Green fluorescent protein has revolutionized cell labeling and molecular tagging, yet the driving force and mechanism for its spontaneous fluorophore synthesis are not established. Here we discover mutations that substantially slow the rate but not the yield of this posttranslational modification, determine structures of the trapped precyclization intermediate and oxidized postcyclization states, and identify unanticipated features critical to chromophore maturation. The protein architecture contains a dramatic Ϸ80°bend in the central helix, which focuses distortions at G67 to promote ring formation from amino acids S65, Y66, and G67. Significantly, these distortions eliminate potential helical hydrogen bonds that would otherwise have to be broken at an energetic cost during peptide cyclization and force the G67 nitrogen and S65 carbonyl oxygen atoms within van der Waals contact in preparation for covalent bond formation. Further, we determine that under aerobic, but not anaerobic, conditions the Gly-Gly-Gly chromophore sequence cyclizes and incorporates an oxygen atom. These results lead directly to a conjugation-trapping mechanism, in which a thermodynamically unfavorable cyclization reaction is coupled to an electronic conjugation trapping step, to drive chromophore maturation. Moreover, we propose primarily electrostatic roles for the R96 and E222 side chains in chromophore formation and suggest that the T62 carbonyl oxygen is the base that initiates the dehydration reaction. Our molecular mechanism provides the basis for understanding and eventually controlling chromophore creation.T he Aequorea victoria green fluorescent protein (GFP) undergoes a remarkable posttranslational modification to create a chromophore out of its amino acids (S65, Y66, and G67) (1-3). GFP is small (238 aa), tolerates both N-and C-terminal fusions, and can be targeted to specific cellular locations (4). Synthesis of the GFP fluorophore occurs spontaneously after protein folding without cofactors or accessory proteins (5), making GFP-protein fusions tractable in a variety of organisms. GFP mutants and homologs exhibit fluorescent emission maxima ranging from blue to red (3, 6-8), which allow concurrent surveillance of multiple targets. Together, these properties have fundamentally altered in vivo molecular tagging and cell labeling. In addition, GFP-based indicators monitor cellular redox potential (9), pH (10, 11), metal ion concentrations (12, 13), and halide levels (14, 15). Because of these applications and the novel fluorophore, there have been extensive structural, spectroscopic, and biochemical characterizations of the protein and its mutants, all in the mature chromophore state (4, 16). The crystallographic structure of GFP reveals that the overall fold is an 11-stranded antiparallel -barrel protein with the chromophore located near the geometric center of the barrel on a distorted ␣-helix (1, 17). Few molecular details are known about chromophore maturation.The proposed fluorophore formation mechanism entails three steps: ...
