The crystal structures of R- and T-state hemoglobin (Hb) Bassett have been determined to 2.15 and 1.80 A resolution, respectively. Physiologically, Hb Bassett (alphaAsp94-->Ala) is characterized by a low affinity for oxygen, a reduced Bohr effect and low cooperativity, as well as being slightly unstable (compared with normal adult hemoglobin; HbA). Comparisons between the Hb Bassett structures and previously determined R- and T-state HbA structures revealed that this mutant shares similar tertiary and quaternary structures with other Hbs. However, this analysis did identify localized structural differences between R-state Hb Bassett and R-state HbA at the alpha1beta2 (alpha2beta1) dimer interface and at the beta-cleft. Specifically, the beta-FG corner has shifted closer to the alpha-C helix in the mutant R structure. In addition, four intersubunit hydrogen bonds found at the alpha1beta2 interfaces of native R-state Hb structures are abolished or weakened and subsequently replaced by two new intersubunit hydrogen bonds in R-state Hb Bassett. Remarkably, the newly formed hydrogen bonds in the R-state mutant structure are also observed in T-state Hb structures. At the beta-cleft, betaHis46, which is known to contribute to the Bohr effect in Hb, makes a unique hydrogen-bonding interaction with betaAsn139 in the R-state Hb Bassett. Unlike the R-state mutant, the T-state Hb Bassett structure does not display any significant structural changes at both the alpha1beta2 (alpha2beta1) dimer interface and the beta-cleft. Quite significantly, the mutation has led to removal of an interdimer repulsion involving alpha1Asp94 and beta2Asp99. The R- and T-state structures of Hb Bassett suggest a stereochemical basis for the observed functional properties of this mutant.