Structure/function analysis of the integrin beta 1 subunit by epitope mapping.

Monoclonal antibodies (mAbs) have been produced against the chicken beta 1 subunit that affect integrin functions, including ligand binding, alpha subunit association, and regulation of ligand specificity. Epitope mapping of these antibodies was used to identify regions of the subunit involved in these functions. To accomplish this, we produced mouse/chicken chimeric beta 1 subunits and expressed them in mouse 3T3 cells. These chimeric subunits were fully functional with respect to heterodimer formation, cell surface expression, and cell adhesion. They differed in their ability to react with a panel anti-chicken beta 1 mAbs. Epitopes were identified by a loss of antibody binding upon substitution of regions of the chicken beta 1 subunit by homologous regions of the mouse beta 1 subunit. The identification of the epitope was confirmed by a reciprocal exchange of chicken and mouse beta 1 domains that resulted in the gain of the ability of the mouse subunit to interact with a particular anti-chicken beta 1 mAb. Using this approach, we found that the epitopes for one set of antibodies that block ligand binding mapped toward the amino terminal region of the beta 1 subunit. This region is homologous to a portion of the ligand-binding domain of the beta 3 subunit. In addition, a second set of antibodies that either block ligand binding, alter ligand specificity, or induce alpha/beta subunit dissociation mapped to the cysteine rich repeats near the transmembrane domain of the molecule. These data are consistent with a model in which a portion of beta 1 ligand binding domain rests within the amino terminal 200 amino acids and a regulatory domain, that affects ligand binding through secondary changes in the structure of the molecule resides in a region of the subunit, possibly including the cysteine-rich repeats, nearer the transmembrane domain. The data also suggest the possibility that the alpha subunit may exert an influence on ligand specificity by interacting with this regulatory domain of the beta 1 subunit.

Influence of anions and protons on the Adair coefficients of haemoglobins A and Cowtown (His HC3(146) beta----Leu).

We have measured the contribution of the alkaline Bohr effect of the C-terminal histidine residues of the beta-chains of haemoglobin A by comparing haemoglobin A with haemoglobin Cowtown in which those histidine residues are replaced by leucine. Oxygenation of a stripped 2.5 mM (haem) solution of haemoglobin A yielded 0.19 H+/haem, while oxygenation of a similar solution of haemoglobin Cowtown produced no change of pH. Oxygen equilibria measured at 60 microM-haem in 0.1 M-Hepes buffer gave an alkaline Bohr effect of -0.21 H+/haem for haemoglobin A and only -0.01 H+/haem for haemoglobin Cowtown, even though its Hill's coefficient was greater than 2 throughout the pH range studied. These results prove that the chloride-independent part of the alkaline Bohr effect is due to the C-terminal histidine residues of the beta-chains. Oxygen equilibria measured in 0.095 M-bis-Tris buffers with minimal chloride or with 0.1 M-chloride showed the contribution of those histidine residues to the alkaline Bohr effect to be about 0.2 H+/haem, independent of chloride concentration. Determination of the individual Adair coefficients in the three different buffers indicated that pH and chloride tend to have their greatest effects at the second or third steps of oxygenation when the change of quaternary structure is most likely to occur; between pH 7 and 9, the fourth Adair coefficient is only very slightly affected by pH and not significantly by chloride.

The chloride effect in human haemoglobin. A new kind of allosteric mechanism.

Chloride reduces the oxygen affinity of mammalian haemoglobin by acting as an allosteric effector that stabilizes the quaternary deoxy (T) structure. Perutz and others showed evidence that it does so by neutralizing electrostatic repulsion by an excess of positive charges in the cavity that runs through the centre of the molecule, but without binding to any specific site. On the basis of this proposal, any amino acid substitutions in the central cavity that halve the number of excess positive charges should halve the chloride effect, neutralization of the excess positive charges should inhibit it and introduction of additional positive charges should enhance it. Charge changes on the surface of the molecule should leave it unaltered. We have tested this proposal by measuring the chloride effects in several abnormal human haemoglobins with replacements of polar residues in the central cavity or on the surface that we happened to come across. They all proved consistent with the proposal. It appears that diffusible electrolytes can modify allosteric equilibria without necessarily binding to any specific site. Our proposal also implies that amino acid substitutions that make the central cavity more electropositive should destabilize the T-structure and therefore increase the oxygen affinity, while substitutions that make it more electronegative should do the reverse. A survey of all substitutions reported in the literature shows that this is true, with a few exceptions due to special stereochemical effects.

