Insertion of the reactive center loop in beta-sheet A in serpins has been typically inferred from the increased stability of the cleaved form to thermal- and urea-induced denaturation. We describe a convenient and rapid fluorescence-based method that differentiates the loop-inserted form from the loop-exposed form in ovalbumin, a prototypic noninhibitory serpin. Recombinant wild-type and R345A ovalbumins in the intact form bind ANS with equilibrium dissociation constants of 116 and 125 microM and a maximal fluorescence increase of 200 and 264%, respectively, in pH 6.8 buffer. Cleavage of the two proteins with porcine pancreatic elastase results in a 1.6- and 2.6-fold increase in the ANS-binding affinity. While cleavage of the reactive center loop in rR345A ovalbumin results in a approximately 200% increase in the ANS fluorescence, the rWT protein exhibits a approximately 50% decrease. Similar experiments with alpha(1)-proteinase inhibitor and antithrombin, two inhibitory serpins that exhibit reactive center loop insertion, show a decrease in ANS fluorescence on cleavage with porcine pancreatic elastase and thrombin, respectively. Denaturation studies in guanidinium hydrochloride indicate that the reactive center loop is inserted in the main body of the serpin in the cleaved form of rR345A mutant, while it is exposed in the cleaved form of rWT ovalbumin. These results demonstrate that ANS fluorescence change is an indicator of the loop-inserted or loop-exposed form in these recombinant ovalbumins, and thus could be advantageously used for probing reactive center loop insertion in ovalbumins. The major increase in fluorescence for the rR345A mutant on cleavage primarily arises from a change in ANS binding rather than from the generation of an additional ANS-binding site.