Study of the irreversible conformation change of immunoglobulin M by spin-labeling at the carbohydrate and peptide moieties of the molecule

The irreversible conformational change of the immunoglobulin M (IgM) molecule (Waldenstr?m disease) at pH approximately 3 was studied by means of spin-labels introduced in the carbohydrate (2,2,6,6,-tetramethyl-4-aminopiperidine-1-oxyl) and peptide (2,2,5,5,-tetramethyl-3-(dichloro-symm.-triazinylamino)-pyrrolidine-1-oxyl) moieties of the molecule. A marked rise of structure density of IgM especially in the (Fc)5-region and some minor local conformational changes in the Fab-regions were found. Comparison of our findings with the published data shows that Fab-regions of the principal immunoglobulins are rigid structures. Steric hindrance for Fab-regions increases markedly in the row Fab--F(ab')2--IgG--IgA--IgM restricting their spatial mobility. Monomeric Fc-regions of IgM are evidently flexible and one of the domains is especially mobile. It is supposed that oligosaccharide groups of IgM are of two types which differ in their spatial mobility. It was found by ammonium sulfate precipitation of IgM spin-labeled at the peptide moiety that the relative mobility of amino acid residues coupled with spin-label is strongly restricted.     

Some peculiarities of the dynamics of the immunoglobulin M structure

The isotropic mobility of separate regions of the intact molecule of immunoglobulin M (IgM) and its Fab and (Fc)5 fragments was studied using spin-labeling of carbohydrate (2,2,6,6-tetramethyl-4-aminopiperidine-1-oxyl) and peptide (2,2,5,5-tetramethyl-3-dichlorotriazinylaminopyrrolidine-1-oxyl) moieties. The spin-labeled oligosaccharide groups (OGs) in the Fab region are shown to have much more amplitude of anisotropic motion than those in the (Fc)5 region. The spin label in the latter is evidently attached in the C mu 3 domain to one of its OGs which is probably stabilized by ionic contacts between terminal N-acetylneuraminic acid residue and the peptide moiety of the IgM molecule. When the amount of the glycosidase-cleaved carbohydrate does not exceed 10-15%, most OGs affected are of the Fab region. Upon profound splitting (greater than or equal to 50%) the OGs of the (Fc)5 region are also affected; that results evidently in loosening the ionic contacts between the shortened OGs and the peptide moiety of IgM, and consequently in increasing mobility of the former. The structure of the (Fc)5 region of IgM is labile; after detaching this moiety from the intact IgM molecule, its structure is stabilized, but one of its domains (C mu 3) becomes more mobile than it is in the intact IgM molecule; at the same time the amplitude of anisotropic motion of OG bound here is decreased. In the latter case, this decrease depends on the sequence of spin-labeling and fragmentation. The most probable cause of stabilization of the (Fc)5 fragment is the heating of IgM solution to 56 degree C during fragmentation with trypsin. At this temperature the tau value for the (Fc)5 fragment is unusually low, equaling 23 ns. The spin-labeling in the peptide part of IgM occurs mostly in the Fab region which is a rather rigid moiety as expected.     

Non-covalent interactions between Fab and Fc regions in immunoglobulin G molecules. Hydrogen-deuterium exchange studies

To reveal non-covalent interactions between the Fab and Fc regions of IgG molecules the average conformational free-energy change (delta Go), associated with reversible micro-unfoldings, was measured by hydrogen-deuterium exchange for the Fab and Fc fragments and the complete molecule. Human monoclonal IgG1 and pooled IgG samples were used in these experiments. Hydrogen-deuterium exchange data were summarized and compared in the form of exchange relaxation spectra. The experimentally observed relaxation spectrum of intact IgG could not be deduced by weighted summation of spectra measured for Fab and Fc fragments. A comparison of the measured and calculated data revealed a 5-kJ/mol increase in the conformational free energy upon splitting the IgG molecule into two Fab and Fc pieces, i.e. an increase of conformational mobility occurred. This change can be explained either by related fluctuation patterns of the Fab and Fc pieces in the intact molecule or by a shielding effect on the contact surfaces. Both interpretations suppose non-covalent interactions between Fab and Fc that can be a means of information transduction between recognition and effector sites. The pH dependence of the hydrogen-deuterium exchange also indicates interactions between the Fab and Fc regions. A shift in the relaxation spectra of the Fab fragment was observed between pH 8.2 and 7.3 revealing destabilization of the structure at lower pH. This effect is absent in the intact molecule, reflecting interactions that stabilize the Fab structure. Comparison of the relaxation spectra of Fab and Fc shows a difference of about 10 kJ/mol in the microstability of these fragments: the Fab part possesses more conformational flexibility (i.e. its microstability is smaller) than the Fc part.     

