Joukov V , De Nicolo A , Rodriguez A , Walter JC , Livingston DM .

GM62267 NIGMS NIH HHS , GM80676 NIGMS NIH HHS , R01 GM062267 NIGMS NIH HHS , R01 GM080676 NIGMS NIH HHS

	Fig. 1. AurA activation and MT assembly promoted in egg extract by sperm nuclei and αAurA beads. (A) Localization of AurA and Cep192 during MT assembly promoted by sperm nuclei-associated centrosomes (time course) and RanGTP. (Scale bars: 5 μm.) (B) W-blots showing the time course of AurA activation in extract by sperm nuclei (4 × 104/μL). (C) Extract was driven into interphase by the addition of calcium and supplemented with demembranated sperm nuclei (2 × 103/μL). Extract aliquots were withdrawn at the indicated times after sperm addition and analyzed by W-blotting using the indicated antibodies. (D) W-blots of extracts supplemented with XB buffer, nocodazole (50 μM), RanT24N (30 μM), Ran(Q69L)GTP (30 μM), or DNA beads (0.1 μL/μL). Where indicated, reaction mixtures contained sperm nuclei (4 × 104/μL). (E and F) Beads coated with nonimmune IgG (N/Imm), αAurA, or αAurA-Fab were incubated in rhodamine-tubulin+Ran(Q69L)GTP-supplemented extract and analyzed by fluorescence microscopy (E) and W-blotting (F). (Scale bar: 10 μm.) (G) W-blots of extract incubated with 1.7 μM goat anti-rabbit IgG, IgG fraction (αIgG) and increasing concentrations of αAurA-Fab [detected as IgG light chain (IgG L.C.)]. The concentration of AurA in egg extract is ≈0.35 μM.
	Fig. 2. Cep192 is a cofactor of AurA at centrosomes. (A) Schematic diagram of Xenopus Cep192. The AurA-BD and the three ASH (ASPM, SPD-2, Hydin) domains (40) are shown. The numbers denote aa. The underlying gray lines indicate the polypeptides used for antibody production. (B) W-blot of Cep192 and TPX2 IPs from extract. IgG H.C., IgG heavy chain. Note that the nonimmune IgG, even when used in approximately a twofold excess over αCep192-C and αTPX2 (as assessed by the intensity of IgG H.C.), brings down only a small, background amount of AurA. (C) Binding of recombinant Xenopus AurA to glutathione Sepharose-immobilized glutathione S-transferase (GST), GST-Cep521–757, and GST-TPX2-NT. (D) W-blot of αAurA beads retrieved from extracts incubated with 3 μM of the indicated GST polypeptides. (E) W-blot of mock-treated, Cep192-, and TPX2-depleted extracts incubated with 4 × 104/μL sperm nuclei (30 min) or with αAurA (0.3 μM) for the indicated times. (F) MT structures assembled in extracts supplemented with sperm nuclei, αAurA beads, or Ran(Q69L)GTP. (Scale bars: 10 μm.) (G) P-AurA and AurA detected by W-blot of αAurA beads retrieved from extracts in Fii. (H) W-blot showing partial rescue of the AurA activation defect by rCep192 in Cep192-depleted, fivefold diluted, extract. (I) Visualization of AurA oligomers by BiFC in extracts and transfected HeLa cells. BiFC complexes are shown in green; MTs (columns 1–3) and CFP (which denotes transfected cells; column 4, pseudocolor) in red; and DNA (DAPI; row 1) in blue. (Scale bars: 10 μm.)
	Fig. 3. Cep192-mediated AurA activation is essential for MTOC function. (A and D) Localization of AurA and Cep192 on centrosomal asters assembled in extracts supplemented with 3 μM GST or Cep521–757 (A) or with 0.7 μM nonimmune IgG or αCep192-N (D). (Scale bars: 2.5 μm.) (B and E) Quantitation of MT aster surface area in A and D, respectively. The results obtained in the presence of 0.2 μM αCep192-N are also shown for comparison (E). Error bars, SD. *P < 0.0001 compared with the corresponding control extract, as determined by a two-tailed Student's t test. The number of asters analyzed is shown in parentheses. (C) W-blot of extracts incubated with XB buffer, Cep521–757 (3 μM), or TPX2-NT (6 μM) in the absence or presence of sperm nuclei (4 × 104/μL) or αAurA (0.6 μM). (F) W-blots and images of αAurA beads that were added to extract before (iii and iv) or after (i and ii) its incubation with 3 μM GST or Cep521–757 on ice. (Scale bar: 10 μm.) (G) In vitro kinase assay of endogenous AurA complexes isolated from egg extract incubated with XB buffer or Cep521–757 (3 μM). The reaction products were resolved by SDS/PAGE and transferred onto a nitrocellulose membrane, which was subjected to autoradiography (32PO4-histone H3 row) followed by W-blotting (the remaining rows). (H) W-blots of extracts incubated with soluble αAurA (0.5 μM) added either before (lanes 5–8) or after (lanes 1–4) incubation of extracts with 3 μM GST or Cep521–757 on ice. (I) Quantitation of MT-nucleating αAurA beads in F, Lower.

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