophosphate produced no morphological change within 6 days when administered alone, but increased proliferation and aggregation in dextran sulfate-treated cultures. Immunocytochemistry of monolayer cultures revealed positive staining for type I but not type II collagen and addition of dexamethasone, ascorbate, and beta-glycerophosphate increased type I collagen deposition. In contrast, the centers of dextran sulfate-induced aggregates were positive for type II collagen, whereas type I collagen was only present at the periphery of the aggregates. Further addition of dexamethasone, ascorbate, and beta-glycerophosphate had little effect.(ABSTRACT TRUNCATED AT 250 WORDS)

Anin vitro model for chick embryonic notochords

A two step method to obtain mesenchymal free 3.5 day old chick embryonic notochordsin vitro is presented. 1.) Notochords are isolated by mechanical microdissection from the embryos below the head and above the leg-buds. 2.) The dissected notochords are trypsinized to eliminate contaminating mesenchymal cells, while the perinotochordal sheath (PNS) is retained. After isolation and trypsinization, notochords are cut in standard 8mm lengths, explantedin vitro and incubated at 37°C. Immediately before incubation and after 3 and 6 daysin vitro, notochords are fixed and stained to follow the morphological changes. The total DNA content of notochords is measured before and during maintenancein vitro to evaluate their metabolic activities. Results show that during thein vitro period, the isolated mesenchymal free notochordal fragments can conserve their characteristic architecture. The total DNA content measurements indicate proliferative activity and a high viability of the notochords in ourin vitro system. In the present study, an isolation andin vitro method is offered which might be an effective tool to study the metabolic activities of chick embryonic notochordsin vitro in comparison toin vivo behaviour, in order to study the underlying mechanism of notochord regression.

Notochord of chick embryos secretes short-form type IX collagen prior to the onset of vertebral chondrogenesis

The notochord of embryonic chicks produces type IX collagen, as well as type II collagen, prior to the onset of vertebral chondrogenesis. To address the question of whether the notochord secretes the "long-form" type IX collagen found in cartilage or the "short-form" type IX found in the cornea and vitreous humor, we examined immunoreactivity of the notochordal type IX collagen using two different monoclonal antibodies. The antibody 2C2 recognizes an epitope close to the carboxyl-terminus of the HMW fragment, which is present in both the long- and short-form type IX collagens, whereas another antibody 4D6 recognizes an epitope in the NC4 domain of the long-form type IX collagen, which is absent in the short-form type IX collagen. Therefore, the long-form is recognized by its reaction with both 2C2 and 4D6, while the short-form by its reaction with only 2C2 and no reaction with 4D6. Immunostaining of vertebral sections with 2C2 shows an identical distribution of staining with that for type II collagen, although the staining with 2C2 is less intense. The 2C2-reactive type IX collagen is found within the notochord at stage 14 and in the notochordal sheath at stage 20. Deposition of this collagen in the perinotochordal matrix increases with time and reaches a level comparable with that for type II at stage 31. In contrast, the 4D6-reactive type IX collagen is not found within the notochord nor in the notochordal sheath.(ABSTRACT TRUNCATED AT 250 WORDS)

Peanut agglutinin and chondroitin-6-sulfate are molecular markers for tissues that act as barriers to axon advance in the avian embryo

Axon outgrowth between the spinal cord and the hindlimb of the chick embryo is constrained by three tissues that border axon pathways. Growth cones turn to avoid the posterior sclerotome, perinotochordal mesenchyme, and pelvic girdle precursor during normal development and after experimental manipulation. We wanted to know if these functionally similar barriers to axon advance also share a common molecular composition. Since the posterior sclerotome differentially binds peanut agglutinin (PNA) and since PNA binding is also typical of prechondrogenic differentiation, we examined the pattern of expression of PNA binding sites and cartilage proteoglycan epitopes in relation to axon outgrowth. We found that all three barrier tissues preferentially express both PNA binding sites and chondroitin-6-sulfate (C-6-S) immunoreactivity at the time when growth cones avoid these tissues. Moreover, both epitopes are expressed in the roof plate of the spinal cord and in the early limb bud, two additional putative barriers to axon advance. In contrast, neither epitope is detected in peripheral axon pathways. In the somites, this dichotomous pattern of expression clearly preceded the invasion of the anterior sclerotome by either motor growth cones or neural crest cells. However, in the limb, barrier markers disappeared from presumptive axon pathways in concert with the invasion of axons. Since this coordinate pattern suggested that the absence of barrier markers in these axon pathways requires an interaction with growth cones, we analyzed the pattern of barrier marker expression following unilateral neural tube deletions. We found that PNA-negative axon pathways developed normally even in the virtual absence of axon outgrowth. We conclude that the absence of staining with carbohydrate-specific barrier markers is an independent characteristic of the cells that comprise axon pathways. These results identify two molecular markers that characterize known functional barriers to axon advance and suggest that barrier tissues may impose patterns on peripheral nerve outgrowth by virtue of their distinct molecular composition.

