Literature DB >> 16888325

The drosophila fragile X protein dFMR1 is required during early embryogenesis for pole cell formation and rapid nuclear division cycles.

Girish Deshpande1, Gretchen Calhoun, Paul Schedl.   

Abstract

The FMR family of KH domain RNA-binding proteins is conserved from invertebrates to humans. In humans, inactivation of the X-linked FMR gene fragile X is the most common cause of mental retardation and leads to defects in neuronal architecture. While there are three FMR family members in humans, there is only a single gene, dfmr1, in flies. As in humans, inactivation of dfmr1 causes defects in neuronal architecture and in behavior. dfmr1 has other functions in the fly in addition to neurogenesis. Here we have analyzed its role during early embryonic development. We found that dfmr1 embryos display defects in the rapid nuclear division cycles that precede gastrulation in nuclear migration and in pole cell formation. While the aberrations in nuclear division are correlated with a defect in the assembly of centromeric/centric heterochromatin, the defects in pole cell formation are associated with alterations in the actin-myosin cytoskeleton.

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Year:  2006        PMID: 16888325      PMCID: PMC1667070          DOI: 10.1534/genetics.106.062414

Source DB:  PubMed          Journal:  Genetics        ISSN: 0016-6731            Impact factor:   4.562


  46 in total

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Journal:  Annu Rev Cell Dev Biol       Date:  1996       Impact factor: 13.827

Review 2.  RNA and microRNAs in fragile X mental retardation.

Authors:  Peng Jin; Reid S Alisch; Stephen T Warren
Journal:  Nat Cell Biol       Date:  2004-11       Impact factor: 28.824

3.  The Drosophila peanut gene is required for cytokinesis and encodes a protein similar to yeast putative bud neck filament proteins.

Authors:  T P Neufeld; G M Rubin
Journal:  Cell       Date:  1994-05-06       Impact factor: 41.582

4.  Characterization of sequences associated with position-effect variegation at pericentric sites in Drosophila heterochromatin.

Authors:  D E Cryderman; M H Cuaycong; S C Elgin; L L Wallrath
Journal:  Chromosoma       Date:  1998-11       Impact factor: 4.316

5.  Localization and possible functions of Drosophila septins.

Authors:  H Fares; M Peifer; J R Pringle
Journal:  Mol Biol Cell       Date:  1995-12       Impact factor: 4.138

6.  Transcriptionally repressed germ cells lack a subpopulation of phosphorylated RNA polymerase II in early embryos of Caenorhabditis elegans and Drosophila melanogaster.

Authors:  G Seydoux; M A Dunn
Journal:  Development       Date:  1997-06       Impact factor: 6.868

7.  Mutations affecting the cytoskeletal organization of syncytial Drosophila embryos.

Authors:  W Sullivan; P Fogarty; W Theurkauf
Journal:  Development       Date:  1993-08       Impact factor: 6.868

8.  Heterochromatin protein 1 distribution during development and during the cell cycle in Drosophila embryos.

Authors:  R Kellum; J W Raff; B M Alberts
Journal:  J Cell Sci       Date:  1995-04       Impact factor: 5.285

9.  Heterochromatin protein 1 is required for correct chromosome segregation in Drosophila embryos.

Authors:  R Kellum; B M Alberts
Journal:  J Cell Sci       Date:  1995-04       Impact factor: 5.285

10.  Anillin, a contractile ring protein that cycles from the nucleus to the cell cortex.

Authors:  C M Field; B M Alberts
Journal:  J Cell Biol       Date:  1995-10       Impact factor: 10.539
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  19 in total

1.  Molecular and genetic analysis of the Drosophila model of fragile X syndrome.

Authors:  Charles R Tessier; Kendal Broadie
Journal:  Results Probl Cell Differ       Date:  2012

2.  Centromeres were derived from telomeres during the evolution of the eukaryotic chromosome.

Authors:  Alfredo Villasante; José P Abad; María Méndez-Lago
Journal:  Proc Natl Acad Sci U S A       Date:  2007-06-08       Impact factor: 11.205

3.  Germ Cell Lineage Homeostasis in Drosophila Requires the Vasa RNA Helicase.

Authors:  Zeljko Durdevic; Anne Ephrussi
Journal:  Genetics       Date:  2019-09-04       Impact factor: 4.562

4.  Substitution of critical isoleucines in the KH domains of Drosophila fragile X protein results in partial loss-of-function phenotypes.

Authors:  Paromita Banerjee; Shweta Nayar; Sarita Hebbar; Catherine F Fox; Michele C Jacobs; Jae H Park; Joyce J Fernandes; Thomas C Dockendorff
Journal:  Genetics       Date:  2006-12-28       Impact factor: 4.562

5.  Short- and long-term memory are modulated by multiple isoforms of the fragile X mental retardation protein.

Authors:  Paromita Banerjee; Brian P Schoenfeld; Aaron J Bell; Catherine H Choi; Michael P Bradley; Paul Hinchey; Maria Kollaros; Jae H Park; Sean M J McBride; Thomas C Dockendorff
Journal:  J Neurosci       Date:  2010-05-12       Impact factor: 6.167

6.  Proteomic analysis reveals CCT is a target of Fragile X mental retardation protein regulation in Drosophila.

Authors:  Kate Monzo; Susan R Dowd; Jonathan S Minden; John C Sisson
Journal:  Dev Biol       Date:  2010-02-01       Impact factor: 3.582

7.  NAT1/DAP5/p97 and atypical translational control in the Drosophila Circadian Oscillator.

Authors:  Sean Bradley; Siddhartha Narayanan; Michael Rosbash
Journal:  Genetics       Date:  2012-08-17       Impact factor: 4.562

Review 8.  Small RNA-directed heterochromatin formation in the context of development: what flies might learn from fission yeast.

Authors:  Kathryn L Huisinga; Sarah C R Elgin
Journal:  Biochim Biophys Acta       Date:  2008-08-16

9.  Zfrp8 forms a complex with fragile-X mental retardation protein and regulates its localization and function.

Authors:  William Tan; Curtis Schauder; Tatyana Naryshkina; Svetlana Minakhina; Ruth Steward
Journal:  Dev Biol       Date:  2016-01-07       Impact factor: 3.582

10.  Drosophila RISC component VIG and its homolog Vig2 impact heterochromatin formation.

Authors:  Elena Gracheva; Monica Dus; Sarah C R Elgin
Journal:  PLoS One       Date:  2009-07-08       Impact factor: 3.240
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