Literature DB >> 30787442

The centrosome protein AKNA regulates neurogenesis via microtubule organization.

Germán Camargo Ortega1,2,3, Sven Falk1,2, Pia A Johansson1,2,4, Elise Peyre5, Loïc Broix5, Sanjeeb Kumar Sahu6, William Hirst7,8, Thomas Schlichthaerle9,10, Camino De Juan Romero11, Kalina Draganova1,2, Stanislav Vinopal12, Kaviya Chinnappa1,11, Anna Gavranovic1, Tugay Karakaya1, Thomas Steininger1, Juliane Merl-Pham13, Regina Feederle14,15, Wei Shao16,17, Song-Hai Shi16,17, Stefanie M Hauck13, Ralf Jungmann9,10, Frank Bradke12, Victor Borrell11, Arie Geerlof18, Simone Reber7,19, Vijay K Tiwari6, Wieland B Huttner20, Michaela Wilsch-Bräuninger20, Laurent Nguyen5, Magdalena Götz21,22,23,24.   

Abstract

The expansion of brain size is accompanied by a relative enlargement of the subventricular zone during development. Epithelial-like neural stem cells divide in the ventricular zone at the ventricles of the embryonic brain, self-renew and generate basal progenitors1 that delaminate and settle in the subventricular zone in enlarged brain regions2. The length of time that cells stay in the subventricular zone is essential for controlling further amplification and fate determination. Here we show that the interphase centrosome protein AKNA has a key role in this process. AKNA localizes at the subdistal appendages of the mother centriole in specific subtypes of neural stem cells, and in almost all basal progenitors. This protein is necessary and sufficient to organize centrosomal microtubules, and promote their nucleation and growth. These features of AKNA are important for mediating the delamination process in the formation of the subventricular zone. Moreover, AKNA regulates the exit from the subventricular zone, which reveals the pivotal role of centrosomal microtubule organization in enabling cells to both enter and remain in the subventricular zone. The epithelial-to-mesenchymal transition is also regulated by AKNA in other epithelial cells, demonstrating its general importance for the control of cell delamination.

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Year:  2019        PMID: 30787442     DOI: 10.1038/s41586-019-0962-4

Source DB:  PubMed          Journal:  Nature        ISSN: 0028-0836            Impact factor:   49.962


  33 in total

1.  Transcriptome sequencing during mouse brain development identifies long non-coding RNAs functionally involved in neurogenic commitment.

Authors:  Julieta Aprea; Silvia Prenninger; Martina Dori; Tanay Ghosh; Laura Sebastian Monasor; Elke Wessendorf; Sara Zocher; Simone Massalini; Dimitra Alexopoulou; Mathias Lesche; Andreas Dahl; Matthias Groszer; Michael Hiller; Federico Calegari
Journal:  EMBO J       Date:  2013-11-15       Impact factor: 11.598

2.  Prospective isolation of functionally distinct radial glial subtypes--lineage and transcriptome analysis.

Authors:  Luisa Pinto; Michael T Mader; Martin Irmler; Marco Gentilini; Federico Santoni; Daniela Drechsel; Robert Blum; Ronny Stahl; Alessandro Bulfone; Paolo Malatesta; Johannes Beckers; Magdalena Götz
Journal:  Mol Cell Neurosci       Date:  2008-02-01       Impact factor: 4.314

Review 3.  The cell biology of neurogenesis: toward an understanding of the development and evolution of the neocortex.

Authors:  Elena Taverna; Magdalena Götz; Wieland B Huttner
Journal:  Annu Rev Cell Dev Biol       Date:  2014-06-27       Impact factor: 13.827

4.  Trnp1 regulates expansion and folding of the mammalian cerebral cortex by control of radial glial fate.

Authors:  Ronny Stahl; Tessa Walcher; Camino De Juan Romero; Gregor Alexander Pilz; Silvia Cappello; Martin Irmler; José Miguel Sanz-Aquela; Johannes Beckers; Robert Blum; Víctor Borrell; Magdalena Götz
Journal:  Cell       Date:  2013-04-25       Impact factor: 41.582

Review 5.  The centrosome cycle: Centriole biogenesis, duplication and inherent asymmetries.

Authors:  Erich A Nigg; Tim Stearns
Journal:  Nat Cell Biol       Date:  2011-10-03       Impact factor: 28.824

6.  Regulation of CD40 and CD40 ligand by the AT-hook transcription factor AKNA.

Authors:  A Siddiqa; J C Sims-Mourtada; L Guzman-Rojas; R Rangel; C Guret; V Madrid-Marina; Y Sun; H Martinez-Valdez
Journal:  Nature       Date:  2001-03-15       Impact factor: 49.962

7.  AP2gamma regulates basal progenitor fate in a region- and layer-specific manner in the developing cortex.

Authors:  Luisa Pinto; Daniela Drechsel; Marie-Theres Schmid; Jovica Ninkovic; Martin Irmler; Monika S Brill; Laura Restani; Laura Gianfranceschi; Chiara Cerri; Susanne N Weber; Victor Tarabykin; Kristin Baer; François Guillemot; Johannes Beckers; Nada Zecevic; Colette Dehay; Matteo Caleo; Hubert Schorle; Magdalena Götz
Journal:  Nat Neurosci       Date:  2009-09-13       Impact factor: 24.884

Review 8.  Cerebral cortex expansion and folding: what have we learned?

