Your search keyword '"γ-TuRC"' showing total 33 results

1. γ-TuRCs and the augmin complex are required for the development of highly branched dendritic arbors in Drosophila.

Author

Mukherjee, Amrita, Jeske, Yaiza Andrés, Becam, Isabelle, Taïeb, Anaelle, Brooks, Paul, Aouad, Joanna, Monguillon, Clementine, and Conduit, Paul T.

Subjects

*DROSOPHILA, *DENDRITES, *MICROTUBULES, *NEURONS, *MORPHOLOGY

Abstract

Microtubules are nucleated by γ-tubulin ring complexes (γ-TuRCs) and are essential for neuronal development. Nevertheless, γ-TuRC depletion has been reported to perturb only higher-order branching in elaborated Drosophila larval class IV dendritic arborization (da) neurons. This relatively mild phenotype has been attributed to defects in microtubule nucleation from Golgi outposts, yet most Golgi outposts lack associated γ-TuRCs. By analyzing dendritic arbor regrowth in pupae, we show that γ-TuRCs are also required for the growth and branching of primary and secondary dendrites, as well as for higher-order branching. Moreover, we identify the augmin complex (hereafter augmin), which recruits γ-TuRCs to the sides of pre-existing microtubules, as being required predominantly for higher-order branching. Augmin strongly promotes the anterograde growth of microtubules in terminal dendrites and thus terminal dendrite stability. Consistent with a specific role in higher-order branching, we find that augmin is expressed less strongly and is largely dispensable in larval class I da neurons, which exhibit few higher-order dendrites. Thus, γ-TuRCs are essential for various aspects of complex dendritic arbor development, and they appear to function in higher-order branching via the augmin pathway, which promotes the elaboration of dendritic arbors to help define neuronal morphology. [ABSTRACT FROM AUTHOR]

Published

2024

2. How Microtubules Build the Spindle Branch by Branch.

Author

Travis, Sophie M., Mahon, Brian P., and Petry, Sabine

Abstract

The microtubule (MT) cytoskeleton provides the architecture that governs intracellular organization and the regulated motion of macromolecules through the crowded cytoplasm. The key to establishing a functioning cytoskeletal architecture is regulating when and where new MTs are nucleated. Within the spindle, the vast majority of MTs are generated through a pathway known as branching MT nucleation, which exponentially amplifies MT number in a polar manner. Whereas other MT nucleation pathways generally require a complex organelle such as the centrosome or Golgi apparatus to localize nucleation factors, the branching site is based solely on a simple, preformed MT, making it an ideal system to study MT nucleation. In this review, we address recent developments in characterizing branching factors, the branching reaction, and its regulation, as well as branching MT nucleation in systems beyond the spindle and within human disease. [ABSTRACT FROM AUTHOR]

Published

2022

3. Microtubule Organizing Centers Contain Testis-Specific γ-TuRC Proteins in Spermatids of Drosophila

Author

Elham Alzyoud, Viktor Vedelek, Zsuzsánna Réthi-Nagy, Zoltán Lipinszki, and Rita Sinka

Subjects

Drosophila, spermatogenesis, γ-TuRC, microtubules, MTOC, basal body, Biology (General), QH301-705.5

Abstract

Microtubule nucleation in eukaryotes is primarily promoted by γ-tubulin and the evolutionary conserved protein complex, γ-Tubulin Ring Complex (γ-TuRC). γ-TuRC is part of the centrosome and basal body, which are the best-known microtubule-organizing centers. Centrosomes undergo intensive and dynamic changes during spermatogenesis, as they turn into basal bodies, a prerequisite for axoneme formation during spermatogenesis. Here we describe the existence of a novel, tissue-specific γ-TuRC in Drosophila. We characterize three genes encoding testis-specific components of γ-TuRC (t-γ-TuRC) and find that presence of t-γ-TuRC is essential to male fertility. We show the diverse subcellular distribution of the t-γ-TuRC proteins during post-meiotic development, at first at the centriole adjunct and then also on the anterior tip of the nucleus, and finally, they appear in the tail region, close to the mitochondria. We also prove the physical interactions between the t-γ-TuRC members, γ-tubulin and Mozart1. Our results further indicate heterogeneity in γ-TuRC composition during spermatogenesis and suggest that the different post-meiotic microtubule organizing centers are orchestrated by testis-specific gene products, including t-γ-TuRC.

Published

2021

4. Reconstitution of the recombinant human γ-tubulin ring complex

Author

Martin Würtz, Anna Böhler, Annett Neuner, Erik Zupa, Lukas Rohland, Peng Liu, Bram J. A. Vermeulen, Stefan Pfeffer, Sebastian Eustermann, and Elmar Schiebel

Subjects

γ-tubulin, microtubules, γ-turc, Biology (General), QH301-705.5

Abstract

Cryo-electron microscopy recently resolved the structure of the vertebrate γ-tubulin ring complex (γ-TuRC) purified from Xenopus laevis egg extract and human cells to near-atomic resolution. These studies clarified the arrangement and stoichiometry of γ-TuRC components and revealed that one molecule of actin and the small protein MZT1 are embedded into the complex. Based on this structural census of γ-TuRC core components, we developed a recombinant expression system for the reconstitution and purification of human γ-TuRC from insect cells. The recombinant γ-TuRC recapitulates the structure of purified native γ-TuRC and has similar functional properties in terms of microtubule nucleation and minus end capping. This recombinant system is a central step towards deciphering the activation mechanisms of the γ-TuRC and the function of individual γ-TuRC core components.

Published

2021

5. Growth cone-localized microtubule organizing center establishes microtubule orientation in dendrites

Author

Xing Liang, Marcela Kokes, Richard D Fetter, Maria Danielle Sallee, Adrian W Moore, Jessica L Feldman, and Kang Shen

Subjects

neuronal cell polarity, dendrite development, microtubule organization, acentrosomal mtoc, γ-TuRC, Medicine, Science, Biology (General), QH301-705.5

Abstract

A polarized arrangement of neuronal microtubule arrays is the foundation of membrane trafficking and subcellular compartmentalization. Conserved among both invertebrates and vertebrates, axons contain exclusively ‘plus-end-out’ microtubules while dendrites contain a high percentage of ‘minus-end-out’ microtubules, the origins of which have been a mystery. Here we show that in Caenorhabditis elegans the dendritic growth cone contains a non-centrosomal microtubule organizing center (MTOC), which generates minus-end-out microtubules along outgrowing dendrites and plus-end-out microtubules in the growth cone. RAB-11-positive endosomes accumulate in this region and co-migrate with the microtubule nucleation complex γ-TuRC. The MTOC tracks the extending growth cone by kinesin-1/UNC-116-mediated endosome movements on distal plus-end-out microtubules and dynein clusters this advancing MTOC. Critically, perturbation of the function or localization of the MTOC causes reversed microtubule polarity in dendrites. These findings unveil the endosome-localized dendritic MTOC as a critical organelle for establishing axon-dendrite polarity.

Published

2020

6. Promiscuous Binding of Microprotein Mozart1 to γ-Tubulin Complex Mediates Specific Subcellular Targeting to Control Microtubule Array Formation

Author

Tzu-Lun Huang, Hsiu-Jung Wang, Ya-Chieh Chang, Shao-Win Wang, and Kuo-Chiang Hsia

Subjects

Mozart1, γ-TuRC, microtubule nucleation, microprotein, γ-TuRC targeting, Biology (General), QH301-705.5

Abstract

Summary: How γ-tubulin ring complex (γ-TuRC), a master template for microtubule nucleation, is spatially and temporally regulated for the assembly of new microtubule arrays remains unclear. Here, we report that an evolutionarily conserved microprotein, Mozart1 (Mzt1), regulates subcellular targeting and microtubule formation activity of γ-TuRC at different cell cycle stages. Crystal structures of protein complexes demonstrate that Mzt1 promiscuously interacts with the N-terminal domains of multiple γ-tubulin complex protein subunits in γ-TuRC via an intercalative binding mode. Genetic- and microscopy-based analyses show that promiscuous binding of Mzt1 in γ-TuRC controls specific subcellular localization of γ-TuRC to modulate microtubule nucleation and stabilization in fission yeast. Moreover, we find Mzt1-independent targeting of γ-TuRC to be crucial for mitotic spindle assembly, demonstrating the cell-cycle-dependent regulation and function of γ-TuRC. Our findings reveal a microprotein-mediated regulatory mechanism underlying microtubule cytoskeleton formation, whereby Mzt1 binding promiscuity confers localization specificity on the multi-protein complex γ-TuRC.

