merocyanine-dye and indoline

The dwindling supply of antibiotics that remain effective against drug-resistant bacterial pathogens has precipitated efforts to identify new compounds that inhibit bacterial growth using untapped mechanisms of action. Here, we report both (1) a high-throughput screening methodology designed to discover chemical perturbants of the essential, yet unexploited, process of bacterial iron homeostasis, and (2) our findings from a small-molecule screen of more than 30,000 diverse small molecules that led to the identification and characterization of two spiro-indoline-thiadiazoles that disrupt iron homeostasis in bacteria. We show that these compounds are intracellular chelators with the capacity to exist in two isomeric states. Notably, these spiroheterocyles undergo a transition to an open merocyanine chelating form with antibacterial activity that is specifically induced in the presence of its transition-metal target.

Topics: Anti-Bacterial Agents; Bacterial Proteins; Benzopyrans; Crystallography, X-Ray; Dose-Response Relationship, Drug; Drug Evaluation, Preclinical; Escherichia coli; High-Throughput Screening Assays; Homeostasis; Indoles; Iron; Iron Chelating Agents; Organometallic Compounds; Small Molecule Libraries; Spiro Compounds; Stereoisomerism; Structure-Activity Relationship; Thiadiazoles; Transcription Factors; Transition Elements

Upon ultraviolet excitation, photochromic spiropyran compounds can be converted by a ring-opening reaction into merocyanine molecules, which in turn can form several isomers differing by cis and trans configurations in the methine bridge. Whereas the spiropyran-merocyanine conversion reaction of the nitro-substituted indolinobenzopyran 6-nitro-1',3',3'-trimethylspiro[2H-1-benzopyran-2,2'-indoline] (6-nitro BIPS) has been studied extensively in theory and experiments, little is known about photoisomerization among the merocyanine isomers. In this article, we employ femtosecond transient absorption spectroscopy with variable excitation wavelengths to investigate the excited-state dynamics of the merocyanine in acetonitrile at room temperature, where exclusively the trans-trans-cis (TTC) and trans-trans-trans (TTT) isomers contribute. No photochemical ring-closure pathways exist for the two isomers. Instead, we found that (18±4)% of excited TTC isomers undergo an ultrafast excited-state cis→trans photoisomerization to TTT within 200 fs, while the excited-state lifetime of TTC molecules that do not isomerize is 35 ps. No photoisomerization was detected for the TTT isomer, which relaxes to the ground state with a lifetime of roughly 160 ps. Moreover, signal oscillations at 170 cm(-1) and 360 cm(-1) were observed, which can be ascribed to excited-state wave-packet dynamics occurring in the course of the TTC→TTT isomerization. The results of high-level time-dependent density functional theory in conjunction with polarizable continuum models are presented in the subsequent article [C. Walter, S. Ruetzel, M. Diekmann, P. Nuernberger, T. Brixner, and B. Engels, J. Chem. Phys. 140, 224311 (2014)].

Topics: Benzopyrans; Indoles; Isomerism; Light; Monte Carlo Method; Nitro Compounds; Pulse; Quantum Theory; Solvents