Oxygen-organophosphate linkage in hemoglobin A. The double hump effect

Exploring the role of receptor flexibility in structure-based drug discovery

The proper understanding of biomolecular recognition mechanisms that take place in a drug target is of paramount importance to improve the efficiency of drug discovery and development. The intrinsic dynamic character of proteins has a strong influence on biomolecular recognition mechanisms and models such as conformational selection have been widely used to account for this dynamic association process. However, conformational changes occurring in the receptor prior and upon association with other molecules are diverse and not obvious to predict when only a few structures of the receptor are available. In view of the prominent role of protein flexibility in ligand binding and its implications for drug discovery, it is of great interest to identify receptor conformations that play a major role in biomolecular recognition before starting rational drug design efforts. In this review, we discuss a number of recent advances in computer-aided drug discovery techniques that have been proposed to incorporate receptor flexibility into structure-based drug design. The allowance for receptor flexibility provided by computational techniques such as molecular dynamics simulations or enhanced sampling techniques helps to improve the accuracy of methods used to estimate binding affinities and, thus, such methods can contribute to the discovery of novel drug leads.

Thermodynamics of allostery paves a way to allosteric drugs

We overview here our recent work on the thermodynamic view of allosteric regulation and communication. Starting from the geometry-based prediction of regulatory binding sites in a static structure, we move on to exploring a connection between ligand binding and the intrinsic dynamics of the protein molecule. We describe here two recently introduced measures, binding leverage and leverage coupling, which allow one to analyze the molecular basis of allosteric regulation. We discuss the advantages of these measures and show that they work universally in proteins of different sizes, oligomeric states, and functions. We also point the problems that have to be solved before completing an atomic level description of allostery, and briefly discuss ideas for computational design of allosteric drugs. This article is part of a Special Issue entitled: The emerging dynamic view of proteins: Protein plasticity in allostery, evolution and self-assembly.

T-quaternary structure of oxy human adult hemoglobin in the presence of two allosteric effectors, L35 and IHP

The cooperative O(2)-binding of hemoglobin (Hb) have been assumed to correlate to change in the quaternary structures of Hb: T(deoxy)- and R(oxy)-quaternary structures, having low and high O(2)-affinities, respectively. Heterotropic allosteric effectors have been shown to interact not only with deoxy- but also oxy-Hbs causing significant reduction in their O(2)-affinities and the modulation of cooperativity. In the presence of two potent effectors, L35 and inositol hexaphosphate (IHP) at pH 6.6, Hb exhibits extremely low O(2)-affinities (K(T)=0.0085mmHg(-1) and K(R)=0.011mmHg(-1)) and thus a very low cooperativity (K(R)/K(T)=1.3 and L(0)=2.4). (1)H-NMR spectra of human adult Hb with these two effectors were examined in order to determine the quaternary state of Hb in solution and to clarify the correlation between the O(2)-affinities and the structural change of Hb caused by the heterotropic effectors. At pH 6.9, (1)H-NMR spectrum of deoxy-Hb in the presence of L35 and IHP showed a marker of the T-quaternary structure (the T-marker) at 14ppm, originated from inter- dimeric α(1)β(2)- (or α(2)β(1)-) hydrogen-bonds, and hyperfine-shifted (hfs) signals around 15-25ppm, caused by high-spin heme-Fe(II)s. Upon addition of O(2), the hfs signals disappeared, reflecting that the heme-Fe(II)s are ligated with O(2), but the T-marker signals still remained, although slightly shifted and broadened, under the partial pressure of O(2) (P(O2)) of 760mmHg. These NMR results accompanying with visible absorption spectroscopy and visible resonance Raman spectroscopy reveal that oxy-Hb in the presence of L35 and IHP below pH 7 takes the ligated T-quaternary structure under the P(O2) of 760mmHg. The L35-concentration dependence of the T-marker in the presence of IHP indicates that there are more than one kind of L35-binding sites in the ligated T-quaternary structure. The stronger binding sites are probably intra-dimeric binding sites between α(1)G- and β(1)G-helices, and the other weaker binding site causes the R→T transition without release of O(2). The fluctuation of the tertiary structure of Hb seems to be caused by both the structural perturbation of α(1)β(1) (or α(2)β(2)) intra-dimeric interface, where the stronger L35-binding sites exist, and by the IHP-binding to the α(1)α(2)- (or β(1)β(2)-) cavity. The tertiary structural fluctuation induced by the allosteric effectors may contribute to the significant reduction of the O(2)-affinity of oxy-Hb, which little depends on the quaternary structures. Therefore, the widely held assumptions of the structure-function correlation of Hb - [the deoxy-state]=[the T-quaternary structure]=[the low O(2)-affinity state] and [the oxy-state]=[the R-quaternary structure]=[the high O(2)-affinity state] and the O(2)-affiny of Hb being regulated by the T/R-quaternary structural transition - are no longer sustainable. This article is part of a Special Issue entitled: Allosteric cooperativity in respiratory proteins.

