Ovalbumin, a member of the serpin superfamily, is transformed via an intermediate state into a non-cleaved, thermostabilized form (S-ovalbumin) during either the storage of unfertilized eggs or development of fertilized eggs; essentially the same thermostabilization also occurs upon in vitro incubation of isolated ovalubumin under alkaline conditions. To investigate the implications of a partial insertion of the alpha-helical serpin loop into beta-sheet A that has been proposed as a conformational mechanism for S-ovalbumin production, we examined the thermostabilization process of ovalbumin with different loop structures. When the thermostabilization processes were compared for the intact, P1-P1'-cleaved and P1-P1'/P8-P7-cleaved forms of egg white ovalbumin, both the rates for the conversion from the native to intermediate and from the intermediate to S-ovalbumin were almost indistinguishable among the three protein forms. Furthermore, the fully loop-inserted form of recombinant ovalbumin mutant R339T that had been thermostabilized by P1-P1' cleavage with Tm values from 72 to 88 degrees C was further thermostabilized by an alkaline treatment, yielding a final product (loop inserted S-ovalbumin) with a Tm value of 93 degrees C. No significant difference was found between native ovalbumin and S-ovalbumin in respect of the rate of proteolytic cleavage of the loop by elastase and subtilisin. These data strongly suggest that S-ovalbumin is produced by a mechanism other than that of the partial loop insertion model.