Brook Rearrangement as Trigger for Dearomatization Reaction: Synthesis of Non-Aromatic N-Heterocycles.

The [1,2]-Brook rearrangement stands as a potent technique for constructing complex molecules. In this study, we showcase its power in the dearomatization of aromatic N-heterocycles. Through a concise four-step process that integrates lithiation, nucleophilic addition, Brook rearrangement and dearomatization reaction, we demonstrate a versatile strategy for generating diverse non-aromatic N-heterocycles which exhibit ambident reactivities.

Sulfonium cations as versatile strongly π-acidic ligands.

More than a century old, sulfonium cations are still intriguing species in the landscape of organic chemistry. On one hand they have found broad applications in organic synthesis and materials science, but on the other hand, while isoelectronic to the ubiquitous tertiary phosphine ligands, their own coordination chemistry has been neglected for the last three decades. Here we report the synthesis and full characterization of the first Rh(i) and Pt(ii) complexes of sulfonium.

Grief and growth of bereaved siblings as related to attachment style and flexibility.

This study examined the relationship between attachment style, coping flexibility, military/non-military cause of death, levels of grief reactions and posttraumatic growth (PTG), in 150 bereaved adult siblings in Israel. Insecurely attached participants, 72% of the sample, reported more grief and less PTG than did securely attached ones. Highly avoidant individuals exhibited the least amount of PTG.

Metabolic buffering exerted by macromolecular crowding on DNA-DNA interactions: origin and physiological significance.

Crowding, which characterizes the interior of all living cells, has been shown to dramatically affect biochemical processes, leading to stabilization of compact morphologies, enhanced macromolecular associations, and altered reaction rates. Due to the crowding-mediated shift in binding equilibria toward association, crowding agents were proposed to act as a metabolic buffer, significantly extending the range of intracellular conditions under which interactions occur. Crowding may, however, impose a liability because, by greatly and generally enhancing macromolecular association, it can lead to irreversible interactions.

Unique condensation patterns of triplex DNA: physical aspects and physiological implications.

Triple-stranded DNA structures can be formed in living cells, either by native DNA sequences or following the application of antigene strategies, in which triplex-forming oligonucleotides are targeted to the nucleus. Recent studies imply that triplex motifs may play a role in DNA transcription, recombination and condensation processes in vivo. Here we show that very short triple-stranded DNA motifs, but not double-stranded segments of a comparable length, self-assemble into highly condensed and ordered structures.