Circular dichroism of soybean leghemoglobin.

Circular dichroic (CD) spectra of soybean leghemoglobin, and some of its liganded derivatives were measured over the wavelength range of 650 to 200 nm. The heme-related circular dichroic bands in the visible, Soret and ultraviolet wavelength regions exhibit Cotton effects characteristic of each of the compounds examined. The positions of the dichroic bands vary with ligand substitutions and the oxidation state of the iron. All leghemoglobin derivatives, except the apoprotein, exhibit negative circular dichroic bands in the region of Soret absorption. In this region the optical activity of compounds with high-spin moments is greater than that of compounds with low or intermediate spin moments. The ellipticity of the heme band at about 260 nm is also altered by ligand binding and spin state. The dichroic spectra in the far-ultraviolet region indicated a high extent of alpha-helical structure (about 70%) in the native leghemoglobin and its liganded derivatives. The helicality of the apoprotein seems to diminish suggesting a decrease caused by the removal of the heme.     

CD studies on the reversed heme orientation in monomeric Glycera dibranchiata hemoglobins

Circular dichroism spectra of three monomeric components of Glycera dibranchiata hemoglobins are reported. Contrary to what is found for most hemoglobins and myoglobins, G. dibranchiata hemoglobins display largely negative dichroic spectra in the Soret region. Independent NMR measurements have shown that the same monomeric hemoglobin components contain the heme moiety predominantly (greater than 85%) oriented in a reversed way with respect to the orientation which occurs in most hemoglobins and myoglobins. On the basis of these independent NMR studies, and also of previous data on other invertebrate hemoproteins, a correlation appears evident between reversed heme orientation in hemoglobins and negative ellipticity in the Soret CD spectrum. This represents a simple tool to evaluate this aspect of heme asymmetric environment.     

Anomalous pH dependence of the heme-bound carbon monoxide spectroscopic properties in the Glycera dibranchiata monomer hemoglobin fraction compared to vertebrate hemoglobins

The pH dependence of infrared and NMR spectroscopic parameters for carbon monoxide bound to human, equine, rabbit and Glycera dibranchiata monomer fraction hemoglobins has been examined. In all cases, the vertebrate hemoglobins exhibit CO vibrations and 13CO chemical shifts which are pH dependent, whereas the invertebrate hemoglobin does not. The Glycera dibranchiata monomer fraction exhibits the highest wavenumber CO vibration (1970 cm-1) and the most shielded chemical shift (206.2 ppm). The pH behavior of the vertebrate CO-hemoglobins is that the heme-coordinated carbon monoxide chemical shifts and principal infrared vibrations tend toward the values observed for the G. dibranchiata CO-hemoglobin fraction. These results are interpreted as originating in protonation of the distal histidine (E-7) in the vertebrate hemoglobins. The anomalous values for Glycera dibranchiata are concluded to be due to the absence of a distal histidine (E-7 His----Leu) in the heme pocket and not to gross structural dissimilarities between the proteins of the different species examined. Primary sequence similarity matrices have been constructed to compare the functional classes of amino acids at homologous positions for the CD and E helices and for the primary heme contacts in human, equine, sperm whale myoglobin, and the Glycera dibranchiata monomer hemoglobin to illustrate this point. They reveal a high correspondence for all globins and do not correlate with the spectroscopic parameters of heme-coordinated CO.     

Isoelectric focusing purity criteria and 1H NMR detectable spectroscopic heterogeneity in the major isolated monomer hemoglobins from Glycera dibranchiata

