Somite chondrogenesis in vitro. Stimulation by exogenous extracellular matrix components

Heparinized collagen sutures for sustained delivery of PDGF-BB: Delivery profile and effects on tendon-derived cells In-Vitro

Suturing is the standard of repair for lacerated flexor tendons. Past studies focused on delivering growth factors to the repair site by incorporating growth factors to nylon sutures which are commonly used in the repair procedure. However, conjugation of growth factors to nylon or other synthetic sutures is not straightforward. Collagen holds promise as a suture material by way of providing chemical sites for conjugation of growth factors. On the other hand, collagen also needs to be reconstituted as a mechanically robust thread that can be sutured. In this study, we reconstituted collagen solutions as suturable collagen threads by using linear electrochemical compaction. Prolonged release of PDGF-BB (Platelet derived growth factor-BB) was achieved by covalent bonding of heparin to the collagen sutures. Tensile mechanical tests of collagen sutures before and after chemical modification indicated that the strength of sutures following chemical conjugation stages was not compromised. Strength of lacerated tendons sutured with epitendinous collagen sutures (11.2±0.7N) converged to that of the standard nylon suture (14.9±2.9N). Heparin conjugation of collagen sutures didn't affect viability and proliferation of tendon-derived cells and prolonged the PDGF-BB release up to 15days. Proliferation of cells seeded on PDGF-BB incorporated collagen sutures was about 50% greater than those seeded on plain collagen sutures. Collagen that is released to the media by the cells increased by 120% under the effects of PDGF-BB and collagen production by cells was detectable by histology as of day 21. Addition of PDGF-BB to collagen sutures resulted in a moderate decline in the expression of the tendon-associated markers scleraxis, collagen I, tenomodulin, and COMP; however, expression levels were still greater than the cells seeded on collagen gel. The data indicate that the effects of PDGF-BB on tendon-derived cells mainly occur through increased cell proliferation and that longer term studies are needed to confirm whether this proliferation is outweighs the moderate reduction in the expression of tendon-associated genes.

STATEMENT OF SIGNIFICANCE

A mechanically robust pure collagen suture was fabricated via linear electrocompaction and conjugated with heparin for prolonged delivery of PDFG-BB. Sustained delivery of the PDGF-BB improved the proliferation of tendon derived cells substantially at the expense of a moderate downregulation of tenogenic markers. The collagen threads were functionally applicable as epitendinous sutures when applied to chicken flexor tendons in vitro. Overall, electrocompacted collagen sutures holds potential to improve repair outcome in flexor tendon surgeries by improving cellularity and collagen production through delivery of the PDGF-BB. The bioinductive suture concept can be applied to deliver other growth factors for a wide-array of applications.

Isolation and characterization of a collagen-binding glycoprotein from chondrocyte membranes

A collagen-binding glycoprotein was isolated from purified chick chondrocyte surface membranes by affinity chromatography on type II collagen-Sepharose. The purified glycoprotein has an apparent mol. wt. of 31,000 and binds to native chick collagen types I, II, III, V and M. Although it contains 30% carbohydrates, the majority of which is fucose, it is hydrophobic and soluble only in detergents. The integral membrane protein character of the 31-K protein became apparent from its ability to insert into lecithin vesicles. Liposome-inserted 31-K protein binds 125I-labelled type II collagen in the presence of 0.5 M NaCl, while detergent-solubilized 31-K protein is dissociated from type II collagen by 0.05-0.1 M NaCl. Electron microscopic studies employing the rotary shadowing technique indicate that 31-K protein particles bind to the ends of collagen molecules. We propose that this glycoprotein serves as anchorage site for extracellular collagen to the chondrocyte membrane and thus may be involved in cell-matrix interactions in cartilage.

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.

Relationship between epithelial and connective tissues in the stomach of the frog Rana temporaria during metamorphosis: an ultrastructural study

In the course of metamorphosis of the stomach of Rana temporaria tadpoles there is a marked increase in the amount of active mesenchymal fibroblasts and extracellular matrix underlying the regenerating gastric epithelium. At the onset of metamorphosis, a thick PAS-positive basement membrane is developed around the epithelial component of the mucosa, formed by the apical, degenerating larval epithelium and the basal, regenerative epithelial cords. Under the electron microscope, a folded basement membrane is usually revealed under the apical degenerating epithelium while a compact basement membrane (up to 1-2 microns thick), forming both patches and more extensive areas, is frequently seen around the regenerative glandular cords. Cytoplasmic processes, extending from both the epithelial and mesenchymal fibroblastic cells, cross the basement membrane and make physical contact between the two cellular types. At mid-metamorphosis areas of thick PAS-positive basement membrane are still observed around the differentiating glandular outlines, before disappearing completely at late metamorphosis. The probable involvement of intertissue interactions between epithelium and connective elements in the morphogenesis, proliferation and differentiation of secondary, definitive frog stomach is discussed. Early contacts between epithelium and phagocytes, probably related to the invasion of epithelium by the phagocytic cells, have also been observed.

