Brietta L. Pike

FHA domains as phospho-threonine binding modules in cell signaling.

Forkhead‐associated (FHA) domains are present in <200 diverse proteins in all phyla from bacteria to mammals and seem to be particularly prevalent in proteins with cell cycle control functions. Recent work from several laboratories has considerably improved our understanding of the structure and function of these domains that were virtually unknown a few years ago, and the first disease associations of FHA domains have now emerged. FHA domains form 11‐stranded beta‐sandwiches that contain some 100‐180 amino acid residues with a high degree of sequence diversity. FHA domains act as phosphorylation‐dependent protein‐protein interaction modules that preferentially bind to phospho‐threonine residues in their targets. Interestingly, point mutations in the human CHK2 gene that lead to single‐residue amino acid substitutions in the FHA domain of this cell cycle checkpoint kinase have been found to cause a subset of cases of the Li‐Fraumeni multi‐cancer syndrome. IUBMB Life, 55: 23‐27, 2003

Mdt1, a novel Rad53 FHA1 domain-interacting protein, modulates DNA damage tolerance and G(2)/M cell cycle progression in Saccharomyces cerevisiae.

ABSTRACT The Rad53 kinase plays a central role in yeast DNA damage checkpoints. Rad53 contains two FHA phosphothreonine-binding domains that are required for Rad53 activation and possibly downstream signaling. Here we show that the N-terminal Rad53 FHA1 domain interacts with the RNA recognition motif, coiled-coil, and SQ/TQ cluster domain-containing protein Mdt1 (YBl051C). The interaction of Rad53 and Mdt1 depends on the structural integrity of the FHA1 phosphothreonine-binding site as well as threonine-305 of Mdt1. Mdt1 is constitutively threonine phosphorylated and hyperphosphorylated in response to DNA damage in vivo. DNA damage-dependent Mdt1 hyperphosphorylation depends on the Mec1 and Tel1 checkpoint kinases, and Mec1 can directly phosphorylate a recombinant Mdt1 SQ/TQ domain fragment. MDT1 overexpression is synthetically lethal with a rad53 deletion, whereas mdt1 deletion partially suppresses the DNA damage hypersensitivity of checkpoint-compromised strains and generally improves DNA damage tolerance. In the absence of DNA damage, mdt1 deletion leads to delayed anaphase completion, with an elongated cell morphology reminiscent of that of G2/M cell cycle mutants. mdt1-dependent and DNA damage-dependent cell cycle delays are not additive, suggesting that they act in the same pathway. The data indicate that Mdt1 is involved in normal G2/M cell cycle progression and is a novel target of checkpoint-dependent cell cycle arrest pathways.

FHA domain boundaries of the Dun1p and Rad53p cell cycle checkpoint kinases

Dun1p and Rad53p of the budding yeast Saccharomyces cerevisiae are members of a conserved family of cell cycle checkpoint protein kinases that contain forkhead‐associated (FHA) domains. Here, we demonstrate that these FHA domains contain 130–140 residues, and are thus considerably larger than previously predicted by sequence comparisons (55–75 residues). In vivo, expression of the proteolytically defined Dun1p FHA domain, but not a fragment containing only the predicted domain boundaries, inhibited the transcriptional induction of repair genes following replication blocks. This indicates that the non‐catalytic FHA domain plays an important role in the transcriptional function of the Dun1p protein kinase.

Role of the N-terminal Forkhead-associated Domain in the Cell Cycle Checkpoint Function of the Rad53 Kinase ,

Forkhead-associated (FHA) domains are multifunctional phosphopeptide-binding modules and are the hallmark of the conserved family of Rad53-like checkpoint protein kinases. Rad53-like kinases, including the human tumor suppressor protein Chk2, play crucial roles in cell cycle arrest and activation of repair processes following DNA damage and replication blocks. Here we show that ectopic expression of the N-terminal FHA domain (FHA1) of the yeast Rad53 kinase causes a growth defect by arresting the cell cycle in G1. This phenotype was highly specific for the Rad53-FHA1 domain and not observed with the similar Rad53-FHA2, Dun1-FHA, and Chk2-FHA domains, and it was abrogated by mutations that abolished binding to a phosphothreonine-containing peptide in vitro. Furthermore, replacement of the RAD53 gene with alleles containing amino acid substitutions in the FHA1 domain resulted in an increased DNA damage sensitivity in vivo. Taken together, these data demonstrate that the FHA1 domain contributes to the checkpoint function of Rad53, possibly by associating with a phosphorylated target protein in response to DNA damage in G1.

Mdt1 facilitates efficient repair of blocked DNA double-strand breaks and recombinational maintenance of telomeres.

