Protein kinase activity of Tel1p and Mec1p, two Saccharomyces cerevisiae proteins related to the human ATM protein kinase

Elevated dNTP levels suppress hyper-recombination in Saccharomyces cerevisiae S-phase checkpoint mutants

MEC1, the essential yeast homolog of the human ATR/ATM genes, controls the S-phase checkpoint and prevents replication fork collapse at slow zones of DNA replication. The viability of hypomorphic mec1-21 is reduced in the rad52 mutant, defective in homologous recombination, suggesting that replication generates recombinogenic lesions. We previously observed a 6-, 10- and 30-fold higher rate of spontaneous sister chromatid exchange (SCE), heteroallelic recombination and translocations, respectively, in mec1-21 mutants compared to wild-type. Here we report that the hyper-recombination phenotype correlates with lower deoxyribonucleoside triphosphate (dNTP) levels, compared to wild-type. By introducing a dun1 mutation, thus eliminating inducible expression of ribonucleotide reductase in mec1-21, rates of spontaneous SCE increased 15-fold above wild-type. All the hyper-recombination phenotypes were reduced by SML1 deletions, which increase dNTP levels. Measurements of dNTP pools indicated that, compared to wild-type, there was a significant decrease in dNTP levels in mec1-21, dun1 and mec1-21 dun1, while the dNTP levels of mec1-21 sml1, mec1-21 dun1 sml1 and sml1 mutants were approximately 2-fold higher. Interestingly, higher dNTP levels in mec1-21 dun1 sml1 correlate with approximately 2-fold higher rate of spontaneous mutagenesis, compared to mec1-21 dun1. We suggest that higher dNTP levels in specific checkpoint mutants suppress the formation of recombinogenic lesions.

Inositol pyrophosphates modulate hydrogen peroxide signalling

Inositol pyrophosphates are involved in a variety of cellular functions, but the specific pathways and/or downstream targets remain poorly characterized. In the present study we use Saccharomyces cerevisiae mutants to examine the potential roles of inositol pyrophosphates in responding to cell damage caused by ROS (reactive oxygen species). Yeast lacking kcs1 [the S. cerevisiae IP6K (inositol hexakisphosphate kinase)] have greatly reduced IP7 (diphosphoinositol pentakisphosphate) and IP8 (bisdiphosphoinositol tetrakisphosphate) levels, and display increased resistance to cell death caused by H2O2, consistent with a sustained activation of DNA repair mechanisms controlled by the Rad53 pathway. Other Rad53-controlled functions, such as actin polymerization, appear unaffected by inositol pyrophosphates. Yeast lacking vip1 [the S. cerevisiae PP-IP5K (also known as IP7K, IP7 kinase)] accumulate large amounts of the inositol pyrophosphate IP7, but have no detectable IP8, indicating that this enzyme represents the physiological IP7 kinase. Similar to kcs1Delta yeast, vip1Delta cells showed an increased resistance to cell death caused by H2O2, indicating that it is probably the double-pyrophosphorylated form of IP8 [(PP)2-IP4] which mediates the H2O2 response. However, these inositol pyrophosphates are not involved in directly sensing DNA damage, as kcs1Delta cells are more responsive to DNA damage caused by phleomycin. We observe in vivo a rapid decrease in cellular inositol pyrophosphate levels following exposure to H2O2, and an inhibitory effect of H2O2 on the enzymatic activity of Kcs1 in vitro. Furthermore, parallel cysteine mutagenesis studies performed on mammalian IP6K1 are suggestive that the ROS signal might be transduced by the direct modification of this evolutionarily conserved class of enzymes.

A two-step model for senescence triggered by a single critically short telomere

Telomeres protect chromosome ends from fusion and degradation. In the absence of a specific telomere elongation mechanism, their DNA shortens progressively with every round of replication, leading to replicative senescence. Here, we show that telomerase-deficient cells bearing a single, very short telomere senesce earlier, demonstrating that the length of the shortest telomere is a major determinant of the onset of senescence. We further show that Mec1p-ATR specifically recognizes the single, very short telomere causing the accelerated senescence. Strikingly, before entering senescence, cells divide for several generations despite complete erosion of their shortened telomeres. This pre-senescence growth requires RAD52 (radiation sensitive) and MMS1 (methyl methane sulfonate sensitive), and there is no evidence for major inter-telomeric recombination. We propose that, in the absence of telomerase, a very short telomere is first maintained in a pre-signalling state by a RAD52-MMS1-dependent pathway and then switches to a signalling state leading to senescence through a Mec1p-dependent checkpoint.

Kinase-independent functions of TEL1 in telomere maintenance

TEL1 is important in Saccharomyces cerevisiae telomere maintenance, and its kinase activity is required. Tel1p associates with telomeres in vivo, is enriched at short telomeres, and enhances the binding of telomerase components to short telomeres. However, it is unclear how the kinase activity and telomere association contribute to Tel1p's overall function in telomere length maintenance. To investigate this question, we generated a set of single point mutants and a double point mutant (tel1(KD)) of Tel1p that were kinase deficient and two Xrs2p mutants that failed to bind Tel1p. Using these separation-of-function alleles in a de novo telomere elongation assay, we found, surprisingly, that the tel1(KD) allele and xrs2 C-terminal mutants were both partially functional. Combining the tel1(KD) and xrs2 C-terminal mutants had an additive effect and resembled the TEL1 null (tel1Delta) phenotype. These data indicate that Tel1p has two separate functions in telomere maintenance and that the Xrs2p-dependent recruitment of Tel1p to telomeres plays an important role even in the absence of its kinase activity.

Rif1 and rif2 inhibit localization of tel1 to DNA ends

Chromosome ends, known as telomeres, have to be distinguished from DNA double-strand breaks (DSBs) that activate the DNA-damage checkpoint. In budding yeast, the ATM homolog Tel1 associates preferentially with short telomeres and promotes telomere addition. Here, we show that the telomeric proteins Rif1 and Rif2 attenuate Tel1 recruitment to DNA ends through distinct mechanisms. Both Rif1 and Rif2 inhibit the localization of Tel1, but not the Mre11-Rad50-Xrs2 (MRX) complex, to adjacent DNA ends. Rif1 function is weaker at short telomeric repeats compared with Rif2 function and is partly dependent on Rif2. Rif2 competes with Tel1 for binding to the C terminus of Xrs2. Once Tel1 is delocalized, MRX does not associate efficiently with Rap1-covered DNA ends. These results reveal a mechanism by which telomeric DNA sequences mask DNA ends from Tel1 recognition for the regulation of telomere length.

UV but not X rays stimulate homologous recombination between sister chromatids and homologs in a Saccharomyces cerevisiae mec1 (ATR) hypomorphic mutant

MEC1, the essential yeast ATM/ATR homolog, prevents replication fork collapse and is required for the cellular response to DNA damage. We had previously observed higher rates of spontaneous SCE, heteroallelic recombination and translocations in mec1-21 mutants, which still retain some G2 checkpoint function, compared to mec1 null mutants, which are completely defective in checkpoint function, and wild type. However, the types of DNA lesions that are more recombinogenic in mec1-21, compared to wild type, are unknown. Here, we measured DNA damage-associated SCE, homolog (heteroallelic) recombination, and homology-directed translocations in mec1-21, and characterized types of DNA damage-associated chromosomal rearrangements that occur in mec1-21. Although frequencies of UV-associated recombination were higher in mec1-21, the mutant was defective in double-strand break-associated SCE and heteroallelic recombination. Over-expression of Rad53 in mec1-21 reduced UV-associated recombination but did not suppress the defect in X-ray-associated recombination. Both X ray and UV exposure increased translocation frequencies in mec1-21, but the majority of the UV-associated products were non-reciprocal translocations. We suggest that although recombinational repair of double-stand breaks is less efficient in mec1 mutants, recombinants may be generated by other mechanisms, such as break-induced replication.