Published

2020

7. Cross-linking mass spectrometry identifies new interfaces of Augmin required to localise the γ-tubulin ring complex to the mitotic spindle

Author

Jack W. C. Chen, Zhuo A. Chen, Kacper B. Rogala, Jeremy Metz, Charlotte M. Deane, Juri Rappsilber, and James G. Wakefield

Subjects

γ-TuRC, Augmin, Drosophila, Microtubule, Mitosis, Spindle, Science, Biology (General), QH301-705.5

Abstract

The hetero-octameric protein complex, Augmin, recruits γ-Tubulin ring complex (γ-TuRC) to pre-existing microtubules (MTs) to generate branched MTs during mitosis, facilitating robust spindle assembly. However, despite a recent partial reconstitution of the human Augmin complex in vitro, the molecular basis of this recruitment remains unclear. Here, we used immuno-affinity purification of in vivo Augmin from Drosophila and cross-linking/mass spectrometry to identify distance restraints between residues within the eight Augmin subunits in the absence of any other structural information. The results allowed us to predict potential interfaces between Augmin and γ-TuRC. We tested these predictions biochemically and in the Drosophila embryo, demonstrating that specific regions of the Augmin subunits, Dgt3, Dgt5 and Dgt6 all directly bind the γ-TuRC protein, Dgp71WD, and are required for the accumulation of γ-TuRC, but not Augmin, to the mitotic spindle. This study therefore substantially increases our understanding of the molecular mechanisms underpinning MT-dependent MT nucleation.

Published

2017

8. Tubgcp3 Is Required for Retinal Progenitor Cell Proliferation During Zebrafish Development

Author

Guobao Li, Daqing Jin, and Tao P. Zhong

Subjects

γ-TuSC, γ-TuRC, tubgcp3, cell cycle, ciliary marginal zone, zebrafish, Neurosciences. Biological psychiatry. Neuropsychiatry, RC321-571

Abstract

The centrosomal protein γ-tubulin complex protein 3 (Tubgcp3/GCP3) is required for the assembly of γ-tubulin small complexes (γ-TuSCs) and γ-tubulin ring complexes (γ-TuRCs), which play critical roles in mitotic spindle formation during mitosis. However, its function in vertebrate embryonic development is unknown. Here, we generated the zebrafish tubgcp3 mutants using the CRISPR/Cas9 system and found that the tubgcp3 mutants exhibited the small eye phenotype. Tubgcp3 is required for the cell cycle progression of retinal progenitor cells (RPCs), and its depletion caused cell cycle arrest in the mitotic (M) phase. The M-phase arrested RPCs exhibited aberrant monopolar spindles and abnormal distributed centrioles and γ-tubulin. Moreover, these RPCs underwent apoptosis finally. Our study provides the in vivo model for the functional study of Tubgcp3 and sheds light on the roles of centrosomal γ-tubulin complexes in vertebrate development.

Published

2019

9. Dynamic life of a microtubule: From birth, growth and stabilization to damage and destruction

Subjects

CDK5RAP2, γ-TuRC, katanin, CAMSAPs, WDR47, TRIM46, Ankyrin-G, Microtubuli, Microtubules, CLASP2, chTOG

Abstract

Microtubules are one of the major types of cytoskeletal filaments in cells. They are very dynamic polymers composed of αβ-tubulin dimers arranged longitudinally in head-to-tail fashion as well as laterally to assemble 13-protofilament hollow cylindrical tubes. The incorporation of GTP-bound αβ-tubulin dimers generates a fast growing plus end exposing β-tubulin and a slow growing minus end exposing α-tubulin. In cells, microtubules are assembled de novo from a template, called γ-TuRC, which interacts with α-tubulin. Microtubules can either remain capped by γ-TuRC and anchored to the microtubule-organizing centers (MTOCs) or be released if they are cut by microtubule severing enzymes like katanin. The release of microtubules from MTOC generates free minus ends, which are then stabilized by minus-end binding proteins called CAMSAPs. However, the plus ends remain very dynamic and undergo transitions from growth to shrinkage, termed “catastrophes”, and the opposite transitions termed “rescues”. Numerous microtubule regulatory proteins act at the plus ends, minus ends and the microtubule shafts connecting the two ends to control the organization and density of cellular microtubule networks. In this thesis, we focused on each of these aspects and explored the dynamic life of microtubules by reconstituting these processes in vitro using purified proteins. We first focused on the birth and growth of microtubules. We reconstituted microtubule nucleation using purified γ-TuRC and microtubule regulatory proteins and showed that CDK5RAP2, CLASP2 and chTOG promoted microtubule nucleation from γ-TuRC. We discovered that CAMSAPs can bind to γ-TuRC-capped microtubule minus ends and displace γ-TuRC from these ends, generating free and stable microtubule minus ends. Furthermore, we found out that CDK5RAP2, but not CLASP2 or chTOG, can inhibit CAMSAP binding and microtubule release. We propose that the destiny of a microtubule depends on the type of protein complex that activates its nucleation. We then described a mechanism for stabilization of microtubule lattice by TRIM46, a neuronal protein, which can bundle parallel microtubules and promote microtubule rescues within these bundles. We also revealed that Ankyrin-G, a scaffold protein, can recruit TRIM46-stabilized microtubule bundles to the axonal membrane to drive the assembly of the axon initial segment in neurons. We also uncovered a new role of CLASP2 as a microtubule repair factor participating in microtubule maintenance. We demonstrated that CLASP2, an anti-catastrophe factor, can promote complete repair of damaged microtubule lattices by inhibiting microtubule depolymerization and promoting tube closure at the damage sites, causing lattice renewal. Finally, we described a three-protein module involving katanin, CAMSAPs, and WDR47 that can regulate microtubule polymer mass and minus-end stability. We showed that katanin can cut and amplify CAMSAP2/3-stabilized microtubule minus ends. WDR47 can inhibit the binding of katanin to CAMSAP2/3-stabilized minus ends and protect them from severing. The presence of WDR47 shifts the balance from microtubule amplification to minus-end growth regulation. To conclude, we obtained mechanistic insights into the regulation of microtubule nucleation, minus-end dynamics, lattice stabilization and maintenance, microtubule number and the interplay between microtubule regulatory proteins. These insights will help to understand how microtubule arrays are organized in cells.

Published

2023

10. Dynamic life of a microtubule: From birth, growth and stabilization to damage and destruction

Author

Rai, Dipti, Sub Cell Biology, Celbiologie, and Akhmanova, Anna

Subjects

CDK5RAP2, γ-TuRC, katanin, CAMSAPs, WDR47, TRIM46, Ankyrin-G, Microtubuli, Microtubules, CLASP2, chTOG

