Induction of chondrogenesis in limb mesenchymal cultures by disruption of the actin cytoskeleton.

Cell shape is known to influence the chondrogenic differentiation of cultured limb bud mesenchyme cells (Solursh, M., T. F. Linsenmayer, and K. L. Jensen, 1982, Dev. Biol., 94: 259-264). To test whether specific cytoskeletal components mediate this influence of cell shape, we examined different cytoskeleton disrupting agents for their ability to affect chondrogenesis. Limb bud cells cultured at subconfluent densities on plastic substrata normally become flattened, contain numerous cytoplasmic microtubules and actin bundles, and do not undergo spontaneous chondrogenesis. If such cultures are treated with 2 micrograms/ml cytochalasin D during the initial 3-24 h in culture, the cells round up, lose their actin cables, and undergo chondrogenesis, as indicated by the production of immunologically detectable type II collagen and a pericellular Alcian blue staining matrix. Cytochalasin D also induces cartilage formation by high-density cultures of proximal limb bud cells, which normally become blocked in a protodifferentiated state. In addition, cytochalasin D was found to reverse the normal inhibition by fibronectin of chondrogenesis by proximal limb bud cells cultured in hydrated collagen gels. Agents that disrupt microtubules have no apparent effect on the shape or chondrogenic differentiation of limb bud mesenchymal cells. These results suggest an involvement of the actin cytoskeleton in controlling cell shape and chondrogenic differentiation of limb bud mesenchyme. Interactions of the actin cytoskeleton and extracellular matrix components may provide a regulatory mechanism for mesenchyme cell differentiation into cartilage or fibrous connective tissue in the developing limb.

Expression of two nonallelic type II procollagen genes during Xenopus laevis embryogenesis is characterized by stage-specific production of alternatively spliced transcripts.

The pattern of type II collagen expression during Xenopus laevis embryogenesis has been established after isolating specific cDNA and genomic clones. Evidence is presented suggesting that in X. laevis there are two transcriptionally active copies of the type II procollagen gene. Both genes are activated at the beginning of neurula stage and steady-state mRNA levels progressively increase thereafter. Initially, the transcripts are localized to notochord, somites, and the dorsal region of the lateral plate mesoderm. At later stages of development and parallel to increased mRNA accumulation, collagen expression becomes progressively more confined to chondrogenic regions of the tadpole. During the early period of mRNA accumulation, there is also a transient pattern of expression in localized sites that will later not undergo chondrogenesis, such as the floor plate in the ventral neural tube. At later times and coincident with the appearance of chondrogenic tissues in the developing embryo, expression of the procollagen genes is characterized by the production of an additional, alternatively spliced transcript. The alternatively spliced sequences encode the cysteine-rich globular domain in the NH2-propeptide of the type II procollagen chain. Immunohistochemical analyses with a type II collagen monoclonal antibody documented the deposition of the protein in the extracellular matrix of the developing embryo. Type II collagen expression is therefore temporally regulated by tissue-specific transcription and splicing factors directing the synthesis of distinct molecular forms of the precursor protein in the developing Xenopus embryo.

Differential displaying of mRNAs from the atrioventricular region of developing chicken hearts at stages 15 and 21.

In an effort to isolate novel genes that may be involved in the development of the cardiac cushions and then the formation of cardiac valves and septa, we utilized the differential mRNA display method in conjunction with the whole-mount in situ hybridization. The total RNAs used to differentially display were prepared from atrioventricular (AV) canal regions of stage 15 and stage 21 chicken hearts because critical events known to be important for the AV valve and septum formation occur during this period of the development. We have successfully obtained 14 potential candidate genes. Three examples, 15H16 (phospholamban), E13 (skeletal alpha-tropomyosin) and 21C (a novel gene), are discussed here. Levels of mRNA expression in developing hearts were determined by Northern blot analysis and their expression patterns were revealed and compared using whole-mount in situ hybridization. Both phospholamban and skeletal alpha-tropomyosin messages in the myocardium of the AV canal region showed significant decrease during this period of the development. The 21C differential display product detects a novel 9.5 Kb message whose expression is cardiac-specific at early stages of development. The expression level of the 21C gene appeared to be increased from stage 15 to stages 21 and 25 as determined by both Northern blot analysis and in situ hybridization. From these data, we demonstrate that the differential display method together with the whole-mount in situ hybridization could be an effective means for the isolation of novel and differentially expressed genes.