A novel Tel1/ATM N-terminal motif, TAN, is essential for telomere length maintenance and a DNA damage response

Tel1/ATM, a conserved phosphatidylinositol 3-kinase-related kinase (PIKK), acts in the response to DNA damage and regulates telomere maintenance. PIKK family members share an extended N-terminal region of low sequence homology. Sequence alignment of the N terminus of Tel1/ATM orthologs revealed a conserved, novel motif we term TAN (for Tel1/ATM N-terminal motif). Point mutations in conserved residues of the TAN motif resulted in telomere shortening, and its deletion caused the same short telomere phenotype as complete deletion of Tel1 did. Overexpressing Tel1 TAN mutants did not rescue telomere shortening. The TAN motif was also essential for the function of Tel1 in the response to DNA damage, as TAN-deleted Tel1 was indistinguishable from the complete lack of Tel1 in causing reduced viability and signaling through Rad53 upon DNA damage. Strikingly, TAN deletion reduced recruitment of Tel1 to a double-strand DNA break. Together, these results define a conserved sequence motif within an otherwise poorly defined region of the Tel1/ATM kinase family proteins that is essential for normal Tel1 function in Saccharomyces cerevisiae.

Relationships among carbohydrate intermediate metabolites and DNA damage and repair in yeast from a systems biology perspective

Glucose and fructose are major dietary carbohydrates that are essential for general metabolism. The elevated consumption of these two monosaccharides by the human population is related to the development of pluri-metabolic syndromes (e.g., diabetes mellitus and obesity). Glucose and fructose are metabolized by specific biochemical pathways to generate energy and metabolites. Many of these metabolites are mono- and bi-phosphorylated compounds, which renders them likely to generate reactive carbonyl species (RCS). Under physiological conditions, RCS react non-enzymatically with macromolecules and small molecules by means of Maillard reactions, forming stable glycated/fructated compounds called advanced glycation end products (AGEs). DNA and dNTPs are prone to react with RCS, forming DNA- and dNTP-AGEs, and many of these compounds are genotoxic and/or mutagenic. Unfortunately, little is understood about the genotoxicity and/or mutagenicity of carbohydrate intermediate metabolites or their interactions with DNA repair and carbohydrate metabolic-associated proteins. To elucidate these associations between carbohydrate metabolic pathways, DNA repair mechanisms, and dNTP-/DNA-AGEs, a systems biology study was performed by employing algorithms to mine literature data and construct physical protein-protein interactions. The results obtained in this work allow us to construct a model suggesting that yeast carbohydrate metabolic-associated enzymes activate different mechanisms for DNA repair and dNTP synthesis and act during DNA replication to protect the genome against the effects of RCS.

ATM-like kinases and regulation of telomerase: lessons from yeast and mammals

Telomeres, the essential structures at the ends of eukaryotic chromosomes, are composed of G-rich DNA and asociated proteins. These structures are crucial for the integrity of the genome, because they protect chromosome ends from degradation and distinguish natural ends from chromosomal breaks. The complete replication of telomeres requires a telomere-dedicated reverse transcriptase called telomerase. Paradoxically, proteins that promote the very activities against which telomeres protect, namely DNA repair, recombination and checkpoint activation, are integral to both telomeric chromatin and telomere elongation. This review focuses on recent findings that shed light on the roles of ATM-like kinases and other checkpoint and repair proteins in telomere maintenance, replication and checkpoint signaling.

Expression and maintenance of mitochondrial DNA: new insights into human disease pathology

Mitochondria are central players in cellular energy metabolism and, consequently, defects in their function result in many characterized metabolic diseases. Critical for their function is mitochondrial DNA (mtDNA), which encodes subunits of the oxidative phosphorylation complexes essential for cellular respiration and ATP production. Expression, replication, and maintenance of mtDNA require factors encoded by nuclear genes. These include not only the primary machinery involved (eg, transcription and replication components) but also those in signaling pathways that mediate or sense alterations in mitochondrial function in accord with changing cellular needs or environmental conditions. Mutations in these contribute to human disease pathology by mechanisms that are being revealed at an unprecedented rate. As I will discuss herein, the basic protein machinery required for transcription initiation in human mitochondria has been elucidated after the discovery of two multifunctional mitochondrial transcription factors, h-mtTFB1 and h-mtTFB2, that are also rRNA methyltransferases. In addition, involvement of the ataxia-telangiectasia mutated (ATM) and target of rapamycin (TOR) signaling pathways in regulating mitochondrial homeostasis and gene expression has also recently been uncovered. These advancements embody the current mitochondrial research landscape, which can be described as exploding with discoveries of previously unanticipated roles for mitochondria in human disease and aging.

High rates of "unselected" aneuploidy and chromosome rearrangements in tel1 mec1 haploid yeast strains

The yeast TEL1 and MEC1 genes (homologous to the mammalian ATM and ATR genes, respectively) serve partially redundant roles in the detection of DNA damage and in the regulation of telomere length. Haploid yeast tel1 mec1 strains were subcultured nonselectively for approximately 200 cell divisions. The subcultured strains had very high rates of chromosome aberrations: duplications, deletions, and translocations. The breakpoints of the rearranged chromosomes were within retrotransposons (Ty or delta-repeats), and these chromosome aberrations nonrandomly involved chromosome III. In addition, we showed that strains with the hypomorphic mec1-21 allele often became disomic for chromosome VIII. This property of the mec1-21 strains is suppressed by a plasmid containing the DNA2 gene (located on chromosome VIII) that encodes an essential nuclease/helicase involved in DNA replication and DNA repair.

Phosphorylation of the axial element protein Hop1 by Mec1/Tel1 ensures meiotic interhomolog recombination

An essential feature of meiosis is interhomolog recombination whereby a significant fraction of the programmed meiotic double-strand breaks (DSBs) is repaired using an intact homologous non-sister chromatid rather than a sister. Involvement of Mec1 and Tel1, the budding yeast homologs of the mammalian ATR and ATM kinases, in meiotic interhomlog bias has been implicated, but the mechanism remains elusive. Here, we demonstrate that Mec1 and Tel1 promote meiotic interhomolog recombination by targeting the axial element protein Hop1. Without Mec1/Tel1 phosphorylation of Hop1, meiotic DSBs are rapidly repaired via a Dmc1-independent intersister repair pathway, resulting in diminished interhomolog crossing-over leading to spore lethality. We find that Mec1/Tel1-mediated phosphorylation of Hop1 is required for activation of Mek1, a meiotic paralogue of the DNA-damage effector kinase, Rad53p/CHK2. Thus, Hop1 is a meiosis-specific adaptor protein of the Mec1/Tel1 signaling pathway that ensures interhomolog recombination by preventing Dmc1-independent repair of meiotic DSBs.

