Structures of deoxy and carbonmonoxy haemoglobin Kansas in the deoxy quaternary conformation.

Haemoglobin Kansas (Asn102(G4)β → Thr) is the only widely studied mutant or modified haemoglobin having four functional haems and displaying lower than normal oxygen affinity. Two forms of this mutant have been investigated by X-ray diffraction. The deoxy form, whose crystals are isomorphous with the native form, has been examined directly by the difference Fourier technique (3.4 Å). In addition to the replaced residue itself, the difference electron density map shows signs of slight movements throughout the region between α and β haem pockets. However, neither type of chain shows stereochemical evidence of a very abnormal oxygen affinity in the tetramer. The nature of the perturbation is different from that proposed in the earlier, low-resolution study of Greer (1971a). Exposure of deoxy crystals to carbon monoxide produces two new crystal forms similar but not identical to the native deoxy form. One of these structures has been solved by rotation and translation function methods and a difference map between carbonmonoxy haemoglobin Kansas in the deoxy quaternary structure and native deoxy haemoglobin has been calculated at 3.5 Å resolution. Carbon monoxide molecules are observed at three of the four haems, and two unidentified large peaks³ appear next to the sulphydryl groups of Cys93β. None of the interchain salt bridges which stabilize the deoxy quaternary state appears to be broken, but large tertiary structural changes are seen in the liganded chains. It seems that when the molecule is subjected to the lattice constraints of the deoxy crystal, the salt bridges do not break upon ligand binding, even though the pH dependence of the first Adair constant and the linearity of proton release with ligand uptake both imply that this does happen to stripped HbA in solution.     

Structure of haemoglobin in the deoxy quaternary state with ligand bound at the alpha haems

We report the X-ray crystal structure of two analogues of human haemoglobin in the deoxy quaternary (T) state with ligand bound exclusively at the alpha haems. These models were prepared from symmetric, mixed-metal hybrid haemoglobin molecules. The structures of alpha Fe(II) beta Co(II), its carbonmonoxy derivative alpha Fe(II)CO beta Co(II), and alpha Fe(II)O2 beta Ni(II) are compared with native deoxy haemoglobin by difference Fourier syntheses at 2.8, 2.9 and 3.5 A resolution, respectively, and the refined alpha Fe(II)CO beta Co(II) structure is analysed. In both the native deoxy and liganded T molecules, the mean plane of the alpha-subunit haem is parallel with the axis of the F helix, but this plane is tilted with respect to the helix axis in the oxy-quaternary R state. The side-chains of LeuFG3 and ValFG5 sterically restrict haem tilting in the T state. We propose that strain energy develops at the contact between the haem and these residues in the liganded T-state haemoglobin, and that the strain is, in part, responsible for the low affinity of the T-state alpha haem.     

Structure of deoxyhaemoglobin Yakima: a high-affinity mutant form exhibiting oxy-like 1 2 subunit interactions

Crystals of deoxyhaemoglobin Yakima (Asp Gl(99)β → His) are isomorphous with those of deoxyhaemoglobin A, even though the mutation produces disturbances in both the tertiary structure of the subunits and the quaternary structure of the tetramer. Asp Gl(99)β₂ lies at the α₁β₂ subunit interface, and in deoxyhaemoglobin A forms a crucial hydrogen bond with Tyr C7(42) α₁. The histidine residue that replaces the aspartate results in the removal of this single important intersubunit bond, and it further acts as a wedge between the α₁ and β₂ subunits, so that they are pushed apart and displaced part of the way towards the oxy structure. These disturbances are accompanied by the formation of a new intersubunit hydrogen bond, which is usually only observed in the oxy quaternary structure of haemoglobin. The disturbances at the α₁β₂ contact affect the stereochemistry of the entire molecule and are transmitted to the α and β haems. The X-ray structure of deoxy Yakima therefore provides a stereochemical explanation for its abnormal function; this being an abnormally high affinity for oxygen and vastly diminished haem-haem interactions.     

Effect of C02 binding to haemoglobin on the reactivity of the SH groups at position beta 93

In deoxygenated human haemoglobin A_II and sheep haemoglobin B, in the presence of CO₂ the rate of reaction of the SH groups at position ß₉₃ decreased significantly, but did not change in deoxygenated haemoglobin A_Ic, where the N-terminal α amino groups of the ß chains are blocked. In the absence of CO₂ the SH reaction rates were identical for all three haemoglobins in deoxy form, but differed for the respective oxyhaemoglobins. In the presence of CO₂ the individual rate constants for oxyhaemoglobin were not altered. It is concluded that binding of CO₂ to haemoglobin leads primarily to a stabilisation of the tertiary deoxy structure of the individual subunits, rather than to a stabilisation of the deoxy quaternary structure of the tetramer.     