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 mutagenic study of the allosteric linkage of His(HC3)146 beta in haemoglobin.

We have examined the contribution of His(HC3)146 beta to the alkaline Bohr effect of human haemoglobin (HbA) by replacing it with Gln, using site-directed mutagenesis, and studying the structural and functional consequences. Oxygen equilibrium curves of the mutant show that the effect of pH on the oxygen affinity, the alkaline Bohr effect, is half that of HbA in the presence of chloride ion and less than 10% in its absence. Crystallographic analysis shows that the mutation introduced only small structural changes localized to the site of substitution, proving that the replacement of the hydrogen bond between the ionizable side-chain of His146 beta and Asp94 beta by a hydrogen bond between the unionizable side-chain of Gln146 beta and the same aspartate is solely responsible for the reduction of the alkaline Bohr effect. Our data confirm that His(HC3)146 beta is predominantly responsible for the chloride-independent component of the alkaline Bohr effect which results from the breaking of the hydrogen bond between His(HC3)146 beta and Asp(FG1)94 beta accompanying the transition from the quaternary deoxy to oxy-structure.

Histidine proton resonances of carbonmonoxyhaemoglobins A and Cowtown in chloride-free buffer.

A re-examination of the C-2 histidine proton resonances of haemoglobins A and Cowtown (His HC3(146) beta----Leu) in chloride-free Hepes buffer has shown that all the resonances present in haemoglobin A are present in haemoglobin Cowtown, so that the pKa of His HC3(146) beta cannot be determined by nuclear magnetic resonance in this buffer.

The pKa values of two histidine residues in human haemoglobin, the Bohr effect, and the dipole moments of alpha-helices.

Studies of abnormal and chemically modified haemoglobins indicate that in 0.1 M-NaCl about 40% of the alkaline Bohr effect of human haemoglobin is contributed by the C-terminal histidine HC3(146) beta. In deoxyhaemoglobin, the imidazole of this histidine forms a salt bridge with aspartate FG1(94) beta, in oxyhaemoglobin or carbonmonoxyhaemoglobin it accepts a hydrogen bond from its own NH group instead. Kilmartin et al. (1973) showed that in 0.2 M-NaCl + 0.2 M-phosphate this change of ligation lowered the pKa of the histidine from 8.0 in Hb to 7.1 in HbCO, but Russu et al. (1980) claimed that in bis-Tris buffer without added NaCl its pKa in HbCO dropped no lower than 7.85, and that in this medium the C-terminal histidine made only a negligible contribution to the alkaline Bohr effect. We have compared the histidine resonances of HbCO A with those of three abnormal haemoglobins: HbCO Cowtown (His HC3(146)beta----Leu), HbCO Wood (His FG4(97)beta----Leu) and HbCO Malmø (His FG4(97)beta----Gln). Our results show that the resonance assigned by Russu et al. to His HC3(146)beta in fact belongs to His FG4(97)beta. Although in Hb the pKa of His HC3(146)beta is 8.05 +/- 0.05 independent of ionic strength, in HbCO its pKa drops sharply with diminishing ionic strength, so that in the buffer employed by Russu et al. it has a pKa of 6.2 and makes a contribution to the alkaline Bohr effect that is 57% larger than in the phosphate buffer employed by Kilmartin et al. (1973). In HbCO A, His FG4(97)beta does not contribute to the Bohr effect, but in HbCO from which His HC3(146)beta has been cleaved (HbCO des-His), His FG4(97)beta is in equilibrium between two conformations with different pKa values. This equilibrium varies with ionic strength and pH, and presumably also with degree of ligation of the haem moiety. In HbCO A, His FG4(97)beta has a pKa of 7.8 compared to the pKa value of about 6.6 characteristic of free histidines at the surface of proteins. This high pKa is accounted for by its interaction with the negative pole at the C terminus of helices F and FG. It corresponds to a free energy change of the same order as that observed in the interaction of histidines with carboxylate ions and confirms the strongly dipolar character of alpha-helices, which manifests itself even when they lie on the surface of the protein.

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.

Site-directed mutagenesis in haemoglobin. Functional role of tyrosine-42(C7) alpha at the alpha 1-beta 2 interface.

