Summary
A method for preparing chromosomes that included enzyme maceration and subsequent flame-drying allowed us to easily detect satellite association in the mitotic cells ofNothoscordum fragrans (2 n=19), which has six acrocentric nucleolar chromosomes in its chromosome complement. Of 593 metaphase plates examined, approximately 60% had satellite association. The number of chromosomes involved in the association varied from two to six, and the incidence decreased as the number of chromosomes involved in the association increased. Comparison of the same chromosomes stained with Giemsa and subsequently with silver demonstrated that the nucleolar organizing regions (NORs) that responded almost negatively to Giemsa and positively to silver was responsible for satellite association. The nucleoli may strongly correlate with satellite association since persistent nucleoli associated with a few metaphase chromosomes were sometimes found and the nucleoli had a strong tendency to fuse with each other at interphase. Four types of acrocentric chromosomes could be discriminated on the basis of the bands negatively staining with Hoechst. All four types were involved in satellite association and there were significant deviations from the expectation for random participation in the association.
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Sato, S., Matsumoto, E. & Kuroki, Y. Satellite association of the nucleolar chromosomes in a plant. Protoplasma 108, 139–147 (1981). https://doi.org/10.1007/BF01276888
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DOI: https://doi.org/10.1007/BF01276888