Molecular oxygen binding with α and β subunits within the R quaternary state of human hemoglobin in solutions and porous sol–gel matrices

Nanosecond laser flash-photolysis technique was used to study bimolecular and geminate molecular oxygen (O₂) rebinding to α and β subunits within oxygenated human adult hemoglobin in solutions and porous wet sol–gel matrices. Plasticity associated with the tertiary structure within R-state hemoglobin is explored through measurements that focus on the functional properties of hemoglobin under conditions designed to tune the tertiary structure without inducing the R to T transition. Inequivalence in the O₂ binding to the α and β hemes within the R quaternary structure is studied. The individual kinetic properties of the α and β subunits within the hemoglobin encapsulated in sol–gels and aged as the oxy derivative are shown to be independent of proton concentration over the pH range from 6.3 to 8.5. However, buffer effects on the subunits' properties are revealed in sol–gel-free mediums. Interestingly, the α and β subunits within the encapsulated hemoglobin possess the O₂ rebinding properties which fall within the range of the ones for oxygenated hemoglobin in the buffer solutions. The combined results show a pattern in which there is a progression of functional properties that are ascribed to a family of conformational substates of R-state hemoglobin. O₂ rebinding to the α and β subunits within the oxygenated R-state hemoglobin in both solutions and wet sol–gels is revealed to be modulated by tertiary structural changes in two quite different ways. The possible structural changes, which modify the O₂ rebinding properties, are discussed.     

Nuclear Magnetic Resonance Studies of Haemoglobin M Milwaukee

Analysis of the NMR spectra of haemoglobin M Milwaukee confirms that ligand binding to the α haems changes the quaternary structure.     

Decay of individual Escherichia coli trp messenger RNA molecules is sequentially ordered.

Human fluoromethaemoglobin with inositol hexaphosphate (IHP) in 0.05 m-phosphate buffer was crystallized by addition of polyethylene glycol (PEG). The crystals are isomorphous with those of deoxyhaemoglobin A without IHP grown in solutions containing PEG by Ward et al. (1975). The structure was investigated by means of a difference Fourier synthesis against deoxyhaemoglobin A based on X-ray data collected within a limiting sphere of 3.5 Å^?1. The four subunits are arranged in the quaternary T structure and IHP is bound at the same site between the β chains as in deoxyhaemoglobin. In both the α and β haem regions the distance between the haem plane and the F helix is reduced in fluoromethaemoglobin relative to deoxyhaemoglobin and the iron atom is moved from the proximal towards the distal side of the plane, but the change, if any, in the distance between the iron and the N_ε of the proximal histidine cannot be clearly established. The α Fe in fluoromethaemoglobin is either in the haem plane or up to 0.8 Å on the distal side, suggesting the possibility of rupture of the bond to the histidines N_ε; it was not possible to estimate the position of the β iron. The main spectral changes associated with the reaction of fluoromethaemoglobin with IHP take place in less than 3 ms at room temperature.     

Structure of horse carbonmonoxyhaemoglobin

The structure is based on a difference Fourier synthesis at 2.8 Å resolution, using observed structure amplitudes and calculated phases, derived from a refinement of horse methaemoglobin at 2.0 Å resolution. Carbonmonoxyhaemoglobin has the same quaternary structure as methaemoglobin, but differs from it by slight changes in tertiary structure in the immediate vicinity of the haems. On transition from met- to carbonmonoxyhaemoglobin the distal histidines move away from the haem ligands towards the molecular surface, and both the haems and F-helices rotate slightly and shift towards the distal side. In methaemoglobin the sulphydryl group of cysteine F9(93)β is in equilibrium between two alternative positions: one external and the other half-buried in the “tyrosine pocket” between helices F and H. In carbonmonoxyhaemoglobin all the electron density for the sulphydryl group is in the half-buried position, so that the side chain of tyrosine HC2(145)β is completely displaced from its pocket. The difference map shows that the CO oxygen lies off the haem axis in both subunits, but the carbon cannot be seen as it coincides with the water molecule in methaemoglobin. A preliminary refinement of carbonmonoxyhaemoglobin suggests that the carbon may be displaced from the haem axis in the same direction as the oxygen. The haem pocket is so constructed that it fits an oxygen molecule in the bent conformation, but not a CO molecule which has its axis normal to the haem plane, because of steric hindrance by N_? of the distal histidine and by C_γ2 of the distal valine. These two side chains apparently push the CO oxygen off the haem axis. The difference map indicates that in methaemoglobin the α-haem is ruffled and that on transition from met- to carbonmonoxyhaemoglobin it becomes flattened; in the β-haem the iron appears to move towards the porphyrin plane. The resolution is not sufficient to determine the exact position of the iron atoms and the proximal histidines relative to the porphyrins.     