To clarify the functional role of Tyr-42(C7) alpha, which forms a hydrogen bond with Asp-99(G1) beta at the alpha 1-beta 2 interface of human deoxyhaemoglobin, we engineered two artificial mutant haemoglobins (Hb), in which Tyr-42 alpha was replaced by Phe (Hb Phe-42 alpha) or His (Hb His-42 alpha), and investigated their oxygen binding properties together with structural consequences of the mutations by using various spectroscopic probes. Like most of the natural Asp-99 beta mutants, Hb Phe-42 alpha showed a markedly increased oxygen affinity, a reduced Bohr effect and diminished co-operativity. Structural probes such as ultraviolet-region derivative and oxy-minus-deoxy difference spectra, resonance Raman scattering and proton nuclear magnetic resonance spectra indicate that, in Hb Phe-42 alpha, the deoxy T quaternary structure is highly destabilized and the strain imposed on the Fe-N epsilon (proximal His) bond is released, stabilizing the oxy tertiary structure. In contrast with Hb Phe-42 alpha, Hb His-42 alpha showed an intermediately impaired function and only moderate destabilization of the T-state, which can be explained by the formation of a new, weak hydrogen bond between His-42 alpha and Asp-99 beta. Spectroscopic data were consistent with this assumption. The present study proves that the hydrogen bond between Tyr-42 alpha and Asp-99 beta plays a key role in stabilizing the deoxy T structure and consequently in co-operative oxygen binding.

Hemoglobin Denver [alpha 2 beta 2(41) (C7) Phe-->Ser]: a low-O2-affinity variant associated with chronic cyanosis and anemia.

OBJECTIVE: To report a previously undescribed low-O2-affinity hemoglobin variant that is associated with chronic cyanosis. DESIGN: Pertinent laboratory and historical data for the index case (from Denver, Colorado) and certain family members were recorded, and the hemoglobin variant was characterized. MATERIAL AND METHODS: Electrophoresis, high-performance liquid chromatography (HPLC), and isoelectric focusing were used to examine blood specimens for the presence of hemoglobin variants, and the O2 affinity of whole blood was determined. The abnormal peptide detected on reverse-phase HPLC of separated globin chains was analyzed for its amino acid composition and sequence. RESULTS: Although no abnormal hemoglobin band separated from hemoglobin A on electrophoresis, HPLC, and isoelectric focusing, a heat test showed hemoglobin instability, and O2 affinity studies disclosed an appreciably right-shifted dissociation curve. On chromatography, the new variant--hemoglobin Denver--was found to be due to a substitution of serine for phenylalanine at position 41 (C7) in the beta chain. In addition to substantial reduction in O2 affinity, hemoglobin Denver is accompanied by moderate reticulocytosis and mild anemia. CONCLUSION: Hemoglobin Denver causes no clinical symptoms other than cyanosis, which is attributable to the low O2 affinity.

Hemoglobin Old Dominion/Burton-upon-Trent, beta 143 (H21) His-->Tyr, codon 143 CAC-->TAC--a variant with altered oxygen affinity that compromises measurement of glycated hemoglobin in diabetes mellitus: structure, function, and DNA sequence.

OBJECTIVE: To determine the nature and characteristics of a unique hemoglobin variant that causes a spurious increase in glycated hemoglobin (HbA1c). MATERIAL AND METHODS: Blood specimens from four unrelated persons with this hemoglobin variant were examined by conventional laboratory methods, including electrophoresis, high-performance ion-exchange chromatography, and isoelectric focusing; by amino acid sequence analysis, polymerase chain reaction-based DNA sequence analysis, and electrospray ionization mass spectrometry, to establish the molecular structure; and by studies of oxygen affinity under varied conditions, to define the functional characteristics of the hemoglobin variant. RESULTS: The unique hemoglobin variant observed in these four cases is due to the mutation CAC-->TAC, at beta-globin gene codon 143, corresponding to beta 143 (H21) His-->Tyr. This amino acid substitution affects an important 2,3-diphosphoglycerate binding site and slightly increases the oxygen affinity of the hemoglobin variant. CONCLUSION: A hitherto unrecognized hemoglobin variant, encountered in four unrelated persons of Irish or Scots-Irish ancestry, hemoglobin Old Dominion/Burton-upon-Trent, beta 143 (H21) His-->Tyr, has now been characterized at the molecular, structural, and functional levels. Although it is associated with a slight increase in oxygen affinity, it is without hematologic effect, and its only clinical significance is that it coelutes with HbA1c on ion-exchange chromatography and thereby causes a spurious increase in HbA1c and compromises the use of this analyte to monitor the treatment of diabetes mellitus.