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.

Cellular reactions to bone-derived material

Demineralized bone has been used as an acceptable alternative to fresh autogenous bone grafting in a variety of clinical reconstructive procedures. With the recent expansion of regional and national tissue banks, more implants are being used in routine applications. Questions raised about the bioactivity of human demineralized bone may be resolved by development of relevant assays for screening a lot of banked tissue. Such a bioassay could be developed based on the effects of osteoinductive materials on cells in vitro. Various effects of culture with demineralized bone or its components have been reported for cell lines or embryonic, fetal, or neonatal rodent and chick tissues and cells. In this study, human dermal fibroblasts and a variety of other cell types expressed features of chondroblastic phenotype when cultured with demineralized bone powder.

The development of fibrocartilage in the rat intervertebral disc

The development of fibrocartilage in rat lumbar intervertebral discs has been correlated with an immunohistochemical analysis of the changing distribution of extracellular matrix components. Disc anlagen were first recognised by embryonic day 14 as segmental cell condensations. By E16, the notochord formed a series of bulges, each representing a future nucleus pulposus, and the annulus fibrosus had differentiated in the disc anlagen. The inner part of the annulus was composed of cartilage which linked that of adjacent vertebral bodies. The outer part was fibroblastic, with layers of parallel fibroblasts. The long axes of the cells in successive layers lay at an angle of approximately 90 degrees to each other. This criss-cross orientation of cells preceded the oriented deposition of collagen fibres to form the lamellae. Disc anlagen were immunolabelled weakly for types I and III collagen, chondroitin 6-sulphate and dermatan sulphate. Later tissue differentiation was marked by the appearance of type II collagen, chondroitin 4-sulphate and keratan sulphate in the inner annulus. These components also appeared in the outer annulus, but only in adult animals, and indicated metaplastic change in the lamellar fibroblasts. Fibrocartilage in the nucleus pulposus was only seen in old animals, and the origin of the tissue was less clear. However, the fibrocartilage cells appeared to be derived from the cartilage end plate and/or from the inner annulus. We conclude that fibrocartilage in the intervertebral disc is derived from several sources and that the radial distribution patterns of extracellular matrix components in the adult disc are explained by the embryonic origins of its parts.

Inhibition of the effects of rheumatoid synovial fluid cells on chondrogenesis and cartilage breakdown in vitro: possible therapeutical conclusions. A morphological--biochemical study

Short-term co-cultivation of blastemal cells from 12-day-old mouse limb buds and human rheumatoid synovial fluid cells in high density cultures (Trowell culture system) resulted, depending on when co-cultivation started, either in (1) an inhibition of chondrogenesis (co-cultivation right from the start) or in (2) an extensive breakdown of cartilaginous matrix (co-cultivation after formation of embryonic cartilage). These synovial effects were markedly impeded if Avarol (a dioxygenase inhibitor) was applied singly or in combination with PAI-2 (a u-PA-inhibitor). PAI-2 alone, however, had no effect on the synovial-induced inhibition of chondrogenesis, but produced a pronounced inhibitory effect on matrix breakdown. The effects of both inhibitors were studied electron microscopically and biochemically (determination of sulfated-glycosaminoglycans in the high density cultures by Alcian Blue binding assay). The results of this study are consistent with the presumption that rheumatoid synovial cells are capable of inhibiting chondrogenesis and enhancing the breakdown of the cartilaginous matrix. Amongst others, the possible mediators involved are prostaglandins and plasminogen activators. The response to the inhibitors Avarol and PAI-2 is compatible with their mode of action. The chondroprotective action of these substances may be useful in developing potential antirheumatic drugs.

Mechanisms of gastrulation and tail formation in ascidians

Ascidian embryos are useful for examining how events that occur during fertilization and cleavage affect gastrulation because they gastrulate early in development, during the seventh cleavage. In ascidians, both dorsal-ventral and anterior-posterior axes are determined before first cleavage. The dorsal-ventral axis is fixed along the animal-vegetal axis of the fertilized egg following the first phase of ooplasmic segregation, perhaps due to determinants moved to the vegetal pole in concert with the myoplasm and plasma membrane components. The first ooplasmic movements appear to be driven by the actin network in the cortical myoplasm. The anterior-posterior axis becomes apparent after the second phase of ooplasmic segregation, when the cortical myoplasm becomes detached from the egg membrane, and moves to the posterior pole of the embryo. This movement is dependent on microtubules and has been attributed to the formation and movement of the sperm aster. A major component of the cortical myoplasm, p58, is co-localized along the microtubules emanating from the sperm aster. Gastrulation begins during the seventh cleavage with the invagination of the large endodermal cells at the vegetal pole of the embryo. The neural plate appears as a thickening of the epidermis on the dorsal side of the larva during the ninth cleavage; then the neural folds are formed, join, and close, elaborating the neural tube. Following neurulation, the tail is elongated as the neural tube and notochord cells intercalate at the midline of the embryo. Investigations using anural (tailless) ascidian larvae suggest that some of the processes underlying elongation can be restored by the zygotic genome. Although ascidian larvae contain fewer cells and cell types than vertebrate embryos, ascidian gastrulation and morphogenesis appear to employ similar mechanisms to those in vertebrate embryos. The extent of our current knowledge about the mechanisms involved in gastrulation and tail formation is summarized, and further experiments are suggested to explore the molecular mechanisms underlying these processes.

