Protein splicing is a posttranslational autocatalytic process in which an intervening sequence, termed an intein, is removed from a host protein, the extein. Although we have a reasonable picture of the basic chemical steps in protein splicing, our knowledge of how these are catalyzed and regulated is less well developed. In the current study, a combination of NMR spectroscopy and segmental isotopic labeling has been used to study the structure of an active protein splicing precursor, corresponding to an N-extein fusion of the Mxe GyrA intein. The (1)J(NC') coupling constant for the (-1) scissile peptide bond at the N-extein-intein junction was found to be approximately 12 Hz, which indicates that this amide is highly polarized, perhaps because of nonplanarity. Additional mutagenesis and NMR studies indicate that conserved box B histidine residue is essential for catalysis of the first step of splicing and for maintaining the (-1) scissile bond in its unusual conformation. Overall, these studies support the "ground-state destabilization" model as part of the mechanism of catalysis.