Lisa Wiesmüller

JAK2 stimulates homologous recombination and genetic instability: potential implication in the heterogeneity of myeloproliferative disorders.

The JAK2(V617F) mutation is frequently observed in classical myeloproliferative disorders, and disease progression is associated with a biallelic acquisition of the mutation occurring by mitotic recombination. In this study, we examined whether JAK2 activation could lead to increased homologous recombination (HR) and genetic instability. In a Ba/F3 cell line expressing the erythropoietin (EPO) receptor, mutant JAK2(V617F) and, to a lesser extent, wild-type (wt) JAK2 induced an increase in HR activity in the presence of EPO without modifying nonhomologous end-joining efficiency. Moreover, a marked augmentation in HR activity was found in CD34(+)-derived cells isolated from patients with polycythemia vera or primitive myelofibrosis compared with control samples. This increase was associated with a spontaneous RAD51 foci formation. As a result, sister chromatid exchange was 50% augmented in JAK2(V617F) Ba/F3 cells compared with JAK2wt cells. Moreover, JAK2 activation increased centrosome and ploidy abnormalities. Finally, in JAK2(V617F) Ba/F3 cells, we found a 100-fold and 10-fold increase in mutagenesis at the HPRT and Na/K ATPase loci, respectively. Together, this work highlights a new molecular mechanism for HR regulation mediated by JAK2 and more efficiently by JAK2(V617F). Our study might provide some keys to understand how a single mutation can give rise to different pathologies.

DNA substrate dependence of p53-mediated regulation of double-strand break repair

ABSTRACT DNA double-strand breaks (DSBs) arise spontaneously after the conversion of DNA adducts or single-strand breaks by DNA repair or replication and can be introduced experimentally by expression of specific endonucleases. Correct repair of DSBs is central to the maintenance of genomic integrity in mammalian cells, since errors give rise to translocations, deletions, duplications, and expansions, which accelerate the multistep process of tumor progression. For p53 direct regulatory roles in homologous recombination (HR) and in non-homologous end joining (NHEJ) were postulated. To systematically analyze the involvement of p53 in DSB repair, we generated a fluorescence-based assay system with a series of episomal and chromosomally integrated substrates for I-SceI meganuclease-triggered repair. Our data indicate that human wild-type p53, produced either stably or transiently in a p53-negative background, inhibits HR between substrates for conservative HR (cHR) and for gene deletions. NHEJ via microhomologies flanking the I-SceI cleavage site was also downregulated after p53 expression. Interestingly, the p53-dependent downregulation of homology-directed repair was maximal during cHR between sequences with short homologies. Inhibition was minimal during recombination between substrates that support reporter gene reconstitution by HR and NHEJ. p53 with a hotspot mutation at codon 281, 273, 248, 175, or 143 was severely defective in regulating DSB repair (frequencies elevated up to 26-fold). For the transcriptional transactivation-inactive variant p53(138V) a defect became apparent with short homologies only. These results suggest that p53 plays a role in restraining DNA exchange between imperfectly homologous sequences and thereby in suppressing tumorigenic genome rearrangements.

The cyclin A1-CDK2 complex regulates DNA double-strand break repair.

ABSTRACT Vertebrates express two A-type cyclins; both associate with and activate the CDK2 protein kinase. Cyclin A1 is required in the male germ line, but its molecular functions are incompletely understood. We observed specific induction of cyclin A1 expression and promoter activity after UV and γ-irradiation which was mediated by p53. cyclin A1−/− cells showed increased radiosensitivity. To unravel a potential role of cyclin A1 in DNA repair, we performed a yeast triple hybrid screen and identified the Ku70 DNA repair protein as a binding partner and substrate of the cyclin A1-CDK2 complex. DNA double-strand break (DSB) repair was deficient in cyclin A1−/− cells. Further experiments indicated that A-type cyclins activate DNA DSB repair by mechanisms that depend on CDK2 activity and Ku proteins. Both cyclin A1 and cyclin A2 enhanced DSB repair by homologous recombination, but only cyclin A1 significantly activated nonhomologous end joining. DNA DSB repair was specific for A-type cyclins because cyclin E was ineffective. These findings establish a novel function for cyclin A1 and CDK2 in DNA DSB repair following radiation damage.