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)

Expression of anchorin CII, a collagen-binding protein of the annexin family, in the developing chick embryo

Expression of anchorin CII, a collagen-binding protein of the annexin family, was followed in the developing chick embryo using Northern and in situ hybridization and Western blotting. During chick somite development, anchorin CII mRNA was detected by Northern blotting as early as stage 11. At stage 24, anchorin mRNA accumulated in the anterior part of the somite sclerotome near the resegmentation line, as shown by in situ hybridization. The presence of anchorin CII protein during stages 11 to 20 was confirmed by Western blotting. In situ hybridization identified anchorin CII also in the otic vesicle adjacent to the site of contact with the statoacoustic ganglion and in the mandibular mesenchyme. The level of anchorin CII mRNA in differentiated hyaline cartilage, exemplified by sternal cartilage, was lower than that in differentiating somites or cultured chondrocytes. These findings are consistent with our notion that anchorin CII may be involved in cell-matrix interactions preceding chondrogenic differentiation events in the chick embryo. A significant level of anchorin CII mRNA and protein synthesis was also found in cultured myoblasts, but less than that in chondroblasts. This distribution pattern is different from that reported for a related protein, p34, or calpactin, the major protein substrate for tyrosine kinase phosphorylation in chick chondrocytes and fibroblasts. The results confirm suggestions from previous sequencing studies that anchorin CII and p34 are different proteins of the annexin/calpactin family.

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.

Toward an understanding of the epithelial requirement for osteogenesis in scleral mesenchyme of the embryonic chick

Explants of scleral tissue from chick embryos of H.H. stage 29-36 (6-10 days of incubation) were used to determine if the epithelial-mesenchymal interaction which initiates scleral bone formation is cell contact, extracellular matrix, or diffusion mediated. Transfilter tissue recombinations, in which explanted interacting tissues are associated across interposing Nuclepore filters of various pore sizes and thicknesses, were performed with scleral mesenchyme and epithelium. When filters with pore sizes which would allow the passage of cell processes and diffusible substances were used, osteogenesis was initiated in the scleral mesenchyme. When cell processes were blocked with thicker filters or smaller pore sizes, bone formation still occurred, indicating that a diffusible substance mediates this tissue interaction. Further support for a diffusion-mediated interaction came from transfilter experiments using dialysis membranes to discriminate the size of the molecule(s), and Millipore filters to determine the distance over which these molecules travel. These experiments revealed that the scleral epithelial diffusible factor has a molecular weight of between 3500 and 6000 daltons, and acts over distances between 150 and 300 microns.

Basement membrane alterations during development and regression of tubular cysts

Tubular cysts consisting of dilatation of the collecting ducts at the level of the subcapsular zone of the kidney were induced in newborn rabbits by a single injection of methylprednisolone acetate. We describe here the structural and compositional modifications of the tubular basement membrane (BM) during the formation, growth, and regression of the tubular cysts. During development of the tubular cysts the cystic BM appeared thickened and multilayered, with numerous matrix vesicles. Alcian blue- (AB) and ruthenium red- (RR) positive material distributed differently along the BM of control and cystic tubuli. While the amount of RR-positive material appeared increased in the cystic BM, no differences in the intensity of the AB staining could be discerned between normal and cystic tubuli. Immunofluorescent staining for laminin and type IV collagen appeared to be slightly decreased in the cystic tubuli. However, the amount of fibronectin appeared clearly increased. These changes in the cystic BM appear at the beginning of the tubular dilatation and are not observed in other renal BM. We suggest that there is a causal relationship between the modifications of the BM and the development of the tubular cysts. Glucocorticoids appear to modify the synthesis and/or secretion of the BM components. An abnormal BM should modify the spatial and chemical signals encoded within the BM that, in turn, could lead to abnormal behavior of the tubular cells. This may result in a loss of the normal developmental constraints imposed upon the tubular epithelium, which then undergoes cystic dilatation. During the regression of the cysts, the abnormalities of the BM progressively disappear. The sharp increase in the number of interstitial cells, which show close relationships with the components of the BM, suggests that these cells may be involved in the removal of the cyst BM.

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.