Some Peculiarities of the Dynamics of the Immunoglobulin M Structure

Abstract

The isotropic mobility of separate regions of the intact molecule of immunoglobulin M (IgM) and its Fab and (Fc)₅ fragments was studied using spin-labeling of carbohydrate (2,2,6,6-tetramethyl-4-aminopiperidine-l-oxyl) and peptide (2,2,5,5-tetramethyl-3-dichloro-triazinylaminopyrrolidine-l-oxyl) moieties.

The spin-labeled oligosaccharide groups (OGs) in the Fab region are shown to have much more amplitude of anisotropic motion than those in the (Fc)₅ region. The spin label in the latter is evidently attached in the Cμ3 domain to one of its OGs which is probably stabilized by ionic contacts between terminal N-acetylneuraminic acid residue and the peptide moiety of the IgM molecule.

When the amount of the glycosidase-cleaved carbohydrate does not exceed 10–15%, most OGs affected are of the Fab region. Upon profound splitting (≥50%) the OGs of the (Fc)₅region are also affected; that results evidently in loosening the ionic contacts between the shortened OGs and the peptide moiety of IgM, and consequently in increasing mobility of the former.

The structure of the (Fc)₅ region of IgM is labile; after detaching this moiety from the intact IgM molecule, its structure is stabilized, but one of its domains (Cμ3) becomes more mobile than it is in the intact IgM molecule; at the same time the amplitude of anisotropic motion of OG bound here is decreased. In the latter case, this decrease depends on the sequence of spin-labeling and fragmentation.

The most probable cause of stabilization of the (Fc)₅ fragment is the heating of IgM solution to 56°C during fragmentation with trypsin. At this temperature the τ value for the (Fc)₅ fragment is unusually low, equaling 23 ns.

The spin-labeling in the peptide part of IgM occurs mostly in the Fab region which is a rather rigid moiety as expected.     

The role of carbohydrate groups in IgM. VIII. The effect of treatment of IgM with acids on the subsequent action of glycosidases and endogenous proteinases

Exposure of IgM to acidic medium (pH approximately 3, 30 min, at 20 degrees) and subsequent returning to neutral conditions leads to irreversible changes in the state of the molecule. This results in the loss of IgM accessibility for the action of glycosidases and, at the same time, makes it more susceptible to the action of proteinases. Both effects are thought to be due to an irreversible conformational rearrangement of IgM in acidic medium.     

Changes in the immunoglobulin M conformation in media with different degrees of acidity

The pH-dependent conformational changes in immunoglobulin M were studied by differential spectrophotometry. It was found that the state of chromophores (tryptophan and tyrosine) which reflects conformational changes of the structure alters stepwise in the course of acidification. The native structure is not restored by neutralization. The recovery of the native structure was obtained only at pH approximately 6.5 of the IgM solution. A possible explanation of concrete conformational transitions during the pH change is proposed. These changes were shown to be similar for IgM and IgG.     

Crystal structure at 2.8 A of an FcRn/heterodimeric Fc complex: mechanism of pH-dependent binding

The neonatal Fc receptor (FcRn) transports immunoglobulin G (IgG) across epithelia, binding IgG in acidic vesicles (pH < or = 6.5) and releasing IgG in the blood at pH 7.4. Well-ordered FcRn/Fc crystals are prevented by the formation of "oligomeric ribbons" of FcRn dimers bridged by Fc homodimers, thus we crystallized a 1:1 complex between rat FcRn and a heterodimeric Fc containing only one FcRn binding site. The 2.8 A complex structure demonstrates that FcRn uses its alpha2 and beta2-microglobulin domains and carbohydrate to interact with the Fc C(gamma)2-C(gamma)3 interface. The structure reveals conformational changes in Fc and three titratable salt bridges that confer pH-dependent binding, and can be used to guide rational design of therapeutic IgGs with longer serum half-lives.     

