Your search keyword '"Centriole assembly"' showing total 188 results

1. Multiple G-quadruplex binding ligand induced transcriptomic map of cancer cell lines.

Author

Revikumar, Amjesh, Kashyap, Vivek, Palollathil, Akhina, Aravind, Anjana, Raguraman, Rajeswari, Kumar, Kenkere Mallikarjunaiah Kiran, Vijayakumar, Manavalan, Prasad, Thottethodi Subrahmanya Keshava, and Raju, Rajesh

Abstract

The G-quadruplexes (G4s) are a class of DNA secondary structures with guanine rich DNA sequences that can fold into four stranded non-canonical structures. At the genomic level, their pivotal role is well established in DNA replication, telomerase functions, constitution of topologically associating domains, and the regulation of gene expression. Genome instability mediated by altered G4 formation and assembly has been associated with multiple disorders including cancers and neurodegenerative disorders. Multiple tools have also been developed to predict the potential G4 regions in genomes and the whole genome G4 maps are also being derived through sequencing approaches. Enrichment of G4s in the cis-regulatory elements of genes associated with tumorigenesis has accelerated the quest for identification of G4-DNA binding ligands (G4DBLs) that can selectively bind and regulate the expression of such specific genes. In this context, the analysis of G4DBL responsive transcriptome in diverse cancer cell lines is inevitable for assessment of the specificity of novel G4DBLs. Towards this, we assembled the transcripts differentially regulated by different G4DBLs and have also identified a core set of genes regulated in diverse cancer cell lines in response to 3 or more of these ligands. With the mode of action of G4DBLs towards topology shifts, folding, or disruption of G4 structure being currently visualized, we believe that this dataset will serve as a platform for assembly of G4DBL responsive transcriptome for comparative analysis of G4DBLs in multiple cancer cells based on the expression of specific cis-regulatory G4 associated genes in the future. [ABSTRACT FROM AUTHOR]

Published

2022

2. Triple deletion ofTP53, PCNT, andCEP215promotes centriole amplification in the M phase

Author

Kunsoo Rhee and Gee In Jung

Subjects

Centriole, Mitosis, Cell Cycle Proteins, Nerve Tissue Proteins, Biology, Gene Knockout Techniques, PCNT, Humans, Antigens, Molecular Biology, Centrioles, Pericentriolar material, Cell Biology, Cell biology, Centrosome, Interphase, CEP135, Tumor Suppressor Protein p53, Cell Division, Gene Deletion, Research Paper, HeLa Cells, Signal Transduction, Developmental Biology, Centriole assembly

Abstract

Supernumerary centrioles are frequently observed in diverse types of cancer cells. In this study, we investigated the mechanism underlying the generation of supernumerary centrioles during the M phase. We generated the TP53;PCNT;CEP215 triple knockout (KO) cells and determined the configurations of the centriole during the cell cycle. The triple KO cells exhibited a precocious separation of centrioles and unscheduled centriole assembly in the M phase. Supernumerary centrioles in the triple KO cells were present throughout the cell cycle; however, among all the centrioles, only two maintained an intact composition, including CEP135, CEP192, CEP295 and CEP152. Intact centrioles were formed during the S phase and the rest of the centrioles may be generated during the M phase. M-phase-assembled centrioles lacked the ability to organize microtubules in the interphase; however, a fraction of them may acquire pericentriolar material to organize microtubules during the M phase. Taken together, our work reveals the heterogeneity of the supernumerary centrioles in the triple KO cells. .

Published

2021

3. Production of Basal Bodies in bulk for dense multicilia formation [version 1; referees: 2 approved]

Author

Xiumin Yan, Huijie Zhao, and Xueliang Zhu

Subjects

Review, Articles, Cell Growth & Division, Control of Gene Expression, Cytoskeleton, ciliogenesis, centriole assembly, Deuterosome, deuterosome-dependent

Abstract

Centriole number is normally under tight control and is directly linked to ciliogenesis. In cells that use centrosomes as mitotic spindle poles, one pre-existing mother centriole is allowed to duplicate only one daughter centriole per cell cycle. In multiciliated cells, however, many centrioles are generated to serve as basal bodies of the cilia. Although deuterosomes were observed more than 40 years ago using electron microscopy and are believed to produce most of the basal bodies in a mother centriole-independent manner, the underlying molecular mechanisms have remained unknown until recently. From these findings arise more questions and a call for clarifications that will require multidisciplinary efforts.

Published

2016

4. PLK4 phosphorylation of CP110 is required for efficient centriole assembly.

Author

Lee, Miseon, Seo, Mi Young, Chang, Jaerak, Hwang, Deog Su, and Rhee, Kunsoo

Abstract

Centrioles are assembled during S phase and segregated into 2 daughter cells at the end of mitosis. The initiation of centriole assembly is regulated by polo-like kinase 4 (PLK4), the major serine/threonine kinase in centrioles. Despite its importance in centriole duplication, only a few substrates have been identified, and the detailed mechanism of PLK4 has not been fully elucidated. CP110 is a coiled-coil protein that plays roles in centriolar length control and ciliogenesis in mammals. Here, we revealed that PLK4 specifically phosphorylates CP110 at the S98 position. The phospho-resistant CP110 mutant inhibited centriole assembly, whereas the phospho-mimetic CP110 mutant induced centriole assembly, even in PLK4-limited conditions. This finding implies that PLK4 phosphorylation of CP110 is an essential step for centriole assembly. The phospho-mimetic form of CP110 augmented the centrosomal SAS6 level. Based on these results, we propose that the phosphorylated CP110 may be involved in the stabilization of cartwheel SAS6 during centriole assembly. [ABSTRACT FROM PUBLISHER]

Published

2017

5. Aufreinigung und Kristallisationsversuche der Proteine Gorab und Sas6 der Spezies Drosophila zum Zweck der Strukturaufklärung

Author

Iby, Lara

Subjects

Golgin-Proteine, centrioles, centriole assembly, Ciliogenese, X-ray, Rab6, protein purification, Zentriolen-Wagenrad, centriole-cartwheel, structural biology, Zusammenbau der Zentriolen, crystallography, Sas6, Strukturbiologie, bifunktionelle Proteine, Röntgenstrukturanalyse, Aufreinigung von Proteinen, Gorab, Zentrosom, golgin proteins, Zentriolen, Drosophila melanogaster, centrosome, Kristallographie, bifunctional proteins, ciliogenesis

Abstract

Ziel dieser Arbeit war es, die Proteine Gorab und Sas6 aus Drosophila melanogaster aufzureinigen und im Anschluss zu kristallisieren, um mehr über den strukturellen Charakter der Interaktion beider Proteine an den Zentriolen während der Zentriolen-Biogenese herauszufinden. Bezüglich des Zusammenbaus der Zentriolen wurden bereits etliche Faktoren ermittelt, die eine Rolle spielen. Der genaue molekulare Mechanismus konnte bisher jedoch noch nicht enthüllt werden. Es werden immer wieder neue Faktoren ermittelt, die in diesen Prozess eingreifen. Eines dieser Proteine in D.melanogaster war Gorab, das als bisher noch nicht charakterisierte Komponente der Zentriolen identifiziert wurde. In der vorliegenden Arbeit soll die Rolle Gorabs beim Zusammenbau der Zentriolen und seine Interaktion mit einem der wichtigsten Proteine des sogenannten ''Zentriolen-Wagenrads'', Sas6, beleuchten. Dafür werden Gorab und Sas6 co-exprimiert und aufgereinigt. Der daraus erhaltene Proteinkomplex soll dazu dienen, Kristallisationsverusche anzusetzen, um mithilfe der Protein-Kristalle mithilfe der Röntgenstrukturanalyse die Struktur aufzuklären. Das soll Einblick in die strukturellen Komponenten der Interaktion zwischen Gorab und Sas6 bieten. Das Endziel besteht darin, den molekularen Mechanismus am äußeren Rand des Wagenrads wahrend dem Zusammenbau der Zentriolen aufzuklären, sowie die genauen Aminosäurensequenzen zu definieren, die in die Interaktion involviert sind. Im Zuge dieser Arbeit wurden Abschnitte der Proteine Gorab und Sas6 erfolgreich aufgereinigt und jeweils Kristalle bei Raumtemperatur und 4°C angesetzt. Bisher blieb eine Bildung von Proteinkristallen jedoch aus. Daher konnte keine Röntgenstrukturanalyse zur Strukturbestimmung durchgeführt werden. Das Hauptaugenmerk liegt daher auf dem Aufreinigungsprozess der Proteine. The aim of this study is the purification and subsequent crystallization of the proteins Gorab and Sas6 derived from Drosophila melanogaster to explore the structural details of their interaction at the centriole cartwheel during centriole biogenesis. Regarding the centriole assembly, multiple essential components have already been identified, but the exact molecular mechanism have not yet been fully revealed. Frequently, new factors have been described which affect the process of centriole biogenesis. In this context, protein Gorab in D.melanogaster was newly identified as an uncharacterized centriolar component. The purpose of this work is to dissect the role of Gorab during centriole assembly and to describe its interaction with the main cartwheel protein Sas6. For this, Gorab and Sas6 are co-expressed and purified. The obtained protein complex is then used to set up crystallization trials for structure determination using X-ray crystallography. This will provide insights into the structural components of the interaction between the two structural components, Sas6 and Gorab. The ultimate aim is to define the molecular mechanism on the outer edge of the centriole cartwheel during centriole assembly between Gorab and Sas6 and to identify the exact amino acid sequences of both proteins involved in this process. During this work, some truncations of Gorab and of Sas6 involved in the interaction were successfully purified and crystal plates were set up at room temperature and at 4°C. Up to now, no crystals have been obtained yet. Therefore, structure determination via X-ray crystallography was not conducted. The focus of this work lies on the purification of the proteins.

Published

2022

6. Polo-like kinase 4 homodimerization is not required for catalytic activation, autodestruction, or centriole assembly

Author

Kevin C. Slep, Cody J. Boese, Anastasia Amoiroglou, Lauren K. Slevin, Spencer Dean, John M. Ryniawec, Gregory C. Rogers, and Daniel W. Buster

Subjects

PLK4, Protein kinase domain, Centriole, Mitotic exit, Centrosome, Chemistry, Polo-like kinase, Degron, Cell biology, Centriole assembly

Abstract

Polo-like kinase 4 (Plk4) is the master-regulator of centriole assembly and cell cycle-dependent regulation of its activity maintains proper centrosome number. During most of the cell cycle, Plk4 levels are nearly undetectable due to its ability to autophosphorylate and trigger its own ubiquitin-mediated degradation. However, during mitotic exit, Plk4 forms a single aggregate on the centriole surface to stimulate centriole duplication. Whereas most Polo-like kinase family members are monomeric, Plk4 is unique because it forms homodimers. Notably, Plk4 trans-autophosphorylates a degron near its kinase domain, a critical step in autodestruction. While it is thought that the purpose of homodimerization is to promote trans-autophosphorylation, this has not been tested. Here, we generate separation-of-function Plk4 mutants that fail to dimerize, and we show that homodimerization is required to create a binding site for the Plk4 activator, Asterless. Surprisingly, Plk4 dimer mutants are catalytically active in cells, promote centriole assembly, and can trans-autophosphorylate by a process based its on concentration-dependent aggregation. Our findings implicate a concentration-dependent pathway of Plk4 activation that does not require Asterless binding or homodimerization. Lastly, we propose a model of Plk4 cell cycle regulation that utilizes both activation pathways – Asterless-dependent and aggregation-driven – to restrict centriole assembly to mother centrioles.

