Release of retinol and denaturation of its plasma carrier, retinol-binding protein.

BACKGROUND: Retinol is tightly packed inside the structure of its plasma carrier (retinol-binding protein, RBP). It was found that retinol release from RBP to aqueous solutions is facilitated by either very low pH or very high temperatures (i.e. by non-physiological conditions that cause protein denaturation). It was also found that alcohols induce protein conformational transitions to denatured states. On this basis, it may be suggested that retinol release in vivo is facilitated by the partial unfolding of the carrier resulting from the concerted action of the moderate local decrease of pH and the moderate local decrease of dielectric constant in proximity to the target membranes. RESULTS: In vitro, at 37 degrees C, retinol is removed from its plasma carrier by the concerted action of the moderately low pH and the moderately low dielectric constant of solutions containing a low ionic strength buffer and methanol in variable proportions. Release of retinol is accompanied by a conformational transition of RBP from the native to the molten-globule state. CONCLUSIONS: The physiological function of RBP-targeted delivery of retinol-is mimicked in vitro by the facilitated release of retinol (associated with a partial unfolding of the protein carrier) in solutions exhibiting pH and dielectric constant values that are within the range of values expected in the in vivo microenvironment.

Molten globule-like state of cytochrome c under conditions simulating those near the membrane surface.

Methanol-induced conformational transitions in cytochrome c have been studied by near- and far-UV circular dichroism, Trp fluorescence, microcalorimetry, and diffusion measurements. The existence of at least two cooperative stages of transition has been shown. At the first stage, the native protein is transformed into an intermediate which has only traces of tertiary structure, but has a native-like secondary structure content and is relatively compact; i.e., it has properties of the molten globule state. On the second stage, the alcohol-induced molten globule is transformed into a more helical state, typical of proteins at high alcohol concentrations. The conditions at which the alcohol-induced molten globule exists (moderately low pH and moderately low dielectric constant) could be similar to those existing near negatively charged membrane surfaces. Consequently, these results might explain how the molten globule state can be achieved under physiological conditions.