Syndecan and tenascin expression is induced by epithelial-mesenchymal interactions in embryonic tooth mesenchyme

Morphogenesis of embryonic organs is regulated by epithelial-mesenchymal interactions associating with changes in the extracellular matrix (ECM). The response of the cells to the changes in the ECM must involve integral cell surface molecules that recognize their matrix ligand and initiate transmission of signal intracellularly. We have studied the expression of the cell surface proteoglycan, syndecan, which is a matrix receptor for epithelial cells (Saunders, S., M. Jalkanen, S. O'Farrell, and M. Bernfield. J. Cell Biol. In press.), and the matrix glycoprotein, tenascin, which has been proposed to be involved in epithelial-mesenchymal interactions (Chiquet-Ehrismann, R., E. J. Mackie, C. A. Pearson, and T. Sakakura. 1986. Cell. 47:131-139) in experimental tissue recombinations of dental epithelium and mesenchyme. Our earlier studies have shown that in mouse embryos both syndecan and tenascin are intensely expressed in the condensing dental mesenchyme surrounding the epithelial bud (Thesleff, I., M. Jalkanen, S. Vainio, and M. Bernfield. 1988. Dev. Biol. 129:565-572; Thesleff, I., E. Mackie, S. Vainio, and R. Chiquet-Ehrismann. 1987. Development. 101:289-296). Analysis of rat-mouse tissue recombinants by a monoclonal antibody against the murine syndecan showed that the presumptive dental epithelium induces the expression of syndecan in the underlying mesenchyme. The expression of tenascin was induced in the dental mesenchyme in the same area as syndecan. The syndecan and tenascin positive areas increased with time of epithelial-mesenchymal contact. Other ECM molecules, laminin, type III collagen, and fibronectin, did not show a staining pattern similar to that of syndecan and tenascin. Oral epithelium from older embryos had lost its ability to induce syndecan expression but the presumptive dental epithelium induced syndecan expression even in oral mesenchyme of older embryos. Our results indicate that the expression of syndecan and tenascin in the tooth mesenchyme is regulated by epithelial-mesenchymal interactions. Because of their early appearance, syndecan and tenascin may be used to study the molecular regulation of this interaction. The similar distribution patterns of syndecan and tenascin in vivo and in vitro and their early appearance as a result of epithelial-mesenchymal interaction suggest that these molecules may be involved in the condensation and differentiation of dental mesenchymal cells.

A role for fibronectin in the migration of avian precardiac cells. I. Dose-dependent effects of fibronectin antibody

An anterior-posterior concentration difference of fibronectin associated with the endoderm in early chick embryos has been implicated in the directional migration of precardiac mesoderm cells. We have examined the effect of increasing concentrations of an antibody to fibronectin (FN) to test the essentiality of FN to precardiac cell migration. For controls embryos were incubated in the presence of antibodies produced against several other extracellular components, such as laminin and anti-collagen types I and IV, as well as against integrin, a cell surface FN receptor. Embryos were also incubated in the presence of a high concentration of exogenous FN, as well as in the presence of an RGD-containing synthetic pentapeptide that is recognized by the FN receptor. After incubation of chick embryos in various concentrations of anti-FN (5 to 80 micrograms/ml), a dose-dependent effect of anti-fibronectin was observed, whereby heart development was arrested at high concentrations of anti-FN. Early developmental stages were more susceptible to lower antibody concentrations than later stages. Incubation in the presence of the RGD-containing synthetic peptide resulted in partial cardiabifida. None of the antibodies serving as controls affected cell migration or early heart development. These results support the hypothesis that FN is a major component in the migratory pathway and plays a role in the directional migration of precardiac cells to the embryonic midline.

Cell lineage conversion in the sea urchin embryo

The mesoderm of the sea urchin embryo conventionally is divided into two populations of cells; the primary mesenchyme cells (PMCs), which produce the larval skeleton, and the secondary mesenchyme cells (SMCs), which differentiate into a variety of cell types but do not participate in skeletogenesis. In this study we examine the morphogenesis of embryos from which the PMCs have been removed microsurgically. We confirm the observation of Fukushi (1962) that embryos lacking PMCs form a complete skeleton, although in a delayed fashion. We demonstrate by microsurgical and cell marking experiments that the appearance of skeletogenic cells in such PMC-deficient embryos is due exclusively to the conversion of other cells to the PMC phenotype. Time-lapse video recordings of PMC-deficient embryos indicate that the converting cells are a subpopulation of late-ingressing SMCs. The conversion of these cells to the skeletogenic phenotype is accompanied by their de novo expression of cell surface determinants normally unique to PMCs, as shown by binding of wheat germ agglutinin and a PMC-specific monoclonal antibody. Cell transplantation and cell marking experiments have been carried out to determine the number of SMCs that convert when intermediate numbers of PMCs are present in the embryo. These experiments indicate that the number of converting SMCs is inversely proportional to the number of PMCs in the blastocoel. In addition, they show that PMCs and converted SMCs cooperate to produce a skeleton that is correct in both size and configuration. This regulatory system should shed light on the nature of cell-cell interactions that control cell differentiation and on the way in which evolutionary processes modify developmental programs.

