Human telomeric protein TRF2 associates with genomic double-strand breaks as an early response to DNA damage

DNA damage surveillance networks in human cells can activate DNA repair, cell cycle checkpoints and apoptosis in response to fewer than four double-strand breaks (DSBs) per genome. These same networks tolerate telomeres, in part because the protein TRF2 prevents recognition of telomeric ends as DSBs by facilitating their organization into T loops. We now show that TRF2 associates with photo-induced DSBs in nontelomeric DNA in human fibroblasts within 2 s of irradiation. Unlike gammaH2AX, a common marker for DSB damage, TRF2 forms transient foci that colocalize closely with DSBs. The TRF2 DSB response requires the TRF2 basic domain but not its Myb domain and occurs in the absence of functional ATM and DNA-PK protein kinases, MRE11/Rad50/NBS1 complex and Ku70, WRN and BLM repair proteins. Furthermore, overexpression of TRF2 inhibits DSB-induced phosphorylation of ATM signaling targets. Our results implicate TRF2 in an initial stage of DSB recognition and processing that occurs before association of ATM with DSBs and activation of the ATM-dependent DSB response network.     

Electro-osmotic and iontophoretic release of noradrenaline from micropipettes

Summary The relative contributions of electro-osmosis and iontophoresis to the electrophoretic release of noradrenaline from micropipettes were examined. Electro-osmosis was responsible for 23.1% (±5.0%) of the total rate of release.This work was supported by the Wellcome Trust. We are grateful to Dr M.N. Jones for his help. Some of the results have been communicated to the British Pharmacological Society. Dublin, July 1979.     

Primary forests are irreplaceable for sustaining tropical biodiversity

Human-driven land-use changes increasingly threaten biodiversity, particularly in tropical forests where both species diversity and human pressures on natural environments are high. The rapid conversion of tropical forests for agriculture, timber production and other uses has generated vast, human-dominated landscapes with potentially dire consequences for tropical biodiversity. Today, few truly undisturbed tropical forests exist, whereas those degraded by repeated logging and fires, as well as secondary and plantation forests, are rapidly expanding. Here we provide a global assessment of the impact of disturbance and land conversion on biodiversity in tropical forests using a meta-analysis of 138 studies. We analysed 2,220 pairwise comparisons of biodiversity values in primary forests (with little or no human disturbance) and disturbed forests. We found that biodiversity values were substantially lower in degraded forests, but that this varied considerably by geographic region, taxonomic group, ecological metric and disturbance type. Even after partly accounting for confounding colonization and succession effects due to the composition of surrounding habitats, isolation and time since disturbance, we find that most forms of forest degradation have an overwhelmingly detrimental effect on tropical biodiversity. Our results clearly indicate that when it comes to maintaining tropical biodiversity, there is no substitute for primary forests.     

Germline transmission of genetically modified primordial germ cells

Primordial germ cells (PGCs) are the precursors of sperm and eggs. In most animals, segregation of the germ line from the somatic lineages is one of the earliest events in development; in avian embryos, PGCs are first identified in an extra-embryonic region, the germinal crescent, after approximately 18 h of incubation. After 50-55 h of development, PGCs migrate to the gonad and subsequently produce functional sperm and oocytes. So far, cultures of PGCs that remain restricted to the germ line have not been reported in any species. Here we show that chicken PGCs can be isolated, cultured and genetically modified while maintaining their commitment to the germ line. Furthermore, we show that chicken PGCs can be induced in vitro to differentiate into embryonic germ cells that contribute to somatic tissues. Retention of the commitment of PGCs to the germ line after extended periods in culture and after genetic modification combined with their capacity to acquire somatic competence in vitro provides a new model for developmental biology. The utility of the model is enhanced by the accessibility of the avian embryo, which facilitates access to the earliest stages of development and supplies a facile route for the reintroduction of PGCs into the embryonic vasculature. In addition, these attributes create new opportunities to manipulate the genome of chickens for agricultural and pharmaceutical applications.