Neuroglobin and prion cellular localization: investigation of a potential interaction

Neuroglobin (Ngb) and the cellular prion protein (PrP(c)), proteins of unknown function in the nervous system, are known to be expressed in the retina and have been observed in different rat retinal cells. The retina is the site of the highest concentration for Ngb, a heme protein of similar size and conformation to myoglobin. In this study, we demonstrated by immunohistochemical analysis of retinal colocalization of Ngb and PrP(c) in the ganglion cell layer. Considering for these two a common protective role in relation to oxidative stress and a possible transient contact during migration of PrP(c) through the eye or upon neuronal degradation, we undertook in vitro studies of the interaction of the purified proteins. Mixing these two proteins leads to rapid aggregation, even at submicromolar concentrations. As observed with the use of dynamic light scattering, particles comprising both proteins evolve to hundreds of nanometers within several seconds, a first report showing that PrP(c) is able to form aggregates without major structural changes. The main effect would then appear to be a protein-protein interaction specific to the surface charge of the Ngb protein with PrP(c) N-terminal sequence. A dominant parameter is the solvent ionic force, which can significantly modify the final state of aggregation. PrP(c), normally anchored to the cell membrane, is toxic in the cytoplasm, where Ngb is present; this could suggest an Ngb function of scavenging proteins capable of forming deleterious aggregates considering a charge complementarity in the complex.

Allostery and cooperativity revisited

Although phenomenlogical models that account for cooperativity in allosteric systems date back to the early and mid-60's (e.g., the KNF and MWC models), there is resurgent interest in the topic due to the recent experimental and computational studies that attempted to reveal, at an atomistic level, how allostery actually works. In this review, using systems for which atomistic simulations have been carried out in our groups as examples, we describe the current understanding of allostery, how the mechanisms go beyond the classical MWC/Pauling-KNF descriptions, and point out that the "new view" of allostery, emphasizing "population shifts," is, in fact, an "old view." The presentation offers not only an up-to-date description of allostery from a theoretical/computational perspective, but also helps to resolve several outstanding issues concerning allostery.

Protein dynamics explain the allosteric behaviors of hemoglobin

Bohr, Hasselbalch, and Krogh discovered homotropic and heterotropic allosteric behaviors of hemoglobin (Hb) in 1903/1904. A chronological description since then of selected principal models of the allosteric mechanism of Hb, such as the Adair scheme, the MWC two-state concerted model, the KNF induced-fit sequential model, the Perutz stereochemical model, the tertiary two-state model, and the global allostery model (an expanded MWC models), is concisely presented, followed by analysis and discussion of their limitations and deficiencies. The determination of X-ray crystallographic structures of deoxy- and ligated-Hb and the structure-based stereochemical model by Perutz are an epoch-making event in this history. However, his assignment of low-affinity deoxy- and high-affinity oxy-quaternary structures of Hb to the T- and R-states, respectively, though apparently reasonable, and as well as his hypothesis that the T-/R-quaternary structural transition regulates the oxygen-affinity, have created confusions and side-tracked studies of Hb on the structure-function relationship. The differences in static molecular structures of Hb between T(deoxy)- and R(oxy)-quaternary states reported in detail by Perutz and others are ligation-linked structural changes, but not related to the control/regulation of the oxygen-affinity. The oxygen-affinity (K(T) and K(R)) of Hb has been shown to be regulated by the heterotropic effector-linked tertiary structural changes without involving the T/R-quaternary changes. However, a recent high-resolution crystallographic analysis of Hb with different oxygen-affinities shows that static molecular structures of Hb determined by crystallography can neither identify the nature of the T(low-affinity) functional state nor decipher the mechanism by which Hb stores free energy in the T(low-affinity) functional state. Molecular dynamics simulations show that fluctuations of helices of oxy-Hb are increased upon de-oxygenation and/or binding 2,3-biphosphoglycerate. These are known to lower the oxygen-affinity of Hb. It is proposed that the coordination mode of the heme Fe with proximal and distal His is modulated by these helical fluctuations, resulting in the modulation of the oxygen-affinity of Hb. Therefore, it is proposed that the oxygen-affinity of Hb is regulated by pentanary (the 5th-order time-dependent or dynamic) tertiary structural changes rather than the T-/R-quaternary structural transitions in Hb. Homotropic and heterotropic allosteric effects of Hb are oxygen- and effector-linked, conformational entropy-driven entropy-enthalpy compensation phenomena and not much to do with static structural changes. The dynamic allostery model, which integrates these observations, provides the structural basis for the global allostery model (an expanded MWC model).

The Oxygen Transport System in Three Species of the Boreal Fish Family Gadidae

The Arctic and Antarctic marine faunas differ by age and isolation. Fishes of the two polar regions have undergone different regional histories that have driven the physiological diversities. Antarctic fish are highly stenothermal, in keeping with stable water temperatures, whereas Arctic fish, being exposed to seasonal temperature variations, exhibit higher physiological plasticity. This study reports the characterization of the oxygen transport system of three Arctic species of the family Gadidae, namely the Arctic cod Arctogadus glacialis, the polar cod Boreogadus saida, and the Atlantic cod Gadus morhua. Unlike Antarctic notothenioids, the blood displays high multiplicity, i.e. it has three hemoglobins, similar to many other acanthomorph teleosts. In the most abundant hemoglobin, oxygen binding is modulated by heterotropic effectors, with marked Bohr and Root effects. Remarkably, in two species (A. glacialis and B. saida), the Hill coefficient is very close to one in the whole pH range, indicating the apparent absence of cooperativity. The amino acid sequences have been used to gain insight into the evolution history of globins of polar fish. The results indicate that Arctic and Antarctic globins have different phylogenies and lead us to suggest that the selective pressure of environment stability allows the phylogenetic signal to be maintained in the Antarctic sequences, whereas environmental variability would tend to disrupt this signal in the Gadidae sequences.