Synthetic peptides that mimic the adhesive recognition signal of fibronectin: differential effects on cell-cell and cell-substratum adhesion in embryonic chick cells

Although fibronectin has been implicated in cell-cell as well as cell-substratum interactions, most experimentation has focused on cell-substratum interactions of fibroblasts. We have examined the effect of the specific peptide GRGDS derived from the cell-binding sequence of fibronectin upon cell-cell and cell-substratum interactions using embryonic cells and tissues. Embryonic chick segmental plate cells undergo compaction (i.e., increased cell-cell adhesion) during the early stages of somitogenesis. Fibronectin has been implicated in this increase in cell-cell interaction. In contrast, precardiac mesoderm undergoes directional migration upon a fibronectin-rich substratum, exhibiting both cell-cell and cell-substratum interactions. The segmental plate cells, which are the precursors of embryonic somites, normally show very little cell-cell or cell-substratum interaction in culture. These cells exhibit a striking increase in intercellular adhesion, but exhibit no cell-substratum adhesion, in the presence of relatively low concentrations of the fibronectin-derived peptide GRGDS. Somite cells, which normally exhibit both cell-cell and cell-substratum adhesion in culture, show complete inhibition of cell-substratum adhesion in the presence of this peptide. Precardiac mesoderm, which normally exhibits both cell-cell and cell-substratum adhesion in culture, shows a marked inhibition of both processes in the presence of GRGDS. Since the finding that a monovalent competitive inhibitor of fibronectin binding can stimulate cell-cell adhesion was unexpected, we propose a "trigger" hypothesis, whereby the peptide recognition signal acts as a specific signal or trigger for the morphogenetic process of compaction. There is a striking specificity to this effect, since synthetic peptides with even conservative changes in the amino acid sequence have no effect. Finally, we find that under certain conditions the effect of the specific peptide is lost in 6-8 hr and the cells resume cell-substratum interactions or, in the case of the segmental plate cells, revert from the compacted state and exhibit a substantial decrease in cell-cell adhesion. Our studies indicate the diversity of cell and tissue responses possible when even a single peptide inhibitor of adhesion, and we have identified the first known activating effect of a fibronectin peptide on cell behavior and differentiation.

Feedback control of selected biosynthetic activities of chondrocytes in culture

The syntheses of proteoglycans and proteins by chondrocytes from the Swarm rat chondrosarcoma in primary cultures were modulated on the addition of matrical molecules. In the presence of hyaluronan, collagen or proteoglycan aggregates the synthesis of proteoglycans was depressed. The synthesis of collagen was also depressed in the presence of hyaluronan or collagen. In the presence of proteoglycan monomers, the incorporation of 35S-sulfate was enhanced in proportion to the concentration of the additive in the medium; the synthesis of protein was unaffected. The proteoglycan monomers synthesized in the presence of proteoglycan monomers were larger than those synthesized in their absence. In combinations, the exogenous macromolecules did not affect the selected biosynthetic activities to an extent greater than that which they exerted separately. The data suggest, however, that the proteoglycan monomers can counteract the inhibitory effects of the macromolecules which are inhibitory. The data, moreover, suggest that the chondrocytes of the Swarm rat chondrosarcoma have the potential to discriminate between proteoglycan monomers produced by self and those produced by chondrocytes of hyaline cartilages.

Distribution of hyaluronic acid and sulfated glycosaminoglycans during blood-vessel development in the chick chorioallantoic membrane

This study uses histochemical methods to determine the ultrastructural distribution of specific glycosaminoglycans (GAGs) during the development of blood vessels in the chick chorioallantoic membrane (CAM) and to correlate changes in GAG composition with the significant structural events in the development of these vessels. Tissues were stained with tannic acid, ruthenium red, and high iron diamine and digested in various GAG-degrading enzymes to identify specific GAGs. The results are consistent with a role for hyaluronic acid in the formation, alignment, or migration of the capillary plexus of the CAM and a role for sulfated GAGs (heparan sulfate, chondroitin sulfate, dermatan sulfate) in the differentiation and development of arterial and venous vessels of the chorioallantoic membrane.

