DNA damage-induced acetylation of lysine 3016 of ATM activates ATM kinase activity

The ATM protein kinase is essential for cells to repair and survive genotoxic events. The activation of ATM's kinase activity involves acetylation of ATM by the Tip60 histone acetyltransferase. In this study, systematic mutagenesis of lysine residues was used to identify regulatory ATM acetylation sites. The results identify a single acetylation site at lysine 3016, which is located in the highly conserved C-terminal FATC domain adjacent to the kinase domain. Antibodies specific for acetyl-lysine 3016 demonstrate rapid (within 5 min) in vivo acetylation of ATM following exposure to bleomycin. Furthermore, lysine 3016 of ATM is a substrate in vitro for the Tip60 histone acetyltransferase. Mutation of lysine 3016 does not affect unstimulated ATM kinase activity but does abolish upregulation of ATM's kinase activity by DNA damage, inhibits the conversion of inactive ATM dimers to active ATM monomers, and prevents the ATM-dependent phosphorylation of the p53 and chk2 proteins. These results are consistent with a model in which acetylation of lysine 3016 in the FATC domain of ATM activates the kinase activity of ATM. The acetylation of ATM on lysine 3016 by Tip60 is therefore a key step linking the detection of DNA damage and the activation of ATM kinase activity.     

Tip60: Connecting chromatin to DNA damage signaling

Cells are constantly exposed to genotoxic events that can damage DNA. To counter this, cells have evolved a series of highly conserved DNA repair pathways to maintain genomic integrity. The ATM protein kinase is a master regulator of the DNA double-strand break (DSB) repair pathway. DSBs activate ATM’s kinase activity, promoting the phosphorylation of proteins involved in both checkpoint activation and DNA repair. Recent work has revealed that two DNA damage response proteins, the Tip60 acetyltransferase and the mre11-rad50-nbs1 (MRN) complex, co-operate in the activation of ATM in response to DSBs. MRN functions to target ATM and the Tip60 acetyltransferase to DSBs. Tip60’s chromodomain then interacts with histone H3 trimethylated on lysine 9, activating Tip60’s acetyltransferase activity and stimulating the subsequent acetylation and activation of ATM’s kinase activity. These results underscore the importance of chromatin structure in regulating DNA damage signaling and emphasize how histone modifications co-ordinate DNA repair. In addition, human tumors frequently exhibit altered patterns of histone methylation. This rewriting of the histone methylation code in tumor cells may impact the efficiency of DSB repair, increasing genomic instability and contributing to the initiation and progression of cancer.     

Three-dimensional structure and regulation of the DNA-dependent protein kinase catalytic subunit (DNA-PKcs)

DNA-PKcs is a large PI3-kinase-related protein kinase (PIKK) that plays a central role in DNA double-strand break (DSB) repair via nonhomologous end joining. Using cryo-electron microscopy we have now generated an approximately 13 A three-dimensional map of DNA-PKcs, revealing the overall architecture and topology of the 4128 residue polypeptide chain and allowing location of domains. The highly conserved C-terminal PIKK catalytic domain forms a central structure from which FAT and FATC domains protrude. Conformational changes observed in these domains on DNA binding suggest that they transduce DNA-induced conformational changes to the catalytic core and regulate kinase activity. The N-terminal segments form long curved tubular-shaped domains based on helical repeats to create interacting surfaces required for macromolecular assembly. Comparison of DNA-PKcs with another PIKK DNA repair factor, ATM, defines a common architecture for this important protein family.     

Emerging common themes in regulation of PIKKs and PI3Ks

Phosphatidylinositol‐3 kinase‐related kinases (PIKKs) comprise a family of protein kinases that respond to various stresses, including DNA damage, blocks in DNA replication, availability of nutrients and errors in mRNA splicing. PIKKs are characterized by the presence of a conserved kinase domain (KD), whose activity is regulated by two C‐terminal regions, referred to as PIKK‐regulatory domain (PRD) and FRAP‐ATM‐TRRAP‐C‐terminal (FATC), respectively. Here, we review functional and structural data that implicate the PRD and FATC domains in regulation of PIKK activity, drawing parallels to phosphatidylinositol‐3 kinases (PI3K), lipid kinases that have sequence similarity to PIKKs. The PI3K C‐terminus, which we propose to be equivalent to the PRD and FATC domains of PIKKs, is in close proximity to the activation loop of the KD, suggesting that in PIKKs, the PRD and FATC domains may regulate kinase activity by targeting the activation loop.     