Published

2021

7. Kinetic and structural roles for the surface in guiding SAS-6 self-assembly to direct centriole architecture

Author

Frieda A. Sorgenfrei, Svenja Svenja de Buhr, Niccolò Banterle, Frauke Gräter, Ulrich S. Schwarz, Georg E. Fantner, Tania Hübscher, Georgios N. Hatzopoulos, Adrian P. Nievergelt, Pierre Gönczy, Santiago H. Andany, and Charlène Brillard

Subjects

Organelle assembly, Centriole, Protein Conformation, Science, Stacking, General Physics and Astronomy, Cell Cycle Proteins, Molecular Dynamics Simulation, Microscopy, Atomic Force, Article, Supramolecular assembly, General Biochemistry, Genetics and Molecular Biology, Molecular dynamics, fragmentation, Organelle, centrosomes, coagulation, Centrioles, Organelles, Organelle Biogenesis, Multidisciplinary, Cilium, cilia, Proteins, dynamics, General Chemistry, organization, field, Kinetics, duplication, Models, Chemical, Biophysics, Protein Multimerization, reveals, Chlamydomonas reinhardtii, Centriole assembly

Abstract

Discovering mechanisms governing organelle assembly is a fundamental pursuit in biology. The centriole is an evolutionarily conserved organelle with a signature 9-fold symmetrical chiral arrangement of microtubules imparted onto the cilium it templates. The first structure in nascent centrioles is a cartwheel, which comprises stacked 9-fold symmetrical SAS-6 ring polymers emerging orthogonal to a surface surrounding each resident centriole. The mechanisms through which SAS-6 polymerization ensures centriole organelle architecture remain elusive. We deploy photothermally-actuated off-resonance tapping high-speed atomic force microscopy to decipher surface SAS-6 self-assembly mechanisms. We show that the surface shifts the reaction equilibrium by ~104 compared to solution. Moreover, coarse-grained molecular dynamics and atomic force microscopy reveal that the surface converts the inherent helical propensity of SAS-6 polymers into 9-fold rings with residual asymmetry, which may guide ring stacking and impart chiral features to centrioles and cilia. Overall, our work reveals fundamental design principles governing centriole assembly., The centriole exhibits an evolutionarily conserved 9-fold radial symmetry that stems from a cartwheel containing vertically stacked ring polymers that harbor 9 homodimers of the protein SAS-6. Here the authors show how dual properties inherent to surface-guided SAS-6 self-assembly possess spatial information that dictates correct scaffolding of centriole architecture.

Published

2021

8. CEP295 interacts with microtubules and is required for centriole elongation.

Author

Ching-Wen Chang, Wen-Bin Hsu, Jhih-Jie Tsai, Tang, Chieh-Ju C., and Tang, Tang K.

Subjects

*CENTRIOLES, *MICROTUBULES, *ELONGATION factors (Biochemistry), *ELECTRON microscopy, *GENE expression

Abstract

Centriole duplication is a tightly ordered process during which procentrioles are assembled in G1-S and elongate during S and G2. Here, we show that human CEP295 (Drosophila Ana1) is not essential for initial cartwheel assembly, but is required to build distal half centrioles during S and G2. Using super-resolution and immunogold electron microscopy, we demonstrate that CEP295 is recruited to the proximal end of procentrioles in early S phase, when it is also localized at the centriolar microtubule wall that surrounds the human SAS6 cartwheel hub. Interestingly, depletion of CEP295 not only inhibits the recruitments of POC5 and POC1B to the distal half centrioles in G2, resulting in shorter centrioles, it also blocks the post-translational modification of centriolar microtubules (e.g. acetylation and glutamylation). Importantly, our results indicate that CEP295 directly interacts with microtubules, and that excess CEP295 could induce the assembly of overly long centrioles. Furthermore, exogenous expression of the N-terminal domain of CEP295 exerts a dominant-negative effect on centriole elongation. Collectively, these findings suggest that CEP295 is essential for building the distal half centrioles and for post-translational modification of centriolar microtubules. [ABSTRACT FROM AUTHOR]

Published

2016

9. The SON RNA splicing factor is required for intracellular trafficking structures that promote centriole assembly and ciliogenesis

Author

Eileen T. O'Toole, Alexander J. Stemm-Wolf, Ryan M. Sheridan, Jacob T. Morgan, and Chad G. Pearson

Subjects

Gene Expression, Cell Cycle Proteins, Biology, Microtubules, Cell Line, Minor Histocompatibility Antigens, Microtubule, Ciliogenesis, Humans, Cilia, Molecular Biology, Centrioles, Centrosome, Centriole duplication, Cell Biology, Articles, Cell biology, DNA-Binding Proteins, Cytoskeletal Proteins, Protein Transport, RNA splicing, RNA, Centriolar satellite, RNA Splicing Factors, human activities, Intracellular, Centriole assembly

Abstract

Control of centrosome assembly is critical for cell division, intracellular trafficking, and cilia. Regulation of centrosome number occurs through the precise duplication of centrioles that reside in centrosomes. Here we explored transcriptional control of centriole assembly and find that the RNA splicing factor SON is specifically required for completing procentriole assembly. Whole genome mRNA sequencing identified genes whose splicing and expression are affected by the reduction of SON, with an enrichment in genes involved in the microtubule (MT) cytoskeleton, centrosome, and centriolar satellites. SON is required for the proper splicing and expression of CEP131, which encodes a major centriolar satellite protein and is required to organize the trafficking and MT network around the centrosomes. This study highlights the importance of the distinct MT trafficking network that is intimately associated with nascent centrioles and is responsible for procentriole development and efficient ciliogenesis.

Published

2021

10. Multiple G-quadruplex binding ligand induced transcriptomic map of cancer cell lines

Author

Rajesh Raju, Rajeswari Raguraman, Kenkere M. Kiran Kumar, M. Vijayakumar, Vivek Kashyap, Anjana Aravind, Amjesh Revikumar, Akhina Palollathil, and Thottethodi Subrahmanya Keshava Prasad

Subjects

Genome instability, NUTS and BOLTS, DNA replication, Cell Biology, Computational biology, Biology, medicine.disease_cause, Biochemistry, Genome, DNA sequencing, Transcriptome, medicine, Carcinogenesis, Molecular Biology, Gene, Centriole assembly

Abstract

The G-quadruplexes (G4s) are a class of DNA secondary structures with guanine rich DNA sequences that can fold into four stranded non-canonical structures. At the genomic level, their pivotal role is well established in DNA replication, telomerase functions, constitution of topologically associating domains, and the regulation of gene expression. Genome instability mediated by altered G4 formation and assembly has been associated with multiple disorders including cancers and neurodegenerative disorders. Multiple tools have also been developed to predict the potential G4 regions in genomes and the whole genome G4 maps are also being derived through sequencing approaches. Enrichment of G4s in the cis-regulatory elements of genes associated with tumorigenesis has accelerated the quest for identification of G4-DNA binding ligands (G4DBLs) that can selectively bind and regulate the expression of such specific genes. In this context, the analysis of G4DBL responsive transcriptome in diverse cancer cell lines is inevitable for assessment of the specificity of novel G4DBLs. Towards this, we assembled the transcripts differentially regulated by different G4DBLs and have also identified a core set of genes regulated in diverse cancer cell lines in response to 3 or more of these ligands. With the mode of action of G4DBLs towards topology shifts, folding, or disruption of G4 structure being currently visualized, we believe that this dataset will serve as a platform for assembly of G4DBL responsive transcriptome for comparative analysis of G4DBLs in multiple cancer cells based on the expression of specific cis-regulatory G4 associated genes in the future. SUPPLEMENTARY INFORMATION: The online version contains supplementary material available at 10.1007/s12079-021-00637-z.

Published

2021

11. Tuning SAS-6 architecture with monobodies impairs distinct steps of centriole assembly

Author

T. Favez, Pierre Gönczy, Isabelle Flückiger, Santiago H. Andany, Oliver Hantschel, Tim Kükenshöner, Niccolò Banterle, Georgios N. Hatzopoulos, Georg E. Fantner, and Virginie Hamel

Subjects

0301 basic medicine, Models, Molecular, Cell biology, Centriole, Cell division, kinase, Science, General Physics and Astronomy, Cell Cycle Proteins, protein sas-6, scaffold, Crystallography, X-Ray, Microscopy, Atomic Force, General Biochemistry, Genetics and Molecular Biology, Article, 03 medical and health sciences, 0302 clinical medicine, Protein structure, inhibitors, Centrosome duplication, 9-fold symmetry, X-ray crystallography, Centrioles, cartwheel, Multidisciplinary, Chemistry, elegans, Algal Proteins, Cryoelectron Microscopy, health, General Chemistry, Chemical biology, Monobody, Protein Structure, Tertiary, 030104 developmental biology, centrosome duplication, Centrosome, Protein Multimerization, Structural biology, Carrier Proteins, reveals, 030217 neurology & neurosurgery, Alpha helix, Biogenesis, Chlamydomonas reinhardtii, Centriole assembly, Protein Binding

Abstract

Centrioles are evolutionarily conserved multi-protein organelles essential for forming cilia and centrosomes. Centriole biogenesis begins with self-assembly of SAS-6 proteins into 9-fold symmetrical ring polymers, which then stack into a cartwheel that scaffolds organelle formation. The importance of this architecture has been difficult to decipher notably because of the lack of precise tools to modulate the underlying assembly reaction. Here, we developed monobodies against Chlamydomonas reinhardtii SAS-6, characterizing three in detail with X-ray crystallography, atomic force microscopy and cryo-electron microscopy. This revealed distinct monobody-target interaction modes, as well as specific consequences on ring assembly and stacking. Of particular interest, monobody MBCRS6-15 induces a conformational change in CrSAS-6, resulting in the formation of a helix instead of a ring. Furthermore, we show that this alteration impairs centriole biogenesis in human cells. Overall, our findings identify monobodies as powerful molecular levers to alter the architecture of multi-protein complexes and tune centriole assembly., Centriole biogenesis begins with self-assembly of SAS-6 proteins into 9-fold symmetrical ring polymers, which then stack into a cartwheel that scaffolds organelle formation. Here, the authors develop monobodies against Chlamydomonas reinhardtii SAS-6 and use X-ray crystallography, atomic force microscopy and cryo-electron microscopy to reveal insights into ring assembly and stacking.

