Using fast-acting temperature-sensitive mutants to study cell division in Caenorhabditis elegans.

Fast-acting temperature-sensitive (ts) mutations are powerful conditional tools for studying transient cellular processes such as cytokinesis. Fast-acting ts cytokinesis-defective mutants are functional at the permissive temperature; yet show a fully penetrant loss-of-function cytokinesis failure phenotype when upshifted to the restrictive temperature. Fast-acting ts mutations thus allow functional tunability and rapid and reversible protein inactivation by simply shifting the temperature at precise times throughout cell division. In this chapter, we describe several techniques and discuss various approaches for harnessing the power of fast-acting ts mutants to study cytokinesis in Caenorhabditis elegans using both simple passive heat transfer and more advanced fluidic-based thermal control systems. We also provide detailed protocols for standard dissection, mounting, and imaging of early worm embryos.

Cyclin E and its associated cdk activity do not cycle during early embryogenesis of the sea Urchin.

Female sea urchins store their gametes as haploid eggs. The zygote enters S-phase 1 h after fertilization, initiating a series of cell cycles that lack gap phases. We have cloned cyclin E from the sea urchin Strongylocentrotus purpuratus. Cyclin E is synthesized during oogenesis, is present in the germinal vesicle, and is released into the egg cytoplasm at oocyte maturation. Cyclin E synthesis is activated at fertilization, although there is no increase in cyclin E protein levels due to continuous turnover of the protein. Cyclin E protein levels decline in morula embryos, while cyclin E mRNA levels remain high. After the blastula stage, cyclin E mRNA and protein levels are very low, and cyclin E expression is predominant only in cells that are actively dividing. These include cells in the left coelomic pouch, which forms the adult rudiment in the embryo. The cyclin E present in the egg is complexed with a protein kinase. Activity of the cyclin E/cdk2 changes little during the initial cell cycles. In particular, cyclin E-cdk2 levels remain high during both S-phase and mitosis. Our results suggest that progression through the early embryonic cell cycles in the sea urchin does not require fluctuations in cyclin E kinase activity.

Cytoplasmic dynein/dynactin drives kinetochore protein transport to the spindle poles and has a role in mitotic spindle checkpoint inactivation.

We discovered that many proteins located in the kinetochore outer domain, but not the inner core, are depleted from kinetochores and accumulate at spindle poles when ATP production is suppressed in PtK1 cells, and that microtubule depolymerization inhibits this process. These proteins include the microtubule motors CENP-E and cytoplasmic dynein, and proteins involved with the mitotic spindle checkpoint, Mad2, Bub1R, and the 3F3/2 phosphoantigen. Depletion of these components did not disrupt kinetochore outer domain structure or alter metaphase kinetochore microtubule number. Inhibition of dynein/dynactin activity by microinjection in prometaphase with purified p50 "dynamitin" protein or concentrated 70.1 anti-dynein antibody blocked outer domain protein transport to the spindle poles, prevented Mad2 depletion from kinetochores despite normal kinetochore microtubule numbers, reduced metaphase kinetochore tension by 40%, and induced a mitotic block at metaphase. Dynein/dynactin inhibition did not block chromosome congression to the spindle equator in prometaphase, or segregation to the poles in anaphase when the spindle checkpoint was inactivated by microinjection with Mad2 antibodies. Thus, a major function of dynein/dynactin in mitosis is in a kinetochore disassembly pathway that contributes to inactivation of the spindle checkpoint.

Proper alignment and adjustment of the light microscope.

The light microscope is a basic tool for the cell biologist, who should have a thorough understanding of how it works, how it should be aligned for different applications (e.g., brightfield, phase-contrast, differential interference contrast, and fluorescence epi-illumination), and how it should be maintained as required to obtain maximum image-forming capacity and resolution. The principles of microscopy and step-by-step alignment and adjustment procedures are described in this unit.

The human SWI/SNF-B chromatin-remodeling complex is related to yeast rsc and localizes at kinetochores of mitotic chromosomes.