Tel1p preferentially associates with short telomeres to stimulate their elongation

In many organisms, telomeric DNA consists of long tracts of short repeats. Shorter tracts are preferentially lengthened by telomerase, suggesting a conserved mechanism that recognizes and elongates short telomeres. Tel1p, an ATM family checkpoint kinase, plays an important role in telomere elongation, as cells lacking Tel1p have short telomeres and show reduced recruitment of telomerase components to telomeres. We show that Tel1p association increased as telomeres shortened in vivo in the presence or absence of telomerase and that Tel1p preferentially associated with the shortest telomeres. Tel1p association was independent of Tel1p kinase activity and enhanced by Mre11p. Tel1p overexpression simultaneously stimulated telomerase-mediated elongation and Tel1p association with all telomeres. Thus, Tel1p preferentially associates with the shortest telomeres and stimulates their elongation by telomerase.

Dominant TEL1-hy mutations compensate for Mec1 lack of functions in the DNA damage response

Eukaryotic genome integrity is safeguarded by two highly conserved protein kinases that are called ATR and ATM for humans and Mec1 and Tel1 for Saccharomyces cerevisiae. Although they share sequence similarities and substrates, these protein kinases perform different specialized functions. In particular, Mec1 plays a key role in the DNA damage checkpoint response, whereas Tel1 primarily is involved in telomere homeostasis, and its checkpoint function is masked by the prevailing activity of Mec1. In order to understand how this specificity is achieved, we searched for TEL1 mutations able to compensate for the lack of Mec1 functions. Here, we describe seven independent dominant TEL1-hy alleles that are able to suppress, to different extents, both the hypersensitivity to genotoxic agents and the checkpoint defects of Mec1-deficient cells. Most of these alleles also cause telomere overelongation. In vitro kinase activity was increased compared to that of wild-type Tel1 in the Tel1-hy385, Tel1-hy394, Tel1-hy680, and Tel1-hy909 variants, but its activity was not affected by the TEL1-hy184 and TEL1-hy628 mutations and was slightly reduced by the TEL1-hy544 mutation. Thus, the phenotypes caused by at least some Tel1-hy variants are not simply the consequence of improved catalytic activity. Further characterization shows that Tel1-hy909 not only can sense and signal a single double-stranded DNA break, unlike wild-type Tel1, but also contributes more efficiently than Tel1 to single-stranded DNA accumulation at double-strand ends, thus enhancing Mec1 signaling activity. Moreover, it causes unscheduled checkpoint activation in unperturbed conditions and upregulates the checkpoint response to small amounts of DNA lesions. Finally, Tel1-hy544 can activate the checkpoint more efficiently than wild-type Tel1, while it causes telomere shortening, indicating that the checkpoint and telomeric functions of Tel1 can be separable.

A Saccharomyces cerevisiae autoselection system for optimised recombinant protein expression

Yeasts are attractive organisms for recombinant protein production. They combine highly developed genetic systems and ease of use with reductions in time and costs. We describe an autoselection system for recombinant protein expression in Saccharomyces cerevisiae which increases yields 5-10-fold compared to conditional selection for expression plasmids. Multicopy expression plasmids encoding essential MOB1 or CDC28 genes are absolutely necessary for the viability of host cells with mob1 or cdc28 deletions in their genomes. Such plasmids are stably maintained, even in rich medium, so optimising biomass production and yields of recombinant protein. Plasmid copy numbers are also increased by limiting selective MOB1 and CDC28 gene expression prior to induction. GST- or 6His-tagged proteins are produced for affinity purification and are expressed from a conditional GAL1-10 promoter to avoid potentially toxic effects of recombinant proteins on growth. Autoselection systems for expressing single or pairs of proteins are described. We demonstrate the versatility of this system by expressing proteins from a number of organisms and include several large and problematic products. The in vitro reconstruction of a step in mitotic regulation shows how this expression system can be successfully applied to the detailed analysis of complex metabolic pathways.

Mec1/Tel1 Phosphorylation of the INO80 Chromatin Remodeling Complex Influences DNA Damage Checkpoint Responses

The yeast Mec1/Tel1 kinases, ATM/ATR in mammals, coordinate the DNA damage response by phosphorylating proteins involved in DNA repair and checkpoint pathways. Recently, ATP-dependent chromatin remodeling complexes, such as the INO80 complex, have also been implicated in DNA damage responses, although regulatory mechanisms that direct their function remain unknown. Here, we show that the Ies4 subunit of the INO80 complex is phosphorylated by the Mec1/Tel1 kinases during exposure to DNA-damaging agents. Mutation of Ies4's phosphorylation sites does not significantly affect DNA repair processes, but does influence DNA damage checkpoint responses. Additionally, ies4 phosphorylation mutants are linked to the function of checkpoint regulators, such as the replication checkpoint factors Tof1 and Rad53. These findings establish a chromatin remodeling complex as a functional component in the Mec1/Tel1 DNA damage signaling pathway that modulates checkpoint responses and suggest that posttranslational modification of chromatin remodeling complexes regulates their involvement in distinct processes.

Telomerase and Tel1p preferentially associate with short telomeres in S. cerevisiae

In diverse organisms, telomerase preferentially elongates short telomeres. We generated a single short telomere in otherwise wild-type (WT) S. cerevisiae cells. The binding of the positive regulators Ku and Cdc13p was similar at short and WT-length telomeres. The negative regulators Rif1p and Rif2p were present at the short telomere, although Rif2p levels were reduced. Two telomerase holoenzyme components, Est1p and Est2p, were preferentially enriched at short telomeres in late S/G2 phase, the time of telomerase action. Tel1p, the yeast ATM-like checkpoint kinase, was highly enriched at short telomeres from early S through G2 phase and even into the next cell cycle. Nonetheless, induction of a single short telomere did not elicit a cell-cycle arrest. Tel1p binding was dependent on Xrs2p and required for preferential binding of telomerase to short telomeres. These data suggest that Tel1p targets telomerase to the DNA ends most in need of extension.

Control of the yeast telomeric senescence survival pathways of recombination by the Mec1 and Mec3 DNA damage sensors and RPA

Saccharomyces cerevisiae telomerase-negative cells undergo homologous recombination on subtelomeric or TG_1–3 telomeric sequences, thus allowing Type I or Type II post-senescence survival, respectively. Here, we find that the DNA damage sensors, Mec1, Mec3 and Rad24 control Type II recombination, while the Rad9 adaptor protein and the Rad53 and Chk1 effector kinases have no effect on survivor type selection. Therefore, the Mec1 and Mec3 checkpoint complexes control telomeric recombination independently of their roles in generating and amplifying the Mec1-Rad53-Chk1 kinase cascade. rfa1-t11 mutant cells, bearing a mutation in Replication Protein A (RPA) conferring a defect in recruiting Mec1-Ddc2, were also deficient in both types of telomeric recombination. Importantly, expression of an Rfa1-t11-Ddc2 hybrid fusion protein restored checkpoint-dependent arrest, but did not rescue defective telomeric recombination. Therefore, the Rfa1-t11-associated defect in telomeric recombination is not solely due to its failure to recruit Mec1. We have also isolated novel alleles of RFA1 that were deficient in Type I but not in Type II recombination and proficient in checkpoint control. Therefore, the checkpoint and recombination functions of RPA can be genetically separated, as can the RPA-mediated control of the two types of telomeric recombination.

