Alpha actinin distribution and extracellular matrix products during somitogenesis and neurulation in the chick embryo

Cellular aspects of somite formation in vertebrates

Vertebrate segmentation, the process that generates a regular arrangement of somites and thereby establishes the pattern of the adult body and of the musculoskeletal and peripheral nervous systems, was noticed many centuries ago. In the last few decades, there has been renewed interest in the process and especially in the molecular mechanisms that might account for its regularity and other spatial-temporal properties. Several models have been proposed but surprisingly, most of these do not provide clear links between the molecular mechanisms and the cell behaviours that generate the segmental pattern. Here we present a short survey of our current knowledge about the cellular aspects of vertebrate segmentation and the similarities and differences between different vertebrate groups in how they achieve their metameric pattern. Taking these variations into account should help to assess each of the models more appropriately.

Cross-Talk Between Extracellular Matrix and Skeletal Muscle: Implications for Myopathies

Skeletal muscle (SM) comprises around 40% of total body weight and is among the most important plastic tissues, as it supports skeletal development, controls body temperature, and manages glucose levels. Extracellular matrix (ECM) maintains the integrity of SM, enables biochemical signaling, provides structural support, and plays a vital role during myogenesis. Several human diseases are coupled with dysfunctions of the ECM, and several ECM components are involved in disease pathologies that affect almost all organ systems. Thus, mutations in ECM genes that encode proteins and their transmembrane receptors can result in diverse SM diseases, a large proportion of which are types of fibrosis and muscular dystrophy. In this review, we present major ECM components of SMs related to muscle-associated diseases, and discuss two major ECM myopathies, namely, collagen myopathy and laminin myopathies, and their therapeutic managements. A comprehensive understanding of the mechanisms underlying these ECM-related myopathies would undoubtedly aid the discovery of novel treatments for these devastating diseases.

Avian fissura prima: differential accumulation of extracellular matrix at a fold

Extracellular matrix components that flank the fissura prima, a primary surface infolding of the cerebellum in birds and mammals, were examined in the embryonic chick using light and transmission electron microscopy. Cerebella dissected from Day 10 embryos were perfused with a paraformaldehyde-glutaraldehyde-tannic acid primary fixative and sectioned in the sagittal plane through the mid-vermis. Ultrastructural analysis revealed a distinct, continuous basal lamina separating the organ parenchyma (epithelia) from pia mater (mesenchyme) at the fissure surface (arbitrarily labeled; fissure floor, folia wall, and folia apex). The basal lamina was significantly thicker (P < 0.001) at the fissure floor compared to that found at the folia wall, which was significantly thicker (P < 0.001) than that observed at the folia apex. Folds in the basal lamina were observed exclusively at the fissure floor. Surface-associated collagen fibrils were distributed in an aligned, relatively dense manner at the fissure floor, compared with fibrils observed in various orientations and widely separated or absent at the folia wall and folia apex. Metachromasia was more pronounced in the fissure floor than in either the folia wall or folia apex in methylene blue-stained tissue sections. Together, the thicker, folded basal lamina and densely aligned collagen fibrils at the fissure floor provide a chemical rationale for this color change. These findings suggest that the differential accumulation of extracellular matrix at the fissura prima is positioned to play a structural and/or biochemical role in the maintenance of this fold.

Cellular mechanisms of neural fold formation and morphogenesis in the chick embryo

The mechanisms underlying neural fold formation and morphogenesis are complex, and how these processes occur is not well understood. Although both intrinsic forces (i.e., generated by the neuroepithelium) and extrinsic forces (i.e., generated by non-neuroepithelial tissues) are known to be important in these processes, the series of events that occur at the neural ectoderm-epidermal ectoderm (NE-EE) transition zone, resulting in the formation of two epithelial layers from one, have not been fully elucidated. Moreover, the region-specific differences that exist in neural fold formation and morphogenesis along the rostrocaudal extent of the neuraxis have not been systematically characterized. In this study, we map the rostrocaudal movements of cells that contribute to the neural folds at three distinct brain and spinal cord levels by following groups of dye-labeled cells over time. In addition, we examine the morphology of the neural folds at the NE-EE transition zone at closely-spaced temporal intervals for comparable populations of neural-fold cells at each of the three levels. Finally, we track the lateral-to-medial displacements that occur in the epidermal ectoderm during neural groove closure. The results demonstrate that neural fold formation and morphogenesis consist of a series of processes comprising convergent-extension movements, as well as epithelial ridging, kinking, delamination, and apposition at the NE-EE transition zone. Regional differences along the length of the neuraxis in the respective roles of these processes are described.

