Warning: Undefined array key "mm" in /www/wwwroot/www.ai-bt.com/si.php on line 10 Deprecated: trim(): Passing null to parameter #1 ($string) of type string is deprecated in /www/wwwroot/www.ai-bt.com/si.php on line 10 Amorphous no more: subdiffraction view of the pericentriolar material architecture.

Literature DB >> 24268653

Amorphous no more: subdiffraction view of the pericentriolar material architecture.

Vito Mennella¹, David A Agard², Bo Huang³, Laurence Pelletier⁴.

Abstract

The centrosome influences the shape, orientation and activity of the microtubule cytoskeleton. The pericentriolar material (PCM), determines this functionality by providing a dynamic platform for nucleating microtubules and acts as a nexus for molecular signaling. Although great strides have been made in understanding PCM activity, its diffraction-limited size and amorphous appearance on electron microscopy (EM) have limited analysis of its high-order organization. Here, we outline current knowledge of PCM architecture and assembly, emphasizing recent super-resolution imaging studies that revealed the PCM has a layered structure made of fibers and matrices conserved from flies to humans. Notably, these studies debunk the long-standing view of an amorphous PCM and provide a paradigm to dissect the supramolecular organization of organelles in cells.

Entities: CellLine Chemical Disease Gene Species

Keywords: cell cycle; centrosomes; cilia; mitosis; pericentriolar material; super-resolution microscopy

Mesh：

Year: 2013 PMID： 24268653 PMCID： PMC3991556 DOI： 10.1016/j.tcb.2013.10.001

Source DB: PubMed Journal: Trends Cell Biol ISSN： 0962-8924 Impact factor: 20.808

113 in total

Review 1. Centrosome composition and microtubule anchoring mechanisms.

Authors: Michel Bornens
Journal: Curr Opin Cell Biol Date: 2002-02 Impact factor: 8.382

Review 2. The centrosome in cells and organisms.

Authors: Michel Bornens
Journal: Science Date: 2012-01-27 Impact factor: 47.728

3. Novel NEDD1 phosphorylation sites regulate γ-tubulin binding and mitotic spindle assembly.

Authors: Maria Ana Gomez-Ferreria; Mikhail Bashkurov; Andreas O Helbig; Brett Larsen; Tony Pawson; Anne-Claude Gingras; Laurence Pelletier
Journal: J Cell Sci Date: 2012-05-17 Impact factor: 5.285

4. Sas-4 provides a scaffold for cytoplasmic complexes and tethers them in a centrosome.

Authors: Jayachandran Gopalakrishnan; Vito Mennella; Stephanie Blachon; Bo Zhai; Andrew H Smith; Timothy L Megraw; Daniela Nicastro; Steven P Gygi; David A Agard; Tomer Avidor-Reiss
Journal: Nat Commun Date: 2011-06-21 Impact factor: 14.919

Review 5. Microtubule nucleation by γ-tubulin complexes.

Authors: Justin M Kollman; Andreas Merdes; Lionel Mourey; David A Agard
Journal: Nat Rev Mol Cell Biol Date: 2011-10-12 Impact factor: 94.444

6. Human Cep192 is required for mitotic centrosome and spindle assembly.

Authors: Maria Ana Gomez-Ferreria; Uttama Rath; Daniel W Buster; Sumit K Chanda; Jeremy S Caldwell; Daniel R Rines; David J Sharp
Journal: Curr Biol Date: 2007-11-01 Impact factor: 10.834

7. Human Cep192 and Cep152 cooperate in Plk4 recruitment and centriole duplication.

Authors: Katharina F Sonnen; Anna-Maria Gabryjonczyk; Eduard Anselm; York-Dieter Stierhof; Erich A Nigg
Journal: J Cell Sci Date: 2013-05-02 Impact factor: 5.285

8. CDK5RAP2 stimulates microtubule nucleation by the gamma-tubulin ring complex.

Authors: Yuk-Kwan Choi; Pengfei Liu; Siu Kwan Sze; Chao Dai; Robert Z Qi
Journal: J Cell Biol Date: 2010-12-06 Impact factor: 10.539

9. Aurora-A kinase is required for centrosome maturation in Caenorhabditis elegans.

Authors: E Hannak; M Kirkham; A A Hyman; K Oegema
Journal: J Cell Biol Date: 2001-12-17 Impact factor: 10.539

10. The augmin complex plays a critical role in spindle microtubule generation for mitotic progression and cytokinesis in human cells.

Authors: Ryota Uehara; Ryu-suke Nozawa; Akiko Tomioka; Sabine Petry; Ronald D Vale; Chikashi Obuse; Gohta Goshima
Journal: Proc Natl Acad Sci U S A Date: 2009-04-14 Impact factor: 11.205

64 in total

Review 1. Centrosome function and assembly in animal cells.

Authors: Paul T Conduit; Alan Wainman; Jordan W Raff
Journal: Nat Rev Mol Cell Biol Date: 2015-09-16 Impact factor: 94.444

2. Correlative light and electron microscopy analysis of the centrosome: A step-by-step protocol.

Authors: Dong Kong; Jadranka Loncarek
Journal: Methods Cell Biol Date: 2015-05-27 Impact factor: 1.441

3. A semi-automated machine learning-aided approach to quantitative analysis of centrosomes and microtubule organization.

Authors: Divya Ganapathi Sankaran; Alexander J Stemm-Wolf; Bailey L McCurdy; Bharath Hariharan; Chad G Pearson
Journal: J Cell Sci Date: 2020-07-30 Impact factor: 5.285

4. Analyzing Centrioles and Cilia by Expansion Microscopy.

Authors: Dong Kong; Jadranka Loncarek
Journal: Methods Mol Biol Date: 2021

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

Authors: Jieyan V Chen; Rebecca A Buchwalter; Ling-Rong Kao; Timothy L Megraw
Journal: Curr Biol Date: 2017-06-29 Impact factor: 10.834

Review 6. The Centrosome, a Multitalented Renaissance Organelle.

Authors: Anastassiia Vertii; Heidi Hehnly; Stephen Doxsey
Journal: Cold Spring Harb Perspect Biol Date: 2016-12-01 Impact factor: 10.005

7. Three-dimensional Super Resolution Microscopy of F-actin Filaments by Interferometric PhotoActivated Localization Microscopy (iPALM).

Authors: Yilin Wang; Pakorn Kanchanawong
Journal: J Vis Exp Date: 2016-12-01 Impact factor: 1.355

Review 8. Centriole structure.

Authors: Mark Winey; Eileen O'Toole
Journal: Philos Trans R Soc Lond B Biol Sci Date: 2014-09-05 Impact factor: 6.237

Review 9. One to only two: a short history of the centrosome and its duplication.

Authors: Greenfield Sluder
Journal: Philos Trans R Soc Lond B Biol Sci Date: 2014-09-05 Impact factor: 6.237

Review 10. Microtubule-organizing centers: from the centrosome to non-centrosomal sites.

Authors: Ariana D Sanchez; Jessica L Feldman
Journal: Curr Opin Cell Biol Date: 2016-09-22 Impact factor: 8.382