Distinct chromatographic forms of human hemi-myeloperoxidase obtained by reductive cleavage of the dimeric enzyme. Evidence for subunit heterogeneity

The enzyme myeloperoxidase (MPO) is a functionally important glycoprotein of neutrophilic granulocytes and occurs in three major isoforms (forms 1, 2, and 3) that are dimeric structures composed of two heavy subunit-light subunit protomers, each of which is associated with a chlorine-like prosthetic group. In the present study, highly purified MPO isoforms were obtained from the cells of a single normal donor, and each protein was subjected to reductive alkylation under nondenaturing conditions. The resulting enzymatically active protomers were separated from unreacted dimer using gel filtration chromatography. Use of a fast protein liquid chromatography cation exchange system with a Mono S matrix revealed heterogeneity of the protomers, and allowed essentially complete resolution of the protomers of MPO form 2. Sodium dodecyl sulfate-polyacrylamide gel electrophoresis of the two resolved protomeric species under reducing conditions revealed small but reproducible differences in the Mr of their heavy subunits (59,000 and 57,000). Treatment with either endo-beta-N-acetylglucosaminidase or peptide N-glycohydrolase F reduced the Mr of each heavy subunit by approximately 3000 but did not change their relative electrophoretic mobilities. Heavy and light subunits were prepared from each of the MPO isoforms by reductive alkylation under conditions that allowed full retention of the prosthetic group with the heavy subunit. Reverse-phase chromatography and amino-terminal sequencing showed that each MPO isoform contained one major species of light subunit and several minor species. No differences in peroxidatic activity or inhibition by salicylhydroxamic acid were observed among any of the MPO isoforms or resolved protomers, but the latter were considerably more heat labile than dimeric forms of the enzyme and a monomeric form isolated from HL-60 cells. This is the first report of the isolation and partial characterization of distinct protomers from a single isoform of human MPO and suggests that the structure of MPO is more complex than considered previously.