Absence of cooperative energy at the heme in liganded hemoglobins

Using resonance Raman and infrared absorption spectroscopies, we show that there are no energetically significant structural changes at the heme upon the quaternary structure transition in six-coordinate hemoglobins. These observations are at variance with the presently accepted mechanism for cooperativity, which postulates severe strain in the T quaternary structure of liganded hemoglobin. By consideration of the present results, and studies on deoxyhemoglobins and photodissociated hemoglobins, a view of the distribution of the free energy of cooperativity emerges. In five-coordinate deoxyhemoglobins the iron-histidine bond is able to respond to the protein structure, thereby accounting for a wide variation (40 cm(1] in its frequency. In contrast, when a sixth ligand is present and the iron is pulled into plane, the histidine-heme-ligand complex becomes structurally rigid, thereby preventing protein-induced changes at the heme. Instead, in liganded hemoglobin the changes in structure that occur at the subunit interface upon the quaternary structure transition are accommodated away from the heme by relatively weak bonds in the protein.     

Resonance Raman Spectra of Photodissociated Hemoglobins: Implications on Cooperative Mechanisms

Resonance Raman spectra at cryogenic temperatures of photodissociated hemoglobins and the corresponding deoxygenated preparations are compared and significant differences are found in modes with contributions from peripheral substituents of the heme as well as in the iron-histidine stretching mode. These differences in heme vibrational spectra reflect differences in the tertiary structure of the heme pocket between deoxyhemoglobin and the CO-bound form. An analysis of the effects of cooperative energy storage on the tertiary structure around the heme is made and used to interpret this resonance Raman data. The differences between the spectra of the deoxygenated preparations and the photoproducts provide evidence that a fraction of the free energy of cooperativity, ΔG, is located away from the heme. These data support models for cooperativity in which the cooperative energy is distributed over many bonds or is localized in protein bonds only, such as those at the subunit interface. In addition, the local changes in amino acid positions, which must occur following the change in the state of ligand binding, may drive the changes in the structural relationships of the subunits and hence form one of the initial steps for triggering the quaternary structure transition.     

Selective binding of divalent cations toward heme proteins

Potential toxicity of transition metals like Hg, Cu and Cd are well known and their affinity toward proteins is of great concern. This work explores the selective nature of interactions of Cu²⁺, Hg²⁺ and Cd²⁺ with the heme proteins leghemoglobin, myoglobin and cytochrome C. The binding profiles were analyzed using absorbance spectrum and steady-state fluorescence spectroscopy. Thermodynamic parameters like enthalpy, entropy and free energy changes were derived by isothermal calorimetry and consequent binding parameters were compared for these heme proteins. Free energy (DG) values revealed Cu²⁺ binding toward myoglobin and leghemoglobin to be specific and facile in contrast to weak binding for Hg²⁺ or Cd²⁺. Time correlated single photon counting indicated significant alteration in excited state lifetimes for metal complexed myoglobin and leghemoglobin suggesting bimolecular collisions to be involved. Interestingly, none of these cations showed significant affinity for cytochrome c pointing that, presence of conserved sequences or heme group is not the only criteria for cation binding toward heme proteins, but the microenvironment of the residues or a specific folding pattern may be responsible for these differential conjugation profile. Binding of these cations may modulate the conformation and functions of these biologically important proteins.     

Calcium-bound structure of bovine cytochrome c oxidase

The crystal structure of bovine cytochrome c oxidase (CcO) shows a sodium ion (Na⁺) bound to the surface of subunit I. Changes in the absorption spectrum of heme a caused by calcium ions (Ca²⁺) are detected as small red shifts, and inhibition of enzymatic activity under low turnover conditions is observed by addition of Ca²⁺ in a competitive manner with Na⁺. In this study, we determined the crystal structure of Ca²⁺-bound bovine CcO in the oxidized and reduced states at 1.7 Å resolution. Although Ca²⁺ and Na⁺ bound to the same site of oxidized and reduced CcO, they led to different coordination geometries. Replacement of Na⁺ with Ca²⁺ caused a small structural change in the loop segments near the heme a propionate and formyl groups, resulting in spectral changes in heme a. Redox-coupled structural changes observed in the Ca²⁺-bound form were the same as those previously observed in the Na⁺-bound form, suggesting that binding of Ca²⁺ does not severely affect enzymatic function, which depends on these structural changes. The relation between the Ca²⁺ binding and the inhibitory effect during slow turnover, as well as the possible role of bound Ca²⁺ are discussed.     

