Cohesin protects genes against γH2AX Induced by DNA double-strand breaks.

Chromatin undergoes major remodeling around DNA double-strand breaks (DSB) to promote repair and DNA damage response (DDR) activation. We recently reported a high-resolution map of γH2AX around multiple breaks on the human genome, using a new cell-based DSB inducible system. In an attempt to further characterize the chromatin landscape induced around DSBs, we now report the profile of SMC3, a subunit of the cohesin complex, previously characterized as required for repair by homologous recombination. We found that recruitment of cohesin is moderate and restricted to the immediate vicinity of DSBs in human cells. In addition, we show that cohesin controls γH2AX distribution within domains. Indeed, as we reported previously for transcription, cohesin binding antagonizes γH2AX spreading. Remarkably, depletion of cohesin leads to an increase of γH2AX at cohesin-bound genes, associated with a decrease in their expression level after DSB induction. We propose that, in agreement with their function in chromosome architecture, cohesin could also help to isolate active genes from some chromatin remodelling and modifications such as the ones that occur when a DSB is detected on the genome.

Deciphering the chromatin landscape induced around DNA double strand breaks.

DNA double strand breaks (DSBs) are among the most deleterious forms of lesions and deciphering the details of the chromatin landscape induced around DSBs represents a great challenge for molecular biologists. Chromatin Immunoprecipitation, followed by microarray hybridisation (ChIP-chip) or high-throughput sequencing (ChIP-seq), are powerful techniques that provide high-resolution maps of protein-genome interactions. However, applying these techniques to study chromatin changes induced around DSBs was previously hindered due to a lack of suitable DSB induction techniques. We have recently developed an experimental system utilizing a restriction enzyme fused to a modified oestrogen receptor ligand binding domain (AsiSI-ER), which generates multiple, sequence-specific and unambiguously positioned DSBs across the genome upon induction with 4-hydroxytamoxifen (4OHT).(1) Cell lines expressing this construct represent a powerful tool to study specific chromatin changes during DSB repair, enabling high-resolution profiling of DNA repair complexes and chromatin modifications induced around DSBs. Using this system, we have recently produced the first map of gammaH2AX, a DSB-induced chromatin modification, on two human chromosomes and have investigated its spreading properties.(1) Here we provide additional data characterizing the cell lines, present a genome-wide profile of gammaH2AX obtained by ChIP-seq, and discuss the potential of our system towards investigations of previously uncharacterized aspects of DSB repair.

Ascorbate improves metabolic abnormalities in Wrn mutant mice but not the free radical scavenger catechin.

Werner syndrome (WS) is a premature aging disorder caused by mutations in a RecQ-like DNA helicase. Mice lacking the helicase domain of the WRN homologue exhibit many phenotypic features of WS. Importantly, mutant Wrn(Deltahel/Deltahel) mice show abnormal increases in visceral fat deposition and fasting blood triglyceride levels followed by insulin resistance and high blood glucose levels. These mice also exhibit increased heart and liver tissue reactive oxygen species concomitantly with oxidative DNA damage, indicating a pro-oxidant status. We treated mice with either ascorbate or catechin hydrate for 9 months. Vitamin C supplementation reduced oxidative stress in liver and heart tissues and reversed hypertriglyceridemia, hyperglycemia, and insulin resistance and reduced fat weight in mutant Wrn(Deltahel/Deltahel) mice. Although the free scavenger catechin hydrate also reduced oxidative DNA damage in heart and liver tissues, it did not reverse any of the metabolic phenotype aspects in treated mutant mice. Finally, vitamin C and catechin hydrate did not affect the metabolic status of wild-type mice. These results indicate that vitamin C supplementation could be beneficial for WS patients.

High-resolution profiling of gammaH2AX around DNA double strand breaks in the mammalian genome.

Chromatin acts as a key regulator of DNA-related processes such as DNA damage repair. Although ChIP-chip is a powerful technique to provide high-resolution maps of protein-genome interactions, its use to study DNA double strand break (DSB) repair has been hindered by the limitations of the available damage induction methods. We have developed a human cell line that permits induction of multiple DSBs randomly distributed and unambiguously positioned within the genome. Using this system, we have generated the first genome-wide mapping of gammaH2AX around DSBs. We found that all DSBs trigger large gammaH2AX domains, which spread out from the DSB in a bidirectional, discontinuous and not necessarily symmetrical manner. The distribution of gammaH2AX within domains is influenced by gene transcription, as parallel mappings of RNA Polymerase II and strand-specific expression showed that gammaH2AX does not propagate on active genes. In addition, we showed that transcription is accurately maintained within gammaH2AX domains, indicating that mechanisms may exist to protect gene transcription from gammaH2AX spreading and from the chromatin rearrangements induced by DSBs.