Chicken Pax-1 gene: structure and expression during embryonic somite development

Recent mouse genetic studies have implicated Pax-1, a paired-box-containing gene, in sclerotomal differentiation and vertebral body formation. To investigate Pax-1 function in somitic sclerotomal differentiation in the chick embryo, we have cloned the chicken Pax-1 gene, and its full length cDNA, and characterized its temporal and spatial expression pattern during somite development. Sequence analysis shows that chicken Pax-1 is highly homologous to murine and human Pax-1 genes with respect to the putative DNA-binding paired-box domain and the octapeptide domain. Northern analysis using probes derived from the paired-box domain and a unique non-paired box sequence of chicken Pax-1 detected 2-kb mRNA transcript. The expression profiles of Pax-1 were examined by in situ hybridization and Northern analysis. The first detectable expression of Pax-1 is seen in the most caudal epithelial somite. As the somite matures, Pax-1 expression takes on a medial distribution, thus corresponding to but preceding the emergence of the sclerotome. In the more mature, rostral somites (stage V and older), Pax-1 expression is found to be progressively localized first to the ventral-medial regions, and then to the caudal-ventral-medial quadrant of the mature somite. This pattern strongly supports the notion that Pax-1 expression is involved in somitogenesis and sclerotomal differentiation, and that it is subsequently a characteristic of the caudal half of the sclerotome, the presumptive precursor of vertebral cartilage. Northern analysis substantiated this expression profile and further revealed that the level of somitic Pax-1 expression increases as a function of embryonic development. Finally, we subjected chicken embryos to controlled heat shock treatment to perturb somite formation and segmentation. The pattern of Pax-1 expression in the anomalous somitic structures generated by controlled heat shock further supports a functional role for Pax-1 in somite development.

Valproic acid-induced somite teratogenesis in the chick embryo: relationship with Pax-1 gene expression

The repeated pattern of the axial skeleton results from the segmentation and re-segmentation of the mesodermally derived somites. During these early events of somite development, the vertebrate embryonic axial skeleton is most susceptible to the teratogenic effects of a variety of pharmaceutical and environmental agents. One example is the anticonvulsant drug valproic acid (VPA), which has been shown to cause craniofacial and minor and major skeletal defects in human and animal embryos. We hypothesize that a candidate set of molecular targets of teratogens are the Pax family of pattern-forming genes, specifically Pax-1, which has been previously demonstrated to be an important regulator of axial skeletal patterning at the somite level. In this study, early developmental stage chick embryos were treated with VPA and dose-dependent malformations in somite development were observed. Two classes of anomalies were evident: class I included discrete sites of somitic fusions or mis-segmentation, and Class II included large areas of disorganized somite patterning. Northern blot analysis revealed a decreased level of Pax-1 expression in VPA-treated embryos. Whole mount in situ hybridization analysis showed that somite anomalies correlate spatially with regions of decreased Pax-1 expression. Finally, comparison of the VPA-induced somitic anomalies with those caused by gene-specific perturbation of Pax-1 gene expression through the use of an antisense oligonucleotide revealed significant similarities. Taken together, these results support the hypothesis that Pax-1 is a molecular target in VPA axial skeletal teratogenicity.

Urokinase expression during the epithelial-mesenchymal transformation of the avian somite

Early events in the morphogenesis of the axial skeleton involve an epithelial-mesenchymal transformation of the somites. Cells of the ventromedial wall of the somite (the sclerotome) migrate to regions surrounding the notochord and neural tube and condense to form the cartilage model of the vertebrae. Urokinase activity in the axial region of the quail embryo trunk was found to increase during these stages. In situ hybridization localized urokinase mRNA expression in this region and suggests an important role for this protease in the process of cell migration and matrix remodeling during development of the axial skeleton.