Effects of Amino and Thiol Group Reagents on the Ferredoxin:NADP+ Oxidoreductase Catalysed Reduction of Dibromothymoquinone

Effects of selective reagents of amino groups (fluorescamine, Fc) and thiol [5,5-dithio-bis(2-nitrobenzoic) acid, DTNB] groups on the diaphorase activity of spinach ferredoxin:NADP⁺ oxidoreductase (FNR, E.C 1.18.1.2) in the presence of dibromothymoquinone (DBMIB) as an electron acceptor were studied. The incubation of FNR with 250 M Fc in the time range from 0 to 120 min led to the gradual decrease of FNR activity according to biphasic kinetics. At the initial phase the activity (defined as the rate of NADPH oxidation) decreased about 4-time faster than at the subsequent second slower phase. Incubation of FNR simultaneously with Fc and DBMIB for more than 20 min caused restoration of the activity to about 80 % of the control. The inhibitory effect of Fc on the FNR-catalysed DBMIB reduction had non-competitive character. Incubation of FNR with DTNB led also to a gradual decrease of the enzyme activity, which reached about 45 % of the control after 2 h of incubation. Thus neither amino nor thiol groups in the FNR molecule are involved directly in the DBMIB reduction. However, the presence of DBMIB in the incubation medium influenced the inhibitory pattern of Fc and DTNB, and this suggests that DBMIB modified the conformational state of the FNR molecule.     

Comparative conformational studies on the tryptic digestion fragments of human immunoglobulins M and G

IgM¹ immunoglobulins were cleaved into Fabμ and (Fc)5μ fragments by tryptic digestion. Comparative circular dichroism studies with the corresponding IgG fragments show that the Fab portions of IgG and IgM proteins have very similar CD spectral features, although the same is not true for their Fc fragments. These studies indicate the presence of higher amount of beta-structured regions in Fcμ than in Fcγ. Also, there are considerable differences in their pH-dependent structural transitions as measured by CD spectral changes. The conformational differences between IgG and IgM immunoglobulins are more pronounced in their Fc portions, which carry out class specific biological functions, rather than in Fab portions, which contain antigen combining sites.     

pH dependence of the circular dichroic bands of phenylmethanesulfonyl-mesentericopeptidase.

The effect of pH on the circular dichroism spectra of phenylmethanesulfonyl-mesentericopeptidase (peptidyl peptide hydrolase, EC 3.4.21) was studied. The ellipticity of the bands below 250 nm, which reflects the backbone conformation of the protein molecule, remains almost unchanged in the pH range 6.2--10.4. However, below pH 6.2 and above pH 10.4 a conformational transition occurs. The pH-dependent changes above 250 nm were also studied. The titration of the CD band at 296 nm reflects the ionization of the "exposed" tyrosines, which phenolic groups are fully accessible to the solvent. An apparent pK of 9.9 is calculated from the titration curve. It is concluded that ionization of the tyrosyl residues with normal pK's is complete before conformational changes in the protein molecule occur.     

Accessibility of tryptophan residues in immunoglobulin M molecule as an indicator of its conformational variability

The accessibility of tryptophan residues in immunoglobulin M to modification with the Koshland reagent (2-hydroxy-5-nitrobenzyl bromide) was used as an indicator of its conformational variability. Of 14 tryptophan residues (per HL-fragment) in the native IgM, only one (presumably Trp312 in the mu-chain) was the most accessible. Irreversible acid- or temperature-induced conformational changes of IgM increased almost 2-fold the number of accessible tryptophan residues. After partial enzymatic deglycosylation of IgM (especially by an intense splitting of mannose), all tryptophan residues became inaccessible. Modification of the most accessible tryptophan residue increased 2- to 3-fold the number of tyrosine residues accessible to nitration with tetranitromethane. Using the spin label method, it was demonstrated that modification of four tryptophan residues in IgM considerably decreased the mobility of the Cmu 3 domain together with an essential drop in. the solubility of the modified IgM.     