Distribution and expression of two interactive extracellular matrix proteins, cytotactin and cytotactin-binding proteoglycan, during development of Xenopus laevis. II. Metamorphosis

During metamorphosis of Xenopus laevis the extracellular matrix (ECM) proteins cytotactin and cytotactin-binding (CTB) proteoglycan and the cell adhesion molecules N-CAM and Ng-CAM, appear in highly restricted patterns determined by immunofluorescence histology. During limb development, cytotactin appears from the earliest stages in a meshwork of ECM fibrils associated with migrating mesenchymal cells forming the limb bud. Cytotactin also appears in the ECM between the apical limb ectoderm and mesenchyme. Later, both cytotactin and CTB proteoglycan appear co-localized within the central (prechondrogenic) limb mesenchyme. During chondrogenesis in these areas, cytotactin becomes restricted to perichondrium, while CTB proteoglycan is expressed throughout the cartilage matrix. The premyogenic mesenchyme surrounding the chondrogenic areas expressed N-CAM. Later, N-CAM is concentrated at the myogenic foci where cytotactin appears at sites of nerve/muscle contact and in tendons. Expression of these molecules in the blastemas of regenerating limbs was also studied, and during development of the central nervous system, stomach, and small intestine. Analysis of the expression patterns of cytotactin and CTB proteoglycan throughout development and metamorphosis reveals several consistent themes. The expression of these molecules is highly dynamic, often transient, and associated with key morphogenetic events. Cytotactin appears at multiple sites where cells undergo a transition from an undifferentiated, migratory phenotype to a differentiated phenotype. One or both molecules appear at several sites of border formation between disparate cell collectives, and CTB proteoglycan expression is associated with chondrogenesis.

Development of floor plate, neurons and axonal outgrowth pattern in the early spinal cord of the notochord-deficient chick embryo

The notochord is probably involved in the development of the neural tube. In this study, a fragment of caudal notochord was extirpated in ovo from chick embryos at 1.5 days of incubation. At 4.5 days a distinct notochord-deficient region at thoracolumbar level was found. Profound effects were seen, especially at the cranial site of this region. Somites were smaller than normal, or even not recognizable, and in some cases the myotomes were fused in the midline. The spinal cord appeared reduced in size and lacked a floor plate. The average amount of spinal cord neurons was 23% of the normal value, the cells being located circularly along the outer margin of the spinal cord, except for the roof plate. Axonal roots left the cord in the ventral midline only. Caudal to this site, neurons or floor plate cells were alternately present in the ventral spinal cord, and axonal roots left bilaterally. In a caudal direction, a normal morphology gradually reappeared. The possibility is discussed that reduction in spinal cord size and amount of neurons is a direct or indirect effect of the absence of the notochord, and that the sclerotome may be involved.(ABSTRACT TRUNCATED AT 250 WORDS)

Absence of neural crest cells from the region surrounding implanted notochords in situ

Avian neural crest cells migrating along the trunk ventral pathway are distributed throughout the rostral half of the sclerotome with the exception of a neural crest cell-free space of approximately 85 microns width surrounding the notochord. To determine if this neural crest cell-free space results from the notochord inhibiting neural crest cell migration, a length of quail notochord was implanted lateral to the neural tube along the neural crest ventral migratory pathway of 2-day chicken embryos. The subsequent distribution of neural crest cells was analyzed in embryos fixed 2 days after grafting. When the donor notochord was isolated using collagenase, neural crest cells avoided the ectopic notochord and were absent from the area immediately surrounding the implant (mean distance of 43 microns). The neural crest cell-free space was significantly less when notochords were isolated using trypsin or chondroitinase digestion and was completely eliminated when notochords were fixed with paraformaldehyde or methanol prior to implantation. The implanted notochords did not appear to affect the overall number of neural crest cells, and therefore were unlikely to exert this effect by altering their viability. These results suggest that the notochord produces a substance that can inhibit neural crest cell migration and that this substance is trypsin and chondroitinase labile.

