Wittmann T , Wilm M , Karsenti E , Vernos I .

	Figure 1. Molecular cloning of TPX2. (A) Northern blot of total Xenopus egg RNA hybridized with a PCR fragment obtained in a reaction with degenerate oligonucleotides designed according to TPX2 peptide sequences. The amount of RNA loaded per lane is indicated on top. The migration position of the 28S rRNA (4,115 nucleotides) and the 18S rRNA (1,826 nucleotides) is shown on the left. The probe recognizes a unique transcript of 3.0–3.5 kb. (B) Amino acid sequence of TPX2. Peptide sequences obtained by mass spectrometry are underlined. Differences between the predicted protein sequence and the peptide sequences are indicated by dotted underlines. Putative cdc2 kinase sites, (S/T)PX(K/R), are shaded in dark gray and MAP kinase phosphorylation sites, PX(S/T)P, are shaded in light gray, nuclear localization signals are shown in bold and the predicted coiled-coil regions are in italics. The complete cDNA sequence of Xenopus laevis TPX2 is available from GenBank/EMBL/DDBJ under accession number AF244546. (C) Sequence comparison of a region from TPX2 (corresponding to amino acids 297–356) with the human protein fls353 (amino acids 328–387) and predicted protein sequences from ESTs from mouse, chicken and zebrafish (these data are available from GenBank/EMBL/DDBJ under accession number AI415194, AJ394859, and AI883915). Conserved residues are shaded in gray and boxes indicate the highly conserved cdc2 and MAP kinase phosphorylation sites within this region.
	Figure 2. TPX2 is phosphorylated in mitotic egg extract and binds to microtubules with high affinity. (A) Immunoblot of low-speed Xenopus egg extracts, mitotic microtubule-associated proteins purified as described (Wittmann et al. 1998) and XL177 SDS lysate probed with affinity-purified anti-TPX2N. The molecular mass of marker proteins is indicated on the left. (B) Phosphorylation of TPX2 in mitotic, M, and interphase, I, egg extract incubated in the presence of γ-[32P]ATP. Taxol was added to 2 μM and the extracts were incubated for 30 min at 20°C. The immunoprecipitates were analyzed on a 6% SDS-PAGE and subjected to autoradiography. TPX2 is phosphorylated in mitotic extract and hyperphosphorylated upon assembly of microtubules. (C) Microtubule sedimentation assay of GFP-TPX2 with pure microtubules. The fraction of GFP-TPX2 bound to microtubules is plotted versus the microtubule concentration. The solid line represents the hyperbolic curve fit. (D) Microtubule sedimentation assay from crude extract. Interphase, I, and mitotic, M, extract were supplemented with either 20 μM nocodazole or 2 μM taxol, incubated for 20 min at 20°C and centrifuged through a 10% sucrose cushion. The immunoblots show the amount of TPX2 present in equivalent amounts of the soluble and pelleted fraction.
	Figure 3. TPX2 is required for the binding of Xklp2 to microtubules. (A) Microtubule sedimentation assay. Pure prepolymerized microtubules (1 μM) were mixed with bacterially expressed TPX2 and GST-Xklp2-Tail (both 0.1–0.2 μM), T, or GST-Xklp2-CDel2, C (Wittmann et al. 1998), as indicated on top, incubated for 20 min at 20°C and centrifuged through a 10% sucrose cushion. Equivalent amounts of the soluble and pelleted fraction were analyzed by immunoblot probed with anti-TPX2N or anti-Xklp2 antibodies as indicated. GST-Xklp2-Tail is only recovered in the pellet in the presence of both microtubules and TPX2. (B) Immunodepletion of TPX2 and GFP-TPX2 addback. 1-μl aliquots of extract were analyzed by immunoblot and probed with anti-TPX2N. The molecular mass of marker proteins is indicated on the left. Additional bands in the addback lane are due to degradation products of GFP-TPX2. (C) Mitotic asters assembled for 30 min at 20°C in the presence of 5% DMSO, 1 μM GST-Xklp2-Tail, and rhodamine-labeled tubulin in control- and TPX2-depleted extract supplemented with bacterially expressed GFP-TPX2. The asters were sedimented onto coverslips and stained with an anti-GST and an Alexa350-conjugated anti–rabbit antibody. (D) Mitotic asters assembled in the presence of Cy5-labeled tubulin as in C but without GST-Xklp2-Tail added. The asters were stained with an anti-Xklp2 and a rhodamine-conjugated anti–rabbit antibody. Bars, 10 μm.
	Figure 4. (A) Immunolocalization of TPX2 throughout the cell cycle. XL177 Xenopus tissue culture cells were fixed in cold methanol and stained with 0.6 μg/ml affinity-purified anti-TPX2N, monoclonal anti-tubulin, and Hoechst 33258 followed by FITC-labeled anti–mouse and TRITC-labeled anti–rabbit antibodies. Images represent single confocal slices. The same staining pattern was observed with anti-TPX2 or when the cells were fixed with glutaraldehyde. TPX2 staining appears at the end of prophase, persists at the spindle poles throughout mitosis until late anaphase. It then relocalizes to the midbody where it disappears in late telophase. (B) Live images of a mitotic XL177 cell expressing low amounts of GFP-TPX2. Note the nuclear fluorescence in telophase. The elapsed time is indicated in the upper right corner. Supplemental video is viewable at http://www.jcb.org/cgi/content/full/149/7/1405/DC1. Bars, 10 μm.