Molecular and crystal structures of monoclinic porcine pepsin refined at 1.8 A resolution

The molecular structure of the archetypal aspartic proteinase, porcine pepsin (EC 3.4.23.1), has been refined using data collected from a single monoclinic crystal on a twin multiwire detector system to 1.8 A resolution. The current crystallographic R-factor (= sigma parallel to Fo/-/Fc parallel to/sigma/Fo/) is 0.174 for the 20,519 reflections with /Fo/ greater than or equal to 3 sigma (Fo) in the range 8.0 to 1.8 A (/Fo/ and /Fc/ are the observed and calculated structure factor amplitudes respectively). The refinement has shown conclusively that there are only 326 amino acid residues in porcine pepsin. Ile230 is not present in the molecule. The two catalytic residues Asp32 and Asp215 have dispositions in porcine pepsin very similar to the dispositions of the equivalent residues in the other aspartic proteinases of known structure. A bound solvent molecule is associated with both carboxyl groups at the active site. No bound ethanol molecule could be identified conclusively in the structure. The average thermal motion parameter of the residues that comprise the C-terminal domain of pepsin is approximately twice that of the residues in the N-terminal domain. Comparisons of the tertiary structure of pepsin with porcine pepsinogen, penicillopepsin, rhizopus pepsin and endothia pepsin reveal that the N-terminal domains are topographically more similar than the conformationally flexible C-terminal domains. The conformational differences may be modeled as rigid-body movements of "reduced" C-terminal domains (residues 193 to 212 and 223 to 298 in pepsin numbering). A similar movement of the C-terminal domain of endothia pepsin has been observed upon inhibitor binding. A phosphoryl group covalently attached to Ser68 O gamma has been identified in the electron density map of porcine pepsin. The low pKa1 value for this group, coupled with unusual microenvironments for several of the aspartyl carboxylate groups, ensures a net negative charge on porcine pepsin in a strongly acid medium. Thus, there is a structural explanation for the very early observations of "anodic migration" of porcine pepsin at pH 1. In the crystals, the molecules are packed tightly into a monoclinic unit cell. There are 190 direct contacts (less than or equal to 4.0 A) between a central pepsin molecule and the five unique symmetry-related molecules surrounding it in the crystalline lattice. The tight packing in this cell makes pepsin's active site and binding cleft relatively inaccessible to substrate analogs or inhibitors.     

Conformation, pH-induced conformational changes, and thermal unfolding of anti-p24 (HIV-1) monoclonal antibody CB4-1 and its Fab and Fc fragments

Conformation, acid-induced conformational changes and stability of the murine monoclonal antibody CB4-1 directed against the human immunodeficiency virus type 1 capsid protein p24, and its Fab and Fc fragments, were analysed by circular dichroism (CD), fluorescence, and differential scanning calorimetry (DSC) measurements. CD spectra show the characteristics expected for beta-proteins. Lowering the pH to 3.5 reduces the stability, but does not change the conformation. Between pH 3.5 and 2.0 conformational changes and the formation of new structures are indicated. Deconvolution of the bimodal DSC curves of CB4-1 reveals five 'two-state' transitions at pH 7.5. At pH 5 and below, only four transitions are found. Half transition temperatures Tm and molar enthalpy changes DeltaHm gradually decrease at pH 4 and 3.4. At pH 2.1, two low-temperature (Tm=36.9 and 44.1 degrees C) and two high-temperature (Tm=74.6 and 76.8 degrees C) transitions are identified. The Fab and Fc fragments behave similarly. Deconvolution of their monophasic DSC curves yields two 'two-state' transitions for each fragment. Tm and DeltaHm values gradually decrease at pH 4.0 and 3.4; and at pH 2.1 and 2.8 for Fab and Fc, respectively, one of the transitions is found at high temperature (Tm=67.2 and 75.9 degrees C for Fab and Fc, respectively).     

Conformational equilibria in a synthetic copolypeptide

A synthetic copolymer of L -glutamic acid and L -tyrosine (23:1) with molecular weight 17,000 was examined conformationally as a function of pH, using circular dichroism, difference spectrophotometry, fluorescence, potentiometic titration, and high-resolution nuclear magnetic resonance (220 MHz). A water-dioxan mixture (2:1) was used to avoid complications due to aggregation (which was shown by infrared spectroscopy to lead to the formation of β-structures). In the α-helical form the tyrosine residues generate a sizeable negative Cotton effect in the near ultraviolet; this is a consequence of perturbation of the chromophores by the helix, and not of tyrosine-tyrosine interactions, which are known to give rise in the right-handed α-helical state to positive Cotton effects. The pH profile of this Cotton effect is different from that of the peptide Cotton effects, which reflect the helix-random coil equilibrium. The data are interpreted in terms of preferential breakdown of the α-helix in the neighborhood of the tyrosine residues. An ultraviolet difference spectrum in the tyrosine absorption bands is generated at the low pH extreme of the conformational transition, the absorbance change being largely complete at a pH at which the other optical parameters have only begun to change. A possible explanation is the formation of a hydrogen bond between the phenolic hydroxyl and a carboxylate, the pK of which is lowered by the hydrogen bonding. An alternative explanation is the freezing of side-chain rotations at a pH below the onset of the helix-random coil transition, when the degree of side chain ionization approaches zero. Some support for the latter scheme comes from the splitting of side-chain methylene proton resonances, indicating partial immobilization, as well as small changes in chemical shift of tyrosine ring protons in the pH (or pD) region in which the difference spectrum appears.     

