Ministry of Education (MOE) Key Laboratory for Protein Science, Tsinghua-Peking Center for Life Sciences, School of Life Sciences, Tsinghua University, Beijing, China.
Laboratory for Marine Biology and Biotechnology, Qingdao National Laboratory for Marine Science and Technology, Qingdao, China.
FASEB J. 2019 May;33(5):6431-6441. doi: 10.1096/fj.201802375RR. Epub 2019 Feb 22.
Members of the MAPK superfamily are known as key regulators of ciliogenesis. Long flagellar (LF) 4, a MAPK-related kinase in , is the first kinase that was implicated in ciliary assembly and length. However, little is known about its cellular properties, regulation, and molecular functions. LF4 is localized both in the flagella and cell body with enrichment at the 2 basal bodies, shown by super-resolution microscopy. LF4 is constitutively phosphorylated at T159 at the kinase activation loop and remains at the basal bodies during flagellar assembly. Gene mutations that affect the kinase activity or T159 phosphorylation alter the localization of LF4 at the basal bodies, and the mutants fail to rescue , a null mutant. LF4 does not affect the velocities of intraflagellar transport (IFT). However, null mutation induces accumulation of IFT proteins in the flagellum and reduces the phosphorylation of the kinesin-II subunit FLA8/KIF3B, indicating that LF4 negatively regulates IFT entry. Furthermore, LF2, a cell cycle-related kinase, and LF3, a novel protein, are required for LF4 phosphorylation. Our study demonstrates that LF4 is likely a constitutively active kinase that is regulated by LF2 and regulates IFT entry at the basal bodies to control flagellar assembly and length.-Wang, Y., Ren, Y., Pan, J. Regulation of flagellar assembly and length in by LF4, a MAPK-related kinase.
MAPK 超家族的成员被认为是纤毛发生的关键调节因子。在 中,长鞭毛 (LF) 4 是一种与 MAPK 相关的激酶,它是第一个被牵连到纤毛组装和长度的激酶。然而,关于其细胞特性、调节和分子功能知之甚少。超分辨率显微镜显示,LF4 既存在于鞭毛中,也存在于细胞体中,在 2 个基体处富集。LF4 在激酶激活环处的 T159 处被持续磷酸化,在鞭毛组装过程中仍位于基体处。影响激酶活性或 T159 磷酸化的基因突变会改变 LF4 在基体处的定位,并且突变体不能拯救 ,一个 null 突变体。LF4 不影响内鞭毛运输 (IFT) 的速度。然而, null 突变会导致 IFT 蛋白在鞭毛中积累,并降低驱动蛋白-II 亚基 FLA8/KIF3B 的磷酸化,表明 LF4 负调节 IFT 进入。此外,细胞周期相关激酶 LF2 和新型蛋白 LF3 需要 LF4 磷酸化。我们的研究表明,LF4 可能是一种组成性激活的激酶,受 LF2 调节,并在基体处调节 IFT 进入,以控制鞭毛的组装和长度。