Single-site modifications of half-ligated hemoglobin reveal autonomous dimer cooperativity within a quaternary T tetramer

The patterns of energetic response elicited by single-site hemoglobin mutations and chemical mocdifications have been determined in order to probe the dimer–dimer interface of the half-ligated tetramer (species[21]) that was previously shown to behave as allosterically distinct from both the unligated and fully ligated molecules¹. In this study the free energies of quaternary assembly(dimers to tetramers) were determined for aseries of 24 tetrameric species in which one dimeric half-molecule is ligated while the adjacent αβ dimer is unligated and contains a single amino acid modification. Assembly energies have also been determined for tetramers bearing the same amino acid modifications but where the hemesites were completely vacant and additionally where they were fully occupied. A total of 72 molecular species were thus characterized. It was found that mutationally induced perturbations to the free energy of quaternary assembly were identical for the half-ligated tetramers and the unligated tetramers over the entire spatial distrubution of altered sites, but exhibited a radically different pattern from that of the fully ligated molecules. These results indicate that the dimer–dimer interface of the half-ligated tetramer(species[21]) has the same quaternary sturcture as that of the unligated molecule, i.e, “quaternary T.” This quaternary structure assignment of species [21] strongly supports the operation of a Symmetry Rule which translates changes in hemesite ligation into six T → R quaternary switchpoints². Analysis of the observed Symmetry Rule behaviour in relation to the measured distribution of cooperative free energies for the partially ligated species reveals significant cooperativity between α and β subunits of the dimeric half-tetramer within quaternary T. The mutational results indicate that these interactions are not “paid for” by breaking or making noncovalent bonds at the dimer–dimer interface (α¹β²). They arise from structural and energetic changes that are “internal” to the ligated dimer even though its association with the unligated dimer is required for the cooperativity to occur. Free energy of “tertiary constraint” is thus generated by the first binding step and is propagated to the second hemesite while the dimer–dimer interface α¹β²serves as a constraint. The “sequential” cooperativity that occurs within the half-molecule is thus preconditioned by the constraint of a quaternary T interface; release of this constraint by dissociation produces only noncooperative dimers. When the constraint is released functionally by T to R dimer rearrangement (at each switch-point specified by the a Symmetry Rule) the alterations of interfacial bonds then dominate the energetics of cooperativity. © 1993 Wiley-Liss, Inc.     

Hemoglobin tertiary structural change on ligand binding its role in the co-operative mechanism