Cardiac integrins the ties that bind.

An elaborate series of morphogenetic events must be precisely coordinated during development to promote the formation of the elaborate three-dimensional structure of the normal heart. In this study we focus on discussing how interconnections between the cardiac myocyte and its surrounding environment regulate cardiac form and function. In vitro experiments from our laboratories provide direct evidence that cardiac cell shape is regulated by a dynamic interaction between constituents of the extracellular matrix (ECM) and by specific members of the integrin family of matrix receptors. Our data indicates that phenotypic information is stored in the tertiary structure and chemical identity of the ECM. This information appears to be actively communicated and transduced by the α1ß1 integrin molecule into an intracellular signal that regulates cardiac cell shape and myofibrillar organization. In this study we have assessed the phenotypic consequences of suppressing the expression and accumulation of the α1 integrin molecule in aligned cultures of cardiac myocytes. In related experiments we have examined how the overexpression of α2 and α5 integrin, integrins normally not present or present at very low copy number on the cell surface of neonatal cardiac myocytes, affect cardiac protein metabolism. We also consider how biochemical signals and the mechanical signals mediated by the integrins may converge on common intracellular signaling pathways in the heart. Experiments with the whole embryo culture system indicate that angiotensin II, a peptide that carries information concerning cardiac load, plays a role in controling cardiac looping and the proliferation of myofibrils during development.

Cross-linking hemoglobin by design: lessons from using molecular clamps.

The development of a red cell substitute by chemical modification of hemoglobin has been approached as a systematic, iterative process. Acyl phosphate methyl esters were designed as anionic electrophiles to permit selective acylation of amino groups in the cationic site of hemoglobin which binds polyanions. Kinetic studies with systematically substituted acyl phosphates and amines show that the reaction is controlled by a reversible addition step followed by an irreversible elimination step. Acyl phosphate methyl esters which are derivatives of rigid dicarboxylic acids introduce cross-links in human hemoglobin between amino groups in the beta subunits (epsilon-NH2-Lys-82, alpha-NH2-Val-1) and permit correlation of oxygen binding properties with cross-link structure. The data suggest that the cross-link maintains cooperativity while reducing overall oxygen affinity by lowering the affinity of the R form for oxygen rather than by perturbing the R,T equilibrium of native hemoglobin. Materials produced from deoxyhemoglobin with a cross-link between positions 1 and 82 of the two beta units have appropriate oxygen affinity for red cell substitutes. The use of a trifunctional cross-linker, trimesyl tris(methyl phosphate) selectively produces hemoglobin with the desired 1-82 connection in good yield. The reagent is readily prepared and the properties of this chemically modified hemoglobin are suitable for trial as a red cell substitute, closely resembling those of optimized materials produced by recombinant technology. Further work is producing new chemicals and providing structural information.

Epitopes of adhesion-perturbing monoclonal antibodies map within a predicted alpha-helical domain of the integrin beta 1 subunit.

Several recent studies have demonstrated the involvement of various domains of the beta 1 integrin subunit in ligand binding. Thus, specific amino acids have been shown to be important in divalent cation binding, and others have been implicated by peptide crosslinking to play an intimate role in integrin-ligand interactions. Added to these data are previous observations that a group of adhesion-blocking anti-chicken beta 1 antibodies mapped within the first 160 amino acid residues of the subunit. These observations suggested that this region plays a critical role in integrin ligand recognition. In order to further define the domain in which the epitopes for these antibodies are clustered, a series of mouse/chicken chimeric beta 1 constructs were examined for their reactivity with each of these antibodies. Most of the antibodies recognize a region between residues 124 to 160 of the chicken beta 1 subunit. Computer modeling predicted a possible amphipathic alpha-helical configuration for the region between residues 141 to 160. Consistent with this prediction, circular dichroism and NMR analysis revealed a tendency for a synthetic peptide containing these residues to form an alpha-helix. The significance of this structural characteristic was demonstrated by a mutation at residue 149 that disrupted the alpha-helix formation and resulted in a loss of the ability to form heterodimers with alpha subunits, localize to focal contacts, or be transported to the cell surface. The direct involvement of residues 141 to 160 in ligand binding was supported by the ability of a peptide with this sequence to elute integrins from a fibronectin affinity column. Thus, our data suggest that residues 141 to 160 of the integrin beta 1 subunit, when arranged in an alpha-helix configuration, participate in ligand binding.