Transient expression of a chondroitin sulfate-related epitope during cartilage histomorphogenesis in the axial skeleton of fetal rats

A monoclonal antibody (MC21C), raised in mouse in response to a mixture of bone proteins, was found to exhibit a unique reactivity toward native chondroitin sulfate chains. Indirect immunofluorescence and immunoperoxidase assays were performed on tissue sections at different stages of fetal rat development, in order to investigate the distribution of the MC21C epitope during cartilage morphogenesis and differentiation. This extracellular marker was present in the sclerotome and its distribution subsequently followed the segmentation pattern of the precartilaginous vertebral column. In addition, changes in the MC21C-immunostaining pattern strongly correlated with the initial growth of the vertebrae. In the axial skeleton (spinal column, basis cranii), the immunostaining by MC21C was maximum in precartilaginous condensations and then rapidly disappeared during the process of chondrification. Also, the perinotochordal matrix was intensely immunostained.

Inhibitory and stimulatory effects of limb ectoderm on in vitro chondrogenesis

Previous studies have indicated possible dual effects of the limb ectoderm in cartilage differentiation. On one hand, explants from early (stage 15) wing buds are dependent on contact with the limb ectoderm for cartilage differentiation (Gumpel-Pinot, J. Embryol. Exp. Morph. 59:157-173, 1980). On the other hand, limb ectoderm from stage 23/24 wing buds inhibits cartilage differentiation by cultured limb mesenchyme cells even without direct contact (Solursh et al., Dev. Biol. 86:471-482, 1981). In the present study, ectoderms from both stage 15/16 and stage 23/24 wings are cultured under the same conditions, and ectoderms from each source are shown to have two effects. Each stimulates chondrogenesis in stage 15 wing bud mesenchyme, and each inhibits chondrogenesis in older wing mesenchyme. The results suggest that the limb ectoderm has at least dual effects on cartilage differentiation, depending on the stage of the mesenchyme. One effect involves an early mesenchymal dependence on the ectoderm. This effect requires contact between the ectoderm and mesoderm (Gumpel-Pinot, J. Embryol. Exp. Morphol. 59:157-173, 1980) but also can be observed at a distance from the ectoderm. Later, the ectoderm can act without direct contact between the ectoderm and mesoderm to inhibit chondrogenesis over some distance.

Development of the notochord in human embryos: ultrastructural, histochemical, and immunohistochemical studies

In the present study of the notochord, the specimens were 54 externally normal human embryos ranging between Carnegie stages 13 and 23. The following staining procedures were used: periodic acid-Schiff (PAS), modified method of PAS, alcian blue, colloidal iron, and toluidine blue. Routine electron microscopic techniques were used. Immunoreactivity of the notochord to alpha-enolase was also examined. The notochord cells were undifferentiated in stage 13 with few intracellular organelles. The microfibrils and deposition of acid mucopolysaccharides appeared in the notochordal sheath in stage 14. The characteristic relation of mitochondria with rough endoplasmic reticulum was observed. Golgi complexes increased in the perinuclear region in stage 15. The layer of microfibrils in the notochordal sheath initially separated from the notochord in stage 16. Glycogen, mucoprotein, neutral mucopolysaccharides, and glycolipids began to increase in the mesenchymal cells around the notochord, starting at stage 16. Acid mucopolysaccharides increased in the notochordal sheath and in the matrix of the precartilage area around the notochord as this embryonic stage advanced. It was also revealed that the immunoreactivity of the notochord to alpha-enolase remained constant during the embryonic period. The results show that the notochord is transformed from an apparently undifferentiated organ into an organ with secretory activity in stage 14, producing microfibrils and depositing acid mucoplysaccharides in the notochordal sheath. The immunoreactivity of the notochord to alpha- and gamma-enolase isoenzymes and the development of the notochord are discussed. This study was undertaken to provide additional information on the development of tumors of notochordal origin.

Synthesis of glycosaminoglycans by islets of Langerhans

Incorporation of (35S)-sulfate into glycosaminoglycans (GAG) of toadfish islets of Langerhans in vitro was examined. (35S)-sulfated GAG were synthesized by a component of the microsomal fraction, and subsequently transferred to the secretion granules, mitochondria and nuclei. The predominant type of GAG synthesized was heparan sulfate, but chondroitin 4- and 6-sulfate and dermatan sulfate were also found.