The telomerase-recruitment domain of the telomere binding protein Cdc13 is regulated by Mec1p/Tel1p-dependent phosphorylation

The DNA damage-responsive protein kinases ATM and ATR phosphorylate SQ/TQ motifs that lie in clusters in most of their in vivo targets. Budding yeast Cdc13p contains two clusters of SQ/TQ motifs, suggesting that it might be a target of Mec1p/Tel1p (yeast ATR/ATM). Here we demonstrated that the telomerase recruitment domain of Cdc13p is phosphorylated by Mec1p and Tel1p. Gel analysis showed that Cdc13p contains a Mec1/Tel1-dependent post-translational modification. Using an immunoprecipitate (IP)-kinase assay, we showed that Mec1p phosphorylates Cdc13p on serine 225, 249, 255 and 306, and Tel1p phosphorylates Cdc13p on serine 225, 249 and 255 in vitro. Phenotypic analysis in vivo revealed that the mutations in the Cdc13p SQ motifs phosphorylated by Mec1p and Tel1p caused multiple telomere and growth defects. In addition, normal telomere length and growth could be restored by expressing a Cdc13-Est1p hybrid protein. These results demonstrate the telomerase recruitment domain of Cdc13p as an important new telomere-specific target of Mec1p/Tel1p.

A telomeric repeat sequence adjacent to a DNA double-stranded break produces an anticheckpoint

Telomeres are complex structures that serve to protect chromosome ends. Here we provide evidence that in Saccharomyces cerevisiae telomeres may contain an anticheckpoint activity that prevents chromosome ends from signaling cell cycle arrest. We found that an internal tract of telomeric repeats inhibited DNA damage checkpoint signaling from adjacent double-strand breaks (DSBs); cell cycle arrest lasted 8-12 h from a normal DSB, whereas it lasted only 1-2 h from a DSB adjacent to a telomeric repeat. The shortened or abridged arrest was not the result of DNA repair, nor reduced amounts of single-stranded DNA, nor of adaptation. The molecular identity of this telomere repeat-associated anticheckpoint activity is unknown, though it is not dependent upon telomerase or telomere-proximal gene silencing. The anticheckpoint may inhibit the ATR yeast ortholog Mec1 because Rad9 and Rad53 became dephosphorylated and inactivated during the abridged arrest. The anticheckpoint acts regionally; it inhibited signaling from DNA breaks up to 0.6 kb away from the telomeric repeat but not from a DSB present on a separate chromosome. We propose that after formation of the DSB near the telomeric repeat, a mature telomere forms in 1-2 h, and the telomere then contains proteins that inhibit checkpoint signaling from nearby DNA breaks.

Def1p is involved in telomere maintenance in budding yeast

Saccharomyces Rrm3p, a member of Pif1 5'-3' DNA helicase subfamily, helps replication forks traverse protein-DNA complexes, including the telomere. Here we have identified an Rrm3p interaction protein known to be Def1p. In def1 mutants, telomeres were approximately 200-bp shorter than that in wild-type cells. DEF1 is also required for the stable maintenance of mitochondrial DNA, and the telomere shortening phenotype seen in def1 cells is not a secondary consequence of the mitochondrion defect. A combination of DEF1 null mutation with deletion of EST2 or EST3 resulted in an accelerated senescence phenotype, suggesting that Def1p is not involved in the telomerase recruitment pathway. In the absence of telomerase, cells escape senescence by either amplifying Y' regions or TG-telomeric repeats to generate type I or type II survivors, respectively. Only type I survivors were recovered from both def1Delta est2Delta and def1Delta est3Delta double mutant cells, further suggesting that the function of Def1p in telomere maintenance is specific. Our novel findings of the functions of Def1p in telomere and mitochondria suggested that Def1p plays multiple roles in yeast.

Inositol pyrophosphates regulate cell death and telomere length through phosphoinositide 3-kinase-related protein kinases

Inositol pyrophosphates physiologically regulate vesicular endocytosis, ribosomal disposition, and directly phosphorylate proteins. Here we demonstrate roles in cell death and regulation of telomere length. Lethal actions of wortmannin and caffeine are selectively abolished in yeast mutants that cannot synthesize inositol pyrophosphates. Wortmannin and caffeine appear to act through the phosphoinositide 3-kinase-related protein kinases Tel1 and Mec1, known regulators of telomere length. Inositol pyrophosphates physiologically antagonize the actions of these kinases, which is demonstrated by the fact that yeast mutants with reduced or elevated levels of inositol pyrophosphates, respectively, display longer and shorter telomeres.

The Hog1 MAP kinase pathway and the Mec1 DNA damage checkpoint pathway independently control the cellular responses to hydrogen peroxide

The DNA damage checkpoint pathway and the MAP kinase pathway respond to various forms of environmental as well as endogenous stresses through signal transduction mechanisms involving protein kinases. Both pathways are intertwined in mammalian cells, but potential crosstalk between these two pathways in budding yeast has not been examined yet. We show that the Rad53 checkpoint kinase and the Hog1 MAP kinase of Saccharomyces cerevisiae become phosphorylated upon exposure to hydrogen peroxide, indicative of activation of the DNA damage checkpoint and MAP kinase pathways in response to oxidative stress. Rad53 kinase is equally activated in wild type and in hog1-Delta cells. Likewise, the activation of Hog1 MAP kinase is not dependent on Mec1 kinase, the central checkpoint kinase in budding yeast. Mutants in either pathway are sensitive to hydrogen peroxide and the double mutants exhibit a near perfectly additive phenotype. These data demonstrate that the DNA damage checkpoint pathway and the MAP kinase pathway respond to oxidative stress independently of each other and suggest that these two stress signaling pathways are activated by different types of insults induced by hydrogen peroxide.

Telomeres and DNA damage checkpoints

In all eukaryotic organisms, interruptions in duplex DNA molecules elicit a DNA damage response, which includes activation of DNA repair machineries and surveillance mechanisms, known as DNA damage checkpoints. Telomeres and double-strand breaks (DSBs) share the common feature of being physical ends of chromosomes. However, unlike DSBs, telomeres do not activate the DNA damage checkpoints and are usually protected from end-to-end fusions and other processing events that normally promote repair of DNA breaks. This indicates that they are shielded from being recognized and processed as DSBs. On the other hand, chromosome ends resemble damaged DNA, as several factors required for DNA repair and checkpoint networks play important roles in telomere length maintenance. Due to the critical role of both DNA damage checkpoints and telomere homeostasis in maintaining genetic stability and in counteracting cancer development, the knowledge of their interconnections is essential for our understanding of these key cellular controls.

A Tel1/MRX-dependent checkpoint inhibits the metaphase-to-anaphase transition after UV irradiation in the absence of Mec1

In Saccharomyces cerevisiae, Mec1/ATR plays a primary role in sensing and transducing checkpoint signals in response to different types of DNA lesions, while the role of the Tel1/ATM kinase in DNA damage checkpoints is not as well defined. We found that UV irradiation in G(1) in the absence of Mec1 activates a Tel1/MRX-dependent checkpoint, which specifically inhibits the metaphase-to-anaphase transition. Activation of this checkpoint leads to phosphorylation of the downstream checkpoint kinases Rad53 and Chk1, which are required for Tel1-dependent cell cycle arrest, and their adaptor Rad9. The spindle assembly checkpoint protein Mad2 also partially contributes to the G(2)/M arrest of UV-irradiated mec1Delta cells independently of Rad53 phosphorylation and activation. The inability of UV-irradiated mec1Delta cells to undergo anaphase can be relieved by eliminating the anaphase inhibitor Pds1, whose phosphorylation and stabilization in these cells depend on Tel1, suggesting that Pds1 persistence may be responsible for the inability to undergo anaphase. Moreover, while UV irradiation can trigger Mec1-dependent Rad53 phosphorylation and activation in G(1)- and G(2)-arrested cells, Tel1-dependent checkpoint activation requires entry into S phase independently of the cell cycle phase at which cells are UV irradiated, and it is decreased when single-stranded DNA signaling is affected by the rfa1-t11 allele. This indicates that UV-damaged DNA molecules need to undergo structural changes in order to activate the Tel1-dependent checkpoint. Active Clb-cyclin-dependent kinase 1 (CDK1) complexes also participate in triggering this checkpoint and are required to maintain both Mec1- and Tel1-dependent Rad53 phosphorylation, suggesting that they may provide critical phosphorylation events in the DNA damage checkpoint cascade.

