Asymmetric distribution of cooperativity in the binding cascade of normal human hemoglobin. 2. Stepwise cooperative free energy

Stepwise cooperative free energies and intermediate Hill coefficients are used to assess the presence of noncooperative sequences in the database of binding free energies previously obtained for the eight partially ligated intermediates of human hemoglobin, encompassing a variety of hemesite analog substitutions. This analysis is prompted by the observed noncooperative binding of two ligands to hemoglobins that are partially substituted with Zn2+-heme, an analog of deoxy Fe2+-heme (Holt et al. (2005) Biochemistry 44, XXXXX). The results show that noncooperative binding sequences are observed in all hemesite analog studied to date. The noncooperative binding observed in (alpha2Znbeta2FeO2) and (alpha2FeO2beta2Zn) is therefore not a Zn-specific substitution artifact. One of several binding sequences from singly to triply ligated hemoglobin is also observed to occur with little or no positive cooperativity. These results demonstrate the variability possible among different ligation pathways in a highly cooperative multi-subunit system such as hemoglobin. As a direct consequence of this variability, differences among ligation pathways are not always detectable using cooperativity functions based on statistical distributions, such as the Hill coefficient n(H). The limitations of Hill coefficient analysis in evaluating cooperativity in intermediates of complex systems is contrasted with the utility of the stepwise binding parameters.     

Asymmetric distribution of cooperativity in the binding cascade of normal human hemoglobin. 1. Cooperative and noncooperative oxygen binding in Zn-substituted hemoglobin

The complete binding cascade of human hemoglobin consists of eight partially ligated intermediates and 16 binding constants. Each intermediate binding constant can be evaluated via dimer-tetramer assembly when ligand configurations within the tetramer are fixed through the use of hemesite analogs. The Zn/Fe analog, in which the nonbinding Zn2+ heme substitutes for deoxy Fe2+ heme, also permits direct measurement of O2 binding to the remaining Fe2+ hemesites within the symmetrically ligated Hb tetramers. Measurement of O2 binding over a range of Zn/Fe Hb concentrations to both alpha-subunits (species 23) or to both beta-subunits (species 24) shows noncooperative binding and incomplete saturation of the available Fe2+ hemesites. In contrast, the asymmetrically ligated Zn/FeO2 species 21, in which both oxygens are bound to one of the dimers within the tetramer, exhibits positive cooperativity and >90% ligation under atmospheric conditions. These properties are confirmed in the present study by measurement of the rate constant for tetramer dissociation to free dimer. The binding constants thus derived for these partially ligated intermediates are consistent with the stoichiometric constants measured for native hemoglobin by standard O2 binding techniques, providing additional evidence that Zn2+-heme substitution provides an excellent deoxy hemoglobin analog. There is no evidence that Zn-substitution stabilizes a low-affinity form of the tetramer, as previously suggested. These characterizations demonstrate distinct, nonadditive physical properties of the doubly ligated tetrameric species, yielding an asymmetric distribution of cooperativity within the cascade of O2 binding by human hemoglobin.     

Ruthenium-iron hybrid hemoglobins as a model for partially liganded hemoglobin: oxygen equilibrium curves and resonance Raman spectra

The structure and function of iron(II)-ruthenium(II) hybrid hemoglobins alpha(Ru-CO)2 beta(Fe)2 and alpha(Fe)2 beta(Ru-CO)2, which can serve as models for the intermediate species of the oxygenation step in native human adult hemoglobin, were investigated by measuring oxygen equilibrium curves and the Fe(II)-N epsilon (His F8) stretching resonance Raman lines. The oxygen equilibrium properties indicated that these iron-ruthenium hybrid hemoglobins are good models for the half-liganded hemoglobin. The pH dependence of the oxygen binding properties and the resonance Raman line revealed that the quaternary and tertiary structural transition was induced by pH changes. When the pH was lowered, both the iron-ruthenium hybrid hemoglobins exhibited relatively higher cooperativity and a Raman line typical of normal deoxy structure, suggesting that their structure is stabilized at a "T-like" state. However, the oxygen affinity of alpha(Fe)2 beta(Ru-CO)2 was lower than that of alpha(Ru-CO)2 beta(Fe)2, and the transition to the "deoxy-type" Fe-N epsilon stretching Raman line of alpha(Fe2)beta(Ru-CO)2 was completed at pH 7.4, while that of the complementary counterpart still remained in an "oxy-like" state under the same condition. These observations clearly indicate that the beta-liganded hybrid has more "T"-state character than the alpha-liganded hybrid. In other words, the ligation to the alpha subunit induces more pronounced changes in the structure and function in Hb than the ligation to the beta subunit. This feature agrees with our previous observations by NMR and sulfhydryl reactivity experiments. The present results are discussed in relation to the molecular mechanism of the cooperative stepwise oxygenation in native human adult hemoglobin.     

