31 research outputs found
MAP1B regulates microtubule dynamics by sequestering EB1/3 in the cytosol of developing neuronal cells
MAP1B, a structural microtubule (MT)-associated protein highly expressed in developing neurons, plays a key role in neurite and axon extension. However, not all molecular mechanisms by which MAP1B controls MT dynamics during these processes have been revealed. Here, we show that MAP1B interacts directly with EB1 and EB3 (EBs), two core 'microtubule plus-end tracking proteins' (+TIPs), and sequesters them in the cytosol of developing neuronal cells. MAP1B overexpression reduces EBs binding to plus-ends, whereas MAP1B downregulation increases binding of EBs to MTs. These alterations in EBs behaviour lead to changes in MT dynamics, in particular overstabilization and looping, in growth cones of MAP1B-deficient neurons. This contributes to growth cone remodelling and a delay in axon outgrowth. Together, our findings define a new and crucial role of MAP1B as a direct regulator of EBs function and MT dynamics during neurite and axon extension. Our data provide a new layer of MT regulation: a classical MAP, which binds to the MT lattice and not to the end, controls effective concentration of core +TIPs thereby regulating MTs at their plus-ends
Protein 4.1R binds to CLASP2 and regulates dynamics, organization and attachment of microtubules to the cell cortex
The microtubule (MT) cytoskeleton is essential for many cellular processes, including cell polarity and migration. Cortical platforms, formed by a subset of MT plus-end-tracking proteins, such as CLASP2, and non-MT binding proteins such as LL5 beta, attach distal ends of MTs to the cell cortex. However, the mechanisms involved in organizing these platforms have not yet been described in detail. Here we show that 4.1R, a FERM-domain-containing protein, interacts and colocalizes with cortical CLASP2 and is required for the correct number and dynamics of CLASP2 cortical platforms. Protein 4.1R also controls binding of CLASP2 to MTs at the cell edge by locally altering GSK3 activity. Furthermore, in 4.1R-knockdown cells MT plus-ends were maintained for longer in the vicinity of cell edges, but instead of being tethered to the cell cortex, MTs continued to grow, bending at cell margins and losing their radial distribution. Our results suggest a previously unidentified role for the scaffolding protein 4.1R in locally controlling CLASP2 behavior, CLASP2 cortical platform turnover and GSK3 activity, enabling correct MT organization and dynamics essential for cell polarity
Mammalian CLASP1 and CLASP2 cooperate to ensure mitotic fidelity by regulating spindle and kinetochore function
CLASPs are widely conserved microtubule plus-end–tracking proteins with essential roles in the local regulation of
microtubule dynamics. In yeast, Drosophila, and Xenopus, a single CLASP orthologue is present, which is required for
mitotic spindle assembly by regulating microtubule dynamics at the kinetochore. In mammals, however, only CLASP1
has been directly implicated in cell division, despite the existence of a second paralogue, CLASP2, whose mitotic roles
remain unknown. Here, we show that CLASP2 localization at kinetochores, centrosomes, and spindle throughout mitosis
is remarkably similar to CLASP1, both showing fast microtubule-independent turnover rates. Strikingly, primary
fibroblasts from Clasp2 knockout mice show numerous spindle and chromosome segregation defects that can be partially
rescued by ectopic expression of Clasp1 or Clasp2. Moreover, chromosome segregation rates during anaphase A and B are
slower in Clasp2 knockout cells, which is consistent with a role of CLASP2 in the regulation of kinetochore and spindle
function. Noteworthy, cell viability/proliferation and spindle checkpoint function were not impaired in Clasp2 knockout
cells, but the fidelity of mitosis was strongly compromised, leading to severe chromosomal instability in adult cells.
Together, our data support that the partial redundancy of CLASPs during mitosis acts as a possible mechanism to prevent
aneuploidy in mammals