To determine the energetic contribution of the hydrogen bond between betaHis81 of the major histocompatibility complex class II (MHC II) molecule, I-E(k), and the bound hemoglobin peptide (Hb), we analyzed the thermal stability of the hydrogen bond-disrupted mutant, I-E(k)-Hb betaH81Y, in which the betaHis81 residue was replaced with Tyr, by differential scanning calorimetry. The thermal stability of the I-E(k)-Hb betaH81Y mutant was lower than that of the I-E(k)-Hb wild-type, mainly due to the decreased enthalpy change. The difference in the denaturation temperature of the I-E(k)-Hb betaH81Y mutant as compared with that of the I-E(k)-Hb wild-type at pH 5.5 was only slightly smaller than that at pH 7.4, in agreement with the increased stability at an acidic pH, a unique characteristic of MHC II. Thus, the hydrogen bond contributed by betaHis81 is critical for peptide binding, and is independent of pH, which can alter the hydrophilicity of the His residue.