Set1-dependent H3K4 methylation becomes critical for limiting DNA damage in response to changes in S-phase dynamics in Saccharomyces cerevisiae.

DNA replication is a highly regulated process that occurs in the context of chromatin structure and is sensitive to several histone post-translational modifications. In Saccharomyces cerevisiae, the histone methylase Set1 is responsible for the transcription-dependent deposition of H3K4 methylation (H3K4me) throughout the genome. Here we show that a combination of a hypomorphic replication mutation (orc5-1) with the absence of Set1 (set1Δ) compromises the progression through S-phase, and this is associated with a large increase in DNA damage. The ensuing DNA damage checkpoint activation, in addition to that of the spindle assembly checkpoint, restricts the growth of orc5-1 set1Δ. The opposite effects of the lack of RNase H activity and the reduction of histone levels on orc5-1 set1Δ viability are in agreement with their expected effects on replication fork progression. We propose that the role of H3K4 methylation during DNA replication becomes critical when the replication forks acceleration due to decreased origin firing in the orc5-1 background increases the risk for transcription replication conflicts. Furthermore, we show that an increase of reactive oxygen species levels, likely a consequence of the elevated DNA damage, is partly responsible for the lethality in orc5-1 set1Δ.

MRX Increases Chromatin Accessibility at Stalled Replication Forks to Promote Nascent DNA Resection and Cohesin Loading.

The recovery of stalled replication forks depends on the controlled resection of nascent DNA and on the loading of cohesin. These processes operate in the context of nascent chromatin, but the impact of nucleosome structure on a fork restart remains poorly understood. Here, we show that the Mre11-Rad50-Xrs2 (MRX) complex acts together with the chromatin modifiers Gcn5 and Set1 and the histone remodelers RSC, Chd1, and Isw1 to promote chromatin remodeling at stalled forks. Increased chromatin accessibility facilitates the resection of nascent DNA by the Exo1 nuclease and the Sgs1 and Chl1 DNA helicases. Importantly, increased ssDNA promotes the recruitment of cohesin to arrested forks in a Scc2-Scc4-dependent manner. Altogether, these results indicate that MRX cooperates with chromatin modifiers to orchestrate the action of remodelers, nucleases, and DNA helicases, promoting the resection of nascent DNA and the loading of cohesin, two key processes involved in the recovery of arrested forks.

Spatially distinct functions of Clb2 in the DNA damage response.

In budding yeast four mitotic cyclins (Clb1-4) cooperate in a partially redundant manner to bring about M-phase specific events, including the apical isotropic switch that ends polarized bud growth initiated at bud emergence. How exactly this morphogenetic transition is regulated by mitotic CDKs remains poorly understood. We have taken advantage of the isotropic bud growth that prevails in cells responding to DNA damage to unravel the contribution of mitotic cyclins in this cellular context. We find that clb2∆, in contrast to the other mitotic cyclin mutants, inappropriately respond to the presence of DNA damage. This aberrant response is characterized by a Cdc42- and Bni1-dependent but Cln-independent resumption of polarized bud growth after a brief period of actin depolarization. Biochemical and genetic evidence is presented that formally excludes the possibility of indirect effects due for instance to unrestrained APC activity, untimely mitotic exit or Swe1-mediated CDK inhibition. Importantly, our data demonstrate that in order to maintain the characteristic dumbbell arrest phenotype upon checkpoint activation Clb2 needs to be efficiently exported into the cytoplasm. We propose that the inhibition of mitotic cyclin destruction by the DNA damage checkpoint pathway leads to a buildup of Clb2 in the cytoplasm where this cyclin can stabilize the apical isotropic switch throughout a G 2/M checkpoint arrest. Our study also unveils an essential role of nuclear Clb2 in both survival and adaptation to the DNA damage checkpoint, illustrating a spatially distinct dual function of this mitotic cyclin in the response to DNA damage.

Spp1 at the crossroads of H3K4me3 regulation and meiotic recombination.

In Saccharomyces cerevisiae, all H3K4 methylation is performed by a single Set1 Complex (Set1C) that is composed of the catalytic (Set1) and seven other subunits (Swd1, Swd2, Swd3, Bre2, Sdc1, Spp1 and Shg1). It has been known for quite some time that trimethylated H3K4 (H3K4me3) is enriched in the vicinity of meiotic double-strand breaks (DSBs), but the link between H3K4me3 and the meiotic nuclease Spo11 was uncovered only recently. The PHD-containing subunit Spp1, by interacting with H3K4me3 and Mer2, was shown to promote the recruitment of potential meiotic DSB sites to the chromosomal axis allowing their subsequent cleavage by Spo11. Therefore, Spp1 emerged as a key regulator of the H3K4 trimethylation catalyzed by Set1C and of the formation of meiotic DSBs. These findings illustrate the remarkable multifunctionality of Spp1, which not only regulates the catalytic activity of the enzyme (Set1), but also interacts with the deposited mark, and mediates its biological effect (meiotic DSB formation) independently of the complex. As it was previously described for Swd2, and now for Spp1, we anticipate that other Set1C subunits, in addition to regulating H3K4 methylation, may participate in diverse biological functions inside or outside of the complex.