Functional links between telomeres and proteins of the DNA-damage response

In response to DNA damage, cells engage a complex set of events that together comprise the DNA-damage response (DDR). These events bring about the repair of the damage and also slow down or halt cell cycle progression until the damage has been removed. In stark contrast, the ends of linear chromosomes, telomeres, are generally not perceived as DNA damage by the cell even though they terminate the DNA double-helix. Nevertheless, it has become clear over the past few years that many proteins involved in the DDR, particularly those involved in responding to DNA double-strand breaks, also play key roles in telomere maintenance. In this review, we discuss the current knowledge of both the telomere and the DDR, and then propose an integrated model for the events associated with the metabolism of DNA ends in these two distinct physiological contexts.

Reciprocal association of the budding yeast ATM-related proteins Tel1 and Mec1 with telomeres in vivo

The phosphoinositide (PI)-3-kinase-related kinase (PIKK) family proteins Tel1p and Mec1p have been implicated in the telomere integrity of Saccharomyces cerevisiae. However, the mechanism of PIKK-mediated telomere length control remains unclear. Here, we show that Tel1p and Mec1p are recruited to the telomeres at specific times in the cell cycle in a mutually exclusive manner. In particular, Mec1p interacts with the telomeres during late S phase and is associated preferentially with shortened telomeres. We propose a model in which telomere integrity is maintained by the reciprocal association of PIKKs, and Mec1p acts as a sensor for structural abnormalities in the telomeres. Our study suggests a mechanistic similarity between telomere length regulation and DNA double-strand break repair, both of which are achieved by the direct association of PIKKs.

ATM and genome maintenance: defining its role in breast cancer susceptibility

The ATM gene is mutated in ataxia-telangiectasia (A-T), a genetic instability syndrome characterized by increased cancer risk, as well as other features. Recent studies have shown that the ATM protein kinase plays a critical role in maintaining genome integrity by activating a biochemical chain reaction that in turn leads to cell cycle checkpoint activation and repair of DNA damage. ATM targets include well-known tumor suppressor genes such as p53 and BRCA1, both of which play an important role in predisposition to breast cancer. Studies of A-T families have consistently reported an increased risk of breast cancer in women with one mutated ATM gene, but so far an increased frequency of ATM mutations has not been found in women with breast cancer. Some specific missense and protein truncating variants of ATM have been reported to confer increased breast cancer risk, but the magnitude of this risk remains uncertain. A more comprehensive analysis of ATM is needed in large case-control studies, and in multiple-case breast cancer families.

The functions of budding yeast Sae2 in the DNA damage response require Mec1- and Tel1-dependent phosphorylation

DNA damage checkpoint pathways sense DNA lesions and transduce the signals into appropriate biological responses, including cell cycle arrest, induction of transcriptional programs, and modification or activation of repair factors. Here we show that the Saccharomyces cerevisiae Sae2 protein, known to be involved in processing meiotic and mitotic double-strand breaks, is required for proper recovery from checkpoint-mediated cell cycle arrest after DNA damage and is phosphorylated periodically during the unperturbed cell cycle and in response to DNA damage. Both cell cycle- and DNA damage-dependent Sae2 phosphorylation requires the main checkpoint kinase, Mec1, and the upstream components of its pathway, Ddc1, Rad17, Rad24, and Mec3. Another pathway, involving Tel1 and the MRX complex, is also required for full DNA damage-induced Sae2 phosphorylation, that is instead independent of the downstream checkpoint transducers Rad53 and Chk1, as well as of their mediators Rad9 and Mrc1. Mutations altering all the favored ATM/ATR phosphorylation sites of Sae2 not only abolish its in vivo phosphorylation after DNA damage but also cause hypersensitivity to methyl methanesulfonate treatment, synthetic lethality with RAD27 deletion, and decreased rates of mitotic recombination between inverted Alu repeats, suggesting that checkpoint-mediated phosphorylation of Sae2 is important to support its repair and recombination functions.

Association of Rad9 with double-strand breaks through a Mec1-dependent mechanism

Rad9 is required for the activation of DNA damage checkpoint pathways in budding yeast. Rad9 is phosphorylated after DNA damage in a Mec1- and Tel1-dependent manner and subsequently interacts with Rad53. This Rad9-Rad53 interaction has been suggested to trigger the activation and phosphorylation of Rad53. Here we show that Mec1 controls the Rad9 accumulation at double-strand breaks (DSBs). Rad9 was phosphorylated after DSB induction and associated with DSBs. However, its phosphorylation and association with DSBs were significantly decreased in cells carrying a mec1Delta or kinase-negative mec1 mutation. Mec1 phosphorylated the S/TQ motifs of Rad9 in vitro, the same motifs that are phosphorylated after DNA damage in vivo. In addition, multiple mutations in the Rad9 S/TQ motifs resulted in its defective association with DSBs. Phosphorylation of Rad9 was partially defective in cells carrying a weak mec1 allele (mec1-81), whereas its association with DSBs occurred efficiently in the mec1-81 mutants, as found in wild-type cells. However, the Rad9-Rad53 interaction after DSB induction was significantly decreased in mec1-81 mutants, as it was in mec1Delta mutants. Deletion mutation in RAD53 did not affect the association of Rad9 with DSBs. Our results suggest that Mec1 promotes association of Rad9 with sites of DNA damage, thereby leading to full phosphorylation of Rad9 and its interaction with Rad53.

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

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 G(2)/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 G(2)/M cell cycle progression and is a novel target of checkpoint-dependent cell cycle arrest pathways.

DNA stimulates Mec1-mediated phosphorylation of replication protein A

The cellular single-stranded DNA (ssDNA)-binding protein replication protein A (RPA) becomes phosphorylated periodically during the normal cell cycle and also in response to DNA damage. In Saccharomyces cerevisiae, RPA phosphorylation requires the checkpoint protein Mec1, a protein kinase homologous in structure and function to human ATR. We confirm here that immunocomplexes containing a tagged version of Mec1 catalyze phosphorylation of purified RPA, likely reflecting an RPA kinase activity intrinsic to Mec1. A significant stimulation of this activity is observed upon the addition of covalently closed ssDNA derived from the bacteriophage M13. This stimulation is not observed with mutant RPA deficient for DNA binding, indicating that DNA-bound RPA is a preferred substrate. Stimulation is also observed upon the addition of linear ssDNA homopolymers or hydrolyzed M13 ssDNA. In contrast to circular ssDNA, these DNA cofactors stimulate both wild type and mutant RPA phosphorylation. This finding suggests that linear ssDNA can also stimulate Mec1-mediated RPA phosphorylation by activating Mec1 or an associated protein. Although the Mec1-interacting protein Ddc2 is required for RPA phosphorylation in vivo, it is required for neither basal nor ssDNA-stimulated RPA phosphorylation in vitro. Therefore, activation of Mec1-mediated RPA phosphorylation by either circular or linear ssDNA does not operate through Ddc2. Our results provide insight into the mechanisms that function in vivo to specifically induce RPA phosphorylation upon initiation of DNA replication, repair, or recombination.

