Slow alpha helix formation during folding of a membrane protein

Very little is known about the folding of proteins within biological membranes. A ''two-stage'' model has been proposed on thermodynamic grounds for the folding of ct helical, integral membrane proteins, the first stage of which involves formation of transmembrane a helices that are proposed to behave as autonomous folding domains. Here, we investigate ct helix formation in bacteriorhodopsin and present a time-resolved circular dichroism study of the slow ia vitro folding of this protein. We show that, although some of the protein's a helices form early, a significant part sf the protein's secondary structure appears to form late in the folding process. Over 30 amino acids, equivalent to at least one of bacteriorhodopsin's seven transmembrane segments, slowly fold from disordered structures to ct helices with an apparent rate constant of about 0.012 s(-1) at pH 6 or 0.0077 s(-1) at pH 8. This is a rate-limiting step in protein folding, which is dependent on the pH and the composition of the lipid bilayer.