Abstract

Microtubules are one of the major types of cytoskeletal filaments in cells. They are very dynamic polymers composed of αβ-tubulin dimers arranged longitudinally in head-to-tail fashion as well as laterally to assemble 13-protofilament hollow cylindrical tubes. The incorporation of GTP-bound αβ-tubulin dimers generates a fast growing plus end exposing β-tubulin and a slow growing minus end exposing α-tubulin. In cells, microtubules are assembled de novo from a template, called γ-TuRC, which interacts with α-tubulin. Microtubules can either remain capped by γ-TuRC and anchored to the microtubule-organizing centers (MTOCs) or be released if they are cut by microtubule severing enzymes like katanin. The release of microtubules from MTOC generates free minus ends, which are then stabilized by minus-end binding proteins called CAMSAPs. However, the plus ends remain very dynamic and undergo transitions from growth to shrinkage, termed “catastrophes”, and the opposite transitions termed “rescues”. Numerous microtubule regulatory proteins act at the plus ends, minus ends and the microtubule shafts connecting the two ends to control the organization and density of cellular microtubule networks. In this thesis, we focused on each of these aspects and explored the dynamic life of microtubules by reconstituting these processes in vitro using purified proteins. We first focused on the birth and growth of microtubules. We reconstituted microtubule nucleation using purified γ-TuRC and microtubule regulatory proteins and showed that CDK5RAP2, CLASP2 and chTOG promoted microtubule nucleation from γ-TuRC. We discovered that CAMSAPs can bind to γ-TuRC-capped microtubule minus ends and displace γ-TuRC from these ends, generating free and stable microtubule minus ends. Furthermore, we found out that CDK5RAP2, but not CLASP2 or chTOG, can inhibit CAMSAP binding and microtubule release. We propose that the destiny of a microtubule depends on the type of protein complex that activates its nucleation. We then described a mechanism for stabilization of microtubule lattice by TRIM46, a neuronal protein, which can bundle parallel microtubules and promote microtubule rescues within these bundles. We also revealed that Ankyrin-G, a scaffold protein, can recruit TRIM46-stabilized microtubule bundles to the axonal membrane to drive the assembly of the axon initial segment in neurons. We also uncovered a new role of CLASP2 as a microtubule repair factor participating in microtubule maintenance. We demonstrated that CLASP2, an anti-catastrophe factor, can promote complete repair of damaged microtubule lattices by inhibiting microtubule depolymerization and promoting tube closure at the damage sites, causing lattice renewal. Finally, we described a three-protein module involving katanin, CAMSAPs, and WDR47 that can regulate microtubule polymer mass and minus-end stability. We showed that katanin can cut and amplify CAMSAP2/3-stabilized microtubule minus ends. WDR47 can inhibit the binding of katanin to CAMSAP2/3-stabilized minus ends and protect them from severing. The presence of WDR47 shifts the balance from microtubule amplification to minus-end growth regulation. To conclude, we obtained mechanistic insights into the regulation of microtubule nucleation, minus-end dynamics, lattice stabilization and maintenance, microtubule number and the interplay between microtubule regulatory proteins. These insights will help to understand how microtubule arrays are organized in cells.

Published

2023

11. Bi-allelic Pathogenic Variants in TUBGCP2 Cause Microcephaly and Lissencephaly Spectrum Disorders.

Author

Mitani, Tadahiro, Punetha, Jaya, Akalin, Ibrahim, Pehlivan, Davut, Dawidziuk, Mateusz, Coban Akdemir, Zeynep, Yilmaz, Sarenur, Aslan, Ezgi, Hunter, Jill V., Hijazi, Hadia, Grochowski, Christopher M., Jhangiani, Shalini N., Karaca, Ender, Fatih, Jawid M., Iwanowski, Piotr, Gambin, Tomasz, Wlasienko, Pawel, Goszczanska-Ciuchta, Alicja, Bekiesinska-Figatowska, Monika, and Hosseini, Masoumeh

Subjects

*MICROCEPHALY, *MICROTUBULE-associated proteins, *DEVELOPMENTAL delay, *DISEASES, *NEURAL development, *MICROTUBULES, *RECESSIVE genes

Abstract

Lissencephaly comprises a spectrum of malformations of cortical development. This spectrum includes agyria, pachygyria, and subcortical band heterotopia; each represents anatomical malformations of brain cortical development caused by neuronal migration defects. The molecular etiologies of neuronal migration anomalies are highly enriched for genes encoding microtubules and microtubule-associated proteins, and this enrichment highlights the critical role for these genes in cortical growth and gyrification. Using exome sequencing and family based rare variant analyses, we identified a homozygous variant (c.997C>T [p.Arg333Cys]) in TUBGCP2, encoding gamma-tubulin complex protein 2 (GCP2), in two individuals from a consanguineous family; both individuals presented with microcephaly and developmental delay. GCP2 forms the multiprotein γ-tubulin ring complex (γ-TuRC) together with γ-tubulin and other GCPs to regulate the assembly of microtubules. By querying clinical exome sequencing cases and through GeneMatcher-facilitated collaborations, we found three additional families with bi-allelic variation and similarly affected phenotypes including a homozygous variant (c.1843G>C [p.Ala615Pro]) in two families and compound heterozygous variants consisting of one missense variant (c.889C>T [p.Arg297Cys]) and one splice variant (c.2025-2A>G) in another family. Brain imaging from all five affected individuals revealed varying degrees of cortical malformations including pachygyria and subcortical band heterotopia, presumably caused by disruption of neuronal migration. Our data demonstrate that pathogenic variants in TUBGCP2 cause an autosomal recessive neurodevelopmental trait consisting of a neuronal migration disorder, and our data implicate GCP2 as a core component of γ-TuRC in neuronal migrating cells. [ABSTRACT FROM AUTHOR]

Published

2019

12. Tubgcp3 Is Required for Retinal Progenitor Cell Proliferation During Zebrafish Development.

Author

Li, Guobao, Jin, Daqing, and Zhong, Tao P.

Subjects

CELL proliferation, PROGENITOR cells, CELL cycle, BRACHYDANIO, SPINDLE apparatus

Abstract

The centrosomal protein γ-tubulin complex protein 3 (Tubgcp3/GCP3) is required for the assembly of γ-tubulin small complexes (γ-TuSCs) and γ-tubulin ring complexes (γ-TuRCs), which play critical roles in mitotic spindle formation during mitosis. However, its function in vertebrate embryonic development is unknown. Here, we generated the zebrafish tubgcp3 mutants using the CRISPR/Cas9 system and found that the tubgcp3 mutants exhibited the small eye phenotype. Tubgcp3 is required for the cell cycle progression of retinal progenitor cells (RPCs), and its depletion caused cell cycle arrest in the mitotic (M) phase. The M-phase arrested RPCs exhibited aberrant monopolar spindles and abnormal distributed centrioles and γ-tubulin. Moreover, these RPCs underwent apoptosis finally. Our study provides the in vivo model for the functional study of Tubgcp3 and sheds light on the roles of centrosomal γ-tubulin complexes in vertebrate development. [ABSTRACT FROM AUTHOR]

Published

2019

13. Centrosome Formation and Function: From self-assembly of pericentriolar material to microtubule organization

Author

Chen, Fangrui, Sub Cell Biology, Celbiologie, and Akhmanova, Anna

Subjects

Centrosome, MTOC, γ-TuRC, PCM, Centrosoom, self-assembly, microtubuli, zelforganiserend, microtubule

Abstract

The centrosome is the main microtubule organizing center (MTOC) in animal cells. It consists of a pair of centrioles surrounded by pericentriolar material (PCM) that nucleates and anchors microtubules. The binding of PCM to centrioles, PCM self-assembly and PCM transport by the microtubule-based motor dynein are the prerequisites for centrosome assembly, but the mechanisms of PCM self-assembly in interphase cells are poorly understood. Moreover, the relative importance of different molecular pathways of PCM assembly varies between different cell systems and different phases of the cell cycle. Previous studies have mostly focused on mitotic cells, but systematic investigations have not been performed in interphase cells. In addition, γ-tubulin ring complex (γ-TuRC) as template for microtubule assembly largely determines the function of MTOC, but the relative importance of different centrosomal components in microtubule nucleation and maintenance of microtubule networks has not been systematically investigated. Moreover, it is unclear whether γ-TuRC can nucleate microtubules and maintain microtubule arrays in mammalian cells in the absence of γ-TuRC adaptors. In this thesis, we address these questions. In addition to the PCM, the other major component of the centrosome are centrioles, microtubule-based organelles whose formation and elongation are regulated by a large number of specific proteins. In vitro reconstitution experiments showed that two centriole biogenesis factors, CPAP and CP110, cooperatively regulate microtubule plus-end growth in vitro, but the importance of their interaction for centriole formation has not been examined on cells. In this thesis, we investigated the role of the CPAP-CP110 interaction in regulating centriole elongation. In Chapter 2, we reported that when centrioles are lost due to either depletion or inhibition of PLK4, self-clustering of PCM proteins is sufficient to form a compact acentriolar MTOC (caMTOC) and thus organize a dense radial microtubule array in interphase cells. We showed that such self-clustering of PCM is dynein-dependent and requires pericentrin, CDK5RAP2, ninein and γ-tubulin, but not CEP192, NEDD1 and CEP152. We found that the formation of caMTOC is sensitive to the non-centrosomal MTOC pathways such as AKAP450-dependent PCM recruitment to the Golgi apparatus and CAMSAP2-mediated stabilization of free microtubule minus ends. We also reproduced the findings of our cellular experiments using computer simulations. In Chapter 3, we describe tools for comprehensive and systematic functional analysis of the complex regulatory pathways of microtubule nucleation and anchoring at mammalian centrosomes using a cellular model that simultaneously lacks multiple PCM components. We found that in cells lacking the non-centrosomal microtubule minus-end stabilization pathways, different γ-TuRC adaptors exert additive effects on microtubule nucleation and attachment at the centrosome, and knocking them out in interphase cells prevents γ-TuRC from generating a dense microtubule array, even though all positive regulators of microtubule dynamics, are still present. In Chapter 4, we examined the importance of CPAP-CP110 interaction in cells by replacing wild-type CPAP with CPAP mutants that cannot bind CP110. Our data indicate that centrioles, albeit shorter ones, could still form in the presence of the CPAP mutant, demonstrating that the CPAP-CP110 interaction is not essential for centriole formation, but promotes centriole elongation.

