EMD-10233
Complete CtTel1 dimer with C2 symmetry
EMD-10233
Single-particle3.7 Å
Deposition: 16/08/2019Map released: 30/10/2019
Last modified: 23/10/2024
Sample Organism:
Chaetomium thermophilum (strain DSM 1495 / CBS 144.50 / IMI 039719)
Sample: CtTel1
Fitted models: 6sl0 (Avg. Q-score: 0.437)
Deposition Authors: Jansma M, Eustermann SE
Sample: CtTel1
Fitted models: 6sl0 (Avg. Q-score: 0.437)
Deposition Authors: Jansma M, Eustermann SE
Near-Complete Structure and Model of Tel1ATM from Chaetomium thermophilum Reveals a Robust Autoinhibited ATP State.
Jansma M,
Linke-Winnebeck C 
,
Eustermann S,
Lammens K,
Kostrewa D,
Stakyte K,
Litz C ,
Kessler B,
Hopfner KP
(2020) Structure , 28 , 83 - 95.e5
,
Eustermann S,
Lammens K,
Kostrewa D,
Stakyte K,
Litz C ,
Kessler B,
Hopfner KP
(2020) Structure , 28 , 83 - 95.e5
Abstract:
Tel1 (ATM in humans) is a large kinase that resides in the cell in an autoinhibited dimeric state and upon activation orchestrates the cellular response to DNA damage. We report the structure of an endogenous Tel1 dimer from Chaetomium thermophilum. Major parts are at 2.8 Å resolution, including the kinase active site with ATPγS bound, and two different N-terminal solenoid conformations are at 3.4 Å and 3.6 Å, providing a side-chain model for 90% of the Tel1 polypeptide. We show that the N-terminal solenoid has DNA binding activity, but that its movements are not coupled to kinase activation. Although ATPγS and catalytic residues are poised for catalysis, the kinase resides in an autoinhibited state. The PIKK regulatory domain acts as a pseudo-substrate, blocking direct access to the site of catalysis. The structure allows mapping of human cancer mutations and defines mechanisms of autoinhibition at near-atomic resolution.
Tel1 (ATM in humans) is a large kinase that resides in the cell in an autoinhibited dimeric state and upon activation orchestrates the cellular response to DNA damage. We report the structure of an endogenous Tel1 dimer from Chaetomium thermophilum. Major parts are at 2.8 Å resolution, including the kinase active site with ATPγS bound, and two different N-terminal solenoid conformations are at 3.4 Å and 3.6 Å, providing a side-chain model for 90% of the Tel1 polypeptide. We show that the N-terminal solenoid has DNA binding activity, but that its movements are not coupled to kinase activation. Although ATPγS and catalytic residues are poised for catalysis, the kinase resides in an autoinhibited state. The PIKK regulatory domain acts as a pseudo-substrate, blocking direct access to the site of catalysis. The structure allows mapping of human cancer mutations and defines mechanisms of autoinhibition at near-atomic resolution.