Description of hemoglobin oxygenation under universal solution conditions by a global allostery model with a single adjustable parameter

Cooperative oxygen binding in beta-semihemoglobins caused by a chemical modification in the alpha1beta1 interface

A beta-semihemoglobin is an alpha-beta dimer of hemoglobin (Hb) in which the beta-subunit carries heme, while the alpha-subunit is heme-less, in apo form. It is characterised by displaying a high affinity for oxygen, and absence of cooperative binding of oxygen. We have modified chemically the residue beta112Cys (G14), located adjacent to the alpha1beta1 interface, and studied the impact of such a modification on the oligomeric state and oxygenation properties of the derivatives. We also studied the impact of modifying beta93Cys (F9) since its modification was unavoidable. For this, we used N-Ethyl maleimide and iodoacetamide. For the alkylation of beta112Cys (G14) in isolated subunits, we used N-Ethyl maleimide, iodoacetamide, or additionally, 4,4'-Dithiopyridine. Seven native and chemically modified beta-subunit derivatives were prepared and analysed. Only those derivatives treated with iodoacetamide showed oxygenation properties that were indistinguishable from those of native beta-subunits. These derivatives were then converted into their respective semihemoglobin forms, and four additional derivatives were prepared and analysed .in terms of ligation-linked oligomeric state, and oxygenation function, and contrasted against native Hb and unmodified beta-subunits. Strikingly, beta-semiHbs with modifications in beta112Cys showed indications of cooperative oxygen binding in various degrees, which suggested the possibility of assembly of two beta-semiHbs. The derivative modified with 4-Thiopyridine in beta112Cys showed a highly cooperative binding of oxygen (nmax = 1.67). A plausible allosteric scheme that could explain allostery in beta-semiHb system is suggested.

Interfacial and distal-heme pocket mutations exhibit additive effects on the structure and function of hemoglobin

Protein engineering strategies seek to develop a hemoglobin-based oxygen carrier with optimized functional properties, including (i) an appropriate O 2 affinity, (ii) high cooperativity, (iii) limited NO reactivity, and (iv) a diminished rate of auto-oxidation. The mutations alphaL29F, alphaL29W, alphaV96W and betaN108K individually impart some of these traits and in combinations produce hemoglobin molecules with interesting ligand-binding and allosteric properties. Studies of the ligand-binding properties and solution structures of single and multiple mutants have been performed. The aromatic side chains placed in the distal-heme pocket environment affect the intrinsic ligand-binding properties of the mutated subunit itself, beyond what can be explained by allostery, and these changes are accompanied by local structural perturbations. In contrast, hemoglobins with mutations in the alpha 1beta 1 and alpha 1beta 2 interfaces display functional properties of both "R"- and "T"-state tetramers because the equilibrium between quaternary states is altered. These mutations are accompanied by global structural perturbations, suggesting an indirect, allostery-driven cause for their effects. Combinations of the distal-heme pocket and interfacial mutations exhibit additive effects in both structural and functional properties, contribute to our understanding of allostery, and advance protein-engineering methods for manipulating the O 2 binding properties of the hemoglobin molecule.

Nitrite reductase activity of sol-gel-encapsulated deoxyhemoglobin. Influence of quaternary and tertiary structure

Nitrite reductase activity of deoxyhemoglobin (HbA) in the red blood cell has been proposed as a non-nitric-oxide synthase source of deliverable nitric oxide (NO) within the vasculature. An essential element in this scheme is the dependence of this reaction on the quaternary/tertiary structure of HbA. In the present work sol-gel encapsulation is used to trap and stabilize deoxy-HbA in either the T or R quaternary state, thus allowing for the clear-cut monitoring of nitrite reductase activity as a function of quaternary state with and without effectors. The results indicate that reaction is not only R-T-dependent but also heterotropic effector-dependent within a given quaternary state. The use of the maximum entropy method to analyze carbon monoxide (CO) recombination kinetics from fully and partially liganded sol-gel-encapsulated T-state species provides a framework for understanding effector modulation of T-state reactivity by influencing the distribution of high and low reactivity T-state conformations.

