Koji Ikegami scite author profile

The life cycle of a primary cilium begins in quiescence and ends prior to mitosis. In quiescent cells, primary cilium insulates itself from contiguous dynamic membrane processes on the cell surface to function as a stable signaling apparatus. Here, we demonstrate that basal restriction of ciliary structure dynamics is established by cilia-enriched phosphoinositide 5-phosphatase, Inpp5e. Growth induction displaces ciliary Inpp5e and accumulates phosphatidylinositol 4,5-bisphosphate to distal cilia. This triggers otherwise forbidden actin polymerization in primary cilia, which excises cilia tips in a process we call cilia decapitation. Whilst cilia disassembly is traditionally thought to occur solely through resorption, we show that an acute loss of IFT-B through cilia decapitation precedes resorption. Finally, we propose that cilia decapitation induces mitogenic signaling and constitutes a molecular link between the cilia life cycle and cell-division cycle. This newly defined ciliary mechanism may find significance in cell proliferation control during normal development and cancer.

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Loss of α-tubulin polyglutamylation in ROSA22 mice is associated with abnormal targeting of KIF1A and modulated synaptic function

Ikegami

Heier²,

Taruishi³

et al. 2007

Proc. Natl. Acad. Sci. U.S.A.

214

222

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Microtubules function as molecular tracks along which motor proteins transport a variety of cargo to discrete destinations within the cell. The carboxyl termini of ␣-and ␤-tubulin can undergo different posttranslational modifications, including polyglutamylation, which is particularly abundant within the mammalian nervous system. Thus, this modification could serve as a molecular ''traffic sign'' for motor proteins in neuronal cells. To investigate whether polyglutamylated ␣-tubulin could perform this function, we analyzed ROSA22 mice that lack functional PGs1, a subunit of ␣-tubulin-selective polyglutamylase. In wild-type mice, polyglutamylated ␣-tubulin is abundant in both axonal and dendritic neurites. ROSA22 mutants display a striking loss of polyglutamylated ␣-tubulin within neurons, including their neurites, which is associated with decreased binding affinity of certain structural microtubule-associated proteins and motor proteins, including kinesins, to microtubules purified from ROSA22-mutant brain. Of the kinesins examined, KIF1A, a subfamily of kinesin-3, was less abundant in neurites from ROSA22 mutants in vitro and in vivo, whereas the distribution of KIF3A (kinesin-2) and KIF5 (kinesin-1) appeared unaltered. The density of synaptic vesicles, a cargo of KIF1A, was decreased in synaptic terminals in the CA1 region of hippocampus in ROSA22 mutants. Consistent with this finding, ROSA22 mutants displayed more rapid depletion of synaptic vesicles than wild-type littermates after high-frequency stimulation. These data provide evidence for a role of polyglutamylation of ␣-tubulin in vivo, as a molecular traffic sign for targeting of KIF1 kinesin required for continuous synaptic transmission.kinesin ͉ microtubules ͉ synaptic vesicles ͉ trafficking ͉ tyrosination

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CEP41 is mutated in Joubert syndrome and is required for tubulin glutamylation at the cilium

et al. 2012

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Tubulin glutamylation is a post-translational modification (PTM) occurring predominantly on ciliary axonemal tubulin and has been suggested to be important for ciliary function 1,2. However, its relationship to disorders of the primary cilium, termed ‘ciliopathies’, has not been explored. Here, in Joubert syndrome (JBTS) 3, we identify the JBTS15 locus and the responsible gene as CEP41, encoding a centrosomal protein of 41 KDa 4. We show that CEP41 is localized to the basal body/primary cilium, and regulates the ciliary entry of TTLL6, an evolutionarily conserved polyglutamylase enzyme 5. Depletion of CEP41 causes ciliopathy-related phenotypes in zebrafish and mouse, and induces cilia axonemal glutamylation defects. Our data identify loss of CEP41 as a cause of JBTS ciliopathy and highlight involvement of tubulin PTM in pathogenesis of the ciliopathy spectrum.

