Peptide-catalyzed kinetic resolution of formamides and thioformamides as an entry to nonracemic amines.

We report a fundamentally unique approach to the catalytic kinetic resolution of amine derivatives based on formamide and thioformamide substrates. Readily accessible histidine-containing peptides mediate the kinetic resolutions with as little as 5 mol % catalyst. Selectivity factors (k(rel)) as high as 43.7 were observed under simple reaction conditions utilizing Boc(2)O as the reagent at room temperature. Mechanistic experiments were conducted that established a higher level of reactivity for thioformamide substrates than for their formamide analogues. The products of these asymmetric reactions were shown to be readily converted to desirable building blocks such as N-Boc-amines and the parent chiral formamide compounds.

A novel small-molecule inhibitor reveals a possible role of kinesin-5 in anastral spindle-pole assembly.

The tetrameric plus-end-directed motor, kinesin-5, is essential for bipolar spindle assembly. Small-molecule inhibitors of kinesin-5 have been important tools for investigating its function, and some are currently under evaluation as anti-cancer drugs. Most inhibitors reported to date are ;non-competitive' and bind to a specific site on the motor head, trapping the motor in an ADP-bound state in which it has a weak but non-zero affinity for microtubules. Here, we used a novel ATP-competitive inhibitor, FCPT, developed at Merck (USA). We found that it induced tight binding of kinesin-5 onto microtubules in vitro. Using Xenopus egg-extract spindles, we found that FCPT not only blocked poleward microtubule sliding but also selectively induced loss of microtubules at the poles of bipolar spindles (and not asters or monoasters). We also found that the spindle-pole proteins TPX2 and gamma-tubulin became redistributed to the spindle equator, suggesting that proper kinesin-5 function is required for pole assembly.