Three major monomeric hemoglobins have been isolated from the erythrocytes of Glycera dibranchiata. Their importance to structure-function studies of heme proteins lies in the fact that they have been shown to possess an exceptional amino acid substitution. In these proteins, the E-7 position is occupied by leucine rather than the more common distal histidine. This substitution alters the polarity of the heme ligand binding environment compared to myoglobin. Due to this, the G. dibranchiata monomer hemoglobins are attracting much attention. However, until now no purity criterion has been developed. Here we demonstrate that, for all of the Glycera monomer hemoglobins, multiple line patterns are shown on high-voltage isoelectric focusing (IEF) gels. Most of these lines are shown to be a consequence of heme-related phenomena and can be understood on the basis of changes in oxidation and ligation state of the heme iron. The multiple line pattern does not indicate significant impurities in the monomer hemoglobin preparations. Similar behavior is also demonstrated for horse heart myoglobin. The multiple line patterns on IEF gels disappear when gels of the apoproteins alone are focused. Single bands occur in this case for all of the monomer hemoglobins except component II, which displays two bands, one major and one minor. The minor band is found to be a modified apoprotein form. It is sensitive to apoprotein handling prior to focusing and depends upon whether the IEF gel is prefocused or not. From this analysis, IEF is shown to be a valuable purity criterion, and the purity of our monomer hemoglobin component II preparation is 97% one globin.(ABSTRACT TRUNCATED AT 250 WORDS)     

Allosteric transitions in cobalt hemoglobins.

Circular dichroism and difference ultraviolet visible spectra were obtained for cobalt hemoglobin derivatives. At 287 nm the ellipticity difference between the oxy- and deoxycobaltohemoglobin is about one-half as great as that for the native proteins indicating smaller quaternary conformational changes for the former. Deoxygenation increases the Soret rotational strengths of both iron and cobalt hemoglobins to comparable degrees suggesting similar conformational changes for their aromatic residues near the "heme." Deoxygenation causes a much larger decrease of L band ellipticity for iron than cobalt hemoglobin. Circular dichroism spectra of nitrosylcobaltohemoglobin indicate the molecule to have a T quaternary structure. The circular dichroism spectra of cobaltihemoglobin do not seem to fit the patterns of the other cobalt derivatives and its 287 nm ellipticity is pH-dependent. From the shape of the Soret circular dichroism spectra, it is estimated that the transition dipole makes an angle with the line joining the two opposing pyrrole nitrogens of about 60 degrees for oxy- and deoxycobaltohemoglobin, 80 degrees for cobaltihemoglobin, as compared to 70 degrees for the native oxy- and deoxyhemoglobins. Inositol hexaphosphate has little or no effect on the circular dichroism spectra of cobalt hemoglobins in the 287 nm region, but it significantly increases the Soret rotational strength and decreases the L band ellipticity. The results are interpreted to mean that polyphosphates modify primarily the protein structure of hemoglobins at the tertiary level, and that the intersubunit interactions are weak in cobalt hemoglobins.     

Studies on the orientations of the mitochondrial redox carriers. I. Orientation of the hemes of cytochrome c oxidase with respect to the plane of a cytochrome oxidase-lipid model membrane.

The liganded derivatives of mitochondrial cytochrome c oxidase have been prepared in hydrated oriented multilayers of membranous cytochrome c oxidase. The optical spectra of the liganded derivatives recorded at an angle of 45 degrees between the incident light beam and the normal to the planes of the membranes in the multilayers show dichroic ratios of almost 2 in the visible region and 1.2-1.4 in the Soret region. The dichroic ratios were found to be similar for both cytochromes a and a3. Electron paramagnetic resonance spectra of the azide, sulfide, and formate complexes of cytochrome c oxidase obtained as a function of the orientation of the applied magnetic field relative to the planes of the membranes in the multilayer confirm the optical data and demonstrate that both hemes of cytochrome c oxidase are oriented such that the angle between the heme normal and the membrane normal is approximately 90 degrees.     

NMR studies of the heme pocket conformations of monomeric hemoglobins from Glycera dibranchiata. Implications for ligand binding

Two-dimensional 1H-NMR methods have been used to assign side-chain resonances for the tryptophan residues and for several amino acids located in the heme pockets of the carbon monoxide complexes of the major monomeric hemoglobins from Glycera dibranchiata. The NMR spectra reveal a high degree of conservation of the heme pocket structure in the different hemoglobins. However some conformational differences are evident and residues at positions B10 and G8 on the distal side of the heme pocket are not conserved. From the present NMR studies it appears that the monomeric G. dibranchiata hemoglobin examined by X-ray crystallography [Padlan, E. A. & Love, W. (1974) J. Biol. Chem. 249, 4067-4078] corresponds to HbC. Except that the orientation of the heme in solution is the reverse of that reported in the crystal structure, there is a close correspondence between the heme pocket structure in the crystal and in solution. The proximal histidine coordination geometry is almost identical in the CO complexes of the three monomeric hemoglobins studied. Distal residues are strongly implicated in determining the observed kinetic differences in ligand binding reactions. In particular, steric crowding of the ligand binding site in hemoglobin A is probably a major factor in the slower kinetics of this component.     