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TTLL7 Is a Mammalian β-Tubulin Polyglutamylase Required for Growth of MAP2-positive Neurites

Ikegami

Mukai

Tsuchida

et al. 2006

Journal of Biological Chemistry

155

180

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Microtubules form a cytoskeletal framework that influences cell shape and provides structural support for the cell. Microtubules in the nervous system undergo a unique post-translational modification, polyglutamylation of the C termini of their tubulin subunits. The mammalian enzymes that perform ␤-tubulin polyglutamylation as well as their physiological functions in the neuronal tissue remain elusive. We report identification of a mammalian polyglutamylase with specificity for ␤-tubulin as well as its distribution and function in neurite growth. To identify putative tubulin polyglutamylases, we searched tubulin tyrosine ligase-like (TTLL) proteins for those predominantly expressed in the nervous system. Of 13 TTLL proteins, TTLL7 was transcribed at the highest level in the nervous system. Recombinant TTLL7 catalyzed tubulin polyglutamylation with high preference to ␤-tubulin in vitro. When expressed in HEK293T cells, TTLL7 demonstrated specificity for ␤-tubulin and not for ␣-tubulin or nucleosome assembly protein 1. Consistent with these findings, knockdown of TTLL7 in a primary culture of superior cervical ganglion neurons caused a loss of polyglutamylated ␤-tubulin. Following stimulation of PC12 cells with nerve growth factor to differentiate, the level of TTLL7 increased concomitantly with polyglutamylation of ␤-tubulin. Short interference RNA-mediated knockdown of TTLL7 repressed nerve growth factor-stimulated MAP (microtubule-associated protein) 2-positive neurite growth in PC12 cells. Consistent with having a role in the growth of MAP2-positive neurites, TTLL7 accumulated within a MAP2-enriched somatodendritic portion of superior cervical ganglion, as did polyglutamylated ␤-tubulin. Anti-TTLL7 antibody revealed that TTLL7 was distributed in a somatodendritic compartment in the mouse brain. These findings indicate that TTLL7 is a ␤-tubulin polyglutamylase and is required for the growth of MAP2-positive neurites in PC12 cells.Microtubules have important functions in a variety of dynamic activities within the cell including intracellular transport, cell motility, and cell division. They provide structural support for the cell and are an important component of the cytoskeletal framework that generates cell morphology. In neurons microtubules are required for formation of specialized processes, i.e. dendrites and axons. Structural microtubule-associated proteins (MAPs), 2 such as MAP2 and tau, regulate the stability of microtubules in those processes.Microtubules are predominantly composed of tubes of polymerized dimers of ␣-and ␤-tubulin. A central question in cell biology is how functional heterogeneity is imparted to different types (e.g. dendritic, axonal, and centriolar) of microtubules. Two basic mechanisms have been proposed to explain this issue. The first involves duplication and divergence of genes encoding tubulin. The second mechanism involves the addition of a variety of post-translational modifications (PTM) to microtubules that further increases the tubulin heterogeneity (1). These PTMs are asso...

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Tubulin polyglutamylation is essential for airway ciliary function through the regulation of beating asymmetry

Ikegami

Sato

Nakamura

et al. 2010

Proc. Natl. Acad. Sci. U.S.A.

142

133

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Airway epithelial cilia protect the mammalian respiratory system from harmful inhaled materials by providing the force necessary for effective mucociliary clearance. Ciliary beating is asymmetric, composed of clearly distinguished effective and recovery strokes. Neither the importance of nor the essential components responsible for the beating asymmetry has been directly elucidated. We report here that the beating asymmetry is crucial for ciliary function and requires tubulin glutamylation, a unique posttranslational modification that is highly abundant in cilia. WT murine tracheal cilia have an axoneme-intrinsic structural curvature that points in the direction of effective strokes. The axonemal curvature was lost in tracheal cilia from mice with knockout of a tubulin glutamylation-performing enzyme, tubulin tyrosine ligase-like protein 1. Along with the loss of axonemal curvature, the axonemes and tracheal epithelial cilia from these knockout (KO) mice lost beating asymmetry. The loss of beating asymmetry resulted in a reduction of cilia-generated fluid flow in trachea from the KO mice. The KO mice displayed a significant accumulation of mucus in the nasal cavity, and also emitted frequent coughing-or sneezing-like noises. Thus, the beating asymmetry is important for airway ciliary function. Our findings provide evidence that tubulin glutamylation is essential for ciliary function through the regulation of beating asymmetry, and provides insight into the molecular basis underlying the beating asymmetry.ciliary dyskinesia | ciliopathy | glutamylase | flagella | microtubule

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Koji Ikegami

Dynamic Remodeling of Membrane Composition Drives Cell Cycle through Primary Cilia Excision

Loss of α-tubulin polyglutamylation in ROSA22 mice is associated with abnormal targeting of KIF1A and modulated synaptic function

CEP41 is mutated in Joubert syndrome and is required for tubulin glutamylation at the cilium

TTLL7 Is a Mammalian β-Tubulin Polyglutamylase Required for Growth of MAP2-positive Neurites

Tubulin polyglutamylation is essential for airway ciliary function through the regulation of beating asymmetry

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