Hydropower and fish - Report and messages from workshop on research and innovation in the context of the European policy framework.

Hydropower is the world's largest renewable electricity source and will have an important role in the future energy system with increased requirements to integrate environmental and socioeconomic aspects of sustainability. One important field of interaction is between hydropower and fish. The aim of optimizing hydropower production as well as fish production via Research and Innovation in the context of the European policy framework was the topic of the workshop "Hydropower and Fish - Research and Innovation in the context of the European Policy Framework" organized in May 2017 in Brussels. This paper reports the main messages from the workshop sessions including future research needs, collaboration strategies and knowledge exchange. In particular, the workshop emphasized the need for standardized monitoring and mitigation approaches and of following a balanced approach in addressing challenges between renewable energy production and river and fish ecology. Future research in the area is needed. As perspective and primer for future discussions, the interrelations of hydropower and fish to the different spheres of the total environment are presented and discussed.

Cohesin and the nucleolus constrain the mobility of spontaneous repair foci.

The regulation of chromatin mobility in response to DNA damage is important for homologous recombination in yeast. Anchorage reduces rates of recombination, whereas increased chromatin mobility correlates with more efficient homology search. Here we tracked the mobility and localization of spontaneous S-phase lesions bound by Rad52, and find that these foci have reduced movement, unlike enzymatically induced double-strand breaks. Moreover, spontaneous repair foci are positioned in the nuclear core, abutting the nucleolus. We show that cohesin and nucleolar integrity constrain the mobility of these foci, consistent with the notion that spontaneous, S-phase damage is preferentially repaired from the sister chromatid.

Exploiting oncogene-induced replicative stress for the selective killing of Myc-driven tumors.

Oncogene-induced replicative stress activates an Atr- and Chk1-dependent response, which has been proposed to be widespread in tumors. We explored whether the presence of replicative stress could be exploited for the selective elimination of cancer cells. To this end, we evaluated the impact of targeting the replicative stress-response on cancer development. In mice (Mus musculus), the reduced levels of Atr found on a mouse model of the Atr-Seckel syndrome completely prevented the development of Myc-induced lymphomas or pancreatic tumors, both of which showed abundant levels of replicative stress. Moreover, Chk1 inhibitors were highly effective in killing Myc-driven lymphomas. By contrast, pancreatic adenocarcinomas initiated by K-Ras(G12V) showed no detectable evidence of replicative stress and were nonresponsive to this therapy. Besides its impact on cancer, Myc overexpression aggravated the phenotypes of Atr-Seckel mice, revealing that oncogenes can modulate the severity of replicative stress-associated diseases.

γH2A is a component of yeast heterochromatin required for telomere elongation.

Histones of heterochromatin are deacetylated in yeast and methylated in more complex eukaryotes to regulate heterochromatin structure and gene silencing. Here, we report that histone H2A phosphorylated at serine 129 (γH2A) in Saccharomyces cerevisiae is a conceptually new type of heterochromatin modification that functions downstream of silent chromatin assembly. We show that γH2A is enriched throughout yeast telomeric and silent mating locus (HM) heterochromatin where γH2A results from the action of kinases Tel1 and Mec1. Interestingly, mutation of γH2A has no apparent effect on the binding of Sir (silent information regulator) complex or on gene silencing. In contrast, deletion of SIR3 abolishes the formation of γH2A at heterochromatin. To address the function of γH2A, we used a Δrif1 mutant strain in which telomeres are excessively elongated to show that γH2A is required for the optimal recruitment of Cdc13, a regulator of telomere elongation, and for telomere elongation itself. Thus, a histone modification that parallels Sir3 protein binding is shown here to be dispensable for the formation of a silent structure but is important for a crucial heterochromatin-specific downstream function in telomere homeostasis.

Cell cycle-dependent phosphorylation of Rad53 kinase by Cdc5 and Cdc28 modulates checkpoint adaptation.

In budding yeast the evolutionarily conserved checkpoint response varies in its sensitivity to DNA damaging agents through the cell cycle. Specifically, higher amounts of damage are needed to activate the downstream checkpoint kinase Rad53 in S-phase cells. We examined here whether phosphorylation of Rad53 itself by cell cycle-dedicated kinases regulates Rad53 activation. We found that during unperturbed growth Rad53 exhibits a small phosphorylation-dependent electrophoretic mobility shift in G(2), M and G(1) phases of the cell cycle that is lost in S phase. We show that Rad53 is phosphorylated in vitro by Cdc5, a mitotic Polo-like kinase, and by the yeast cyclin-dependent kinase, Cdc28. Consistently, the cell cycle-dependent Rad53 mobility shift requires both Cdc5 and Cdc28 activities. We mapped the in vitro targeted phosphorylation sites by mass spectrometry and confirmed with mass spectroscopy that serines 774, 789 and 791 within Rad53 are phosphorylated in vivo in M-phase arrested cells. By creating nonphosphorylatable mutations in the endogenous RAD53 gene, we confirmed that the CDK and Polo kinase target sites are responsible for the observed cell cycle-dependent shift in protein mobility. The loss of phospho-acceptor sites does not interfere with Rad53 activation but accelerates checkpoint adaptation after induction of a single irreparable double-strand break. We thus demonstrate that cell cycle-dependent phosphorylation can fine-tune the response of Rad53 to DNA damage.

Cdk2 suppresses cellular senescence induced by the c-myc oncogene.

