Energy transfer in PPV-based conjugated polymers: a defocused widefield fluorescence microscopy study.

Both pendant and main chain conjugated MEH-PPV based polymers have been studied at the level of single chains using confocal and widefield fluorescence microscopy techniques. In particular, defocused widefield fluorescence is applied to reveal the extent of energy transfer in these polymers by identifying whether they act as single emitters. For main chain conjugated MEH-PPV, molecular weight and the surrounding matrix play a primary role in determining energy transport processes and whether single emitter behaviour is observed. Surprisingly in polymers with a saturated backbone but containing the same pendant MEH-PPV oligomer on each repeating unit, intra-chain energy transfer to a single emitter is also apparent. The results imply there is chromophore heterogeneity that can facilitate energy funneling to the emitting site. Both main chain conjugated and pendant MEH-PPV polymers exhibit changes in orientation of the emission dipole during a fluorescence trajectory of many seconds, whereas a model MEH-PPV oligomer does not. The results suggest that, in the polymers, the nature of the emitting chromophores can change during the time trajectory.

Molecular modeling of the prekallikrein structure provides insights into high-molecular-weight kininogen binding and zymogen activation.

BACKGROUND: Prekallikrein (PK) plays a central role in the contact system that activates blood coagulation and is involved in the regulation of blood pressure. OBJECTIVES: To provide three-dimensional structural data for PK and rationalize the molecular basis of substrate recognition and zymogen activation. PATIENTS/METHODS: The PK homology model was constructed using the coagulation factor (F) XI crystal structure as a template with the program SWISS-MODEL. RESULTS: The domain organization of the PK apple domains and serine protease is conserved compared to FXI. Surface charge calculations on the PK model revealed that ligand binding to high-molecular-weight kininogen (HK) is predicted to have two key determinants: a pocket within the apple 2 domain and a basic channel formed at the interface of apple domains 1 and 4. A hereditary mutation resulting in PK deficiency (Gly104Arg) and the Lys140 alpha-kallikrein cleavage site both disrupt HK binding and are shown to map to opposite sides of the apple 2 domain pocket. The model also describes the differences in the apple 4 domain that prevents dimer formation in PK vs. FXI. A C-terminal extension in the PK serine protease domain is described as a potential substrate for prolylcarboxypeptidase. CONCLUSIONS: The interaction between PK and HK is mediated by two discrete surfaces formed by the PK A1, A2 and A4 domains with charge likely to be a critical component of the binding. A novel mode of PK activation is postulated to involve prolylcarboxypeptidase cleaving at the C-terminus rather than the activation loop.