Transient expression of collagen type II at epitheliomesenchymal interfaces during morphogenesis of the cartilaginous neurocranium

In the avian embryo a matrix-mediated tissue interaction between retinal pigmented epithelium and neural crest-derived periocular mesenchyme leads to the differentiation of (scleral) cartilage. The composition of the extracellular matrix at the interface between these two tissues has been examined immunohistochemically, both during and after the interaction has taken place. Of the matrix components studied (fibronectin, laminin, and collagen types I, II, IV, and V) only collagen type II displayed a dramatic change in distribution between the two stages. During the interaction, at stage 15, type II was present in the extracellular compartment basal to the epithelium. After completion of the interaction, collagen type II was no longer detectable at the interface even though it was readily detectable in the vitreous humor, cornea, and perinotochordal sheath, and subsequently will be expressed by the chondrogenic tissue itself as overt differentiation commences. These results suggest that collagen type II might be causally involved in this particular epitheliomesenchymal interaction. Examination of the spatial and temporal patterns of collagen type II expression elsewhere in the developing craniofacial complex revealed a hitherto unreported pattern of distribution. In addition to its predictable locations (i.e., cornea, vitreous, and perinotochordal sheath) it was found to be present at certain other sites, for example, at the basal surfaces of some neuroepithelia. These additional locations are all known to be sites of chondrogenesis-promoting tissue interactions which result in the formation of the elements of the cartilaginous neurocranium (e.g., otic vesicle). Furthermore this spatial distribution exhibits a changing temporal pattern in that it is detectable at the time that the interactions are known to be taking place, but subsequently is no longer detectable by the immunohistochemical means employed. This definable pattern of transient collagen type II expression, occurring at very early stages of craniofacial development, is interpreted as reflecting one level of morphogenetic specification of chondrocranial/skull form in the developing vertebrate head.

Development of extracellular matrix in chick paravertebral sympathetic ganglia

Alcian blue staining coupled with enzyme digestion or critical electrolyte staining revealed differences in the development of extracellular matrix (ECM) within sympathetic ganglia compared with the surrounding capsule. On day 5 of chick development (Hamburger-Hamilton stage 26) only hyaluronic acid (HA) could be detected in the ECM surrounding condensing primary ganglia. By day 7 (st 30) the ganglionic capsule contained HA, as well as sulfated glycosaminoglycans (GAGs), and this pattern continued into the adult stage. During the later stages of embryonic life (st 41-45) satellite cells appear, showing fine structural characteristics that point to their role in the secretion of intraganglionic ECM. Only during these stages could ECM be detected histochemically within ganglia, the same stages (days 15-19) when routine electron microscopic methods reveal collagen fibrils embedded in a granular ground substance. Thus, the intraganglionic environment appears as a separate compartment free of detectable amounts of GAG until late embryonic stages when ECM is secreted around satellite cells. This developmental pattern could represent a role of ECM in the histological stabilization of ganglia during the late stages of differentiation, since the appearance of intraganglionic ECM is correlated with the appearance of small dense-cored vesicles characteristic of adult neurons. The developmental pattern of ECM in differentiating sympathetic ganglia is compared with that of other tissues that undergo condensation and morphogenesis.

Glucocorticoid inhibition of fibroblast contraction of collagen gels

When skin fibroblasts are grown in culture on collagen gels, the collagen gels contract. We have studied the effects of various steroids on the contraction process. Cortisol, beta-estradiol and dexamethasone inhibited fibroblast-mediated gel contraction at low (10(-8) to 10(-9) M) concentrations whereas dihydrotestosterone was without effect. These effects were time and concentration dependent and could be reversed if the steroids were removed. This system may be useful for assaying the activities of various steroids in terms of their activities and modulating effects on connective tissue.

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.

Matrix-cytoskeletal interactions in the developing eye

The embryonic avian corneal epithelium in vitro responds to extracellular matrix (ECM) molecules in either soluble or polymerized form by flattening its basal surface, organizing the basal cortical actin cytoskeleton, and stepping up its production of corneal stroma twofold. Embryonic corneal epithelia, like hepatocytes and mammary gland cells, seem to contain heparan sulfate proteoglycan (HSPG) in their plasmalemma, which may interact with actin on the one hand or underlying collagen on the other. Work on the corneal epithelium suggests that, in addition to HSPG, specific glycoprotein receptors for laminin and collagen exist in the basal plasmalemma and play the critical role in actually organizing the basal epithelial cytoskeleton. As yet, uncharacterized proteins may link such receptors to actin. We suggest that ECM-dependent organization of the cytoskeleton is responsible for ECM enhancement of corneal epithelial differentiation. Cell shape and exogenous ECM also affect mesenchymal cell differentiation. In the case of the corneal fibroblast migrating in collagen gels, an actin cortex present around the elongate cell seems to interact with myosin in the cytosol to bring about pseudopodial extension. Both microtubules and actin microfilaments are involved in fibroblast elongation in collagen gels. It follows from the rules presented in this review that the mesenchymal cell surface is quite different from the epithelial cell surface in its organization. Nevertheless, epithelial cell surface-ECM interaction can be modified in the embryo at particular times to permit predesignated epithelial-mesenchymal transformations, as for example at the primitive streak. Though basal surfaces of definitive, nonmalignant epithelia adhere rather strictly to the rules of epithelium-ECM interaction and do not invade underlying ECM, the environment can be manipulated in vitro to cause these epithelia to send out pseudopodia and give rise aberrantly to mesenchymal cells in collagen gels. Further study of this phenomenon should cast light on the manner in which epithelial and mesenchymal cells organize receptors for matrix molecules on their cell surfaces and develop appropriate cytoskeletal responses to the extracellular matrix.

