Biological implications of a 3 A structure of dimeric antithrombin.

BACKGROUND: Antithrombin, a member of the serpin family of inhibitors, controls coagulation in human plasma by forming complexes with thrombin and other coagulation proteases in a process greatly accelerated by heparin. The structures of several serpins have been determined but not in their active conformations. We have determined the structure of intact antithrombin in order to study its mechanism of activation, particularly with respect to heparin, and the dysfunctions of this mechanism that predispose individuals to thrombotic disease. RESULTS: The crystal structure of a dimer of one active and one inactive molecule of antithrombin has been determined at 3 A. The first molecule has its reactive-centre loop in a predicted active conformation compatible with initial entry of two residues into the main beta-sheet of the molecule. The inactive molecule has a totally incorporated loop as in latent plasminogen activator inhibitor-1. The two molecules are linked by the reactive loop of the active molecule which has replaced a strand from another beta-sheet in the latent molecule. CONCLUSION: The structure, together with identified mutations affecting its heparin affinity, allows the placement of the heparin-binding site on the molecule. The conformation of the two forms of antithrombin demonstrates the extraordinary mobility of the reactive loop in the serpins and provides insights into the folding of the loop required for inhibitory activity together with the potential modification of this by heparin. The mechanism of dimerization is relevant to the polymerization that is observed in diseases associated with variant serpins.

Structure of deoxyhaemoglobin of the antarctic fish Pagothenia bernacchii with an analysis of the structural basis of the root effect by comparison of the liganded and unliganded haemoglobin structures.

We have determined the structure of deoxyhaemoglobin from the antarctic fish Pagothenia bernacchii at pH 6.2 to a resolution of 2.2 A with X-ray data from a twinned crystal deconvoluted so as to approximate data from a single crystal. The R-factor between the (twinned) model and the observed data is 16% for reflections used in refinement and 22% for reflections not used in refinement. The T (deoxy) structure was compared with the R (liganded) structure at pH 8.0 in an attempt to understand the structural basis of the greater affinity for hydrogen ions of T, relative to R, that comprises the Root effect. Up to half of the effect can be attributed to interaction of the residues Asp95 (G1)alpha and Asp101 (G3)beta: in R the residues are far apart and their carboxyl groups are unprotonated, but the shift at the alpha 1 beta 2 interface that accompanies the R to T transition brings them so close that they appear to share a proton between them. The proximity of Asp99 (G1)beta may contribute to the required raising of the pKa values of the other two Asp residues. These and neighbouring residues are sufficiently conserved in the haemoglobins of trout (component IV), carp and bluefin tuna, all of which exhibit the Root effect, for the same mechanism to apply. However, the environment is equally conserved in haemoglobins of Trematomus newnesi (major component) and trout (component I), which do not exhibit the Root effect, so that the structural factors controlling the Asp-Asp interaction remain unclear. No other residue appears to undergo an R to T change in the immediate neighbourhoods that could account for any significant portion of the Root effect, so at least half of the effect must result either from long-range electrostatic interactions or from a large number of local interactions.

Structure of deoxy-quaternary haemoglobin with liganded beta subunits.

We have determined the structure of a T-state haemoglobin in which the haem groups of the beta subunits have carbon monoxide bound, and the alpha subunits have nickel replacing the haem iron and are ligand-free. The structural adjustments on binding ligand in the T state are in the same direction as those associated with the quaternary transition, and a translational shift of the haem is severely restricted. We explain how these observations may account for the low ligand affinity of the beta haem of T-state haemoglobin.

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.

The crystal structure of human deoxyhaemoglobin at 1.74 A resolution.