Analysis of the tertiary structural alterations in hemoglobin induced by ligand binding demonstrates that an allosteric core composed of the heme, histidine F8, the FG corner and part of the F-helix plays an essential role in co-operativity. This conclusion is based on structural and spectroscopic data and theoretical studies of hemoglobin chains. The methodology employed in the calculations is presented with details of the empirical energy function. Energy minimized structures of the unliganded hemoglobin chains, which serve as reference systems for the analysis, are described. To determine the structural changes induced by ligand binding, the effects of FeN bond shortening and of heme translation and tilting perturbations are examined. Energy minimization in the presence of the perturbations serves to provide information concerning the globin structural modifications produced by them. The validity of the results is supported by comparisons with the X-ray data of Anderson, Pulsinelli, Baldwin and Chothia on tertiary changes in the hemoglobin subunits.Internal to the allosteric core, there appear to be two stable positions for its elements: one of these corresponds to the liganded and the other to the unliganded species. The unliganded geometry fits without strain into the deoxy tetramer, while the liganded one fits without strain into the oxy tetramer. On ligation of a subunit in the deoxy tetramer, the structural changes within the allosteric core are in the direction of those found in going from the unliganded deoxy to the liganded oxy system, although they are reduced by the presence of constraints due to the other subunits in the deoxy tetramer. In addition, the quaternary constraints in the deoxy tetramer prevent the large overall displacement of the allosteric core that occurs in the transition to the liganded oxy tetramer. The coupling between the changes internal to the allosteric core, produced on ligation and the overall displacement of the core that accompanies the quaternary transition, is an essential element of the co-operative mechanism. As shown in previous work (Gelin & Karplus, 1977), the proximal histidine serves as the link between the position of the heme and the F-helix; the asymmetric orientation of the histidine in the deoxy structure, coupled with contributions from other heme-protein interactions, appears to initiate the tertiary structural changes induced by ligand binding. The reduced oxygen affinity of hemoglobin results not from tension on the heme in the unliganded structure (there is none) but instead from strain in the liganded subunit of the tetramer within the deoxy quaternary structure. Further, the changes in the allosteric core provide a relatively localized reaction path for transmitting information concerning ligand binding from the heme group to the surface of the subunit; particularly in the α-chain, the residue Val FG5 appears to play an important role in the reaction path.The present analysis has important implications for realistic statistical thermodynamic models of hemoglobin co-operativity. It suggests that the previously formulated model (Szabo & Karplus, 1972) should be generalized by the introduction of two different subunit tertiary structures in the deoxy and in the oxy tetramer; they would be associated with the unliganded and the liganded allosteric core, respectively, and would take account of steric constraints that reduce the ligand affinity of the deoxy tetramer.     

NMR study of hybrid hemoglobins containing unnatural heme: effect of heme modification on their tertiary and quaternary structures

The effect of heme modification on the tertiary and quaternary structures of hemoglobins was examined by utilizing the NMR spectra of the reconstituted [mesohemoglobin (mesoHb), deuterohemoglobin (deuteroHb)] and hybrid heme (meso-proto, deutero-proto) hemoglobins (Hbs). The heme peripheral modification resulted in the preferential downfield shift of the proximal histidine N1H signal for the beta subunit, indicating nonequivalence of the structural change induced by the heme modification in the alpha and beta subunits of Hb. In the reconstituted and hybrid heme Hbs, the exchangeable proton resonances due to the intra- and intersubunit hydrogen bonds, which have been used as the oxy and deoxy quaternary structural probes, were shifted by 0.2-0.3 ppm from that of native Hb upon the beta-heme substitution. This suggests that, in the fully deoxygenated form, the quaternary structure of the reconstituted Hbs is in an "imperfect" T state in which the hydrogen bonds located at the subunit interface are slightly distorted by the conformational change of the beta subunit. Moreover, the two heme orientations are found in the alpha subunit of deuteroHb, but not in the beta subunit of deuteroHb, and in both the alpha and beta subunits of mesoHb. The tertiary and quaternary structural changes in the Hb molecule induced by the heme peripheral modification were also discussed in relation to their functional properties.     

Picosecond phase grating spectroscopy of hemoglobin and myoglobin: energetics and dynamics of global protein motion.

Phase grating spectroscopy has been used to follow the optically triggered tertiary structural changes of carboxymyoglobin (MbCO) and carboxyhemoglobin (HbCO). Probe wavelength and temperature dependencies have shown that the grating signal arises from nonthermal density changes induced by the protein structural changes. The material displaced through the protein structural changes leads to the excitation of coherent acoustic modes of the surrounding water. The coupling of the structural changes to the fluid hydrodynamics demonstrates that a global change in the protein structure is occurring in less than 30 ps. The global relaxation is on the same time scale as the local changes in structure in the vicinity of the heme pocket. The observed dynamics for global relaxation and correspondence between the local and global structural changes provides evidence for the involvement of collective modes in the propagation of the initial tertiary conformational changes. The energetics can also be derived from the acoustic signal. For MbCO, the photodissociation process is endothermic by 21 +/- 2 kcal/mol, which corresponds closely to the expected Fe-CO bond enthalpy. In contrast, HbCO dissipates approximately 10 kcal/mol more energy relative to myoglobin during its initial tertiary structural relaxation. The difference in energetics indicates that significantly more energy is stored in the hemoglobin structure and is believed to be related to the quaternary structure of hemoglobin not present in the monomeric form of myoglobin. These findings provide new insight into the biomechanics of conformational changes in proteins and lend support to theoretical models invoking stored strain energy as the driving force for large amplitude correlated motions.     

