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Figure 6-1 Anatomy of the mitotic spindle
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Figure 6-2 General mechanisms of spindle assembly
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Figure 6-3 Microtubule structure
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Figure 6-4 Dynamic instability of microtubules
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Figure 6-5 Structure of the γ-tubulin ring complex
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Figure 6-6 Control of microtubule dynamics by associated proteins
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Figure 6-7 Motor proteins in the spindle
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Figure 6-8 The mammalian centrosome
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Figure 6-9 The centrosome cycle in an animal cell
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Figure 6-10 The spindle pole body of budding yeast
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Figure 6-11 Evidence for a block to centrosome reduplication in G2 cells
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Figure 6-12 Reduplication of centrosomes in prolonged S-phase arrest
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Figure 6-13 Kinetochore structure
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Figure 6-14 A possible mechanism for dynamic kinetochore–microtubule attachment
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Figure 6-15 Centrosome separation in prophase
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Figure 6-16 Recruitment of γ-tubulin to mitotic centrosomes
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Figure 6-17 Structure of the nuclear envelope
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Figure 6-18 Nuclear envelope breakdown in mitosis
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Figure 6-19 Fragmentation of the Golgi apparatus in mitosis
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Figure 6-20 Self-organization of a bipolar microtubule array
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Figure 6-21 Stabilization of microtubules around chromosomes by Ran–GTP
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Figure 6-22 Search and capture of chromosomes by the centrosomal spindle
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Figure 6-23 Kinetochore-derived microtubule formation
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Figure 6-24 Stable and unstable chromosome attachments
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Figure 6-25 Accumulation of syntelic attachments in the absence of aurora B kinase activity
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Figure 6-26 Processing of merotelic attachments
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Figure 6-27 Poleward force generation by the kinetochore
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Figure 6-28 Microtubule flux in metaphase and anaphase
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Figure 6-29 Changes in the state of kinetochores cause oscillations of chromatid pairs on the spindle
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Figure 6-30 Polar ejection forces in chromosome congression
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Figure 6-31 Force gradients driving chromosome congression
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