Structure and Subunit Interaction of Haemoglobin M Milwaukee

In haemoglobin M Milwaukee, substitution of a glutamic acid for a valine in the haem pocket of the β chains leads to a link between the γ carboxyl group and the ferric iron. Interaction between ferrous and ferric haems is observed.     

Indirect allosteric effects of a neutral mutation. Structure of deoxyhaemoglobin north Chicago (ProC2(36)beta----Ser)

Haemoglobin North Chicago (ProC2(36 beta----Ser) has an abnormally high oxygen affinity. A survey of other abnormal human haemoglobins with high oxygen affinity has indicated that mutations leading to a cavity in the quaternary T-structure, or to the rupture of any bond in that structure, have raised oxygen affinities, because such mutations loosen the constraints of the T-structure. They do not usually affect the oxygen affinity of the R-structure. Haemoglobin North Chicago aroused our interest because the side-chain of serine is smaller than that of proline by only one carbon atom, and it was hard to conceive how such a small gap should raise the oxygen affinity significantly. Our X-ray study shows that the mutation produces unexpectedly large indirect changes in the T-structure.     

Structure of erythrocruorin in different ligand states refined at 1.4 A resolution.

The crystal structure of erythrocruorin has been refined by constrained crystallographic refinement at 1·4 Å resolution in the following ligand states: aquomet (Fe³⁺, high spin), cyanomet (Fe³⁺, low spin), deoxy (Fe²⁺, high spin) and carbonmonoxy (Fe²⁺, low spin). The final R-value at this resolution is better than 0·19 for each of these models. The positional errors of the co-ordinates are less than 0·1 Å.The root-mean-square differences between the deoxygenated and the ligated erythrocruorin are about 0·1 Å, being largest for cyanomet-erythrocruorin. The changes in tertiary structures propagate from the location of primary events and often fade out at the molecular surface. Helix E passing the distal side of the haem group is affected most by the direct contact with the ligand bound to the haem iron.Steric hindrance by the distal residue IleE11 forces the cyanide and carbonmonoxide ligands to bind at an angle to the haem axis. The strain at the ligand is partially relieved by movement of the haem deeper into the haem pocket and rearrangement of neighbouring residues.The differences in iron location with respect to the mean haem plane are spin-dependent but unexpectedly small (the largest value is 0·15 Å between deoxy and carbonmonoxy-erythrocruorin). Spin state changes seem to have little influence on the porphyrin stereochemistry; it is determined primarily by the chemical properties of the ligand and its interaction with the haem and the globin. These non-covalent interactions are largely responsible for the initiation of the structural changes on ligand binding.     

The structure of the large regulatory α subunit of phosphorylase kinase examined by modeling and hydrogen‐deuterium exchange

Phosphorylase kinase (PhK), a 1.3 MDa regulatory enzyme complex in the glycogenolysis cascade, has four copies each of four subunits, (αβγδ)₄, and 325 kDa of unique sequence (the mass of an αβγδ protomer). The α, β and δ subunits are regulatory, and contain allosteric activation sites that stimulate the activity of the catalytic γ subunit in response to diverse signaling molecules. Due to its size and complexity, no high resolution structures have been solved for the intact complex or its regulatory α and β subunits. Of PhK's four subunits, the least is known about the structure and function of its largest subunit, α. Here, we have modeled the full‐length α subunit, compared that structure against previously predicted domains within this subunit, and performed hydrogen‐deuterium exchange on the intact subunit within the PhK complex. Our modeling results show α to comprise two major domains: an N‐terminal glycoside hydrolase domain and a large C‐terminal importin α/β‐like domain. This structure is similar to our previously published model for the homologous β subunit, although clear structural differences are present. The overall highly helical structure with several intervening hinge regions is consistent with our hydrogen‐deuterium exchange results obtained for this subunit as part of the (αβγδ)₄ PhK complex. Several low exchanging regions predicted to lack ordered secondary structure are consistent with inter‐subunit contact sites for α in the quaternary structure of PhK; of particular interest is a low‐exchanging region in the C‐terminus of α that is known to bind the regulatory domain of the catalytic γ subunit.     

