Myelin basic protein binds heme at a specific site near the tryptophan residue

Fluorescence of the single tryptophan residue in myelin basic protein (MBP) was excited directly at 295 nm (red-edge excitation) or at 278 nm which allows, in addition, indirect excitation by resonance energy transfer (RET) from any nearby tyrosine residues. Both red-edge excitation and the RET pathway were collisionally quenched by I- and acrylamide, but not by Cs+ or Co2+, implying that the fluorophore is in an exposed, positively charged environment. The quenching coefficients (K) for I- are 12-15 M-1 at both excitation wavelengths while coefficients for acrylamide are 15 M-1 at 278-nm and 8 M-1 at 295-nm excitation. Chloroheme, cyanoheme, and protoporphyrin IX also quench both red-edge excitation and the RET pathway with apparent quenching coefficients which are (2-5) X 10(4)-fold higher. This suggests that the mechanism of quenching now includes static in addition to collisional processes and thus that heme has a relatively high affinity for MBP. Scatchard analysis of the quenching suggests that chloroheme binds to MBP at two sites with dissociation constants (Kd) of 1.6 X 10(-8) and 2.0 X 10(-7) M and stoichiometries of 0.04:1 and 0.16:1, respectively. The hydrophobic fluorescent probe 4,4'-bis[1-(phenylamino)-8-naphthalenesulfonate] [bis(ANS)] binds to MBP less avidly (Kd = 10(-7) M) and is rapidly displaced by chloroheme (Ki = 2 X 10(-8) M). The affinities of bis(ANS) and heme for MBP, along with the fluorescent amino acid quenching data, demonstrate that a subfraction of MBP molecules contain considerable structural specificity, implying stable long-range interactions in the molecule.(ABSTRACT TRUNCATED AT 250 WORDS)     

Functional effects of heme orientational disorder in sperm whale myoglobin

The optical absorption and ligand binding properties of newly reconstituted sperm whale myoglobin were examined systematically at pH 8, 20 degrees C. The conventional absorbance and magnetic circular dichroism spectra of freshly reconstituted samples were identical to those of the native protein. In contrast, reconstituted azide or CO myoglobin initially exhibited less circular dichroism in the Soret wavelength region than native myoglobin. These data support the theory proposed by La Mar and co-workers (La Mar, G. N., Davis, N. L., Parish, D. W., and Smith, R. M. (1983) J. Mol. Biol. 168, 887-896) that protoheme inserts into apomyoglobin in two distinct orientations. The equilibrium and kinetic parameters for O2 and CO binding to newly reconstituted myoglobin were observed to be identical to those of the native protein. Thus, the orientation of the heme group has no effect on the physiological properties of myoglobin. This result is in disagreement with the preliminary report of Livingston et al. (Livingston, D. J., Davis, N. L., La Mar, G. N., and Brown, W. D. (1984) J. Am. Chem. Soc. 106, 3025-3026) which suggested that the abnormal heme conformation exhibited a 10-fold greater affinity and association rate constant for O2 binding. Significant kinetic heterogeneity was observed only for long-chain isonitrile binding to newly reconstituted myoglobin, and even in these cases, the rate constants for the abnormal and normal heme conformations differed by less than a factor of 4.     

Reconstitution of myoglobin from apoprotein and heme, monitored by stopped-flow absorption, fluorescence and circular dichroism

