Dictenberg JB , Zimmerman W , Sparks CA , Young A , Vidair C , Zheng Y , Carrington W , Fay FS , Doxsey SJ .

R01 RR09799-01A1 NCRR NIH HHS , R01GM51994 NIGMS NIH HHS , R01 GM051994 NIGMS NIH HHS

	Figure 4. Pericentrin forms a novel lattice at the centrosome. Microtubule aster and centrosome from a CHO cell stained with antibodies to α-tubulin (A) and pericentrin (B) and imaged by conventional immunofluorescence methods. (C) High magnification of unfixed CHO cell centrosome imaged as in (B). (D) Image of same centrosome shown in (C) using commercially-available deconvolution software (Scanalytics). (E and F) High resolution stereo images of same centrosome in (C) restored by the algorithm of Carrington (1995) (D, +6 degrees; E, −6 degrees). (G–K) Centrosome isolated from a CHO cell and labeled with antibodies to pericentrin to visualize lattice (G–I) and α-tubulin to visualize centrioles (J and K). Before restoration, pericentrin (G) and α-tubulin (K). After restoration, pericentrin staining showing entire three-dimensional data set (H) or five central planes (I) and α-tubulin staining showing three central planes (J). The two areas devoid of pericentrin staining (I) represent positions occupied by centrioles (J). (L–O) GFP–pericentrin expressed in COS cells (M) localized to the center of a microtubule aster detected by α-tubulin immunofluorescence staining (L). GFP-pericentrin before (N) and after (O) image restoration. Bars: (B) 10 μm for A and B; (C) 1 μm; (F) 1 μm for D–F; (K) 1 μm for G–K; (M) 10 μm for L and M; (O), 1 μm for N and O.
	Figure 6. γ-Tubulin and pericentrin are part of the same lattice. (A and B) Restored images of two prophase centrosomes in CHO cells labeled by immunofluorescence for γ-tubulin (A) and pericentrin (B). (C and D) CHO cell centrosome stained for dynactin (C) and pericentrin (D). (E) Quantitative analysis of the coincidence of centrosome proteins in CHO cells using secondary antibodies tagged with different fluorophores (see Materials and Methods). Column 1, rat anti-pericentrin/rabbit anti-pericentrin; column 2, rabbit anti-pericentrin/mixed (fluorescein- and rhodamine-conjugated) anti–rabbit IgGs; column 3, rat anti-pericentrin/rabbit anti–γ-tubulin; column 4, rabbit anti-pericentrin/ mouse anti-centrin; and column 5, rat anti-pericentrin/rabbit anti-dynactin. Bar, 1 μm.
	Figure 8. Dramatic cell cycle changes in the intracellular distribution of pericentrin and γ-tubulin and lattice structure. (A) Quantitative analysis of immunofluorescence signals from centrosome-associated pericentrin and γ-tubulin in CHO cells at various stages of the cell cycle (see Materials and Methods). Protein levels rise progressively from G1 until mitosis and then drop precipitously to basal levels. (B) Levels of pericentrin and γ-tubulin do not appear to change upon exit from mitosis. Lysates were prepared from metaphase cells (M) or from an equal number of metaphase cells induced to enter telophase (T; see Materials and Methods). Pericentrin was immunoprecipitated from lysates and immunoblotted with pericentrin antibodies as described in Fig. 3 (panel 1). Other lysates were used for immunoblotting with antibodies to γ-tubulin (Fig. 3 B, panel 2) or antibodies to cyclin B (Fig. 3 B, panel 3). Note that the cyclin B signal decreases from M to T, while the levels of pericentrin and γ-tubulin do not appear to change during this time. (C) Changes in lattice structure closely correlate with changes in the levels of centrosome-associated protein. The pericentrin lattice is simplest in G1 and enlarges to maximal size and complexity at G2, before separating to form a pair of centrosomes whose combined size at metaphase (M) is slightly larger than the G2 centrosome. When cells exit mitosis, the lattice rapidly returns to its simplest form (similar to that seen in G1). Similar results were observed with antibodies to γ-tubulin. Cell cycle stages: G1; S; G2; M, metaphase; A, anaphase; and T, telophase. Bar, 1 μm.
	Figure 1. Pericentrin and γ-tubulin cosediment in sucrose gradients. (A) In vitro–translated, [35S]methionine-labeled mouse pericentrin was sedimented in sucrose gradients (10–40%) and exposed to SDS-PAGE as described in Materials and Methods. (A and B) Xenopus extracts were sedimented in sucrose gradients and immunoblotted using antibodies to pericentrin (B) or γ-tubulin (C). Parallel sample of the same extract immunodepleted of γ-tubulin (D and E) or treated with 0.1% Triton X-100 (F and G) before gradient centrifugation. Pericentrin immunoblots (B, D, and F); γ-tubulin immunoblots (C, E, and G). Molecular weight standards are for all panels.