Tenascin is associated with chondrogenic and osteogenic differentiation in vivo and promotes chondrogenesis in vitro

The tissue distribution of the extracellular matrix glycoprotein, tenascin, during cartilage and bone development in rodents has been investigated by immunohistochemistry. Tenascin was present in condensing mesenchyme of cartilage anlagen, but not in the surrounding mesenchyme. In fully differentiated cartilages, tenascin was only present in the perichondrium. In bones that form by endochondral ossification, tenascin reappeared around the osteogenic cells invading the cartilage model. Tenascin was also present in the condensing mesenchyme of developing bones that form by intramembranous ossification and later was present around the spicules of forming bone. Tenascin was absent from mature bone matrix but persisted on periosteal and endosteal surfaces. Immunofluorescent staining of wing bud cultures from chick embryos showed large amounts of tenascin in the forming cartilage nodules. Cultures grown on a substrate of tenascin produced more cartilage nodules than cultures grown on tissue culture plastic. Tenascin in the culture medium inhibited the attachment of wing bud cells to fibronectin-coated substrates. We propose that tenascin plays an important role in chondrogenesis by modulating fibronectin-cell interactions and causing cell rounding and condensation.

Proteoglycans synthesized by human chondrocytes cultivated in clusters

Proteoglycan metabolism was studied by a specific human cartilage proteoglycan radioimmunoassay in human chondrocytes cultivated in clusters. In this culture system, after a few days, previously dissociated chondrocytes were aggregated. They then synthesized a new cartilage matrix and were morphologically differentiated; they had a round shape and were situated inside small individual cavities (lacunae). The amounts of proteoglycan released into culture medium and present in chondrocyte clusters were maximal on the third to fifth day of culture; production decreased and stabilized from the 10th day to the end of culture. During the first days of culture, monomeric proteoglycans were present in large proportion; they gradually decreased between the sixth and 11th day of culture. These results suggest a modified synthesis of proteoglycan and hyaluronic acid during cultivation.

Regulation of chondrogenesis by heparan sulfate and structurally related glycosaminoglycans

To test the possible involvement of heparan sulfate proteoglycans in chondrogenesis, we have studied the effect of their major glycosaminoglycan (GAG) component, heparan sulfate, and other structurally related GAGs on chondrogenesis in micromass cultures of chick limb bud mesenchyme (Hamburger-Hamilton stages 23/24). Heparan sulfate and several of its analogs (heparin, dermatan sulfate, and dextran sulfate) were found to significantly stimulate cartilage nodule formation; in addition, heparan sulfate and heparin also promoted nodule growth. Chondroitin sulfate did not stimulate chondrogenesis. The activity of the GAGs was dependent on their dose, molecular size, charge, and chemical structure. Similar effects were also observed in micromass cultures derived from stage 25 embryonic wing-tip subridge mesoderm, an enriched population of chondroprogenitor cells. The time of action of the GAGs during culture suggested their involvement in post-cell aggregation events of chondrogenesis, such as the initial expression of the chondrocyte phenotype or the growth of cartilage nodules.

Changes in the types of collagen synthesized during chondrogenesis of the mouse otic capsule

We have investigated the temporal relationship between the morphological differentiation of the mouse otic capsule and the pattern of collagen synthesis by mouse otocyst-mesenchyme complexes labeled in vitro. In 10.5- to 12-day embryos the mesenchyme surrounding the otocyst was loosely organized except for a few lateroventral condensations; explants from these embryos synthesized only small amounts of collagen. Collagen synthesis by whole explants increased by more than 50% between 12 and 13 days concomitant with metachromatic staining of the lateral periotic mesenchyme. Cartilage specific type II collagen was the predominant collagen synthesized by these explants as confirmed by SDS-PAGE, densitometry, CNBr cleavage, and V8 protease digestion. This biochemical expression of the cartilage phenotype preceded morphologic recognition of otic capsular cartilage by almost 2 days. Type II collagen synthesis continued to increase and predominate through Day 16 of gestation by which time the otic labyrinth was surrounded by mature cartilage. The minor cartilage collagen chains, 1 alpha, 2 alpha, and 3 alpha, first appeared on different days of gestation. The 1 alpha, and 3 alpha chains were synthesized by explants from 11-day embryos while the 2 alpha chain appeared during Day 13, just before overt differentiation of mature cartilage. These results suggested that the 1 alpha, 2 alpha, and 3 alpha chains may not form heterotrimers containing all three chains and that synthesis of the 2 alpha chain may be associated with stabilization of the cartilaginous matrix. Comparison of these data with the patterns of collagen production by mutant, diseased, or experimentally manipulated inner ear tissues may provide insights into the molecular basis of chondrogenic tissue interactions.