Ex vivo generation of fully mature human red blood cells from hematopoietic stem cells

We describe here the large-scale ex vivo production of mature human red blood cells (RBCs) from hematopoietic stem cells of diverse origins. By mimicking the marrow microenvironment through the application of cytokines and coculture on stromal cells, we coupled substantial amplification of CD34(+) stem cells (up to 1.95 x 10(6)-fold) with 100% terminal differentiation into fully mature, functional RBCs. These cells survived in nonobese diabetic/severe combined immunodeficient mice, as do native RBCs. Our system for producing 'cultured RBCs' lends itself to a fundamental analysis of erythropoiesis and provides a simple in vitro model for studying important human viral or parasitic infections that target erythroid cells. Further development of large-scale production of cultured RBCs will have implications for gene therapy, blood transfusion and tropical medicine.

Structure and function of the Gondwanian hemoglobin of Pseudaphritis urvillii, a primitive notothenioid fish of temperate latitudes

The suborder Notothenioidei dominates the Antarctic ichthyofauna. The non-Antarctic monotypic family Pseudaphritidae is one of the most primitive families. The characterization of the oxygen-transport system of euryhaline Pseudaphritis urvillii is herewith reported. Similar to most Antarctic notothenioids, this temperate species has a single major hemoglobin (Hb 1, over 95% of the total). Hb 1 has strong Bohr and Root effects. It shows two very uncommon features in oxygen binding: At high pH values, the oxygen affinity is exceptionally high compared to other notothenioids, and subunit cooperativity is modulated by pH in an unusual way, namely the curve of the Hill coefficient is bell-shaped, with values approaching 1 at both extremes of pH. Molecular modeling, electronic absorption and resonance Raman spectra have been used to characterize the heme environment of Hb 1 in an attempt to explain these features, particularly in view of some potentially important nonconservative replacements found in the primary structure. Compared to human HbA, no major changes were found in the structure of the proximal cavity of the alpha-chain of Hb 1, although an altered distal histidyl and heme position was identified in the models of the beta-chain, possibly facilitated by a more open heme pocket due to reduced steric constraints on the vinyl substituent groups. This conformation may lead to the hemichrome form identified by spectroscopy in the Met state, which likely fulfils a potentially important physiological role.

The functionally distinct hemoglobins of the Arctic spotted wolffish Anarhichas minor

The Arctic fish Anarhichas minor, a benthic sedentary species, displays high hemoglobin multiplicity. The three major hemoglobins (Hb 1, Hb 2, and Hb 3) show important functional differences in pH and organophosphate regulation, subunit cooperativity, and response of oxygen binding to temperature. Hb 1 and Hb 2 display a low, effector-enhanced Bohr effect and no Root effect. In contrast, Hb 3 displays pronounced Bohr and Root effects, accompanied by strong organophosphate regulation. Hb 1 has the beta (beta(1)) chain in common with Hb 2; Hb 3 and Hb 2 share the alpha (alpha(2)) chain. The amino acid sequences have been established. Several substitutions in crucial positions were observed, such as Cys in place of C-terminal His in the beta(1) chain of Hb 1 and Hb 2. In Hb 3, Val E11 of the beta(2) chain is replaced by Ile. Homology modeling revealed an unusual structure of the Hb 3 binding site of inositol hexakisphoshate. Phylogenetic analysis indicated that only Hb 2 displays higher overall similarity with the major Antarctic hemoglobins. The oxygen transport system of A. minor differs remarkably from those of Antarctic Notothenioidei, indicating distinct evolutionary pathways in the regulatory mechanisms of the fish respiratory system in the two polar environments.

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.

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

The Monod-Wyman-Changeux allosteric model parameters evaluated from accurate oxygen equilibrium curves (OECs) of hemoglobin that were measured in an extremely wide range of structural constraints, imposed by allosteric effectors, yielded a closed circle when log K(T) and log K(R) were plotted against log L(0) and log L(4), respectively, showing novel phenomena that L(0) and L(4) have a maximal value and a minimal value, respectively, and K(T) and K(R) vary by more than three orders of magnitude. These phenomena were successfully described by a global allostery model, which mathematically keeps the frame work of the MWC model, but allows that K(T) under a set of solution conditions becomes larger than K(R) under another set of solution conditions and postulates that a representative allosteric effector binds to both the T and R states with a lower affinity but with a larger stoichiometry for the R state than for the T state. Thus, this global model can describe any given OEC measured under universal solution conditions with the single adjustable parameter, the concentration of the representative effector.

CO binding and valency exchange in asymmetric Hb hybrids

There remains a major controversy concerning the properties of asymmetric hemoglobin hybrids, that is, doubly liganded tetramers consisting of an unliganded dimer and a liganded dimer. Different experimental evidence leads to opposing conclusions. Based on dimer-tetramer equilibrium studies, special "T-like" properties were assigned to this hybrid (species 21), while the other biliganded tetramers were considered as similar to fully liganded Hb [Ackers et al. (1992) Science 255, 54-63]. We report here results for three types of experiment. In the first, the asymmetric hybrids are produced by photodissociating CO ligands from [dimer-CO/dimer-azido-met] hybrids. Since the CO association rates differ by over an order of magnitude for the two allosteric states, the CO kinetics are a sensitive probe of the tetramer conformation. The results show mainly rapid R-like kinetics for CO rebinding to the asymmetric hybrids. The second technique employs a stopped-flow apparatus to obtain a higher percentage and a longer equilibration time of the asymmetric hybrid. In this case, sodium dithionite is used to remove oxygen from a solution containing [dimer-oxy/dimer-azido-met] hybrids. After a fixed delay (but before loss of azide ligands), a second mixing with a buffer equilibrated under CO allows observation of CO binding to species 21. As for the flash measurements, the kinetics show predominantly rapid CO binding, typical of the liganded (R-state) tetramer. The rapid CO binding is not in agreement with the predictions of a T-like conformation for species 21. One possible explanation is that the long incubation times used to study the dimer-tetramer equilibrium do not lead to a stable asymmetric hybrid, but rather a random distribution of oxidized subunits due to electron transfer between the iron atoms of the subunits [Shibayama et al. (1997) Biochemistry 36, 4375-4381]. We have repeated these experiments and confirm the valency exchange in a mixture of Hb A and S (or C) parent forms, as evidenced by compensating amounts of oxidation or reduction of the Hb parents.

