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Literature DB >> 21270334

Poly(ADP-ribose) polymerase 3 (PARP3), a newcomer in cellular response to DNA damage and mitotic progression.

Christian Boehler¹, Laurent R Gauthier, Oliver Mortusewicz, Denis S Biard, Jean-Michel Saliou, Anne Bresson, Sarah Sanglier-Cianferani, Susan Smith, Valérie Schreiber, François Boussin, Françoise Dantzer.

Abstract

The ADP ribosyl transferase [poly(ADP-ribose) polymerase] ARTD3(PARP3) is a newly characterized member of the ARTD(PARP) family that catalyzes the reaction of ADP ribosylation, a key posttranslational modification of proteins involved in different signaling pathways from DNA damage to energy metabolism and organismal memory. This enzyme shares high structural similarities with the DNA repair enzymes PARP1 and PARP2 and accordingly has been found to catalyse poly(ADP ribose) synthesis. However, relatively little is known about its in vivo cellular properties. By combining biochemical studies with the generation and characterization of loss-of-function human and mouse models, we describe PARP3 as a newcomer in genome integrity and mitotic progression. We report a particular role of PARP3 in cellular response to double-strand breaks, most likely in concert with PARP1. We identify PARP3 as a critical player in the stabilization of the mitotic spindle and in telomere integrity notably by associating and regulating the mitotic components NuMA and tankyrase 1. Both functions open stimulating prospects for specifically targeting PARP3 in cancer therapy.

Entities: Chemical Disease Gene Species

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Year: 2011 PMID： 21270334 PMCID： PMC3041075 DOI： 10.1073/pnas.1016574108

Source DB: PubMed Journal: Proc Natl Acad Sci U S A ISSN： 0027-8424 Impact factor: 11.205

25 in total

1. PARP-3 is a mono-ADP-ribosylase that activates PARP-1 in the absence of DNA.

Authors: Olga Loseva; Ann-Sofie Jemth; Helen E Bryant; Herwig Schüler; Lari Lehtiö; Tobias Karlberg; Thomas Helleday
Journal: J Biol Chem Date: 2010-01-11 Impact factor: 5.157

2. A human poly(ADP-ribose) polymerase gene family (ADPRTL): cDNA cloning of two novel poly(ADP-ribose) polymerase homologues.

Authors: M Johansson
Journal: Genomics Date: 1999-05-01 Impact factor: 5.736

3. PARP-3 and APLF function together to accelerate nonhomologous end-joining.

Authors: Stuart L Rulten; Anna E O Fisher; Isabelle Robert; Maria C Zuma; Michele Rouleau; Limei Ju; Guy Poirier; Bernardo Reina-San-Martin; Keith W Caldecott
Journal: Mol Cell Date: 2011-01-07 Impact factor: 17.970

4. The role of NuMA in the interphase nucleus.

Authors: A Merdes; D W Cleveland
Journal: J Cell Sci Date: 1998-01 Impact factor: 5.285

5. PARP-3 localizes preferentially to the daughter centriole and interferes with the G1/S cell cycle progression.

Authors: Angélique Augustin; Catherine Spenlehauer; Hélène Dumond; Josiane Ménissier-De Murcia; Matthieu Piel; Anne-Catherine Schmit; Françoise Apiou; Jean-Luc Vonesch; Michael Kock; Michel Bornens; Gilbert De Murcia
Journal: J Cell Sci Date: 2003-04-15 Impact factor: 5.285

6. Cloning and expression of PARP-3 (Adprt3) and U3-55k, two genes closely linked on mouse chromosome 9.

Authors: P Urbánek; J Paces; J Králová; M Dvorák; V Paces
Journal: Folia Biol (Praha) Date: 2002 Impact factor: 0.906

7. Cell cycle defects in polyhomeotic mutants are caused by abrogation of the DNA damage checkpoint.

Authors: Samantha A Beck; Ester Falconer; Amanda Catching; Jacob W Hodgson; Hugh W Brock
Journal: Dev Biol Date: 2010-01-04 Impact factor: 3.582

Review 8. Toward a unified nomenclature for mammalian ADP-ribosyltransferases.

Authors: Michael O Hottiger; Paul O Hassa; Bernhard Lüscher; Herwig Schüler; Friedrich Koch-Nolte
Journal: Trends Biochem Sci Date: 2010-01-26 Impact factor: 13.807

9. NuMA is required for proper spindle assembly and chromosome alignment in prometaphase.

Authors: Laurence Haren; Nicole Gnadt; Michel Wright; Andreas Merdes
Journal: BMC Res Notes Date: 2009-04-28

10. Sister telomeres rendered dysfunctional by persistent cohesion are fused by NHEJ.

Authors: Susan J Hsiao; Susan Smith
Journal: J Cell Biol Date: 2009-02-16 Impact factor: 10.539

121 in total

1. Spontaneous transformation of murine epithelial cells requires the early acquisition of specific chromosomal aneuploidies and genomic imbalances.