Production of a monoclonal antibody by in vitro immunization that recognizes a native chondroitin sulfate epitope in the embryonic chick limb and heart.

We report the production of a monoclonal antibody (d1C4) by in vitro immunization that has immunoreactivity with a native chondroitin sulfate epitope in embryonic chick limb and heart. Murine lymphocytes were stimulated by direct exposure to unfixed, unsolubilized precartilage mesenchymal aggregates in high-density micromass culture derived from Stage 22-23 chick limb buds. Specificity of d1C4 reactivity was demonstrated by sensitivity of immunohistochemical staining to pretreatment with chondroitinase ABC or AC, preferential immunoreactivity with chondroitin-6-sulfate glycosaminoglycan (CS-C GAG) in ELISA, and competition of immunohistochemical staining with CS-C GAG. Immunohistochemical analysis of the expression of the d1C4 epitope revealed a striking localization of immunoreactivity in the extracellular matrix (ECM) of precartilage aggregates of chick limb mesenchyme in high-density micromass culture by 16 hr and the prechondrogenic limb core at Stage 23 in vivo. Immunoreactivity in both cultured limb mesenchyme and the embryonic limb continued through differentiation of prechondrogenic condensations into cartilage tissue. In the developing chick heart, d1C4 staining was found throughout the ECM of atrioventricular cushion tissue by Stage 25, but was localized to mesenchyme adjacent to the myocardium in the outflow tract cushions. There was an abrupt demarcation between d1C4-reactive intracardiac mesenchyme and unreactive extracardiac mesenchyme of the dorsal mesocardium in the Stage 22 embryo. This study demonstrates the efficacy of in vitro immunization of lymphocytes for the production of MAbs to native ECM constituents, such as CS-GAGs. Immunohistochemical data utilizing d1C4 suggest that CS-GAGs bearing this epitope may be important in early morphogenetic events leading to cartilage differentiation in the limb and valvuloseptal morphogenesis in the heart.

Extracellular matrix and cell surface as determinants of connective tissue differentiation.

This paper reviews in vitro studies, largely from the author's laboratory, concerning the conditions that are permissive for the differentiation of limb bud mesenchymal cells into chondrocytes. In high-density cell culture, even in a defined medium, the same normal sequence of events that is found in vivo in developing cartilage is also observed. This system can be used to study heritable disorders in model systems such as in mutant mouse embryos. In addition, single mesenchymal cells can differentiate into hypertrophic chondrocytes in hydrated collagen gel or agarose cultures. A rounded cell shape promotes chondrogenesis, while a flattened cell shape promotes fibroblast differentiation. The actin cytoskeleton is shown to play a central role in regulating connective tissue cell differentiation. By use of such cell culture manipulations, it is now possible to grow large numbers of fibroblastic cells from human biopsy material for storage and to carry out experimental studies after re-expression of chondrogenesis in gel cultures. It is suggested that cytoskeletal-extracellular matrix interactions play a fundamental role in connective tissue differentiation. Matrix receptors might be developmentally regulated and modify epithelial effects on mesenchymal cells. In this way mesenchymal cells differentiate in a highly organized manner in spatial and temporal terms.

Bone cell expression on titanium surfaces is altered by sterilization treatments.