Thermodynamics of inositol hexakisphosphate interaction with human oxyhemoglobin

The interaction of inositol hexakisphosphate (IHP) with oxygenated human adult hemoglobin (Hb) was investigated at 25 degreesC. The affinity of IHP for oxygenated Hb is strongly pH-dependent, and potentiometric measurements of proton uptake and release upon IHP addition have shown that over the range between pH 8.0 and pH 6.0 in oxygenated Hb there are three groups of residues that change their pKa values after IHP addition, likely because of their interaction with negative charges of the heterotropic effector. On the basis of previous calculations on the electrostatic properties of human Hb (Matthew, J. B., Hanania, G. I. H., and Gurd, F. R. N. (1979) Biochemistry 18, 1919-1928; Lee, A. W.-m., Karplus, M., Poyart, C., and Bursaux, E. (1988) Biochemistry 27, 1285-1301), two of these groups might be Val1beta and His143beta, which are located in the beta1beta2 dyad axis, where they have been also proposed to interact with 2,3-diphosphoglycerate, whereas the third group does not appear easily identifiable. Calorimetric measurements of the heat associated with IHP binding at different pH values over the same range indicate that IHP binding is mostly enthalpy-driven at pH < 7 and mostly entropy-driven at pH > 7.

Conformational fluctuations in deoxy hemoglobin revealed as a major contributor to anionic modulation of function through studies of the oxygenation and oxidation of hemoglobins A0 and Deer Lodge beta2(NA2)His --> Arg

Organisms rely on regulation at the molecular level, such as the allosteric regulation of hemoglobin (Hb) function by anions, to meet challenges presented by changing environmental and physiological conditions. A comparison of the effects of anions on oxygenation, oxidation, and sulfhydryl reactivity of Hb leads us to suggest that a large and significant part of the shift in oxygen affinity brought about by anion binding occurs as a result of increased conformational rigidity of the T state of deoxy Hb. As conformational rigidity increases, it becomes increasingly difficult for subunits in the deoxygenated T-state tetramer to assume higher oxygen affinity forms (T', T", T"'...) with less steric hindrance. The oxygen affinity reflects the average of the rapidly equilibrating conformations within the T state and is correspondingly decreased when anion levels are increased. The initial stage of the oxidation of Hb is relatively insensitive to steric alterations and thus reflects, primarily, the electronic aspects of the quaternary (T, T', T", T"'...) <--> equilibrium. We show that the reactivity of the sterically obscured sulfhydryl of beta93 Cys in deoxy Hb is much greater in chloride-free buffers than in buffers with added chloride. Anion-induced decreases in the extent and frequency of conformational fluctuations of subunits within the T-quaternary state thus reduce sulfhydryl reactivity as well as oxygen affinity. This parallel in anionic control of function allowed us to test, and disprove, the possibility that uncompensated positive charges in the central cavity of Hb Deer Lodge increase the frequency and extent of conformational fluctuations in its deoxy structure. This Hb variant exhibits increased anion sensitivity, increased oxygen affinity, and increased ease of oxidation, but without increased reactivity of its sulfhydryl groups, indicating that active-site alterations in deoxy Hb Deer Lodge are primarily electronic and not associated with increased conformational fluctuations within its T state. The restoration of normal properties in Hb Deer Lodge by addition of anions reinforces our conclusion that anionic control can be exerted through both steric and electronic alterations. The anionic control of fluctuations within the T state of Hb illustrates an important principle of macromolecular structure-function relationships: that functional regulation can be achieved by alterations in conformational rigidity.

Hb Godavari [alpha 95(G2)Pro-->Thr]: a neutral amino acid substitution in the alpha 1 beta 2 interface that modifies the electrophoretic mobility of hemoglobin

Hb Godavari [alpha 95(G2)Pro-->Thr] was characterized independently in two families of different ethnic origin. The first case, found in the Netherlands, involved an Indian patient. The second one was identified a few months later in an African family from Mali, living in France. Hb Godavari is the fourth example of a substitution involving neutral residues at position alpha 95(G2). In all these variants the electrophoretic pattern suggested that the structural modification unmasks a charged residue buried in the alpha 1 beta 2 contact area. The oxygen affinity of this abnormal hemoglobin was approximately 10% higher than that of Hb A; in the absence of 2,3-diphosphoglycerate, its cooperativity was moderately decreased, suggesting a slightly unstable T state.