MEC1-dependent phosphorylation of yeast RPA1 in vitro

Replication protein A (RPA) is a conserved single-stranded DNA (ssDNA) binding protein with well-characterized roles in DNA metabolism. RPA is phosphorylated in response to genotoxic stress and is required for efficient checkpoint function, although these aspects of RPA function are not well understood. We have investigated the association between RPA and the checkpoint kinase Mec1 in yeast. RPA and Mec1 were found to be physically associated during unperturbed cell growth and in response to DNA damage. Using a Mec1 immunoprecipitate (IP)-kinase assay, we show that the two large subunits, RPA1 and RPA2, are good substrates for Mec1 kinase. The major phosphorylation site of RPA1 was further investigated as it was found to be localized to its amino terminus (RPA1N), which is a non-ssDNA binding domain implicated in regulatory function. This phosphorylation site mapped to serine 178 and phosphorylation-defective mutant protein, expressed from rfa1-S178A, showed reduced physical interaction with Mec1. Phenotypic analysis in vivo revealed that the rfa1-S178A mutation affected the kinetics of RPA1 and Rad53 phosphorylation but did not otherwise affect the checkpoint response. We suggest that phosphorylation of RPA1N by Mec1 may function together with other checkpoint events to regulate the checkpoint response.

DNA damage response-mediated degradation of Ho endonuclease via the ubiquitin system involves its nuclear export

Yeast mating switch Ho endonuclease is rapidly degraded by the ubiquitin system and this depends on the DNA damage response functions, MEC1, RAD9, and CHK1. A PEST sequence marks Ho for degradation. Here we show that the novel F-box receptor, Ufo1, recruits phosphorylated Ho for degradation. Mutation of PEST residue threonine 225 stabilizes Ho, yet HoT225A still binds Ufo1 in vitro. Stable HoT225A accumulates within the nucleus, whereas HoT225E is degraded. Deletion of the nuclear exportin Msn5 traps native Ho in the nucleus and extends its half-life. These experiments suggest that Ho is degraded in the cytoplasm. In mec1 mutants stable Ho accumulates within the nucleus; Ho produced in mec1 cells does not bind Ufo1. Thus the MEC1 pathway has functions both in phosphorylation of Thr-225 for nuclear export and in additional phosphorylations for binding Ufo1. Cells with HO under its genomic promoter, but stabilized by deletion of the Msn5 exportin, proliferate, but are multibudded. These experiments elucidate some of the links between the DNA damage response and degradation of Ho by the ubiquitin system.

Amino acid changes in Xrs2p, Dun1p, and Rfa2p that remove the preferred targets of the ATM family of protein kinases do not affect DNA repair or telomere length in Saccharomyces cerevisiae

In eukaryotes, mutations in a number of genes that affect DNA damage checkpoints or DNA replication also affect telomere length [Curr. Opin. Cell Biol. 13 (2001) 281]. Saccharomyces cerevisae strains with mutations in the TEL1 gene (encoding an ATM-like protein kinase) have very short telomeres, as do strains with mutations in XRS2, RAD50, or MRE11 (encoding members of a trimeric complex). Xrs2p and Mre11p are phosphorylated in a Tel1p-dependent manner in response to DNA damage [Genes Dev. 15 (2001) 2238; Mol. Cell 7 (2001) 1255]. We found that Xrs2p, but not Mre11p or Rad50p, is efficiently phosphorylated in vitro by immunopreciptated Tel1p. Strains with mutations eliminating all SQ and TQ motifs in Xrs2p (preferred targets of the ATM kinase family) had wild-type length telomeres and wild-type sensitivity to DNA damaging agents. We also showed that Rfa2p (a subunit of RPA) and the Dun1p checkpoint kinase, which are required for DNA damage repair and which are phosphorylated in response to DNA damage in vivo, are in vitro substrates of the Tel1p and Mec1p kinases. In addition, Dun1p substrates with no SQ or TQ motifs are phosphorylated by Mec1p in vitro very inefficiently, but retain most of their ability to be phosphorylated by Tel1p. We demonstrated that null alleles of DUN1 and certain mutant alleles of RFA2 result in short telomeres. As observed with Xrs2p, however, strains with mutations of DUN1 or RFA2 that eliminate SQ motifs have no effect on telomere length or DNA damage sensitivity.

Systematic trans-genomic comparison of protein kinases between Arabidopsis and Saccharomyces cerevisiae

The genome of the budding yeast (Saccharomyces cerevisiae) provides an important paradigm for transgenomic comparisons with other eukaryotic species. Here, we report a systematic comparison of the protein kinases of yeast (119 kinases) and a reference plant Arabidopsis (1,019 kinases). Using a whole-protein-based, hierarchical clustering approach, the complete set of protein kinases from both species were clustered. We validated our clustering by three observations: (a) clustering pattern of functional orthologs proven in genetic complementation experiments, (b) consistency with reported classifications of yeast kinases, and (c) consistency with the biochemical properties of those Arabidopsis kinases already experimentally characterized. The clustering pattern identified no overlap between yeast kinases and the receptor-like kinases (RLKs) of Arabidopsis. Ten more kinase families were found to be specific for one of the two species. Among them, the calcium-dependent protein kinase and phosphoenolpyruvate carboxylase kinase families are specific for plants, whereas the Ca(2+)/calmodulin-dependent protein kinase and provirus insertion in mouse-like kinase families were found only in yeast and animals. Three yeast kinase families, nitrogen permease reactivator/halotolerance-5), polyamine transport kinase, and negative regulator of sexual conjugation and meiosis, are absent in both plants and animals. The majority of yeast kinase families (21 of 26) display Arabidopsis counterparts, and all are mapped into Arabidopsis families of intracellular kinases that are not related to RLKs. Representatives from 11 of the common families (54 kinases from Arabidopsis and 17 from yeast) share an extremely high degree of similarity (blast E value < 10(-80)), suggesting the likelihood of orthologous functions. Selective expansion of yeast kinase families was observed in Arabidopsis. This is most evident for yeast genes CBK1, HRR25, and SNF1 and the kinase family S6K. Reduction of kinase families was also observed, as in the case of the NEK-like family. The distinguishing features between the two sets of kinases are the selective expansion of yeast families and the generation of a limited number of new kinase families for new functionality in Arabidopsis, most notably, the Arabidopsis RLKs that constitute important components of plant intercellular communication apparatus.

Telomerase and ATM/Tel1p protect telomeres from nonhomologous end joining

Telomeres protect chromosome ends from fusing to double-stranded breaks (DSBs). Using a quantitative real-time PCR assay, we show that nonhomologous end joining between a telomere and an inducible DSB was undetectable in wild-type cells, but occurred within a few hours of DSB induction in approximately 1/2000 genomes in telomerase-deficient cells and in >1/1000 genomes in telomerase-deficient cells also lacking the ATM homolog Tel1p. The fused telomeres contained very little telomeric DNA, suggesting that catastrophic telomere shortening preceded fusion. Lengthening of telomeres did not prevent such catastrophic telomere shortening and fusion events. Telomere-DSB fusion also occurred in cells containing a catalytically inactive telomerase and in tel1 mec1 cells where telomerase cannot elongate telomeres. Thus, telomerase and Tel1p function in telomere protection as well as in telomere elongation.