Distant N- and C-terminal domains are required for intrinsic kinase activity of SMG-1, a critical component of nonsense-mediated mRNA decay

Phosphatidylinositol 3-kinase-related kinases (PIKKs) consisting of SMG-1, ATM, ATR, DNA-PKcs, and mTOR are a family of proteins involved in the surveillance of gene expression in eukaryotic cells. They are involved in mechanisms responsible for genome stability, mRNA quality, and translation. They share a large N-terminal domain and a C-terminal FATC domain in addition to the unique serine/threonine protein kinase (PIKK) domain that is different from classical protein kinases. However, structure-function relationships of PIKKs remain unclear. Here we have focused on one of the PIKK members, SMG-1, which is involved in RNA surveillance, termed nonsense-mediated mRNA decay (NMD), to analyze the roles of conserved and SMG-1-specific sequences on the intrinsic kinase activity. Analyses of sets of point and deletion mutants of SMG-1 in a purified system and intact cells revealed that the long N-terminal region and the conserved leucine in the FATC domain were essential for SMG-1 kinase activity. However, the conserved tryptophan in the TOR SMG-1 (TS) homology domain and the FATC domain was not. In addition, the long insertion region between PIKK and FATC domains was not essential for SMG-1 kinase activity. These results indicated an unexpected feature of SMG-1, i.e. that distantly located N- and C-terminal sequences were essential for the intrinsic kinase activity.     

Activation of ATR and related PIKKs

The DNA damage response kinase ATR is an essential regulator of genome integrity. TopBP1 functions as a general activator of ATR. We have recently shown that TopBP1 activates ATR through its regulatory subunit ATRIP and a PIKK regulatory domain (PRD) located adjacent to its kinase domain. This mechanism of ATR activation is conserved in the S. cerevisiae ortholog Mec1. ATR is a member of the PIKK family of protein kinases that includes ATM, DNA-PKcs, mTOR, and SMG1. The PRD regulates the kinase activity of other PIKKs and may serve as a site of interaction between these kinase and their respective activators. Activation of ATR by TopBP1 is maximal at low substrate concentrations and declines exponentially as substrate concentration increases. These data are consistent with a model in which TopBP1 acts to alter the conformation of ATR-ATRIP to increase the ability of ATR to bind substrates. A further understanding of the mechanism of ATR activation will likely provide insights into the regulation of related PIK kinases.     

NMR- and Circular Dichroism-monitored Lipid Binding Studies Suggest a General Role for the FATC Domain as Membrane Anchor of Phosphatidylinositol 3-Kinase-related Kinases (PIKK)

The FATC domain is shared by all members of the family of phosphatidylinositol-3 kinase-related kinases (PIKKs). It has been shown that the FATC domain plays an important role for the regulation of each PIKK. However, other than an involvement in protein-protein interactions, a common principle for the action of the FATC domain has not been detected. A detailed characterization of the structure and lipid binding properties of the FATC domain of the Ser/Thr kinase target of rapamycin (TOR) revealed that it contains a redox-sensitive membrane anchor in its C terminus. Because the C-terminal regions of the FATC domains of all known PIKKs are rather hydrophobic and especially rich in aromatic residues, we examined whether the ability to interact with lipids and membranes might be a general property. Here, we present the characterization of the interactions with lipids and different membrane mimetics for the FATC domains of human DNA-PKcs, human ATM, human ATR, human SMG-1, and human TRRAP by NMR and CD spectroscopy. The data indicate that all of these can interact with different membrane mimetics and may have different preferences only for membrane properties such as surface charge, curvature, and lipid packing. The oxidized form of the TOR FATC domain is well structured overall and forms an α-helix that is followed by a disulfide-bonded loop. In contrast, the FATC domains of the other PIKKs are rather unstructured in the isolated form and only significantly populate α-helical secondary structure upon interaction with membrane mimetics.     

The radioprotective agent WR1065 protects cells from radiation damage by regulating the activity of the Tip60 acetyltransferase

Background: The aminothiol WR1065 is a highly effective free radical scavenger which can protect cells from the cytotoxic effects of ionizing radiation. Currently, WR1065 is used clinically to protect patients from radiation injury occurring during radiation therapy protocols. However, it is becoming increasingly clear that WR1065 can alter radiosensitivity through a mechanism which is independent of its ability to function as a free radical scavenger. Here, we examined the ability of WR1065 to directly regulate signaling pathways involved in the DNA damage response. Methodology: The ability of WR1065 to enhance the survival of irradiated bone marrow cells and primary cultures was established. DNA damage signaling was monitored by measuring activation of the ATM kinase by western blot analysis and activation of Tip60 using an in vitro acetylation assay. Tip60 function was abrogated by expression of a catalytically inactive Tip60, and the effect on radiosensitivity evaluated. Principal findings: Treatment of cells with WR1065 led to a small but significant increase in the kinase activity of ATM. Further, WR1065 robustly activated the Tip60 acetyltransferase, which is a key upstream regulator of the ATM kinase. In addition, WR1065 directly activated the acetyltransferase activity of purified Tip60 in vitro, indicating a direct interaction between WR1065 and Tip60. Finally, cells with reduced levels of Tip60 activity exhibited a significant reduction in radioprotection by WR1065. Conclusions: Direct regulation of Tip60''s acetyltransferase activity by WR1065 makes a significant contribution to the radioprotective effects of WR1065. Activators of Tip60 may therefore make effective clinical radioprotectors.     

