Library

Notes: Summary In the chick embryo, the tail bud reaches its maximum length at about stage 22 of Hamburger and Hamilton, after which it starts to regress. By this stage the neural tube and notochord extend right to the tip of the tail, but the somites do not do so, the terminal tail bud mesoderm never becoming segmented. The investigation is concerned with analysing why this mesoderm fails to segment. When tail buds were explanted to the chorio-allantoic membrane, they continued to form somites only until the “correct” number had segmented, i.e., the tail bud formed no more somites when isolated from the embryo than it would have formed if undisturbed. Morphological studies suggest that in the normal embryo massive cell death overtakes the tail bud mesoderm before it can segment. It is suggested therefore that cell death may be a contributory factor in preventing segmentation.

Notes: Summary The development of the ventricular conducting tissue of the embryonic chicken heart has been studied using a previous finding that morphologically recognizable atrial conducting tissue coexpresses the atrial and the ventricular myosin isoforms. It is found that, by these criteria, at 9 days part of the ventricular conduction system consists of a myocardial ring located around the infundibula of the aorta and truncus pulmonalis. Part of this ring is formed by the retro-aortic root branch. The ring continues via the septal branch into the atrioventricular bundle and its branches, that all express both myosin isoforms. The retroaortic root branch could be traced back as a part of the myocardial wall of the truncus arteriosus at the 4 days embryonic stage. At the 16th day of development, the septal branch, atrioventricular bundle and left and right bundle branches no longer express the atrial isomyosin, but two bundles originating from the septal branch still express both isomyosins, one being the retro-aortic root branch, the other being only immunologically recognizable and directed to the ventral side of the truncus pulmonalis; this latter we call the pulmonary root branch. Both bundles are remnants of the myocardial ring.

Notes: Summary Lectins have been used extensively to detect changes in carbohydrate moieties on the surface of embryonic cells during early development. Peanut agglutinin (PNA) in particular has been used to investigate changes related to cell differentiation. PNA has also been used to differentiate between the rostral and caudal sclerotome halves which have been shown to be functionally different, with neural crest cells and neurites traversing only the rostral half during their migration. In this study, we have sectioned and stained chick embryos between 3 and 8 days of age with PNA to examine the distribution of PNA binding sites associated with the vertebral column during this period and also to determine the fates of the rostral and caudal sclerotome halves. Ultrastructural localisation of PNA-gold conjugate showed that binding sites for this lectin were present intracellularly and extracellularly both on cell surfaces and in the matrix. At the light microscope level, a clear banding pattern emerged after staining with PNA which consisted of alternating light and dark staining along the entire length of the vertebral axis of the embryo. In the younger embryos, a simple banding pattern emerged where the rostral sclerotome half of each segment stained only lightly while the caudal half stained darkly. This banding pattern was present throughout the 6 day period of development and could be traced continuously but grew more complex as the sclerotome cells migrated to surround the notochord and neural tube and as the dorsal root ganglia developed. The rostral sclerotome half was found to contribute to the caudal part of one vertebral body and its neural arch, while the caudal sclerotome half was found to contribute to the intervertebral disc, the rostral half of the next caudal vertebra, and part of its neural arch.

Notes: Abstract We examined the effects of transforming growth factor-β1 (TGFβ1) and a neutralizing monoclonal antibody on two phases of early chick embryo development: gastrulation and chondrogenesis. We carried out experiments in vivo and in vitro on mesoderm cells from the gastrulating embryo at day 1, and on sclerotome cells from day 3 embryos, having previously shown that this factor is present among these cells at these stages of development. Addition of the antibody to cultures of these cells produced a dose-dependent decrease in cell outgrowth and spreading and concomitantly reduced fibronectin deposition. In vivo studies of the effects of TGFβ1 on mesoderm during gastrulation were carried out by grafting beads carrying this agent into gastrulating embryos. We used beads of ion-exchange resin as well as hydrolysed polyacrylamide, and found that the grafts produced an accumulation of mesoderm cells around the implant and, at later stages, the formation of enlarged somites. There was no effect on embryonic axis formation. Studies of bromodeoxyuridine (BrdU) incorporation indicated that the mesoderm accumulation was due, at least in part, to an increase in cell proliferation. However, examination of the effect of TGFβ1 on BrdU incorporation by mesoderm during gastrulation and sclerotome cells in vitro indicated in inhibition of cell proliferation, an inconsistency explained in terms of the variation between the in vivo and in vitro conditions. We conclude that TGFβ1 is both appropriately located, and is able, to influence cell proliferation among the mesodermal cell populations during early development, and that this effect contributes to the overall control of mesodermal morphogenesis. Chondrogenesis was studied in vitro using micromass cocultures of sclerotome cells with notochordon a permeable substratum. Under these conditions, the addition of TGFβ1 caused an increase in the deposition of Alcian blue-stainable material, indicating a stimulation of chondrogenesis. We suggest that this result, coupled with the previous demonstration that TGFβ1 is present among the sclerotome cells in the embryo at this time, supports the contention that this factor exerts a regulatory effect on sclerotome cell differentiation.

Notes: Abstract This paper reviews the evidence indicating possible roles for tumour necrosis factor-alpha (TNFα) in development. It is proposed that TNFα may have essentially three major roles during embryonic development, which may be analogous to its roles in the immune system and during inflammation: a role in programmed cell death; a role as a cellular growth and differentiation factor; and also a role in the remodelling of extracellular matrix, and the regulation of cell adhesion molecules and integrins. The concept of the existence of a cytokine array during embryogenesis, analogous to that occurring in inflammation, is discussed, as well as potential roles for TNFα in the induction of ubiquitin; protective mechanisms embryonic cells may employ against TNFα-mediated cytotoxicity; and a consideration of the role TNFα may play in a “free radical theory of development”.