Characterization of the changes in the state of aggregation induced by ligand binding in the hemoglobin system of a primitive vertebrate, the hagfish Eptatretus cirrhatus

Hemoglobin (Hb) from the hagfish, Eptatretus cirrhatus, is composed of subunits of approx. 20,000 mol. wt. Aggregation of the deoxy subunits occurred, particularly at low pH and at high protein concentration. Oxygen equilibrium studies indicated slight cooperativity and the presence of a small, phosphate-independent Bohr effect. Equilibrium properties were protein concentration dependent indicating an oxygen-linked dissociation in the millimolar concentration range. Kinetic studies indicated a dimer to monomer transition in the micromolar concentration range. The ligand-binding character of hagfish Hb was similar to that of lampreys, but was governed by different kinetic and equilibrium parameters.     

Denaturant dependence of equilibrium unfolding intermediates and denatured state structure of horse ferricytochrome c

Nuclear magnetic resonance spectroscopy is employed to characterize unfolding intermediates and the denatured state of horse ferricytochrome c in guanidine hydrochloride. Unfolded and partially unfolded species with non-native heme ligation are detected by analysis of hyperfine-shifted (1)H resonances. Two equilibrium unfolding intermediates with His-Lys heme axial ligation are detected, as are two unfolded species with bis-His heme ligation. These results are contrasted with previous results on horse ferricytochrome c denaturation by urea, for which only one unfolding intermediate and one unfolded species were detected by NMR spectroscopy. Urea and guanidine hydrochloride are often used interchangeably in protein denaturation studies, but these results and those of others indicate that unfolded and intermediate states in these two denaturants may have substantially different properties. Implications of these results for folding studies and the biological function of mitochondrial cytochromes c are discussed.     

Effect of removal of a salt-bridge on the oxygen binding properties and the electronic structure of heme in cobalt-iron hybrid hemoglobin.

In order to clarify the role of salt-bridges in hemoglobin, the oxygen equilibrium curves and electron paramagnetic resonance (EPR) spectra of cobalt-iron hybrid hemoglobins were determined. The EPR spectra of deoxy alpha(Co)2 beta(Fe)2 could be interpreted as a mixture of two distinct paramagnetic species: one showed a maximum of the first derivative spectrum at g = 2.39 and the other at g = 2.33. The oxygen equilibrium curves of the hybrid indicated that the former is assignable to the T structure and the latter to the R structure. The cooperativity of oxygen binding of alpha(Co)2 beta(Fe)2 exhibited a maximum at g = 2.33, which is characteristic of the R structure, regardless of the pH. Addition of inositol hexaphosphate (IHP) to des-Arg alpha(Co)2 beta(Fe)2 restored the cooperativity of oxygen binding, which implies that the deoxygenated form of des-Arg alpha(Co)2 beta(Fe)2 is converted to the T structure upon addition of IHP. However, the EPR signal at g = 2.39 was not restored upon conversion to the T structure by addition of IHP. It is therefore concluded that the EPR spectrum of the deoxy alpha(Co) subunit depends both on the quaternary structure and on the localized strain at the heme.     

Understanding mechanisms in a cooperative protein: the CO ligation intermediates of hemoglobin.