Circular dichroism spectroscopy of tertiary and quaternary conformations of human hemoglobin entrapped in wet silica gels

The relative contributions to changes in visible and near UV circular dichroism spectra of hemoglobin of heme ligation and tertiary and quaternary conformational transitions were separated by exploiting the slowing down of structural relaxations for proteins encapsulated in wet, nanoporous silica gels. Spectral signatures, previously assumed to be characteristic of T and R quaternary states, were demonstrated to be specific to different tertiary conformations. The results support the view that ligation and allosteric effectors can modulate the structural and functional properties of hemoglobin by regulating the equilibrium between the same tertiary species within both quaternary states.

Modulation of reactivity and conformation within the T-quaternary state of human hemoglobin: the combined use of mutagenesis and sol-gel encapsulation

A range of conformationally distinct functional states within the T quaternary state of hemoglobin are accessed and probed using a combination of mutagenesis and sol-gel encapsulation that greatly slow or eliminate the T --> R transition. Visible and UV resonance Raman spectroscopy are used to probe the proximal strain at the heme and the status of the alpha(1)beta(2) interface, respectively, whereas CO geminate and bimolecular recombination traces in conjunction with MEM (maximum entropy method) analysis of kinetic populations are used to identify functionally distinct T-state populations. The mutants used in this study are Hb(Nbeta102A) and the alpha99-alpha99 cross-linked derivative of Hb(Wbeta37E). The former mutant, which binds oxygen noncooperatively with very low affinity, is used to access low-affinity ligated T-state conformations, whereas the latter mutant is used to access the high-affinity end of the distribution of T-state conformations. A pattern emerges within the T state in which ligand reactivity increases as both the proximal strain and the alpha(1)beta(2) interface interactions are progressively lessened after ligand binding to the deoxy T-state species. The ligation and effector-dependent interplay between the heme environment and the stability of the Trp beta37 cluster in the hinge region of the alpha(1)beta(2) interface appears to determine the distribution of the ligated T-state species generated upon ligand binding. A qualitative model is presented, suggesting that different T quaternary structures modulate the stability of different alphabeta dimer conformations within the tetramer.

New insights into the proton-dependent oxygen affinity of Root effect haemoglobins

A long-standing puzzle with regard to protein structure/function relationships is the proton-dependent modification of haemoglobin (Hb) structure that causes oxygen to be unloaded from Root effect Hbs into the swim bladders and eyes of fish even against high oxygen pressure gradients. Although oxygen unloading in Root effect Hbs has generally been attributed to proton-dependent stabilization of the T-state, protonation of Root effect Hbs can alter their ligand affinities in both R- and T-state conformations and either stabilize the T-state or destabilize the R-state. The C-terminal residues that are so important in the Bohr effect of human Hb appear to be involved in the Root effects of some fish Hbs and not in others, indicating that several evolutionary pathways have resulted in expression of highly pH-dependent Hbs. New data are presented that show surprising similarities in the pH- and anion-dependence of sulfhydryl group reactivity and anaerobic oxidation of human and fish Hbs. The available evidence supports the concept that in both Bohr effect and Root effect Hbs a large steric component acts in addition to quaternary shifts between R and T conformations to regulate ligand affinity. Allosteric effectors moderate these steric effects within both R- and T-state conformations and allow for an elegant match between Hb function and the wide-ranging physiological needs of diverse organisms.

R-state hemoglobin bound to heterotropic effectors: models of the DPG, IHP and RSR13 binding sites

We performed a docking study followed by a 500-ps molecular dynamics simulation of R-state human adult hemoglobin (HbA) complexed to different heterotropic effectors [2,3-diphosphoglycerate (DPG), inositol hexaphosphate (IHP), and 2-[4-[(3,5-dichlorophenylcarbamoyl)-]methyl]-phenoxy]-2-methylpropionic acid (RSR13)) to propose a molecular basis for recently reported interactions of effectors with oxygenated hemoglobin. The simulations were carried out with counterions and explicit solvation. As reported for T-state HbA, the effector binding sites are also located in the central cavity of the R-state and differ depending on effector anionic character. DPG and IHP bind between the alpha-subunits and the RSR13 site spans the alpha1-, alpha2- and beta2-subunits. The generated models provide the first report of the molecular details of R-state HbA bound to heterotropic effectors.