Somite chondrogenesis in vitro: 1. Alterations in proteoglycan synthesis

During embryonic development, somites undergo chondrogenic differentiation when stimulated by notochord or spinal cord. The present study shows that, when cultured in suitable medium, explanted somites incorporated radioactive sulfate into cartilage-specific proteoglycans and the synthetic rate increased when notochord was included with somites. With increased culture time, explanted somites also synthesized proteoglycan monomers which were larger in size along with a larger proportion that were capable of interacting with exogenous hyaluronic acid. Interaction with notochord also resulted in increased synthesis of chondroitin 4-sulfate. Gel electrophoretic analysis showed that proteoglycans from unstimulated somites did not contain link protein (required for stable aggregate formation), even on day 9, while notochord-induced somites showed link protein as early as day 3, increasing 3-fold by day 9.

Biochemical specificity of Xenopus notochord

The biochemical composition and biosynthetic activity of Xenopus notochord were examined and compared with those of chick and mouse notochord. The notochords of all three species contain type-II collagen, and the notochords of Xenopus and chick synthesize a soluble glycoprotein with a molecular mass of 86 kilodaltons (kd). Mouse embryos were not tested for this molecule, because their notochords are too small to be dissected out. Most interestingly, Xenopus and chick notochords share a keratan-sulphate-containing proteoglycan which appears to be absent from mouse notochord. The presence or absence of keratan sulphate in the notochords of the different species reflects its presence or absence in cartilage. Since one role of the notochord in vivo is to stimulate chondrogenesis in the sclerotomes of the somites, this result provides support for the view that cells responding to the extracellular matrix produced by one tissue do so by increasing their production of the same matrix components.

Somite chondrogenesis: alterations in cyclic AMP levels and proteoglycan synthesis

Cyclic AMP (cAMP) levels have been shown to have a positive influence on chondrogenesis in limb buds and pelvic cartilage. In the present study the level of cAMP was measured during somite chondrogenesis in vitro and found to decrease from 1.38 pmol/micrograms DNA on day 0 to 0.9 pmol/micrograms DNA on day 6. Inclusion of notochord with somites caused a marked reduction, with levels decreasing from 1.41 pmol/micrograms DNA on day 0 to 0.36 pmol/micrograms DNA on day 6. Concurrently, the incorporation of radioactive sulfate into sulfated glycosaminoglycans increased from day 3 to day 6 by 38% in somite and 77% in somite-notochord explants. The aggregation of proteoglycans was analyzed by gel chromatography and found to increase with a corresponding decrease in cAMP levels. The results indicate that a decrease in cAMP levels may be necessary for chondrogenic expression in somites.

Notochordal development as influenced by the insecticide dicrotophos (Bidrin)

White Leghorn chicken embryos were treated at different ages with the insecticide dicrotophos to determine the time period of maximum effect upon notochordal development. Doses of insecticide ranging from 250 micrograms to 2.0 mg were injected into eggs at 8, 16, 24, 32, 40, 48, 72, or 96 hr of incubation and the eggs allowed to incubate for an additional 48 hr. Dicrotophos treatment caused dorsoventral and lateral folding of the notochord, with the cervical region being most severely affected. Although there was no apparent difference in dose responsiveness at any one age, there was an obvious age relationship. Notochordal responsiveness, expressed as both the number and severity of folds, was low among the 8- and 16-hr treated embryos, increased to a maximum in the 48-hr treatment group, and then declined among the older embryos. The time of maximum effect correlates closely with the time of sheath deposition and vacuolization of the notochord, but not to initial formation of the notochord from the mesoblast or later extracellular matrix production by sclerotome cells. It is proposed that dicrotophos interferes with some aspect of sheath formation. The pressure exerted by the vacuolization upon a structurally weakened sheath is thought to cause the observed folding.