The reconstitution reaction of ferric cyanomyoglobin from apomyoglobin and hemin dicyanide was investigated with a stopped-flow apparatus by the use of five kinds of probes; (a) Soret absorption, (b) fluorescence quenching of tryptophan, (c) far-ultraviolet CD, (d) near-ultraviolet CD, and (e) Soret CD. After mixing of apomyoglobulin with equimolar amounts of hemin dicyanide, the Soret absorption band was shifted to longer wavelengths within 10 ms. The shifted band kept its shape for a few seconds, and then gradually shifted to shorter wavelengths. A rate constant of the slow reaction was 1.1 x 10(-2) s-1. Time courses of fluorescence quenching followed a second-order reaction with a rate constant of 9 x 10(7) M-1 s-1. Far-ultraviolet CD recovered to the level of native state within the response time of an apparatus (= 64 ms). Near-ultraviolet CD and Soret CD changed with first-order rate constants of 5-30 s-1 and 5 x 10(-3) s-1 respectively. On the basis of the kinetic results we propose the following reconstitution pathway of myoglobin. Apomyoglobin has essentially a highly folded structure similar to myoglobin, but there are some differences in the secondary structure between them. In the first step, heme enters the pocket-like site of apomyoglobin and interacts with surrounding hydrophobic residues in the pocket, and then the interaction may give a complete ordered structure to the protein. Second, the tertiary structure of the heme pocket is partly constructed. Third, the iron-proximal His bond occurs, followed by the attainment of the final conformation. This sequence of the events shows that the polypeptide chain is entirely folded before the completion of three-dimensional structure of the heme pocket. The reconstitution pathway is fairly different from that of the alpha subunit of hemoglobin reported by Leutzinger and Beychok [Proc. Natl Acad. Sci. USA (1981) 78, 780-784], which described how a drastic recovery in helicity was observed on the heme-binding, and that the recovery is introduced by the formation of the heme pocket structure. The difference in the results found for the alpha subunit and myoglobin suggests a difference in conformation: in apomyoglobin most of the helices are arranged and folded around a helix core to form a compact structure as a whole, while in apo-alpha subunit some helices are not folded around the helix core. Helix D, which is absent in the alpha subunit, may play an important role in folding of the helices.     

Identification of Cys385 in the isolated kinase insertion domain of heme-regulated eIF2 alpha kinase (HRI) as the heme axial ligand by site-directed mutagenesis and spectral characterization

Heme-regulated eIF2alpha kinase (HRI) is an important enzyme that modulates protein synthesis during cellular emergency/stress conditions, such as heme deficiency in red cells. It is essential to identify the heme axial ligand(s) and/or binding sites to establish the heme regulation mechanism of HRI. Previous reports suggest that a His residue in the N-terminal region and a Cys residue in the C-terminal region trans to the His are axial ligands of the heme. Moreover, mutational analyses indicate that a residue located in the kinase insertion (KI) domain between Kinase I and Kinase II domains in the C-terminal region is an axial ligand. In the present study, we isolate the KI domain of mouse HRI and employ site-directed mutagenesis to identify the heme axial ligand. The optical absorption spectrum of the Fe(III) hemin-bound wild-type KI displays a broad Soret band at around 373nm, while that of the Fe(II) heme-bound protein contains a band at 422nm. Spectral titration studies conducted for both the Fe(III) hemin and Fe(II) heme complexes with KI support a 1:1 stoichiometry of heme iron to protein. Resonance Raman spectra of Fe(III) hemin-bound KI suggest that thiol is the axial ligand in a 5-coordinate high-spin heme complex as a major form. Electron spin resonance (ESR) spectra of Fe(III) hemin-bound KI indicate that the axial ligands are OH(-) and Cys. Since Cys385 is the only cysteine in KI, the residue was mutated to Ser, and its spectral characteristics were analyzed. The Soret band position, heme spectral titration behavior and ESR parameters of the Cys385Ser mutant were markedly different from those of wild-type KI. Based on these spectroscopic findings, we conclude that Cys385 is an axial ligand of isolated KI.     

Binding, electrochemical activation, and cleavage of DNA by cobalt(II) tetrakis-N-methylpyridyl porphyrin and its beta-pyrrole brominated derivative

The binding of nucleic acids by water-soluble cobalt(II) tetrakis-N-methylpyridyl porphyrin, (TMPyP)Co, and its highly electron-deficient derivative cobalt(II) tetrakis-N-methyl pyridyl-beta-octabromoporphyrin, (Br(8)TMPyP)Co, was investigated by UV-visible absorption, circular dichroism (CD), and electrochemical and gel electrophoresis methods. The changes of the absorption spectra during the titration of these complexes with polynucleotides revealed a shift in the absorption maxima and a hypochromicity of the porphyrin Soret bands. The intrinsic binding constants were found to be in the range of 10(5)-10(6) M(-1). These values were higher for the more electron-deficient (Br(8)TMPyP)Co. Induced CD bands were noticed in the Soret region of the complexes due to the interaction of these complexes with different polynucleotides, and an analysis of the CD spectra supported a mainly external mode of binding. Electrochemical studies revealed the cleavage of polynucleotides by (TMPyP)Co and (Br(8)TMPyP)Co in the presence of oxygen preferentially at the A-T base pair region. Gel electrophoresis experiments further supported the cleavage of nucleic acids. The results indicate that the beta-pyrrole brominated porphyrin, (Br(8)TMPyP)Co, binds strongly and cleaves nucleic acids efficiently as compared with (TMPyP)Co. This electrolytic procedure offers a unique tool in biotechnology for cleaving double-stranded DNA with specificity at the A-T regions.     