Spectral changes upon subunit association in valency hybrid hemoglobins

The absorption, circular dichroism (CD) and magnetic circular dichroism (MCD) spectra of valency hybrid hemoglobins and their constituents (alpha + and beta chains for alpha 2+beta 2, alpha and beta + chains for alpha 2 beta 2+: + denotes ferric heme) were measured in the Soret region for F-, H2O, N3- and CN- derivatives. Absorption and MCD spectra of valency hybrid hemoglobins were very similar to the arithmetic mean of respective spectra of their corresponding component chains in all derivatives. The Soret MCD intensity around 408 nm for various complexes of valency hybrid hemoglobins seems to reflect the spin state of ferric chains. Upon ferric and deoxy ferrous subunit association to make the deoxy valency hybrid hemoglobins, only the high-spin forms bound with F- and H2O of alpha 2+beta 2 displayed a blue shift in the peak position around 430 nm and those of alpha 2 beta 2+ an increase in intensity around 430 nm. The blue shift and the increase in intensity were considered to be caused by the structural changes in deoxy beta chains of alpha 2+beta 2 and deoxy alpha chains of alpha beta 2+, respectively. These spectral changes were interpreted on the basis of their oxygen-equilibrium properties. In contrast to absorption and MCD spectra, the CD spectra of valency hybrid hemoglobins were markedly different from the simple addition of those of their component chains in all derivatives examined. The large part of CD spectral changes upon subunit association were interpreted as changes in the heme vicinity accompanied by formation of the alpha 1 beta 1 subunit contact.     

The structural bases for the unique ligand binding properties of Glycera dibranchiata hemoglobins. A resonance Raman study

The hemoglobin of the marine annelid Glycera dibranchiata possesses several unique features: the hemoglobin consists of multiple monomeric and polymeric components, quaternary structure is lacking, the distal histidine is replaced by leucine in at least one monomeric constituent, and 4) the protein exhibits extremely rapid ligand binding kinetics. The effect of these structural modifications on the ligand binding process has been evaluated using resonance Raman spectroscopy to examine the vibrational modes of the porphyrin macrocycle in deoxy and carbonmonoxy equilibrium species of hemoglobin G. dibranchiata in both the unseparated monomeric and polymeric forms and in a single monomeric component designated Fraction II. Significant differences relative to hemoglobin were found in porphyrin pi electron density, vinyl environment, low frequency vibrational modes, and, in particular, the Fe-proximal histidine stretching mode. Spectra of the deoxy heme transients generated within 10 ns of ligand photolysis have also been examined. These clearly indicate large differences in the heme pocket dynamics subsequent to CO photolysis in G. dibranchiata hemoglobins relative to other hemoglobins. The significance of these results in terms of the kinetics and thermodynamics of ligand binding is discussed.     

Structural consequences of heme isomerism in monomeric hemoglobins from Glycera dibranchiata

Two-dimensional 1H-NMR methods have been used to assign heme and amino acid proton resonances in both isomeric states of the carbon monoxide complexes of two Glycera dibranchiata monomeric hemoglobins, HbA and HbB. For each hemoglobin, there are small differences in heme pocket structure in the two isomeric forms. The largest structural perturbations associated with heme isomerism involve residues close to pyrrole rings I and II. The positions relative to the heme of phenylalanine CD1 and the proximal histidine ligand are almost unaffected by heme isomerism. These residues probably play a key role in determining the location of the heme within the heme pocket.     