Published

2021

12. CEP135 isoform dysregulation promotes centrosome amplification in breast cancer cells

Author

Divya Ganapathi Sankaran, Chad G. Pearson, and Alexander J. Stemm-Wolf

Subjects

Centriole, Mitosis, Breast Neoplasms, Biology, Genomic Instability, S Phase, 03 medical and health sciences, 0302 clinical medicine, Chromosome instability, Cell Line, Tumor, Chromosomal Instability, Chromosome Segregation, Humans, Protein Isoforms, Centrosome duplication, Molecular Biology, Cytoskeleton, 030304 developmental biology, Pericentriolar material, Centrioles, Centrosome, 0303 health sciences, Cell Cycle, Cell Biology, Articles, Aneuploidy, Cell biology, 030220 oncology & carcinogenesis, Female, CEP135, Carrier Proteins, Multipolar spindles, Centriole assembly

Abstract

The centrosome, composed of two centrioles surrounded by pericentriolar material, is the cell’s central microtubule-organizing center. Centrosome duplication is coupled with the cell cycle such that centrosomes duplicate once in S phase. Loss of such coupling produces supernumerary centrosomes, a condition called centrosome amplification (CA). CA promotes cell invasion and chromosome instability, two hallmarks of cancer. We examined the contribution of centriole overduplication to CA and the consequences for genomic stability in breast cancer cells. CEP135, a centriole assembly protein, is dysregulated in some breast cancers. We previously identified a short isoform of CEP135, CEP135mini, that represses centriole duplication. Here, we show that the relative level of full-length CEP135 (CEP135full) to CEP135mini (the CEP135full:mini ratio) is increased in breast cancer cell lines with high CA. Inducing expression of CEP135full in breast cancer cells increases the frequency of CA, multipolar spindles, anaphase-lagging chromosomes, and micronuclei. Conversely, inducing expression of CEP135mini reduces centrosome number. The differential expression of the CEP135 isoforms in vivo is generated by alternative polyadenylation. Directed genetic mutations near the CEP135mini alternative polyadenylation signal reduces the CEP135full:mini ratio and decreases CA. We conclude that dysregulation of CEP135 isoforms promotes centriole overduplication and contributes to chromosome segregation errors in breast cancer cells.

Published

2019

13. Ubiquitin signaling in the control of centriole duplication

Author

Ushma Anand, Swarnendu Mukhopadhyay, Tapas Manna, and Binshad Badarudeen

Subjects

0301 basic medicine, PLK4, Centrosome, Centriole, biology, Ubiquitin, Ubiquitin-Protein Ligases, Cell Cycle, Cell Cycle Proteins, Cell Biology, Protein degradation, Biochemistry, Ubiquitin ligase, Cell biology, 03 medical and health sciences, 030104 developmental biology, 0302 clinical medicine, 030220 oncology & carcinogenesis, Ciliogenesis, biology.protein, Molecular Biology, Centriole assembly, Centrioles

Abstract

The centrosome plays an essential role in maintaining genetic stability, ciliogenesis and cell polarisation. The core of the centrosome is made up of two centrioles that duplicate precisely once during every cell cycle to generate two centrosomes that are required for bipolar spindle assembly and chromosome segregation. Abundance of centriole proteins at optimal levels and their recruitment to the centrosome are tightly regulated in time and space in order to restrict aberrant duplication of centrioles, a phenomenon that is observed in many cancers. Recent advances have conclusively shown that dedicated ubiquitin ligase-dependent protein degradation machineries are involved in governing centriole duplication. These studies revealed intricate mechanistic insights into how the ubiquitin ligases target different centriole proteins. In certain cases, a specific ubiquitin ligase targets a number of substrate proteins that co-regulate centriole assembly, prompting the possibility that substrate-targeting occurs during formation of the sub-centriolar structures. There are also instances where a specific centriole duplication protein is targeted by several ubiquitin ligases at different stages of the cell cycle, suggesting synchronised actions. Recent evidence also indicated a direct association of E3 ubiquitin ligase with the centrioles, supporting the notion that substrate-targeting occurs in the organelle itself. In this review, we highlight these advances by underlining the mechanisms of how different ubiquitin ligase machineries control centriole duplication and discuss our views on their coordination.

Published

2021

14. Human centrosome organization and function in interphase and mitosis

Author

Jadranka Loncarek and Alejandra Vásquez-Limeta

Subjects

0301 basic medicine, Centrosome, Centriole, Cell Biology, Biology, Article, Cell biology, Chromosome segregation, 03 medical and health sciences, 030104 developmental biology, 0302 clinical medicine, Humans, Interphase, Mitotic spindle pole, Mitosis, 030217 neurology & neurosurgery, Developmental Biology, Centriole assembly, Pericentriolar material, Centrioles

Abstract

Centrosomes were first described by Edouard Van Beneden and named and linked to chromosome segregation by Theodor Boveri around 1870. In the 1960-1980s, electron microscopy studies have revealed the remarkable ultrastructure of a centriole -- a nine-fold symmetrical microtubular assembly that resides within a centrosome and organizes it. Less than two decades ago, proteomics and genomic screens conducted in multiple species identified hundreds of centriole and centrosome core proteins and revealed the evolutionarily conserved nature of the centriole assembly pathway. And now, super resolution microscopy approaches and improvements in cryo-tomography are bringing an unparalleled nanoscale-detailed picture of the centriole and centrosome architecture. In this chapter, we summarize the current knowledge about the architecture of human centrioles. We discuss the structured organization of centrosome components in interphase, focusing on localization/function relationship. We discuss the process of centrosome maturation and mitotic spindle pole assembly in centriolar and acentriolar cells, emphasizing recent literature.

Published

2021

15. The SON RNA splicing factor is required for intracellular trafficking that promotes centriole assembly

Author

Eileen T. O'Toole, Jacob T. Morgan, Chad G. Pearson, Alexander J. Stemm-Wolf, and Ryan M. Sheridan

Subjects

sports.league, Procentriole, MRNA Sequencing, Centriole, Microtubule, Centrosome, sports, RNA splicing, Centriolar satellite, Biology, Centriole assembly, Cell biology

Abstract

Control of centrosome assembly is critical for cell division, intracellular trafficking and cilia. Regulation of centrosome number occurs through the precise duplication of centrioles that reside in centrosomes. Here we explored transcriptional control of centriole assembly and find that the RNA splicing factor SON is specifically required for completing procentriole assembly. Whole genome mRNA sequencing identified genes whose splicing and expression are affected by the reduction of SON, with an enrichment in genes involved in the microtubule cytoskeleton, centrosome and centriolar satellites. SON is required for the proper splicing and expression ofCEP131which encodes a major centriolar satellite protein and is required to organize the trafficking and microtubule network around the centrosomes. This study highlights the importance of the distinct microtubule trafficking network that is intimately associated with nascent centrioles and is responsible for procentriole development.

Published

2021

16. The 3D architecture and molecular foundations of de novo centriole assembly via bicentrioles

Author

Alexander J. Holmes, Erin M. Tranfield, Jörg Becker, Gohta Goshima, Martin Schorb, Catarina Nabais, Mónica Bettencourt-Dias, Tiago Paixão, Sónia Gomes Pereira, and Ana Laura Sousa

Subjects

Centrosome, Male, Centriole, Cell Cycle, Eukaryota, Biology, Microtubules, General Biochemistry, Genetics and Molecular Biology, Spindle pole body, Cell biology, De novo centriole assembly, Microtubule, Motile cilium, Animals, Cilia, General Agricultural and Biological Sciences, Biogenesis, Centriole assembly, Centrioles

Abstract

Centrioles are structurally conserved organelles, composing both centrosomes and cilia. In animal cycling cells, centrioles often form through a highly characterized process termed canonical duplication. However, a large diversity of eukaryotes assemble centrioles de novo through uncharacterized pathways. This unexplored diversity is key to understanding centriole assembly mechanisms and how they evolved to assist specific cellular functions. Here, we show that, during spermatogenesis of the bryophyte Physcomitrium patens, centrioles are born as a co-axially oriented centriole pair united by a cartwheel. Interestingly, we observe that these centrioles are twisted in opposite orientations. Microtubules emanate from the bicentrioles, which localize to the spindle poles during cell division. After their separation, the two resulting sister centrioles mature asymmetrically, elongating specific microtubule triplets and a naked cartwheel. Subsequently, two motile cilia are assembled that appear to alternate between different motility patterns. We further show that centriolar components SAS6, Bld10, and POC1, which are conserved across eukaryotes, are expressed during spermatogenesis and required for this de novo biogenesis pathway. Our work supports a scenario where centriole biogenesis, while driven by conserved molecular modules, is more diverse than previously thought.

Published

2021

17. The 3D Architecture and Molecular Foundations of De Novo Centriole Assembly Via Bicentrioles

Author

Sónia Gomes Pereira, Catarina Nabais, Alexander J. Holmes, Martin Schorb, Ana Laura Sousa, Gohta Goshima, Jörg Becker, Erin M. Tranfield, Mónica Bettencourt-Dias, and Tiago Paixão

Subjects

De novo centriole assembly, Cell division, Centriole, Microtubule, Centrosome, Biology, Biogenesis, Spindle pole body, Cell biology, Centriole assembly

Abstract

Centrioles are structurally conserved organelles, composing both centrosomes and cilia. In animal cycling cells, centrioles often form through a highly characterized process termed canonical duplication. However, a large diversity of eukaryotes form centrioles de novo through uncharacterized pathways. This unexplored diversity is key to understanding centriole assembly mechanisms and how they evolved to assist specific cellular functions. Here, combining electron microscopy and tomography, we show that during spermatogenesis of the moss Physcomitrium patens, centrioles are born as a co-axially oriented centriole pair united by a cartwheel. We observe that microtubules emanate from those bicentrioles, which localize to the spindle poles during cell division. Thereafter, each bicentriole breaks apart, and the two resulting sister centrioles mature asymmetrically, elongating specific microtubule triplets and a naked cartwheel. Subsequently, two cilia are assembled which are capable of beating asynchronously. We further show that conserved cartwheel and centriole wall components, SAS6, BLD10 and POC1 are expressed during spermatogenesis and are required for this de novo biogenesis pathway. Our work supports a scenario where centriole biogenesis is more diverse than previously thought and that conserved molecular modules underlie diversification of this essential pathway.

Published

2021

18. The 3D architecture and molecular foundations ofde novocentriole assemblyviabicentrioles

Author

Gohta Goshima, Sónia Gomes Pereira, Mónica Bettencourt-Dias, Catarina Nabais, Tiago Paixão, Alexander J. Holmes, Martin Schorb, Ana Laura Sousa, Erin M. Tranfield, and Jörg Becker

Subjects

De novo centriole assembly, Cell division, Centriole, Microtubule, Centrosome, Biology, Spindle pole body, Biogenesis, Centriole assembly, Cell biology

Abstract

/SummaryCentrioles are structurally conserved organelles, composing both centrosomes and cilia. In animal cycling cells, centrioles often form through a highly characterized process termed canonical duplication. However, a large diversity of eukaryotes form centriolesde novothrough uncharacterized pathways. This unexplored diversity is key to understanding centriole assembly mechanisms and how they evolved to assist specific cellular functions. Here, combining electron microscopy and tomography, we show that during spermatogenesis of the mossPhyscomitrium patens, centrioles are born as a co-axially oriented centriole pair united by a cartwheel. We observe that microtubules emanate from those bicentrioles, which localize to the spindle poles during cell division. Thereafter, each bicentriole breaks apart, and the two resulting sister centrioles mature asymmetrically, elongating specific microtubule triplets and a naked cartwheel. Subsequently, two cilia are assembled which are capable of beating asynchronously. We further show that conserved cartwheel and centriole wall components, SAS6, BLD10 and POC1 are expressed during spermatogenesis and are required for thisde novobiogenesis pathway. Our work supports a scenario where centriole biogenesis is more diverse than previously thought and that conserved molecular modules underlie diversification of this essential pathway.

