Use of Quantitative Mass Spectrometric Analysis to Elucidate the Mechanisms of Phospho-priming and Auto-activation of the Checkpoint Kinase Rad53 in Vivo

The cell cycle checkpoint kinases play central roles in the genome maintenance of eukaryotes. Activation of the yeast checkpoint kinase Rad53 involves Rad9 or Mrc1 adaptor-mediated phospho-priming by Mec1 kinase, followed by auto-activating phosphorylation within its activation loop. However, the mechanisms by which these adaptors regulate priming phosphorylation of specific sites and how this then leads to Rad53 activation remain poorly understood. Here we used quantitative mass spectrometry to delineate the stepwise phosphorylation events in the activation of endogenous Rad53 in response to S phase alkylation DNA damage, and we show that the two Rad9 and Mrc1 adaptors, the four N-terminal Mec1-target TQ sites of Rad53 (Rad53-SCD1), and Rad53-FHA2 coordinate intimately for optimal priming phosphorylation to support substantial Rad53 auto-activation. Rad9 or Mrc1 alone can mediate surprisingly similar Mec1 target site phosphorylation patterns of Rad53, including previously undetected tri- and tetraphosphorylation of Rad53-SCD1. Reducing the number of TQ motifs turns the SCD1 into a proportionally poorer Mec1 target, which then requires the presence of both Mrc1 and Rad9 for sufficient priming and auto-activation. The phosphothreonine-interacting Rad53-FHA domains, particularly FHA2, regulate phospho-priming by interacting with the checkpoint mediators but do not seem to play a major role in the phospho-SCD1-dependent auto-activation step. Finally, mutation of all four SCD1 TQ motifs greatly reduces Rad53 activation but does not eliminate it, and residual Rad53 activity in this mutant is dependent on Rad9 but not Mrc1. Altogether, our results provide a paradigm for how phosphorylation site clusters and checkpoint mediators can be involved in the regulation of signaling relay in protein kinase cascades in vivo and elucidate an SCD1-independent Rad53 auto-activation mechanism through the Rad9 pathway. The work also demonstrates the power of mass spectrometry for in-depth analyses of molecular mechanisms in cellular signaling in vivo.Eukaryotic cells are most vulnerable to exogenous DNA-damaging agents during the S phase of the cell cycle, when unprogrammed DNA lesions interfere with the tightly choreographed DNA replication process. DNA damage during this phase leads to the activation of two overlapping checkpoint pathways in Saccharomyces cerevisiae, the DNA replication checkpoint and the intra-S-phase DNA damage checkpoint (1, 2). Phospho-priming for auto-activation of the central checkpoint kinase Rad53 by the upstream kinase Mec1/Tel1 depends on Mrc1 as an adaptor in the DNA replication checkpoint pathway and Rad9 as an adaptor in the DNA damage checkpoint pathway (3–10). Rad53, a well-accepted model system for studying the function and regulation of Chk2-like kinases, contains two forkhead-associated (FHA)¹ domains (FHA1 and -2) and two SQ/TQ cluster domains (SCD1 and -2) enriched in Mec1/Tel1-target phosphorylation sites (11–13).Mrc1 normally is a replisome component that functionally couples DNA Pol ε with Cdc45 and MCM helicase during replication fork progression (14, 15). As the replication forks are stalled by replication stress, the recruited checkpoint sensor kinase Mec1 phosphorylates the SCD of Mrc1, which abolishes its N-terminal interaction with Pol ε and enables Mrc1 to recruit Rad53 and promote Rad53 phosphorylation by Mec1 as an initial step in the activation of Rad53 in the Mrc1 branch (6, 14, 16). Alanine substitution of all Mec1 target sites of Mrc1 (designated the mrc1-AQ allele) has been shown to selectively disable its checkpoint function for Rad53 activation without affecting its DNA replication functions (4). In response to DNA damage, Rad9 is able to associate with damaged chromatin via its BRCT and Tudor domains, which tether it to Ser129-phosphorylated histone H2A (γH2A) and Lys79-methylated histone H3, respectively (17, 18). Alternatively, the recruitment of Rad9 onto damaged DNA could also be facilitated by its phosphorylation by CDK1, which enables the specific interaction of Rad9 with Dpb11, allowing the formation of the ternary complex of Dpb11, Mec1, and Rad9 (19, 20). Similar to Mrc1, Mec1 activates the adaptor function of Rad9 by phosphorylation of its SCD, which then binds to the Rad53-FHA domains to promote Rad53 phosphorylation by Mec1 (3, 5, 10).Beyond serving as scaffolds to recruit Rad53, Mrc1 and Rad9 have been shown to promote Rad53 phosphorylation by Mec1 in a dose-dependent manner in vitro (3, 16), underlining their adaptor role to enhance the enzyme–substrate (Mec1–Rad53) interaction. However, how they can specifically regulate the priming phosphorylation at specific sites and how this then leads to Rad53 activation remains poorly understood. Finally, hyperphosphorylated Rad9 has also been shown to catalyze the auto-phosphorylation of recombinant Rad53 (21), but it remains to be examined whether and how this occurs in vivo.The activation of SCD-FHA containing kinases such as human Chk2 and fission yeast Cds1 has been suggested to involve a two-step phosphorylation process: first, SCD phosphorylation by an ATM/ATR-like kinase leads to intermolecular binding to the FHA domain of another Chk2/Cds1 monomer, which then results in dimerization/oligomerization-dependent auto-phosphorylation within the kinase activation loop (22–26). In addition to the characteristic N-terminal SCD-FHA module of Chk2-like kinases, Rad53 contains another SCD2-FHA2 module C-terminal to its kinase domain. Similar to its orthologues, Rad53 activation has been proposed to depend on SCD1 phosphorylation (but not SCD2 phosphorylation) and partially redundant functions of the two FHA domains (9, 27–29). However, although Rad53-FHA1 can interact with SCD1 in a phospho-threonine (pT)-dependent manner in vitro (9, 28), it appears to be required for Rad53 activation only in G2/M-arrested cells (27, 29). In contrast, the FHA2 domain, which seems to be more important overall for Rad53 activation, does not appreciably bind phospho-SCD1 peptides in vitro (27, 28). Thus, the mechanisms by which Mrc1, Rad9, SCD1 phosphorylation, and FHA domains interact during checkpoint-dependent Rad53 priming and auto-activation remain to be elucidated.Quantitative mass spectrometric analysis has revolutionized the functional analysis of cellular signaling pathways, including site-specific phosphorylation events of key signaling molecules (30–33), but an important caveat is that MS studies often involve protein tags or nonphysiological expression levels that can interfere with normal protein functions. For example, the integration of a triple HA tag into the endogenous RAD53 gene locus has been shown to reduce Rad53 protein levels, resulting in significantly altered checkpoint activity (34). In this study we used quantitative MS analyses to dissect the stepwise phosphorylation events of endogenous, untagged Rad53 in response to MMS-induced alkylation DNA damage and replication stress during the S phase. Together with functional analyses, our results delineate how the two Mec1 adaptors Rad9 and Mrc1 can coordinate with the four SCD1 priming sites (T5, T8, T12, and T15) to regulate the phospho-priming of Rad53 by Mec1. In addition, an SCD1-priming independent Rad53 auto-activation mechanism and the specific roles of the FHA domains during Rad53 hyperphosphorylation are also elucidated in this work.