The primary cilium is an antenna-like structure that protrudes from the cell surface of quiescent/differentiated cells and participates in extracellular signal processing [1][2][3] . Here, we report that mice deficient for the lipid 5-phosphatase Inpp5e develop a multiorgan disorder associated with structural defects of the primary cilium. In ciliated mouse embryonic fibroblasts, Inpp5e is concentrated in the axoneme of the primary cilium. Inpp5e inactivation did not impair ciliary assembly but altered the stability of pre-established cilia after serum addition. Blocking phosphoinositide 3-kinase (PI3K) activity or ciliary platelet-derived growth factor receptor a (PDGFRa) restored ciliary stability. In human INPP5E, we identified a mutation affecting INPP5E ciliary localization and cilium stability in a family with MORM syndrome, a condition related to Bardet-Biedl syndrome. Together, our results show that INPP5E plays an essential role in the primary cilium by controlling ciliary growth factor and PI3K signaling and stability, and highlight the consequences of INPP5E dysfunction.Lipid 5-phosphatases selectively remove the phosphate from position D-5 of the inositol ring of phosphoinositides and inositolphosphates 4,5 . To characterize the functions of the 5-phosphatase Inpp5e 6-8 , we generated Inpp5e D/+ mice ( Supplementary Fig. 1a). We obtained no adult Inpp5e D/D mutant mice from intercrosses between Inpp5e D/+ mice. However, at embryonic day 13.5 (E13.5) and E18.5, 16.9% (11/65) and 14.8% (12/81) of embryos were homozygous for the deletion allele, respectively. The mutant mice died soon after birth, indicating that total inactivation of Inpp5e led to embryonic and postnatal death. Analyses confirmed the absence of Inpp5e protein in mutant cells and tissues (Fig. 1a). Inpp5e D/D mice presented with bilateral anophthalmos (100%, n ¼ 43) and postaxial hexadactyly (62.5%, n ¼ 16; Fig. 1b,c). Histological analyses revealed that eye development ceased at the optic vesicle stage, just before the appearance of the optic cup (Fig. 1d). Analysis of kidneys from the mice revealed the presence of multiple cysts (100%, n ¼ 10; Fig. 1e). Of the cysts, 84% expressed AQP2 and 14% expressed AQP1, indicating an origin in cortical collecting and connecting ducts (when AQP2 + ) as well as proximal tubules and the descending limb of the loop of Henle (when AQP1 + ) ( Supplementary Fig. 2). Only 2% of the renal glomeruli were cystic. Inpp5e D/D embryos had skeletal abnormalities such as a bifid sternum (50%, n ¼ 6), delayed ossification of metacarpals and phalanges (100%, n ¼ 5) and cleft palate (75%, n ¼ 4; Fig. 1f-h). We identified cerebral developmental defects, such as anencephaly and exencephaly, in 30% of Inpp5e D/D embryos at E15.5 (n ¼ 30; Fig. 1i,j). We did not detect liver alterations, laterality defects or respiratory cilium defects in mutant animals. The tissue localization of lesions observed in Inpp5e D/D embryos matched the tissue expression of Inpp5e mRNA during mouse embryogenesis ( Supplementary Fig. 3).Becau...
The gene encoding the Aurora-A protein kinase is located in the 20q13 breast cancer amplicon and is also overexpressed in colorectal, pancreatic and gastric tumours. Although Aurora-A may not be a bona fide oncoprotein in humans, it is a promising drug target in cancer therapy. Thus, it is surprising that so little is known of its role in normal cells. The primary function of Aurora-A is to promote bipolar spindle assembly, but the molecular details of this process remained obscure until recently. The discovery of several novel Aurora-A-binding proteins and substrates has implicated Aurora-A in centrosome maturation and separation, acentrosomal and centrosomal spindle assembly, kinetochore function, cytokinesis and in cell fate determination. Here we discuss recent advances in determining the early mitotic role of Aurora-A, with a strong emphasis on its function at the mitotic spindle poles.
The ch-TOG/XMAP215 protein is essential for spindle pole organization in human somatic cells
The ch-TOG/XMAP215 family of proteins bind directly to microtubules and appear to play an essential role in stabilizing spindle microtubules. These proteins stabilize microtubules mainly by influencing microtubule plus-end dynamics, yet, in vivo, they are all strongly concentrated at spindle poles, where the minus ends of the microtubules are concentrated. In Drosophila embryos, the centrosomal protein D-TACC is required to efficiently recruit ch-TOG/Msps to centrosomes. In humans, ch-TOG and the three known TACC proteins have been implicated in cancer, but their functions are unknown. Here we extensively depleted TACC3 and ch-TOG from HeLa cells using RNA interference. In TACC3-depleted cells, spindles are well organized, but microtubules are partially destabilized and ch-TOG is no longer concentrated on spindle microtubules. In ch-TOG-depleted cells, relatively robust spindles form, but the spindles are highly disorganized. Thus, in human somatic cells, ch-TOG appears to play a major role in organizing spindle poles, and a more minor role in stabilizing spindle microtubules that is, at least in part, mediated via an interaction with TACC3. The XMAP215/ch-TOG family of microtubule associated proteins (MAPs) are among the best studied microtubule-stabilizing proteins. In the presence of purified tubulin, these proteins stabilize microtubules mainly by stimulating growth rates at microtubule plus ends, whereas in Xenopus egg extracts they also increase microtubule plus-end stability by counteracting the activity of the microtubule catastrophe factor XKCM1 (Tournebize et al. 2000;Kinoshita et al. 2001). These proteins are essential for stabilizing spindle microtubules in both Xenopus egg extracts and worm embryos (Matthews et al. 1998;Tournebize et al. 2000;Popov et al. 2001). Surprisingly, although XMAP215/ch-TOG mainly influences microtubule plus-end dynamics, these proteins are strongly concentrated at centrosomes, where the minus ends of the microtubules are clustered (Nabeshima et al. 1995;Wang et al. 1997;Charrasse et al. 1998;Matthews et al. 1998;Cullen et al. 1999;Tournebize et al. 2000;Garcia et al. 2001).In Drosophila, the centrosomal protein D-TACC has been shown to be required to efficiently recruit Msps/ ch-TOG to centrosomes (Cullen et al. 2001;Lee et al. 2001). The interaction between D-TACC and Msps/ch-TOG is highly conserved, and in human cells, all three known TACC proteins are concentrated at centrosomes and can interact with ch-TOG (Gergely et al. 2000;Cullen et al. 2001). Interestingly, ch-TOG and the three human TACC proteins have been implicated in cancer but the function of these proteins in mammalian cells is not known (Gergely 2002;Raff 2002). An attractive possibility is that these proteins function in human somatic cells as they do in frog and fly embryos, and are required to stabilize spindle microtubules. Perturbing their function could therefore lead to spindle defects and so contribute to the genetic instability that is essential for the development of cancer (Li et al. 1997;Brinkle...
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