Published

2020

19. Fate of the M-phase-assembled centrioles during the cell cycle in the TP53;PCNT;CEP215-deleted cells

Author

Giyoung Jung and K. Rhee

Subjects

Centriole, Microtubule, Cell culture, Chemistry, PCNT, Cancer cell, Interphase, Cell cycle, Cell biology, Centriole assembly

Abstract

Cancer cells frequently include supernumerary centrioles. Here, we generated TP53;PCNT;CEP215 triple knockout cell lines and observed precocious separation and amplification of the centrioles at M phase. Many of the triple KO cells maintained supernumerary centrioles throughout the cell cycle. The M-phase-assembled centrioles lack an ability to function as templates for centriole assembly during S phase. They also lack an ability to organize microtubules in interphase. However, we found that a fraction of them acquired an ability to organize microtubules during M phase. Our works provide an example how supernumerary centrioles behave in dividing cells.

Published

2020

20. TRIM37 prevents formation of centriolar protein assemblies by regulating Centrobin stability

Author

Fernando R. Balestra, Marita Lipsanen-Nyman, Andrés Domínguez-Calvo, Alizée Buff, Tessa Averink, Rosa M. Ríos, Pablo Huertas, Benita Wolf, Pierre Gönczy, and Coralie Busso

Subjects

Mulibrey nanism, PLK4, 0303 health sciences, Centriole, biology, Chemistry, medicine.disease, medicine.disease_cause, PLK1, Cell biology, Ubiquitin ligase, 03 medical and health sciences, 0302 clinical medicine, 030220 oncology & carcinogenesis, Centrin, medicine, biology.protein, Carcinogenesis, 030304 developmental biology, Centriole assembly

Abstract

TRIM37 is an E3 ubiquitin ligase mutated in Mulibrey nanism, a disease characterized by impaired growth and increased tumorigenesis, whose cellular etiology is poorly understood. TRIM37 depletion from tissue culture cells results in supernumerary foci bearing the centriolar protein Centrin. Here, we characterized these centriolar protein assemblies (Cenpas) to uncover the mechanism of action of TRIM37. We established that an atypical de novo assembly pathway is notably involved in forming Cenpas, which can nevertheless trigger further centriole assembly and act as MTOCs. We found also that Cenpas are present and act similarly in Mulibrey patient cells. Through correlative light electron microscopy, we uncovered that Cenpas correspond to centriole related structures and elongated electron-dense structures with stripes. Importantly, we established that TRIM37 regulates the stability and solubility of the centriolar protein Centrobin. Our findings suggest that elongated Centrobin assemblies are a major constituent of the striped electron dense structures. Furthermore, we established that Cenpas formation upon TRIM37 depletion requires PLK4 activity, as well as two parallel pathways relying respectively on Centrobin and PLK1. Overall, our work uncovers how TRIM37 prevents the formation of Cenpas that would otherwise threaten genome integrity, including possibly in Mulibrey patients.

Published

2020

21. The architecture of the centriole cartwheel-containing region revealed by cryo-electron tomography

Author

Stefan Geimer, Miroslava Schaffer, Gabriel Aeschlimann, Philipp Erdmann, Kenneth N. Goldie, Paul Guichard, Nikolai Klena, Maeva Le Guennec, Lubomír Kováčik, Anne-Marie Tassin, Hugo van den Hoek, Virginie Hamel, Henning Stahlberg, and Benjamin D. Engel

Subjects

Physics, Radial spoke, biology, Centriole, Centrosome, Trichonympha, Microtubule, Chlamydomonas, Cryo-electron tomography, biology.organism_classification, Centriole assembly, Cell biology

Abstract

Centrioles are evolutionarily conserved barrels of microtubule triplets that form the core of the centrosome and the base of the cilium. In the proximal region of the centriole, nine microtubule triplets attach to each other via A-C linkers and encircle a central cartwheel structure, which directs the early events of centriole assembly. While the crucial role of the proximal region in centriole biogenesis has been well documented in many species, its native architecture and evolutionary conservation remain relatively unexplored. Here, using cryo-electron tomography of centrioles from four evolutionarily distant species, including humans, we report on the architectural diversity of the centriolar proximal cartwheel-bearing region. Our work reveals that the cartwheel central hub, previously reported to have an 8.5 nm periodicity in Trichonympha, is constructed from a stack of paired rings with an average periodicity of ∼4 nm. In all four examined species, cartwheel inner densities are found inside the hub’s ring-pairs. In both Paramecium and Chlamydomonas, the repeating structural unit of the cartwheel has a periodicity of 25 nm and consists of three ring-pairs with 6 radial spokes emanating and merging into a single bundle that connects to the triplet microtubule via the pinhead. Finally, we identified that the cartwheel is indirectly connected to the A-C linker through a flexible triplet-base structure extending from the pinhead. Together, our work provides unprecedented evolutionary insights into the architecture of the centriole proximal region, which underlies centriole biogenesis.

Published

2020

22. Identification of compounds that bind the centriolar protein SAS-6 and inhibit its oligomerization

Author

Ioannis Vakonakis, Julia M.C. Busch, Minos-Timotheos Matsoukas, Georgios A. Spyroulias, Philip C. Biggin, and Maria Musgaard

Subjects

0301 basic medicine, ligand design, Centriole, Protein Conformation, nuclear magnetic resonance (NMR), Cell Cycle Proteins, Flagellum, Molecular Dynamics Simulation, Biochemistry, Protein–protein interaction, Small Molecule Libraries, protein-protein interaction, 03 medical and health sciences, Microtubule, biophysics, Protein oligomerization, Animals, protein-drug interaction, Caenorhabditis elegans, Caenorhabditis elegans Proteins, Molecular Biology, Centrioles, 030102 biochemistry & molecular biology, Chemistry, Cell Biology, High-Throughput Screening Assays, inhibitor, 030104 developmental biology, centrosome, Centrosome, Biophysics, Pharmacophore, Protein Multimerization, Molecular Biophysics, Centriole assembly

Abstract

Centrioles are key eukaryotic organelles that are responsible for the formation of cilia and flagella, and for organizing the microtubule network and the mitotic spindle in animals. Centriole assembly requires oligomerization of the essential protein spindle assembly abnormal 6 (SAS-6), which forms a structural scaffold templating the organization of further organelle components. A dimerization interaction between SAS-6 N-terminal “head” domains was previously shown to be essential for protein oligomerization in vitro and for function in centriole assembly. Here, we developed a pharmacophore model allowing us to assemble a library of low-molecular-weight ligands predicted to bind the SAS-6 head domain and inhibit protein oligomerization. We demonstrate using NMR spectroscopy that a ligand from this family binds at the head domain dimerization site of algae, nematode, and human SAS-6 variants, but also that another ligand specifically recognizes human SAS-6. Atomistic molecular dynamics simulations starting from SAS-6 head domain crystallographic structures, including that of the human head domain which we now resolve, suggest that ligand specificity derives from favorable Van der Waals interactions with a hydrophobic cavity at the dimerization site.

Published

2020

23. Evolution of centriole assembly

Author

Catarina Peneda, Mónica Bettencourt-Dias, and Catarina Nabais

Subjects

0301 basic medicine, Centriole, Eukaryota, Biology, General Biochemistry, Genetics and Molecular Biology, Structure and function, Evolution, Molecular, 03 medical and health sciences, 030104 developmental biology, 0302 clinical medicine, Phylogenetics, Evolutionary biology, Basal body, Animals, Primer (molecular biology), General Agricultural and Biological Sciences, 030217 neurology & neurosurgery, Cell Division, Phylogeny, Centriole assembly, Centrioles

Abstract

In this Primer, Nabais et al. discuss the evolution of the structure and function of centrioles and basal bodies, describe conserved centriole assembly features and the diversity in centriole architecture across eukaryotes, and highlight important outstanding evolutionary questions concerning centriole assembly.

Published

2020

24. Plk4 triggers autonomous de novo centriole biogenesis and maturation

Author

Catarina Nabais, Jorge Carneiro, Thomas S. van Zanten, Jorge de-Carvalho, Ivo A. Telley, Satyajit Mayor, Paulo Duarte, Delphine Pessoa, and Mónica Bettencourt-Dias

Subjects

Male, PLK4, Centriole, Cell Cycle Proteins, Development, Protein Serine-Threonine Kinases, Biology, Article, 03 medical and health sciences, 0302 clinical medicine, Tubulin, Animals, Drosophila Proteins, Cytoskeleton, Cells, Cultured, Centrioles, Pericentriolar material, 030304 developmental biology, Centrosome, 0303 health sciences, Cilium, Cell Cycle, Cell Biology, biology.organism_classification, Cell biology, De novo centriole assembly, Drosophila melanogaster, Female, Cell Division, 030217 neurology & neurosurgery, Biogenesis, Centriole assembly

Abstract

Nabais et al. use an egg explant system overexpressing Plk4 to study the spatiotemporal and biochemical regulation of de novo centriole assembly. They show that the onset and kinetics of biogenesis depend on Plk4 concentration, requiring the matrix that surrounds centrioles., Centrioles form centrosomes and cilia. In most proliferating cells, centrioles assemble through canonical duplication, which is spatially, temporally, and numerically regulated by the cell cycle and the presence of mature centrioles. However, in certain cell types, centrioles assemble de novo, yet by poorly understood mechanisms. Herein, we established a controlled system to investigate de novo centriole biogenesis, using Drosophila melanogaster egg explants overexpressing Polo-like kinase 4 (Plk4), a trigger for centriole biogenesis. We show that at a high Plk4 concentration, centrioles form de novo, mature, and duplicate, independently of cell cycle progression and of the presence of other centrioles. Plk4 concentration determines the temporal onset of centriole assembly. Moreover, our results suggest that distinct biochemical kinetics regulate de novo and canonical biogenesis. Finally, we investigated which other factors modulate de novo centriole assembly and found that proteins of the pericentriolar material (PCM), and in particular γ-tubulin, promote biogenesis, likely by locally concentrating critical components.

Published

2020

25. Sas-6, Ana2 and Sas-4 self-organise into macromolecular structures that can be used to probe centriole/centrosome assembly

Author

Lisa Gartenmann, Zsofi A. Novak, Jordan W. Raff, Jennifer H. Richens, Catarina Vicente, Alan Wainman, and Boris Sieber

Subjects

PLK4, 0303 health sciences, Centriole, Cell Biology, Biology, Spindle apparatus, Cell biology, 03 medical and health sciences, 0302 clinical medicine, Microtubule, Centrosome, 030217 neurology & neurosurgery, Actin, 030304 developmental biology, Pericentriolar material, Centriole assembly

Abstract

Centriole assembly requires a small number of conserved proteins. The precise pathway of centriole assembly has been difficult to study, as the lack of any one of the core assembly proteins [Plk4, Ana2 (the homologue of mammalian STIL), Sas-6, Sas-4 (mammalian CPAP) or Asl (mammalian Cep152)] leads to the absence of centrioles. Here, we use Sas-6 and Ana2 particles (SAPs) as a new model to probe the pathway of centriole and centrosome assembly. SAPs form in Drosophila eggs or embryos when Sas-6 and Ana2 are overexpressed. SAP assembly requires Sas-4, but not Plk4, whereas Asl helps to initiate SAP assembly but is not required for SAP growth. Although not centrioles, SAPs recruit and organise many centriole and centrosome components, nucleate microtubules, organise actin structures and compete with endogenous centrosomes to form mitotic spindle poles. SAPs require Asl to efficiently recruit pericentriolar material (PCM), but Spd-2 (the homologue of mammalian Cep192) can promote some PCM assembly independently of Asl. These observations provide new insights into the pathways of centriole and centrosome assembly.