Dissociation of the recombination control and the sequence-specific transactivation function of P53

Recently, we described a new biological function of p53 in inhibiting recombination processes when encountering mismatches in heteroduplexes (Dudenhöffer et al., 1998). Here, we characterized protein domains of p53 participating in this process by in vitro analysis of mutated p53 proteins, and by applying our SV40-based assay system on monkey cells, which express different p53 variants. We present evidence that both binding of artificial recombination intermediates and p53-dependent recombination control require an intact p53 core and the oligomerization domain, strongly suggesting that the recognition of DNA undergoing recombination represents an essential step of this genomic surveillance mechanism. Further analyses indicated a role of the C-terminus in negatively regulating recombination control, an effect which can be neutralized by concurrent mismatch recognition. p53 lacking the oligomerization domain totally lost its ability to suppress homologous recombination. The cancer-related mutant p53(273H) was also significantly defective in this function, although we observed only twofold reductions in the corresponding transactivation activities on p53-response elements in episomal constructs. HDM2, an inhibitor of p53s transcriptional and growth regulatory activities, interfered with the inhibition of DNA exchange processes by p53 only weakly. Thus, functions of p53 in recombination control can be structurally dissociated from p53-dependent transcriptional transactivation.

Take a break—resveratrol in action on DNA

The phytochemical resveratrol (RV) has become a focus of intense research owing to its roles in promoting longevity and in cancer prevention. As an anticancer agent, RV has primarily been linked to growth and death regulatory pathways. There is now growing evidence that, under physiological conditions, RV additionally contributes to the maintenance of genome stability. Thus, at the stage of DNA damage formation, RV protects the genome as an antioxidant via inhibition of inflammation, suppression of metabolic carcinogen activation, de novo expression of genes that encode detoxifying proteins and possibly even via radical scavenging properties. However, results demonstrating RV-dependent DNA breakage in the presence of Cu(II) ions and inhibition of DNA polymerases alpha and delta produced some controversy regarding RVs role as a caretaker compound. Significantly, recent studies have revealed that activation of ataxia telangiectasia mutated and ataxia telangiectasia Rad3 related could be a central effect of RV that underlies cell-cycle regulation and the newly described activation of fidelity control mechanisms in DNA double-strand break repair involving Nbs1 and p53. In this review, we discuss the existing data on RVs direct and indirect effects on genome integrity, in the light of future chemopreventive and chemotherapeutic protocols involving RV or related compounds.

Role of heteroduplex joints in the functional interactions between human Rad51 and wild-type p53

Our previous work (Dudenhöffer et al., 1999) unveiled a link between the capacity of p53 to regulate homologous recombination processes and to specifically bind to heteroduplex junction DNAs. Here, we show that p53 participates in ternary complex formation after preassembly of nucleoproteins, consisting of the human recombinase hRad51 and junction DNA. The cancer-related mutant p53(273H), which is defective in inhibiting recombination processes, displays a reduced capacity to associate with hRad51-DNA complexes, even under conditions which support DNA-binding. This suggests that hRad51-p53 contacts play a role in targeting p53 to heteroduplex joints and indicates an involvement in recombination immediately following hRad51-mediated strand transfer. To study the initial phase of strand exchange, when heteroduplex joints arise, we applied oligonucleotide based strand transfer assays. We observed that hRad51 stimulates exonucleolytic DNA degradation by p53, when it generates strand transfer intermediates. In agreement with this observation, artificial 3-stranded junction DNAs, designed to mimic nascent recombination intermediates, were found to represent preferred exonuclease substrates, especially when comprising a mismatch within the heteroduplex part. From our data, we propose a model according to which, p53-dependent correction of DNA exchange events is triggered by high-affinity binding to joint molecules and by stabilizing contacts with hRad51 oligomers.

Role of SIRT1 in homologous recombination.

The class III histone deacetylase (HDAC) SIRT1 plays a role in the metabolism, aging, and carcinogenesis of organisms and regulates senescence and apoptosis in cells. Recent reports revealed that SIRT1 also deacetylates several DNA double-strand break (DSB) repair proteins. However, its exact functions in DNA repair remained elusive. Using nuclear foci analysis and fluorescence-based, chromosomal DSB repair reporter, we find that SIRT1 activity promotes homologous recombination (HR) in human cells. Importantly, this effect is unrelated to functions of poly(ADP-ribose) polymerase 1 (PARP1), another NAD(+)-catabolic protein, and does not correlate with cell cycle changes or apoptosis. Interestingly, we demonstrate that inactivation of Rad51 does not eliminate the effect of SIRT1 on HR. By epistasis-like analysis through knockdown and use of mutant cells of distinct SIRT1 target proteins, we show that the non-homologous end joining (NHEJ) factor Ku70 as well as the Nijmegen Breakage Syndrome protein (nibrin) are not needed for this SIRT1-mediated effect, even though a partial contribution of nibrin cannot be excluded. Strikingly however, the Werner helicase (WRN), which in its mutated form causes premature aging and cancer and which was linked to the Rad51-independent single-strand annealing (SSA) DSB repair pathway, is required for SIRT1-mediated HR. These results provide first evidence that links SIRT1s functions to HR with possible implications for genomic stability during aging and tumorigenesis.