Published

2023

14. Centrosome Formation and Function: From self-assembly of pericentriolar material to microtubule organization

Subjects

Centrosome, MTOC, γ-TuRC, PCM, Centrosoom, self-assembly, microtubuli, zelforganiserend, microtubule

Abstract

The centrosome is the main microtubule organizing center (MTOC) in animal cells. It consists of a pair of centrioles surrounded by pericentriolar material (PCM) that nucleates and anchors microtubules. The binding of PCM to centrioles, PCM self-assembly and PCM transport by the microtubule-based motor dynein are the prerequisites for centrosome assembly, but the mechanisms of PCM self-assembly in interphase cells are poorly understood. Moreover, the relative importance of different molecular pathways of PCM assembly varies between different cell systems and different phases of the cell cycle. Previous studies have mostly focused on mitotic cells, but systematic investigations have not been performed in interphase cells. In addition, γ-tubulin ring complex (γ-TuRC) as template for microtubule assembly largely determines the function of MTOC, but the relative importance of different centrosomal components in microtubule nucleation and maintenance of microtubule networks has not been systematically investigated. Moreover, it is unclear whether γ-TuRC can nucleate microtubules and maintain microtubule arrays in mammalian cells in the absence of γ-TuRC adaptors. In this thesis, we address these questions. In addition to the PCM, the other major component of the centrosome are centrioles, microtubule-based organelles whose formation and elongation are regulated by a large number of specific proteins. In vitro reconstitution experiments showed that two centriole biogenesis factors, CPAP and CP110, cooperatively regulate microtubule plus-end growth in vitro, but the importance of their interaction for centriole formation has not been examined on cells. In this thesis, we investigated the role of the CPAP-CP110 interaction in regulating centriole elongation. In Chapter 2, we reported that when centrioles are lost due to either depletion or inhibition of PLK4, self-clustering of PCM proteins is sufficient to form a compact acentriolar MTOC (caMTOC) and thus organize a dense radial microtubule array in interphase cells. We showed that such self-clustering of PCM is dynein-dependent and requires pericentrin, CDK5RAP2, ninein and γ-tubulin, but not CEP192, NEDD1 and CEP152. We found that the formation of caMTOC is sensitive to the non-centrosomal MTOC pathways such as AKAP450-dependent PCM recruitment to the Golgi apparatus and CAMSAP2-mediated stabilization of free microtubule minus ends. We also reproduced the findings of our cellular experiments using computer simulations. In Chapter 3, we describe tools for comprehensive and systematic functional analysis of the complex regulatory pathways of microtubule nucleation and anchoring at mammalian centrosomes using a cellular model that simultaneously lacks multiple PCM components. We found that in cells lacking the non-centrosomal microtubule minus-end stabilization pathways, different γ-TuRC adaptors exert additive effects on microtubule nucleation and attachment at the centrosome, and knocking them out in interphase cells prevents γ-TuRC from generating a dense microtubule array, even though all positive regulators of microtubule dynamics, are still present. In Chapter 4, we examined the importance of CPAP-CP110 interaction in cells by replacing wild-type CPAP with CPAP mutants that cannot bind CP110. Our data indicate that centrioles, albeit shorter ones, could still form in the presence of the CPAP mutant, demonstrating that the CPAP-CP110 interaction is not essential for centriole formation, but promotes centriole elongation.

Published

2023

15. Molecular Mechanisms Involved in Chromosome Segregation

Author

Yatskevich, Stanislau

Subjects

gamma-Tubulin Ring Complex, γ-TuRC, kinetochores, anaphase-promoting complex (APC/C), Structural biology

Abstract

Eukaryotic organisms use large and intricate macromolecular machines to accurately pass chromosomes to two daughter cells during cell division. Errors during chromosome segregation are frequently deleterious to the cell and often result in aneuploidy leading to the formation of cancer cells. Kinetochores are large macromolecular machines that assemble specifically at the centromeric chromatin and act as a structural scaffold to support chromosome segregation. The inner kinetochore (CCAN) recognises centromere-specific CENPA nucleosome (CENP-ANuc) and couples it to the microtubules (MTs) of the mitotic spindle. In human cells, the details of CCAN-CENP-ANuc assembly are unknown. This thesis investigates the structure and assembly of the human CCAN-CENP- ANuc complex, showing that CCAN tightly grips the linker DNA of the CENPANuc. CENP-C emerges as the main recognition protein of the inner kinetochore. CCAN topologically entraps the linker DNA, explaining how it can withstand both pushing and pulling forces applied by the mitotic spindle. Kinetochores are also platforms for spindle assembly checkpoint (SAC) signalling, a pathway that ensures all chromosomes are correctly attached to the mitotic spindle prior to their segregation. The anaphase promoting complex/cyclosome (APC/C) is a key regulator of the anaphase transition, and SAC directly inhibits APC/C via a soluble mitotic checkpoint complex (MCC). While many molecular details of APC/C function are now known, recent data suggest that the APC/C is also SUMOylated but the function of this modification is unknown. To address the role of this modification, the APC/C was SUMOylated in vitro and the function of SUMOylated APC/C was investigated. We show that SUMOylation results in repositioning of a small domain of APC2, which sterically competes and displaces the MCC from APC/C. This allows a more robust APC/C reactivation during anaphase onset. Microtubule organising centres (MTOCs) nucleate and organise the mitotic spindle. The γ-tubulin Ring Complex (γ-TuRC) is a highly conserved part of MTOCs in most eukaryotes and it is essential for MT nucleation. The molecular mechanism of MT nucleation from γ-TuRC remains unclear. We have purified MTOC from yeast (known as Spindle Pole Body) and performed cryo-electron tomography analysis of native γ-TuRC complexes nucleating microtubules. We observed that γ-TuRC is a perfect symmetry match for MT nucleation and that additional factors allow efficient MT nucleation at native γ-TuRCs., Cambridge Trust Boehringer Ingelheim Fonds

Published

2023

16. γ-Tubulin small complex formation is essential for early zebrafish embryogenesis.

