CHROMOSOME MICROMANIPULATION: III. Spindle Fiber Tension and the Reorientation of Mal-Oriented Chromosomes

doi:10.1083/jcb.43.1.40

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ARTICLE

CHROMOSOME MICROMANIPULATION

: III. Spindle Fiber Tension and the Reorientation of Mal-Oriented Chromosomes

R. Bruce Nicklas ¹ and Carol A. Koch ¹

¹ From the Department of Zoology, Duke University, Durham, North Carolina 27706

Kinetochore reorientation is the critical process ensuringnormal chromosome distribution. Reorientation has been studiedin living grasshopper spermatocytes, in which bivalents withboth chromosomes oriented to the same pole (unipolar orientation)occur but are unstable: sooner or later one chromosome reorients,the stable, bipolar orientation results, and normal anaphasesegregation to opposite poles follows. One possible source ofstability in bipolar orientations is the normal spindle forcestoward opposite poles, which slightly stretch the bivalent.This tension is lacking in unipolar orientations because allthe chromosomal spindle fibers and spindle forces are directedtoward one pole. The possible role of tension has been testeddirectly by micromanipulation of bivalents in unipolar orientationto artificially create the missing tension. Without exception,such bivalents never reorient before the tension is released;a total time "under tension" of over 5 hr has been accumulatedin experiments on eight bivalents in eight cells. In controlexperiments these same bivalents reoriented from a unipolarorientation within 16 min, on the average, in the absence oftension. Controlled reorientation and chromosome segregationcan be explained from the results of these and related experiments.

Submitted on March 6, 1969
Revised on May 19, 1969

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