DiGeorge critical region 8 (DGCR8) is a double-cysteine-ligated heme protein

All known heme-thiolate proteins ligate the heme iron using one cysteine side chain. We previously found that DiGeorge Critical Region 8 (DGCR8), an essential microRNA processing factor, associates with heme of unknown redox state when overexpressed in Escherichia coli. On the basis of the similarity of the 450-nm Soret absorption peak of the DGCR8-heme complex to that of cytochrome P450 containing ferrous heme with CO bound, we identified cysteine 352 as a probable axial ligand in DGCR8. Here we further characterize the DGCR8-heme interaction using biochemical and spectroscopic methods. The DGCR8-heme complex is highly stable, with a half-life exceeding 4 days. Mutation of the conserved proline 351 to an alanine increases the rate of heme dissociation and allows the DGCR8-heme complex to be reconstituted biochemically. Surprisingly, DGCR8 binds ferric heme without CO to generate a hyperporphyrin spectrum. The electronic absorption, magnetic circular dichroism, and electron paramagnetic resonance spectra of the DGCR8-heme complex suggest a ferric heme bearing two cysteine ligands. This model was further confirmed using selenomethionine-substituted DGCR8 and mercury titration. DGCR8 is the first example of a heme-binding protein with two endogenous cysteine side chains serving as axial ligands. We further show that native DGCR8 binds heme when expressed in eukaryotic cells. This study provides a chemical basis for understanding the function of the DGCR8-heme interaction in microRNA maturation.     

A protein with multiple heme-binding sites from rabbit serum

A 93,000 molecular weight protein (HBP.93) which binds hemin and protoporphyrin IX with high affinity has been isolated from rabbit serum using affinity chromatography on hemin-conjugated agarose. The amino acid composition of this protein is unique in that the proline and histidine contents are remarkably high (16.6 and 9.9 mol %, respectively). A large increase in the absorbance of the Soret region arises from the heme-protein interaction. The spectrophotometric titration showed that the protein can bind 25-35 mol of hemin/mol of protein. The apparent dissociation constant was estimated to be 1-4 X 10(-7) M for hemin at pH 7.4 and approximately 10(-6) M for protoporphyrin IX at pH 9.2. The similarity of the difference spectrum of heme-HBP.93 complex to that of heme-hemopexin complex suggests that a bisimidazol-type coordination of heme iron is involved in the binding. The extremely high capacity of HBP.93 to bind heme is also demonstrated by a large increase in the sedimentation velocity of the protein upon heme binding. The native heme-protein complex migrates faster than the heme-free protein in a polyacrylamide gel at pH 8.8; the increased mobility appears to be due to the charge on the carboxyl groups of the bound heme. Although the use of a hemin-agarose column has failed to reveal a protein of similar size and heme affinity in the sera of a number of other species, including man, the heme-binding properties and high histidine level of the human alpha 2-histidine-rich glycoprotein raise the possibility that the two proteins are related.     

Spectroscopic and equilibrium properties of the indoleamine 2,3-dioxygenase-tryptophan-O2 ternary complex and of analogous enzyme derivatives. Tryptophan binding to ferrous enzyme adducts with dioxygen, nitric oxide, and carbon monoxide