Author

Pouchucq, Luis, Undurraga, Cristian A., Fuentes, Ricardo, Cornejo, Mauricio, Allende, Miguel L., and Monasterio, Octavio

Subjects

*TUBULINS, *MICROTUBULES, *NUCLEATION, *ZEBRA danio, *CELL cycle proteins

Abstract

Abstract The centrosomal protein γ-tubulin is part of the cytoplasmic γ-tubulin small (γ-TuSCs) and large complexes (γ-TuRCs). Both, molecular and cellular evidence indicate that γ-tubulin plays a central role in microtubule nucleation and mitotic spindle formation. However, the molecular mechanisms of complex formation and subsequent biological roles in animal development remain unclear. Here, we used γ-tubulin gene knockdown in the zebrafish early embryo model to gain insights into its activity and cellular contribution during vertebrate embryogenesis. γ-Tubulin loss-of-function impaired γ-TuSC formation, impacting the microtubule nucleation rate in vitro. Moreover, decreased γ-tubulin synthesis caused dramatic defects in nuclear dynamics and cell cycle progression, leading to developmental arrest at the mid-gastrula stage. At the subcellular level, microtubule organization and function were altered, affecting chromosome segregation and triggering cell proliferation arrest and apoptosis. Our results suggest that de novo translated γ-tubulin participates in γ-TuSC formation required for early animal development. Importantly, formation of this complex is essential for both centrosome assembly and function, and cell proliferation. Thus, γ-TuSC integrity appears to be critical for cell cycle progression, and concomitantly, for coordinating the many distinct activities carried out by the early embryo. Our findings identify a novel role for γ-TuSC in the regulation of early vertebrate embryogenesis, providing molecular and biochemical starting points for future in depth studies of γ-tubulin functionality and its specific role in development. Highlights • In vivo blocking of γ-tubulin mRNA translation impairs γ-TuSC formation. • γ-TuSC formation is essential for the function of centrosomes and mitotic spindles during zebrafish embryogenesis. • γ-TuSC formation is essential for cell cycle progression and cell survival. [ABSTRACT FROM AUTHOR]

Published

2018

17. Regulation of γ-Tubulin Ring Complex Recruitment in Drosophila

Author

Tovey, Corinne

Subjects

γ-TuRC, Centrosomin, Microtubules, Mozart1

Abstract

Microtubule nucleation is catalysed by γ-tubulin ring complexes (γ-TuRCs) which are recruited to specific microtubule organising centres (MTOCs) within cells. The recruitment and activation of γ-TuRCs allows regulation of microtubule nucleation in both time and space. Mozart1 (Mzt1) is a recently-discovered component of the γ-TuRC which is important for the recruitment of γ-TuRCs to MTOCs, and therefore for cell division, in all systems in which it has so far been studied. Work in yeasts and cultured human cells suggests that Mzt1 is important for the binding of tethering proteins to the γ-TuRC, driving oligomerisation of the ring or activation of the γ-TuRC, and Mzt1 has been proposed to stabilise a hinge region in GCP3 which moves upon tethering-protein binding. In this thesis, I show that Mzt1 is a member of the γ-TuRC in Drosophila but that, surprisingly, its expression is restricted to the testes. This relatively simple finding has a major impact on the field, as it answers the longstanding question of whether γ-TuRC heterogeneity exists. Consistent with testes-specific expression, mzt1 null mutants are viable but develop male sterility as they age. Thus, unlike in other organisms, Drosophila Mzt1 is dispensable for cell division but is required for the production of sperm. Intriguingly, I found that Mzt1 is important for the recruitment of γ-TuRCs to the basal bodies but not to the mitochondrial derivatives of spermatids, demonstrating that γ-TuRC heterogeneity can exist even within the same cell at the same developmental stage. I have also found that differences between the centrosomal and testes-specific mitochondrial isoforms of the γ-TuRC tethering protein Centrosomin (Cnn) represent a means of regulating γ-TuRC recruitment and activity in a tissue-specific manner, and that this mechanism may be conserved in humans. I demonstrate that the extended N-terminus of centrosomal isoforms of Cnn is inhibitory to the CM1-domain-γ-TuRC interaction and that mutations that mimic phosphorylation within the N-terminus confer binding ability. Given that the centrosomal Cnn isoform is known to be phosphorylated specifically at centrosomes during mitosis, I propose that centrosome-specific phosphorylation events within the N-terminus relieve the CM1-domain inhibition. In contrast, the absence of the inhibitory N-terminal extension within the testes-specific Cnn isoforms allows these isoforms to bind γ-TuRCs at mitochondria, which lack mitotic kinases. This would provide cycling cells with control over when and where their γ-TuRCs are activated, contributing to the precise spatiotemporal regulation of spindle formation., BBSRC

Published

2020

18. New insights into subcomplex assembly and modifications of centrosomal proteins.

Author

Habermann, Karin and Lange, Bodo M. H.

Subjects

*CENTROSOMES, *PROTEOMICS, *PROTEIN-protein interactions, *CELL cycle, *MOLECULAR biology

Abstract

This review provides a brief overview of the recent work on centrosome proteomics, protein complex identification and functional characterization with an emphasis on the literature of the last three years. Proteomics, genetic screens and comparative genomics studies in different model organisms have almost exhaustively identified the molecular components of the centrosome. However, much knowledge is still missing on the protein-protein interactions, protein modifications and molecular changes the centrosome undergoes throughout the cell cycle and development. The dynamic nature of this large multi-protein complex is reflected in the variety of annotated subcellular locations and biological processes of its proposed components. Some centrosomal proteins and complexes have been studied intensively in different organisms and provided detailed insight into centrosome functions. For example, the molecular, structural and functional characterization of the γ-Tubulin ring complex (γ-TuRC) and the discovery of the Augmin/HAUS complex has advanced our understanding of microtubule (MT) capture, nucleation and organization. Surprising findings revealed new functions and localizations of proteins that were previously regarded as bona fide centriolar or centrosome components, e.g. at the kinetochore or in the nuclear pore complex regulating MT plus end capture or mRNA processing. Many centrosome components undergo posttranslational modifications such as phosphorylation, SUMOylation and ubiquitylation that are critical in modulating centrosome function and biology. A wealth of information has recently become available driven by new developments in technologies such as mass spectrometry, light and electron microscopy providing more detailed molecular and structural definition of the centrosome and particular roles of proteins throughout the cell cycle and development. [ABSTRACT FROM AUTHOR]

Published

2012

19. The role of Aspergillus nidulans polo-like kinase PlkA in microtubule-organizing center control.

Author

Xiaolei Gao, Herrero, Saturnino, Wernet, Valentin, Erhardt, Sylvia, Valerius, Oliver, Braus, Gerhard H., and Fischer, Reinhard

Subjects

*ASPERGILLUS nidulans, *SPINDLE apparatus, *PROTEIN receptors, *CATALYTIC activity, *CENTROSOMES

Abstract

Centrosomes are important microtubule-organizing centers (MTOC) in animal cells. In addition, non-centrosomal MTOCs (ncMTOCs) have been described in many cell types. The functional analogs of centrosomes in fungi are the spindle pole bodies (SPBs). In Aspergillus nidulans, additional MTOCs have been discovered at septa (sMTOC). Although the core components are conserved in both MTOCs, their composition and organization are different and dynamic. Here, we show that the polo-like kinase PlkA binds the γ-tubulin ring complex (γ-TuRC) receptor protein ApsB and contributes to targeting ApsB to both MTOCs. PlkA coordinates the activities of the SPB outer plaque and the sMTOC. PlkA kinase activity was required for astral MT formation involving ApsB recruitment. PlkA also interacted with the γ-TuRC inner plaque receptor protein PcpA. Mitosis was delayed without PlkA, and the PlkA protein was required for proper mitotic spindle morphology, although this function was independent of its catalytic activity. Our results suggest that the polo-like kinase is a regulator of MTOC activities and acts as a scaffolding unit through interaction with γ-TuRC receptors. [ABSTRACT FROM AUTHOR]

Published

2021

20. Promiscuous Binding of Microprotein Mozart1 to γ-Tubulin Complex Mediates Specific Subcellular Targeting to Control Microtubule Array Formation

Author

Shao-Win Wang, Hsiu-Jung Wang, Kuo-Chiang Hsia, Tzu-Lun Huang, and Ya-Chieh Chang