Modification of hemoglobin with site-directed bifunctional reagents.

Reaction of deoxy-Hb with the periodate-oxidized derivatives of nicotinamide adenine dinucleotide (o-NAD), phosphoribosyl pyrophosphate (o-PRPP), adenosine triphosphate (o-ATP), glucose-1-phosphate (o-glc-1-P) and nicotinamide adenine dinucleotide phosphate (o-NADP) led to formation of cross-link adducts in varying yields as determined by SDS-polyacrylamide gel electrophoresis. Oxygen equilibrium studies were performed on Hb's cross-linked with o-NAD, o-PRPP and o-ATP. These derivatives were found to have increased oxygen affinity and were cross-linked between the beta chains. Inositol hexaphosphate (IHP) blocked modification by these reagents, suggesting that modification was occurring in the organic phosphate binding site. In addition, it was found that the bifunctional reagent 4,4'-diisothiocyanatostilbene-2,2'-disulfonate (DIDS) also led to formation of Hb cross-linked between the beta chains, but resulted in a derivative with a dramatically decreased oxygen affinity, properties making it a potential candidate as an Hb-based cell-free blood substitute.

Affinity labeling of hemoglobin with 4,4'-diisothiocyanostilbene-2,2'-disulfonate: covalent cross-linking in the 2,3-diphosphoglycerate binding site.

The bifunctional reagent 4,4'-diisothiocyanostilbene-2,2'-disulfonate (DIDS) reacts with hemoglobin to give various products whose properties are dependent on the ligation state of the protein during the reaction. A major product obtained after reaction of (carbonmonoxy)hemoglobin with DIDS was a high oxygen affinity derivative [P50 = 1.4 mmHg, control P50 = 6 mmHg; 50 mM [bis(2-hydroxyethyl)-amino]tris(hydroxymethyl)methane (Bis-Tris), pH 7.4, 0.1 M Cl-, 25 degrees C] which contained two molecules of DIDS per tetramer resulting from adduct formation at each beta-chain amino terminus. In contrast, a major product of the reaction of deoxyhemoglobin with DIDS consisted of hemoglobin which had incorporated one molecule of DIDS per tetramer and was cross-linked between the beta-chain amino termini. This cross-linked hemoglobin was found to have a greatly decreased O2 affinity (P50 = 28 mmHg). Inhibition of the T to R transition due to the structural constraint produced by cross-linking the beta amino termini is likely to be a major factor in the decreased O2 affinity of this product. The structural and functional properties of this molecule make it a potential candidate for a cell-free blood substitute.

Was the loss of the D helix in alpha globin a functionally neutral mutation?

Proteins in the globin family are found in a variety of species from bacteria to man. From the many globin sequences known, evolutionary trees have been constructed showing that alpha and beta globins diverged from a common ancestor between 425 and 500 million years ago, after vertebrate species had appeared and roughly when sharks and bony vertebrates diverged. The alpha and beta globins assemble to form tetrameric haemoglobin, alpha 2 beta 2, which can switch between quaternary states having high and low oxygen affinity. This allows the protein to bind oxygen cooperatively and therefore efficiently transport oxygen from the lungs to respiring tissues. The alpha and beta globins have closely related tertiary structures, being alpha-helical proteins with similar haem-binding sites. Most globins consist of eight helices, designated A to H from the N terminus, connected by short nonhelical segments, but all known vertebrate alpha globins lack a D helix. Because the loss of this helix by alpha globin occurred shortly before tetrameric haemoglobin appeared, it might be a functionally important mutation required for a tetramer assembly or allostery. We have now tested this idea by engineering human haemoglobins containing beta subunits without a D helix and alpha subunits with a D helix. Both of these mutations have little effect on the oxygen-binding properties of the molecule. Thus it is possible that deletion of the D helix in the alpha subunit was caused by a neutral mutation.

Altered ligand rebinding kinetics due to distal-side effects in hemoglobin chico (Lysbeta66(E10) --> thr).

