Structural analysis of the role of TPX2 in branching microtubule nucleation

Alfaro-Aco, Raymundo; Thawani, Akanksha; Petry, Sabine

doi:10.1083/jcb.201607060

Cited by 83 publications

(128 citation statements)

References 47 publications

(105 reference statements)

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“…Spindle‐shrinking effects in Xenopus did not depend on Aurora A, but rather on a change in spindle microtubule distribution caused by increased recruitment of the cross‐linking Eg5 motor to spindle poles (Helmke & Heald, ). TPX2 also regulates microtubule nucleation in the spindle (Alfaro‐Aco, Thawani, & Petry, ; Petry, ; Petry, Groen, Ishihara, Mitchison, & Vale, ; Scrofani, Sardon, Meunier, & Vernos, ). TPX2 has thus emerged as a central player of spindle assembly and organization in a wide variety of cell types (Fu et al, ; Helmke, Heald, & Wilbur, ; Levy & Heald, ; Ma, Titus, Gable, Ross, & Wadsworth, ) and is overexpressed in many cancers (Chang et al, ; Neumayer, Belzil, Gruss, & Nguyen, ).…”

Section: Resultsmentioning

confidence: 99%

Spindle assembly in egg extracts of the Marsabit clawed frog, Xenopus borealis

2018

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Egg extracts of the African clawed frog Xenopus laevis have provided a cell-free system instrumental in elucidating events of the cell cycle, including mechanisms of spindle assembly. Comparison with extracts from the diploid Western clawed frog, Xenopus tropicalis, which is smaller at the organism, cellular and subcellular levels, has enabled the identification of spindle size scaling factors. We set out to characterize the Marsabit clawed frog, Xenopus borealis, which is intermediate in size between the two species, but more recently diverged in evolution from X. laevis than X. tropicalis. X. borealis eggs were slightly smaller than those of X. laevis, and slightly smaller spindles were assembled in egg extracts. Interestingly, microtubule distribution across the length of the X. borealis spindles differed from both X. laevis and X. tropicalis. Extract mixing experiments revealed common scaling phenomena among Xenopus species, while characterization of spindle factors katanin, TPX2, and Ran indicate that X. borealis spindles possess both X. laevis and X. tropicalis features. Thus, X. borealis egg extract provides a third in vitro system to investigate interspecies scaling and spindle morphometric variation.

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Section: Resultsmentioning

confidence: 99%

Spindle assembly in egg extracts of the Marsabit clawed frog, Xenopus borealis

2018

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“…Augmin is necessary to recruit g-TuRC to spindle microtubules (Goshima et al, 49 2007), and following the recombinant expression of augmin (Hsia et al, 2014), this activity was 50 confirmed using purified proteins (Song et al, 2018). In meiotic Xenopus egg extract, the Ran-51 regulated protein TPX2 is released near chromatin (Gruss et al, 2001), where it stimulates 52 branching microtubule nucleation (Petry et al, 2013), potentially by activating g-TuRC (Alfaro-53 Aco et al, 2017). Recently, TPX2 was also observed to form a co-condensate with tubulin along 54 microtubules, which enhances the kinetic efficiency of branching microtubule nucleation (King 55 and Petry, 2019).…”

Section: Introduction 30mentioning

confidence: 99%

Biochemical reconstitution of branching microtubule nucleation

Alfaro-Aco

Thawani

Petry

2019

Preprint

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16Microtubules are nucleated from specific locations at precise times in the cell cycle. However, the 17 factors that constitute these microtubule nucleation pathways still need to be identified along with 18 their mode of action. Here, using purified Xenopus laevis proteins we biochemically reconstitute 19 branching microtubule nucleation, a nucleation pathway where microtubules originate from pre-20 existing microtubules, which is essential for spindle assembly and chromosome segregation. We 21 found that besides the microtubule nucleator gamma-tubulin ring complex (g-TuRC), the two 22 branching effectors augmin and TPX2 are required to efficiently nucleate branched microtubules. 23Specifically, TPX2 generates regularly-spaced patches that recruit augmin and g-TuRC to 24 microtubules, which then nucleate new microtubules at preferred branching angles of less than 90 25 degrees. Our work demonstrates how g-TuRC is brought to its nucleation site for branching 26 microtubule nucleation. It provides a blueprint for other microtubule nucleation pathways and for 27 generating a particular microtubule architecture by regulating microtubule nucleation. 28 29