	Figure 5. Immunolocalization of TPX2 in Xenopus egg extract. (A) Sperm nuclei were incubated in extract released into interphase by the addition of calcium for the indicated time, fixed and sedimented onto coverslips. (B) Mitotic spindles assembled in the presence of rhodamine-labeled tubulin in cycled CSF-extract. Reactions were fixed at the indicated times after reentry into mitosis and sedimented onto coverslips. Spindles and nuclei were stained with 3 μg/ml anti-TPX2N, a Cy2-labeled anti–rabbit antibody and Hoechst 33258. TPX2 localizes to a branched structure in interphase nuclei and migrates to the spindle poles in mitosis. (C) Mitotic spindles centrifuged onto coverslips, postfixed in cold methanol and stained for either TPX2 or NuMA. Images were taken under identical conditions. Bars, 10 μm.
	Figure 6. The dynein–dynactin complex is required for the localization of TPX2 to spindle poles. (A) Recombinant p50/dynamitin was added to cycled spindle reactions at ∼0.7 mg/ml. The spindles were sedimented onto coverslips and stained with anti-TPX2N and a Cy2-conjugated anti–rabbit antibody. In the overlay, also the DNA visualized by Hoechst 33258 staining is shown in blue. Fluorescence intensity of the TPX2 staining and the rhodamine-labeled tubulin was measured in a 100-pixel wide stripe (width is indicated by arrowheads on the right) along the spindle axis. (B) The average fluorescence intensity of eleven spindles with (red) and without (black) p50/dynamitin added was plotted against the distance from the metaphase plate.
	Figure 8. Depletion of TPX2 affects spindle pole structure. (A) Immunoblot probed with anti-TPX2N demonstrating the depletion efficiency. 1-, 0.2-, and 0.05-μl samples of mitotic Xenopus egg extract are compared with 1 μl of control- and TPX2-depleted extract supplemented with bacterially expressed TPX2. The molecular mass of marker proteins is indicated on the left. (B) Quantification of structures observed in control- and TPX2-depleted extract 1 h after cycling the extract back into mitosis. The number of quantified structures is indicated on top. (C) Representative bipolar structures observed in control- and TPX2-depleted extract supplemented with recombinant TPX2. Cycled spindles were assembled in the presence of rhodamine-labeled tubulin, fixed, centrifuged onto coverslips, and stained with anti-TPX2N and Hoechst 33258. (D) Quantification of the microtubule density in bipolar structures assembled in control- and TPX2-depleted extract supplemented with recombinant TPX2 from two independent experiments. The red boxes indicate representative areas in which the rhodamine fluorescence intensity was measured. The number of structures analyzed is shown on top of the columns. Error bars indicate the standard deviation. Bars, 10 μm.
	Figure 7. Immunoprecipitation of TPX2 from egg extract. (A) Immunoprecipitated proteins using a control rabbit IgG or anti-TPX2N were eluted with a high-salt buffer and proteins remaining on the beads or recovered in the eluate were analyzed on a Coomassie-stained SDS-PAGE. (B) GST-TPX2 was added to mitotic egg extract, incubated for 30 min at 20°C and immunoprecipitated with an anti-GST antibody. For both gels, the molecular mass of marker proteins is indicated on the left. A polypeptide of ∼90 kD (arrowhead) is specifically immunoprecipitated together with the endogenous TPX2 or with GST-TPX2.
	Figure 9. Cycled spindle assembly in Xklp2- and TPX2-depleted extract. (A) Immunoblot of 1-μl samples of control-, TPX2-, Xklp2-, and double-depleted extract compared with 1, 0.2, 0.05, and 0.02 μl of mitotic egg extract and probed for Xklp2 and TPX2 as indicated. (B) Quantification of structures observed under the various depletion conditions. The number of quantified structures is indicated on top. (C) Representative bipolar structures observed in Xklp2- and double-depleted extract. Cycled spindles were assembled in the presence of rhodamine-labeled tubulin, fixed, centrifuged onto coverslips and stained with anti-TPX2N and Hoechst 33258. (D) TPX2-depleted structure stained for NuMA. Bars, 10 μm.
	Figure 10. An excess of TPX2 prevents the formation of bipolar spindles. (A) Representative structures observed in control and TPX2-supplemented reactions. Cycled spindles were assembled in the presence of rhodamine-labeled tubulin, fixed, centrifuged onto coverslips, and stained with anti-TPX2N and Hoechst 33258. (B) Quantification of structures observed in spindle assembly reactions supplemented with either control buffer or a 5–10-fold molar excess of TPX2. The number of quantified structures is indicated on top. (C) Quantification of the microtubule density in bipolar control spindles and in monopolar structures in TPX2-supplemented reactions. Error bars indicate the standard deviation (n = 20). (D) Monopolar structure in the presence of excess TPX2 stained for NuMA. Bars, 10 μm.

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