Recombinant [Phe(beta)63]hemoglobin shows rapid oxidation of the beta chains and low-affinity, non-cooperative oxygen binding to the alpha subunits

We have engineered alpha2beta2 [Phe63]hemoglobin by changing the highly conserved distal histidine of the beta chains to a phenylalanine. The mutant tetramer binds four high-affinity ligands, such as CO or NO, to the ferrous form, or CN to the oxidized iron; however, it binds only two low-affinity ligands, oxygen and azide. The absorption spectrum of the ferrous deoxy or ferric forms are not normal, displaying an enhanced absorption of the visible band near 560 nm. Half of the autooxidation process, attributed to the mutated beta subunits, is over 1000-fold faster than for Hb A. The mutant Hb exhibits non-cooperative binding of two oxygens with an affinity about fivefold lower than those of HbA valency hybrids (alpha met beta)2. Functional properties of this mutant Hb resemble those of Hb Saskatoon ([Tyr63]Hb) [Suzuki, T., Hayashi, A., Shimizu, A. & Yamamura, Y. (1966) Biochim. Biophys. Acta 127, 280-282]. Flash-photolysis experiments also indicate non-cooperative behaviour: the CO-recombination kinetics were independent of the fraction dissociated. Furthermore, the amplitude of the CO bimolecular phase was the same for the (alpha(CO)metbeta)2 valency hybrid or the (alphaCO betaCO)2 form, suggesting mainly geminate CO-recombination kinetics to the beta chains. EPR and Resonance Raman spectra did not show evidence for a hemichrome, normally considered as a six-coordinated iron with low-spin character. The EPR and resonance Raman spectra for the mutated beta subunits demonstrate the presence of a high-spin compound in the ferric and deoxy ferrous forms. In particular, the ferrous mutated beta subunits are penta-coordinated. The abnormal absorption spectra are possibly due to an interaction between the porphyrin and the phenyl ring in the distal position rather than to direct binding to the iron.

Hb Bruxelles, deletion of Phebeta42, shows a low oxygen affinity and low cooperativity of ligand binding

Functional studies of partially purified hemoglobin (Hb) Bruxelles, Phebeta42 (CD1) --> 0 indicate a major shift in the allosteric equilibrium toward the deoxy (T state) conformation. While Hb A shows a roughly symmetrical oxygenation curve with maximum cooperativity near half-saturation, Hb Bruxelles shows mainly properties of the low affinity (T state) form. The oxygen equilibrium curves for purified (>80%) Hb Bruxelles show little cooperativity and a P50 (without 2,3-diphosphoglycerate) about twice that of Hb A. The low cooperativity for Hb Bruxelles is partially compensated by an increase in oxygen affinity of the deoxy conformation and a lower 2,3-diphosphoglycerate effect. The beta chains of normal Hb have consecutive phenylalanine residues at positions 41 and 42. DNA sequencing studies of Hb Bruxelles showed a deletion of the codon TTT, which corresponds to residue Phe42. The CO rebinding kinetics after flash photolysis show mainly the slow phase, characteristic of CO binding to the deoxy conformation. In phosphate buffer at pH 7, the slow phase dominates even at low photolysis levels, where the main reaction is ligand binding to the triply liganded form. This indicates a switchover point, from the deoxy to oxy conformation, occurring beyond three ligands for Hb Bruxelles. There are few natural mutants that show a change in the oxygen affinity and cooperativity as large as that observed for Hb Bruxelles.

Two mutations in recombinant Hb beta F41(C7)Y, K82 (EF6)D show additive effects in decreasing oxygen affinity

Based on the properties of two low oxygen affinity mutated hemoglobins (Hb), we have engineered a double mutant Hb (rHb beta YD) in which the beta F41Y substitution is associated with K82D. Functional studies have shown that the Hb alpha 2 beta 2(C7)F41Y exhibits a decreased oxygen affinity relative to Hb A, without a significantly increased autooxidation rate. The oxygen affinity of the natural mutant beta K82D (Hb Providence-Asp) is decreased due to the replacement of two positive charges by two negative ones at the main DPG-binding site. The functional properties of both single mutants are interesting in the view of obtaining an Hb-based blood substitute, which requires: (1) cooperative oxygen binding with an overall affinity near 30 mm Hg at half saturation, at 37 degrees C, and in the absence of 2,3 diphosphoglycerate (DPG), and (2) a slow rate of autooxidation in order to limit metHb formation. It was expected that the two mutations were at a sufficient distance (20 A) that their respective effects could combine to form low oxygen affinity tetramers. The double mutant does display additive effects resulting in a fourfold decrease in oxygen affinity; it can insure, in the absence of DPG, an oxygen delivery to the tissues similar to that of a red cell suspension in vivo at 37 degrees C. Nevertheless, the rate of autooxidation, 3.5-fold larger than that of Hb A, remains a problem.

Characterization of the interactions of NADH with the dimeric and tetrameric states of methaemoglobin

The binding of NADH to the dimeric (alpha beta) and tetrameric (alpha 2 beta 2) states of human aquomethaemoglobin has been characterized by sedimentation equilibrium studies of the effect of the concentration of free ligand on the macromolecular state of the haemoprotein. Both macromolecular states of aquomethaemoglobin exhibit a single binding site for NADH, which interacts approximately tenfold more strongly (6000 cf. 700 M-1) with the tetramer under the conditions studied (pH 6.0, I 0.10). Because the structure of aquomethaemoglobin resembles that of the deoxy state of haemoglobin, there is a high probability that organic phosphates also bind to dimeric deoxyhaemoglobin, a phenomenon which is not considered in thermodynamic treatments of the interplay between oxygen binding and its allosteric inhibition by 2,3-bisphosphoglycerate. Fortunately, the equilibrium constant for deoxyhaemoglobin self-association is so large that neglect of the interaction between allosteric inhibitor and dimeric haemoglobin is an oversight that should have no deleterious implications in the resultant thermodynamic analysis of the interplay between the preferential interactions of oxygen and organic phosphate with the various macromolecular states of deoxyhaemoglobin.

