A dynein-driven nucleokinesis program enables neural crest migration through confined tissues in vivo

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Abstract

Cell migration through confined tissue environments requires precise coordination between the nucleus and the cytoskeleton. Translocation of the nucleus through small pores is a limiting step in confined cell migration. Work in immune and cancer cells has illuminated a key role for actin polymerization and Myosin-II contractility in facilitating nucleus translocation through confinement. However, the microtubule cytoskeleton can also adaptively stabilise under confinement. Microtubule-dependent nucleokinesis constitutes an evolutionarily conserved cellular program ensuring directional nucleus translocation by deployment of cytoplasmic dynein motors. However, whether microtubule-driven nucleokinesis can operate during cell migration through confinement remained so far unexplored.

The zebrafish neural crest (NC) provides a unique in vivo system to address this question. NC cells are a highly migratory, multipotent precursors of the vertebrate peripheral nervous system, which traverse diverse environments along the anterior–posterior axis of the embryo. In the head, cranial neural crest (cNC) cells migrate through loosely organised tissues, whereas trunk neural crest (tNC) cells navigate narrowly confined tissue spaces.

Here, we show that tNC cells engage a microtubule motor-driven program of nuclear deformation and translocation during confined migration in vivo . Under confinement, tNC cells reorganize their microtubules from a perinuclear meshwork into a polarized, centrosome-associated bundle positioned ahead of the nucleus. Laser ablation reveals that this microtubule array actively pulls and deforms the nucleus. Using pharmacological and genetic approaches, we discover that dynein-dependent pulling forces enable nucleus translocation through confinement. Strikingly, this process occurs independently of Rho/ROCK/myosin II–mediated contractility, revealing a novel neuronal-like mode of nucleokinesis operating in confined tissue environments.

Together, our findings uncover a conserved nuclear translocation program deployed during neural crest migration and suggest that microtubule-based nucleokinesis represents a fundamental strategy for navigating tissue confinement in vivo during both central and peripheral nervous system development.

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