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“…The formation of augmin-dependent 12 branched MT arrays was also visualized in Xenopus egg extracts (Petry et al, 2013) although 13 the postulated steps of branching MT nucleation: 1) augmin binding, 2) recruitment of -TuRC to 14 mother MTs, and 3) nucleation of daughter MTs were not directly observed. In the egg extract 15 model, both RanGTP and its downstream target Targeting Protein for Xklp2 (TPX2), which 16 mediate acentrosomal spindle assembly around DNA (Groen et al, 2009;Maresca et al, 2009) 17 have been implicated in promoting branching MT nucleation (Alfaro-Aco et al, 2017;Petry et 18 al., 2013). Interestingly, these factors are unlikely to contribute to branching MT nucleation in 19 interphase cortical MT arrays in plant cells as both RanGTP and plant TPX2 are nuclear during 20 interphase (Vos et al, 2008).…”

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“…While the occurrence of shallow 9 angle/parallel branching events cannot be ruled out, we could not confidently identify bona-fide 10 parallel branch events, as defined by daughters originating from a mother-associated γ-TuRC, 11 because parallel MTs were bundled during cytokinesis. It should be noted that augmin depletion 12 in Arabidopsis, resulted in a majority of nucleation events (63%) becoming parallel (Liu et al, 14 TPX2 is a highly conserved protein and its activity has been associated with multiple 15 roles in mitosis, such as, spindle assembly (Gruss et al, 2001;Gruss et al, 2002;Ma et al, 16 2010;Wadsworth, 2015;Wittmann et al, 2000), MT nucleation, and MT stabilization (Alfaro-Aco 17 et al, 2017;Groen et al, 2009;Petry et al, 2013;Reid et al, 2016;Roostalu and Surrey, 2017).…”

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Direct observation of branching MT nucleation in living animal cells

Verma

Maresca²

2019

Preprint

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160 words) 1 Centrosome-mediated microtubule (MT) nucleation has been well-characterized; however, 2 numerous non-centrosomal MT nucleation mechanisms exist. The branching MT nucleation 3 pathway envisages that the γ-tubulin ring complex (γ-TuRC) is recruited to MTs by the augmin 4 complex to initiate nucleation of new MTs. While the pathway is well-conserved at a molecular 5 and functional level, branching MT nucleation by core constituents has never been directly 6 observed in animal cells. Here, multi-color TIRF microscopy was applied to visualize and 7 quantitatively define the entire process of branching MT nucleation in dividing Drosophila cells. 8 The stereotypical branching nucleation event entailed augmin first binding to a "mother" MT, 9 recruitment of γ-TuRC after 16s, followed by nucleation 15s later of a "daughter" MT at a 36° 10 branch angle. Daughters typically remained attached throughout their ~40s lifetime unless the 11 mother depolymerized past the branch point. Assembly of branched MT arrays, which did not 12 require D-TPX2 (Drosophila TPX2) or evident regulation by a RanGTP gradient, enhanced 13 localized RhoA activation during cytokinesis. 14 15

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Structural analysis of the role of TPX2 in branching microtubule nucleation

Abstract: TPX2 is required for microtubule nucleation in mitosis, but the mechanism underlying its function is unclear. Alfaro-Aco et al. analyze the domains of TPX2 necessary for its activity and identify the minimal region required for branching microtubule nucleation.

Cited by 83 publications

References 47 publications

Spindle assembly in egg extracts of the Marsabit clawed frog, Xenopus borealis

Spindle assembly in egg extracts of the Marsabit clawed frog, Xenopus borealis

Biochemical reconstitution of branching microtubule nucleation

Direct observation of branching MT nucleation in living animal cells

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