[Transfer of functional properties from bovine hemoglobin to human hemoglobin]

Bovine hemoglobin (Hb) has been proposed as a potential blood substitute because of its low intrinsic oxygen affinity in the absence of chloride anions and 2,3-diphosphoglycerate. The use of bovine blood as a source of Hb does not eliminate the risks of viral infections. Biotechnology techniques allow to produce modified recombinant Hbs. We have engineered human Hb mutants with the aim of mimicking the functional properties of bovine Hb. The argument for this work resides in the crystallographic studies and in the comparison of human and bovine beta globin sequences. The mutant recombinant Hbs exhibit the heterotropic effects of bovine Hb do not exhibit the low intrinsic oxygen affinity of bovine Hb.

[Recombinant human hemoglobin with low oxygen affinity: additional effects of two mutations]

The search for human Hb variants exhibiting a low oxygen affinity without requiring 2,3-diphosphoglycerate, together with a low oxygation rate, is of an increased interest in the view of producing an artificial oxygen carrier. We have synthesized the recombinant Hb beta 41Phe-->Tyr (rHb beta F41Y) which exhibits a low oxygen affinity due to the stabilization of the deoxy state of tetrameric Hb [1]. Interestingly, the autooxydation rate for this mutant is similar to that for Hb A. We have associated the mutation beta F41Y with the naturally occurring beta 82Lys-->Asp substitution (Hb Providence) known to be responsible for a low oxygen affinity [2]. The second-site mutation further decreases the oxygen affinity of the rHb beta F41Y. The effects of the beta F41Y and K82D mutations are additive, resulting in a four fold decrease in oxygen affinity of the artificial mutant Hb beta F41Y-K82D, compared to Hb A. In spite of the marked decrease in oxygen affinity, the autooxydation rate is 2- to 3 fold larger than that of Hb A. These data show that it is possible to adjust the oxygen binding properties of human Hb by using protein engineering methods. Because of the low oxygen affinity coexisting with a moderately increased autooxydation rate, this variant is a good candidate for the development of a Hb-based oxygen carrier.

Association of a novel high oxygen affinity haemoglobin variant with delta beta thalassaemia

We report an uncommon association of delta beta thalassaemia and a haemoglobin (Hb) variant with high oxygen affinity in an Asian Indian family. Minimal polycythaemia was seen in a heterozygote for this novel Hb variant, Hb Headington (beta 72 (E16) Ser-->Arg), while compound heterozygosity for Hb Headington and the Indian G gamma (A gamma delta beta)(0) thalassaemia produces a marked increase in erythrocytosis with a concomitant increase in the level of the variant Hb. The HbF in such compound heterozygotes remains at a level consistent with that usually observed in individuals heterozygous for the G gamma (A gamma delta beta)(0) thalassaemia alone. The purified Hb variant showed an increased oxygen affinity, moderately decreased co-operativity and a normal Bohr effect. Results of functional studies suggest that the high oxygen affinity of Hb Headington is due to the Ser-->Arg substitution which disrupts the normal and tight interaction between A, B and E helices leading to a destabilization of the T deoxy-structure of the abnormal haemoglobin.

Hb Poitiers [alpha 45(CE3)His-->Asp]: a new hemoglobin variant with a two-fold increase in oxygen affinity

Hb Poitiers or alpha 45(CE3)His-->Asp was found in a 9-year-old French Caucasian boy. The structural modification concerns a heme contact and is responsible for an increased oxygen affinity and a faster than normal rate of autooxidation.

Functional properties of beta(NA1)Val-deleted,(NA2)His-->Met hemoglobin synthesized in Escherichia coli

Bovine Hb (hemoglobin) has a low oxygen affinity in the absence of chloride ions and DPG. Because of the increasing interest of this Hb as a potential blood substitute we have engineered a human Hb mutant with the aim of mimicking the functional properties of bovine Hb. This was achieved by deleting residue beta NA1 Val and substituting a methionine for histidine at the beta NA2 position as previously suggested by Perutz and Imai in 1980. Our results show that the artificial mutant exhibits some of the characteristics of bovine Hb but does not show the low oxygen affinity which is measured in bovine blood.

Hb Villaverde [beta 89 (F5) Ser-->Thr]: the structural modification of an intrasubunit contact is responsible for a high oxygen affinity

Hb Villaverde [beta 89 (F5) Ser-->Thr], identified in a Spanish patient, is a new human hemoglobin variant, electrophoreticaly silent, responsible for a severe erythrocytosis. This abnormal hemoglobin displays a very high oxygen affinity and a markedly reduced cooperativity that is partly restored in the presence of IHP. Determination of the structural abnormality was achieved on a mixture of the normal and abnormal beta-chains. After isolation of the abnormal tryptic peptide by RP-HPLC, its sequence was determined by mass spectrometry. The structural abnormality disturbs the intrasubunit interaction between helices F and H and, thus, may weaken the C-terminal bonds of the deoxy conformation and the heme contacts of several hydrophobic residues. Hb Villaverde demonstrates that this intrasubunit contact between helices F and H is essential for the cohesion of the hemoglobin molecule.