Phenotypic responses of rat calvarial osteoblast-like cells (RCOB) were evaluated on commercially pure titanium (cpTi) surfaces when cultured at high density (5100 cells/mm2). These surfaces were prepared to three different clinically relevant surface preparations (1-micron, 600-grit, and 50-microns-grit sand-blast), followed by sterilization with either ultraviolet light, ethylene oxide, argon plasma-cleaning, or routine clinical autoclaving. Osteocalcin and alkaline phosphatase, but not collagen expression, were significantly affected by surface roughness when these surfaces were altered by argon plasma-cleaning. In general, plasma-cleaned cpTi surfaces demonstrated an inverse relationship between surface roughness and phenotypic markers for a bone-like response. On a per-cell basis, levels of the bone-specific protein, osteocalcin, and the enzymatic activity of alkaline phosphatase were highest on the smooth 1-micron polished surface and lowest on the roughest surfaces for the plasma-cleaned cpTi. Detectable bone cell expression can be altered by clinically relevant surfaces prepared by standard dental implant preparation techniques.

The formation of premuscle masses during chick wing bud development.

The skeletal musculature of chick limb buds is derived from somitic cells that migrate into the somatopleure of the future limb regions. These cells become organized into the earliest muscle primordia, the dorsal and ventral premuscle masses, prior to myogenic differentiation. Therefore, skeletal-muscle specific markers cannot be used to observe myogenic cells during the process of premuscle mass formation. In this study, an alternative marking method was used to determine the specific stages during which this process occurs. Quail somite strips were fluorescently labeled and implanted into chick hosts. Paraffin sections of the resulting chimeric wing buds were stained with the monoclonal antibody QH1 in order to identify graft-derived endothelium. Non-endothelial graft-derived cells present in the wing mesenchyme were assumed to be myogenic. At Hamburger and Hamilton stage 20, myogenic cells were distributed throughout the central region of the limb, including the future dorsal and ventral premuscle mass regions and the prechondrogenic core region. By stage 21, the myogenic cells were present at greater density in dorsal and ventral regions than in the core. By stage 23, nearly all myogenic cells were located in the dorsal and ventral premuscle masses. Therefore, the two premuscle masses become established by stage 21 and premuscle mass formation is not complete until stage 23 or later. Premuscle mass formation occurs concurrently with early chondrogenic events, as observed with the marker peanut agglutinin. To facilitate the investigation of possible underlying mechanisms of premuscle mass formation, the micromass culture system was evaluated, to determine whether or not it can serve as an accurate in vitro model system. The initially randomly distributed myogenic cells were observed to segregate from prechondrogenic regions prior to myogenic differentiation. This is similar to myogenic patterning in vivo.

The distribution of mesenchyme proteoglycan (PG-M) during wing bud outgrowth.

This study utilizes immunofluorescence to describe the distribution of several extracellular matrix molecules in the chick embryo during the process of limb outgrowth and the formation of precartilage condensations. A large chondroitin sulfate proteoglycan (PG-M) is detected at the wing level at Hamburger and Hamilton stage 14 in and under the dorsal ectoderm, and is associated with the basement membranes around the neural tube, notochord and pronephros, but not with other basement membranes. The galactose-specific lectin, peanut agglutinin (PNA), has a similar distribution except that it also binds to the dorsal side of the neural tube. PG-M is not detected in the limb mesenchyme until after stage 17, when it is present in the distal region, as is PNA-binding material. With further development of the wing bud, PG-M is present in the subectodermal mesenchyme, the mesenchyme at the distal tip and in the prechondrogenic core. After stage 22 PNA-binding material becomes localized in the prechondrogenic core, the basement membranes under the apical ectodermal ridge, and the ventral sulcus. The distribution of these components (PG-M and PNA binding material) overlaps, but differs from that of type I collagen and fibronectin and basement membrane components, such as laminin, basement membrane heparan sulfate proteoglycan, and type IV collagen. Tenascin, on the other hand, is not detected in the limb bud until stage 25, after the appearance of cartilage matrix components such as type II collagen and cartilage proteoglycan (PG-H). These results are considered in relation to the formation of precartilage aggregates, and indicate that PNA binds to components in precartilage aggregates other than PG-M or tenascin.

Myogenic potential of chick limb bud mesenchyme in micromass culture.