The structure of human deoxyhaemoglobin was refined at 1.74 A resolution using data collected on film at room temperature from a synchrotron X-ray source. The crystallographic R-factor is 16.0%. The estimated error in atomic positions is 0.1 A overall, 0.14 A for main-chain atoms of internal segments, and 0.05 A for the iron atoms. The effects of intermolecular contacts on the structure were investigated; such contacts cause only highly localized distortions, as judged from the degree of molecular asymmetry that they induce. The geometry of the iron-nitrogen complex closely resembles that of the deoxymyoglobin structure of Takano (1977) and of the 5-co-ordinated model compounds of Hoard (1975) and Jameson et al. (1980). The distance of the iron from the mean plane of N(porphyrin) is 0.40(5) A and 0.36(5) A, respectively, at the alpha and beta haems, in contrast to the corresponding distance of +0.12(8) A and -0.11(8) A in oxyhaemoglobin ( Shaanan , 1983); the Fe-N epsilon (F8) bond length is 2.12(4) A and the Fe-N(porphyrin) bond length is 2.06(2) A; the last is also in good agreement with extended X-ray fluorescence spectroscopy measurements on deoxyhaemoglobin ( Eisenberger et al., 1978; Perutz et al., 1982). The haems are domed toward the proximal side; the separation between the mean planes of N(porphyrin) and C(porphyrin) being 0.16(6) A and 0.10(6) A, respectively at the alpha and beta haems. At the alpha haems, the normals to the mean pyrrole planes are tilted uniformly toward the haem centre, by about three degrees relative to the haem normal, and there is a folding of about four degrees of the haem about an axis running between the methene carbons that are between the pyrrole rings bearing like-type side-chains. At the beta haems, there is no such folding, and only pyrroles II and IV (those eclipsed by His F8) are appreciably tilted, by about eight degrees. The independence of these parameters from restraints imposed on the model was verified by unrestrained refinement of the entire molecule starting from a structure with modified haem geometry.

Functional role of the distal valine (E11) residue of alpha subunits in human haemoglobin.

We have expressed human alpha-globin to a high level in Escherichia coli as a fusion protein, purified it and removed the N-terminal leader sequence by site-specific proteolysis with blood coagulation factor Xa. The apo globin has been refolded and reconstituted with haem and native beta-globin to form fully functional haemoglobin (Hb) with properties identical to those of native human Hb. By site-directed mutagenesis we have altered the distal residues of the alpha subunits and compared the functional properties of these mutant proteins. The rates of various ligands binding to these proteins in the R-state have been reported by Mathews et al. Here, we present the oxygen equilibrium curves of three E11 alpha mutants and the crystal structures of two of these mutants in the deoxy form. Replacing the distal valine residue of alpha-globin with alanine, leucine or isoleucine has no effect on the oxygen affinity of the protein in either quaternary state, in contrast to the equivalent mutations of beta subunits. The crystal structure of the valine E11 alpha----isoleucine mutant shows that the larger E11 residue excludes water from the haem pocket, but causes no significant movement of other amino acid residues. We conclude that the distal valine residue of alpha-globin does not control the oxygen affinity of the protein by sterically hindering ligand binding.

A novel allosteric mechanism in haemoglobin. Structure of bovine deoxyhaemoglobin, absence of specific chloride-binding sites and origin of the chloride-linked Bohr effect in bovine and human haemoglobin.

The structure of bovine deoxyhaemoglobin has been determined at 2.2 A resolution and refined to an R-factor of 0.193 for all 32,583 reflections, and a free R-factor of 0.249 for 1527 reflections excluded from the refinement. The structure shows no significant differences between the alpha-carbon positions of bovine and human haemoglobin, except at the N-terminal segment and the first helix (A) which are closer to the dyad symmetry axis and pushed more tightly against the rest of the beta-subunits in the bovine form. In a search for the predicted chloride-binding sites, three-dimensional data were collected from crystals suspended in 50% polyethylene glycol buffered either with 50 mM Na phosphate (pH 7.3) +/- 0.1 M NaCl or with 0.1 M Hepes (pH 7.3) +/- 0.1 M NaBr. Difference electron density maps with and without NaCl or NaBr showed no evidence of specific halide ion-binding sites. Oxygen equilibria were measured in 10 mM Hepes buffer without added NaCl, with 0.1 mM NaCl, 0.1 M NaCl + 1 mM 2,3-diphosphoglycerate, and 0.1 M NaCl + 1 mM inositol hexaphosphate. Without added chloride, P50 of stripped bovine haemoglobin was similar to that of human haemoglobin with 0.1 M NaCl. With 0.1 M NaCl it was similar to that of human haemoglobin saturated with 2,3-diphosphoglycerate. In 0.1 M NaCl neither organic phosphate significantly affected the oxygen affinity. Titration of P50 with NaCl showed delta log P50/delta log[Cl-] of bovine and human haemoglobin to be identical. Analysis of the oxygen equilibrium curves showed the low intrinsic oxygen affinity of bovine haemoglobin to be due to a larger oxygen dissociation constant from the T-structure. The influence of chloride on P50 and on the alkaline Bohr effect is the same in bovine and human haemoglobins. It is proposed that this is due to the excess positive charges in the central cavity and its widening in the transition from the R to the T-structure. The widening would allow more chloride ions to enter and neutralize the positive charges, but these ions would remain mobile and therefore do not show up as peaks of high electron density. Repulsion between excess positive charges in the central cavity raises the free energy of the T-structure relative to the R-structure, thereby raising the oxygen affinity. Conversely, entry of chloride ions on widening of the cavity reduces the free energy of the T-structure and therefore lowers the oxygen affinity.(ABSTRACT TRUNCATED AT 400 WORDS)

