Conformational changes in tertiary structure near the ligand binding site of an integrin I domain

For efficient ligand binding, integrins must be activated. Specifically, a conformational change has been proposed in a ligand binding domain present within some integrins, the inserted (I) domain [Lee, J., Bankston, L., Arna out, M. & Liddington, R. C. (1995) Structure (London) 3, 1333-1340]. This p roposal remains controversial, however, despite extensive crystal structure studies on the I domain [Lee, J., Bankston, L., Arnaout, M. & Liddington, R C. (1995) Structure (London) 3, 1333-1340; Liddington, R. & Bankston, L. (1998) Structure (London) 6, 937-938; Qu, A. & Leahy, D. J. (1996) Structur e (London) 4, 931-942; and Baldwin, E. T., Sarver, R. W., Bryant; G. L., Jr ., Curry, K. A., Fairbanks, M. B., Finzel, B. C., Garlick, R. L., Heinrikso n, RL., Horton, N. C. & Belly, L. L. (1998) Structure (London) 6, 923-935]. By defining the residues present in the epitope of a mAb against the human Mac-1 integrin (alpha<beta 2, CD11b/CD18) that binds only the active recep tor, we provide biochemical evidence that the I domain itself undergoes a c onformational change with activation. This mAb, CBRM1/5, binds the I domain very close to the ligand binding site in a region that is widely exposed r egardless of activation as judged by reactivity with other antibodies. The conformation of the epitope differs in two crystal forms of the I domain, p reviously suggested to represent active and inactive receptor. Our data sug gests that conformational differences in the I domain are physiologically r elevant and not merely a consequence of different crystal lattice interacti ons. We also demonstrate that the transition between the two conformational states depends on species-specific residues at the bottom of the I domain, which are proposed to be in an interface with another integrin domain, and that this transition correlates with functional activity.