Identification of a novel pro‐apopotic function of NF‐κB in the DNA damage response

NF‐κB is activated by DNA‐damaging anticancer drugs as part of the cellular stress response. However, the consequences of drug‐induced NF‐κB activation are still only partly understood. To investigate the impact of NF‐κB on the cell’s response to DNA damage, we engineered glioblastoma cells that stably express mutant IκBα superrepressor (IκBα‐SR) to block NF‐κB activation. Here, we identify a novel pro‐apoptotic function of NF‐κB in the DNA damage response in glioblastoma cells. Chemotherapeutic drugs that intercalate into DNA and inhibit topoisomerase II such as Doxorubicin, Daunorubicin and Mitoxantrone stimulate NF‐κB DNA binding and transcriptional activity prior to induction of cell death. Importantly, specific inhibition of drug‐induced NF‐κB activation by IκBα‐SR or RNA interference against p65 significantly reduces apoptosis upon treatment with Doxorubicin, Daunorubicin or Mitoxantrone. NF‐κB exerts this pro‐apoptotic function especially after pulse drug exposure as compared to continuous treatment indicating that the contribution of NF‐κB becomes relevant during the recovery phase following the initial DNA damage. Mechanistic studies show that NF‐κB inhibition does not alter Doxorubicin uptake and efflux or cell cycle alterations. Genetic silencing of p53 by RNA interference reveals that NF‐κB promotes drug‐induced apoptosis in a p53‐independent manner. Intriguingly, drug‐mediated NF‐κB activation results in a significant increase in DNA damage prior to the induction of apoptosis. By demonstrating that NF‐κB promotes DNA damage formation and apoptosis upon pulse treatment with DNA intercalators, our findings provide novel insights into the control of the DNA damage response by NF‐κB in glioblastoma.

Wild-type p53 inhibits replication-associated homologous recombination

In mammalian cells homologous recombination is stimulated, when the replication fork stalls at DNA breaks or unrepaired lesions. The tumor suppressor p53 downregulates homologous recombination independently of its transcriptional transactivation function and has been linked to enzymes of DNA recombination and replication. To study recombination with respect to replication, we utilized a SV40 virus based assay, to follow the synchronous events after primate cell infection. γ-ray treatment at different times after viral entry unveiled an increase of interchromosomal exchange frequencies, when the damage was introduced during DNA synthesis. Elevated recombination frequencies were fully suppressed by p53. With respect to the downregulation of spontaneous recombination, we noticed a requirement for active p53 molecules, when replication started. After a transient treatment with replication inhibitors, we observed inhibition of the drug induced recombination by p53, particularly for the elongation inhibitor aphidicolin. Consequently, we propose that p53 is a surveillance factor of homologous recombination at replication forks, when they stall as a consequence of endogenous or of exogenously introduced damage.

The human DEK oncogene regulates DNA damage response signaling and repair

The human DEK gene is frequently overexpressed and sometimes amplified in human cancer. Consistent with oncogenic functions, Dek knockout mice are partially resistant to chemically induced papilloma formation. Additionally, DEK knockdown in vitro sensitizes cancer cells to DNA damaging agents and induces cell death via p53-dependent and -independent mechanisms. Here we report that DEK is important for DNA double-strand break repair. DEK depletion in human cancer cell lines and xenografts was sufficient to induce a DNA damage response as assessed by detection of γH2AX and FANCD2. Phosphorylation of H2AX was accompanied by contrasting activation and suppression, respectively, of the ATM and DNA-PK pathways. Similar DNA damage responses were observed in primary Dek knockout mouse embryonic fibroblasts (MEFs), along with increased levels of DNA damage and exaggerated induction of senescence in response to genotoxic stress. Importantly, Dek knockout MEFs exhibited distinct defects in non-homologous end joining (NHEJ) when compared to their wild-type counterparts. Taken together, the data demonstrate new molecular links between DEK and DNA damage response signaling pathways, and suggest that DEK contributes to DNA repair.