Werner's syndrome helicase participates in transcription of phenobarbital-inducible CYP2B genes in rat and mouse liver.

Werner's syndrome (WS) is a rare human autosomal recessive segmental progeroid syndrome clinically characterized by atherosclerosis, cancer, osteoporosis, type 2 diabetes mellitus and ocular cataracts. The WRN gene codes for a RecQ helicase which is present in many tissues. Although the exact functions of the WRN protein remain unclear, accumulating evidence suggests that it participates in DNA repair, replication, recombination and telomere maintenance. It has also been proposed that WRN participates in RNA polymerase II-dependent transcription. However no promoter directly targeted by WRN has yet been identified. In this work, we report mammalian genes that are WRN targets. The rat CYP2B2 gene and its closely related mouse homolog, Cyp2b10, are both strongly induced in liver by phenobarbital. We found that there is phenobarbital-dependent recruitment of WRN to the promoter of the CYP2B2 gene as demonstrated by chromatin immunoprecipitation analysis. Mice homozygous for a Wrn mutation deleting part of the helicase domain showed a decrease in basal and phenobarbital-induced CYP2B10 mRNA levels compared to wild type animals. The phenobarbital-induced level of CYP2B10 protein was also reduced in the mutant mice. Electrophoretic mobility shift assays showed that WRN can participate in the formation of a complex with a specific sequence within the CYP2B2 basal promoter. Hence, there is a WRN binding site in a region of DNA sequence to which WRN is recruited in vivo. Taken together, these results suggest that WRN participates in transcription of CYP2B genes in liver and identifies the first physical interaction between a specific promoter sequence and WRN.

Vitamin C restores healthy aging in a mouse model for Werner syndrome.

Werner syndrome (WS) is a premature aging disorder caused by mutations in a RecQ-like DNA helicase. Mice lacking the helicase domain of the WRN homologue exhibit many phenotypic features of WS, including a prooxidant status and a shorter mean life span compared to wild-type animals. Here, we show that Wrn mutant mice also develop premature liver sinusoidal endothelial defenestration along with inflammation and metabolic syndrome. Vitamin C supplementation rescued the shorter mean life span of Wrn mutant mice and reversed several age-related abnormalities in adipose tissues and liver endothelial defenestration, genomic integrity, and inflammatory status. At the molecular level, phosphorylation of age-related stress markers like Akt kinase-specific substrates and the transcription factor NF-kappaB, as well as protein kinase Cdelta and Hif-1alpha transcription factor levels, which are increased in the liver of Wrn mutants, were normalized by vitamin C. Vitamin C also increased the transcriptional regulator of lipid metabolism PPARalpha. Finally, microarray and gene set enrichment analyses on liver tissues revealed that vitamin C decreased genes normally up-regulated in human WS fibroblasts and cancers, and it increased genes involved in tissue injury response and adipocyte dedifferentiation in obese mice. Vitamin C did not have such effect on wild-type mice. These results indicate that vitamin C supplementation could be beneficial for patients with WS.

Werner syndrome protein prevents DNA breaks upon chromatin structure alteration.

Werner syndrome is a rare disorder characterized by genome instability and the premature onset of several pathologies associated with aging. The gene responsible for Werner syndrome codes for a RecQ-type DNA helicase and is believed to be involved in different aspects of DNA repair, replication, and transcription. The human Werner protein (WRN) translocates from nucleoli to the nucleoplasm upon DNA damage. Here, for the first time we show WRN translocation following treatment with chloroquine (CHL) or trichostatin A (TSA), agents that alter chromatin structure without producing DNA breaks. In contrast to normal cells, WRN deficient human and murine cells incurred extensive DNA breaks upon CHL or TSA treatment, indicating a functional role for WRN in the proper response to these agents. Cells deficient for another RecQ-type helicase, Bloom syndrome, were not sensitive to these agents. WRN is known from in vitro studies to bind and stimulate the activity of topoisomerase I (Topol). CHL enhanced the association between WRN and Topol, suggesting that topological stress elicits a requirement for the stimulation of Topol by WRN. Supporting this idea, overexpression of Topol reduced CHL and TSA-induced DNA breaks in WRN null cells. We thus describe a novel function for WRN in ensuring genome stability to act in concert with Topol to prevent DNA breaks, following alterations in chromatin topology.

Expression of Hoxa2 in cells entering chondrogenesis impairs overall cartilage development.

