The identity of intermolecular contact residues in sickle hemoglobin (HbS) fiber is largely known. However, our knowledge about combinatorial effects of two or more contact sites or the mechanistic basis of such effects is rather limited. Lys16, His20, and Glu23 of the alpha-chain occur in intra-double strand axial contacts in the sickle hemoglobin (HbS) fiber. Here we have constructed two novel double mutants, HbS (K16Q/E23Q) and (H20Q/E23Q), with a view to delineate cumulative impact of interactions emanating from the above contact sites. Far-UV and visible region CD spectra of the double mutants were similar to the native HbS indicating the presence of native-like secondary and tertiary structure in the mutants. The quaternary structures in both the mutants were also preserved as judged by the derivative UV spectra of liganded (oxy) and unliganded (deoxy) forms of the double mutants. However, the double mutants displayed interesting polymerization behavior. The polymerization behaviour of the double mutants was found to be non-additive of the individual single mutants. While HbS (H20Q/E23Q) showed inhibitory effect similar to that of HbS (E23Q), the intrinsic inhibitory propensity of the associated single mutants was totally quelled in HbS (K16Q/E23Q) double mutant. Molecular dynamics (MD) simulations studies of the isolated alpha-chains as well as a module of the fiber containing the double and associated single mutants suggested that these contact sites at the axial interface of the fiber impact HbS polymerization through a coupled interaction network. The overall results demonstrate a subtle role of dynamics and electrostatics in the polymer formation and provide insights about interaction-linkage in HbS fiber assembly.
The AB and GH regions of the ␣-chain are located in spatial proximity and contain a cluster of intermolecular contact residues of the sickle hemoglobin (HbS) fiber. We have examined the role of dynamics of AB/GH region on HbS polymerization through simultaneous replacement of non-contact Ala 19 and Ala 21 of the AB corner with more flexible Gly or rigid ␣-aminoisobutyric acid (Aib) residues. The polymerization behavior of HbS with Aib substitutions was similar to the native HbS. In contrast, Gly substitutions inhibited HbS polymerization. Molecular dynamics simulation studies of ␣-chains indicated that coordinated motion of AB and GH region residues present in native (Ala) as well as in Aib mutant was disrupted in the Gly mutant. The inhibitory effect due to Gly substitutions was further explored in triple mutants that included mutation of an inter-doublestrand contact (␣Asn 78 3 His or Gln) at the EF corner. Although the inhibitory effect of Gly substitutions in the triple mutant was unaffected in the presence of ␣Gln 78 , His at this site almost abrogated its inhibitory potential. The polymerization studies of point mutants (␣Gln 78 3 His) indicated that the inhibitory effect due to Gly substitutions in the triple mutant was synergistically compensated for by the polymerization-enhancing activity of His 78 . Similar synergistic coupling, between ␣His 78and an intra-double-strand contact point (␣16) mutation located in the AB region, was also observed. Thus, two conclusions are made: (i) Gly mutations at the AB corner inhibit HbS polymerization by perturbing the dynamics of the AB/GH region, and (ii) perturbations of AB region (through changes in dynamics of the AB/GH region or abolition of a specific fiber contact site) that influence HbS polymerization do so in concert with ␣78 site at the EF corner. The overall results provide insights about the interaction-linkage between distant regions of the HbS tetramer in fiber assembly.Sickle cell anemia arises because of a point mutation at the sixth position of the -chain (Glu 6 3 Val) in the hemoglobin (Hb) 1 molecule (1). Deoxygenated sickle hemoglobin (HbS) polymerizes into long helical fibers that are believed to be responsible for the pathophysiology of the sickle cell disease. The knowledge gleaned so far from structural analysis of HbS crystal (2-4), solution polymerization studies of natural variants or engineered mutant hemoglobins (5-24), and electron microscopic studies (25) have led to a 14-stranded model of the fiber (26, 27). These strands appear as seven double strands of the type found in HbS crystals, albeit with a slight twist caused by fiber packing. The models specify several amino acid residues from both ␣-and -chains that participate in inter-or intradouble-strand contacts stabilizing the fiber structure. By and large, the fiber models agree with the solution polymerization experiments of mutant hemoglobins in that polymerizationsensitive mutations are usually located in fiber contact regions (27). However, the models present an approximate...
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