Abnormalities of cells and extracellular matrix of T/T embryos

The dominant mutation T, (Brachyury), of the T/t-complex in the mouse causes severe disorganization in neural tube, notochord, and somites in homozygotes. The use of scanning electron microscopy to investigate the relationships of cells to one another and to the extracellular matrix in the three axial organs and in the head mesenchyme reveals that cells in all areas examined are abnormal in size, shape, and arrangement in T/T embryos. Cells of T/T head mesenchyme and somites are arrayed in flat sheets of broadened cells with fewer cytoplasmic processes than those of normal littermates. The notochord is discontinuous and its surface is exposed rather than covered by a dense matrix as in the normal. Likewise the sheath of the T/T neural tube is less dense than normal. Cell size and shape are very irregular whereas normal neural tube cells are all about the same size. Extracellular matrix in T/T embryos is greatly decreased in all areas.

Extracellular matrix and the maintenance of the differentiated state: proteoglycans synthesized by replated chondrocytes and nonchondrocytes

It has been previously shown that undifferentiated stage 23 to 24 chick limb bud mesenchymal cells can be maintained in culture under conditions which promote chondrogenesis. As the chondrocytes mature in vitro, their proteoglycan synthesis progresses through a specific and reproducible biosynthetic program. By the eighth day of culture, the chondrocytes are making proteoglycans that are similar to proteoglycans isolated from adult animal tissues. Relative to the Day 8 proteoglycans, the proteoglycans synthesized by chick limb bud chondrocytes earlier in culture have a smaller monomer size, longer chondroitin sulfate chains, shorter keratan sulfate chains, a higher ratio of chondroitin-6-sulfate to chondroitin-4-sulfate, and a decreased ability to interact with hyaluronic acid. We have reported a procedure to remove the cells from Day 8 cultures and strip away most, if not all, of the extracellular matrix. In addition, the chondrocytes can be separated from the 40-50% nonchondrocytic cells normally found in Day 8 cultures, and the two cell populations replated separately. This report describes the analysis of the proteoglycans synthesized by replated cells; this analysis demonstrates quantitative and qualitative differences between chondrocyte and nonchondrocyte proteoglycans. The overall rate of proteoglycan synthesis is fourfold higher and the rate of synthesis of high buoyant density proteoglycans 30-fold higher for replated chondrocytes relative to nonchondrocytes. Qualitatively, more newly synthesized nonchondrocyte proteoglycans partition at lower buoyant density on CsCl equilibrium density gradients than do chondrocyte proteoglycans. Nonchondrocyte proteoglycans are of two major classes: One has a monomer size slightly smaller than that of Day 8 chondrocyte proteoglycan, but has much longer glycosaminoglycan chains. The other is considerably smaller than Day 8 chondrocyte proteoglycans, but has glycosaminoglycans of slightly larger size. In contrast, replated chondrocytes synthesize, even as soon as 4.5 hr after replating, proteoglycans that are identical to Day 8 chondrocyte proteoglycan in monomer size, in glycosaminoglycan chain size, in aggregability, and in the ratio of 6-sulfated to 4-sulfated chondroitin. Since denuding mature Day 8 chondrocytes of their extracellular matrix does not cause them to recapitulate their developmentally regulated program for the biosynthesis of proteoglycans, it is concluded that the quality of mature chondrocyte proteoglycan is not altered by the absence of extracellular matrix.

Biosynthesis of proteoglycans in organ cultures of developing kidney mesenchyme

The biosynthesis of proteoglycans was studied in organ cultures of differentiating metanephric mesenchymes. When triggered by a contact-mediated inductive interaction, this tissue undergoes transition from a mesenchyme to an epithelium. In the present study, proteoglycans were extracted by guanidinium hydrochloride in the presence of protease inhibitors. We found that, as a response to induction, the differentiating mesenchyme begins to synthesize large size proteoglycans with an apparent molecular weight (MW) of 1 X 10(6) D. The major glycosaminoglycans detected were chondroitin sulfates. Heparan sulfate proteoglycans were also detected, constituting 20% of the proteoglycans. An inhibitor of glucosamine synthesis, 6-diazo-5-oxo-norleucine (DON) was found to inhibit glycosaminoglycan synthesis by approx. 60%, and the size of the proteoglycans was also diminished. Our studies suggest that the transition of the mesenchyme to epithelium is associated with initiation of synthesis of large size proteoglycans.