Subjects

0301 basic medicine, γ-TuRC, microtubule nucleation, Mitosis, Microtubules, Models, Biological, General Biochemistry, Genetics and Molecular Biology, Evolution, Molecular, 03 medical and health sciences, microprotein, 0302 clinical medicine, Protein Domains, Tubulin, Microtubule, Schizosaccharomyces, Humans, Interphase, Mozart1, lcsh:QH301-705.5, Conserved Sequence, Sequence Deletion, Microtubule nucleation, Tubulin complex, Chemistry, Microtubule cytoskeleton, Cell cycle, Subcellular localization, Yeast, Cell biology, Solutions, 030104 developmental biology, lcsh:Biology (General), Spindle Pole Bodies, Multiprotein Complexes, Schizosaccharomyces pombe Proteins, Microtubule-Associated Proteins, γ-TuRC targeting, Microtubule-Organizing Center, 030217 neurology & neurosurgery, Function (biology), Protein Binding, Subcellular Fractions

Abstract

Summary: How γ-tubulin ring complex (γ-TuRC), a master template for microtubule nucleation, is spatially and temporally regulated for the assembly of new microtubule arrays remains unclear. Here, we report that an evolutionarily conserved microprotein, Mozart1 (Mzt1), regulates subcellular targeting and microtubule formation activity of γ-TuRC at different cell cycle stages. Crystal structures of protein complexes demonstrate that Mzt1 promiscuously interacts with the N-terminal domains of multiple γ-tubulin complex protein subunits in γ-TuRC via an intercalative binding mode. Genetic- and microscopy-based analyses show that promiscuous binding of Mzt1 in γ-TuRC controls specific subcellular localization of γ-TuRC to modulate microtubule nucleation and stabilization in fission yeast. Moreover, we find Mzt1-independent targeting of γ-TuRC to be crucial for mitotic spindle assembly, demonstrating the cell-cycle-dependent regulation and function of γ-TuRC. Our findings reveal a microprotein-mediated regulatory mechanism underlying microtubule cytoskeleton formation, whereby Mzt1 binding promiscuity confers localization specificity on the multi-protein complex γ-TuRC.

Published

2020

21. γ-Tubulin⁻γ-Tubulin Interactions as the Basis for the Formation of a Meshwork

Author

Matthieu Corvaisier, Greta Eklund, Lisa Lindström, Maria Alvarado Kristensson, and Catalina Ana Rosselló

Subjects

0301 basic medicine, γ-TuRC, Cellular functions, γ-tubules, macromolecular substances, Spindle Apparatus, Review, Microtubules, Catalysis, Inorganic Chemistry, 03 medical and health sciences, meshwork, Microtubule, Tubulin, Animals, Humans, Physical and Theoretical Chemistry, Molecular Biology, Spectroscopy, Microtubule nucleation, γ-TuSC, biology, Chemistry, Organic Chemistry, General Medicine, Heterotetramer, Computer Science Applications, Cell biology, Cell and molecular biology, 030104 developmental biology, Cytoplasm, biology.protein, Tubulin Interactions, γ-strings, γ-tubulin, Protein Binding

Abstract

In cytoplasm, protein γ-tubulin joins with various γ-tubulin complex proteins (GCPs) to form a heterotetramer γ-tubulin small complex (γ-TuSC) that can grow into a ring-shaped structure called the γ-tubulin ring complex (γ-TuRC). Both γ-TuSC and γ-TuRC are required for microtubule nucleation. Recent knowledge on γ-tubulin with regard to its cellular functions beyond participation in its creation of microtubules suggests that this protein forms a cellular meshwork. The present review summarizes the recognized functions of γ-tubulin and aims to unite the current views on this protein.

Published

2018

22. Microtubule Organizing Centers Contain Testis-Specific γ-TuRC Proteins in Spermatids of Drosophila.

Author

Alzyoud E, Vedelek V, Réthi-Nagy Z, Lipinszki Z, and Sinka R

Abstract

Microtubule nucleation in eukaryotes is primarily promoted by γ-tubulin and the evolutionary conserved protein complex, γ-Tubulin Ring Complex (γ-TuRC). γ-TuRC is part of the centrosome and basal body, which are the best-known microtubule-organizing centers. Centrosomes undergo intensive and dynamic changes during spermatogenesis, as they turn into basal bodies, a prerequisite for axoneme formation during spermatogenesis. Here we describe the existence of a novel, tissue-specific γ-TuRC in Drosophila. We characterize three genes encoding testis-specific components of γ-TuRC (t-γ-TuRC) and find that presence of t-γ-TuRC is essential to male fertility. We show the diverse subcellular distribution of the t-γ-TuRC proteins during post-meiotic development, at first at the centriole adjunct and then also on the anterior tip of the nucleus, and finally, they appear in the tail region, close to the mitochondria. We also prove the physical interactions between the t-γ-TuRC members, γ-tubulin and Mozart1. Our results further indicate heterogeneity in γ-TuRC composition during spermatogenesis and suggest that the different post-meiotic microtubule organizing centers are orchestrated by testis-specific gene products, including t-γ-TuRC., Competing Interests: The authors declare that the research was conducted in the absence of any commercial or financial relationships that could be construed as a potential conflict of interest., (Copyright © 2021 Alzyoud, Vedelek, Réthi-Nagy, Lipinszki and Sinka.)

Published

2021

23. The role of Aspergillus nidulans polo-like kinase PlkA in microtubule-organizing center control.

Author

Gao X, Herrero S, Wernet V, Erhardt S, Valerius O, Braus GH, and Fischer R

Subjects

Animals, Centrosome, Microtubule-Associated Proteins genetics, Microtubules, Spindle Apparatus, Spindle Pole Bodies, Tubulin, Aspergillus nidulans genetics, Microtubule-Organizing Center

Abstract

Centrosomes are important microtubule-organizing centers (MTOC) in animal cells. In addition, non-centrosomal MTOCs (ncMTOCs) have been described in many cell types. The functional analogs of centrosomes in fungi are the spindle pole bodies (SPBs). In Aspergillus nidulans, additional MTOCs have been discovered at septa (sMTOC). Although the core components are conserved in both MTOCs, their composition and organization are different and dynamic. Here, we show that the polo-like kinase PlkA binds the γ-tubulin ring complex (γ-TuRC) receptor protein ApsB and contributes to targeting ApsB to both MTOCs. PlkA coordinates the activities of the SPB outer plaque and the sMTOC. PlkA kinase activity was required for astral MT formation involving ApsB recruitment. PlkA also interacted with the γ-TuRC inner plaque receptor protein PcpA. Mitosis was delayed without PlkA, and the PlkA protein was required for proper mitotic spindle morphology, although this function was independent of its catalytic activity. Our results suggest that the polo-like kinase is a regulator of MTOC activities and acts as a scaffolding unit through interaction with γ-TuRC receptors., Competing Interests: Competing interests The authors declare no competing or financial interests., (© 2021. Published by The Company of Biologists Ltd.)

Published

2021

24. Promiscuous Binding of Microprotein Mozart1 to γ-Tubulin Complex Mediates Specific Subcellular Targeting to Control Microtubule Array Formation.

Author

Huang, Tzu-Lun, Wang, Hsiu-Jung, Chang, Ya-Chieh, Wang, Shao-Win, and Hsia, Kuo-Chiang

Abstract

How γ-tubulin ring complex (γ-TuRC), a master template for microtubule nucleation, is spatially and temporally regulated for the assembly of new microtubule arrays remains unclear. Here, we report that an evolutionarily conserved microprotein, Mozart1 (Mzt1), regulates subcellular targeting and microtubule formation activity of γ-TuRC at different cell cycle stages. Crystal structures of protein complexes demonstrate that Mzt1 promiscuously interacts with the N-terminal domains of multiple γ-tubulin complex protein subunits in γ-TuRC via an intercalative binding mode. Genetic- and microscopy-based analyses show that promiscuous binding of Mzt1 in γ-TuRC controls specific subcellular localization of γ-TuRC to modulate microtubule nucleation and stabilization in fission yeast. Moreover, we find Mzt1-independent targeting of γ-TuRC to be crucial for mitotic spindle assembly, demonstrating the cell-cycle-dependent regulation and function of γ-TuRC. Our findings reveal a microprotein-mediated regulatory mechanism underlying microtubule cytoskeleton formation, whereby Mzt1 binding promiscuity confers localization specificity on the multi-protein complex γ-TuRC. • Mzt1 interacts with multiple γ-TuRC subunits via an intercalative binding mode • Promiscuous binding of Mzt1 to γ-TuRC modulates γ-TuRC assembly and targeting • Mzt1 regulates specific subcellular localization of γ-TuRC • γ-TuRC possesses functional heterogeneity, modulating microtubule formation Huang et al. demonstrate that the microprotein Mzt1 adopts an intercalative binding mode to tightly associate with N-terminal domains of multiple γ-TuRC subunits. Furthermore, they show that promiscuous binding of Mzt1 in γ-TuRC regulates γ-TuRC assembly and targeting, controlling subcellular localizations of γ-TuRC and modulating microtubule formation in fission yeast. [ABSTRACT FROM AUTHOR]