Vertebrate Hox genes act as developmental architects by patterning embryonic structures like axial skeletal elements, limbs, brainstem territories, or neural crest derivatives. While active during the patterning steps of development, these genes turn out to be down-regulated in specific differentiation programs like that leading to chondrogenesis. To investigate why chondrocyte differentiation is correlated to the silencing of a Hox gene, we generated transgenic mice allowing Cre-mediated conditional misexpression of Hoxa2 and induced this gene in Collagen 2 alpha 1-expressing cells committed to enter chondrogenesis. Persistent Hoxa2 expression in chondrogenic cells resulted in overall chondrodysplasia with delayed cartilage hypertrophy, mineralization, and ossification but without proliferation defects. The absence of skeletal patterning anomaly and the regular migration of precursor cells indicated that the condensation step of chondrogenesis was normal. In contrast, closer examination at the differentiation step showed severely impaired chondrocyte differentiation. In addition, this inhibition affected structures independently of their embryonic origin. In conclusion, for the first time here, by a cell-type specific misexpression, we precisely uncoupled the patterning function of Hoxa2 from its involvement in regulating differentiation programs per se and demonstrate that Hoxa2 displays an anti-chondrogenic activity that is distinct from its patterning function.

Formation of a nuclear complex containing the p53 tumor suppressor, YB-1, and the Werner syndrome gene product in cells treated with UV light.

YB-1 is a multifunctional protein involved in the regulation of transcription, translation, and mRNA splicing. In recent years, several laboratories have demonstrated that YB-1 is also directly involved in the cellular response to genotoxic stress. Accordingly, one report has indicated that the Werner syndrome gene product (WRN) is eluted from an YB-1 affinity chromatography column. Werner syndrome is a rare disorder characterized by the premature onset of a number of age-related diseases, including cancer. The gene responsible for Werner syndrome encodes a DNA helicase/exonuclease protein believed to be involved in some aspect of DNA repair with p53. In this study, we demonstrate that the tumor suppressor, p53, bridges the WRN and YB-1 proteins in vitro. Microscopic analyses of fluorescent-tagged proteins and co-immunoprecipitation experiments confirmed the formation of an YB-1/p53/WRN complex in human cells, but only after treatment with UV light. We also confirmed that p53 is a major player in the translocation of GFP-YB-1 fusion proteins from the cytoplasm to several nuclear foci containing WRN proteins upon UV irradiation. Such translocation did not occur in cells treated with the topoisomerase inhibitor, etoposide, or the radiomimetic drug, bleomycin. Such results suggest that an YB-1/p53/WRN complex is formed in response to the emergence of specific DNA lesions in cells.

Increased insulin, triglycerides, reactive oxygen species, and cardiac fibrosis in mice with a mutation in the helicase domain of the Werner syndrome gene homologue.

Werner Syndrome (WS) is a rare disorder characterized by the premature onset of a number of age-related diseases. The gene responsible for WS encodes a DNA helicase/exonuclease protein. Previously, we generated a mouse model lacking part of the helicase domain of the murine Wrn homologue. Mutant WrnDeltahel/Deltahel mice developed severe cardiac interstitial fibrosis in addition to tumors. Further analyses of these mice on the pure C57Bl/6 genetic background revealed abnormal increases in visceral fat deposition, fasting blood triglyceride and cholesterol levels followed by insulin resistance and high blood glucose levels. These phenotypes were more severe in mutant females than mutant males. In addition, adult mice had clear hemodynamic signs of aortic stenosis. All these symptoms appeared before the onset of cardiomyopathy and are known to cause heart failure. Interestingly, WrnDeltahel/Deltahel adult mice (but not juveniles) showed higher levels of serum and cardiac tissue reactive oxygen species followed in time by an increase in cardiac oxidative DNA damage, all this prior to cardiac fibrosis.

In vivo misregulation of genes involved in apoptosis, development and oxidative stress in mice lacking both functional Werner syndrome protein and poly(ADP-ribose) polymerase-1.

Werner syndrome (WS) is a rare disorder characterized by the premature onset of a number of age-related diseases. The gene responsible for WS is believed to be involved in different aspects of transcription, replication and/or DNA repair. The poly(ADP-ribose) polymerase-1 (PARP-1) enzyme is also involved in DNA repair and is known to affect transcription of several genes. In this study, we examined the expression profile of cells lacking the normal function of either or both enzymes. All mutant cells exhibited altered expression of genes normally responding to oxidative stress. Interestingly, more than 58% of misregulated genes identified in double mutant cells were not altered in cells with either the Wrn or PARP-1 mutation alone. So, the impact on gene expression profile when both Wrn and PARP-1 are mutated was greater than a simple addition of individual mutant genotype. In addition, double mutant cultured cells showed major misregulation of genes involved in apoptosis, cell cycle control, embryonic development, metabolism and signal transduction. More importantly, in vivo analyses of double mutant mice have confirmed the increased apoptosis and the developmental defects in embryos as well as the major increase in intracellular phosphorylation and oxidative DNA damage in adult tissues. They also exhibited a progressive increase in oxidative stress with age. Thus, a major result of this study is that changes in expression of several genes and physiological functions identified in vitro were confirmed in mouse embryonic and adult tissues.