Inactivation of Cdc13p triggers MEC1-dependent apoptotic signals in yeast

Inactivation of the budding yeast telomere binding protein Cdc13 results in abnormal telomeres (exposed long G-strands) and activation of the DNA damage checkpoint. In the current study, we show that inactivation of Cdc13p induces apoptotic signals in yeast, as evidenced by caspase activation, increased reactive oxygen species production, and flipping of phosphatidylserine in the cytoplasmic membrane. These apoptotic signals were suppressed in a mitochondrial (rho(o)) mutant. Moreover, mitochondrial proteins (e.g. MTCO3) were identified as multicopy suppressors of cdc13-1, suggesting the involvement of mitochondrial functions in telomere-initiated apoptotic signaling. These telomere-initiated apoptotic signals were also shown to depend on MEC1, but not TEL1, and were antagonized by MRE11. Our results are consistent with a model in which single-stranded G-tails in the cdc13-1 mutant trigger MEC1-dependent apoptotic signaling in yeast.

Saccharomyces cerevisiae Dap1p, a novel DNA damage response protein related to the mammalian membrane-associated progesterone receptor

The response to damage is crucial for cellular survival, and eukaryotic cells require a broad array of proteins for an intact damage response. We have found that the YPL170W (DAP1 [for damage response protein related to membrane-associated progesterone receptors]) gene is required for growth in the presence of the methylating agent methyl methanesulfonate (MMS). The DAP1 open reading frame shares homology with a broadly conserved family of membrane-associated progesterone receptors (MAPRs). Deletion of DAP1 leads to sensitivity to MMS, elongated telomeres, loss of mitochondrial function, and partial arrest in sterol synthesis. Sensitivity of dap1 strains to MMS is not due to loss of damage checkpoints. Instead, dap1 cells are arrested as unbudded cells after MMS treatment, suggesting that Dap1p is required for cell cycle progression following damage. Dap1p also directs resistance to itraconazole and fluconazole, inhibitors of sterol synthesis. We have found that dap1 cells have slightly decreased levels of ergosterol but increased levels of the ergosterol intermediates squalene and lanosterol, indicating that dap1 cells have a partial defect in sterol synthesis. This is the first evidence linking a MAPR family member to sterol regulation or the response to damage, and these functions are probably conserved in a variety of eukaryotes.

Novel functions of the phosphatidylinositol metabolic pathway discovered by a chemical genomics screen with wortmannin

We report a novel connection between the phosphatidylinositol (PI) metabolic pathway and the DNA replication and damage checkpoint pathway discovered from an unbiased chemical genomics screen. Substrates and products of PI kinases are important signaling molecules that affect a wide range of biological processes. The full collection of yeast deletion strains was screened to identify genes that confer altered sensitivity to the natural product wortmannin, a PI kinase inhibitor. These experiments have allowed us to explore metabolomic and proteomic implications of PI synthesis and turnover. This study also uncovers other biological processes affected by wortmannin treatment, including proteasome-mediated degradation and chromatin remodeling. Bioinformatic analyses were used to reveal the relative distances among cellular processes affected by wortmannin and protein-protein interactions in the wortmannin-sensitive proteomic subnetwork. These results illustrate the great utility of using a whole-genome approach in annotating the biological effects of small molecules and have clear implications for pharmacogenomics. Furthermore, our discovery points to a route to overcoming genome instability, a result of defective DNA damage signaling/repair and a hallmark of cancer.

The ATM-related Tel1 protein of Saccharomyces cerevisiae controls a checkpoint response following phleomycin treatment

MEC1 and TEL1 encode ATR- and ATM-related proteins in the budding yeast Saccharomyces cerevisiae, respectively. Phleomycin is an agent that catalyzes double-strand breaks in DNA. We show here that both Mec1 and Tel1 regulate the checkpoint response following phleomycin treatment. MEC1 is required for Rad53 phosphorylation and cell-cycle progression delay following phleomycin treatment in G1, S or G2/M phases. The tel1Delta mutation confers a defect in the checkpoint responses to phleomycin treatment in S phase. In addition, the tel1Delta mutation enhances the mec1 defect in activation of the phleomycin-induced checkpoint pathway in S phase. In contrast, the tel1Delta mutation confers only a minor defect in the checkpoint responses in G1 phase and no apparent defect in G2/M phase. Methyl methanesulfonate (MMS) treatment also activates checkpoints, inducing Rad53 phosphorylation in S phase. MMS-induced Rad53 phosphorylation is not detected in mec1Delta mutants during S phase, but occurs in tel1Delta mutants similar to wild-type cells. Finally, Xrs2 is phosphorylated after phleomycin treatment in a TEL1-dependent manner during S phase, whereas no significant Xrs2 phosphorylation is detected after MMS treatment. Together, our results support a model in which Tel1 contributes to checkpoint control in response to phleomycin-induced DNA damage in S phase.

Direct kinase-to-kinase signaling mediated by the FHA phosphoprotein recognition domain of the Dun1 DNA damage checkpoint kinase

The serine-threonine kinase Dun1 contains a forkhead-associated (FHA) domain and functions in the DNA damage checkpoint pathway of Saccharomyces cerevisiae. It belongs to the Chk2 family of checkpoint kinases, which includes S. cerevisiae Rad53 and Mek1, Schizosaccharomyces pombe Cds1, and human Chk2. Dun1 is required for DNA damage-induced transcription of certain target genes, transient G(2)/M arrest after DNA damage, and DNA damage-induced phosphorylation of the DNA repair protein Rad55. Here we report that the FHA phosphoprotein recognition domain of Dun1 is required for direct phosphorylation of Dun1 by Rad53 kinase in vitro and in vivo. trans phosphorylation by Rad53 does not require the Dun1 kinase activity and is likely to involve only a transient interaction between the two kinases. The checkpoint functions of Dun1 kinase in DNA damage-induced transcription, G(2)/M cell cycle arrest, and Rad55 phosphorylation are severely compromised in an FHA domain mutant of Dun1. As a consequence, the Dun1 FHA domain mutant displays enhanced sensitivity to genotoxic stress induced by UV, methyl methanesulfonate, and the replication inhibitor hydroxyurea. We show that the Dun1 FHA domain is critical for direct kinase-to-kinase signaling from Rad53 to Dun1 in the DNA damage checkpoint pathway.

Identification of in vitro and in vivo phosphorylation sites in the catalytic subunit of the DNA-dependent protein kinase

The DNA-dependent protein kinase (DNA-PK) is required for the repair of DNA double-strand breaks (DSBs), such as those caused by ionizing radiation and other DNA-damaging agents. DNA-PK is composed of a large catalytic subunit (DNA-PKcs) and a heterodimer of Ku70 and Ku80 that assemble on the ends of double-stranded DNA to form an active serine/threonine protein kinase complex. Despite in vitro and in vivo evidence to support an essential role for the protein kinase activity of DNA-PK in the repair of DNA DSBs, the physiological targets of DNA-PK have remained elusive. We have previously shown that DNA-PK undergoes autophosphorylation in vitro, and that autophosphorylation correlates with loss of protein kinase activity and dissociation of the DNA-PK complex. Also, treatment of cells with the protein phosphatase inhibitor, okadaic acid, enhances DNA-PKcs phosphorylation and reduces DNA-PK activity in vivo. Here, using solid-phase protein sequencing, MS and phosphospecific antibodies, we have identified seven in vitro autophosphorylation sites in DNA-PKcs. Six of these sites (Thr2609, Ser2612, Thr2620, Ser2624, Thr2638 and Thr2647) are clustered in a region of 38 amino acids in the central region of the protein. Five of these sites (Thr2609, Ser2612, Thr2638, Thr2647 and Ser3205) are conserved between six vertebrate species. Moreover, we show that DNA-PKcs is phosphorylated in vivo at Thr2609, Ser2612, Thr2638 and Thr2647 in okadaic acid-treated human cells. We propose that phosphorylation of these sites may play an important role in DNA-PK function.