Activated oncogenes induce compensatory tumour-suppressive responses, such as cellular senescence or apoptosis, but the signals determining the main outcome remain to be fully understood. Here, we uncover a role for Cdk2 (cyclin-dependent kinase 2) in suppressing Myc-induced senescence. Short-term activation of Myc promoted cell-cycle progression in either wild-type or Cdk2 knockout mouse embryo fibroblasts (MEFs). In the knockout MEFs, however, the initial hyper-proliferative response was followed by cellular senescence. Loss of Cdk2 also caused sensitization to Myc-induced senescence in pancreatic beta-cells or splenic B-cells in vivo, correlating with delayed lymphoma onset in the latter. Cdk2-/- MEFs also senesced upon ectopic Wnt signalling or, without an oncogene, upon oxygen-induced culture shock. Myc also causes senescence in cells lacking the DNA repair protein Wrn. However, unlike loss of Wrn, loss of Cdk2 did not enhance Myc-induced replication stress, implying that these proteins suppress senescence through different routes. In MEFs, Myc-induced senescence was genetically dependent on the ARF-p53-p21Cip1 and p16INK4a-pRb pathways, p21Cip1 and p16INK4a being selectively induced in Cdk2-/- cells. Thus, although redundant for cell-cycle progression and development, Cdk2 has a unique role in suppressing oncogene- and/or stress-induced senescence. Pharmacological inhibition of Cdk2 induced Myc-dependent senescence in various cell types, including a p53-null human cancer cell line. Our data warrant re-assessment of Cdk2 as a therapeutic target in Myc- or Wnt-driven tumours.

Posttranslational modifications of repair factors and histones in the cellular response to stalled replication forks.

DNA damage during replication requires an integration of checkpoint response with replication itself and distinct repair pathways, such as replication pausing, recombination and translesion synthesis. Here we focus on recent advances in our understanding of how protein posttranslational modifications contribute to the maintenance of fork integrity. In particular, we examine the role of histone modifications and chromatin remodeling complexes in this process.

Ino80 chromatin remodeling complex promotes recovery of stalled replication forks.

BACKGROUND: Chromatin remodeling complexes facilitate the access of enzymes that mediate transcription, replication or repair of DNA by modulating nucleosome position and/or composition. Ino80 is the DNA-dependent Snf2-like ATPase subunit of a complex whose nucleosome remodeling activity requires actin-related proteins, Arp4, Arp5 and Arp8, as well as two RuvB-like DNA helicase subunits. Budding yeast mutants deficient for Ino80 function are not only hypersensitive to reagents that induce DNA double-strand breaks, but also to those that impair replication fork progression. RESULTS: To understand why ino80 mutants are sensitive to agents that perturb DNA replication, we used chromatin immunoprecipitation to map the binding sites of the INO80 chromatin-remodeling complex on four budding yeast chromosomes. We found that Ino80 and Arp5 binding sites coincide with origins of DNA replication and tRNA genes. In addition, Ino80 was bound at 67% of the promoters of genes that are sensitive to ino80 mutation. When replication forks were arrested near origins in the presence of hydroxyurea (HU), the amount of INO80 complex at stalled forks and at unfired origins increased selectively. Importantly, the resumption of DNA replication after release from a HU block was impaired in ino80 mutants. These cells accumulated double-strand breaks as they attempted to restart replication. Consistently, ino80-deficient cells, although proficient for checkpoint activation, delay recovery from the checkpoint response. CONCLUSIONS: The INO80 chromatin remodeling complex is enriched at stalled replication forks, where it promotes the resumption of replication upon recovery from fork arrest.

Replisome instability, fork collapse, and gross chromosomal rearrangements arise synergistically from Mec1 kinase and RecQ helicase mutations.

The yeast checkpoint kinases Mec1 and Rad53 are required for genomic stability in the presence of replicative stress. When replication forks stall, the stable maintenance of replisome components requires the ATR kinase Mec1/Ddc2 and the RecQ helicase Sgs1. It was unclear whether either Mec1 or Sgs1 action requires the checkpoint effector kinase, Rad53. By combining sgs1Delta with checkpoint-deficient alleles, we can now distinguish the role of Mec1 at stalled forks from that of Rad53. We show that the S-phase-specific mec1-100 allele, like the sgs1Delta mutation, partially destabilizes DNA polymerases at stalled forks, yet combining the mec1-100 and sgs1Delta mutations leads to complete disassociation of the replisome, loss of RPA, irreversible termination of nucleotide incorporation, and compromised recovery from hydroxyurea (HU) arrest. These events coincide with a dramatic increase in both spontaneous and HU-induced chromosomal rearrangements. Importantly, in sgs1Delta cells, RPA levels at stalled forks do not change, although Ddc2 recruitment is compromised, explaining the partial Sgs1 and Mec1 interdependence. Loss of Rad53 kinase, on the other hand, does not affect the levels of DNA polymerases at arrested forks, but leads to MCM protein dissociation. Finally, confirming its unique role during replicative stress, Mec1, and not Tel1, is shown to modify fork-associated histone H2A.

Transient CENP-E-like kinetochore proteins in plants.

Derived from candidate sequences of a barley EST database two proteins with homology to the coiled coil region of the human kinetochore protein (KP) CENP-E were generated and classified as centromere protein E-like 1 and 2 (Cpell and Cpe12). Specific antibodies produced against recombinant Cpe11 and Cpe12 proteins labeled the centromere on mitotic chromosomes of barley and field bean and recognized specifically proteins from nuclear/chromosomal protein extracts on immunoblots. No function was predicted for homologues of Cpe11 within the databases for Arabidopsis and rice genomes. However, the centromeric location of Cpe11 and Cpe12 suggests they may have a function within the kinetochore. Plant homologues to barley Cpe12 are N-type kinesins, suggesting that Cpe12 is functionally homologous to human CENP-E.