Molecular dynamics simulation of cytochrome c3: studying the reduction processes using free energy calculations.

The tetraheme cytochrome c3 from Desulfovibrio vulgaris Hildenborough is studied using molecular dynamics simulation studies in explicit solvent. The high heme content of the protein, which has its core almost entirely made up of c-type heme, presents specific problems in the simulation. Instability in the structure is observed in long simulations above 1 ns, something that does not occur in a monoheme cytochrome, suggesting problems in heme parametrization. Given these stability problems, a partially restrained model, which avoids destruction of the structure, was created with the objective of performing free energy calculations of heme reduction, studies that require long simulations. With this model, the free energy of reduction of each individual heme was calculated. A correction in the long-range electrostatic interactions of charge groups belonging to the redox centers had to be made in order to make the system physically meaningful. Correlation is obtained between the calculated free energies and the experimental data for three of four hemes. However, the relative scale of the calculated energies is different from the scale of the experimental free energies. Reasons for this are discussed. In addition to the free energy calculations, this model allows the study of conformational changes upon reduction. Even if the precise details of the structural changes that take place in this system upon individual heme reduction are probably out of the reach of this study, it appears that these structural changes are small, similarly to what is observed for other redox proteins. This does not mean that their effect is minor, and one example is the conformational change observed in propionate D from heme I when heme II becomes reduced. A motion of this kind could be the basis of the experimentally observed cooperativity effects between heme reduction, namely positive cooperativity.     

Zinc binding promotes greater hydrophobicity in Alzheimer's Aβ42 peptide than copper binding: Molecular dynamics and solvation thermodynamics studies

The aggregation of Aβ42 peptides is considered as one of the main causes for the development of Alzheimer's disease. In this context, Zn²⁺ and Cu²⁺ play a significant role in regulating the aggregation mechanism, due to changes in the structural and the solvation free energy of Aβ42. In practice, experimental studies are not able to determine the latter properties, since the Aβ42–Zn²⁺ and Aβ42–Cu²⁺ peptide complexes are intrinsically disordered, exhibiting rapid conformational changes in the aqueous environment. Here, we investigate atomic structural variations and the solvation thermodynamics of Aβ42_, Aβ42–Cu²⁺, and Aβ42–Zn²⁺ systems in explicit solvent (water) by using quantum chemical structures as templates for a metal binding site and combining extensive all-atom molecular dynamics (MD) simulations with a thorough solvation thermodynamic analysis. Our results show that the zinc and copper coordination results in a significant decrease of the solvation free energy in the C-terminal region (Met35-Val40), which in turn leads to a higher structural disorder. In contrast, the β-sheet formation at the same C-terminal region indicates a higher solvation free energy in the case of Aβ42_. The solvation free energy of Aβ42 increases upon Zn²⁺ binding, due to the higher tendency of forming the β-sheet structure at the Leu17-Ala42 residues, in contrast to the case of binding with Cu²⁺. Finally, we find the hydrophobicity of Aβ42–Zn²⁺ in water is greater than in the case of Aβ42–Cu²⁺.     

Exploring the folding energy landscapes of heme proteins using a hybrid AWSEM-heme model

Heme is an active center in many proteins. Here we explore computationally the role of heme in protein folding and protein structure. We model heme proteins using a hybrid model employing the AWSEM Hamiltonian, a coarse-grained forcefield for the protein chain along with AMBER, an all-atom forcefield for the heme. We carefully designed transferable force fields that model the interactions between the protein and the heme. The types of protein–ligand interactions in the hybrid model include thioester covalent bonds, coordinated covalent bonds, hydrogen bonds, and electrostatics. We explore the influence of different types of hemes (heme b and heme c) on folding and structure prediction. Including both types of heme improves the quality of protein structure predictions. The free energy landscape shows that both types of heme can act as nucleation sites for protein folding and stabilize the protein folded state. In binding the heme, coordinated covalent bonds and thioester covalent bonds for heme c drive the heme toward the native pocket. The electrostatics also facilitates the search for the binding site.

