| Abstract: | Reduced 3-thionicotinamide--adenine dinucleotide (sNADH) is shown to be fluorescent, with an emission maximum at 510 nm when excited in the region of the absorption maximum (398 nm), and with a very low quantum yield, (3.4 +/- 0.5) x 10(-4). The interaction between sNADH and octopine dehydrogenase was investigated by ultraviolet-difference spectroscopy and fluorescence. Some surprising fluorescence features were found when sNADH was bound to the enzyme in the presence of D-octopine, as follows. (a) There is an unusually high enhancement of the dinucleotide fluorescence (by at least a factor of 100) attended by a 40-nm blue shift of the emission maximum. (b) The protein fluorescence is quenched almost completely. (c) The bound coenzyme analog undergoes a photoreaction, which proceeds differently from that occurring the free form. These features appear to be unique to the octopine.sNADH complex, as for example they are not present when sNADH is bound to horse liver alcohol dehydrogenase, or when NADH is bound to octopine dehydrogenase. The possible origin of these fluorescence features is discussed. Binding and kinetic studies were carried out with sNAD and sNADH. It was found that sNAD neither binds nor acts kinetically as a coenzyme. sNADH exhibits relatively good binding, with Km and Ki values close to those of the natural coenzyme, but the turnover number is 460 times smaller than that with NADH. The kinetic consequences of these findings are discussed. The sNADH dissociation constants were determined as a function of temperature, and appear to be practically temperature-independent in the range 10--40 degrees C. It seems thus, in agreement with previous studies, that the interaction between octopine dehydrogenase and coenzymes proceeds athermically, regardless of the structure, affinity, and chemical reactivity of the coenzyme. The possible biological and chemical meaning of this finding is discussed. |
