Photochromic histone deacetylase inhibitors based on dithienylethenes and fulgimides.

Histone deacetylases (HDACs) play a crucial role in numerous biological processes and therefore are targeted in anticancer research and in the field of epigenetics. Dithienylethenes (DTEs) and fulgimides were functionalized with hydroxamic acids, which is a known moiety binding to zinc dependent HDACs, to gain photoswitchable HDAC inhibitors. The new DTE based inhibitors showed moderate photochromic properties in polar solvents and the inhibitory activity changes up to a factor of four. The photochromic performance of the prepared fulgimide inhibitors was very good, even in aqueous buffer. They achieved a maximum three-fold difference in inhibitory activity. Docking experiments using the crystal structures of the tested enzymes gave a rationale for the observed moderate differences in the activities of the inhibitors.

Synthesis, biological characterisation and structure activity relationships of aromatic bisamidines active against Plasmodium falciparum.

Malaria is one of the most significant tropical diseases and remains a major challenge due to the lack of a broadly effective vaccine and parasite resistance to current drugs. This means there is a need for new drug candidates with novel modes of action. Aromatic bisamidines, such as furamidine (DB75), were initially developed as anti-Trypanosoma agents however as clinical trials with furamidine highlighted potential side effects they were not pursued further in that setting. Despite apparent cytotoxicity liabilities the potency of furamidine against Plasmodium falciparum makes it a promising scaffold for the development of new anti-Plasmodium agents with improved selectivity. In this study a bisamidine compound series based on furamidine was synthesized by introducing modifications at the furan core structure and terminal amidine groups. The activity of the derived compounds was tested in vitro against drug sensitive and resistant P. falciparum lines and a human cell line (HEK293 cells) to generate anti-Plasmodium structure-activity relationships and to provide preliminary selectivity data.

Molecular combination of the dopamine and serotonin scaffolds yield in novel antipsychotic drug candidates - characterization by in vivo experiments.

Serotonin and dopamine play an important role in the aetiology of schizophrenia. Combination of the structural scaffolds of both neurotransmitters in a single molecule lead to aromatic [d,g]-bisannelated azecine derivatives, which have been shown to be nanomolar to subnanomolar dopamine D1-D5 receptor antagonists with a preference for the D1 family. In this work the potential antipsychotic activity of some azecine derivatives was predicted by their dopamine receptor affinities obtained in vitro from radioligand binding experiments and conclusively confirmed in vivo (rats) by applying a conditioned avoidance model. Furthermore, the compounds were tested in vivo for the development of catalepsy, which is a predictive parameter for extra-pyramidal side-effects caused by many antipsychotics. The investigated azecines displayed low cytotoxicity, and the affinities for human dopamine D1-D5 and serotonin 5-HT2 A receptors were in a nanomolar range. In vivo, their antipsychotic activities in the rat model were comparable with those of haloperidol and risperidone, but revealed a 2-5 times better therapeutic range with regard to catalepsy. Preliminary tests for oral bioavailability also revealed promising results for this new class of potential antipsychotic compounds. In conclusion, our in vivo experiments show that aromatic [d,g]-annelated azecines represent a novel and advantageous class of potential atypical neuroleptics.