     

Conformational transitions of a dipeptide in water: Effects of imposed pathways using umbrella sampling techniques

The free energy difference between two states of a molecular system separated by an energy barrier can generally be computed using the technique of umbrella sampling along a chosen reaction coordinate or pathway. The effect of a particular choice of pathway upon the obtained free energy difference is investigated by molecular dynamics simulation of a model system consisting of a glycine dipeptide in aqueous solution. Two different reaction coordinates connecting the so-called C₅ and C₇ conformations, one involving intramolecular hydrogen bonds and the other involving the peptide ?, ψ angles, are considered. The Gibbs free energy differences ΔG(C₅ – C₇) are small in both cases, 1.5 ± 1 kJ mol^?1 and 2.2 ± 1 kJ mol ^?1, respectively. The two different reaction coordinates yield free energy differences that are identical to within their statistical error. It is found that the exchange of solute–solute, solute–water, and water–water hydrogen bonds involves free energy changes of less than k_BT, which points at the existence of a multitutde of low free energy pathways connecting the C₅ and C₇ dipeptide conformations. © 1994 John Wiley & Sons, Inc.     

Quaternary structure and spin-state transition in azide methemoglobin A

The temperature-dependent ultraviolet and visible absorption changes of human azide methemoglobin with and without inositol hexaphosphate (IHP) were examined in a 4'-35 degrees C range. The 537-nm absorption change of IHP-free hemoglobin was about 1.2-fold larger than that of IHP-bound hemoglobin. The data were analyzed by considering the thermal spin equilibrium within the R and T conformers and the quaternary equilibrium between the two conformers. The spin equilibrium analysis suggested that the T conformer has a larger high-spin content than the R conformer. The quaternary equilibrium analysis, on the other hand, showed that the T conformer is more populated at lower temperature. The thermodynamic values for the quaternary equilibrium were determined to be delta H = -13.3 kcal/mol and delta S = -47.6 eu. The large negative delta H and delta S values were compensated for each other to give a small energy difference between the two quaternary states, e.g., delta G4 = 670 cal/mol of tetramer at 20 degrees C. The coincidence of the temperature-dependent IHP-induced changes in the visible and ultraviolet absorptions of heme and aromatic chromophores at the subunit boundaries suggested that the quaternary transition energy is not localized at heme moiety. The reverse temperature dependence of the T conformer fraction as compared with the high-spin fraction of heme iron was interpreted as indicating that the appearance of the T state is not directly coupled with an increase in the strain of Fe-N(F8 His) linkage in azide methemoglobin A.     

Ligand-linked structural transitions in crystals of a cooperative dimeric hemoglobin

Cooperative ligand binding in the dimeric hemoglobin (HbI) from the blood clam Scapharca inaequivalvis is mediated primarily by tertiary structural changes, but with a small quaternary rearrangement (approximately 3 degrees), based on analysis of distinct crystal forms for ligated and unligated molecules. We report here ligand transition structures in both crystal forms. Binding CO to unligated HbI crystals results in a structure that approaches, but does not attain, the full allosteric transition. In contrast, removing CO from the HbI-CO crystals results in a structure that possesses all the key low affinity attributes previously identified from analysis of HbI crystals grown in the unligated state. Subsequent binding of CO shows the reversibility of this process. The observed structural changes include the quaternary rearrangement even under the constraints of lattice interactions, demonstrating that subunit rotation is an integral component of the ligand-linked structural transition in HbI. Analysis of both crystal forms, along with data from HbI mutants, suggests that the quaternary structural change is linked to the movement of the heme group, supporting a hypothesis that the heme movement is the central event that triggers cooperative ligand binding in this hemoglobin dimer. These results show both the effects of a crystal lattice in limiting quaternary structural transitions and provide the first example of complete allosteric transitions within another crystal lattice.     