Structure-function relationships in the low-affinity mutant haemoglobin Aalborg (Gly74 (E18)beta----Arg).

Haemoglobin Aalborg (Gly74 (E18)beta----Arg) has a reduced oxygen affinity, in both the absence and the presence of organic phosphates; it has a raised affinity for organic phosphates, and it is moderately unstable. By contrast, haemoglobin Shepherds Bush (Gly74 (E18)beta----Asp) has an increased oxygen affinity in both the absence and the presence of organic phosphates, a diminished affinity for organic phosphates and is also unstable. We have determined the crystal structure of deoxyhaemoglobin Aalborg at 2.8 A resolution and compared it to the structures of deoxy- and oxyhaemoglobin A and of deoxyhaemoglobin Shepherds Bush. The guanidinium group of Arg74(E18)beta protrudes from the haem pocket and donates hydrogen bonds to the E and F helices. The carboxylate group of Asp74(E18)beta forms a hydrogen bond only with residue EF6 and is partially buried, which may be why haemoglobin Shepherds Bush appears to be more unstable than haemoglobin Aalborg. To discover why the latter has a low oxygen affinity, we superimposed the B, G and H helices of haemoglobin A, whose conformation is known to be unaffected by ligand binding, on those of haemoglobin Aalborg. This also brought helices E and the haems into superposition, but revealed a shift of the F helix of deoxyhaemoglobin Aalborg towards the EF-corner. This shift is opposite to that which occurs on ligand binding and on transition to the quaternary oxy-structure, and is linked to an increased tilt of the proximal histidine residue away from the haem axis. Since the relative positions of helices E and F and of the haem group are thought to be the main determinants of the changes in oxygen affinity, the shift of helix F may account for the reduced oxygen affinity of haemoglobin Aalborg. The shift may be due to a combination of steric and electrostatic effects introduced by the arginine residue's side-chain. The effects of the arginine and aspartate substitutions at position E18 beta on the 2,3-diphosphoglycerate affinity are equal and opposite. They can be quantitatively accounted for by the electrostatic attraction or repulsion by the oppositely charged side-chains.

Haemoglobin of the antarctic fish Pagothenia bernacchii. Amino acid sequence, oxygen equilibria and crystal structure of its carbonmonoxy derivative.

The Antarctic fish Pagothenia bernacchii has one major haemoglobin, Hb1 (over 95% of the total blood content). Hb1 has a strong alkaline Bohr effect and at low pH exhibits the reduced ligand affinity and co-operativity that comprise the Root effect. We have determined the complete amino acid sequence of P. bernacchii Hb1 and also the structure of its carbonmonoxy derivative by X-ray crystallography, to a resolution of 2.5 A. The crystallographic R-factor of the refined structure is 18%. The three-dimensional structure of this fish haemoglobin is similar to that of human haemoglobin A, with a root-mean-square difference in main-chain atom positions of 1.4 A after superimposition of the two structures, despite only 48% homology of their amino acid sequences (including insertion of a single residue in the CD region of the fish alpha-chain). Large structural differences occur only at the N and C termini of both the alpha- and beta-chains. Neither these nor other smaller structural differences provide any obvious explanation of the Root effect of this or other fish haemoglobins.

