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1 May 2004 Torsion Potential Works in Rhodopsin
Atsushi Yamada, Takahisa Yamato, Toshiaki Kakitani, Shigeyoshi Yamamoto
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We investigate the role of protein environment of rhodopsin and the intramolecular interaction of the chromophore in the cistrans photoisomerization of rhodopsin by means of a newly developed theoretical method. We theoretically produce modified rhodopsins in which a force field of arbitrarily chosen part of the chromophore or the binding pocket of rhodopsin is altered. We compare the equilibrium conformation of the chromophore and the energy stored in the chromophore of modified rhodopsins with those of native rhodopsins. This method is called site-specific force field switch (SFS). We show that this method is most successfully applied to the torsion potential of rhodopsin. Namely, by reducing the twisting force constant of the C11=C12 of 11-cis retinal chromophore of rhodopsin to zero, we found that the equilibrium value of the twisting angle of the C11=C12 bond is twisted in the negative direction down to about −80°. The relaxation energy obtained by this change amounts to an order of 10 kcal/mol. In the case that the twisting force constant of the other double bond is reduced to zero, no such large twisting of the bond happens. From these results we conclude that a certain torsion potential is applied specifically to the C11=C12 bond of the chromophore in the ground state of rhodopsin. This torsion potential facilitates the bond-specific cistrans photoisomerization of rhodopsin. This kind of the mechanism is consistent with our torsion model proposed by us more than a quarter of century ago. The origin of the torsion potential is analyzed in detail on the basis of the chromophore structure and protein conformation, by applying the SFS method extensively.

Atsushi Yamada, Takahisa Yamato, Toshiaki Kakitani, and Shigeyoshi Yamamoto "Torsion Potential Works in Rhodopsin," Photochemistry and Photobiology 79(5), 476-486, (1 May 2004).
Received: 20 September 2003; Accepted: 1 February 2004; Published: 1 May 2004

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