Inhibition of precartilaginous chick somites by oncogenic virus

Infection of embryonic chicken notochord-somite explants with Rous sarcoma virus inhibited the in vitro differentiation of somites into cartilage. Visual inspection of the explants revealed that viral infection reduced the size of cartilage nodule formation. Formation of the complex of sulfated proteoglycans with hyaluronic acid was inhibited by RSV infection, and sedimentation analysis of the sulfated proteoglycans showed that very little fast sedimenting proteoglycans were synthesized by RSV-infected explants. The infected explants primarily synthesize a slowly sedimenting sulfated proteoglycan which was chondroitinase resistant. These slow-sedimenting sulfated proteoglycans lack the ability to associate with hyaluronic acid and appear to be noncartilaginous. These effects of RSV are apparently due to the src gene of this virus since the mutant td108, which lacks part of the src gene, has no detectable influence on the chondrogenic differentiation of somite explants. Similarly, infection with RAV-2 as well as with uv-irradiated virus had no detectable effect. The inhibition of synthesis of fast sedimenting proteoglycans was observed at 41 degrees C with explants infected with tsNY68, suggesting that residual activity of transforming gene of this virus at the non-permissive temperature is sufficient for this inhibition in the explants.

The effect of prostaglandins on in vitro limb cartilage differentiation

A variety of studies indicate that a key event in limb chondrogenic differentiation is a cellular condensation process during which an intimate cell-cell interaction occurs that triggers cartilage differentiation by elevating cAMP levels. It has recently been demonstrated that when limb mesenchymal cells are subjected to high density monolayer culture under conditions conducive to chondrogenesis, they synthesize several prostaglandins, including PGE2 and prostacyclin, which are important local modulators of cAMP formation in a number of cells and tissues. In the present study, we demonstrate that exogenous PGE2 stimulates the in vitro chondrogenic differentiation of the subridge mesoderm of the embryonic chick limb bud. The stimulatory effect of PGE2 is greatly potentiated by the phosphodiesterase inhibitor, theophylline, suggesting its influence on chondrogenesis is mediated by its ability to increase cAMP levels. The stimulatory effect of PGE2 is dose-dependent and can be detected at a concentration as low as 10(-8)M. PGE1 is just as effective as PGE2 in stimulating in vitro chondrogenesis, whereas PGA1 and PGF1 alpha are less than half as effective. Thromboxane B2 has no effect on chondrogenesis. On the basis of our results, the possibility that endogenous prostaglandins might regulate limb cartilage differentiation by acting as local regulators of cAMP content is discussed.

An electron microscopic analysis of notochordal and mesenchymal cell abnormalities in embryos of Danforth's short-tail (Sd) mice

Abnormalities of notochordal cells and of mesenchymal cells in embryos of Danforth's short-tail (Sd) and C57BL mice were examined by means of electron microscopy and cytochemical staining at 11.0 and 11.5 days of gestation. In abnormal (Sd/+; Sd/Sd) embryos, the notochordal cells were markedly deficient in bundles of filaments and lacked surface protrusions, and the notochordal basal lamina was continuous; in contrast, notochordal cells of normal (+/+) littermates and of C57BL embryos contained numerous bundles of filaments and showed fingerlike surface protrusions and discontinuous basal laminae. The pathologic notochordal cells also lacked the accumulations of glycogen revealed in the normals by means of thiocarbohydrazide cytochemical staining at the electron microscopic level. The mesenchymal cells of abnormals also were deficient in filaments but did stain for glycogen, though less prominently than did normal mesenchymal cells.

The fine localization of acid phosphatase activity in the unvacuolated notochordal cells of the early chick embryo

The electron microscopical localization of acid phosphatase activity was investigated in ultra-thin and semi-thin sections of unvacuolated notochordal cells of chick embryos from stages 9 to 14 (as defined by Hamburger & Hamilton). At stage 9, many notochordal cells show a lightly positive reaction for acid phosphatase activity. Thereafter, the acid phosphatase-positive cells of the notochord increase in number and, at stage 14, the reaction products for the enzymes are distributed throughout almost all the cisternae of the nuclear envelope and a well-differentiated endoplasmic reticulum, the parallel cisternal and reticular parts of the Golgi complex, and various lysosomes in nearly all notochordal cells. In the cisternae of the nuclear envelope and endoplasmic reticulum, the acid phosphatase reaction products are in a fine granular form. In the outermost layer of the cisternal parts of the Golgi complex, faint lead deposits similar to those in the endoplasmic reticulum are found, but in other cisternal and reticular regions which may correspond to the GERL, considerable amounts of reaction products are present. Knob-like projections are also seen protruding from the reticular parts of the Golgi complex. These results suggest that, at least up to stage 14, the notochordal cells are actively synthesizing acid phosphatase which is directly transported from the endoplasmic reticulum to the Golgi complex. The enzyme may be accumulated by the Golgi complex from which primary lysosomes are formed. Furthermore, the pattern of the ultrastructural localization of acid phosphatase activity in embryonic notochordal cells of the chick differs from that of adult cells of other animals.

