Spindle Position in Symmetric Cell Divisions during Epiboly Is Biology Diagrams Summary Proper spatial control of the cell division plane is essential to any developing organism. In most cell types, the relative size of the two daughter cells is determined by the position of the mitotic spindle within the geometry of the mother cell. We review the underlying mechanisms responsible for positioning of the mitotic spindle, both in cases where the spindle is placed in the Abstract The mechanical environment of a cell has a profound effect on its behaviour, from dictating cell shape to driving the transcription of specific genes. Recent studies have demonstrated that mechanical forces play a key role in orienting the mitotic spindle, and therefore cell division, in both single cells and tissues.
Abstract Accurate positioning of spindles is essential for asymmetric mitotic and meiotic cell divisions that are crucial for animal development and oocyte maturation, respectively. The predominant model for spindle positioning, termed "cortical pulling," involves attachment of the microtubule-based motor cytoplasmic dynein to the cortex, where it exerts a pulling force on microtubules that The direction in which a cell divides is determined by the orientation of its mitotic spindle at metaphase. Spindle orientation is therefore important for a wide range of developmental processes, ranging from germline stem cell division to epithelial tissue homeostasis and regeneration. In multiple cell types in multiple animals, spindle orientation is controlled by a conserved biological The spindle positioning checkpoint (SPOC) ensures the correct positioning of the mitotic spindle during cell division. Proper spindle alignment is crucial for successful mitotic exit and cytokinesis, as it determines the plane of cell division and ensures that sister chromatids are accurately segregated to daughter cells [34], [5].
Spindle Positioning by Cortical Pulling Forces Biology Diagrams
Zellag et al. use in situ live-cell imaging to show that mitotic spindles orient parallel to the tissue plane in the C. elegans germ line. They propose a mechanism wherein basal centrosome positioning in interphase and a cycle of LIN-5/NuMA cortical localization establishes and maintains proper germ cell spindle orientation during mitosis.
Abstract Accurate positioning of spindles is essential for asymmetric mitotic and meiotic cell divisions that are crucial for animal development and oocyte maturation, respectively. The predominant model for spindle positioning, termed "cortical pulling," involves attachment of the microtubule-based motor cytoplasmic dynein to the cortex, where it exerts a pulling force on microtubules
Force and the spindle: Mechanical cues in mitotic spindle orientation Biology Diagrams
The orientation of cell divisions regulates tissue architecture and cell fate and depends on mitotic spindle positioning, which is controlled by intracellular and extracellular cues. Building on
Proper spatial control of the cell division plane is essential to any developing organism. In most cell types, the relative size of the two daughter cells is determined by the position of the mitotic spindle within the geometry of the mother cell. We review the underlying mechanisms responsible for positioning of the mitotic spindle, both in cases where the spindle is placed in the center of
