Differential reaction of tomato chromosomes with hydroxylamine

Zusammenfassung Hydroxylamin, welches spezifisch mit Cytosin reagiert, stört die Struktur der verschiedenen Chromosomen in Pollenmutterzellen der Tomate unterschiedlich stark. Das Chromosomenpaar Nr. 2 wird wesentlich weniger stark geschädigt als die übrigen. Die Bedeutung dieses Befundes wird kurz angedeutet.     

High-temperature metal-organic magnets

For over two decades there have been intense efforts aimed at the development of alternatives to conventional magnets, particularly materials comprised in part or wholly of molecular components. Such alternatives offer the prospect of realizing magnets fabricated through controlled, low-temperature, solution-based chemistry, as opposed to high-temperature metallurgical routes, and also the possibility of tuning magnetic properties through synthesis. However, examples of magnetically ordered molecular materials at or near room temperature are extremely rare, and the properties of these materials are often capricious and difficult to reproduce. Here we present a versatile solution-based route to a new class of metal-organic materials exhibiting magnetic order well above room temperature. Reactions of the metal (M) precursor complex bis(1,5-cyclooctadiene)nickel with three different organics A-TCNE (tetracyanoethylene), TCNQ (7,7,8,8-tetracyanoquinodimethane) or DDQ (2,3-dichloro-5,6-dicyano-1,4-benzoquinone)--proceed via electron transfer from nickel to A and lead to materials containing Ni(II) ions and reduced forms of A in a 2:1 Ni:A ratio--that is, opposite to that of conventional (low Curie temperature) MA(2)-type magnets. These materials also contain oxygen-based species within their architectures. Magnetic characterization of the three compounds reveals spontaneous field-dependent magnetization and hysteresis at room temperature, with ordering temperatures well above ambient. The unusual stoichiometry and striking magnetic properties highlight these three compounds as members of a class of stable magnets that are at the interface between conventional inorganic magnets and genuine molecule-based magnets.     

Break-induced replication and telomerase-independent telomere maintenance require Pol32

Break-induced replication (BIR) is an efficient homologous recombination process to initiate DNA replication when only one end of a chromosome double-strand break shares homology with a template. BIR is thought to re-establish replication at stalled and broken replication forks and to act at eroding telomeres in cells that lack telomerase in pathways known as 'alternative lengthening of telomeres' (reviewed in refs 2, 6). Here we show that, in haploid budding yeast, Rad51-dependent BIR induced by HO endonuclease requires the lagging strand DNA Polalpha-primase complex as well as Poldelta to initiate new DNA synthesis. Polepsilon is not required for the initial primer extension step of BIR but is required to complete 30 kb of new DNA synthesis. Initiation of BIR also requires the nonessential DNA Poldelta subunit Pol32 primarily through its interaction with another Poldelta subunit, Pol31. HO-induced gene conversion, in which both ends of a double-strand break engage in homologous recombination, does not require Pol32. Pol32 is also required for the recovery of both Rad51-dependent and Rad51-independent survivors in yeast strains lacking telomerase. These results strongly suggest that both types of telomere maintenance pathways occur by recombination-dependent DNA replication. Thus Pol32, dispensable for replication and for gene conversion, is uniquely required for BIR; this finding provides an opening into understanding how DNA replication re-start mechanisms operate in eukaryotes. We also note that Pol32 homologues have been identified both in fission yeast and in metazoans where telomerase-independent survivors with alternative telomere maintenance have also been identified.