The global allostery model of hemoglobin: an allosteric mechanism involving homotropic and heterotropic interactions

Studies of the allosteric mechanism of hemoglobin (Hb) have evolved from phenomenological descriptions to structure-based molecular mechanisms, as the molecular structures of Hb in deoxy and ligated states have been elucidated. The MWC two-state concerted model has been the widely accepted as the most plausible of the allosteric mechanisms of Hb. It assumes that the O2-affinity of Hb is regulated/controlled primarily by the T/R quaternary structural transition and that heterotropic effectors bind preferentially to T (deoxy) Hb to shift the T/R allosteric equilibrium toward the T state. However, recent more comprehensive O2-binding measurements of Hb have revealed a new mechanism, the Global Allostery model. It describes that the O2-affinity and the cooperativity are modulated in greater extents and the Bohr effect is generated primarily by the tertiary structural changes in both T (deoxy) and R (ligated) states of Hb. Differential interactions of heterotropic allosteric effectors with both T (deoxy) and R (ligated) states of Hb induce these tertiary structural changes. The X-ray structure of a complex of R (ligated) Hb with BZF, a potent heterotropic effector, has revealed the stereo-chemical influence of these effectors on the structure of R (ligated) Hb, resulting in the reduction of the ligand affinity in R (ligated) Hb. This model stresses the fundamental importance of the heterotropic interactions in regulation/control of the functionality of Hb. They alter the tertiary structures of both T (deoxy) and R (oxy) Hb, leading to large-scale modulations of the O2 affinity (KT and KR), and consequently the cooperativity (KR/KT) and the Bohr effect (delta P50/delta pH) from a global viewpoint of allostery in Hb.

Domain-specific effector interactions within the central cavity of human adult hemoglobin in solution and in porous sol-gel matrices: evidence for long-range communication pathways

The water-filled central cavity of human adult hemoglobin (Hb A) is the binding or interaction site for many different allosteric effectors. Oxygen binding titrations reveal that pyrenetetrasulfonate (PyTS), a fluorescent analogue of 2,3-diphosphoglycerate, behaves like an allosteric effector. The ligation state, pH, and concentrations of other effectors (IHP, L35, and chloride) alter PyTS fluorescence for both solution-phase and sol-gel-encapsulated Hb samples. These conditions also alter the resonance Raman spectra and rates of geminate recombination of CO-ligated Hb. Together, these results demonstrate that there are conformational and functional consequences resulting from interactions between specific domains of the central cavity and individual effectors as well as from long-range synergistic effects that are mediated through the central cavity.

Global allostery model of hemoglobin. Modulation of O(2) affinity, cooperativity, and Bohr effect by heterotropic allosteric effectors

The O(2) equilibria of human adult hemoglobin have been measured in a wide range of solution conditions in the presence and absence of various allosteric effectors in order to determine how far hemoglobin can modulate its O(2) affinity. The O(2) affinity, cooperative behavior, and the Bohr effect of hemoglobin are modulated principally by tertiary structural changes, which are induced by its interactions with heterotropic allosteric effectors. In their absence, hemoglobin is a high affinity, moderately cooperative O(2) carrier of limited functional flexibility, the behaviors of which are regulated by the homotropic, O(2)-linked T/R quaternary structural transition of the Monod-Wyman-Changeux/Perutz model. However, the interactions with allosteric effectors provide such "inert" hemoglobin unprecedented magnitudes of functional diversities not only of physiological relevance but also of extreme nature, by which hemoglobin can behave energetically beyond what can be explained by the Monod-Wyman-Changeux/Perutz model. Thus, the heterotropic effector-linked tertiary structural changes rather than the homotropic ligation-linked T/R quaternary structural transition are energetically more significant and primarily responsible for modulation of functions of hemoglobin.