Oded Khaner

The chick's marginal zone and primitive streak formation. I. Coordinative effect of induction and inhibition

A variety of transplantation experiments of posterior and lateral marginal zone fragments at stages X, XI, and XII have been carried out in order to test their relevance to the development of a primitive streak (PS). At the stages studied the marginal zone (MZ) was shown to behave as a ring-like gradient field, the maximal value of which was at the posterior end (PM). The PM was found to be capable at the same time of promoting the development of a PS and of suppressing the inductive potential of other regions of the MZ. By systematically evaluating inductive and suppressive capacities of PMs, at different developmental stages, it was found that both features are maximal at stage X. During stages XI and XII, both properties gradually decrease in the MZ and build up in the forming hypoblast.

The chick's marginal zone and primitive streak formation: II. Quantification of the marginal zone's potencies—Temporal and spatial aspects☆

When a posterior fragment of the chicks marginal zone (PM) was exchanged with equal sized lateral marginal zone fragment (LM), of the same blastoderm, its capacity to initiate an ectopic primitive streak (PS) was found to be both size and stage dependent. Good correlation was demonstrated between the areas of PM fragments and the number of cells they contained. In stage X blastoderms, PM fragments containing less than 1200 cells were incapable of initiating an ectopic PS. Transplanted PMs containing between 1200 and 1500 cells initiated a lateral ectopic PS in 50% of the cases, while in the other 50% a posterior PS developed from the original posterior side. PMs containing 1500 cells or more in all cases initiating an ectopic PS and inhibited the formation of a posterior PS. At stage XI, laterally transplanted PMs containing less than 1800 cells were not effective. Stage XI PMs containing 1800-2300 cells in some cases succeeded in initiating a lateral ectopic PS, in addition to the posterior one. Stage XI PMs containing 2300 cells or more invariably promoted the development of an ectopic PS, but were unable to suppress the formation of a posterior PS, so that two PSs developed in the same blastoderm, one posterior and one ectopic. When a stage XI PM fragment was laterally transplanted into a younger, stage X blastoderm, the minimal effective cell number needed to initiate an ectopic PS increased to at least 3000 cells, again without inhibiting the formation of a posterior PS. The inductive potential of a stage X PM is therefore at least twice that of a stage XI PM. The marginal zone belt of stage X blastoderms was checked for the decrease in its developmental potential from the posterior to the lateral side by evaluating its effect on the developmental expression of two competing stage X PMs, one located posteriorly and the other inserted laterally. The developmental expression of the laterally inserted PM was consistently inferior to that of the posterior PM. The developmental expression of each PM was not related to absolute size, but depended on the size ratio of lateral PM/posterior PM. When the ratio was 1.2 or less, only posterior PSs developed. When the ratio was 1.3-1.4, three different results were encountered: (1) only a posterior PS, (2) posterior plus lateral, and (3) only lateral PS. When the ratio was 1.5 or more, only a lateral PS developed, which suppressed the posterior PS.

The embryo-forming potency of the posterior marginal zone in stages X through XII of the chick☆

At stage X a small posterior marginal zone (PM) fragment, when transplanted into similar-size hole in the lateral marginal zone, can initiate the development of an ectopic axis. The laterally transplanted PM, inhibits the regeneration of an axis at the original posterior side from the lateral section of the marginal zone (LM) inserted to replace it. At stage XI both the axis-forming and inhibitory capacities of the PM fragment become weaker and an axis-forming capacity starts to build up anterior to the PM, resulting in the formation of two primitive streaks at 90 degrees to each other. At stage XII the change of potencies exhibited at stage XI is more pronounced, the ability of the transplanted PM to promote axis formation at the new site is lost, and an axis is formed from the original posterior side of the blastoderm.

Variation in anuran embryogenesis: Differences in sequence and timing of early developmental events

Comparative embryology of closely related species can shed light on the evolution of developmental processes. An important mechanism in the evolution of developmental processes, which can lead to significant changes in larval or adult form, is variation in the sequence and timing of developmental events. We compared the development of 12 species of anurans, including a wide taxonomic range as well as a number of congeneric species. The comparison consisted of monitoring a series of external morphological markers and histological markers. For each species we noted the timing of each of the markers, using a uniform parameter of normalized time. We compared the normalized time of each of these events among the species, as well as the sequence of the events. Our analysis revealed many differences in sequence and in timing of developmental events. We mapped these differences on a cladogram of the studied species, using sequence units as discrete characters. The differences do not seem to be connected to the phylogenetic relations between the species or to any obvious ecological factors. We suggest a hypothetical ancestral sequence of developmental events, and discuss the possible factors that could have caused the observed variations from the ancestral sequence.

Axis determination in the avian embryo

Publisher Summary This chapter describes the anatomical and morphological aspects of the early stages of chick development and a new consensus terminology. The dynamics of cell populations and the cell interactions during the early developmental stages are fundamental to the analysis of the gradual processes of axis determination in the chick embryo. Hence, the gradual steps that determine the bilateral symmetry of the embryo are examined, as will the sequential processes that establish the posterior–anterior axis of the embryo. This chapter mainly describes the developmental potential of the marginal zone and the role of the hypoblast in the formation of the primitive streak. In addition, issues concerning the molecular and cellular basis of mesoderm induction and formation in the chick embryo are discussed in this chapter. The formation of the axis in the avian embryo is a complex integrative and sequential process that produces highly organized axial structure from the fertilized egg. The unfertilized avian egg shows a distinct radial symmetry and is polarized along its animal-vegetal axis that was determined during oogenesis. The determination of the axis in the avian embryo is a multistep process at the molecular and cellular levels. The unfertilized avian egg shows a distinct radial symmetry. After the egg is fertilized, the bilateral symmetry of the embryo is determined, by the formation of the polarized area pellucid, during the intrauterine stages.

Limited left-right cell migration across the midline of the gastrulating avian embryo.

During avian development the earliest phase in which the avian embryo expresses axial features of a left-right axis is at the primitive streak stage. Until the stage of definitive primitive streak (streak 4 H&H), the axis seems to possess morphological bilateral symmetry. Morphological asymmetry begins only during the next few hours of incubation, with development of overt morphological and molecular asymmetry within Hensens node (stage 5 H&H). In this report, we present an experimental study aimed at following the pattern of cell movements during primitive streak formation and gastrulation of specific left-right regions from earlier stages of the avian embryo. To determine the origin of cells contributing to each side of the primitive streak, we applied the dye Lysinated-Rodamine-Dextran (LRD) to one half, either left or right, of the pre-streak blastoderm (stages X-XIII, EG&K). We tried to estimate the relative cell contribution to primitive streak formation, and to the three germ layers evolving during gastrulation in the context of the left-right axis. Moreover, we asked whether the midline serves as a border, that is, as a physiological barrier preventing cell passing during gastrulation. Our results demonstrate that on each side of the axis, either the right or the left, most of the cells originate from the same half of a pre-streak blastoderm, populate the same half of the PS and contribute to tissues largely confined to that particular side. However, along the primitive streak, a few cells were detected on the opposite side of the midline. Moreover, variation in the number of cells crossing the midline at specific regions along the primitive streak was found. Most crossing cells were located near the mid rostrocaudal extent of the primitive streak, from 25-85% of its length. At the posterior end of the primitive streak, fewer crossing cells were detected. At the anterior region of the PS, that is, within Hensens node, cells do not cross the midline. These results suggest that differences occur in the process of ingression along the rostrocaudal extent of the PS.