Design, synthesis, and evaluation of nickel dipyridylmethane complexes for Coordination-Induced Spin State Switching (CISSS).

In order to develop a new system capable of performing Ligand-Driven Coordination-Induced Spin State Switching (LD-CISSS), a new CISSS complex based on a nickel(ii) dipyridylmethane framework was rationally designed, synthesized, and investigated both experimentally and theoretically. In DFT calculations, a dipyridylmethane dicarboxylic acid ligand was determined to be most suitable for this purpose. The corresponding nickel(ii) complex was synthesized by an optimized procedure, and the CISSS effect was evidenced by crystallography as well as Evans NMR susceptibility measurements. In the solid state, the square planar nickel complex is diamagnetic and the octahedral bispyridine adduct is paramagnetic. Also, a dimer containing three ethanol ligands was obtained. Dimer formation occurs in solution as well. Upon addition of pyridine, a continuous transition from predominantly diamagnetic to paramagnetic behavior takes place. Equilibrium constants for the binding of pyridine as well as corresponding thermodynamic parameters indicate a high affinity for this ligand and show that the title system is a suitable candidate for LD-CISSS.

Structure-Activity Relationship of Propargylamine-Based HDAC Inhibitors.

As histone deacetylases (HDACs) play an important role in the treatment of cancer, their selective inhibition has been the subject of various studies. These continuous investigations have given rise to a large collection of pan- and selective HDAC inhibitors, containing diverse US Food and Drug Administration (FDA)-approved representatives. In previous studies, a class of alkyne-based HDAC inhibitors was presented. We modified this scaffold in two previously neglected regions and compared their cytotoxicity and affinity toward HDAC1, HDAC6, and HDAC8. We were able to show that R-configured propargylamines contribute to increased selectivity for HDAC6. Docking studies on available HDAC crystal structures were carried out to rationalize the observed selectivity of the compounds. Substitution of the aromatic portion by a thiophene derivative results in high affinity and low cytotoxicity, indicating an improved drug tolerance.