Towards a unifying model for the metaphase/anaphase transition.

The term mitosis actually covers a complex sequence of events at the level of the cell membrane, the cytoplasm, the nuclear membrane and the chromosomes; recently attention has been focused more and more on the checkpoints that control their orderly progression. The term 'checkpoint' refers here to the inhibitory pathways that coordinate coupling between the sequence of events, ensuring dependence of the initiation of each upon successful completion of others. This paper will mainly focus upon the possible checkpoint which controls a brief but essential step, dissociation of the sister chromatids into two identical chromosomes. This step will be called the metaphase/anaphase transition. First, the molecular components that are important in metaphase/anaphase transition will be reviewed: accurate segregation of sister chromatids between the daughter cells is dependent on coordinated interaction of centrosomes, centromeres, kinetochores, spindle fibres, topoisomerases, proteolytic processes and motor proteins. Deficiencies in or impairment of any of these structures or in their control systems may lead to a more or less important genomic imbalance. A model combining the ultrastructural components, the molecular components and the controlling molecules will be proposed. The unifying concept emerging from this synthesis indicates that sister chromatids separate independently of the tubulin fibres, as a result of proteolytic processes controlled by the anaphase promoting complex. The spindle fibres are thus necessary to move the separated chromatids to the spindle poles but probably not to initiate separation. A number of remaining questions are also highlighted.