Photoregulated Transmembrane Charge Separation by Linked Spiropyran−Anthraquinone Molecules

Abstract

Amide-linked spiropyran−anthraquinone (SP−AQ) conjugates were shown to mediate ZnTPPS^4--photosensitized transmembrane reduction of occluded Co(bpy)₃³⁺ within unilamellar phosphatidylcholine vesicles by external EDTA. Overall quantum yields for these reactions were dependent upon the isomeric state of the dye; specifically, 30−35% photoconversion of the closed-ring spiropyran (SP) moiety to the open-ring merocyanine (MC) form caused the quantum yield to decrease by 6-fold in the simple conjugate and 3-fold for an analogue containing a lipophilic 4-dodecylphenoxy substituent on the anthraquinone moiety. Transient spectroscopic and fluorescence quenching measurements revealed that two factors contributed to these photoisomerization-induced changes in quantum yields: increased efficiencies of fluorescence quenching of ¹ZnTPPS^4- by the merocyanine group and lowered transmembrane diffusion rates of the merocyanine-containing redox carriers. Transient spectrophotometry also revealed the sequential formation and decay of two reaction intermediates, identified as ³ZnTPPS^4- and a species with the optical properties of a semiquinone radical. Kinetic profiles for Co(bpy)₃³⁺ reduction under continuous photolysis in the presence and absence of added ionophores indicated that transmembrane redox mediated by SP-AQ was electroneutral, but reaction by the other quinone-containing mediators was electrogenic. The minimal reaction mechanism suggested from the combined studies is oxidative quenching of vesicle-bound ³ZnTPPS^4- by the anthraquinone unit, followed by either H⁺/e^- cotransport by transmembrane diffusion of SP-AQH^• or, for the other redox mediators, semiquinone anion-quinone electron exchange leading to net transmembrane electron transfer, with subsequent one-electron reduction of the internal Co(bpy)₃³⁺. Thermal one-electron reduction of Co(bpy)₃³⁺ by EDTA is energetically unfavorable; the photosensitized reaction therefore occurs with partial conversion of photonic energy to chemical and transmembrane electrochemical potentials.