Hb Chico is an unusual human hemoglobin variant that has lowered oxygen affinity, but unaltered cooperativity and anion sensitivity. Previous studies showed these features to be associated with distal-side heme pocket alterations that confer increased structural rigidity on the molecule and that increase water content in the beta-chain heme pocket. We report here that the extent of nanosecond geminate rebinding of oxygen to the variant and its isolated beta-chains is appreciably decreased. Structural alterations in this variant decrease its oxygen recombination rates without significantly altering rates of migration out of the heme pocket. Data analysis indicates that one or more barriers that impede rebinding of oxygen from docking sites in the heme pocket are increased, with less consequence for CO rebinding. Resonance Raman spectra show no significant alterations in spectral regions sensitive to interactions between the heme iron and the proximal histidine residue, confirming that the functional differences in the variant are due to distal-side heme pocket alterations. These effects are discussed in the context of a schematic representation of heme pocket wells and barriers that could aid the design of novel hemoglobins with altered ligand affinity without loss of the normal allosteric responses that facilitate unloading of oxygen to respiring tissues.

Monoclonal antibody 9EG7 defines a novel beta 1 integrin epitope induced by soluble ligand and manganese, but inhibited by calcium.

The monoclonal antibody 9EG7 has been previously found to recognize an epitope induced by manganese on the integrin beta 1 chain (Lenter, M., Uhlig, H., Hamann, A., Jeno, P., Imhof, B., and Vestweber, D. (1993) Proc. Natl. Acad. Sci. U.S.A. 90, 9051-9055). Here we show that treatment of beta 1 integrins with manganese or soluble integrin ligands (e.g. fibronectin and RGD peptide) induced the 9EG7 epitope. This epitope was also induced upon EGTA treatment to remove calcium, and the addition of calcium inhibited 9EG7 epitope induction by manganese or by ligand. Further emphasizing the importance of the 9EG7 epitope, the 9EG7 antibody itself stimulated adhesion mediated by multiple beta 1 integrins, and conversely, ligands for alpha 2 beta 1, alpha 3 beta 1, alpha 4 beta 1, and alpha 5 beta 1 all stimulated 9EG7 expression. Together these results support a model whereby (i) calcium inhibits beta 1 integrin function because it prevents the appearance of a conformation favorable to ligand binding and (ii) manganese enhances beta 1 integrin function because it induces the same favorable conformation that is induced by adding ligand, or removing calcium. Notably, other beta 1-stimulating agents (magnesium and mAb TS2/16) did not induce 9EG7 expression unless ligand was also present. Thus, although 9EG7 may reliable detect the ligand-bound conformation of beta 1 integrins, its expression does not always correlate with integrin "activation". Finally, mouse/chicken beta 1 chimeric molecules were used to map the 9EG7 epitope to beta 1 residues 495-602 within the cysteine-rich region, and antibody cross-blocking studies showed that the 9EG7 epitope is distinct from all previously defined human beta 1 epitopes.

Involvement of the distal histidine in the low affinity exhibited by Hb Chico (Lys beta 66----Thr) and its isolated beta chains.

Hemoglobin (Hb) Chico (Lys beta 66----Thr at E10) has a diminished oxygen affinity (Shih, D. T.-b., Jones, R. T., Shih, M. F.-C., Jones, M. B., Koler, R. D., and Howard, J. (1987) Hemoglobin 11, 453-464). Our studies show that its P50 is about twice that of Hb A and that its cooperativity, anion, and Bohr effects between pH 7 and 8 are normal. The Bohr effect above pH 8 is somewhat reduced, indicating a small but previously undocumented involvement of the ionic bond formed by Lys beta 66 in the alkaline Bohr effect. Since the oxygen affinity of the alpha-hemes is likely to be normal, that of the beta-hemes in the tetramer is likely to be reduced by the equivalent of 1.2 kcal/mol beta-heme in binding energy. Remarkably, both initial and final stages of oxygen binding to Hb Chico are of lowered affinity relative to Hb A under all conditions examined. The isolated beta chains also show diminished oxygen affinity. In T-state Hb A, Lys(E10 beta) forms a salt bridge with one of the heme propionates, but comparison with other hemoglobin variants shows that rupture of this bridge cannot be the cause of the low oxygen affinity. X-ray analysis of the deoxy structure has now shown that Thr beta 66 either donates a hydrogen bond to or accepts one from His beta 63 via a bridging water molecule. This introduces additional steric hindrance to ligand binding to the T-state that results in slower rates of ligand binding. We measured the O2/CO partition coefficient and the kinetics of oxygen dissociation and carbon monoxide binding and found that lowered O2 and CO affinity is also exhibited by the R-state tetramers and the isolated beta chains of Hb Chico.