Iron distances in hemoglobin: comparison of x-ray crystallographic and extended x-ray absorption fine structure studies.

A comparison is presented of the structures obtained around the iron atom in deoxyhemoglobin (Hb). The data come from extended x-ray absorption fine structure (EXAFS) studies of the iron, which gave Fe-porphyrin nitrogen distances of 2.06 +/- 0.01 A, and from the most recent high-resolution x-ray crystallographic study, which gave exactly the same distance--2.06 +/- 0.02 A. The distance of Fe above the plane of the porphyrin nitrogens was 0.38 +/- 0.04 A from the crystallographic study; this value is not far from the upper limit of the distances 0.20 +/- (0.10)0.20 A calculated from the EXAFS experiment by triangulation. These distances above the nitrogen plane are shorter than those estimated in the earliest x-ray structures.

Structure of deoxyhemoglobin Cowtown [His HC3(146) beta----Leu]: origin of the alkaline Bohr effect and electrostatic interactions in hemoglobin.

Hemoglobin Cowtown [His HC3(146)-beta----Leu] exhibits high oxygen affinity and a halved alkaline Bohr effect. X-ray analysis shows the COOH-terminal leucine to be in equilibrium between two positions: one with the salt bridge between the terminal carboxyl and Lys C5(40)alpha intact and the leucyl side chain leaning against main chain atoms of helices F and FG and the other with the terminal salt bridge broken and the leucyl side chain touching Pro C2(37)alpha. Structural changes are confined to the immediate neighborhood of the COOH terminus, showing the halving of the alkaline Bohr effect to be due directly to the loss of the histidine, without significant contributions from changes in pK values of other ionizable groups due to structural changes elsewhere.

LR16, a compound with potent effects on the oxygen affinity of hemoglobin, on blood cholesterol, and on low density lipoprotein.

2-[4-(3,4-Dichlorophenylureido)phenoxy]-2-methylpropionic acid, LR16, combines with two symmetrically related sites in the central cavity of deoxyhemoglobin, 20 A away from the binding site of 2,3-bisphosphoglycerate, and acts as an allosteric effector synergistic with 2,3-bisphosphoglycerate. LR16 (1 mM) raises P50, the partial pressure of oxygen needed to achieve half-saturation with oxygen of a hemolysate of human hemoglobin, about 50 times more strongly than 1 mM 2,3-bisphosphoglycerate. Oral administration of LR16 (at small doses that produced no ill effects) to rats that were fed a diet rich in cholesterol caused substantial reductions of total serum cholesterol and low density lipoprotein-cholesterol, while high density lipoprotein-cholesterol remained unchanged.

Structure and function of human hemoglobin covalently labeled with periodate-oxidized adenosine triphosphate.

Periodate-oxidized adenosine triphosphate (o-ATP), a ribose ring-opened dialdehyde derivative of ATP, reacts specifically with human deoxyhemoglobin to give a single major covalently modified product after reduction with sodium borohydride. This product, designated di-ATP Hb, was isolated using ion-exchange chromatography and shown to have incorporated two molecules of o-ATP/tetramer. Peptide mapping and x-ray crystallography at 2.8-A resolution indicate that a covalent adduct is formed between the ligand and residues Lys-82 EF6 of each beta chain in the organic phosphate-binding site of the molecule. di-ATP Hb exhibits a significantly decreased oxygen affinity (P50 = 20.8 mm Hg versus 5.8 mm Hg control; 50 mM 2-[bis(2-hydroxyethyl)amino]-2-(hydroxymethyl)-propane-1,3-diol, pH 7.4, 0.1 M C, 20 degrees C). The subunit cooper-activity of di-ATP Hb is also reduced (nmax = 1.9 versus 2.7 control).

Probing the alpha 1 beta 2 interface of human hemoglobin by mutagenesis. Role of the FG-C contact regions.

