Abstract
We recently reported a new technique, light-induced triplet–triplet electron resonance spectroscopy (LITTER), which allows quantification of the dipolar interaction between the photogenerated triplet states of two chromophores. Here we carry out a systematic LITTER study, considering orientation selection by the detection pulses, of a series of bis-porphyrin model peptides with different porphyrin–porphyrin distances and relative orientations. Orientation-dependent analysis of the dipolar datasets yields conformational information of the molecules in frozen solution which is in good agreement with density functional theory predictions. Additionally, a fast partial orientational-averaging treatment produces distance distributions with minimized orientational artefacts. Finally, by direct comparison of LITTER data to double electron–electron resonance (DEER) measured on a system with Cu(II) coordinated into the porphyrins, we demonstrate the advantages of the LITTER technique over the standard DEER methodology. This is due to the remarkable spectroscopic properties of the photogenerated porphyrin triplet state. This work sets the basis for the use of LITTER in structural investigations of unmodified complex biological macromolecules, which could be combined with Förster resonance energy transfer and microscopy inside cells.
Supplementary materials
Title
Supporting Information for Determining and controlling conformational information from orientationally selective Light-Induced Triplet–Triplet Electron Resonance spectroscopy for a set of bis-porphyrin rulers
Description
CONTENTS
S1. Spectroscopic characterization of [3]
S2. Spectroscopic characterization of Cu2-[3]
S3. Computational results
S4. Orientation-dependent analysis
S5. Orientation-independent analysis
S6. Modulation depth to noise ratio
S7. Reporting checklist and data deposition checklist for LITTER
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