Hb Val de Marne [alpha 133(H16)Ser-->Arg]: a new hemoglobin variant with moderate increase in oxygen affinity

Hb Val de Marne [alpha 133(H16)Ser-->Arg] was found in a French family during a neonatal hemoglobinopathy screening program. The abnormal hemoglobin was found, within a few months interval, in two newborn children who were first cousins. In the children as well as in the parents carrying this hemoglobin variant, the red cell parameters were normal. Hb Val de Marne, isolated by isoelectrofocusing, displayed a slightly higher auto-oxidation rate than Hb A. Its oxygen affinity was increased 1.7-fold in comparison to that of Hb A. The heterotropic effects were normal.

Functional consequences of mutations at the allosteric interface in hetero- and homo-hemoglobin tetramers

A seminal difference exists between the two types of chains that constitute the tetrameric hemoglobin in vertebrates. While alpha chains associate weakly into dimers, beta chains self-associate into tightly assembled tetramers. While heterotetramers bind ligands cooperatively with moderate affinity, homotetramers bind ligands with high affinity and without cooperativity. These characteristics lead to the conclusion that the beta 4 tetramer is frozen in a quaternary R-state resembling that of liganded HbA. X-ray diffraction studies of the liganded beta 4 tetramers and molecular modeling calculations revealed several differences relative to the native heterotetramer at the "allosteric" interface (alpha 1 beta 2 in HbA) and possibly at the origin of a large instability of the hypothetical deoxy T-state of the beta 4 tetramer. We have studied natural and artificial Hb mutants at different sites in the beta chains responsible for the T-state conformation in deoxy HbA with the view of restoring a low ligand affinity with heme-heme interaction in homotetramers. Functional studies have been performed for oxygen equilibrium binding and kinetics after flash photolysis of CO for both hetero- and homotetramers. Our conclusion is that the "allosteric" interface is so precisely tailored for maintaining the assembly between alpha beta dimers that any change in the side chains of beta 40 (C6), beta 99 (G1), and beta 101 (G3) involved in the interface results in increased R-state behavior. In the homotetramer, the mutations at these sites lead to the destabilization of the beta 4 hemoglobin and the formation of lower affinity noncooperative monomers.

Hemoglobin Rouen (alpha-140 (HC2) Tyr-->His): alteration of the alpha-chain C-terminal region and moderate increase in oxygen affinity

Hb Rouen (alpha 140(HC2) Tyr-->His) is a moderately high oxygen-affinity variant that was found in coincidence with polycythemia vera in a French patient. This hemoglobin provides an example of an alteration of the C-terminus of the alpha-chain, a region involved in the mechanisms of allosteric regulation. The increase in oxygen-affinity and decrease in cooperativity of this variant is much smaller than that resulting from the same substitution in the beta-chain. This model provides additional evidence for the inequivalence between the alpha- and beta-subunits.

HB Al-Ain Abu Dhabi [alpha 18(A16)Gly----Asp]: a new hemoglobin variant discovered in an Emiratee family

During a routine program of hemoglobin screening performed in the United Arab Emirates, we observed an electrophoretically fast-moving variant in a 9-month-old girl and in several members of her family. The structural determination, performed by reversed phase high performance liquid chromatography and amino acid sequencing, revealed a new variant that we named Hb Al-Ain Abu Dhabi [alpha 18(A16) Gly----Asp]. Its functional properties were normal.

Coupling of ferric iron spin and allosteric equilibrium in hemoglobin

The allosteric transition in triply ferric hemoglobin has been studied with different ferric ligands. This valency hybrid permits observation of oxygen or CO binding properties to the single ferrous subunit, whereas the liganded state of the other three ferric subunits can be varied. The ferric hemoglobin (Hb) tetramer in the absence of effectors is generally in the high oxygen affinity (R) state; addition of inositol hexaphosphate induces a transition towards the deoxy (T) conformation. The fraction of T-state formed depends on the ferric ligand and is correlated with the spin state of the ferric iron complexes. High-spin ferric ligands such as water or fluoride show the most T-state, whereas low-spin ligands such as cyanide show the least. The oxygen equilibrium data and kinetics of CO recombination indicate that the allosteric equilibrium can be treated in a fashion analogous to the two-state model. The binding of a low-spin ferric ligand induces a change in the allosteric equilibrium towards the R-state by about a factor of 150 (at pH 6.5), similar to that of the ferrous ligands oxygen or CO; however, each high-spin ferric ligand induces a T to R shift by a factor of 40.

Allosteric transition in triply met-haemoglobin

Methaemoglobin undergoes a transition to a T-like form at acid pH in the presence of strong effectors such as inositol hexakisphosphate (IHP), as evidenced by spectroscopic and oxidation potential measurements. Since oxygen and CO do not bind to the ferric haems, it is difficult to compare the properties of the R-met and T-met forms with those of ferrous haemoglobin. We have therefore prepared 90% oxidized samples, where the dominant signal for ligand (oxygen or CO) binding is due to tetramers with three met haems. Measurements were made of the oxygen equilibrium curves and CO rebinding kinetics after photodissociation. Without effectors, the partially oxidized samples show mainly R-state properties. Addition of IHP at acid pH induces an increase in T-state behaviour, as indicated by a lower oxygen affinity and a higher fraction of the slow bimolecular component for CO rebinding.