Published

2020

25. Reconstitution of the recombinant human γ-tubulin ring complex.

Author

Würtz M, Böhler A, Neuner A, Zupa E, Rohland L, Liu P, Vermeulen BJA, Pfeffer S, Eustermann S, and Schiebel E

Subjects

Animals, Humans, Microtubules chemistry, Microtubules metabolism, Recombinant Proteins chemistry, Recombinant Proteins metabolism, Sf9 Cells, Single Molecule Imaging, Spodoptera, Swine, Tubulin metabolism, Xenopus, Tubulin chemistry

Abstract

Cryo-electron microscopy recently resolved the structure of the vertebrate γ-tubulin ring complex (γ-TuRC) purified from Xenopus laevis egg extract and human cells to near-atomic resolution. These studies clarified the arrangement and stoichiometry of γ-TuRC components and revealed that one molecule of actin and the small protein MZT1 are embedded into the complex. Based on this structural census of γ-TuRC core components, we developed a recombinant expression system for the reconstitution and purification of human γ-TuRC from insect cells. The recombinant γ-TuRC recapitulates the structure of purified native γ-TuRC and has similar functional properties in terms of microtubule nucleation and minus end capping. This recombinant system is a central step towards deciphering the activation mechanisms of the γ-TuRC and the function of individual γ-TuRC core components.

Published

2021

26. Growth cone-localized microtubule organizing center establishes microtubule orientation in dendrites.

Author

Liang X, Kokes M, Fetter RD, Sallee MD, Moore AW, Feldman JL, and Shen K

Subjects

Animals, Caenorhabditis elegans metabolism, Caenorhabditis elegans growth & development, Dendrites metabolism, Growth Cones metabolism, Microtubule-Organizing Center metabolism, Microtubules metabolism

Abstract

A polarized arrangement of neuronal microtubule arrays is the foundation of membrane trafficking and subcellular compartmentalization. Conserved among both invertebrates and vertebrates, axons contain exclusively 'plus-end-out' microtubules while dendrites contain a high percentage of 'minus-end-out' microtubules, the origins of which have been a mystery. Here we show that in Caenorhabditis elegans the dendritic growth cone contains a non-centrosomal microtubule organizing center (MTOC), which generates minus-end-out microtubules along outgrowing dendrites and plus-end-out microtubules in the growth cone. RAB-11-positive endosomes accumulate in this region and co-migrate with the microtubule nucleation complex γ-TuRC. The MTOC tracks the extending growth cone by kinesin-1/UNC-116-mediated endosome movements on distal plus-end-out microtubules and dynein clusters this advancing MTOC. Critically, perturbation of the function or localization of the MTOC causes reversed microtubule polarity in dendrites. These findings unveil the endosome-localized dendritic MTOC as a critical organelle for establishing axon-dendrite polarity., Competing Interests: XL, MK, RF, MS, AM, JF No competing interests declared, KS Reviewing editor, eLife, (© 2020, Liang et al.)

Published

2020

27. Nucleation and dynamics of Golgi-derived microtubules

Author

Irina Kaverina and Anna A. W. M. Sanders

Subjects

γ-TuRC, Mini Review, microtubule nucleation, Golgi Apparatus, Biology, Bioinformatics, Clasps, Microtubules, lcsh:RC321-571, 03 medical and health sciences, symbols.namesake, CLASP1, 0302 clinical medicine, Microtubule, Golgi-derived microtubules, Cell polarity, lcsh:Neurosciences. Biological psychiatry. Neuropsychiatry, 030304 developmental biology, Microtubule nucleation, Psychiatry, 0303 health sciences, Golgi membrane, General Neuroscience, Microtubule organizing center, Golgi apparatus, microtubule dynamics, CLASP, Cell biology, Centrosome, symbols, 030217 neurology & neurosurgery, CLASP2

Abstract

Integrity of the Golgi apparatus requires the microtubule (MT) network. A subset of MTs originates at the Golgi itself, which in this case functions as a MT-organizing center (MTOC). Golgi-derived MTs serve important roles in post-Golgi trafficking, maintenance of Golgi integrity, cell polarity and motility, as well as cell type-specific functions, including neurite outgrowth/branching. Here, we discuss possible models describing the formation and dynamics of Golgi-derived MTs. How Golgi-derived MTs are formed is not fully understood. A widely discussed model implicates that the critical step of the process is recruitment of mo-lecular factors, which drive MT nucleation (γ-tubulin ring complex, or γ-TuRC), to the Golgi membrane via specific scaffolding interactions. Based on recent findings, we propose to introduce an additional level of regulation, whereby MT-binding proteins and/or local tubulin dimer concentration at the Golgi helps to overcome kinetic barriers at the initial nucleation step. According to our model, emerging MTs are subsequently stabilized by Golgi-associated MT-stabilizing proteins. We discuss molecular factors potentially involved in all three steps of MT formation. To preserve proper cell functioning, a balance must be maintained between MT subsets at the centrosome and the Golgi. Recent work has shown that certain centrosomal factors are important in maintaining this balance, suggesting a close connection between regulation of centrosomal and Golgi-derived MTs. Finally, we will discuss potential functions of Golgi-derived MTs based on their nucleation site location within a Golgi stack.

Published

2015

28. γ-Tubulin–γ-Tubulin Interactions as the Basis for the Formation of a Meshwork.

Author

Rosselló, Catalina Ana, Lindström, Lisa, Eklund, Greta, Corvaisier, Matthieu, and Kristensson, Maria Alvarado

Subjects

*MICROTUBULES, *CYTOPLASM, *TUBULINS, *ORGANELLES, *PROTEINS

Abstract

In cytoplasm, protein γ-tubulin joins with various γ-tubulin complex proteins (GCPs) to form a heterotetramer γ-tubulin small complex (γ-TuSC) that can grow into a ring-shaped structure called the γ-tubulin ring complex (γ-TuRC). Both γ-TuSC and γ-TuRC are required for microtubule nucleation. Recent knowledge on γ-tubulin with regard to its cellular functions beyond participation in its creation of microtubules suggests that this protein forms a cellular meshwork. The present review summarizes the recognized functions of γ-tubulin and aims to unite the current views on this protein. [ABSTRACT FROM AUTHOR]

Published

2018

29. New insights into subcomplex assembly and modifications of centrosomal proteins

Author

Bodo Lange and Karin Habermann

Subjects

Comparative genomics, Centrosome, γ-TuRC, Kinetochore, lcsh:Cytology, SUMO protein, Review, Cell Biology, Biology, Proteomics, lcsh:Neoplasms. Tumors. Oncology. Including cancer and carcinogens, Augmin/HAUS complex, lcsh:RC254-282, Biochemistry, Cell biology, Microtubule, HAUS complex, Nuclear pore, lcsh:QH573-671, Molecular Biology

Abstract

This review provides a brief overview of the recent work on centrosome proteomics, protein complex identification and functional characterization with an emphasis on the literature of the last three years. Proteomics, genetic screens and comparative genomics studies in different model organisms have almost exhaustively identified the molecular components of the centrosome. However, much knowledge is still missing on the protein-protein interactions, protein modifications and molecular changes the centrosome undergoes throughout the cell cycle and development. The dynamic nature of this large multi-protein complex is reflected in the variety of annotated subcellular locations and biological processes of its proposed components. Some centrosomal proteins and complexes have been studied intensively in different organisms and provided detailed insight into centrosome functions. For example, the molecular, structural and functional characterization of the γ-Tubulin ring complex (γ-TuRC) and the the discovery of the Augmin/HAUS complex has advanced our understanding of microtubule (MT) capture, nucleation and organization. Surprising findings revealed new functions and localizations of proteins that were previously regarded as bona fide centriolar or centrosome components, e.g. at the kinetochore or in the nuclear pore complex regulating MT plus end capture or mRNA processing. Many centrosome components undergo posttranslational modifications such as phosphorylation, SUMOylation and ubiquitylation that are critical in modulating centrosome function and biology. A wealth of information has recently become available driven by new developments in technologies such as mass spectrometry, light and electron microscopy providing more detailed molecular and structural definition of the centrosome and particular roles of proteins throughout the cell cycle and development.