Published

2020

26. Asterless is a Polo-like kinase 4 substrate that both activates and inhibits kinase activity depending on its phosphorylation state

Author

Gregory C. Rogers, Tiffany A. McLamarrah, Cody J. Boese, Kevin C. Slep, Nasser M. Rusan, Jonathan Nye, Daniel W. Buster, and Amy E. Byrnes

Subjects

0301 basic medicine, PLK4, Cell Cycle Proteins, Polo-like kinase, Protein Serine-Threonine Kinases, Biology, Cell Line, 03 medical and health sciences, 0302 clinical medicine, otorhinolaryngologic diseases, Animals, Drosophila Proteins, Amino Acid Sequence, Phosphorylation, Kinase activity, Molecular Biology, Cytoskeleton, Centrioles, Kinase, Cell Cycle, Autophosphorylation, Articles, Cell Biology, Cell biology, 030104 developmental biology, Protein kinase domain, Drosophila, 030217 neurology & neurosurgery, Protein Binding, Centriole assembly

Abstract

Centriole assembly initiates when Polo-like kinase 4 (Plk4) interacts with a centriole “targeting-factor.” In Drosophila, Asterless/Asl (Cep152 in humans) fulfills the targeting role. Interestingly, Asl also regulates Plk4 levels. The N-terminus of Asl (Asl-A; amino acids 1-374) binds Plk4 and promotes Plk4 self-destruction, although it is unclear how this is achieved. Moreover, Plk4 phosphorylates the Cep152 N-terminus, but the functional consequence is unknown. Here, we show that Plk4 phosphorylates Asl and mapped 13 phospho-residues in Asl-A. Nonphosphorylatable alanine (13A) and phosphomimetic (13PM) mutants did not alter Asl function, presumably because of the dominant role of the Asl C-terminus in Plk4 stabilization and centriolar targeting. To address how Asl-A phosphorylation specifically affects Plk4 regulation, we generated Asl-A fragment phospho-mutants and expressed them in cultured Drosophila cells. Asl-A-13A stimulated kinase activity by relieving Plk4 autoinhibition. In contrast, Asl-A-13PM inhibited Plk4 activity by a novel mechanism involving autophosphorylation of Plk4’s kinase domain. Thus, Asl-A’s phosphorylation state determines which of Asl-A’s two opposing effects are exerted on Plk4. Initially, nonphosphorylated Asl binds Plk4 and stimulates its kinase activity, but after Asl is phosphorylated, a negative-feedback mechanism suppresses Plk4 activity. This dual regulatory effect by Asl-A may limit Plk4 to bursts of activity that modulate centriole duplication.

Published

2018

27. PPP1R35 ensures centriole homeostasis by promoting centriole-to-centrosome conversion

Author

Meng-Fu Bryan Tsou, Chii Shyang Fong, and Kanako Ozaki

Subjects

G2 Phase, 0301 basic medicine, Centriole, Microtubule-associated protein, Phosphatase, Regulator, Mitosis, Cell Cycle Proteins, Biology, Cell Line, 03 medical and health sciences, Protein Phosphatase 1, Homeostasis, Humans, Molecular Biology, Centrioles, Centrosome, Brief Report, Cell Cycle, Cell Biology, Cell biology, 030104 developmental biology, S Phase Cell Cycle Checkpoints, Interphase, Microtubule-Associated Proteins, Centriole assembly

Abstract

Centriole-to-centrosome conversion (CCC) safeguards centriole homeostasis by coupling centriole duplication with segregation, and is essential for stabilization of mature vertebrate centrioles naturally devoid of the geometric scaffold or the cartwheel. Here we identified PPP1R35, a putative regulator of the protein phosphatase PP1, as a novel centriolar protein required for CCC. We found that PPP1R35 is enriched at newborn daughter centrioles in S or G2 phase. In the absence of PPP1R35, centriole assembly initiates normally in S phase, but none of the nascent centrioles can form active centrosomes or recruit CEP295, an essential factor for CCC. Instead, all PPP1R35-null centrioles, although stable during their birth in interphase, become disintegrated after mitosis upon cartwheel removal. Surprisingly, we found that neither the centriolar localization nor the function of PPP1R35 in CCC requires the putative PP1-interacting motif. PPP1R35 is thus acting upstream of CEP295 to induce CCC for proper centriole maintenance.

Published

2018

28. Interaction between theCaenorhabditis eleganscentriolar protein SAS-5 and microtubules facilitates organelle assembly

Author

Nicola J. Dynes, Sarah Bianchi, Michel O. Steinmetz, Pierre Gönczy, Manuel Hilbert, Ioannis Vakonakis, Kacper B. Rogala, and Sebastian A. Leidel

Subjects

0301 basic medicine, Organelle assembly, biology, Centriole, Cell Biology, Flagellum, biology.organism_classification, Cell biology, 03 medical and health sciences, 030104 developmental biology, 0302 clinical medicine, Microtubule, Organelle, Organelle biogenesis, Molecular Biology, 030217 neurology & neurosurgery, Caenorhabditis elegans, Centriole assembly

Abstract

Centrioles are microtubule-based organelles that organize the microtubule network and seed the formation of cilia and flagella. New centrioles assemble through a stepwise process dependent notably on the centriolar protein SAS-5 in Caenorhabditis elegans. SAS-5 and its functional homologues in other species form oligomers that bind the centriolar proteins SAS-6 and SAS-4, thereby forming an evolutionarily conserved structural core at the onset of organelle assembly. Here, we report a novel interaction of SAS-5 with microtubules. Microtubule binding requires SAS-5 oligomerization and a disordered protein segment that overlaps with the SAS-4 binding site. Combined in vitro and in vivo analysis of select mutants reveals that the SAS-5–microtubule interaction facilitates centriole assembly in C. elegans embryos. Our findings lead us to propose that the interdependence of SAS-5 oligomerization and microtubule binding reflects an avidity mechanism, which also strengthens SAS-5 associations with other centriole components and, thus, promotes organelle assembly.

Published

2018

29. VDAC3 regulates centriole assembly by targeting Mps1 to centrosomes.

Author

Majumder, Shubhra, Slabodnick, Mark, Pike, Amanda, Marquardt, Joseph, and Fisk, Harold A.

Published

2012

30. A syndromic extreme insulin resistance caused by biallelic POC1A mutations in exon 10

Author

Barbara Pasini, Fabio Sirchia, Alessandro Bruselles, Elisa Rubino, Simone Pizzi, Sergio Duca, Alfredo Brusco, Marco Tartaglia, Elisa Giorgio, and Innocenzo Rainero

Subjects

Adult, 0301 basic medicine, medicine.medical_specialty, Endocrinology, Diabetes and Metabolism, Biology, medicine.disease_cause, Short stature, Frameshift mutation, 03 medical and health sciences, Exon, Endocrinology, Internal medicine, medicine, Humans, Allele, Abnormalities, Multiple, Exons, Female, Genetic Pleiotropy, Insulin Resistance, Mutation, Proteins, Syndrome, Alleles, Exome sequencing, Genetics, General Medicine, medicine.disease, Diabetes and Metabolism, 030104 developmental biology, Hypotrichosis, Abnormalities, medicine.symptom, Multiple, Centriole assembly

Abstract

POC1A encodes a protein with a role in centriole assembly and stability, and in ciliogenesis. Biallelic loss-of-function mutations affecting POC1A cause SOFT syndrome, an ultra-rare condition characterized by short stature, onychodysplasia, facial dysmorphism and hypotrichosis. Using exome sequencing, we identified a homozygous frameshift mutation (c.1047_1048dupC; p.G337Rfs*25) in a patient presenting with short stature, facial hirsutism, alopecia, dyslipidemia and extreme insulin resistance. The truncating variant affected exon 10, which is retained in only two of the three POC1A-mature RNAs, due to alternative processing of the transcript. Clinical discrepancies with SOFT syndrome support the hypothesis that POC1A mutations affecting exon 10 are associated with a distinct condition, corroborating a previous hypothesis based on a similar case. Furthermore, this report provides an additional example of a genetic condition presenting with clinical heterogeneity due to alternative transcript processing. In conclusion, POC1A mutations in exon 10 should be taken into account in patients with extreme insulin resistance and short stature.

Published

2017

31. The Evolution of Centriole Structure: Heterochrony, Neoteny, and Hypermorphosis

Author

Katerina A. Turner and Tomer Avidor-Reiss

Subjects

Male, 0303 health sciences, Centriole, Cilium, Centriole structure, Biology, Sperm, Spermatozoa, Article, 03 medical and health sciences, Evolutionary biology, Centrosome, Animals, Cilia, Heterochrony, Neoteny, 030304 developmental biology, Centriole assembly, Centrioles

Abstract

Centrioles are subcellular organelles that were present in the last eukaryotic common ancestor, where the centriole's ancestral role was to form cilia. Centrioles have maintained a remarkably conserved structure in eukaryotes that have cilia, while groups that lack cilia have lost their centrioles, highlighting the structure-function relationship that exists between the centriole and the cilium. In contrast, animal sperm cells, a ciliated cell, exhibit remarkable structural diversity in the centriole. Understanding how this structural diversity evolved may provide insight into centriole assembly and function, as well as their unique role in sperm. Here, we apply concepts used in the study of the evolution of animal morphology to gain insight into the evolution of centriole structure. We propose that centrioles with an atypical structure form because of changes in the timing of centriole assembly events, which can be described as centriolar "heterochrony." Atypical centrioles of insects and mammals appear to have evolved through different types of heterochrony. Here, we discuss two particular types of heterochrony: neoteny and hypermorphosis. The centriole assembly of insect sperm cells exhibits the retention of "juvenile" centriole structure, which can be described as centriolar "neoteny." Mammalian sperm cells have an extended centriole assembly program through the addition of novel steps such as centrosome reduction and centriole remodeling to form atypical centrioles, a form of centriole "hypermorphosis." Overall, centriole heterochrony appears to be a common mechanism for the development of the atypical centriole during the evolution of centriole assembly of various animals' sperm.

