The embryo of the nematode Caenorhabditis elegans is surrounded by an inconspicuous inner vitelline membrane and a prominent outer chitinous eggshell proper. We demonstrate that the complete removal of the chitinous eggshell does not interfere with successful development to yield a normal worm. The same result can be obtained when the vitelline membrane is penetrated with laser microbeam irradiation of only the eggshell proper, gently enough to permit its resealing after a while. However, when large holes are made into the eggshell the concomitantly penetrated vitelline membrane does not reseal. While early development is quite normal under these conditions, gastrulation is defective in that gut precursor cells do not migrate in properly, eventually leading to embryonic arrest. This suggests a crucial role for pattern formation of the "micro-environment" around the embryo preserved by the intact vitelline membrane. Removing both eggshell and vitelline membrane results in a string-like arrangement of founder cells and subsequent grossly abnormal cell patterns. Our experiments support the idea that the prominent eggshell proper just functions as a mechanical protection while the thin vitelline membrane directly or indirectly serves as a necessary control element affecting the positions of cells which to begin with are determined by the orientation of the cleavage spindle.
Our earlier studies on embryonic arrest mutants of C. elegans had indicated that early deviations from the normal temporal and spatial pathway of development lead to monstrous terminal phenotypes with little resemblance to a hatched juvenile. To analyze more directly the roles of different parameters for cellular pattern formation, various experiments with a laser microbeam have now been performed and are described in this and the accompanying paper. By ablating early blastomeres we demonstrate here that the establishment of certain cell lineages is not necessary for the generation of a hatching juvenile. However, no replacement of missing cells was observed in these cases, and the resultant animals lacked those structures which are normally produced by the ablated cells. We found that retardation of cell cycle periods in certain cell lineages and thus a change in the normal order of cell divisions is compatible with development to a hatching juvenile. This is also true when, after irradiation of gut precursor cells, their inward migration is considerably delayed. Our results demonstrate that the invariant pattern of early nematode embryogenesis is not a necessary prerequisite for normal development. Studying parameters necessary for gastrulation we found that after irradiation leading to prolonged cell cycle periods the undivided gut founder cell itself rather than its two daughters moves into the center of the embryo. We removed individual early blastomeres and tested whether the typical inward movement of gut precursors still took place. Our results show that the presence of specific neighboring founder cells is not required, indicating that prospective gut cells reduce their cohesive contacts with adjacent blastomeres prior to the onset of gastrulation.
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