Computer simulations reveal mechanisms that organize nuclear dynein forces to separate centrosomes

Centrosome separation along the surface of the nucleus at the onset of mitosis is critical for bipolar spindle assembly. Dynein anchored on the nuclear envelope is known to be important for centrosome separation, but it is unclear how nuclear dynein forces are organized in an anisotropic manner to promote the movement of centrosomes away from each other. Here we use computational simulations of Caenorhabditis elegans embryos to address this fundamental question, testing three potential mechanisms by which nuclear dynein may act. First, our analysis shows that expansion of the nuclear volume per se does not generate nuclear dynein-driven separation forces. Second, we find that steric interactions between microtubules and centrosomes contribute to robust onset of nuclear dynein-mediated centrosome separation. Third, we find that the initial position of centrosomes, between the male pronucleus and cell cortex at the embryo posterior, is a key determinant in organizing microtubule aster asymmetry to power nuclear dynein-dependent separation. Overall our work reveals that accurate initial centrosome position, together with steric interactions, ensures proper anisotropic organization of nuclear dynein forces to separate centrosomes, thus ensuring robust bipolar spindle assembly.

Mechanisms of centrosome separation in C. elegans

Alessandro De Simone

Centrosomes are the major microtubule organizing centers of animal cells. The two centrosomes present at the onset of mitosis must separate in a timely fashion along the nuclear envelope to ensure proper bipolar spindle assembly and thus genome stability. Microtubuleassociated motors of the kinesin-5 family are required for centrosome separation in several systems, but are partially redundant or entirely dispensable in others, where the minus-end directed motor dynein plays an important role. The mechanisms by which dynein powers centrosome separation are incompletely understood. Furthermore, the nature of the symmetry-breaking mechanisms that imbalance the forces acting on centrosomes to favor theirmovement away from each other are not known. We addressed these questions using a combination of 3D time-lapse microscopy, image processing and computational modeling to dissect centrosome separation in the polarized one-cell C. elegans embryo that entirely relies on dynein for this process. First, we have characterized the quantitative features of centrosome separation in the wild-type. Next, we compared centrosome separation between wild-type and mutant/RNAi conditions. Our analysis revealed that centrosome separation is powered by the combined action of dynein at the nuclear envelope and at the cell cortex. Moreover, we demonstrated that cortical dynein requires actomyosin contractility to separate centrosomes. These observations suggest that cortical dynein acts by harnessing anterior-directed actomyosin cortical flows initiated earlier in the cell cycle by the centrosomes themselves. To confirmthismodel, we successfully tested experimentally two of its key predictions, namely that dynein complexes flow toward the anterior together with the cortex and that the velocity of centrosome separation correlates with that of the flow of the nearby cortex. Taken together, these results demonstrate that centrosome separation is driven by nuclear and cortical dynein, where the latter acts by transmitting forces produced by the cortical actomyosin flow. To test whether this model is sufficient to explain centrosome separation, we developed a 3D computationalmodel of cytoskeleton dynamics. Indeed, predicted centrosome separation agrees quantitatively with the experimental observations in wild-type and mutant/RNAi conditions. Moreover, the qualitative predictions of the model are robust for parameter changes. Furthermore, computational simulations demonstrate that forces are intrinsically organized to move centrosomes away from each other without the need of any extrinsic symmetry-breaking mechanism. Indeed, in the case of nuclear dynein-driven separation, the position of centrosomes between the nuclear envelope and the cortex results in an asymmetric microtubule aster that leads to centrosome outward movement. In the case of cortical dynein, cortical flows are triggered by centrosomes and always move away from them, such that their forces are always directed to separate centrosomes. Therefore, this separation mechanism functions irrespective of the initial position of centrosomes along the cortex. In conclusion, in this thesis we uncover a novel organizing principle in which dynein, coupled with cell geometry and flow pattern, serves to robustly separate centrosomes and thus ensure genome stability.

EPFL2016

lis-1 is required for dynein-dependent cell division processes in C. elegans embryos

Pierre Gönczy

We investigated the role of the evolutionarily conserved protein Lis1 in cell division processes of Caenorhabditis elegans embryos. We identified apparent null alleles of lis-1, which result in defects identical to those observed after inactivation of the dynein heavy chain dhc-1, including defects in centrosome separation and spindle assembly. We raised antibodies against LIS-1 and generated transgenic animals expressing functional GFP-LIS-1. Using indirect immunofluorescence and spinning-disk confocal microscopy, we found that LIS-1 is present throughout the cytoplasm and is enriched in discrete subcellular locations, including the cell cortex, the vicinity of microtubule asters, the nuclear periphery and kinetochores. We established that lis-1 contributes to, but is not essential for, DHC-1 enrichment at specific subcellular locations. Conversely, we found that dhc-1, as well as the dynactin components dnc-1 (p150Glued) and dnc-2 (p50/dynamitin), are essential for LIS-1 targeting to the nuclear periphery, but not to the cell cortex nor to kinetochores. These results suggest that dynein and Lis1, albeit functioning in identical processes, are targeted partially independently of one another.

2004

Clathrin regulates centrosome positioning by promoting acto-myosin cortical tension in C. elegans embryos

Alessandro De Simone, Pierre Gönczy, Kalyani Thyagarajan, Sylvain Träger

Regulation of centrosome and spindle positioning is crucial for spatial cell division control. The one-cell Caenorhabditis elegans embryo has proven attractive for dissecting the mechanisms underlying centrosome and spindle positioning in a metazoan organism. Previous work revealed that these processes rely on an evolutionarily conserved force generator complex located at the cell cortex. This complex anchors the motor protein dynein, thus allowing cortical pulling forces to be exerted on astral microtubules emanating from microtubule organizing centers (MTOCs). Here, we report that the clathrin heavy chain CHC-1 negatively regulates pulling forces acting on centrosomes during interphase and on spindle poles during mitosis in one-cell C. elegans embryos. We establish a similar role for the cytokinesis/apoptosis/RNA-binding protein CAR-1 and uncover that CAR-1 is needed to maintain proper levels of CHC-1. We demonstrate that CHC-1 is necessary for normal organization of the cortical acto-myosin network and for full cortical tension. Furthermore, we establish that the centrosome positioning phenotype of embryos depleted of CHC-1 is alleviated by stabilizing the acto-myosin network. Conversely, we demonstrate that slight perturbations of the acto-myosin network in otherwise wild-type embryos results in excess centrosome movements resembling those in chc-1(RNAi) embryos. We developed a 2D computational model to simulate cortical rigidity-dependent pulling forces, which recapitulates the experimental data and further demonstrates that excess centrosome movements are produced at medium cortical rigidity values. Overall, our findings lead us to propose that clathrin plays a critical role in centrosome positioning by promoting acto-myosin cortical tension.

Company Of Biologists Ltd2014

Mechanisms of centrosome separation in C. elegans

Alessandro De Simone

EPFL2016