The allosteric transition of hemoglobin involves an extensive reorganization of the alpha 1 beta 2 interface, in which two contact regions have been identified. This paper concerns at the effect of two mutations located in the "switch" (alpha C3 Thr --> Trp) and the "flexible joint" (beta C3 Trp --> Thr). We have expressed and characterized one double and two single mutants: Hb alpha T38W/beta W37T, Hb beta W37T, and Hb alpha T38W, whose structure has been determined by crystallography. We present data on: (i) the interface structure in the contact regions, (ii) oxygen and CO binding kinetics and cooperativity, (iii) dissociation rates of deoxy tetramers and association rates of deoxy dimers, and (iv) the effect of NaI on deoxy tetramer dissociation rate constant. All the mutants are tetrameric and T-state in the deoxygenated derivative. Reassociation of deoxygenated dimers is not modified by interface mutations. DeoxyHb alpha T38W/beta W37T dissociate much faster. We propose a binding site for I- at the switch region. The single mutants binds O2 cooperatively; the double one is almost non-cooperative, a feature confirmed by CO binding. The functional data, analyzed with the two-state model, indicate that these mutations reduce the value of the allosteric constant LO.

Adaptation of bird hemoglobins to high altitudes: demonstration of molecular mechanism by protein engineering.

Of two closely related species of geese, one, the greylag goose, lives in the Indian plains all year round, while the other, the bar-headed goose, lives at the Tibetan lakes and migrates across the Himalayas to winter in India. Another species, the Andean goose, lives in the High Andes all year round. Possession of a Hb with high oxygen affinity helps to adapt bar-headed and Andean geese to high altitudes. The Hb amino acid sequences of the bar-headed and the greylag geese differ by four substitutions, of which only one is unique among bird sequences: Pro-119 alpha (H2)----Ala. Perutz proposed that the two-carbon gap left by this substitution at the alpha 1 beta 1 contact raises the oxygen affinity, because it relaxes the tension in the deoxy or T structure [Perutz, M. F. (1983) Mol. Biol. Evol. 1, 1-28]. It was later found that the Hb of the Andean goose has a gap in the same position, due to the complementary substitution Leu-55 beta (D6)----Ser. We have tested Perutz's hypothesis by introducing each of these substitutions into human globin synthesized in Escherichia coli. The reconstituted Hbs combine cooperatively with oxygen. Their oxygen affinities exceed that of normal human Hb by an even larger factor than that found between the high-flying geese and the greylag goose. The mutant Hb Met-55 beta (D6)----Ser was crystallized. Its structure is the same as that of HbA, except in the immediate environment of the gap left by the substitution of the serine for the methionine side chain, which evidently causes the increased oxygen affinity of this Hb.

Hemoglobin Warsaw (Phe beta 42(CD1)----Val), an unstable variant with decreased oxygen affinity. Characterization of its synthesis, functional properties, and structure.

In Hb Warsaw Val replaces the Phe normally present at the heme contact position beta 42 (CD1). This variant is unstable, and it readily undergoes methemoglobin formation. In DEAE-cellulose chromatography, the variant hemoglobin co-eluted with Hb A; a partially heme-depleted fraction of the variant, representing 5-6% of the total hemoglobin, eluted separately and in pure form. The heme replete form of Hb Warsaw exhibited decreased oxygen affinity with a normal Bohr effect and normal cooperativity and interaction with 2,3-diphosphoglycerate (DPG). The heme-depleted Hb Warsaw had a higher oxygen affinity than that of Hb A, decreased cooperativity and 2,3-DPG interaction, and a very low alkaline Bohr effect. Gel filtration of the heme-depleted form showed it to exist entirely as alpha beta dimers. Globin chain synthesis by Hb Warsaw-containing reticulocytes followed a balanced alpha/beta ratio. In short-term synthesis experiments, a major portion of incorporated radiolabeled L-leucine was recovered from the dimeric, heme-depleted Hb Warsaw fraction, suggesting that subunit association precedes the incorporation of heme into the beta subunits in the post-synthetic assembly of this hemoglobin. Structural analysis of deoxyhemoglobin containing roughly equal proportions of normal and variant beta chains showed that the replacement leaves a cavity next to the heme that is large enough to hold a water molecule, which may account for the instability of Hb Warsaw. The heme and the pyrrol nearest to ValCD1 tilt into the cavity. The resulting increase in the tilt of the proximal histidine relative to the heme plane, coupled with a possible stretching of the Fe-N epsilon bond may account for the low oxygen affinity.