The dioxygen adduct of the heme protein indoleamine 2,3-dioxygenase has been generated at -30 degrees C in mixed solvents, and spectroscopic and equilibrium studies of its L-tryptophan (substrate) binding properties have been carried out for the first time. Comparative studies have also been performed with the NO and CO adducts of the ferrous enzyme. Under the conditions employed (-30 degrees C), both autoxidation and turnover (L-tryptophan + O2----formylkynurenine) of the ternary complex are effectively suppressed. Structural identification of the ternary complex is based on the 1:1 molar stoichiometry for the substrate-oxygenated enzyme adduct formation (Kd approximately 10(-4) M), the time-dependent linear product formation (turnover) at -20 degrees C, and the quantitative conversion of the complex to the ferrous CO derivative by bubbling with CO. Binding of L-tryptophan to the oxygenated enzyme leads to decreases in the intensities of its major absorption bands (lambda max 415, 541, 576 nm) and to a blue shift of its Soret peak. Interestingly, among the ferrous enzyme derivatives examined, only the substrate-bound oxygenated enzyme exhibits solvent-dependent Soret absorption peak positions, e.g., lambda max 411.5 and 413.5 nm in 65% (v/v) aqueous glycerol and ethylene glycol, respectively. In addition, indole binds to the oxygenated enzyme, causing a red shift of its Soret peak in these solvents only in the presence of substrate (411.5----414 nm and 413.5----414.5 nm, respectively), while similar effects of indole are independent of tryptophan for the other ferrous enzyme derivatives.(ABSTRACT TRUNCATED AT 250 WORDS)     

Construction, characterization, and mutagenesis of an anti-fluorescein single chain antibody idiotype family.

In addition to crystallographic studies that determined antigen contact residues for monoclonal anti-fluorescein (Fl) antibody 4-4-20 (Ka = 2.5 x 10(10) M-1), primary structure comparisons revealed idiotypically cross-reactive monoclonal antibodies (mAbs) 9-40 (Ka = 4.4 x 10(7) M-1), 12-40 (Ka = 4.0 x 10(8) M-1), and 5-14 (Ka = 2.4 x 10(8) M-1) possessed identical Fl contact residues, with the exception of L34His for L34Arg. Site-specific mutagenesis of single chain antibody (SCA) 4-4-20 in which L34Arg was changed to L34His resulted in approximately 1000- and 3-fold decreases in binding affinity and Qmax (maximum quenching of bound Fl), respectively, which suggested that L34Arg was directly involved in increased binding affinity and fluorescence quenching. Therefore, substitution of Arg for His at residue L34 in mAbs 9-40, 12-40, and 5-14 should result in increased binding affinity and Qmax. To facilitate site-specific mutagenesis studies, single chain derivatives of mAbs 9-40, 12-40, and 5-14 were constructed. Following expression in Escherichia coli, characterization of the SCAs demonstrated that when compared with the respective parental mAb, the SCAs possessed identical binding affinities and similar Qmax and lambda max (absorption profiles of bound Fl) values. These results validated SCA 9-40, 12-40, and 5-14 for use in site-directed mutagenesis studies. Results of mutagenesis studies indicated that substitution of L34Arg into the active sites of 9-40, 12-40, and 5-14 was not enough to produce 4-4-20-like binding characteristics. Therefore, the following single chain mutants were constructed: 9-40L34Arg/L46Val, 12-40L34Arg/L46Val and 5-14L34Arg/L46Val, 9-40L34Arg/L46Val/H101Asp and 4-4-20H101Ala. Results demonstrated that these mutations were not able to render the mutant SCAs with increased binding affinity and fluorescence quenching values. Collectively, these results suggest that the combining sites of mAb 9-40, 12-40, and 5-14 may possess different active site structures than mAb 4-4-20.     

Studies of the interaction between paraquat and bovine hemoglobin

The interaction between paraquat (PQ) and bovine hemoglobin (BHb) was investigated using fluorescence and UV/vis absorption spectroscopy. The reactivity of the heme centers with superoxide anions formed by PQ was judged on the basis of the decrease of the Soret band. The experimental results showed that the fluorescence quenching of BHb by PQ was a result of the formation of PQ-BHb complex; static quenching was confirmed to result in the fluorescence quenching. The binding site number n, apparent binding constant K(A) and corresponding thermodynamic parameters were measured at different temperatures. The process of binding PQ molecule on BHb was a spontaneous molecular interaction procedure in which entropy increased and Gibbs free energy decreased. Hydrophobic and electrostatic interactions played a major role in stabilizing the complex. The effect of PQ on the conformation of BHb was analyzed using synchronous fluorescence spectroscopy.     