Myosin-like proteins 1 and 2 are not required for silencing or telomere anchoring, but act in the Tel1 pathway of telomere length control

The positioning of chromosomal domains in interphase nuclei is thought to facilitate transcriptional repression in yeast. It has been reported that two large coiled-coil proteins of the nuclear envelope, myosin-like proteins 1 and 2, play direct roles in anchoring yeast telomeres to the nuclear periphery, thereby creating a subcompartment enriched for Sir proteins. We have created strains containing complete deletions of mlp1 and mlp2 genes, as well as the double null strain, and find no evidence for the disruption of telomere anchoring at the nuclear periphery in these cells. We also detect no disruption of telomere-associated gene silencing. We confirm, on the other hand, that mlp mutants are particularly sensitive to DNA-damaging agents, such as bleomycin. Moreover, we show that rather than having short telomeres as in yKu-deficient strains, the mlp1 mlp2 strains have extended telomeres, resembling phenotypes of mutations in rif1. Whereas the mlp1 mlp2 mutations act on a pathway of telomere length regulation different from that of yKu70, the effects of the tel1 deletion are epistatic to the mlp mutations, suggesting that the Mlp proteins restrict telomere length in wild-type cells by influencing the Rif-Tel1 pathway of telomerase regulation.

A dominant-negative MEC3 mutant uncovers new functions for the Rad17 complex and Tel1

The Rad17-Mec3-Ddc1 complex is essential for the cellular response to genotoxic agents and is thought to be important for sensing DNA lesions. Deletion of any of the RAD17, MEC3 or DDC1 genes abolishes the G(1) and G(2) and impairs the intra-S DNA-damage checkpoints. We characterize a dominant-negative mec3-dn mutation that has an unexpected phenotype. It inactivates the G(1) checkpoint while it leaves the G(2) response functional, thus revealing a difference in the requirements of the DNA-damage response in different phases of the cell cycle. In an attempt to identify the molecular defect imparted by the mutation, we dissected step-by-step the signaling cascade, which is triggered by DNA lesions and requires the activity of Mec1 and Rad53 kinases. The analysis of the phosphorylation state of checkpoint factors and critical protein interactions showed that, in mec3-dn cells, the signal transduction cascade is triggered normally, and the central kinase Mec1 can be activated. In G(1) cells expressing the mutation, the signaling cannot proceed any further along the pathway, indicating that the Rad17 complex acts after the activation of Mec1, possibly recruiting targets for the kinase. We also show that the function of the G(2) checkpoint in mutant cells is maintained by an uncharacterized activity of Tel1, the yeast homologue of ATM. This work thus reports a previously undiscovered role for Tel1 in checkpoint control.

Genomic instability, centrosome amplification, cell cycle checkpoints and Gadd45a

Genomic instability has been a recognized feature of many human tumors for decades. Until recently, however, there was little insight into potential mechanisms for this phenomenon. Recent work has shown first, that increased centrosome numbers (also referred to as centrosome amplification) often accompany genomic instability and second, that when centrosome numbers are increased, cells become genetically unstable. Deletion of Gadd45a leads to centrosome amplification and consequent abnormal mitosis and aneuploidy. Gadd45a is known to be involved in a G2 checkpoint and may be involved in the normal progression from G2 to M and its coordination with S phase events. Whether these functions contribute to prevention of centrosome amplification is being investigated. However, potential mechanisms can be proposed based on known protein associations with Gadd45a, as well as proteins that regulate Gadd45a transcription and are also required for efficient coordination of centrosome duplication and DNA synthesis.

MEC3, MEC1, and DDC2 are essential components of a telomere checkpoint pathway required for cell cycle arrest during senescence in Saccharomyces cerevisiae

When telomerase is absent and/or telomeres become critically short, cells undergo a progressive decline in viability termed senescence. The telomere checkpoint model predicts that cells will respond to a damaged or critically short telomere by transiently arresting and activating repair of the telomere. We examined the senescence of telomerase-deficient Saccharomyces cerevisiae at the cellular level to ask if the loss of telomerase activity triggers a checkpoint response. As telomerase-deficient mutants were serially subcultured, cells exhibited a progressive decline in average growth rate and an increase in the number of cells delayed in the G2/M stage of the cell cycle. MEC3, MEC1, and DDC2, genes important for the DNA damage checkpoint response, were required for the cell cycle delay in telomerase-deficient cells. In contrast, TEL1, RAD9, and RAD53, genes also required for the DNA damage checkpoint response, were not required for the G2/M delay in telomerase-deficient cells. We propose that the telomere checkpoint is distinct from the DNA damage checkpoint and requires a specific set of gene products to delay the cell cycle and presumably to activate telomerase and/or other telomere repair activities.

A quantitative assay for telomere protection in Saccharomyces cerevisiae

Telomeres are the protective ends of linear chromosomes. Telomeric components have been identified and described by their abilities to bind telomeric DNA, affect telomere repeat length, participate in telomeric DNA replication, or modulate transcriptional silencing of telomere-adjacent genes; however, their roles in chromosome end protection are not as well defined. We have developed a genetic, quantitative assay in Saccharomyces cerevisiae to measure whether various telomeric components protect chromosome ends from homologous recombination. This "chromosomal cap" assay has revealed that the telomeric end-binding proteins, Cdc13p and Ku, both protect the chromosome end from homologous recombination, as does the ATM-related kinase, Tel1p. We propose that Cdc13p and Ku structurally inhibit recombination at telomeres and that Tel1p regulates the chromosomal cap, acting through Cdc13p. Analysis with recombination mutants indicated that telomeric homologous recombination events proceeded by different mechanisms, depending on which capping component was compromised. Furthermore, we found that neither telomere repeat length nor telomeric silencing correlated with chromosomal capping efficiency. This capping assay provides a sensitive in vivo approach for identifying the components of chromosome ends and the mechanisms by which they are protected.

Regulation of genome stability by TEL1 and MEC1, yeast homologs of the mammalian ATM and ATR genes

In eukaryotes, a family of related protein kinases (the ATM family) is involved in regulating cellular responses to DNA damage and telomere length. In the yeast Saccharomyces cerevisiae, two members of this family, TEL1 and MEC1, have functionally redundant roles in both DNA damage repair and telomere length regulation. Strains with mutations in both genes are very sensitive to DNA damaging agents, have very short telomeres, and undergo cellular senescence. We find that strains with the double mutant genotype also have approximately 80-fold increased rates of mitotic recombination and chromosome loss. In addition, the tel1 mec1 strains have high rates of telomeric fusions, resulting in translocations, dicentrics, and circular chromosomes. Similar chromosome rearrangements have been detected in mammalian cells with mutations in ATM (related to TEL1) and ATR (related to MEC1) and in mammalian cells that approach cell crisis.