Far-ultraviolet optical activity of saccharide derivatives. II. Dextran,amylose, and mycodextran acetes; dextran and amylose xanthates

The ultraviolet ORD and CD spectra of amylose, dextran, and mycodextran acetates and some of thier oligomers were recorded in trifluoroethanol solution in the 300–185nm wavelength range. Similarly, the spectra of amylose and dextran xanthates in water solution were obtained in the 400–200 nm range. In the amylose acetate series, the monomer and dimer both show a normal acetyl n → π* transition in CD, while the trimer and the polymer both exhibit an additional, shorter wavelength peak. The latter is presumed to arise from a helical conformation of the amylose chain. This interpretation is substantiated by a helix–coil type transition of the CD spectra of amylose triacetate at elevated temperatures and a reversion of the anomalous CD to the normal CD upon partial deacetylation. By contrast, neither dextran acetates nor mycodextran acetate exhibit any conformational effects. The CD of dextran acetates is quite sensitive to β-1,6 and branch linkages. The ORD and CD of amylose xanthate are complex, suggesting the presence of organized structure in solution. The dextran xanthate shows only a simple ORD spectrum and no observable CD.     

Steady-state fluorescence and circular dichroism of trout hemoglobins I and IV interacting with tributyltin

The effect of tributyltin chloride (TBTC) on rainbow trout (Salmo irideus) hemoglobin I (HbI) and hemoglobin IV (HbIV) was characterized by the steady-state fluorescence of intrinsic and extrinsic fluorescent probes. The fluorescence emission spectrum (lambdaex 280 nm) is greatly increased in intensity by the presence of the organotin in both proteins. Circular dichroism spectra in the same samples show a small decrease in theta222, a measure correlated with the percentage of the alpha-helical content. Morever, important changes in near-UV, Soret, and visible regions of CD were induced by TBTC. The correlation of data obtained with trout hemoglobins (HbI and HbIV) with similar measurements on globins suggests that the presence of heme is necessary for the interaction of the organotin compound with the proteins.     

Studies on the orientations of the mitochondrial redox carriers I. Orientation of the hemes of cytochrome c oxidase with respect to the plane of a cytochrome oxidase-lipid model membrane

The liganded derivatives of mitochondrial cytochrome c oxidase have been prepared in hydrated oriented multilayers of membranous cytochrome c oxidase. The optical spectra of the liganded derivatives recorded at an angle of 45° between the incident light beam and the normal to the planes of the membranes in the multilayers show dichroic ratios of almost 2 in the visible region and 1.2–1.4 in the Soret region. The dichroic ratios were found to be similar for both cytochromes a and a₃. Electron paramagnetic resonance spectra of the azide, sulfide, and formate complexes of cytochrome c oxidase obtained as a function of the orientation of the applied magnetic field relative to the planes of the membranes in the multilayer confirm the optical data and demonstrate that both hemes of cytochrome c oxidase are oriented such that the angle between the heme normal and the membrane normal is approximately 90°.     

Circular dichroism studies of myoglobin and leghemoglobin.

The circular dichroism spectra of leghemoglobin a from the root nodules of soybean have been compared with those for sperm whale myoglobin in the fat- and near-ultraviolet and the Soret and visible regions of the spectrum. Circular dichroism spectra in the far-ultraviolet show that the leghemoglobins all have a high alpha-helix content (soybean leghemoglobin a, 55%) regardless of the nature of bound ligands and oxidation or spin state of the heme iron. The known sequence homologies with mammalian hemoglobins may therefore be reflected in conformational homologies as suggested by the x-ray studies of Vainshtein et al. ((1975) Nature (London) 254, 163-164) on lupin leghemoglobin. Removal of the heme moiety decreases helicity by only 9% for leghemoglobins, compared with 23% for myoglobin. This, the much smaller heme contribution to the near-ultraviolet circular dichroism than in myoglobin, and the greater accessibility of the heme moiety to aqueous solvent (Nicola et al. (1974), Proc. Aust. Biochem. Soc. 7, 21) suggest that the association between heme and protein is much weaker in leghemoglobins than in myoglobin. The aromatic Soret and visible circular dichroism spectra for all derivatives of leghemoglobin are opposite in sense to those for myoglobin, showing that the patterns of protein side chain contacts with the heme are different in the two classes of heme proteins. There is strong evidence that one of the two tryptophans whose identity and structural role in myoglobin is known, is present also in plant leghemoglobins, hydrogen-bonded and in a similar nonpolar environment whether heme is present or not. The above findings help to explain the remarkably high oxygen affinity and some other ligand-binding properties of leghemoglobins which differ from those of myoglobin.     