Intracellular and extracellular control of the differentiation of cartilage and bone

This paper provides an overview of one aspect of the differentiation of cartilage and bone, namely, the degree of control provided by the extracellular matrix and microenvironment. A brief review of the diagnostic features of cartilage and bone is followed by a discussion of stem cells, emphasizing how to identify them using cytochemical, ultrastructural or experimental procedures. The role of extracellular matrices in the initiation of differentiation is discussed with reference to the initiation of chondrogenesis in the vertebral skeleton of the embryonic chick and of osteogenesis in the mandibular skeletons of embryonic chick and mice. The role of extracellular matrices in the maintenance of the differentiated state is discussed with reference to the ability of chondrocytes to compensate for depletion of their extracellular matrices and to the maintenance of altered differentiated states in achondroplasia. Some emphasis is placed on the notion that skeletal cells can neither be considered nor studied in isolation. The epigenetic approach used in studies of growth and morphogenesis needs to be applied to studies on both the initiation and the maintenance of cytodifferentiation.

Analysis of perinotochordal materials. I. Studies on proteoglycans synthesis

Perinotochordal proteoglycans have been shown to influence somite chondrogenic differentiation. However, information concerning the composition of the proteoglycan molecules synthesized by the notochord, or the exact type of molecule necessary for the induction of somite chondrogenesis is not known. The results of the present study indicate that the proteoglycan extracted from the 8 day old notochord culture consists of predominantly small proteoglycans, while the large aggregates form less than 30% of the total. The chondroitin sulfate composition also shows a cartilage type of proteoglycan molecules synthesized by the notochord.

The role of epithelial collagen and proteoglycan in the initiation of osteogenesis by avian neural crest cells

Osteogenesis was inhibited when mandibular processes from 3 1/2-day-old embryos were cultured in BUdR, LACA, alpha, alpha'-Dipyridyl, 4-Methylumbelliferone, and 4-Methylumbelliferyl-beta-D-glucoside or beta-D-xyloside. Mandibular processes were then cultured in the test substances for 3 days, enzymatically separated into their epithelial and ectomesenchymal components, combined with mandibular components from untreated embros, and either organ-cultured or grafted to chorioallantoic membranes of host embryos. Osteogenesis was inhibited when treated epithelium, but not when treated ectomesenchyme, was present in the tissue recombinations. Analysis of the known action of these inhibitors indicates that proliferation, hydroxylation of collagen, and synthesis of proteoglycans by epithelial cells are all necessary components of this osteogenic epithelial-ectomesenchymal interaction.

Surface ultrastructure of the isolated avian notochord in vitro: the effect of the perinotochordal sheath

The perinotochordal sheath (PNS) is a "tube" of extracellular matrix (ECM) that surrounds the avian notochord beginning in the second day of development. Somites, like the notochord, derive from chordamesoblast but are encased by a less substantial perisomitic matrix (PSM). Initially both tissue types exhibit epithelioid characteristics. Somitic cells subsequently disperse, however, while notochordal histoarchitecture is maintained until much later. To test the possible shape-preserving role of the PNS, otochords were isolated from chick embryos by homogenization (which retains the sheath) or by trypsinization (which removes the sheath). Somites were similarly isolated. Tissues were cultured 12-72 hours and studied by LM, SEM and TEM. Mechanically isolated notochords are initially rigid with smooth surfaces. During the culture period a few cells grow outward from cut ends of the notochord, but its overall rod shape and intact PNS are maintained. In contrast, uncultured trypsinized notochords are flaccid, denuded cylinders with numerous cytoplasmic blebs. They adhere to the substratum within 12 hours of culture when a few cells break away from the central tissue rod, migrate laterally, and appear mesenchymal. This cellular dispersion is directional (perpendicular to the long notochordal axis) and continuous (up to 72 hours). At this time a flattened ovoid growth area is formed. Cultured somites form flat circular growth areas within 12 hours of culture irrespective of the isolation method. These data suggest that the maintenance of an epithelial configuration by notochords in vivo may be due in part to physical restraints of the PNS. It seems possible that notochordal secretions (manifested by the formation of a PNS) could result in its compartmentation and axial confinement while its unrestrained somitic relatives are free to disperse.