DIVISION IN THE DINOFLAGELLATE GYRODINIUM COHNII (SCHILLER): A New Type of Nuclear Reproduction

doi:10.1083/jcb.40.2.508

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ARTICLE

DIVISION IN THE DINOFLAGELLATE GYRODINIUM COHNII (SCHILLER)

: A New Type of Nuclear Reproduction

Donna F. Kubai ¹ and Hans Ris ¹

¹ From the Department of Zoology, University of Wisconsin, Madison, Wisconsin 53706

Dinoflagellates are of interest because their chromosomes resemblethe nucleoplasm of prokaryotes both chemically and ultrastructurally.We have studied nuclear division in the dinoflagellate Gyrodiniumcohnii (Schiller), using cells obtained from cultures undergoingphasic growth. Electron micrographs of serial sections wereused to prepare three-dimensional reconstructions of nucleiand chromosomes at various stages of nuclear division. Duringdivision, a complex process of invagination of the intact nuclearenvelope takes place at one side of the nucleus and resultsin the formation of parallel cylindrical cytoplasmic channelsthrough the nucleus. These invaginations contain bundles ofmicrotubules, and each of the bundles comes to lie in the cytoplasmof a cylindrical channel. Nuclear constriction occurs perpendicularto these channels without displacement of the microtubules.There are no associations between chromosomes and the cytoplasmicmicrotubules. In dividing cells most chromosomes become V-shaped,and the apices of the V's make contact with the membrane surroundingcytoplasmic channels. It is proposed that the membrane surroundingcytoplasmic channels in the dividing nucleus may be involvedin the separation of daughter chromosomes. Thus, dinoflagellatesmay resemble prokaryotes in the manner of genophore separationas well as in genophore chemistry and ultrastructure.

Submitted on September 5, 1968
Revised on October 2, 1968

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