Authors: Hesed M Padilla-Nash; Karen Hathcock; Nicole E McNeil; David Mack; Daniel Hoeppner; Rea Ravin; Turid Knutsen; Raluca Yonescu; Danny Wangsa; Kathleen Dorritie; Linda Barenboim; Yue Hu; Thomas Ried
Journal: Genes Chromosomes Cancer Date: 2011-12-08 Impact factor: 5.006

2. The potential for poly (ADP-ribose) polymerase inhibitors in cancer therapy.

Authors: M Javle; N J Curtin
Journal: Ther Adv Med Oncol Date: 2011-11 Impact factor: 8.168

3. A New DNA Break Repair Pathway Involving PARP3 and Base Excision Repair Proteins.

Authors: E A Belousova; M M Kutuzov; P A Ivankina; A A Ishchenko; O I Lavrik
Journal: Dokl Biochem Biophys Date: 2018-11-05 Impact factor: 0.788

4. Exploring molecular pathways of triple-negative breast cancer.

Authors: Valeria Ossovskaya; Yipeng Wang; Adam Budoff; Qiang Xu; Alexander Lituev; Olga Potapova; Gordon Vansant; Joseph Monforte; Nikolai Daraselia
Journal: Genes Cancer Date: 2011-09

Review 5. Functions of the poly(ADP-ribose) polymerase superfamily in plants.

Authors: Rebecca S Lamb; Matteo Citarelli; Sachin Teotia
Journal: Cell Mol Life Sci Date: 2011-08-23 Impact factor: 9.261

Review 6. NAD⁺ metabolism and its roles in cellular processes during ageing.

Authors: Anthony J Covarrubias; Rosalba Perrone; Alessia Grozio; Eric Verdin
Journal: Nat Rev Mol Cell Biol Date: 2020-12-22 Impact factor: 94.444

7. Nuclear transport of nicotinamide phosphoribosyltransferase is cell cycle-dependent in mammalian cells, and its inhibition slows cell growth.

Authors: Petr Svoboda; Edita Krizova; Sarka Sestakova; Kamila Vapenkova; Zdenek Knejzlik; Silvie Rimpelova; Diana Rayova; Nikol Volfova; Ivana Krizova; Michaela Rumlova; David Sykora; Rene Kizek; Martin Haluzik; Vaclav Zidek; Jarmila Zidkova; Vojtech Skop
Journal: J Biol Chem Date: 2019-04-11 Impact factor: 5.157

Poly(ADP-ribose) polymerase 3 (PARP3), a newcomer in cellular response to DNA damage and mitotic progression.

1. PARP-3 is a mono-ADP-ribosylase that activates PARP-1 in the absence of DNA.

2. A human poly(ADP-ribose) polymerase gene family (ADPRTL): cDNA cloning of two novel poly(ADP-ribose) polymerase homologues.

3. PARP-3 and APLF function together to accelerate nonhomologous end-joining.

4. The role of NuMA in the interphase nucleus.

5. PARP-3 localizes preferentially to the daughter centriole and interferes with the G1/S cell cycle progression.

6. Cloning and expression of PARP-3 (Adprt3) and U3-55k, two genes closely linked on mouse chromosome 9.

7. Cell cycle defects in polyhomeotic mutants are caused by abrogation of the DNA damage checkpoint.

Review 8. Toward a unified nomenclature for mammalian ADP-ribosyltransferases.

9. NuMA is required for proper spindle assembly and chromosome alignment in prometaphase.

10. Sister telomeres rendered dysfunctional by persistent cohesion are fused by NHEJ.

1. Spontaneous transformation of murine epithelial cells requires the early acquisition of specific chromosomal aneuploidies and genomic imbalances.

2. The potential for poly (ADP-ribose) polymerase inhibitors in cancer therapy.

3. A New DNA Break Repair Pathway Involving PARP3 and Base Excision Repair Proteins.

4. Exploring molecular pathways of triple-negative breast cancer.

Review 5. Functions of the poly(ADP-ribose) polymerase superfamily in plants.

Review 6. NAD⁺ metabolism and its roles in cellular processes during ageing.

7. Nuclear transport of nicotinamide phosphoribosyltransferase is cell cycle-dependent in mammalian cells, and its inhibition slows cell growth.

Review 8. DNA damage and tissue repair: What we can learn from planaria.

9. Poly(ADP-ribose) polymerase 1 promotes transcriptional repression of integrated retroviruses.

Review 10. Rucaparib: A Review in Ovarian Cancer.

Review 8. Toward a unified nomenclature for mammalian ADP-ribosyltransferases.

Review 5. Functions of the poly(ADP-ribose) polymerase superfamily in plants.

Review 6. NAD+ metabolism and its roles in cellular processes during ageing.

Review 8. DNA damage and tissue repair: What we can learn from planaria.

Review 10. Rucaparib: A Review in Ovarian Cancer.

Review 6. NAD⁺ metabolism and its roles in cellular processes during ageing.