| Abstract: | Abstract– Dehydration of purple membrane (PM) causes a hlue-shift of the absorbance maximum from 570 nm to about 530 nm [Lazarev and Terpugov (1980) Biochim. Biophys. Acta 590 .324–338; Hildebrandt and Stockburger (1984) Biochemistry 23 ,5539–5548]. The absorbance spectra of PM dried in films at pH 0, 7 and 11 were measured at controlled relative humidities (RH). At pH 7, a blue-shift was observed similar to that previously reported. At pH 0(1M H2SO4) a reversible transition was observed from the “acid blue membrane” (maximum near 600 nm at 100% RH) to a blue-shifted dehydrated pigment (maximum near 578 nm at 50% RH), with isosbestic points at 592 and 710 nm. At pH 11 (NaOH) the absorbance maximum shifted to 530 nm, similar to the dehydrated form at pH 7. The fraction of hydrated chromophore, Xh, was calculated (assuming only two chromophore states, hydrated and dehydrated) as a function of humidity and pH. The resulting curve at pH 7 showed a steep decline in Xh below 20% RH. Near this hydration level, water clusters on protein surfaces break up, causing side-chain pK reversals. The Hill coefficient for the transition was about 2, indicating the minimum number of water molecules involved in a cooperative transition. The results suggest that as few as two water molecules are coordinated to the protonated retinal Schiff base of bacteriorhodopsin. A mechanism for the pH 7 dehydration blue-shift is proposed, involving a pK reversal of the protonated Schiff base and a nearby carboxyl side chain. At pH 0, a sharp decline in Xh occurs between 100 and 70% RH. Near this hydration level, complete protein surface coverage by a water monolayer occurs. The Hill coefficient is about 20, suggesting involvement of a large region of the surface. |