ABSTRACT DNA recombination plays critical roles in DNA repair and alternative telomere maintenance. Here we show that absence of the SQ/TQ cluster domain-containing protein Mdt1 (Ybl051c) renders Saccharomyces cerevisiae particularly hypersensitive to bleomycin, a drug that causes 3′-phospho-glycolate-blocked DNA double-strand breaks (DSBs). mdt1Δ also hypersensitizes partially recombination-defective cells to camptothecin-induced 3′-phospho-tyrosyl protein-blocked DSBs. Remarkably, whereas mdt1Δ cells are unable to restore broken chromosomes after bleomycin treatment, they efficiently repair “clean” endonuclease-generated DSBs. Epistasis analyses indicate that MDT1 acts in the repair of bleomycin-induced DSBs by regulating the efficiency of the homologous recombination pathway as well as telomere-related functions of the KU complex. Moreover, mdt1Δ leads to severe synthetic growth defects with a deletion of the recombination facilitator and telomere-positioning factor gene CTF18 already in the absence of exogenous DNA damage. Importantly, mdt1Δ causes a dramatic shift from the usually prevalent type II to the less-efficient type I pathway of recombinational telomere maintenance in the absence of telomerase in liquid senescence assays. As telomeres resemble protein-blocked DSBs, the results indicate that Mdt1 acts in a novel blocked-end-specific recombination pathway that is required for the efficiency of both drug-induced DSB repair and telomerase-independent telomere maintenance.

Location-specific functions of the two forkhead-associated domains in Rad53 checkpoint kinase signaling.

Signaling proteins often contain multiple modular protein-protein interaction domains of the same type. The Saccharomyces cerevisiae checkpoint kinase Rad53 contains two phosphothreonine-binding forkhead-associated (FHA) domains. To investigate if the precise position of these domains relative to each other is important, we created three rad53 alleles in which FHA1 and FHA2 domains were individually or simultaneously transposed to the opposite location. All three mutants were approximately 100-fold hypersensitive to DNA lesions whose survival requires intact Rad53 FHA domain functions, but they were not hypersensitive to DNA damage that is addressed in an FHA domain-independent manner. FHA domain-transposed Rad53 could still be recruited for activation by upstream kinases but then failed to autophosphorylate and activate FHA domain-dependent downstream functions. The results indicate that precise FHA domain positions are important for their roles in Rad53, possibly via regulation of the topology of oligomeric Rad53 signaling complexes.

Dual functions of Mdt1 in genome maintenance and cell integrity pathways in Saccharomyces cerevisiae

Recent evidence indicates considerable cross‐talk between genome maintenance and cell integrity control pathways. The RNA recognition motif (RRM)‐ and SQ/TQ cluster domain (SCD)‐containing protein Mdt1 is required for repair of 3′‐blocked DNA double‐strand breaks (DSBs) and efficient recombinational maintenance of telomeres in budding yeast. Here we show that deletion of MDT1 (PIN4/YBL051C) leads to severe synthetic sickness in the absence of the genes for the central cell integrity MAP kinases Bck1 and Slt2/Mpk1. Consistent with a cell integrity function, mdt1Δ cells are hypersensitive to the cell wall toxin calcofluor white and the Bck1–Slt2 pathway activator caffeine. An RRM‐deficient mdt1‐RRM0 allele shares the severe bleomycin hypersensitivity, inefficient recombinational telomere maintenance and slt2 synthetic sickness phenotypes, but not the cell wall toxin hypersensitivity with mdt1Δ. However, the mdt1‐RRM(3A) allele, where only the RNA‐binding site is mutated, behaves similarly to the wild‐type, suggesting that the Mdt1 RRM functions as a protein–protein interaction rather than a nucleic acid‐binding module. Surprisingly, in a strain background where double mutants are sick but still viable, bck1Δmdt1Δ and slt2Δmdt1Δ mutants differ in some of their phenotypes, consistent with the emerging concept of flexible signal entry and exit points in the Bck1–Mkk1/2–Slt2 pathway. Overall, the results indicate that Mdt1 has partially separable functions in both cell wall and genome integrity pathways. Copyright

Crystallization and preliminary X-ray diffraction studies of FHA domains of Dun1 and Rad53 protein kinases

Forkhead-associated (FHA) domains are modular protein-protein interaction domains of approximately 130 amino acids present in numerous signalling proteins. FHA-domain-dependent protein interactions are regulated by phosphorylation of target proteins and FHA domains may be multifunctional phosphopeptide-recognition modules. FHA domains of the budding yeast cell-cycle checkpoint protein kinases Dun1p and Rad53p have been crystallized. Crystals of the Dun1-FHA domain exhibit the symmetry of the space group P6(1)22 or P6(5)22, with unit-cell parameters a = b = 127.3, c = 386.3 A; diffraction data have been collected to 3.1 A resolution on a synchrotron source. Crystals of the N-terminal FHA domain (FHA1) of Rad53p diffract to 4.0 A resolution on a laboratory X-ray source and have Laue-group symmetry 4/mmm, with unit-cell parameters a = b = 61.7, c = 104.3 A.