Staining of proteoglycans in mouse lung alveoli. I. Ultrastructural localization of anionic sites

In order to contrast anionic sites in mouse lung alveoli, two staining procedures were applied: (a) staining with Ruthenium Red and Alcian Blue and (b) staining with Cuprolinic Blue in a critical electrolyte concentration method. The Ruthenium Red-Alcian Blue staining procedure revealed electron-dense granules in the alveolar basement membrane. The granules were closely associated with the epithelial cell membrane and continued to stain even when the procedure was carried out at a low pH, indicating the presence of sulphate groups in the granules. After staining with Cuprolinic Blue, electron-dense filaments, also closely associated with the cell membrane, became visible in the basement membrane of type I epithelial cells. Their length depended on the MgCl2 concentration used during staining. At 0.4 M MgCl2, the length was mostly within the range 100-180 nm. Using a modified Cuprolinic Blue method, the appearance of the filaments closely resembled that of spread proteoglycan monomers with their side-chains condensed. The basement membrane of type II epithelial cells also contained filaments positive towards Cuprolinic Blue; their length, however, was smaller in comparison with those of type I epithelial cells. The filaments lay in one plane and provided the whole alveolus with an almost continuous sheet of anionic sites. Cuprolinic Blue staining also revealed filaments in the basement membrane of the capillary endothelial cells. Furthermore, Cuprolinic Blue-positive filaments (average length about 40 nm) became apparent in close contact with collagen fibrils and separated from each other according to the main banding period of the collagen fibrils (about 60 nm), indicating a specific ultrastructural interaction between these two components. Filaments connecting collagen fibrils with each other were also detected.

Role of anchorin CII, a 31,000-mol-wt membrane protein, in the interaction of chondrocytes with type II collagen

We have previously reported the isolation of a hydrophobic, type-II collagen-binding glycoprotein of molecular weight 31,000 (31,000-mol-wt protein) from chick chondrocyte membranes (Mollenhauer, J., and K. von der Mark, EMBO Eur. Mol. Biol. Organ. J., 2:45-50). The function of this protein in anchoring pericellular type II collagen to the chondrocyte surface was inferred from its ability to bind native type-II collagen either when detergent solubilized or when inserted into liposomes. In the present study we have used specific antibodies to localize this protein, which we now call anchorin CII, to the surface of chondrocytes in both cartilage sections, and in cell culture. In immunofluorescence studies of isolated chondrocytes we observed a dense, punctate distribution of anchorin CII on the cell surface when chondrocytes were enclosed by a pericellular type II collagen matrix. Removal of the pericellular matrix with trypsin also removed anchorin CII. The membrane protein character of anchorin CII was indicated by the demonstration of antibody-induced patching and capping on the chondrocyte surface at 22 degrees C and 37 degrees C, respectively. In monolayer culture, the amount of anchorin CII appeared reduced on flattened chondrocytes lacking a pericellular type II collagen matrix but was prominent upon intercellular cell processes. Fab' fragments prepared from either anchorin CII antiserum or an antiserum directed against the entire chondrocyte membrane inhibited the attachment of chondrocytes to a type II collagen substrate. In each case, the inhibition of attachment was neutralized by preincubation of Fab' fragments with purified anchorin CII.

Low buoyant density proteoglycans from saline and dissociative extracts of embryonic chicken retinas

Retinas were labeled in culture with [3H]glucosamine or [3H]leucine and [35S]sulfate and extracted sequentially with physiologically balanced saline and 4 M guanidine HCl. They were dialyzed into associative conditions (0.5 M NaCl) and chromatographed on agarose columns. Under these conditions, some of the proteoglycans were associated in massive complexes that showed low buoyant densities when centrifuged in CsCl density gradients under dissociative conditions (4 M guanidine HCl). Much of the label in these complexes was in molecules other than proteoglycans. Most of the proteoglycans, however, were included on the agarose columns, where they appeared to be constitutionally of low buoyant density. They resisted attempts to separate potential low buoyant density contaminants from the major proteoglycans by direct CsCl density gradient centrifugation or by the fractionation of saline or 8 M urea extracts on diethylaminoethyl-Sephacel. The diethylaminoethyl-Sephacel fractions were either subjected to CsCl density gradient centrifugation or were chromatographed on Sephacryl S-300, in both cases before and after alkaline cleavage, to confirm the presence of typical O-linked glycosaminoglycans. The medium and balanced salt extracts were enriched in chondroitin sulfate and other sulfated macromolecules, possibly highly sulfated oligosaccharides, that resisted digestion by chondroitinase ABC but were electrophoretically less mobile than heparan sulfate. Guanidine HCl or urea extracts of the residues were mixtures of high and low density proteoglycans that were enriched in heparan sulfate.

