Abstract
Human α-hemoglobin stabilizing protein (AHSP) is a conserved mammalian erythroid protein that facilitates the production of Hemoglobin A by stabilizing free α-globin. AHSP rapidly binds to ferrous α with association (k'(AHSP)) and dissociation (k(AHSP)) rate constants of ≈10 μm(-1) s(-1) and 0.2 s(-1), respectively, at pH 7.4 at 22 °C. A small slow phase was observed when AHSP binds to excess ferrous αCO. This slow phase appears to be due to cis to trans prolyl isomerization of the Asp(29)-Pro(30) peptide bond in wild-type AHSP because it was absent when αCO was mixed with P30A and P30W AHSP, which are fixed in the trans conformation. This slow phase was also absent when met(Fe(3+))-α reacted with wild-type AHSP, suggesting that met-α is capable of rapidly binding to either Pro(30) conformer. Both wild-type and Pro(30)-substituted AHSPs drive the formation of a met-α hemichrome conformation following binding to either met- or oxy(Fe(2+))-α. The dissociation rate of the met-α·AHSP complex (k(AHSP) ≈ 0.002 s(-1)) is ∼100-fold slower than that for ferrous α·AHSP complexes, resulting in a much higher affinity of AHSP for met-α. Thus, in vivo, AHSP acts as a molecular chaperone by rapidly binding and stabilizing met-α hemichrome folding intermediates. The low rate of met-α dissociation also allows AHSP to have a quality control function by kinetically trapping ferric α and preventing its incorporation into less stable mixed valence Hemoglobin A tetramers. Reduction of AHSP-bound met-α allows more rapid release to β subunits to form stable fully, reduced hemoglobin dimers and tetramers.
Highlights
Hemoglobin A (HbA)2 is a highly conserved dioxygen transport protein present in red cells of all mature, healthy verte
In agreement with work done by Gell et al [16], we report that the affinity of AHSP is dependent on ␣ oxidation state and for the first time show that the rate of met-␣ dissociation from AHSP is dramatically slower than that for reduced ␣ dissociation
The two phases observed for the reaction of ␣WT with AHSPWT (Figs. 1 and 4) seem to verify the structural heterogeneity first characterized by Santiveri et al [13]
Summary
Hemoglobin A (HbA) is a highly conserved dioxygen transport protein present in red cells of all mature, healthy verte-. HbA production includes ␣ and  gene transcription and translation, subunit folding, heme binding to the aposubunits, redox regulation, and subunit assembly into tetramers [5,6,7,8,9]. Questions remain regarding its role in ␣ prosthetic group acquisition, oxidation state maintenance, subunit folding, and stabilization prior to incorporation into HbA. Experiments with clinically significant and rationally selected AHSP and ␣ mutants revealed the functional wild-type AHSP with an N-terminal Gly-Ser dipeptide; WT, wild-type  subunits; Hb, hemoglobin; heme, ferroprotoporphyrin IX; hemin, ferriprotoporphyrin IX; met, ferric oxidation state. This work suggests that AHSP stabilizes ␣ in vivo by preferentially binding an oxidized ␣ hemichrome folding intermediate and temporarily impairing ␣ assembly into HbA until reduction to the ferrous state has occurred
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