BACKGROUND: Unscheduled expression of critical cellular regulators could be central to malignant genome reprogramming and tumor establishment. One such factor appears to be ATAD2, a remarkably conserved protein normally predominantly expressed in germ cells but almost systematically over-expressed in a variety of unrelated cancers. The presence of a bromodomain adjacent to an AAA type ATPase domain, points to ATAD2 as a factor preliminarily acting on chromatin structure and function. Accordingly, ATAD2 has been shown to cooperate with a series of transcription factors and chromatin modifiers to regulate specific set of genes. SCOPE OF REVIEW: Here we discuss our knowledge on ATAD2 to evaluate its role as a cancer driver and its value as a new anti-cancer target. MAJOR CONCLUSIONS: Upon its activation, ATAD2 through its interaction with defined transcription factors, initiates a loop of transcriptional stimulation of target genes, including ATAD2 itself, leading to enhanced cell proliferation and resistance to apoptosis in an ATAD2-dependent manner. Approaches aiming at neutralizing ATAD2 activity in cancer, including the use of small molecule inhibitors of its two "druggable" domains, AAA ATPase and bromodomain, could become part of a promising anti-cancer strategy.
BACKGROUND: Unscheduled expression of critical cellular regulators could be central to malignant genome reprogramming and tumor establishment. One such factor appears to be ATAD2, a remarkably conserved protein normally predominantly expressed in germ cells but almost systematically over-expressed in a variety of unrelated cancers. The presence of a bromodomain adjacent to an AAA type ATPase domain, points to ATAD2 as a factor preliminarily acting on chromatin structure and function. Accordingly, ATAD2 has been shown to cooperate with a series of transcription factors and chromatin modifiers to regulate specific set of genes. SCOPE OF REVIEW: Here we discuss our knowledge on ATAD2 to evaluate its role as a cancer driver and its value as a new anti-cancer target. MAJOR CONCLUSIONS: Upon its activation, ATAD2 through its interaction with defined transcription factors, initiates a loop of transcriptional stimulation of target genes, including ATAD2 itself, leading to enhanced cell proliferation and resistance to apoptosis in an ATAD2-dependent manner. Approaches aiming at neutralizing ATAD2 activity in cancer, including the use of small molecule inhibitors of its two "druggable" domains, AAA ATPase and bromodomain, could become part of a promising anti-cancer strategy.
Authors: Pavlo Lazarchuk; John Hernandez-Villanueva; Maria N Pavlova; Alexander Federation; Michael MacCoss; Julia M Sidorova Journal: Mol Cell Biol Date: 2020-04-13 Impact factor: 4.272
Authors: Andrew D Klocko; Miki Uesaka; Tereza Ormsby; Michael R Rountree; Elizabeth T Wiles; Keyur K Adhvaryu; Shinji Honda; Eric U Selker Journal: Genetics Date: 2018-12-15 Impact factor: 4.562
Authors: Mulu Y Lubula; Brian E Eckenroth; Samuel Carlson; Amanda Poplawski; Maksymilian Chruszcz; Karen C Glass Journal: FEBS Lett Date: 2014-09-30 Impact factor: 4.124
Authors: Paul Bamborough; Chun-Wa Chung; Emmanuel H Demont; Rebecca C Furze; Andrew J Bannister; Ka Hing Che; Hawa Diallo; Clement Douault; Paola Grandi; Tony Kouzarides; Anne-Marie Michon; Darren J Mitchell; Rab K Prinjha; Christina Rau; Samuel Robson; Robert J Sheppard; Richard Upton; Robert J Watson Journal: Angew Chem Int Ed Engl Date: 2016-08-17 Impact factor: 15.336