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.

Growth and differentiation of hamster tracheal epithelial cells in culture

The purpose of these studies was to define culture conditions that support growth and differentiation of normal epithelial cells obtained from hamster tracheas. Epithelial cells from tracheas of adult hamsters were collected using enzymatic procedures and cultured under various conditions. The medium used consisted of a 1:1 mixture of medium 199 and Dulbecco's modified Eagle's medium with 2% fetal bovine serum, which was conditioned by mouse 3T3 cells before use. Insulin, transferrin, hydrocortisone, epidermal growth factor, and an extract from bovine hypothalamus were used as supplements. When seeded on uncoated or collagen-coated tissue culture dishes, the hamster cells grew only poorly. When the cells were seeded on collagen gels, however, rapid and prolonged growth ensued. The cultures had a population doubling time of 20 hr and a colony-forming efficiency of 7-10%, and they could be grown for up to three passages. Growth was dependent on the presence of transferrin, insulin, epidermal growth factor, and 3T3 conditioning factors in the medium. The latter could be omitted if the concentration of serum was increased. Less important for growth was the presence of hydrocortisone and bovine hypothalamus extract. In contrast to results with tracheal epithelial cells from adult rabbits, rats, and mice, differentiation into ciliated cells regularly occurred in cultures of cells derived from hamster tracheas. The appearance of ciliated cells in the cultures was dependent on the presence of collagen gel as a substratum and of 3T3 conditioning factors in the medium. In addition, there were numerous cells that contained electron-dense cytoplasmic granules. The granules were not stained by dialyzed iron, which stains acidic glycoproteins, but were stained positively by periodic acid-Schiff reagents and the periodic acid-thiocarbohydrazide-silver proteinate method, suggesting the presence of secretory granules containing neutral glycoproteins. A similar staining pattern was observed for the secretory granules of intact hamster tracheas. The culture system described supports growth and cellular differentiation of normal tracheal epithelial cells of hamsters. We believe therefore that it will be a useful model for studying the regulation of tracheal cell function on the cellular and biochemical level.

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.

Consequences of neural tube and notochord excision on the development of the peripheral nervous system in the chick embryo

Notochordectomy and neuralectomy were carried out either in one- or in two-step experiments on the chick embryo. The aim of this operation was to study the influence of the axial organs (notochord and neural tube) on the development of the ganglia of the peripheral nervous system. The neural crest cells from which most peripheral ganglion cells arise were labeled through the quail-chick marker system and their fate was followed under various experimental conditions. It appeared that the development of the dorsal root and sympathetic ganglia depends on survival and differentiation of somite-derived structures. In the absence of neural tube and notochord, somitic cells die rapidly, and so do the neural crest cells that are present in the somitic mesenchyme at that time. In contrast, those crest cells which can reach the mesenchymal wall of the aorta, the suprarenal glands, or the gut survive and develop normally into nerve and paraganglion cells. Differentiation of the neural crest- and placode-derived sensory ganglia of the head which develop in the cephalic mesenchyme is not affected by removal of notochord and encephalic vesicles. These results show that the peripheral ganglia are differentially sensitive to the presence of the neural tube and the notochord. Among the various ganglia of the peripheral nervous system, spinal and sympathetic ganglia are the only ones which require the presence of these axial structures. The neural tube allows both the spinal and the sympathetic ganglia to develop in the absence of the notochord. In contrast, if the notochord is left in situ and the neural tube removed, the spinal ganglia fail to differentiate and only sympathetic ganglia can develop.

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.

Interaction of embryonic surface and cytoskeleton with extracellular matrix

Evidence for cell-matrix in vitro and in the embryo is briefly reviewed, and more detailed observations are presented on the reactions of corneal epithelium and mesenchyme to extracellular matrix (ECM). The basal surface of embryonic corneal epithelium blebs when the underlying ECM is removed. If the epithelium is cultured on top of the lens capsule or collagen gel, the basal surface flattens and the cortical cytoskeleton reorganizes to resemble that present in vivo. The basal surface also responds to soluble matrix molecules (types I-IV collagens, laminin, fibronectin), and the cells step up synthesis of corneal stroma as measured by incorporation of proline into collagen. When embryonic corneal fibroblasts are placed on top of hydrated gels they tend to burrow into the gel rather than sitting on top as does epithelium. When grown inside collagen gels, these mesenchymal cells elongate and the entire cell surface and cytoskeleton organize in response to matrix. Stress fibers and ruffling membranes characterize the cells grown on glass. When embryonic lens or corneal epithelial are place within, instead of on top of, collagen gels, they give rise to mesenchyme-like cells from their apical surfaces. In vivo, these epithelia do not give rise to mesenchyme. The rules for epithelial-mesenchymal transformation in vivo are discussed in relation to these observations on cell-matrix interaction.