	Figure 2. Pericentrin and γ-tubulin cofractionate by gel filtration. Xenopus extracts were fractionated by gel filtration using a Superose-6 column. Proteins were precipitated from fractions with trichloroacetic acid, immunoblotted using antibodies to pericentrin or γ-tubulin, and then resulting bands were quantified (see Materials and Methods for details). Under optimal conditions, the majority of γ-tubulin and pericentrin eluted together in fractions 3–5, suggesting that they were part of a large complex (A and B, closed arrow). A variable portion of pericentrin eluted at fractions 5–7 and γ-tubulin at 9–11 (B, open arrows) when extracts were incubated for extended periods on ice (1 h). Y axes represent units of band intensity from Western blots.
	Figure 5. The lattice is a conserved feature of centrosomes and other MTOCs. (A and B) Xenopus spindle assembled in vitro. (A) Spindle labeled for pericentrin (green), α-tubulin (red), and DNA (blue), imaged by conventional methods and superimposed. (B) Restored image of centrosome at upper pole of spindle in A. (C and D) Acentriolar mouse meiotic spindle arrested in metaphase II. (C) Spindle labeled for α-tubulin (green), pericentrin (red), and DNA (blue) prepared as in A. (D) Restored image of spindle pole at top of image in (C). Note difference in magnification between B and D. Bars: (A and C) 5 μm; (B and D) 1 μm.
	Figure 7. The proximity of γ-tubulin and pericentrin at the centrosome is sufficient to produce FRET. Centrosomes colabeled for pericentrin (A, fluorescein) and γ-tubulin (B, rhodamine), or for pericentrin (C, fluorescein) and centrin (D, rhodamine) were illuminated to excite fluorescein. Images were captured using fluorescein and rhodamine emission filters and restored as in Fig. 4. The image resulting from the transfer of energy to rhodamine-labeled antibody bound to γ-tubulin (B) is very similar to that generated by the donor signal (A). In contrast, images generated when antibodies bound to centrin serve as acceptor (D) represent a small subset of the pericentrin image (C). The FRET ratio (E) is expressed as the proportion of fluorescence generated by the acceptor over that generated by the donor (which is quenched after efficient transfer). The FRET ratio of pericentrin and γ-tubulin (2) is similar to that obtained with two pericentrin antibodies (1) and much greater than that of pericentrin and centrin (3). Bar, 1 μm.
	Figure 9. Nucleated microtubules contact the lattice. Images of nucleated microtubules (red) and pericentrin (yellow) have been merged to show that the number of nucleated microtubules converging at the centrosome (many bundled in G2) and the size of the pericentrin lattice increase from S to G2 (also see Fig. 8, A and C). The inset in the first panel shows microtubule– lattice contacts in the simple early S phase centrosome. Inset shows the area of interaction (white) demonstrating near complete overlap of microtubule ends with lattice elements. See Materials and Methods. Similar results were obtained with γ-tubulin. Bars, 1 μm.
	Figure 10. A model for centrosome assembly. The stoichiometry of pericentrin and γ-tubulin is consistent with a large complex consisting of one pericentrin complex and two γ-tubulin complexes. This model accommodates both of the current schemes proposed for microtubule nucleating complexes (Zheng et al., 1995; Erickson and Stoffler, 1996) (see Discussion). The complex appears to assemble at the centrosome to form a unique lattice (left). When dissociated, the complex gives rise to a pericentrin subcomplex, a γ-tubulin subcomplex and perhaps other proteins (right). Whereas the γ-tubulin subcomplex has not been characterized in this study, it has previously been shown that purified γ-TuRCs are capable of nucleating microtubules in vitro but are unable to assemble onto centrosomes (see Discussion). The pericentrin complex may facilitate assembly of γ-tubulin complexes into the centrosome lattice. Centrosome assembly and stabilization are likely to require other proteins.