Authors:  Virginia Fernández; Cristina Llinares-Benadero; Víctor Borrell
Journal:  EMBO J       Date:  2016-04-07       Impact factor: 11.598

9.  Cortical neurogenesis in the absence of centrioles.

Authors:  Ryan Insolera; Hisham Bazzi; Wei Shao; Kathryn V Anderson; Song-Hai Shi
Journal:  Nat Neurosci       Date:  2014-10-05       Impact factor: 24.884

Review 10.  Who are you, subdistal appendages of centriole?

Authors:  Rustem Uzbekov; Irina Alieva
Journal:  Open Biol       Date:  2018-07       Impact factor: 6.411
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  19 in total

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Authors:  Eneritz Agirre; Mohammed Inayatullah; Sanjeeb Kumar Sahu; Arun Mahesh; Neha Tiwari; Deborah P Lavin; Aditi Singh; Susanne Strand; Mustafa Diken; Reini F Luco; Juan Carlos Izpisua Belmonte; Vijay K Tiwari
Journal:  Nat Cell Biol       Date:  2022-08-08       Impact factor: 28.213

2.  Centrosome linker protein C-Nap1 maintains stem cells in mouse testes.

Authors:  Hairuo Dang; Ana Martin-Villalba; Elmar Schiebel
Journal:  EMBO Rep       Date:  2022-05-23       Impact factor: 9.071

3.  CAMSAPs organize an acentrosomal microtubule network from basal varicosities in radial glial cells.

Authors:  Laure Coquand; Guiliana Soraya Victoria; Alice Tata; Jacopo Amerigo Carpentieri; Jean-Baptiste Brault; Fabien Guimiot; Vincent Fraisier; Alexandre D Baffet
Journal:  J Cell Biol       Date:  2021-05-21       Impact factor: 10.539

Review 4.  Moonlighting in Mitosis: Analysis of the Mitotic Functions of Transcription and Splicing Factors.

Authors:  Maria Patrizia Somma; Evgeniya N Andreyeva; Gera A Pavlova; Claudia Pellacani; Elisabetta Bucciarelli; Julia V Popova; Silvia Bonaccorsi; Alexey V Pindyurin; Maurizio Gatti
Journal:  Cells       Date:  2020-06-26       Impact factor: 6.600

5.  PI3K-Yap activity drives cortical gyrification and hydrocephalus in mice.

Authors:  Achira Roy; Rory M Murphy; Mei Deng; James W MacDonald; Theo K Bammler; Kimberly A Aldinger; Ian A Glass; Kathleen J Millen
Journal:  Elife       Date:  2019-05-16       Impact factor: 8.140

Review 6.  Recent advances in understanding neocortical development.

Authors:  Victor Borrell
Journal:  F1000Res       Date:  2019-10-23

7.  Early dorsomedial tissue interactions regulate gyrification of distal neocortex.

Authors:  Victor V Chizhikov; Igor Y Iskusnykh; Ekaterina Y Steshina; Nikolai Fattakhov; Anne G Lindgren; Ashwin S Shetty; Achira Roy; Shubha Tole; Kathleen J Millen
Journal:  Nat Commun       Date:  2019-11-15       Impact factor: 14.919

8.  AKNA Is a Potential Prognostic Biomarker in Gastric Cancer and Function as a Tumor Suppressor by Modulating EMT-Related Pathways.

Authors:  Gang Wang; Dan Sun; Wenhui Li; Yan Xin
Journal:  Biomed Res Int       Date:  2020-05-13       Impact factor: 3.411

9.  MAP7 promotes migration and invasion and progression of human cervical cancer through modulating the autophagy.

Authors:  Li Zhang; Xudong Liu; Lina Song; Hui Zhai; Chaohua Chang
Journal:  Cancer Cell Int       Date:  2020-01-13       Impact factor: 5.722

10.  ABHD4-dependent developmental anoikis safeguards the embryonic brain.

Authors:  Zsófia I László; Zsolt Lele; Miklós Zöldi; Vivien Miczán; Fruzsina Mógor; Gabriel M Simon; Ken Mackie; Imre Kacskovics; Benjamin F Cravatt; István Katona
Journal:  Nat Commun       Date:  2020-08-31       Impact factor: 14.919
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