Published

2019

32. Centriole assembly at a glance

Author

Pierre Gönczy and Georgios N. Hatzopoulos

Subjects

Axoneme, PLK4, Centriole, stil, sports, centrosomal protein, Mitosis, Cell Cycle Proteins, Biology, Protein Serine-Threonine Kinases, Microtubules, molecular architecture, mitotic centrosome, 03 medical and health sciences, Procentriole, Mice, 0302 clinical medicine, kinase-activity, sas-6, epsilon-tubulin, centriole, Animals, Humans, 9-fold symmetry, 030304 developmental biology, Pericentriolar material, Centrioles, 0303 health sciences, Organelle Biogenesis, Intracellular Signaling Peptides and Proteins, plk4, structural basis, Cell Biology, Naegleria, Embryo, Mammalian, Cell biology, sports.league, centrosome, duplication, Eukaryotic Cells, Gene Expression Regulation, Centrosome, Marsileaceae, basal bodies, 030217 neurology & neurosurgery, Centriole assembly, Signal Transduction

Abstract

The centriole organelle consists of microtubules (MTs) that exhibit a striking 9-fold radial symmetry. Centrioles play fundamental roles across eukaryotes, notably in cell signaling, motility and division. In this Cell Science at a Glance article and accompanying poster, we cover the cellular life cycle of this organelle – from assembly to disappearance – focusing on human centrioles. The journey begins at the end of mitosis when centriole pairs disengage and the newly formed centrioles mature to begin a new duplication cycle. Selection of a single site of procentriole emergence through focusing of polo-like kinase 4 (PLK4) and the resulting assembly of spindle assembly abnormal protein 6 (SAS-6) into a cartwheel element are evoked next. Subsequently, we cover the recruitment of peripheral components that include the pinhead structure, MTs and the MT-connecting A-C linker. The function of centrioles in recruiting pericentriolar material (PCM) and in forming the template of the axoneme are then introduced, followed by a mention of circumstances in which centrioles form de novo or are eliminated.

Published

2019

33. Author response: Pericentrin-mediated SAS-6 recruitment promotes centriole assembly

Author

Jaroslaw Surkont, Sihem Zitouni, Mónica Bettencourt-Dias, Daisuke Ito, Paulo Duarte, Miguel Godinho Ferreira, Swadhin Chandra Jana, José B. Pereira-Leal, and Zita Carvalho-Santos

Subjects

Biology, Centriole assembly, Cell biology

Published

2019

34. Klp10A modulates the localization of centriole-associated proteins during Drosophila male gametogenesis

Author

Maria Giovanna Riparbelli, Marco Gottardo, and Giuliano Callaini

Subjects

Male, 0301 basic medicine, PLK4, Centriole, Kinesins, Gametogenesis, 03 medical and health sciences, Meiosis, centriole-associated proteins, Report, male gametogenesis, Testis, Animals, Drosophila Proteins, Basal body, Molecular Biology, Centrioles, Genetics, biology, Cell Biology, centrioles, Drosophila, Developmental Biology, biology.organism_classification, Protein subcellular localization prediction, Protein Transport, Drosophila melanogaster, 030104 developmental biology, Mutation, Drosophila Protein, Centriole assembly

Abstract

Mutations in Klp10A, a microtubule-depolymerising Kinesin-13, lead to overly long centrioles in Drosophila male germ cells. We demonstrated that the loss of Klp10A modifies the distribution of typical proteins involved in centriole assembly and function. In the absence of Klp10A the distribution of Drosophila pericentrin-like protein (Dplp), Sas-4 and Sak/Plk4 that are restricted in control testes to the proximal end of the centriole increase along the centriole length. Remarkably, the cartwheel is lacking or it appears abnormal in mutant centrioles, suggesting that this structure may spatially delimit protein localization. Moreover, the parent centrioles that in control cells have the same dimensions grow at different rates in mutant testes with the mother centrioles longer than the daughters. Daughter centrioles have often an ectopic position with respect to the proximal end of the mothers and failed to recruit Dplp.

Published

2016

35. Promotion and Suppression of Centriole Duplication Are Catalytically Coupled through PLK4 to Ensure Centriole Homeostasis

Author

Prasad V. Jallepalli, Rajesh K. Soni, Brian P. O’Rourke, Meng-Fu Bryan Tsou, Ronald C. Hendrickson, and Minhee Kim

Subjects

0301 basic medicine, PLK4, Centriole, Cell Cycle Proteins, Biology, Protein Serine-Threonine Kinases, General Biochemistry, Genetics and Molecular Biology, Article, 03 medical and health sciences, Gene duplication, Basal body, Animals, Homeostasis, Humans, Phosphorylation, Cell Cycle Protein, lcsh:QH301-705.5, Centrioles, Genetics, Cell Cycle, Centriole duplication, Cell biology, 030104 developmental biology, lcsh:Biology (General), Mother centriole, Centriole assembly

Abstract

SUMMARY PLK4 is the major kinase driving centriole duplication. Duplication occurs only once per cell cycle, forming one new (or daughter) centriole that is tightly engaged to the preexisting (or mother) centriole. Centriole engagement is known to block the reduplication of mother centrioles, but the molecular identity responsible for the block remains unclear. Here, we show that the centriolar cartwheel, the geometric scaffold for centriole assembly, forms the identity of daughter centrioles essential for the block, ceasing further duplication of the mother centriole to which it is engaged. To ensure a steady block, we found that the cartwheel requires constant maintenance by PLK4 through phosphorylation of the same substrate that drives centriole assembly, revealing a parsimonious control in which “assembly” and “block for new assembly” are linked through the same catalytic reaction to achieve homeostasis. Our results support a recently deduced model that the cartwheel-bound PLK4 directly suppresses centriole reduplication., Graphical Abstract

Published

2016

36. The Centrosome Undergoes Plk1-Independent Interphase Maturation during Inflammation and Mediates Cytokine Release

Author

Maria Ivshina, Anastassiia Vertii, Stephen J. Doxsey, Shashi Kant, Wendy Zimmerman, and Heidi Hehnly

Subjects

Lipopolysaccharides, 0301 basic medicine, Centriole, Cell Cycle Proteins, Centrosome cycle, Protein Serine-Threonine Kinases, Biology, PLK1, General Biochemistry, Genetics and Molecular Biology, Mice, 03 medical and health sciences, Tubulin, Microtubule, Proto-Oncogene Proteins, Animals, Humans, Antigens, Interphase, Molecular Biology, Centrioles, Pericentriolar material, Microtubule nucleation, Centrosome, Inflammation, Macrophages, Cell Biology, Cell biology, 030104 developmental biology, Cytokines, Developmental Biology, Centriole assembly

Abstract

Cytokine production is a necessary event in the immune response during inflammation and is associated with mortality during sepsis, autoimmune disorders, cancer, and diabetes. Stress-activated MAP kinase signaling cascades that mediate cytokine synthesis are well established. However, the downstream fate of cytokines before they are secreted remains elusive. We report that pro-inflammatory stimuli lead to recruitment of pericentriolar material, specifically pericentrin and γ-tubulin, to the centrosome. This is accompanied by enhanced microtubule nucleation and enrichment of the recycling endosome component FIP3, all of which are hallmarks of centrosome maturation during mitosis. Intriguingly, centrosome maturation occurs during interphase in an MLK-dependent manner, independent of the classic mitotic kinase, Plk1. Centrosome disruption by chemical prevention of centriole assembly or genetic ablation of pericentrin attenuated interleukin-6, interleukin-10, and MCP1 secretion, suggesting that the centrosome is critical for cytokine production. Our results reveal a function of the centrosome in innate immunity.

Published

2016

37. The E2F-DP1 Transcription Factor Complex Regulates Centriole Duplication inCaenorhabditis elegans

Author

Miller, Jacqueline G., Liu, Yan, Williams, Christopher W., Smith, Harold E., and O’Connell, Kevin F.

Subjects

0301 basic medicine, PLK4, Transcription, Genetic, Centriole, centriole duplication, Transcription factor complex, Investigations, QH426-470, Biology, Animals, Genetically Modified, 03 medical and health sciences, Genetics, Animals, Basal body, transcriptional regulation, SAS-6, Caenorhabditis elegans, Caenorhabditis elegans Proteins, Molecular Biology, Genetics (clinical), Centrioles, Genome, Helminth, E2F/DP1, biology.organism_classification, E2F Transcription Factors, Spindle apparatus, 030104 developmental biology, Gene Expression Regulation, Multiprotein Complexes, Mutation, C. elegans, Genes, Lethal, Transcription Factor DP1, Cell Division, Centriole assembly

Abstract

Centrioles play critical roles in the organization of microtubule-based structures, from the mitotic spindle to cilia and flagella. In order to properly execute their various functions, centrioles are subjected to stringent copy number control. Central to this control mechanism is a precise duplication event that takes place during S phase of the cell cycle and involves the assembly of a single daughter centriole in association with each mother centriole . Recent studies have revealed that posttranslational control of the master regulator Plk4/ZYG-1 kinase and its downstream effector SAS-6 is key to ensuring production of a single daughter centriole. In contrast, relatively little is known about how centriole duplication is regulated at a transcriptional level. Here we show that the transcription factor complex EFL-1-DPL-1 both positively and negatively controls centriole duplication in the Caenorhabditis elegans embryo. Specifically, we find that down regulation of EFL-1-DPL-1 can restore centriole duplication in a zyg-1 hypomorphic mutant and that suppression of the zyg-1 mutant phenotype is accompanied by an increase in SAS-6 protein levels. Further, we find evidence that EFL-1-DPL-1 promotes the transcription of zyg-1 and other centriole duplication genes. Our results provide evidence that in a single tissue type, EFL-1-DPL-1 sets the balance between positive and negative regulators of centriole assembly and thus may be part of a homeostatic mechanism that governs centriole assembly.

Published

2016

38. Revisiting Centrioles in Nematodes—Historic Findings and Current Topics

Author

Prabhu Sankaralingam, Anna Schwarz, Kevin F. O’Connell, and Thomas Müller-Reichert

Subjects

0301 basic medicine, Centriole, General Medicine, Review, Centriole structure, Biology, 03 medical and health sciences, 030104 developmental biology, centrosome, lcsh:Biology (General), Centrosome, Evolutionary biology, Boveri, C. elegans, centriole, lcsh:QH301-705.5, Centriole assembly

Abstract

Theodor Boveri is considered as the “father” of centrosome biology. Boveri’s fundamental findings have laid the groundwork for decades of research on centrosomes. Here, we briefly review his early work on centrosomes and his first description of the centriole. Mainly focusing on centriole structure, duplication, and centriole assembly factors in C. elegans, we will highlight the role of this model in studying germ line centrosomes in nematodes. Last but not least, we will point to future directions of the C. elegans centrosome field.

Published

2018

39. Direct binding of CEP85 to STIL ensures robust PLK4 activation and efficient centriole assembly

Author

Sally W.T. Cheung, Christopher M. Johnson, Carol V. Robinson, Stephen H. McLaughlin, Laurence Pelletier, Gagan D. Gupta, Shahid Mehmood, Stefan M.V. Freund, Deepak D. Barnabas, Fikret G. Agircan, Di Wu, Antonina Andreeva, Etienne Coyaud, Mark van Breugel, Yi Liu, and Brian Raught

Subjects

Models, Molecular, Protein Conformation, alpha-Helical, 0301 basic medicine, PLK4, Oncogene Proteins, Fusion, Centriole, Science, Gene Expression, Mitosis, General Physics and Astronomy, Protein Serine-Threonine Kinases, Biology, Crystallography, X-Ray, medicine.disease_cause, Article, General Biochemistry, Genetics and Molecular Biology, Chromosome segregation, 03 medical and health sciences, Cell Line, Tumor, Chromosome Segregation, medicine, Humans, Protein Interaction Domains and Motifs, lcsh:Science, Centrioles, Pericentriolar material, Mutation, Binding Sites, Osteoblasts, Multidisciplinary, Intracellular Signaling Peptides and Proteins, General Chemistry, Recombinant Proteins, 3. Good health, Cell biology, Cytoskeletal Proteins, 030104 developmental biology, Centrosome, Protein Conformation, beta-Strand, lcsh:Q, Protein Binding, Centriole assembly

Abstract

Centrosomes are required for faithful chromosome segregation during mitosis. They are composed of a centriole pair that recruits and organizes the microtubule-nucleating pericentriolar material. Centriole duplication is tightly controlled in vivo and aberrations in this process are associated with several human diseases, including cancer and microcephaly. Although factors essential for centriole assembly, such as STIL and PLK4, have been identified, the underlying molecular mechanisms that drive this process are incompletely understood. Combining protein proximity mapping with high-resolution structural methods, we identify CEP85 as a centriole duplication factor that directly interacts with STIL through a highly conserved interaction interface involving a previously uncharacterised domain of STIL. Structure-guided mutational analyses in vivo demonstrate that this interaction is essential for efficient centriolar targeting of STIL, PLK4 activation and faithful daughter centriole assembly. Taken together, our results illuminate a molecular mechanism underpinning the spatiotemporal regulation of the early stages of centriole duplication., Centriole duplication is tightly regulated in vivo, but the underlying molecular mechanisms are incompletely understood. Here the authors use high-resolution structural and imaging methods to show that CEP85 directly interacts with STIL and mediates efficient centriolar targeting of STIL, PLK4 activation and centriole assembly.