Interhelical hydrogen bonds in transmembrane region are important for function and stability of Ca2+-transporting ATPase

Ca²⁺-transporting adenosine triphosphatase (ATPase) of sarcoplasmic reticulum couples ATP hydrolysis with ion transport. Phosphorylation of the cytosolic region of the calcium-bound conformation (E1) of the protein leads to drastic conformational rearrangements of the transmembrane helices and the release of Ca²⁺. The resulting calcium-free conformation (E2) is less stable than the E1 form. The changes in van der Waals interactions and interhelical hydrogen bonding in the E1 and E2 conformations were compared. Conformational changes in the transmembrane region concomitant with the release of Ca²⁺ mainly affect the number of interhelical hydrogen bonds, which is reduced to half of that in E1 form, whereas the number of interhelical atomic pairwise contacts reflecting van der Waals interactions experience little change. The interhelical hydrogen bonds in Ca²⁺-transporting ATPase can be divided into two groups according to their roles: those that play a structural stabilizing role and those that are important for the correct geometry of the Ca²⁺ binding site. Interhelical hydrogen bonds in the transmembrane regions play important roles for the stability and specificity of helix-helix interactions in proteins where change of conformation is required for transport of ions or small molecules.     

Degradation Pathway of Bisphenol A: Does ipso Substitution Apply to Phenols Containing a Quaternary α-Carbon Structure in the para Position?

The degradation of bisphenol A and nonylphenol involves the unusual rearrangement of stable carbon-carbon bonds. Some nonylphenol isomers and bisphenol A possess a quaternary α-carbon atom as a common structural feature. The degradation of nonylphenol in Sphingomonas sp. strain TTNP3 occurs via a type II ipso substitution with the presence of a quaternary α-carbon as a prerequisite. We report here a new degradation pathway of bisphenol A. Consequent to the hydroxylation at position C-4, according to a type II ipso substitution mechanism, the C-C bond between the phenolic moiety and the isopropyl group of bisphenol A is broken. Besides the formation of hydroquinone and 4-(2-hydroxypropan-2-yl)phenol as the main metabolites, further compounds resulting from molecular rearrangements consistent with a carbocationic intermediate were identified. Assays with resting cells or cell extracts of Sphingomonas sp. strain TTNP3 under an ¹⁸O₂ atmosphere were performed. One atom of ¹⁸O₂ was present in hydroquinone, resulting from the monooxygenation of bisphenol A and nonylphenol. The monooxygenase activity was dependent on both NADPH and flavin adenine dinucleotide. Various cytochrome P450 inhibitors had identical inhibition effects on the conversion of both xenobiotics. Using a mutant of Sphingomonas sp. strain TTNP3, which is defective for growth on nonylphenol, we demonstrated that the reaction is catalyzed by the same enzymatic system. In conclusion, the degradation of bisphenol A and nonylphenol is initiated by the same monooxygenase, which may also lead to ipso substitution in other xenobiotics containing phenol with a quaternary α-carbon.     

The structure of horseradish peroxidase C characterized as a molten globule state after Ca2+ depletion

The structure and activity of native horseradish peroxidase C (HRP) is stabilized by two bound Ca²⁺ ions. Earlier studies suggested a critical role of one of the bound Ca²⁺ ions but with conflicting conclusions concerning their respective importance. In this work we compare the native and totally Ca²⁺-depleted forms of the enzyme using pH-, pressure-, viscosity- and temperature-dependent UV absorption, CD, H/D exchange-FTIR spectroscopy and by binding the substrate benzohydroxamic acid (BHA). We report that Ca²⁺-depletion does not change the alpha helical content of the protein, but strongly modifies the tertiary structure and dynamics to yield a homogeneously loosened molten globule-like structure. We relate observed tertiary changes in the heme pocket to changes in the dipole orientation and coordination of a distal water molecule. Deprotonation of distal His42, linked to Asp43, itself coordinated to the distal Ca²⁺, perturbs a H-bonding network connecting this Ca²⁺ to the heme crevice that involves the distal water. The measured effects of Ca²⁺ depletion can be interpreted as supporting a structural role for the distal Ca²⁺ and for its enhanced significance in finetuning the protein structure to optimize enzyme activity.     

