SUMMARYTadpole larvae of the ascidian Halocynthia roretzi show morphological left-right asymmetry. The tail invariably bends towards the left side within the vitelline membrane. The structure of the larval brain is remarkably asymmetric. nodal, a conserved gene that shows left-sided expression, is also expressed on the left side in H. roretzi but in the epidermis unlike in vertebrates. We show that nodal signaling at the late neurula stage is required for stereotypic morphological left-right asymmetry at later stages. We uncover a novel mechanism to break embryonic symmetry, in which rotation of whole embryos provides the initial cue for leftsided expression of nodal. Two hours prior to the onset of nodal expression, the neurula embryo rotates along the anteriorposterior axis in a counterclockwise direction when seen in posterior view, and then this rotation stops when the left side of the embryo is oriented downwards. It is likely that epidermis monocilia, which appear at the neurula rotation stage, generate the driving force for the rotation. When the embryo lies on the left side, protrusion of the neural fold physically prevents it from rotating further. Experiments in which neurula rotation is perturbed by various means, including centrifugation and sandwiching between glass, indicate that contact of the left epidermis with the vitelline membrane as a consequence of neurula rotation promotes nodal expression in the left epidermis. We suggest that chemical, and not mechanical, signals from the vitelline membrane promote nodal expression. Neurula rotation is also conserved in other ascidian species.
In spite of extensive knowledge on the structure and function of ascidian blood cells, little is known about their embryological origin. In the present investigation, the developmental fate of trunk lateral cells (TLCs) was explored using a specific monoclonal antibody. TLCs comprise a group of undefined embryonic cells of the ascidian Halocynthia roretzi, which arise from the A7.6 blastomeres of a 64‐cell embryo. The antigenicity first appeared at the middle tailbud stage in a pair of TLC‐clusters situated lateral to the brain stem of the bilaterally symmetrical embryo. The position and number of stained cells did not change during later embryogenesis until hatching. After hatching, the stained cells were found in the entire trunk region of the swimming larva. After metamorphosis, cells that expressed the antigen were present within the coelom and within the tunic layer of the juvenile. In addition, the antibody stained adult basophilic blood cells. These observations suggest a relationship of this group of embryonic cells with the prospective blood forming mesenchymal cells.
Specification of the mammalian left-right (L-R) axis is controlled by fluid flows in the embryonic node, a ciliated pit like structure located at the distal tip of the mouse embryo. Nodal cilia rotate so as to cause a leftward fluid flow-this has been experimentally demonstrated to control embryonic sidedness.
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