Chromatin perturbations during the DNA damage response in higher eukaryotes

The DNA damage response is a widely used term that encompasses all signaling initiated at DNA lesions and damaged replication forks as it extends to orchestrate DNA repair, cell cycle checkpoints, cell death and senescence. ATM, an apical DNA damage signaling kinase, is virtually instantaneously activated following the introduction of DNA double-strand breaks (DSBs). The MRE11-RAD50-NBS1 (MRN) complex, which has a catalytic role in DNA repair, and the KAT5 (Tip60) acetyltransferase are required for maximal ATM kinase activation in cells exposed to low doses of ionizing radiation. The sensing of DNA lesions occurs within a highly complex and heterogeneous chromatin environment. Chromatin decondensation and histone eviction at DSBs may be permissive for KAT5 binding to H3K9me3 and H3K36me3, ATM kinase acetylation and activation. Furthermore, chromatin perturbation may be a prerequisite for most DNA repair. Nucleosome disassembly during DNA repair was first reported in the 1970s by Smerdon and colleagues when nucleosome rearrangement was noted during the process of nucleotide excision repair of UV-induced DNA damage in human cells. Recently, the multi-functional protein nucleolin was identified as the relevant histone chaperone required for partial nucleosome disruption at DBSs, the recruitment of repair enzymes and for DNA repair. Notably, ATM kinase is activated by chromatin perturbations induced by a variety of treatments that do not directly cause DSBs, including treatment with histone deacetylase inhibitors. Central to the mechanisms that activate ATR, the second apical DNA damage signaling kinase, outside of a stalled and collapsed replication fork in S-phase, is chromatin decondensation and histone eviction associated with DNA end resection at DSBs. Thus, a stress that is common to both ATM and ATR kinase activation is chromatin perturbations, and we argue that chromatin perturbations are both sufficient and required for induction of the DNA damage response.     

ATM and KAT5 safeguard replicating chromatin against formaldehyde damage

Many carcinogens damage both DNA and protein constituents of chromatin, and it is unclear how cells respond to this compound injury. We examined activation of the main DNA damage-responsive kinase ATM and formation of DNA double-strand breaks (DSB) by formaldehyde (FA) that forms histone adducts and replication-blocking DNA-protein crosslinks (DPC). We found that low FA doses caused a strong and rapid activation of ATM signaling in human cells, which was ATR-independent and restricted to S-phase. High FA doses inactivated ATM via its covalent dimerization and formation of larger crosslinks. FA-induced ATM signaling showed higher CHK2 phosphorylation but much lower phospho-KAP1 relative to DSB inducers. Replication blockage by DPC did not produce damaged forks or detectable amounts of DSB during the main wave of ATM activation, which did not require MRE11. Chromatin-monitoring KAT5 (Tip60) acetyltransferase was responsible for acetylation and activation of ATM by FA. KAT5 and ATM were equally important for triggering of intra-S-phase checkpoint and ATM signaling promoted recovery of normal human cells after low-dose FA. Our results revealed a major role of the KAT5-ATM axis in protection of replicating chromatin against damage by the endogenous carcinogen FA.     

The histone chaperone ASF1 regulates the activation of ATM and DNA-PKcs in response to DNA double-strand breaks

The Ataxia-telangiectasia mutated (ATM) kinase and the DNA-dependent protein kinase catalytic subunit (DNA-PKcs) are activated by DNA double-strand breaks (DSBs). These DSBs occur in the context of chromatin but how chromatin influences the activation of these kinases is not known. Here we show that loss of the replication-dependent chromatin assembly factors ASF1A/B or CAF-1 compromises ATM activation, while augmenting DNA-PKcs activation, in response to DNA DSBs. Cells deficient in ASF1A/B or CAF-1 exhibit reduced histone H4 lysine 16 acetylation (H4K16ac), a histone mark known to promote ATM activation. ASF1A interacts with the histone acetyl transferase, hMOF that mediates H4K16ac. ASF1A depletion leads to increased recruitment of DNA-PKcs to DSBs. We propose normal chromatin assembly and H4K16ac during DNA replication is required to regulate ATM and DNA-PKcs activity in response to the subsequent induction of DNA DSBs.     

