A POLD3/BLM dependent pathway handles DSBs in transcribed chromatin upon excessive RNA:DNA hybrid accumulation.

Transcriptionally active loci are particularly prone to breakage and mounting evidence suggests that DNA Double-Strand Breaks arising in active genes are handled by a dedicated repair pathway, Transcription-Coupled DSB Repair (TC-DSBR), that entails R-loop accumulation and dissolution. Here, we uncover a function for the Bloom RecQ DNA helicase (BLM) in TC-DSBR in human cells. BLM is recruited in a transcription dependent-manner at DSBs where it fosters resection, RAD51 binding and accurate Homologous Recombination repair. However, in an R-loop dissolution-deficient background, we find that BLM promotes cell death. We report that upon excessive RNA:DNA hybrid accumulation, DNA synthesis is enhanced at DSBs, in a manner that depends on BLM and POLD3. Altogether our work unveils a role for BLM at DSBs in active chromatin, and highlights the toxic potential of RNA:DNA hybrids that accumulate at transcription-associated DSBs.

Direct coupling between meiotic DNA replication and recombination initiation.

During meiosis in Saccharomyces cerevisiae, DNA replication occurs 1. 5 to 2 hours before recombination initiates by DNA double-strand break formation. We show that replication and recombination initiation are directly linked. Blocking meiotic replication prevented double-strand break formation in a replication-checkpoint-independent manner, and delaying replication of a chromosome segment specifically delayed break formation in that segment. Consequently, the time between replication and break formation was held constant in all regions. We suggest that double-strand break formation occurs as part of a process initiated by DNA replication, which thus determines when meiotic recombination initiates on a regional rather than a cell-wide basis.

Use of a recombination reporter insert to define meiotic recombination domains on chromosome III of Saccharomyces cerevisiae.

In Saccharomyces cerevisiae, meiotic recombination is initiated by DNA double-strand breaks (DSBs). DSBs usually occur in intergenic regions that display nuclease hypersensitivity in digests of chromatin. DSBs are distributed nonuniformly across chromosomes; on chromosome III, DSBs are concentrated in two "hot" regions, one in each chromosome arm. DSBs occur rarely in regions within about 40 kb of each telomere and in an 80-kb region in the center of the chromosome, just to the right of the centromere. We used recombination reporter inserts containing arg4 mutant alleles to show that the "cold" properties of the central DSB-deficient region are imposed on DNA inserted in the region. Cold region inserts display DSB and recombination frequencies that are substantially less than those seen with similar inserts in flanking hot regions. This occurs without apparent change in chromatin structure, as the same pattern and level of DNase I hypersensitivity is seen in chromatin of hot and cold region inserts. These data are consistent with the suggestion that features of higher-order chromosome structure or chromosome dynamics act in a target sequence-independent manner to control where recombination events initiate during meiosis.

DNA topoisomerase II sites in the histone H4 gene during the highly synchronous cell cycle of Physarum polycephalum.

The nearly perfect synchrony of nuclear division in a plasmodium of Physarum polycephalum provides a powerful system to analyze topoisomerase II cleavage sites in the course of the cell cycle. The histone H4 locus, whose schedule of replication and transcription is precisely known, was chosen for this analysis. Drug-induced topoisomerase II sites are clustered downstream of the histone H4 gene and appear highly dependent on cell cycle stage. They were only detected in mitosis and at the very beginning of S phase, precisely at the time of replication of the histone H4 region. The sites, which were absent in G2 phase, reappeared at the next mitosis. Remarkably, DNase I hypersensitive sites occurred in nearly the same location, but their schedule was totally different: they were absent in mitosis and present in G2. This schedule follows H4 transcription, which peaks in mid-S phase and in the second part of G2 phase and is off during mitosis. These results suggest that topoisomerase II may not be involved in transcription, but plays a role in remodeling chromatin structure, both during chromosome condensation in prophase/metaphase to allow their decatenation and during chromosome decondensation after metaphase to allow replication fork passage throughout the region.

The mapping of DNA topoisomerase sites in vivo: a tool to enlight the functions of topoisomerases.

The possibility to record a trace of the precise sites of topoisomerase action has been exploited for almost 12 years in many laboratories. The large majority of the studies were performed in vitro, giving a good picture of sequence specificities of topoisomerases, and of the preference of various drugs for some sequences. Only a relatively small number of reports concern in vivo studies. Their main conclusions are the following: i) topoisomerase II sites are often found near replication origins and termini, where they are supposed to play a role in the decatenation of daughter DNA molecules, and possibly in the initiation of replication; ii) topoisomerase II sites are found in the promoter region of many genes, but they seem related to the condensation state of chromatin in this region, rather than to transcription per se; iii) some topoisomerase II sites, resistant to high salt, are found in or near matrix associated regions (MARs), suggesting a role in loop anchorage or (and) in the control of topology of individual chromatin loops; iv) topoisomerase I sites appear less localized, acting all along the transcription units, where they seem directly involved in transcription; and v) topoisomerase I sites are possibly connected with replication fork progression and (or) with the termination of replication. Despite these advances, the precise role of topoisomerases in vivo is still poorly understood, especially in recombination and chromatin condensation and decondensation during the cell cycle. Future attempts should take into account the possible specialization of the multiple topoisomerases found in a given cell, and the use of highly synchronized systems.

In vivo topoisomerase II cleavage sites in the ribosomal DNA of Physarum polycephalum.

We have analyzed the topoisomerase II cleavage sites in the extrachromosomal ribosomal DNA of the lower eukaryote Physarum polycephalum using the topoisomerase II-specific inhibitor, 6,8-difluoro-7-(4-hydroxyphenyl)-1-cyclopropyl-4-quinolone-3-carboxylic acid. Most of the in vivo topoisomerase II cleavage sites were found either in the transcribed region of ribosomal DNA or in the palindromic region surrounded by the replication origins. Two classes of sites were identified: those which correlate with DNase I hypersensitive sites and corresponding to an open chromatin configuration (transcribed region) and internucleosomal cleavage sites (in the region of replication origins). Topoisomerase II drug-induced cleavage in the ribosomal DNA was considerably reduced upon Physarum differentiation to a dormant stage of life, the spherules. In contrast, the amount of drug-dependent cleavage was found to increase during the metaphase of mitosis, when rDNA transcription is shut off. These findings suggest a role for topoisomerase II in the ribosomal DNA minichromosomes segregation, in addition to its role in transcription. Finally, the similarity between in vivo sites and those observed following drug treatment of isolated nuclei indicates that no profound change occurs in rDNA chromatin conformation during nuclei isolation. By contrast, in vitro cleavage sites with purified topoisomerase II weakly correlate to in vivo, indicating a prominent role for chromatin structure in determining the interaction sites of topoisomerase II with DNA in vivo.