Published

2012

30. A Splice Variant of Centrosomin Converts Mitochondria to Microtubule-Organizing Centers.

Author

Chen, Jieyan V., Buchwalter, Rebecca A., Kao, Ling-Rong, and Megraw, Timothy L.

Subjects

*CENTROSOMIN, *MITOCHONDRIAL physiology, *MICROTUBULE organizing centers (Cytology), *GERM cell anatomy, *SPERMIOGENESIS in animals

Abstract

Summary Non-centrosomal microtubule organizing centers (MTOCs) direct microtubule (MT) organization to exert diverse cell-type-specific functions. In Drosophila spermatids, the giant mitochondria provide structural platforms for MT reorganization to support elongation of the extremely long sperm. However, the molecular basis for this mitochondrial MTOC and other non-centrosomal MTOCs has not been discerned. Here we report that Drosophila centrosomin ( cnn ) expresses two major protein variants: the centrosomal form (CnnC) and a non-centrosomal form in testes (CnnT). CnnC is established as essential for functional centrosomes, the major MTOCs in animal cells. We show that CnnT is expressed exclusively in testes by alternative splicing and localizes to giant mitochondria in spermatids. In cell culture, CnnT targets to the mitochondrial surface, recruits the MT nucleator γ-tubulin ring complex (γ-TuRC), and is sufficient to convert mitochondria to MTOCs independent of core pericentriolar proteins that regulate MT assembly at centrosomes. We mapped two separate domains in CnnT: one that is necessary and sufficient to target it to mitochondria and another that is necessary and sufficient to recruit γ-TuRCs and nucleate MTs. In elongating spermatids, CnnT forms speckles on the giant mitochondria that are required to recruit γ-TuRCs to organize MTs and support spermiogenesis. This molecular characterization of the mitochondrial MTOC defines a minimal molecular requirement for MTOC generation and implicates the potent role of Cnn (or its related) proteins in the direct regulation of MT assembly and organization of non-centrosomal MTOCs. [ABSTRACT FROM AUTHOR]

Published

2017

31. Cross-linking mass spectrometry identifies new interfaces of Augmin required to localise the γ-tubulin ring complex to the mitotic spindle.

Author

Chen JWC, Chen ZA, Rogala KB, Metz J, Deane CM, Rappsilber J, and Wakefield JG

Abstract

The hetero-octameric protein complex, Augmin, recruits γ-Tubulin ring complex (γ-TuRC) to pre-existing microtubules (MTs) to generate branched MTs during mitosis, facilitating robust spindle assembly. However, despite a recent partial reconstitution of the human Augmin complex in vitro , the molecular basis of this recruitment remains unclear. Here, we used immuno-affinity purification of in vivo Augmin from Drosophila and cross-linking/mass spectrometry to identify distance restraints between residues within the eight Augmin subunits in the absence of any other structural information. The results allowed us to predict potential interfaces between Augmin and γ-TuRC. We tested these predictions biochemically and in the Drosophila embryo, demonstrating that specific regions of the Augmin subunits, Dgt3, Dgt5 and Dgt6 all directly bind the γ-TuRC protein, Dgp71WD, and are required for the accumulation of γ-TuRC, but not Augmin, to the mitotic spindle. This study therefore substantially increases our understanding of the molecular mechanisms underpinning MT-dependent MT nucleation., Competing Interests: Competing interestsThe authors declare no competing or financial interests., (© 2017. Published by The Company of Biologists Ltd.)

Published

2017

32. Nucleation and Dynamics of Golgi-derived Microtubules.

Author

Sanders AA and Kaverina I

Abstract

Integrity of the Golgi apparatus requires the microtubule (MT) network. A subset of MTs originates at the Golgi itself, which in this case functions as a MT-organizing center (MTOC). Golgi-derived MTs serve important roles in post-Golgi trafficking, maintenance of Golgi integrity, cell polarity and motility, as well as cell type-specific functions, including neurite outgrowth/branching. Here, we discuss possible models describing the formation and dynamics of Golgi-derived MTs. How Golgi-derived MTs are formed is not fully understood. A widely discussed model implicates that the critical step of the process is recruitment of molecular factors, which drive MT nucleation (γ-tubulin ring complex, or γ-TuRC), to the Golgi membrane via specific scaffolding interactions. Based on recent findings, we propose to introduce an additional level of regulation, whereby MT-binding proteins and/or local tubulin dimer concentration at the Golgi helps to overcome kinetic barriers at the initial nucleation step. According to our model, emerging MTs are subsequently stabilized by Golgi-associated MT-stabilizing proteins. We discuss molecular factors potentially involved in all three steps of MT formation. To preserve proper cell functioning, a balance must be maintained between MT subsets at the centrosome and the Golgi. Recent work has shown that certain centrosomal factors are important in maintaining this balance, suggesting a close connection between regulation of centrosomal and Golgi-derived MTs. Finally, we will discuss potential functions of Golgi-derived MTs based on their nucleation site location within a Golgi stack.

Published

2015

33. Functional replacement of fission yeast γ-tubulin small complex proteins Alp4 and Alp6 by human GCP2 and GCP3.

Author

Riehlman TD, Olmsted ZT, Branca CN, Winnie AM, Seo L, Cruz LO, and Paluh JL

Subjects

Amino Acid Sequence, Humans, Microtubule-Associated Proteins genetics, Models, Molecular, Molecular Sequence Data, Protein Structure, Secondary, Schizosaccharomyces genetics, Schizosaccharomyces metabolism, Schizosaccharomyces pombe Proteins genetics, Tubulin chemistry, Tubulin genetics, Microtubule-Associated Proteins metabolism, Schizosaccharomyces pombe Proteins metabolism, Tubulin metabolism

Abstract

Microtubule-organizing centers such as the γ-tubulin ring complex (γ-TuRC) act as a template for polarized growth and regulation of microtubules that are essential for diverse cellular structures and processes in eukaryotes. New structural models of the budding yeast γ-tubulin small complex (γ-TuSC) of the γ-TuRC combined with functional studies done in multiple eukaryotes are revealing the first mechanistic clues into control of microtubule nucleation and organization. Cross-species studies of human and budding yeast γ-TuSC proteins in fission yeast revealed conserved and divergent structural and functional features of the γ-TuSC. We show genetically that GCP3/Spc98 function is fully conserved with Alp6 across species but that functional differences exist between GCP2/Spc97 and Alp4. By further analysis of human γ-TuSC proteins, we found that GCP3 assembles normally into the >2000 kDa fission yeast γ-TuRC and that the GCP3 gene replaces fission yeast alp6. Interestingly, human GCP2 replaces the essential alp4 gene but is unable to rescue a normally recessive G1 defect of the alp4-1891 allele that results in loss of γ-TuRC from poles in subsequent cell cycles. Biochemically, GCP2 incorporation into fission yeast γ-TuRC is limited in the presence of Alp4; instead, the bulk of GCP2 fractionates as smaller complexes. By generating a functional Alp4-GCP2 chimeric protein we determined that the GCP2 N-terminal domain limits its ability to fully displace or compete with Alp4 during γ-TuRC assembly. Our findings have broad importance for understanding the essential domains of γ-TuSC proteins in the γ-TuRC mechanism.

Published

2013