Heme-copper oxidases have two putative proton channels, the so-called K-channel and the membrane-spanning D-channel. The latter contains a number of polar groups with glutamate-286 located in its center, which could-together with bound water-contribute to a transmembrane hydrogen-bonded network. Protonation states of carboxyl groups from cytochrome bo3 of Escherichia coli were studied by redox Fourier transform infrared (FTIR) difference spectroscopy. A net absorbance increase in the carboxyl region was observed upon reduction. The band signature typically found in heme-copper oxidases comprises an absorbance decrease (reduced-minus-oxidized difference spectra) at 1745 cm-1 and increase at 1735 cm-1. No significant changes in the carboxyl region were found in the site-specific mutants D135E and D407N. The difference bands were lacking in redox spectra of mutants at position 286; they could clearly be related to Glu-286. In wild-type oxidase, the pK of Glu-286 appears to be higher than 9.8. Upon solvent isotope exchange from H2O to D2O, the band at 1745 cm-1 shifts more readily than the one at 1735 cm-1, indicating dissimilar accessibility of the carboxyl side chain to the hydrogen-bonded network in both redox states. The data are consistent with a redox-triggered conformational change of Glu-286, which attributes to the carboxyl group an orientation toward the interior of the D-channel for the oxidized form. The change of Glu-286 is retained in cyanide complexes of cytochrome bo3 and of cytochrome c oxidase; therefore it should be related to oxidoreduction of the heme b and/or CuB metal centers.