Absorption spectroscopy and circular dichroism studies of sperm whale myoglobin chemically modified on the N-terminal α-aminogroup by isothiocyanate reagents

Sperm whale metMb [Mb(SW)] was modified chemically by fluorescein isothiocyanate and methylisothiocyanate. Individual modification products on the α-aminogroup of the N-terminal Val were isolated with ion exchange chromatography (FITC-Mb and MITC-Mb). Absorption spectra in the 200–700 nm region and spectrophotometric titration curves in the Soret band of the modified metMb derivatives and intact metMb were compared. Characteristic differences between them indicate that upon modification there occurs a shift in the equilibrium of isomers of the metMb aquo complex towards the low-spin form. The CD spectra of FITC-metMb and MITC-inetMb in the 200–450 nm region attest to small changes in the heme environment as compared to native metMb without, however, any appreciable conformational changes of the polypeptide chain. No differences have been found in the absorption and CD spectra in the Soret region between native deoxy-Mb and the modified Mb derivatives in deoxy forms. An analysis of the present results and of those reported in the literature shows that the conformational changes at the N-end of Mb upon modification of the N-terminal α-amino group result in structural alterations in the heme environment which are most likely to consist in some reorientation of the side group of His E7 and, possibly, those of phe B14, Phe CD1,and Phe CD4 on the distal side of the heme. A scheme of the electronic conformational interactions (ECI) in ferrimyoglobin is proposed.     

Expression,Purification, and Characterization of the Recombinant Putative Periplasmic Hemin-Binding Protein (HutB) of Photobacterium damselae subsp. piscicida

HutB, the periplasmic hemin binding protein of Photobacterium damselae subsp. piscicida, was produced as a recombinant protein. UV-Vis spectrophotometrical analysis showed absorption spectral changes in hemin upon mixing it with the recombinant protein, indicating complex formation. Spectrophotometric titration of HutB with hemin showed saturation at a heme/HutB ratio of 1:1 and a binding affinity (K _d) of 10 μM.     

An archaeal b-type cytochrome containing a nonfunctional carbonic anhydrase-like domain

A new type of cytochrome b was isolated from the cytoplasmatic fraction of the archaeon Acidianus ambivalens, which is the first soluble cytochrome found in this member of the thermoacidophilic order of the Sulfolobales. The protein is a monomeric and monohemic cytochrome b with a molecular mass of 22 kDa. Visible spectroscopy of the as-purified protein shows a Soret peak at 405 nm and a broad band at 625 nm, indicating the presence of a high-spin ferric heme. Upon reduction, the Soret band shifts to 422 nm and a broad band at 560 nm develops, again characteristic of high-spin ferrous heme. The reduced form can bind carbon monoxide, with visible absorption bands arising at 411 and 566 nm. EPR spectroscopy of the oxidized protein shows a spectrum typical of a high-spin heme, with major g values at 6.56 and 5.85. The reduction potential of the heme cofactor was determined to be -16+/-10 mV, at pH 6.5. Analysis of the protein amino acid sequence shows that it consists of a novel arrangement of domains. The first domain, at the N-terminus, has a remarkable similarity towards beta class carbonic anhydrases, whereas the second region comprises a putative cytochrome domain. The latter presumably consists of a novel fold, as it bears no sequence similarities towards other known cytochromes, or towards known domains. Strikingly, the first module contains the C-X (n)-H-X(2)-C motif that accounts for the binding of the catalytic zinc in carbonic anhydrases, but lacks several other critical residues required for substrate binding and proper active site geometry. In agreement with this finding, the isolated cytochrome contains one bound zinc atom, but has no carbonic anhydrase activity. Inspection of the sequences available from the genomic sequencing project of the close relative archaeon Sulfolobus solfataricus shows the presence of an identical protein, suggesting its dissemination among the Sulfolobales. The role of zinc as a key element for the intrinsic thermal stability of these proteins is discussed.     