Interaction of fully liganded valency hybrid hemoglobin with inositol hexaphosphate. Implication of the IHP-induced T state of human adult methemoglobin in the low-spin state

To gain further insight into the quaternary structures of methemoglobin derivatives in the low-spin state, the interaction of fully liganded valency hybrid human hemoglobins with IHP was studied by proton NMR spectroscopy. Upon addition of IHP to (alpha CO beta + N3-)2, the same resonances as the previously reported IHP-induced NMR peaks for azidomethemoglobin (alpha + N3-beta +N3-)2 appeared, whereas the binding of IHP did not significantly affect the NMR spectra for (alpha + N3-beta CO)2. The binding of IHP also brought about more pronounced spectral changes for (alpha CO beta + Im)2 and (alpha CO beta + H2O)2 than for (alpha + Im beta CO)2 and (alpha + H2O beta CO)2. Therefore, the IHP-induced NMR peaks for azidomethemoglobin are attributed to the beta heme methyl group. Such IHP-induced beta heme methyl resonances were also observed for (alpha NO beta + N3-)2, which undergoes quaternary structural change, analogously to the R-T transition by the binding of IHP. From the above results, it was suggested that the IHP-induced heme methyl resonances for azidomethemoglobin and (alpha CO beta +N3-)2 may also be associated with the quaternary structure of these Hbs, implying the presence of the IHP-induced "T-like" state in low-spin metHb A.     

Growth Cycle-Dependent Overproduction and Accumulation of Protoporphyrin IX in Tetrahymena: Effect of Heavy Metals1

Cells of the ciliate Tetrahymena pyriformis GL overproduce and accumulate massive quantities of the heme intermediate, protoporphyrin IX. Protoporphyrin is localized intracellularly in discrete membranous compartments. The amount of porphyrin stored in the cell changes dramatically as cells progress through the growth cycle. Porphyrin overproduction is stimulated by δ-aminolevulinic acid, but only during the mid-stationary phase. Overproduction of protoporphyrin IX apparently results from an increase, late in the growth cycle, of activities subsequent to δ-aminolevulinic acid synthetase. Feedback inhibition in the pathway by accumulated protoporphyrin IX does not occur. The presence of Co²⁺ completely inhibits accumulation of protoporphyrin IX in a manner reversed by δ-aminolevulinic acid. Sn⁴⁺ stimulates protoporphyrin IX accumulation in the culture.     

High pressure NMR studies of hemoproteins. The effect of pressure on the tertiary and quaternary structures of human adult ferrous hemoglobin

The effect of pressure on the tertiary and quaternary structures of human oxy, carbonmonoxy, and deoxyhemoglobin was examined by high pressure NMR spectroscopy at 300 MHz. The increased pressure displaced the ring current-shifted gamma 1-methyl resonance of beta E11 valine for oxy- and carbonmonoxyhemoglobin to the upfield side, whereas that of the alpha subunit was insensitive to pressure. Such a preferential pressure-induced upfield shift for the beta E11 valine gamma 1-methyl signal was also encountered for the isolated carbonmonoxy beta chain. For deoxyhemoglobin, hyperfine shifted resonances of the heme peripheral proton groups and the proximal histidyl NH proton for the beta subunit were pressure-dependent, in contrast to the pressure-insensitive responses for these resonances of the alpha subunit. These results indicate the structural nonequivalence of the pressure-induced structural changes in the alpha and beta subunits of hemoglobin. The exchangeable proton resonances due to the intra- and intersubunit hydrogen bonds which have been used as the oxy and deoxy quaternary structural probes were not changed upon pressurization. From all of above results, it was concluded that pressure induces the tertiary structural change preferentially at the beta heme pocket of the ferrous hemoglobin derivatives with the quaternary structure retained.