Notes: Abstract  Focal adhesion kinase (pp125FAK or FAK) is a protein tyrosine kinase which is associated with intracellular signalling cascades which are initiated when the integrin family of cell adhesion molecules engage extracellular matrix molecules. In cultured cells, this molecule is physically associated with focal adhesions, which are well-defined regions of intimate cell-to-substratum adhesion. In this location, it interacts with other proteins of the focal adhesion to activate intracellular signalling events associated with cell adhesion. The in vitro expression of FAK and its level of phosphorylation appear to be related to several physiological phenomena, including cell spreading, cell differentiation, cell locomotion and cell death. Because these phenomena are all of critical importance during morphogenesis, and because FAK is expressed in embryonic cells, evidence has been accumulating to indicate that FAK may be an important modulator of developmental processes. In this review, this evidence is surveyed together with evidence from analogous situations, such as tumour cell migration and invasiveness. Although evidence suggesting a role for FAK in morphogenesis is accumulating, current uncertainties regarding its cytoplasmic location and its molecular interactions in vivo make it difficult to reach definitive conclusions regarding the significance of its contributions to developmental processes.

Notes: Summary In the chick embryo the final number of somites is achieved at about stage 22 of Hamburger and Hamilton. By this time the neural tube and notochord have reached the tip of the tail bud but some paraxial mesoderm remains unsegmented. In this study using scanning electron microscopy we show that somitomeres are present in this mesoderm. This indicates that the terminal paraxial mesoderm of the tail bud may have the potential to form supplementary somites, though we do not as yet know what prohibits the completion of segmentation to the tip.

Notes: Summary In a number of species, the floor plate of the developing neural tube and spinal cord has been ascribed specialized functions associated with the patterning of neuronal differentiation. The differentiation of the floor plate itself is believed to be closely related to the presence of the underlying notochord. Grafting experiments have previously shown that in the chick embryo an implanted segment of notochord is capable of inducing the adjacent host neural plate or neural tube to produce an additional floor plate, although the inductive effect diminishes with increasing age of the host. We have examined the potential of notochord to promote the appearance of floor plate-like structures from neural tube tissue in culture. To facilitate this, it was necessary initially to examine the immunoreactivity of the early neural tube and floor plate in situ and in vitro with a panel of antibodies to identify a suitable marker for floor plate differentiation in vitro. In situ, the differentiation of the floor plate was characterized by a lack of immunoperoxidase staining with antibody to neurofilaments and the monoclonal antibody HNK-1 throughout the period examined. This distinguished the floor plate from other regions of the neural tube, and was in contrast to its conspicuous affinity for antibodies to N-CAM and highly sialylated N-CAM, which also stained several closely adjacent regions of the neural tube over the period examined. We also found that oligodendrocytes occurred both in the floor plate and in the flanking ventral neural tube, and that astrocytes were too poorly represented throughout the neural tube at the stages examined to be useful markers of floor plate differentiation. We therefore concluded that only the anti-neurofilament and the HNK-1 antibodies were potentially useful markers for floor plate differentiation. When these antibodies were tested on cells in culture, neural tube tissue showed the presence of neurofilament and HNK-1-positive neurites, while floor plate cultures showed few of these. These distributions were consistent with those demonstrated in situ. However, cells staining positively for N-CAM, sialylated N-CAM and the glial cell markers were relatively sparse in floor plate cultures, suggesting that these epitopes were not retained or were masked in cultured cells. As a result of these experiments, we selected the absence of neurofilament-positive cells as a marker for floor plate differentiation in culture. Co-culture of pieces of neural tube from 3-day embryos with notochord segments resulted in the suppression of neurofilament-positive neurite outgrowth from the former, and the consequent production of tissue with floor plate-like characteristics. The absence of neurites was most marked on the side of the neural tube tissue that was apposed to the notochord. Co-culture of neural tube with other tissues did not produce this effect. We suggest that the neurite suppression by notochord in vitro is analogous to its activity in situ, and that neural tubes from 3-day embryos are still competent to respond to notochordal tissue.

Notes: Summary Intracellular microinjection of the fluorescent tracer Lucifer Yellow into mesoderm cells along the rostrocaudal axis of the early chick embryo has revealed compartments where the intercellular diffusion of dye, presumably via gap junctions, is restricted at the borders between groups of cells. Cells in the segmental plate were dye-coupled, as were cells forming the epithelial somites. However, dye-coupling was not observed between different somites, nor was it observed between the outer epithelial cells and the cells in the somitocoele. On dispersal of the somite, dermatome cells were dye-coupled. However, sclerotome cells were found to be divided into rostral and caudal compartments separated by a group of cells bordering the intrasclerotomal fissure (of von Ebner) that also exhibited dye-coupling, restricted primarily to cells along the fissure. Some of these compartment borders can be accounted for by the presence of a morphological barrier which reduces cell-cell contact, but others are more difficult to explain, as there appears to be extensive cell-cell contact across the border. This would be analogous to some compartments found in insects. Some of the compartments also have borders similar to those described by cell lineage studies. The results also indicate that dye-coupling becomes restricted in a spatial and temporal manner as the mesodermal cells mature.