THE ULTRASTRUCTURE OF A MAMMALIAN CELL DURING THE MITOTIC CYCLE

doi:10.1083/jcb.21.3.429

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ARTICLE

THE ULTRASTRUCTURE OF A MAMMALIAN CELL DURING THE MITOTIC CYCLE

Elliott Robbins M.D.¹ and Nicholas K. Gonatas M.D.¹

¹ From the Departments of Neurology and Pathology, Albert Einstein Medical College, New York

With a technique of preselecting the mitotic cell in the livingstate for subsequent electron microscopy, it has been possibleto examine the ultrastructure of the various stages of mitosiswith greater precision than has been reported previously. Theearly dissolution of the nuclear envelope has been found tobe preceded by a marked undulation of this structure withinthe nuclear "hof." This undulation appears to be intimatelyrelated to the spindle-forming activity of the centriole atthis time. Marked pericentriolar osmiophilia and extensive arraysof vesicles are also prominent at this stage, the former continuinginto anaphase. Progression of the cell through prophase is accompaniedby a disappearance of these vesicles. A complex that first makesits appearance in prophase but becomes most prominent in metaphaseis a partially membrane-bounded cluster of dense osmiophilicbodies. These clusters which have a circumferential distributionin the mitotic cell are shown to be derived from multivesicularbodies and are acid phosphatase-positive. The precise selectionof cells during the various stages of anaphase has made it possibleto follow chronologically the morphological features of theinitiation of nuclear membrane reformation. The nuclear membraneappears to be derived from polar aggregates of endoplasmic reticulum,and the process begins less than 2 minutes after the onset ofkaryokinesis. While formation of the nuclear envelope is initiatedon the polar aspects of the chromatin mass, envelope elementsappear on the equatorial aspect long before the polar elementsfuse. Apparently interfering with this fusion are continuousspindle tubules which traverse the chromatin mass in strikingdensity at characteristic points. Several cortical changes,also most pronounced in anaphase, have been described, as hasthe kinetochore which is seen to good advantage only in thisstage. The Golgi complex has been found to disappear both morphologicallyand histochemically during mitosis and to reappear rapidly intelophase. Evidence is presented which implicates the continuousspindle tubules in certain phases of chromosome movement.

Submitted on August 14, 1963

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