The myogenic potential of chick limb mesenchyme from stages 18-25 was assessed by micromass culture under conditions conductive to myogenesis, and was measured as the proportion of differentiated (muscle myosin-positive) mononucleated cells detected. It was found that similar myogenic potentials existed in mesenchyme from whole limbs between stages 18 and 19, but this potential was halved by stage 20. At stage 21, proximal mesenchyme showed significantly more myogenesis than distal mesenchyme, but this difference was abolished by stage 22. Thereafter, myogenesis was increasingly restricted from the distal mesenchyme, whilst the potential in more proximal regions did not significantly increase after stage 23. When the ratio between total limb myoblasts which differentiated on days 1 and 4 of culture was analysed, it was found that two distinct peaks existed at stages 20 and 23. The significance of these ratio peaks is unclear, but may be related to different proliferative potentials of the pre-myoblasts at these stages.

Comparative analysis of fibrillar and basement membrane collagen expression in embryos of the sea urchin, Strongylocentrotus purpuratus.

The time of appearance and location of three distinct collagen gene transcripts termed 1 alpha, 2 alpha, and 3 alpha, were monitored in the developing S. purpuratus embryo by in situ hybridization. The 1 alpha and 2 alpha transcripts of fibrillar collagens were detected simultaneously in the primary (PMC) and secondary (SMC) mesenchyme cells of the late gastrula stage and subsequently expressed in the spicules and gut associated cells of the pluteus stage. The 3 alpha transcripts of the basement membrane collagen appeared earlier than 1 alpha and 2 alpha, and were first detected in the presumptive PMC at the vegetal plate of the late blastula stage. The PMC exhibited high expression of 3 alpha at the mesenchyme blastula stage, but during gastrulation the level of expression was reduced differentially among the PMC. In the late gastrula and pluteus stages, both PMC and SMC expressed 3 alpha mRNA, and thus at these stages all three collagen genes displayed an identical expression pattern by coincidence. This study thus provides the first survey of onset and localization of multiple collagen transcripts in a single sea urchin species.

Stable, position-related responses to retinoic acid by chick limb-bud mesenchymal cells in serum-free cultures.

Retinoic acid (RA) has dramatic effects on limb-skeletal patterning in vivo and may well play a pivotal role in normal limb morphogenesis. RA's effects on the expression of pattern-related genes in the developing limb are probably mediated by cytoplasmic RA-binding proteins and nuclear RA-receptors. Little is known, however, about how RA modifies specific cellular behaviors required for skeletal morphogenesis. Earlier studies supported a role for regional differences in RA concentration in generating the region-specific cell behaviors that lead to pattern formation. The present study explores the possibility that position-related, cell-autonomous differences in the way limb mesenchymal cells respond to RA might have a role in generating pattern-related cell behavior. Mesenchymal cells from different proximodistal regions of stage 21-22 and 23-24 chick wing-buds were grown in chemically defined medium and exposed to 5 or 50 ng/ml of RA for 4 days in high-density microtiter cultures. The effects of RA on chondrogenesis in these cultures clearly differed depending on the limb region from which the cells were isolated. Regional differences in RA's effects on growth over 4 days in these cultures were less striking. The region-dependent responses of these cells to RA proved relatively stable in culture despite ongoing cytodifferentiation. This serum-free culture model will be useful in exploring the mechanisms underlying the region-dependent responsiveness of these cells to RA.

Peripheral nerve extract effects on mesenchymal cells.

