Holokinetic composite chromosomes with ?diffuse? kinetochores in the micronuclear mitosis of a heterotrichous ciliate

Abstract

During micronuclear mitosis of the heterotrichous ciliate Nyctotherus ovalis Leidy rod-shaped composite chromosomes are formed by lateral association of telokinetic chromosomes. The formation of these composite chromosomes seems to be a highly ordered process since only nuclei with either 18 or 24 such chromosomes can be observed, and nuclei with the same chromosome number show a similar length distribution of their chromosomes. Further, these data indicate that we examined two otherwise indistinguishable races. During metaphase the composite chromosomes become arranged in the spindle equator in a holokinetic fashion, their entire poleward surfaces being covered by kinetochore material. These “diffuse” kinetochores have a trilaminar appearance comparable to those of monokinetic chromosomes. Their electron density after employing Bernhard's procedure revealed the same ribonucleoprotein distribution as reported for the localized kinetochores formed during the extranuclear mitosis in other cells. During early anaphase the outer kinetochore layer remains continuous while the individual chromosomes in the composite group show a tendency to separate leaving chromatin-free spaces of about 40 nm diameter. Kinetochore microtubules which are still anchored in the outer kinetochore layer seem to elongate and to extend into the interpolar spindle region predominantly through these “holes” in the chromatin. These observations suggest a like polarity of kinetochore and interpolar microtubules in the polar spindle region while microtubules in the interpolar space seem to interdigitate in an antiparallel fashion. The activity of the kinetochore to act as a microtubule-organizing center (MTOC) seems to be modulated by the chromatin underlying the outer kinetochore layer which may prevent further outgrowth of kinetochore microtubules.