The SWI/SNF family of chromatin-remodeling complexes facilitates gene expression by helping transcription factors gain access to their targets in chromatin. SWI/SNF and Rsc are distinctive members of this family from yeast. They have similar protein components and catalytic activities but differ in biological function. Rsc is required for cell cycle progression through mitosis, whereas SWI/SNF is not. Human complexes of this family have also been identified, which have often been considered related to yeast SWI/SNF. However, all human subunits identified to date are equally similar to components of both SWI/SNF and Rsc, leaving open the possibility that some or all of the human complexes are rather related to Rsc. Here, we present evidence that the previously identified human SWI/SNF-B complex is indeed of the Rsc type. It contains six components conserved in both Rsc and SWI/SNF. Importantly, it has a unique subunit, BAF180, that harbors a distinctive set of structural motifs characteristic of three components of Rsc. Of the two mammalian ATPases known to be related to those in the yeast complexes, human SWI/SNF-B contains only the homolog that functions like Rsc during cell growth. Immunofluorescence studies with a BAF180 antibody revealed that SWI/SNF-B localizes at the kinetochores of chromosomes during mitosis. Our data suggest that SWI/SNF-B and Rsc represent a novel subfamily of chromatin-remodeling complexes conserved from yeast to human, and could participate in cell division at kinetochores of mitotic chromosomes.

The role of pre- and post-anaphase microtubules in the cytokinesis phase of the cell cycle.

The cytokinesis phase, or C phase, of the cell cycle results in the separation of one cell into two daughter cells after the completion of mitosis. Although it is known that microtubules are required for proper positioning of the cytokinetic furrow [1] [2], the role of pre-anaphase microtubules in cytokinesis has not been clearly defined for three key reasons. First, inducing microtubule depolymerization or stabilization before the onset of anaphase blocks entry into anaphase and cytokinesis via the spindle checkpoint [3]. Second, microtubule organization changes rapidly at anaphase onset as the mitotic kinase, Cdc2-cyclin B, is inactivated [4]. Third, the time between the onset of anaphase and the initiation of cytokinesis is very short, making it difficult to unambiguously alter microtubule polymer levels before cytokinesis, but after inactivation of the spindle checkpoint. Here, we have taken advantage of the discovery that microinjection of antibodies to the spindle checkpoint protein Mad2 (mitotic arrest deficient) in prometaphase abrogates the spindle checkpoint, producing premature chromosome separation, segregation, and normal cytokinesis [5] [6]. To test the role of pre-anaphase microtubules in cytokinesis, microtubules were disassembled in prophase and prometaphase cells, the cells were then injected with anti-Mad2 antibodies and recorded through C phase. The results show that exit from mitosis in the absence of microtubules triggered a 50 minute period of cortical contractility that was independent of microtubules. Furthermore, upon microtubule reassembly during this contractile C-phase period, approximately 30% of the cells underwent chromosome poleward movement, formed a midzone microtubule complex, and completed cytokinesis.

Microtubules suppress actomyosin-based cortical flow in Xenopus oocytes.

Several cell motility processes including cytokinesis and cell locomotion are dependent on the interplay of the microtubule and actomyosin cytoskeletons. However, because such processes are essentially visual phenomena, interactions between the two cytoskeletal systems have been difficult to study quantitatively. To overcome this difficulty, we have developed the Xenopus oocyte as an inducible, quantitative model system for actomyosin-based cortical flow and then exploited the strengths of this system to assess the relationship between microtubules and cortical flow. As in other systems, oocyte cortical flow entails: (1) redistribution of cortical filamentous actin (f-actin); (2) a requirement for actomyosin; (3) redistribution of cell surface proteins; (4) a requirement for cell surface protein mobility; and (5) directed movement of cortical organelles. Cortical flow rate in the oocyte system is inversely proportional to the level of polymeric tubulin and microinjection of free tubulin has no effect on the rate of cortical flow. Enhancement of microtubule polymerization inhibits cortical f-actin cable formation during cortical flow. The effects of microtubule depolymerization on cortical flow are rapid, independent of transcription or translation, independent of effects on the oocyte intermediate filament system, and independent of the upstream stimulus for cortical flow. The results show that the microtubules themselves, or a factor associated with them, suppress cortical flow, either by mechanically resisting flow, or by modulating the actomyosin cytoskeleton.