Several common congenital limb disorders are characterized by normal tissue differentiation but abnormal somatic growth. These include: idiopathic clubfoot, idiopathic leg length discrepancy, hemi-atrophy and hemi-hypertrophy. Both clinical and research studies have suggested that peripheral nerves may be important in regulating somatic growth of limb tissues. To investigate the hypothesis that peripheral nerves convey trophic substances to mesenchymal tissues that are involved in the regulation of growth, we developed an in vitro assay to assess the effect of fractions of peripheral nerve on myoblast and chondroblast growth and differentiation in a mammalian (rat) system. Whole rat sciatic nerve extract was fractionated by ammonium sulfate precipitation and by affinity chromatography. Concavalin A chromatography resolved whole nerve extract into a glycoprotein and a non-glycoprotein fraction. Serial ammonium sulfate precipitation yielded three pellet fractions designated as 35%, 70%, and 100% pellets; corresponding to ammonium sulfate concentrations of 0 to 35%, 35 to 70%, and 70 to 100% saturation, respectively. Dialyzed solutions of these pellets as well as the fractions from Concavalin A chromatography were assayed for biological activity in micromass cultures of rat limb bud mesenchyme, which allowed assessment of both myoblast and chondroblast stimulation. Stimulation of protein synthesis and myoblast proliferation (as measured by MF20 staining) occurred with both 70% and 100% ammonium sulfate fractions. Stimulation of chondroblasts (as measured by the number of alcian blue staining nodules) occurred with the 35% and 100% fractions. The glycoprotein fraction from the affinity chromatography stimulated protein synthesis and myoblast proliferation and inhibited chondroblast development. Stimulation of chondroblasts was seen with the non-glycoprotein fraction. No effect on protein synthesis, myoblast proliferation or chondroblast proliferation was found in cultures treated with rat transferrin (transferrin has been reported to stimulate myoblasts in avian culture systems).

Ectoderm as a determinant of early tissue pattern in the limb bud.

This review considers the hypothesis that the limb bud ectoderm establishes the initial pattern of the various mesodermal components within the limb bud. The evidence reviewed supports the hypothesis that the ectoderm establishes a peripheral, non-chondrogenic, avascular sleeve around the limb bud. The ectodermal influence is a diffusible factor that acts by altering the collagenous extracellular matrix so that cell flattening and fibrogenic differentiation are promoted. It is hypothesized that just within this sleeve is a vascular-rich zone where myogenic cells migrate in response to a chemotactic influence. In the center of the limb bud is the prechondrogenic core, whose size determines the number of skeletal elements which subsequently form. The dimensions of the developing limb bud are established during distal limb outgrowth by the reciprocal interaction between the apical ectodermal ridge, which has a mitogenic influence, and the underlying mesoderm.

The migratory capacity of myogenic cells in vitro.

Time-lapse films of micromass cultures prepared from stage 19-24 chick embryo wing buds indicate that the majority of the mesenchymal cells present undergo little net movement, even during the formation of prechondrogenic aggregates. Rather, these cells undergo mitosis and pulsatile movements in place. In the same cultures, round or elongate myoblasts could be observed migrating as single cells on or between the mesenchymal cells. These in vitro observations are consistent with the suggestion that migratory myoblasts may establish the myogenic pattern in the limb by extensive migration through the nonmigrating limb mesenchyme.

Formation of cartilage tissue in vitro.

Articular cartilage is notoriously defective in its capacity for self-repair, making joints particularly sensitive to degenerative processes. However, methods are now available for the preparation of large numbers of differentiated chondrocytes from a small biopsy sample from any patient. The cells are amplified by proliferation as fibroblast-like cells that will re-express the cartilage phenotype when placed in suspension or gel culture. The chondrocytes can be collected from gel cultures after agarase treatment and reconstituted into cartilage tissue in pellet cultures. In addition, these chondrocytes can be suspended in an appropriate delivery vehicle and implanted into defect sites with a high reparative success rate in an animal model. Appropriate procedures can now be tested in appropriate patient populations.

Cartilage stem cells: regulation of differentiation.

The developing limb bud is a useful source of cartilage stem cells for studies on the regulation of chondrogenesis. In high density cultures these cells can progress through all stages of chondrogenesis to produce mineralized hypertrophic cartilage. If the cells are maintained in a spherical shape, single stem cells can progress through a similar sequence. The actin cytoskeleton is implicated in the regulation of chondrogenesis since conditions that favor its disruption promote chondrogenesis and conditions that favor actin assembly inhibit chondrogenesis. Since a number of extracellular matrix receptors mediate effects of the extracellular matrix on cytoskeletal organization and some of these receptors are developmentally regulated, it is proposed that matrix receptor expression plays a central role in the divergence of connective tissue cells during development.