Transferrin-bipyridine iron transfer mediated by haemoproteins

Rabbit reticulocyte cytosol was able to mediate transferrin-bipyridine iron transfer in the presence of ATP. The cytoplasmic factor responsible for the mediation of iron transfer was identified as haemoglobin. Other cytoplasmic proteins and the membrane fraction were ineffective. Human α and β subunits and human myoglobin were over three times more effective than human haemoglobin A. Carbon monoxide strongly inhibited the mediation of iron transfer. Oxidation of haemoglobin abolished it but methaemoglobin could be reactivated with NADH, even when azide was bound to the haem iron.Neither globin nor haem alone were able to mediate iron transfer, even when NADH was present. Together, the reconstituted methaemoglobin A could be reactivated with NADH.Although the physiological significance of this phenomenon is not clear, the involvement of haemoproteins in intracellular iron metabolism seems likely.     

Kinetics of ligand binding to ferrous heme groups of hemoglobin MSaskatoon.

Hemoglobin M_Saskatoon (α₂^Aβ₂^63tyr) has two α chains in the normal ferrous state, while its two β chains are in the ferric state. The reaction of hemoglobin M_Saskatoon with carbon monoxide at pH 7 and 20 °C in the presence and absence of dithionite was studied. In the absence of dithionite only the α chains react and the combination rate is slow and similar to that of normal deoxyhemoglobin. After the addition of dithionite the rate of reaction is greatly increased initially and then decreases to a rate similar to that seen in the absence of dithionite. The dissociation of oxygen from hemoglobin M_Saskatoon at pH 7 and 20 °C was found for the α subunits to be similar to that seen for normal oxyhemoglobin. This similarity in the kinetic properties of normal hemoglobin and the α subunits of hemoglobin M_Saskatoon in both ligand combination and dissociation reactions indicates that the α subunits of hemoglobin M_Saskatoon undergo a structural transition from a low to high affinity form on liganding. Since the β subunits react rapidly with carbon monoxide even when the α subunits are unliganded, it appears that the ligand binding sites of the β chains are uncoupled from the state of liganding of the α subunits.     

Structure of human deoxy cobalt haemoglobin

The structure of human adult deoxy cobalt haemoglobin has been compared to that of the native ferrous form by refinements based on X-ray data to 2.5 Å resolution. The two structures were refined in parallel by conventional methods and selected structural differences were measured by a novel difference refinement method applicable to closely related structures. The distance between the metal and the haem plane is 0.33 ± 0.08 Å in the cobalt derivative and 0.56 ± 0.03 Å in the native. The Co²⁺HisF8N_? bond length is about 0.1 to 0.2 Å longer than the Fe²⁺HisF8N_? bond length; the distance of N_? from the mean haem plane remains the same in the two structures and the substitution of cobalt for iron produces no significant change in globin structure. The free energy of co-operativity of cobalt haemoglobin is known to be about one-half of that of the native haemoglobin; the reason for this reduction is not evident from the structure of cobalt deoxyhaemoglobin.     

Structure of the three-haem core of cytochrome c 551.5 determined by 1H NMR

 The trihaem cytochrome c _551.5, formerly known as cytochrome c ₇, from the organism Desulfuromonas acetoxidans, has been studied in the reduced state by 2D proton NMR. The haem proton resonances were assigned, and several nuclear Overhauser enhancements (NOEs) between resonances arising from different haems were detected and assigned. The relative orientations of the three haems were calculated by fitting both the intensities of the interhaem NOEs and the magnitudes of the ring current shifts of the haem resonances, following the strategy previously used by the authors to reassess the X-ray structure of the haem core in tetrahaem cytochrome c ₃ from Desulfumicrobium baculatum. It is concluded that, although the comparison of the protein sequence with those of the tetrahaem cytochromes c ₃ shows that in cytochrome c _551.5 about 40% of the sequence is deleted, including the region involved in the attachment of the second of the four haems, this does not induce any significant rearrangement of the remaining three haems other than a slight decrease in the iron-iron distance between two of the haems, namely those corresponding to haems I and IV of cytochrome c ₃. Received: 2 February 1996 / Accepted: 26 March 1996