Adams, Fluorescence ratio imaging of cyclic AMP in single cells. 1991, Pubmed

Adams, Fluorescence ratio imaging of cyclic AMP in single cells. 1991, Pubmed
Albers, The molecular biology of intermediate filament proteins. 1992, Pubmed
Archer, Deconstructing the microtubule-organizing center. 1994, Pubmed , Xenbase
Blomberg-Wirschell, Rapid isolation of centrosomes. 1998, Pubmed
Brown, Molecular chaperones and the centrosome. A role for TCP-1 in microtubule nucleation. 1996, Pubmed
Carrington, Superresolution three-dimensional images of fluorescence in cells with minimal light exposure. 1995, Pubmed
Doxsey, Pericentrin, a highly conserved centrosome protein involved in microtubule organization. 1994, Pubmed , Xenbase
Echeverri, Molecular characterization of the 50-kD subunit of dynactin reveals function for the complex in chromosome alignment and spindle organization during mitosis. 1996, Pubmed
Erickson, Protofilaments and rings, two conformations of the tubulin family conserved from bacterial FtsZ to alpha/beta and gamma tubulin. 1996, Pubmed
Félix, Centrosome assembly in vitro: role of gamma-tubulin recruitment in Xenopus sperm aster formation. 1994, Pubmed , Xenbase
Gard, Centrosome duplication continues in cycloheximide-treated Xenopus blastulae in the absence of a detectable cell cycle. 1990, Pubmed , Xenbase
Gould, The pericentriolar material in Chinese hamster ovary cells nucleates microtubule formation. 1977, Pubmed
Heim, Improved green fluorescence. 1995, Pubmed
Jacobsen, Thermodynamic analysis of the effects of small inert cosolutes in the ultracentrifugation of noninteracting proteins. 1996, Pubmed
Kellogg, The centrosome and cellular organization. 1994, Pubmed
Kuriyama, Microtubule-nucleating activity of centrosomes in Chinese hamster ovary cells is independent of the centriole cycle but coupled to the mitotic cycle. 1981, Pubmed
Ludwig, Calibration of a resonance energy transfer imaging system. 1992, Pubmed
MARTIN, A method for determining the sedimentation behavior of enzymes: application to protein mixtures. 1961, Pubmed
Mazia, The chromosome cycle and the centrosome cycle in the mitotic cycle. 1987, Pubmed
McNally, Katanin, the microtubule-severing ATPase, is concentrated at centrosomes. 1996, Pubmed
Merdes, Pathways of spindle pole formation: different mechanisms; conserved components. 1997, Pubmed
Miyawaki, Fluorescent indicators for Ca2+ based on green fluorescent proteins and calmodulin. 1997, Pubmed
Mogensen, Centrosomal deployment of gamma-tubulin and pericentrin: evidence for a microtubule-nucleating domain and a minus-end docking domain in certain mouse epithelial cells. 1997, Pubmed
Moritz, Microtubule nucleation by gamma-tubulin-containing rings in the centrosome. 1995, Pubmed
Murray, Cyclin synthesis drives the early embryonic cell cycle. 1989, Pubmed , Xenbase
Nicolas, Freeze substitution after fast-freeze fixation in preparation for immunocytochemistry. 1993, Pubmed
Nováková, gamma-Tubulin redistribution in taxol-treated mitotic cells probed by monoclonal antibodies. 1996, Pubmed
Oakley, Identification of gamma-tubulin, a new member of the tubulin superfamily encoded by mipA gene of Aspergillus nidulans. 1989, Pubmed
Prasher, Primary structure of the Aequorea victoria green-fluorescent protein. 1992, Pubmed
Salisbury, Centrin, centrosomes, and mitotic spindle poles. 1995, Pubmed
Sawin, Poleward microtubule flux mitotic spindles assembled in vitro. 1991, Pubmed , Xenbase
Siegel, Determination of molecular weights and frictional ratios of proteins in impure systems by use of gel filtration and density gradient centrifugation. Application to crude preparations of sulfite and hydroxylamine reductases. 1966, Pubmed
Sparks, Phosphorylation of NUMA occurs during nuclear breakdown and not mitotic spindle assembly. 1995, Pubmed
Stearns, In vitro reconstitution of centrosome assembly and function: the central role of gamma-tubulin. 1994, Pubmed , Xenbase
Stryer, Fluorescence energy transfer as a spectroscopic ruler. 1978, Pubmed
Urata, A three-dimensional structural dissection of Drosophila polytene chromosomes. 1995, Pubmed
Vogel, Centrosomes isolated from Spisula solidissima oocytes contain rings and an unusual stoichiometric ratio of alpha/beta tubulin. 1997, Pubmed
Walczak, Kinesin-related proteins at mitotic spindle poles: function and regulation. 1996, Pubmed
Wu, Resonance energy transfer: methods and applications. 1994, Pubmed
Zheng, Nucleation of microtubule assembly by a gamma-tubulin-containing ring complex. 1995, Pubmed , Xenbase
de Haën, Molecular weight standards for calibration of gel filtration and sodium dodecyl sulfate-polyacrylamide gel electrophoresis: ferritin and apoferritin. 1987, Pubmed