Published

2018

40. An ancestral role of pericentrin in centriole formation through SAS-6 recruitment

Author

Zita Carvalho-Santos, Jaroslaw Surkont, José B. Pereira-Leal, Mónica Bettencourt-Dias, Paulo Duarte, Swadhin Chandra Jana, Miguel Godinho Ferreira, Daisuke Ito, and Sihem Zitouni

Subjects

Centriole, Centrosome, Biology, Matrix (biology), Biogenesis, Spindle pole body, Cell biology, Centriole assembly

Abstract

The centrosome is composed of two centrioles surrounded by a microtubule-nucleating pericentriolar matrix (PCM). Centrioles regulate matrix assembly. Here we ask whether the matrix also regulates centriole assembly. To define the interaction between the matrix and individual centriole components, we take advantage of a heterologous expression system using fission yeast. Importantly, its centrosome, the spindle pole body (SPB), has matrix but no centrioles. Surprisingly, we observed that the SPB can recruit several animal centriole components. Pcp1/pericentrin, a conserved matrix component that is often upregulated in cancer, recruits a critical centriole constituent, SAS-6. We further show that this novel interaction is conserved and important for centriole biogenesis and elongation in animals. We speculate that the Pcp1/pericentrin-SAS-6 interaction surface was conserved for one billion years of evolution after centriole loss in yeasts, due to its conserved binding to calmodulin. This study reveals an ancestral relationship between pericentrin and the centriole, where both regulate each other assembly, ensuring mutual localisation.

Published

2018

41. Cyclin-dependent kinase control of motile ciliogenesis

Author

Jeffrey D. Axelrod, Glicella Salazar-De Simone, Eszter K. Vladar, Miranda B. Stratton, Tim Stearns, Maxwell L. Saal, Debra J. Wolgemuth, and Xiangyuan Wang

Subjects

0301 basic medicine, Centriole, Cell division, Organogenesis, DNA-protein interactions, Cell organelles--Formation, Basal body, Biology (General), Centrioles, biology, Receptors, Notch, General Neuroscience, Cell Differentiation, General Medicine, Cell cycle, Cell biology, Up-Regulation, Trachea, Protein Transport, Motile cilium, Medicine, cell cycle, Centriole assembly, Signal Transduction, Cdk2, QH301-705.5, Science, Movement, Mitosis, Mice, Transgenic, DNA replication, Microbiology, General Biochemistry, Genetics and Molecular Biology, 03 medical and health sciences, Cyclin-dependent kinase, Ciliogenesis, Cyclin E, centriole, Animals, Cilia, Cell Nucleus, 030102 biochemistry & molecular biology, General Immunology and Microbiology, Cyclin-Dependent Kinase 2, Epithelial Cells, Cyclin-dependent kinases, Mice, Inbred C57BL, 030104 developmental biology, Purines, FOS: Biological sciences, Mutation, biology.protein, Cyclin A1, ciliogenesis

Abstract

Cycling cells maintain centriole number at precisely two per cell in part by limiting their duplication to S phase under the control of the cell cycle machinery. In contrast, postmitotic multiciliated cells (MCCs) uncouple centriole assembly from cell cycle progression and produce hundreds of centrioles in the absence of DNA replication to serve as basal bodies for motile cilia. Although some cell cycle regulators have previously been implicated in motile ciliogenesis, how the cell cycle machinery is employed to amplify centrioles is unclear. We use transgenic mice and primary airway epithelial cell culture to show that Cdk2, the kinase responsible for the G1 to S phase transition, is also required in MCCs to initiate motile ciliogenesis. While Cdk2 is coupled with cyclins E and A2 during cell division, cyclin A1 is required during ciliogenesis, contributing to an alternative regulatory landscape that facilitates centriole amplification without DNA replication.

Published

2018

42. An ordered pattern of Ana2 phosphorylation by Plk4 is required for centriole assembly

Author

Daniel W. Buster, Cody J. Boese, Natalie A. Hollingsworth, Kevin C. Slep, John M. Ryniawec, Amy E. Byrnes, Gregory C. Rogers, Christopher W. Brownlee, Brian J. Galletta, Tiffany A. McLamarrah, and Nasser M. Rusan

Subjects

0301 basic medicine, PLK4, Centriole, sports, Mutant, Cell Cycle Proteins, Biology, Protein Serine-Threonine Kinases, Article, Cell Line, 03 medical and health sciences, Procentriole, 0302 clinical medicine, Animals, Drosophila Proteins, Protein Interaction Domains and Motifs, Phosphorylation, Kinase activity, Research Articles, Centrioles, 030304 developmental biology, 0303 health sciences, Kinase, Chemistry, Cell Cycle, Cell Biology, Cell biology, sports.league, Protein Transport, enzymes and coenzymes (carbohydrates), 030104 developmental biology, Drosophila melanogaster, Protein kinase domain, Mutation, Microtubule-Associated Proteins, 030217 neurology & neurosurgery, Protein Binding, Signal Transduction, Centriole assembly

Abstract

Centriole duplication is tightly regulated throughout the cell cycle to ensure one duplication event per centriole. McLamarrah et al. show that a stepwise pattern of Ana2 phosphorylation by Plk4 facilitates proper centriole duplication., Polo-like kinase 4 (Plk4) initiates an early step in centriole assembly by phosphorylating Ana2/STIL, a structural component of the procentriole. Here, we show that Plk4 binding to the central coiled-coil (CC) of Ana2 is a conserved event involving Polo-box 3 and a previously unidentified putative CC located adjacent to the kinase domain. Ana2 is then phosphorylated along its length. Previous studies showed that Plk4 phosphorylates the C-terminal STil/ANa2 (STAN) domain of Ana2/STIL, triggering binding and recruitment of the cartwheel protein Sas6 to the procentriole assembly site. However, the physiological relevance of N-terminal phosphorylation was unknown. We found that Plk4 first phosphorylates the extreme N terminus of Ana2, which is critical for subsequent STAN domain modification. Phosphorylation of the central region then breaks the Plk4–Ana2 interaction. This phosphorylation pattern is important for centriole assembly and integrity because replacement of endogenous Ana2 with phospho-Ana2 mutants disrupts distinct steps in Ana2 function and inhibits centriole duplication.

Published

2017

43. The Rise of the Cartwheel: Seeding the Centriole Organelle

Author

Pierre Gönczy, Paul Guichard, and Virginie Hamel

Subjects

0301 basic medicine, Physics, Organelles, Centriole, Cilium, Cell Cycle Proteins, Flagellum, Microtubules, General Biochemistry, Genetics and Molecular Biology, Cell biology, 03 medical and health sciences, Microscopy, Electron, 030104 developmental biology, 0302 clinical medicine, Microtubule, Centrosome, Basal body, Animals, Cilia, 030217 neurology & neurosurgery, Biogenesis, Centriole assembly, Centrioles

Abstract

The cartwheel is a striking structure critical for building the centriole, a microtubule-based organelle fundamental for organizing centrosomes, cilia, and flagella. Over the last 50 years, the cartwheel has been described in many systems using electron microscopy, but the molecular nature of its constituent building blocks and their assembly mechanisms have long remained mysterious. Here, we review discoveries that led to the current understanding of cartwheel structure, assembly, and function. We focus on the key role of SAS-6 protein self-organization, both for building the signature ring-like structure with hub and spokes, as well as for their vertical stacking. The resemblance of assembly intermediates in vitro and in vivo leads us to propose a novel registration step in cartwheel biogenesis, whereby stacked SAS-6-containing rings are put in register through interactions with peripheral elements anchored to microtubules. We conclude by evoking some avenues for further uncovering cartwheel and centriole assembly mechanisms.

Published

2017

44. Centrin 3 is an inhibitor of centrosomal Mps1 and antagonizes centrin 2 function

Author

Jennifer L. Perkins, Patrick A. Eyers, Dwitiya B. Sawant, Harold A. Fisk, Shubhra Majumder, and Ching-Hui Yang

Subjects

Centriole, Cell Cycle Proteins, Protein Serine-Threonine Kinases, Biology, Humans, Centrosome duplication, Amino Acid Sequence, Phosphorylation, Protein kinase A, Molecular Biology, Cells, Cultured, Centrioles, Centrosome, Cell Cycle, Calcium-Binding Proteins, Autophosphorylation, Articles, Cell Biology, Protein-Tyrosine Kinases, Cell biology, HEK293 Cells, Centrin, HeLa Cells, Centriole assembly

Abstract

Cetn3 inhibits Mps1 kinase activity in vitro and at centrosomes by blocking activating autophosphorylation and can prevent Mps1 from phosphorylating Cetn2 even when Mps1 is present at 10-fold molar excess. Cetn3 also prevents incorporation of Cetn2 into centrioles, but mimicking phosphorylation of Cetn2 bypasses the inhibitory effects of Cetn3., Centrins are a family of small, calcium-binding proteins with diverse cellular functions that play an important role in centrosome biology. We previously identified centrin 2 and centrin 3 (Cetn2 and Cetn3) as substrates of the protein kinase Mps1. However, although Mps1 phosphorylation sites control the function of Cetn2 in centriole assembly and promote centriole overproduction, Cetn2 and Cetn3 are not functionally interchangeable, and we show here that Cetn3 is both a biochemical inhibitor of Mps1 catalytic activity and a biological inhibitor of centrosome duplication. In vitro, Cetn3 inhibits Mps1 autophosphorylation at Thr-676, a known site of T-loop autoactivation, and interferes with Mps1-dependent phosphorylation of Cetn2. The cellular overexpression of Cetn3 attenuates the incorporation of Cetn2 into centrioles and centrosome reduplication, whereas depletion of Cetn3 generates extra centrioles. Finally, overexpression of Cetn3 reduces Mps1 Thr-676 phosphorylation at centrosomes, and mimicking Mps1-dependent phosphorylation of Cetn2 bypasses the inhibitory effect of Cetn3, suggesting that the biological effects of Cetn3 are due to the inhibition of Mps1 function at centrosomes.