Requirement of the FATC domain of protein kinase Tel1 for localization to DNA ends and target protein recognition

Two large phosphatidylinositol 3-kinase–related protein kinases (PIKKs), ATM and ATR, play a central role in the DNA damage response pathway. PIKKs contain a highly conserved extreme C-terminus called the FRAP-ATM-TRRAP-C-terminal (FATC) domain. In budding yeast, ATM and ATR correspond to Tel1 and Mec1, respectively. In this study, we characterized functions of the FATC domain of Tel1 by introducing substitution or truncation mutations. One substitution mutation, termed tel1-21, and a truncation mutation, called tel1-ΔC, did not significantly affect the expression level. The tel1-21 mutation impaired the cellular response to DNA damage and conferred moderate telomere maintenance defect. In contrast, the tel1-ΔC mutation behaved like a null mutation, conferring defects in both DNA damage response and telomere maintenance. Tel1-21 protein localized to DNA ends as effectively as wild-type Tel1 protein, whereas Tel1-ΔC protein failed. Introduction of a hyperactive TEL1-hy mutation suppressed the tel1-21 mutation but not the tel1-ΔC mutation. In vitro analyses revealed that both Tel1-21 and Tel1-ΔC proteins undergo efficient autophosphorylation but exhibit decreased kinase activities toward the exogenous substrate protein, Rad53. Our results show that the FATC domain of Tel1 mediates localization to DNA ends and contributes to phosphorylation of target proteins.     

Common mechanisms of PIKK regulation

Kinases in the phosphoinositide three-kinase-related kinase (PIKK) family include ATM (ataxia-telangiectasia mutated), ATR (ATM- and Rad3-related), DNA-PKcs (DNA-dependent protein kinase catalytic subunit), mTOR (mammalian target of rapamycin), and SMG1 (suppressor with morphological effect on genitalia family member). These atypical protein kinases regulate DNA damage responses, nutrient-dependent signaling, and nonsense-mediated mRNA decay. This review focuses on the mechanisms regulating the PIKK family with a strong emphasis on the DNA damage regulated kinases. We outline common regulatory themes and suggest how discoveries about the regulation of one PIKK can be informative for the other family members.     

The VRK1 chromatin kinase regulates the acetyltransferase activity of Tip60/KAT5 by sequential phosphorylations in response to DNA damage

The regulation of histone epigenetic modifications mediates the adaptation of chromatin to different biological processes. DNA damage causes a local relaxation of chromatin associated to histone H4 acetylation in K16, mediated by Tip60/KAT5. In this work, we have studied the role that the VRK1 chromatin kinase plays on the activation of Tip60 during this process. In the DNA damage response induced by doxorubicin, VRK1 directly phosphorylates Tip60. However, the phosphorylated Tip60 residues and their functional roles are unknown. In DDR, we have identified these two Tip60 phosphorylated residues and the cooperation of the participating kinases. The T158 phosphorylation, mediated by VRK1, is early and transient, preceding that of S199, which is more sustained in time, and mediated by DNA-PK. The role of each phosphorylated residues was determined by using phosphomimetic and phosphonull mutants and their combination. T158 phosphorylation protects Tip60 from ubiquitin-mediated degradation, promotes its recruitment to chromatin from the nucleoplasm, and is necessary for its full trans-acetylase activity. The phosphorylation in S199 by DNA-PK directly facilitates Tip60 autoacetylation, but it is not enough for trans-acetylation of two of its targets, histone H4 and ATM, which requires a double phosphorylation of Tip60 in T158 and S199. DNA-PK inhibitors block the phosphorylation of S199. We propose a model in which the cooperation between VRK1 and DNA-PK mediates the sequential phosphorylation of Tip60/KAT5, and contributes to the recruitment of this protein to initiate the sequential remodeling of chromatin in DDR. Both proteins are candidates for novel synthetic lethality strategies in cancer treatment.     

乙酰基转移酶Tip60(KAT5)的功能研究进展

Tip60(KAT5)属于MYST乙酰基转移酶家族,同时它也是进化上非常保守的Nu A4蛋白质复合体的重要成员.过去十几年的研究证实,Tip60一方面可以作为转录调控因子结合核受体(如雄激素受体,AR)或c-MYC、AICD/Fe65、NCo R、E2F等转录因子来激活或抑制下游基因的表达,另一方面,KAT5可以乙酰化一系列蛋白来调控这些蛋白质的活性及稳定性,进而调控DNA损伤修复反应、细胞周期进程、细胞周期检查点的激活、凋亡、代谢及自噬等重要细胞功能.此外,Tip60在肿瘤的发生发展及转移、胚胎发育等过程中也发挥着至关重要的作用.本文将主要对Tip60近几年的研究进展做一个综述.