Conformational changes induced in a homogeneous anti-type III pneumococcal antibody by oligosaccharides of increasing size.

The circular polarization of luminescence (CPL) emitted by tryptophan residues was used as a sensitive probe for measuring ligand-induced structural changes in a homogeneous type III pneumococcal antibody. A series of oligosaccharide ligands of increasing size derived from type III polysaccharide by partial acid hydrolysis was assayed. Ligand-induced changes in the circular polarization of fluorescence of the antibody were observed for all antigens tested, including tetra-, hexa-, and octasaccharides and a 16-residue oligomer, the largest changes being recorded upon interaction with the intact soluble type III pneumococcal (SIII) polysaccharide. When Fab' or F(ab')2 fragments were used instead of the antibody IgG for binding of SIII polysaccharide, the extent of conformational changes was decreased. This suggests interactions between Fab and Fc portions in the IgG molecule and subsequent conformational changes in Fc part upon antigen binding. Reduction of interchain disulfide bonds abolished the additional spectral changes attributed to the Fc part but not the changes observed in the Fab part, thus suggesting that the presence of the interchain disulfide bond in the hinge region is required for maximal CPL changes to occur. Small monovalent ligands, i.e., the tetra-, hexa-, and octasaccharides, were capable of inducing CPL changes in the Fab part of the antibody molecule as well as CPL changes attributed to the Fc portion. A multivalent ligand containing about 16 sugar residues appears to be the minimal antigenic size required for triggering conformational changes attributed to the Fc part, similar to those seen in the interaction with the whole polysaccharide antigen.     

Structural dynamics of the manganese-stabilizing protein-effect of pH, calcium, and manganese

The photosystem-II-associated 33-kDa extrinsic manganese-stabilizing protein is found in all oxygen-evolving organisms. In this paper, we show that this protein undergoes pH-induced conformational changes in the physiological pH range. At a neutral pH of 7.2, the hydrophobic amino acid residues that are most likely located inside the beta barrel are "closed" and the protein binds neither Mn2+ nor Ca2+ ions. When the protein is transferred to a solution with a slightly acidic pH of 5.7, hydrophobic amino acid residues become exposed to the surrounding medium, enabling them to bind the fluorescent probe 8,1-ANS. At this pH-induced open state, Mn2+ and Ca2+ bind to the manganese-stabilizing protein. The pH values used in this study, 7.2 and 5.7, are typical of the pH found in the thylakoid lumen in the dark and light, respectively. A model is presented in which the manganese-stabilizing protein undergoes a pH-dependent conformational change that in turn influences its capacity to bind calcium and manganese. In this model, the proton-dependent conformational changes of the tertiary structure of the manganese-stabilizing protein are of functional relevance for the regulation of substrate (water) delivery to and product (proton) release from the water-oxidizing complex by forming a proton-sensing proton-transport pathway.     

NMR characterization of a pH-dependent equilibrium between two folded solution conformations of the pheromone-binding protein from Bombyx mori

NMR spectroscopic changes as a function of pH in solutions of the pheromone-binding protein of Bombyx mori (BmPBP) show that BmPBP undergoes a conformational transition between pH 4.9 and 6.0. At pH below 4.9 there is a single "acid form" (A), and a homogeneous "basic form" (B) exists at pH above 6.0. Between pH 5 and 6, BmPBP exists as a mixture of A and B in slow exchange on the NMR chemical shift time scale, with the transition midpoint at pH 5.4. The form B has a well-dispersed NMR spectrum, indicating that it represents a more structured, "closed" conformation than form A, which has a significantly narrower chemical shift dispersion. Conformational transitions of the kind observed here may explain heterogeneity reported for a variety of odorant-binding proteins, and it will be of interest to further investigate possible correlations with pH-dependent regulation of ligand binding and release in the biological function of this class of proteins.     