Migration of chick blastoderm under the vitelline membrane: the role of fibronectin

In the earliest stages of its development the chick blastoderm is a flattened disc at the surface of the yolk. It gradually increases in diameter, partially because the cells are rapidly proliferating, but also because the cells at the periphery (the margin of overgrowth) are migrating in a centrifugal direction. These cells utilize the inner surface of the vitelline membrane as their substratum. In the normal blastoderm, these cells at the edge of the spreading blastoderm are the only cells which are attached to the vitelline membrane. This investigation is concerned with the possible role played by fibronectin in the interaction between these migrating cells and the vitelline membrane. Chick blastoderms, explanted by the New (1955) technique have been treated with synthetic peptides that mimic the adhesive recognition signal of the fibronectin molecule. The pentapeptide GRGDS (containing the specific RGD cell adhesion sequence) caused the edge cells of the blastoderm to detach within minutes, and the expansion of the blastoderm was inhibited for about 4 hr. After this period there was gradual recovery and the cells reattached and spreading resumed. Examination of the margin of the blastoderm by scanning electron microscopy showed that cell processes were lost soon after treatment with GRGDS but concomitant with reattachment and the resumption of spreading, the cell processes reformed. The pentapeptide GRDGS (with the amino acids G and D inverted) produced a brief inhibition of spreading, but after an hour these blastoderms spread at the same rate as controls. Immunocytochemical staining with anti-fibronectin demonstrated that fibronectin was not only present at the interface of the edge cells and the vitelline membrane, but also between the epiblast and the hypoblast. These results indicate that tissue movement during blastoderm spreading is dependent upon fibronectin and that the specific RGD amino acid sequence, and presumably the VLA/integrin family of receptors, is involved in this embryonic morphogenetic movement.

Somitogenesis in the mouse embryo

This report describes the initiation of somitogenesis in the mouse embryo. Correlations are made with fibronectin distribution around the unsegmented mesoderm and the distribution of cytoskeletal elements within the cells as they undergo morphogenetic movements. The same temporal and topological changes in fibronectin, laminin, and cytoskeletal elements are seen in mouse somitogenesis as in the chick embryo. A notable exception is that the epithelial stage of somitogenesis in the mouse does not form a closed vesicle as it does in the chick. In the mouse the mesial portion of the forming somite does not become epithelial before the migration of sclerotomal cells.

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.

Stress fiber and cleavage furrow formation in living cells microinjected with fluorescently labeled alpha-actinin

alpha-Actinins, isolated from muscle and nonmuscle sources and labeled with various fluorescent dyes, were microinjected into living PtK2 cells during interphase to observe the reformation of stress fibers following cell division. Fluorescently labeled ovalbumin and bovine serum albumin were also injected as control proteins. alpha-Actinin was incorporated into stress fibers within 5 minutes after injection and remained present in the fibers for up to 11 days. The pattern of incorporation was the same regardless of whether the alpha-actinin was isolated from muscle or nonmuscle tissues or whether it was labeled with fluorescein, Lucifer Yellow, or rhodamine dyes. In contrast, neither labeled ovalbumin nor bovine serum albumin were incorporated into stress fibers. When the injected cells entered prophase, all stress fibers disassembled, resulting in a distribution of the fluorescent alpha-actinin throughout the cytoplasm. During cytokinesis, the fluorescent alpha-actinin was concentrated in the broad area between the separated chromosomes and along the edge of the cell in the cleavage area. Within 10 minutes after the completion of cleavage, the first fluorescent stress fibers reformed parallel to the spreading edges of the daughter cells and in close association with the midbody with a concomitant loss of alpha-actinin in the former cleavage furrow. Additional fibers formed adjacent to these first stress fibers. In some cases, new stress fibers formed between two existing stress fibers and some stress fibers moved up to 4 micron apart from one another in the course of 2 hours. Thus, fluorescent alpha-actinin, injected into living cells, undergoes the same cyclical changes in distribution as endogenous alpha-actinin during the cell cycle: from stress fibers to cleavage furrow and back to stress fibers.