Crystal structures of unligated and CN-ligated Glycera dibranchiata monomer ferric hemoglobin components III and IV

Erythrocytes of the marine annelid, Glycera dibranchiata, contain a mixture of monomeric and polymeric hemoglobins. There are three major monomer hemoglobin components, II, III, IV (also called GMH2, 3, and 4), that have been highly purified and well characterized. We have now crystallized GMH3 and GMH4 and determined their structures to 1.4-1.8 A resolution. The structures were determined for these two monomer hemoglobins in the oxidized (Fe3+, ferric, or met-) forms in both the unligated and cyanide-ligated states. This work differs from two published, refined structures of a Glycera dibranchiata monomer hemoglobin, which has a sequence that is substantially different from any bona fide major monomer hemoglobins (GMH2, 3, or 4). The high-resolution crystal structures (presented here) and the previous NMR structure of CO-ligated GMH4, provide a basis for interpreting structure/function details of the monomer hemoglobins. These details include: (1) the strong correlation between temperature factor and NMR dynamics for respective protein forms; (2) the unique nature of the HisE7Leu primary sequence substitutions in GMH3 and GMH4 and their impact on cyanide ion binding kinetics; (3) the LeuB10Phe difference between GMH3 and GMH4 and its impact on ligand binding; and (4) elucidation of changes in the structural details of the distal and proximal heme pockets upon cyanide binding.     

Circular dichroism spectra of purified cytochromes P-450 from rabbit liver microsomes.

Circular dichroism (CD) spectra were measured for cytochromes P-450 (P-450) purified from phenobarbital- and 3-methylcholanthrene-induced rabbit liver microsomes. No striking difference in alpha-helix content was seen between phenobarbital-induced P-450 (PB P-450) (50%), phenobarbital-induced P-448 (PB P-448) (40%) and 3-methylcholanthrene-induced P-448 (MC P-448) (45--50%) in terms of ultraviolet CD spectra. Strong negative CD spectra associated with 3-methylcholanthrene transitions for MC P-448 in the near-ultraviolet region (250--310 nm) and weaker negative CD spectra associated with Soret transitions for PBP-448 ([theta] = 50 000) and MCP-448 ([theta] = 160 000), indicated that structures of these preparations are strikingly different from each other. Reduction of P-450 and P-448 led to a remarkable decrease of the Soret CD trough, suggesting that reduction was accompanied by a striking conformational change in the vicinity of the heme. Since CO complexes of reduced P-450 and P-448 showed a CD trough and an S-shaped CD, respectively, associated with the absorption peak at 450 nm, the heme vicinities are remarkably different from each other. The CD spectra in the visible region are also discussed. It was noticed that P-420, the denatured form of P-450, exhibited no CD spectra in the Soret and visible regions.     

Circular dichroism studies on cytochrome c peroxidase from baker's yeast (Saccharomyces cerevisiae).

Circular dichroism spectra of cytochrome c peroxidase from baker's yeast, those of the reduced enzyme, the carbonyl, cyanide and fluoride derivatives and the hydrogen peroxide compound, Compound I, have been recorded in the wavelength range 200 to 660 nm. All derivatives show negative Soret Cotton effects. The results suggest that the heme group is surrounded by tightly packed amino acid sidechains and that there is a histidine residue bound to the fifth coordination site of the heme iron. The native ferric enzyme is probably pentacoordinated. The circular dichroism spectra of the ligand compounds indicate that the ligands form a nonlinear bond to the heme iron as a result of steric hindrance in the vicinity of the heme. The spectrum of Compound I shows no perturbation of the porphyrin symmetry. The dichroic spectrum of the native enzyme in the far-ultraviolet wave-length region suggests that the secondary structure consists of roughly equal amounts of alpha-helical, beta-structure and unordered structure. After the removal of the heme group no great changes in the secondary structure can be observed.     

Conformation of biological macromolecules. Circular dichroism and magnetic circular dichroism studies of metmyoglobin and its derivatives.