Heme symmetry, vibronic structure, and dynamics in heme proteins: ferrous nicotinate horse myoglobin and soybean leghemoglobin

We report the visible and Soret absorption bands, down to cryogenic temperatures, of the ferrous nicotinate adducts of native and deuteroheme reconstituted horse heart myoglobin in comparison with soybean leghemoglobin-a. The band profile in the visible region is analyzed in terms of vibronic coupling of the heme normal modes to the electronic transition in the framework of the Herzberg-Teller approximation. This theoretical approach makes use of the crude Born-Oppenheimer states and therefore neglects the mixing between electronic and vibrational coordinates; however, it takes into account the vibronic nature of the visible absorption bands and allows an estimate of the vibronic side bands for both Condon and non-Condon vibrational modes. In this framework, an x-y splitting of the Q transition for native and deuteroheme reconstituted horse myoglobin is clearly assessed and attributed to electronic perturbations that, in turn, are caused by a reduction of the typical D(4h) symmetry of the system due to heme distortions of B(1g)-type symmetry and/or to an x-y asymmetric position of the nicotinate ring; in deuteroheme reconstituted horse myoglobin the asymmetric heme peripheral substituents add to the above effect(s). On the contrary, in leghemoglobin-a no spectral splitting upon nicotinate binding is observed, pointing to a planar heme configuration in which only distortions of A(1g)-type symmetry are effective and to which the nicotinate ring is bound in an x - y symmetric position. The local dynamic properties of the heme pocket of the three proteins are investigated through the temperature dependence of spectral line broadening. Leghemoglobin-a behaves as a softer matrix with respect to horse myoglobin, thus validating the hypothesis of a looser heme pocket conformation in the former protein, which allows a nondistorted heme configuration and a symmetric binding of the bulky nicotinate ligand.     

Chromatographically distinguishable heme insertion isoforms of human hemopexin

Two spectroscopically distinct, non-interconverting forms of human hemopexin have been isolated by immobilized metal ion affinity chromatography and characterized spectroscopically. Form alpha (characterized by a bisignate Soret CD spectrum) and form beta (Soret CD characterized by a positive Cotton effect) exhibit different spectroscopic responses to addition of Zn2+ or Cu2+, yet both forms exhibit the same metal ion-induced decrease in Tm for the thermally induced release of the heme prosthetic group. Far UV-CD spectra indicate that the two isoforms possess essentially identical secondary structures, but their differential retention during metal ion affinity chromatography indicates slight differences in exposure of His residues on the protein surface. We propose that these observations result from the binding of heme in form beta with an orientation that differs from the crystallographically observed binding orientation for rabbit hemopexin by rotation of the heme prosthetic group by 180 degrees about the alpha-gamma meso-carbon axis and from interaction of metal ions at two separate binding sites.     

Evidence for redox cooperativity between c-type hemes of MauG which is likely coupled to oxygen activation during tryptophan tryptophylquinone biosynthesis

MauG is a novel 42 kDa diheme protein which is required for the biosynthesis of tryptophan tryptophylquinone, the prosthetic group of methylamine dehydrogenase. The visible absorption and resonance Raman spectroscopic properties of each of the two c-type hemes and the overall redox properties of MauG are described. The absorption maxima for the Soret peaks of the oxidized and reduced hemes are 403 and 418 nm for the low-spin heme and 389 and 427 nm for the high-spin heme, respectively. The resonance Raman spectrum of oxidized MauG exhibits a set of marker bands at 1503 and 1588 cm(-1) which exhibit frequencies similar to those of the nu3 and nu2 bands of c-type heme proteins with bis-histidine coordination. Another set of marker bands at 1478 and 1570 cm(-1) is characteristic of a high-spin heme. Two distinct oxidation-reduction midpoint potential (E(m)) values of -159 and -244 mV are obtained from spectrochemical titration of MauG. However, the two nu3 bands located at 1478 and 1503 cm(-1) shift together to 1467 and 1492 cm(-1), respectively, upon reduction, as do the Soret peaks of the low- and high-spin hemes in the absorption spectrum. Thus, the two hemes with distinct spectral properties are reduced and oxidized to approximately the same extent during redox titrations. This indicates that the high- and low-spin hemes have similar intrinsic E(m) values but exhibit negative redox cooperativity. After the first one-electron reduction of MauG, the electron equilibrates between hemes. This makes the second one-electron reduction of MauG more difficult. Thus, the two E(m) values do not describe redox properties of distinct hemes, but the first and second one-electron reductions of a diheme system with two equivalent hemes. The structural and mechanistic implications of these findings are discussed.