Published

2015

45. A Short CEP135 Splice Isoform Controls Centriole Duplication

Author

Divya Ganapathi Sankaran, Thomas H. Giddings, Brian A. Bayless, Kristin D. Dahl, Chad G. Pearson, Mary Pinter, Lydia R. Heasley, and Domenico F. Galati

Subjects

Centriole, RNA Splicing, Cell Cycle Proteins, Biology, Microtubules, Article, General Biochemistry, Genetics and Molecular Biology, S Phase, Tubulin, Microtubule, Humans, Protein Isoforms, Basal body, Centrioles, Anaphase, Microtubule nucleation, Centrosome, Agricultural and Biological Sciences(all), Biochemistry, Genetics and Molecular Biology(all), Cell Cycle, Cell biology, CEP135, Carrier Proteins, General Agricultural and Biological Sciences, Microtubule-Associated Proteins, HeLa Cells, Protein Binding, Centriole assembly

Abstract

Centriole duplication is coordinated such that a single round of duplication occurs during each cell cycle. Disruption of this synchrony causes defects including supernumerary centrosomes in cancer and perturbed ciliary signaling [1-5]. To preserve the normal number of centrioles, the level, localization, and post-translational modification of centriole proteins is regulated so that, when centriole protein expression and/or activity are increased, centrioles self-assemble. Assembly is initiated by the formation of the cartwheel structure that comprises the base of centrioles [6-11]. SAS-6 constitutes the cartwheel, and SAS-6 levels remain low until centriole assembly is initiated at S phase onset [3, 12, 13]. CEP135 physically links to SAS-6 near the site of microtubule nucleation and binds to CPAP for triplet microtubule formation [13, 14]. We identify two distinct protein isoforms of CEP135 that antagonize each other to modulate centriole duplication: full-length CEP135 (CEP135(full)) promotes new assembly, whereas a short isoform, CEP135(mini), represses it. CEP135(mini) represses centriole duplication by limiting the centriolar localization of CEP135(full) binding proteins (SAS-6 and CPAP) and the pericentriolar localization of γ-tubulin. The CEP135 isoforms exhibit distinct and complementary centrosomal localization during the cell cycle. CEP135(mini) protein decreases from centrosomes upon anaphase onset. We suggest that the decrease in CEP135(mini) from centrosomes promotes centriole assembly. The repression of centriole duplication by a splice isoform of a protein that normally promotes it serves as a novel mechanism to limit centriole duplication.

Published

2015

46. Reversible centriole depletion with an inhibitor of Polo-like kinase 4

Author

Amir Motamedi, Karen Oegema, Andrew K. Shiau, Jennifer W. Mitchell, Sun K. Kim, Michelle Yoon, John V. Anzola, Brian J. Mitchell, Chanmee P. Seo, Timothy C. Gahman, Ashley V. Kroll, Judy E. Hsia, Robert L. Davis, Yao Liang Wong, and Arshad Desai

Subjects

PLK4, Multidisciplinary, Centriole, Hippo signaling, Centrosome, Cancer cell, Polo-like kinase, Biology, Mitosis, Centriole assembly, Cell biology

Abstract

Giving an old organelle the old heave-ho Centrioles are ancient cellular organelles that build centrosomes, the major microtubule-organizing centers in animal cells. Duplication of centrioles is tightly controlled to ensure that each dividing cell has precisely two centrosomes. Human cancer cells often have extra centrosomes, which has been hypothesized to confer a proliferative advantage. Wong et al. developed small molecules (centrinones) that allowed them to reversibly “delete” centrioles from cells (see the Perspective by Stearns). Surprisingly, cancer cells continued to divide in the absence of centrosomes, whereas normal cells stopped dividing. Science , this issue p. 1155 ; see also p. 1091

Published

2015

47. Two Polo-like kinase 4 binding domains in Asterless perform distinct roles in regulating kinase stability

Author

Natalie A. Hollingsworth, Jonathan Nye, Kevin C. Slep, Daniel W. Buster, Gregory C. Rogers, Nasser M. Rusan, Brian J. Galletta, Joseph E. Klebba, and Karen M. Plevock

Subjects

Scaffold protein, PLK4, Centriole, Mitosis, Cell Cycle Proteins, Plasma protein binding, Polo-like kinase, Protein Serine-Threonine Kinases, Biology, Article, Cell Line, Enzyme Stability, otorhinolaryngologic diseases, Animals, Drosophila Proteins, Phosphorylation, RNA, Small Interfering, Research Articles, Centrioles, Genetics, Cell Cycle, Autophosphorylation, Cell Biology, Protein Structure, Tertiary, 3. Good health, Cell biology, Drosophila melanogaster, RNA Interference, Protein Multimerization, Protein Binding, Centriole assembly

Abstract

The Asterless N terminus promotes Plk4 homodimerization and autophosphorylation during interphase, whereas its C terminus stabilizes Plk4 during mitosis., Plk4 (Polo-like kinase 4) and its binding partner Asterless (Asl) are essential, conserved centriole assembly factors that induce centriole amplification when overexpressed. Previous studies found that Asl acts as a scaffolding protein; its N terminus binds Plk4’s tandem Polo box cassette (PB1-PB2) and targets Plk4 to centrioles to initiate centriole duplication. However, how Asl overexpression drives centriole amplification is unknown. In this paper, we investigated the Asl–Plk4 interaction in Drosophila melanogaster cells. Surprisingly, the N-terminal region of Asl is not required for centriole duplication, but a previously unidentified Plk4-binding domain in the C terminus is required. Mechanistic analyses of the different Asl regions revealed that they act uniquely during the cell cycle: the Asl N terminus promotes Plk4 homodimerization and autophosphorylation during interphase, whereas the Asl C terminus stabilizes Plk4 during mitosis. Therefore, Asl affects Plk4 in multiple ways to regulate centriole duplication. Asl not only targets Plk4 to centrioles but also modulates Plk4 stability and activity, explaining the ability of overexpressed Asl to drive centriole amplification.

Published

2015

48. Plk4-dependent phosphorylation of STIL is required for centriole duplication

Author

Anne-Sophie Kratz, Felix Bärenz, Ingrid Hoffmann, and Kai T. Richter

Subjects

Genetics, PLK4, Centrosome, Centriole duplication, Centriole, QH301-705.5, sports, Science, Biology, General Biochemistry, Genetics and Molecular Biology, Cell biology, sports.league, Procentriole, STIL, Gene duplication, Plk4, Phosphorylation, Biology (General), General Agricultural and Biological Sciences, Biogenesis, Centriole assembly, Research Article

Abstract

Duplication of centrioles, namely the formation of a procentriole next to the parental centriole, is regulated by the polo-like kinase Plk4. Only a few other proteins, including STIL (SCL/TAL1 interrupting locus, SIL) and Sas-6, are required for the early step of centriole biogenesis. Following Plk4 activation, STIL and Sas-6 accumulate at the cartwheel structure at the initial stage of the centriole assembly process. Here, we show that STIL interacts with Plk4 in vivo. A STIL fragment harboring both the coiled-coil domain and the STAN motif shows the strongest binding affinity to Plk4. Furthermore, we find that STIL is phosphorylated by Plk4. We identified Plk4-specific phosphorylation sites within the C-terminal domain of STIL and show that phosphorylation of STIL by Plk4 is required to trigger centriole duplication.

Published

2015

49. Binding of STIL to Plk4 activates kinase activity to promote centriole assembly

Author

Kevin M. Clutario, Bramwell G. Lambrus, Vikas Daggubati, Tyler C. Moyer, and Andrew J. Holland

Subjects

PLK4, Indazoles, Indoles, Centriole, Cell division, sports, Biology, Protein Serine-Threonine Kinases, Article, Antibodies, Cell Line, Procentriole, Adenosine Triphosphate, Humans, Kinase activity, Phosphorylation, RNA, Small Interfering, Research Articles, Centrioles, Binding Sites, HEK 293 cells, Intracellular Signaling Peptides and Proteins, Cell Biology, Cell Cycle Checkpoints, 3. Good health, Cell biology, Protein Structure, Tertiary, sports.league, Enzyme Activation, HEK293 Cells, Centrosome, RNA Interference, RNA Editing, Microtubule-Associated Proteins, Cell Division, Centriole assembly, Protein Binding

Abstract

Binding of STIL activates Plk4, and the subsequent phosphorylation of STIL by Plk4 primes the binding of STIL to SAS6 to promote centriole assembly., Centriole duplication occurs once per cell cycle in order to maintain control of centrosome number and ensure genome integrity. Polo-like kinase 4 (Plk4) is a master regulator of centriole biogenesis, but how its activity is regulated to control centriole assembly is unclear. Here we used gene editing in human cells to create a chemical genetic system in which endogenous Plk4 can be specifically inhibited using a cell-permeable ATP analogue. Using this system, we demonstrate that STIL localization to the centriole requires continued Plk4 activity. Most importantly, we show that direct binding of STIL activates Plk4 by promoting self-phosphorylation of the activation loop of the kinase. Plk4 subsequently phosphorylates STIL to promote centriole assembly in two steps. First, Plk4 activity promotes the recruitment of STIL to the centriole. Second, Plk4 primes the direct binding of STIL to the C terminus of SAS6. Our findings uncover a molecular basis for the timing of Plk4 activation through the cell cycle–regulated accumulation of STIL.

Published

2015

50. Human microcephaly protein RTTN interacts with STIL and is required to build full-length centrioles

Author

Hsin Yi Chen, Chien-Ting Wu, Tang K. Tang, Yi-Nan Lin, Won Jing Wang, and Chieh Ju C. Tang

Subjects

0301 basic medicine, Microcephaly, Centriole, Science, sports, Mutant, General Physics and Astronomy, Cell Cycle Proteins, Plasma protein binding, Biology, medicine.disease_cause, Article, General Biochemistry, Genetics and Molecular Biology, 03 medical and health sciences, Procentriole, medicine, Humans, Gene knockout, Centrioles, Genetics, Mutation, Multidisciplinary, Intracellular Signaling Peptides and Proteins, General Chemistry, medicine.disease, sports.league, 030104 developmental biology, Carrier Proteins, Protein Binding, Centriole assembly

Abstract

Mutations in many centriolar protein-encoding genes cause primary microcephaly. Using super-resolution and electron microscopy, we find that the human microcephaly protein, RTTN, is recruited to the proximal end of the procentriole at early S phase, and is located at the inner luminal walls of centrioles. Further studies demonstrate that RTTN directly interacts with STIL and acts downstream of STIL-mediated centriole assembly. CRISPR/Cas9-mediated RTTN gene knockout in p53-deficient cells induce amplification of primitive procentriole bodies that lack the distal-half centriolar proteins, POC5 and POC1B. Additional analyses show that RTTN serves as an upstream effector of CEP295, which mediates the loading of POC1B and POC5 to the distal-half centrioles. Interestingly, the naturally occurring microcephaly-associated mutant, RTTN (A578P), shows a low affinity for STIL binding and blocks centriole assembly. These findings reveal that RTTN contributes to building full-length centrioles and illuminate the molecular mechanism through which the RTTN (A578P) mutation causes primary microcephaly., Mutations in many centriolar protein-encoding genes cause primary microcephaly. Here the authors show that human microcephaly protein RTTN directly interacts with STIL and acts downstream of STIL-mediated centriole assembly, contributing to building full-length centrioles

Published

2017