The circular dichroism (CD) and magnetic circular dichroism (MCD) spectra of horse heart metmyoglobin and the following derivatives were measured in the Soret and near ultraviolet regions: metmyoglobin and its peroxide compound, and hydroxide, cyanide, azide, and fluoride derivatives. The heme-related CD bands in the Soret and near ultraviolet wavelength regions were altered by ligand substitution, though their relationships to the magnetic moment were quite different. In the Soret region, the CD peak had no definite relation to the magnetic moment, while in the near ultraviolet region the magnitude of the CD peak decreased with the magnetic moment. The MCD peak in the Soret and near Ultraviolet regions also varied with ligand substitution. The magnetic ellipticity decreased with the magnetic moment in both wavelength regions. There was a more quantitative correlation between the magnetic ellipticity and the magnetic moment in the near ultraviolet region than in the Soret region. Metmyoglobin peroxide compound exhibited slightly different behavior in the MCD spectrum from other derivatives. It is suggested that the heme iron of the metmyoglobin peroxide compound is in an oxidation state other than the ferric state and that the porphyrin structure of metmyoglobin may be modified by the reaction with hydrogen peroxide.     

Heme Orientation of Cavity Mutant Hemoglobins (His F8 → Gly) in Either α or β Subunits: Circular Dichroism, 1H NMR,and Resonance Raman Studies

Native human adult hemoglobin (Hb A) has mostly normal orientation of heme, whereas recombinant Hb A (rHb A) expressed in E. coli contains both normal and reversed orientations of heme. Hb A with the normal heme exhibits positive circular dichroism (CD) bands at both the Soret and 260‐nm regions, while rHb A with the reversed heme shows a negative Soret and decreased 260‐nm CD bands. In order to examine involvement of the proximal histidine (His F8) of either α or β subunits in determining the heme orientation, we prepared two cavity mutant Hbs, rHb(αH87G) and rHb(βH92G), with substitution of glycine for His F8 in the presence of imidazole. CD spectra of both cavity mutant Hbs did not show a negative Soret band, but instead exhibited positive bands with strong intensity at the both Soret and 260‐nm regions, suggesting that the reversed heme scarcely exists in the cavity mutant Hbs. We confirmed by ¹H NMR and resonance Raman (RR) spectroscopies that the cavity mutant Hbs have mainly the normal heme orientation in both the mutated and native subunits. These results indicate that the heme Fe‐His F8 linkage in both α and β subunits influences the heme orientation, and that the heme orientation of one type of subunit is related to the heme orientation of the complementary subunits to be the same. The present study showed that CD and RR spectroscopies also provided powerful tools for the examination of the heme rotational disorder of Hb A, in addition to the usual ¹H NMR technique. Chirality 28:585–592, 2016. © 2016 Wiley Periodicals, Inc.     

Oxygen infrared spectra of oxyhemoglobins and oxymyoglobins. Evidence of two major liganded O2 structures

The dioxygen stretch bands in infrared spectra for solutions of oxy species of human hemoglobin A and its separated subunits, human mutant hemoglobin Zurich (beta 63His to Arg), rabbit hemoglobin, lamprey hemoglobin, sperm whale myoglobin, bovine myoglobin, and a sea worm chlorocruorin are examined. Each protein exhibits multiple isotope-sensitive bands between 1160 and 1060 cm-1 for liganded 16O2, 17O2, and 18O2. The O-O stretch bands for each of the mammalian myoglobins and hemoglobins are similar, with frequencies that differ between proteins by only 3-5 cm-1. The spectra for the lamprey and sea worm hemoglobins exhibit greater diversity. For all proteins an O-O stretch band expected to occur near 1125 cm-1 for 16O2 and 17O2, but not 18O2, appears split by approximately 25 cm-1 due to an unidentified perturbation. The spectrum for each dioxygen isotope, if unperturbed, would contain two strong bands for the mammalian myoglobins (1150 and 1120 cm-1) and hemoglobins (1155 and 1125 cm-1). Two strong bands separated by approximately 30 cm-1 for each oxy heme protein subunit indicate that two major protein conformations (structures) that differ substantially in O2 bonding are present. The two dioxygen structures can result from a combination of dynamic distal and proximal effects upon the O2 ligand bound in a bent-end-on stereochemistry.