Abstract
Mutations in hemoglobin can cause a wide range of phenotypic outcomes, including anemia due to protein instability and red cell lysis. Uncovering the biochemical basis for these phenotypes can provide new insights into hemoglobin structure and function as well as identify new therapeutic opportunities. We report here a new hemoglobin α chain variant in a female patient with mild anemia, whose father also carries the trait and is from the Turkish city of Kirklareli. Both the patient and her father had a His-58(E7) → Leu mutation in α1. Surprisingly, the patient's father is not anemic, but he is a smoker with high levels of HbCO (∼16%). To understand these phenotypes, we examined recombinant human Hb (rHb) Kirklareli containing the α H58L replacement. Mutant α subunits containing Leu-58(E7) autoxidize ∼8 times and lose hemin ∼200 times more rapidly than native α subunits, causing the oxygenated form of rHb Kirklareli to denature very rapidly under physiological conditions. The crystal structure of rHb Kirklareli shows that the α H58L replacement creates a completely apolar active site, which prevents electrostatic stabilization of bound O2, promotes autoxidation, and enhances hemin dissociation by inhibiting water coordination to the Fe(III) atom. At the same time, the mutant α subunit has an ∼80,000-fold higher affinity for CO than O2, causing it to rapidly take up and retain carbon monoxide, which prevents denaturation both in vitro and in vivo and explains the phenotypic differences between the father, who is a smoker, and his daughter.
Highlights
Mutations in hemoglobin can cause a wide range of phenotypic outcomes, including anemia due to protein instability and red cell lysis
We measured for the first time the rates of autoxidation, hemin loss, and precipitation of recombinant human Hb (rHb) Kirklareli, and we have shown how carbon monoxide (CO) binding to the mutant ␣ subunit stabilizes the protein and inhibits its oxidative degradation both in vitro and in vivo
The clinical phenotypes of over 125 different hemoglobinopathies were interpreted in terms of structural alterations in globin structure
Summary
Hematological Analyses for the Patient—The propositus was a 21-year-old Turkish female diagnosed with iron deficiency anemia (IDA). The MS/MS spectrum of its triple charge ion at m/z 565.66 yielded an amino acid sequence of a normal ␣A6 peptide except that the histidine at position 58 was replaced by a leucine or isoleucine (Fig. 3). We tried to examine O2 equilibrium binding to rHb Kirklareli and a small amount of native Hb Kirklareli purified from the patient’s blood (see Fig. 4) These experiments proved to be very difficult, because the HbCO Kirklareli samples require oxidation to remove all CO bound to the mutant ␣ subunits and a reduction in air to generate an unstable HbO2 form. In deoxygenated native ␣ subunits, a distal pocket water molecule is present in the active site, stabilized by hydrogen bonding to the distal histidine, and must be displaced before ligands can bind.
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
