Álvaro Tavares

Spatiotemporal control of mitosis by the conserved spindle matrix protein Megator

A putative spindle matrix has been hypothesized to mediate chromosome motion, but its existence and functionality remain controversial. In this report, we show that Megator (Mtor), the Drosophila melanogaster counterpart of the human nuclear pore complex protein translocated promoter region (Tpr), and the spindle assembly checkpoint (SAC) protein Mad2 form a conserved complex that localizes to a nuclear derived spindle matrix in living cells. Fluorescence recovery after photobleaching experiments supports that Mtor is retained around spindle microtubules, where it shows distinct dynamic properties. Mtor/Tpr promotes the recruitment of Mad2 and Mps1 but not Mad1 to unattached kinetochores (KTs), mediating normal mitotic duration and SAC response. At anaphase, Mtor plays a role in spindle elongation, thereby affecting normal chromosome movement. We propose that Mtor/Tpr functions as a spatial regulator of the SAC, which ensures the efficient recruitment of Mad2 to unattached KTs at the onset of mitosis and proper spindle maturation, whereas enrichment of Mad2 in a spindle matrix helps confine the action of a diffusible “wait anaphase” signal to the vicinity of the spindle.

The conserved mitotic kinase polo is regulated by phosphorylation and has preferred microtubule-associated substrates in Drosophila embryo extracts.

The Drosophila gene polo encodes a protein kinase required for progression through mitosis. Wild‐type polo protein migrates as a tight doublet of 67 kDa which is converted to a single band by phosphatase treatment, which also inactivates the kinase. We have determined putative polo substrates in a cell‐free system derived from mutant embryos. Exogenous polo protein kinase phosphorylates proteins of sizes 220 kDa, 85 kDa and 54 kDa, to a greater extent when added to extracts of polo(1)‐derived embryos compared with extracts of wild‐type embryos, which in both cases have been subject to mild heat treatment to inactivate endogenous kinases. Proteins of the same size are predominantly phosphorylated by the endogenous kinases present in wild‐type extracts, and are either not phosphorylated or are poorly phosphorylated in extracts of polo(1)‐derived embryos. We show that a specific monoclonal antibody to beta‐tubulin precipitates the phosphorylated 54 kDa protein together with an associated 85 kDa protein also phosphorylated by polo protein kinase. Moreover polo binds to an 85 kDa protein which is enriched in microtubule preparations. We discuss the extent to which these in vitro phosphorylation results reflect the effects of mutations in polo on microtubule behaviour during the mitotic cycle.

Mouse polo-like kinase 1 associates with the acentriolar spindle poles, meiotic chromosomes and spindle midzone during oocyte maturation

Abstract. We have examined the dynamics of the localisation of the polo-like kinase 1 (Plk1) during maturation of the mouse oocyte. Levels of Plk1 protein increase following germinal vesicle breakdown, at which time the enzyme begins to accumulate at discrete positions on the condensing chromosomes and, subsequently, at the poles of the meiotic spindle, which moves towards the cortex of the egg. Interestingly, at metaphase in both meiotic divisions, Plk1 shows a punctate localisation along the broad spindle poles. Moreover, the punctate distribution of Plk1 on the meiotic chromosomes appears at early anaphase to correspond to the centromeric regions. The protein relocates to the spindle midzone during late anaphase and then associates with the midbody at telophase. We have confirmed the specific pattern of immuno-localisation seen in fixed preparations by observing the distribution of Plk1 tagged with green fluorescent protein in living oocytes. We discuss the localisation of the enzyme in light of the structure of the spindle poles, which are known to lack centrioles, and the highly asymmetric nature of the meiotic divisions.

Mob1: defining cell polarity for proper cell division

Mob1 is a component of both the mitotic exit network and Hippo pathway, being required for cytokinesis, control of cell proliferation and apoptosis. Cell division accuracy is crucial in maintaining cell ploidy and genomic stability and relies on the correct establishment of the cell division axis, which is under the control of the cells environment and its intrinsic polarity. The ciliate Tetrahymena thermophila possesses a permanent anterior–posterior axis, left–right asymmetry and divides symmetrically. These unique features of Tetrahymena prompted us to investigate the role of Tetrahymena Mob1. Unexpectedly, we found that Mob1 accumulated in basal bodies at the posterior pole of the cell, and is the first molecular polarity marker so far described in Tetrahymena. In addition, Mob1 depletion caused the abnormal establishment of the cell division plane, providing clear evidence that Mob1 is important for its definition. Furthermore, cytokinesis was arrested and ciliogenesis delayed in Tetrahymena cells depleted of Mob1. This is the first evidence for an involvement of Mob1 in cilia biology. In conclusion, we show that Mob1 is an important cell polarity marker that is crucial for correct division plane placement, for cytokinesis completion and for normal cilia growth rates.

Mitotic protein kinases in Drosophila embryos.

Publisher Summary This chapter discusses the mitotic protein kinases in drosophila embryos. To understand the biological function of enzymes regulating cell cycle progression, it is necessary to study both cyclical changes in catalytic activity and physiological substrates. Although genetic approaches in Drosophila have identified genes encoding cell cycle regulatory protein kinases there have been few attempts to measure kinase activity in relation to the mitotic cycle in Drosophila. This is in part due to the lack of an efficient protocol for synchronizing cultured Drosophila cells and to the inability to achieve synchronous development of a population of embryos. This chapter describes assays that allows following the cyclical activity and to identify physiological substrates of the Drosophila mitotic protein kinase polo, but the approaches could equally well be used to follow other enzyme activities.