Hemoglobin Saint Mandé [beta 102 (G4) Asn----Tyr]. Functional studies and structural modeling reveal an altered T state

Oxygen equilibrium studies of purified hemoglobin Saint Mandé (Hb SM) [beta 102 (G4) Asn----Tyr] reveal a decreased oxygen affinity and cooperativity but to a lesser extent than found for Hb Kansas (beta 102 Thr). The low affinity of Hb SM depends on environmental conditions: eliminating chloride or raising the pH greatly elevated the ratio of p50 of Hb SM to that of Hb A. The alkaline Bohr effect is reduced by about 40%. The effects of anions (chloride, organophosphates) binding to deoxy Hb SM are also reduced. These data indicate that the functional properties of Hb SM are intermediary between Hb A and Hb Kansas. In addition, molecular graphics modeling of Hb SM in the oxy and deoxy structures indicate the possibility of a new hydrogen bond in the T state between beta(1)102 Tyr and alpha(2)42 Tyr. Stabilisation of the T state in this manner is a plausible explanation for several of the effects observed.

Hemoglobin Calais [beta 76 (E20) Ala----Pro]: a hemoglobin variant with decreased intrinsic oxygen affinity

Hb Calais [beta 76 (E20) Ala----Pro] is a new human hemoglobin variant displaying a decreased oxygen affinity. The only electrophoretical difference with Hb A was a slightly more acidic isoelectric point. A 2-fold decrease in the oxygen affinity was found by equilibrium measurements performed in a suspension of intact red blood cells and in the lysate. It was confirmed by kinetic studies of the purified abnormal hemoglobin. The rate of methemoglobin formation at 37 degrees C of Hb Calais was also increased relative to Hb A. The mechanism by which the Pro for Ala substitution of an external residue in the beta-chains results in these profound functional abnormalities is unclear. Subtle changes at the heme pocket, at a distance from the mutation, may be a plausible explanation for the effects observed.

Fitting abnormal oxygen equilibrium curves of hemoglobin

A growing number of oxygen equilibrium curves for hemoglobin (Hb) mutants, post-translational modifications, or the binding of potent new effectors of Hb cannot be fitted adequately with the two-state model. Examples are curves showing double maxima in the derivative of the Hill plot, or slopes of less than unity. We present such examples of modified hemoglobins and strong effectors in this study and calculate at which substate level the two-state model differs from the data. Analysis of hemoglobin oxygen equilibrium curves is reconsidered using the two-state model extended to allow variation of the individual substate probabilities. In this way the effect on the equilibrium due to perturbations in energy of each substate can be studied as a diagnostic tool.

Effectors of hemoglobin. Separation of allosteric and affinity factors

The relative contributions of the allosteric and affinity factors toward the change in p50 have been calculated for a series of effectors of hemoglobin (Hb). Shifts in the ligand affinity of deoxy Hb and the values for 50% ligand saturation (p50) were obtained from oxygen equilibrium data. Because the high-affinity parameters (liganded conformation) are poorly determined from the equilibrium curves, they were determined from kinetic measurements of the association and dissociation rates with CO as ligand. The CO on-rates were obtained by flash photolysis measurements. The off-rates were determined from the rate of oxidation of HbCO by ferricyanide, or by replacement of CO with NO. The partition function of fully liganded hemoglobin for oxygen and CO is only slightly changed by the effectors. Measurements were made in the presence of the effectors 2,3-diphosphoglycerate (DPG), inositol hexakisphosphate (IHP), bezafibrate (Bzf), and two recently synthesized derivatives of Bzf (LR16 and L35). Values of p50 change by over a factor of 60; the on-rates decrease by nearly a factor of 8, with little change in the off-rates for the liganded conformation. The data indicate that both allosteric and affinity parameters are changed by the effectors; the changes in ligand affinity represent the larger contribution toward shifts in p50.

Secondary structure determination for alpha-neurotoxin from Dendroaspis polylepis polylepis based on sequence-specific 1H-nuclear-magnetic-resonance assignments

Sequence-specific assignments are presented for the polypeptide backbone protons and a majority of the amino-acid-side-chain protons of alpha-neurotoxin from Dendroaspis polylepis polylepis, and individual amide proton-exchange rates with the solvent are reported. The secondary structure and the hydrogen-bonding patterns in the regular secondary structure elements are deduced from nuclear Overhauser effects and the sequence locations of the slowly exchanging amide protons. The molecule includes a three-stranded antiparallel beta-sheet, and there are indications that two additional short chain segments are arranged in an antiparallel beta-sheet. These structural elements are similar, but not identical, to either the secondary structure reported for erabutoxin b in single crystals, or the solution structure of cytotoxin CTXIIb from Naja mossambica mossambica.

Hemoglobin J Guantanamo [alpha 2 beta 2 128 (H6) Ala----Asp] in association with hemoglobin C and alpha-thalassemia in a family from Benin

Hemoglobin J (HbJ), Guantanamo, which had been described but once in the literature, was found in a family originating from Benin; this second case was found to be in association with hemoglobin C (HbC) and alpha-thalassemia. High-performance liquid chromatography (HPLC) procedures and microsequencing were used for characterization of the aminoacid substitution. The main hematological disorder, in relation with the instability of Hb J Guantanamo, seems to be a worsening of the rheological properties of the red blood cells (RBC), as demonstrated by ektacytometric studies. Oxygen-binding properties of the RBC were almost normal, but a slight decrease in cooperativity and lowered Bohr and 2,3-diphosphoglycerate (DPG) effects were observed for pure stripped Hb J Guantanamo. The expression of the electrophoretic charge difference was partly masked, as is often observed when the structural abnormality is situated in or near a contact area.