Myelin-Associated Glycoprotein Shares an Antigenic Determinant with a Glycoprotein of Human Melanoma Cells

A sulfated 100K-dalton glycoprotein has been shown to be released into the culture medium of melanoma cells. Monoclonal antibodies 10C5 and 11B5, which were raised to human melanoma cells, as well as HNK-1 bind to this glycoprotein. It is shown here that mouse anti-myelin-associated glycoprotein (MAG) carbohydrate antibodies raised to human MAG and a human IgM paraprotein associated with neuropathy also bind to the same 100K molecule. However, anti-MAG antibodies recognizing peptide epitopes do not appear to react with this glycoprotein of melanoma cells, a result suggesting that its similarity to MAG is restricted to shared carbohydrate moieties. The anti-melanoma antibodies (10C5 and 11B5) resemble HNK-1 in binding to MAG and to some 19-28K-dalton glycoproteins and sulfated, glucuronic acid-containing sphingoglycolipids of the peripheral nervous system (PNS). In addition, the anti-melanoma antibodies cross-react with neural cell adhesion molecule (N-CAM), an observation emphasizing the shared antigenicity between MAG and other adhesion molecules. The results demonstrate that the anti-melanoma antibodies fall into a class of monoclonal antibodies (including HNK-1, human IgM paraproteins associated with neuropathy, anti-human MAG antibodies, and L2 antibodies) that are characterized by reactivity against related carbohydrate determinants shared by human MAG, N-CAM, and several protein and lipid glycoconjugates of the PNS.     

Unique,pH-dependent biphasic band shape of the visible circular dichroism of curcumin-serum albumin complex

Interaction between the plant derived polyphenolic type curcumin molecule having anticarcinogenic, antiinflammatory, and antioxidant activities, and human serum albumin was studied at different pH values by circular dichroism (CD) and electronic absorption spectroscopy. The weak, induced CD spectrum of curcumin-HSA complex measured at pH 7.4 in the visible spectral region shows striking changes upon alkalization; CD spectra collected between pH 7.7 and 9.3 exhibit characteristic, oppositely signed CD band pair according to the visible absorption band of HSA-bound curcumin. At 0.3 curcumin/HSA molar ratio, typical molar CD values are Delta epsilon (496.6nm)+40M(-1)cm(-1) and Delta epsilon (426.8nm)-40M(-1)cm(-1), respectively (pH 9.0, t=37 degrees C). The induced optical activity is attributed to a bent, right-handed chiral conformation of the HSA-bound curcumin molecule within which intramolecular exciton coupling occurs between the electric dipole transition moments of the dissymmetrically juxtaposed feruloyl chromophores. Deprotonation of phenolic OH group(s) of curcumin seems to be the reason leading to the conformational alteration of HSA-bound curcumin.     

Iron-histidine stretching vibration in the deoxy state of insect hemoglobins with different O2 affinities and Bohr effects

Resonance Raman spectroscopy has been employed to detect the iron-proximal histidine stretching mode in deoxyhemoglobins from insect larvae of Chironomus thummi thummi (CTT). With the excitation of 413.1 nm, we observe a sharp and intense line in the 220-224 cm-1 region. The assignment of this line to the Fe-N epsilon (His) stretching mode was made on the basis of a 3-cm-1 shift upon 57Fe/54Fe isotope substitution. The Fe-N epsilon (His) vibration is used to monitor the possible changes in the Fe-N epsilon (His) bond strength (hence bone length) in the deoxy state of the monomeric (CTT I, III, and IV) and dimeric (CTT II) insect hemoglobins. As these hemoglobins differ in O2 affinity, off-rate and on-rate constants, and in the Bohr effect, they are excellent model systems for investigating the mechanism of protein control of the heme reactivity. Some of these hemoglobins (CTT III, IV, and II) are allosteric, exhibiting two interconvertible conformational states with high and low O2 affinity at high and low pH, respectively. The Fe-N epsilon (His) stretching frequency does not correlate with the O2 affinity, the on-rate and the off-rate constants for different hemoglobins, for different conformational states, and for modified hemoglobins with different heme peripheral groups. This vibrational mode is insensitive to deuteration of the heme vinyl groups. It is important to note that the Fe-N epsilon (His) bonds in the high pH (high-affinity) and the low pH (low-affinity) states are identical. This implies that the O2 molecule, prior to binding, "sees" identical binding sites. Thus, the difference in free energy changes upon O2 binding is manifested only in the oxy form.