The COMPASS subunit Spp1 links histone methylation to initiation of meiotic recombination.

During meiosis, combinatorial associations of genetic traits arise from homologous recombination between parental chromosomes. Histone H3 lysine 4 trimethylation marks meiotic recombination hotspots in yeast and mammals, but how this ubiquitous chromatin modification relates to the initiation of double-strand breaks (DSBs) dependent on Spo11 remains unknown. Here, we show that the tethering of a PHD-containing protein, Spp1 (a component of the COMPASS complex), to recombinationally cold regions is sufficient to induce DSB formation. Furthermore, we found that Spp1 physically interacts with Mer2, a key protein of the differentiated chromosomal axis required for DSB formation. Thus, by interacting with H3K4me3 and Mer2, Spp1 promotes recruitment of potential meiotic DSB sites to the chromosomal axis, allowing Spo11 cleavage at nearby nucleosome-depleted regions.

Alternative ends: telomeres and meiosis.

Meiosis is a specialized type of cell division that halves the diploid number of chromosomes, yielding four haploid nuclei. Dramatic changes in chromosomal organization occur within the nucleus at the beginning of meiosis which are followed by the separation of homologous chromosomes at the first meiotic division. This is the case for telomeres that display a meiotic-specific behavior with gathering in a limited sector of the nuclear periphery. This leads to a characteristic polarized chromosomal configuration, called the "bouquet" arrangement. The widespread phenomenon of bouquet formation among eukaryotes has led to the hypothesis that it is functionally linked to the process of interactions between homologous chromosomes that are a unique feature of meiosis and are essential for proper chromosome segregation. Various studies in different model organisms have questioned the role of the telomere bouquet in chromosome pairing and recombination, and very recently in meiotic spindle formation, and have provided some clues about the molecular mechanisms that carry out this specific clustering of telomeres.

Set1- and Clb5-deficiencies disclose the differential regulation of centromere and telomere dynamics in Saccharomyces cerevisiae meiosis.

The entry into meiosis is characterized by a lengthy premeiotic S phase and a reorganization of the nuclear architecture. Analysis of centromere and telomere dynamics in wild-type Saccharomyces cerevisiae meiosis suggests that resolution of vegetative centromere and telomere clusters are independent events differently connected to premeiotic S phase. Absence of the B-type cyclin Clb5 or the Set1 histone methyltransferase leads to a delay of premeiotic S phase by separate mechanisms. In clb5Delta cells, centromere cluster resolution appears normal, whereas dissolution of the vegetative telomere clusters is impaired and meiosis-specific clustering of telomeres, i.e. bouquet formation, is grossly delayed. In set1Delta cells, centromere and telomere redistribution are both impaired and bouquet nuclei are absent, despite proper location of the meiosis-specific telomere protein Ndj1. Thus, centromere and telomere redistribution at the onset of prophase I is differentially regulated, with centromere dispersion occurring independently of premeiotic S phase. The normal kinetics of dissolution of the vegetative telomere clusters in a set1Delta mec1-1 mutant suggests the presence of a checkpoint that limits the dispersion of telomeres in absence of Set1.

Tails and cuts: the role of histone post-translational modifications in the formation of programmed double-strand breaks.

In eukaryotic organisms, various DNA recombination mechanisms have been described that are an integral part of nuclear differentiation processes. In several places, the recombination is initiated by one or more double-strand breaks that result from the action of specific endonucleolytic activities. The importance of chromatin in controlling susceptibility of DNA to various DNA transactions has been recognized for long. Recent literature links post-transcriptional modifications of the amino-terminal part of histones (the tails) to the formation of developmentally regulated DNA double-strand break (the cuts). In this review, I compare the existing data in three different DNA rearrangement-based processes, i.e., genetic recombination associated to meiosis, lymphoid-specific V(D)J recombination and excision of DNA fragments in the nucleus of ciliates. Inspired by some of the concepts established in the field of transcription, models are proposed for molecular mechanisms that sustain the epigenetic control of programmed double-strand break formation.

Set1 is required for meiotic S-phase onset, double-strand break formation and middle gene expression.

The Set1 protein of Saccharomyces cerevisiae is a histone methyltransferase (HMTase) acting on lysine 4 of histone H3. Inactivation of the SET1 gene in a diploid leads to a sporulation defect. We have studied various processes that take place during meiotic differentiation in set1delta diploid cells. The absence of Set1 leads to a delay of meiotic S-phase onset, which reflects a defect in DNA replication initiation. The timely induction of meiotic DNA replication does not require the Set1 HMTase activity, but depends on the SET domain. In addition, set1delta displays a severe impairment of the DNA double-strand break formation, which is not only the consequence of the replication delay. Transcriptional profiling experiments show that the induction of middle meiotic genes, but not of early meiotic genes, is affected by the loss of Set1. In contrast to meiotic replication, the transcriptional induction of the middle meiotic genes appears to depend on the methylation of H3-K4. Our results unveil multiple roles of Set1 in meiotic differentiation and distinguish between HMTase-dependent and -independent Set1 functions.