Hemoglobin is a regulatory component of the oxygen transport to the tissues, and for decades has been a prototype to develop new strategies for the study of the structure/function relationships in proteins. One of the most difficult, and so far, unattained objectives of hemoglobin research has been the study of the hemoglobin molecules in a state of partial ligation with oxygen, or intermediates, as a means of testing theories of cooperativity. A cryogenic technique has been developed for the isolation, identification and quantification of the reaction intermediates of hemoglobin and CO, which in many aspects is a close approximation to the physiological ligand. The technical features that are crucial for the evaluation of the significance of the experimental data obtained using this technique and various approaches to the analysis of the data are reported. The discussion points out the importance of accessing direct information on the nature and concentrations of the intermediates in solution to clarify mechanisms of cooperativity as opposed to the less informative studies of the bulk properties of the solution.     

Hemoglobin Saint Mandé [beta 102 (G4) Asn----Tyr]. Functional studies and structural modeling reveal an altered T state

Oxygen equilibrium studies of purified hemoglobin Saint Mandé (Hb SM) [beta 102 (G4) Asn----Tyr] reveal a decreased oxygen affinity and cooperativity but to a lesser extent than found for Hb Kansas (beta 102 Thr). The low affinity of Hb SM depends on environmental conditions: eliminating chloride or raising the pH greatly elevated the ratio of p50 of Hb SM to that of Hb A. The alkaline Bohr effect is reduced by about 40%. The effects of anions (chloride, organophosphates) binding to deoxy Hb SM are also reduced. These data indicate that the functional properties of Hb SM are intermediary between Hb A and Hb Kansas. In addition, molecular graphics modeling of Hb SM in the oxy and deoxy structures indicate the possibility of a new hydrogen bond in the T state between beta(1)102 Tyr and alpha(2)42 Tyr. Stabilisation of the T state in this manner is a plausible explanation for several of the effects observed.     

Evidence for identity between the equilibrium unfolding intermediate and a transient folding intermediate: a comparative study of the folding reactions of alpha-lactalbumin and lysozyme

The refolding kinetics of alpha-lactalbumin at different concentrations of guanidine hydrochloride have been investigated by means of kinetic circular dichroism and stopped-flow absorption measurements. The refolding reaction consists of at least two stages, the instantaneous accumulation of the transient intermediate that has peptide secondary structure and the subsequent slow process associated with formation of tertiary structure. The transient intermediate is compared with the well-characterized equilibrium intermediate observed during the denaturant-induced unfolding. Stabilities of the secondary structures against the denaturant, affinities for Ca2+, and tryptophan absorption properties of the transient and equilibrium intermediates were investigated. In all of these respects, the transient intermediate is identical with the equilibrium one, demonstrating the validity of the use of the equilibrium intermediate as a model of the folding intermediate. Essentially the same transient intermediate was also detected in the folding of lysozyme, the protein known to be homologous to alpha-lactalbumin but whose equilibrium unfolding is represented as a two-state reaction. The stability and cooperativity of the secondary structure of the intermediate of lysozyme are compared with those of alpha-lactalbumin. The results show that the protein folding occurring via the intermediate is not limited to the proteins that show equilibrium intermediates. Although the unfolding equilibria of most proteins are well approximated as a two-state reaction, the two-state hypothesis may not be applicable to the folding reaction under the native condition. Two models of protein folding, intermediate-controlled folding model and multiple-pathway folding model, which are different in view of the role of the intermediate in determining the pathway of folding, are also discussed.     

Quaternary-transformation-induced changes at the heme in deoxyhemoglobins

Quaternary-structure-induced differences in both the high- and low-frequency regions of the resonance Raman spectrum of the heme have been detected in a variety of hemoglobins. These differences may be the result of (1) changes in the amino acid sequence, induced by genetic and chemical modifications, and (2) alterations in the quaternary structure. For samples in solution in low ionic strength buffers, differences in the 1357-cm-1 line (an electron-density-sensitive vibrational mode) correlate with differences in the 216-cm-1 line (the iron-histidine stretching mode). Thus, changes in the iron-histidine bond and changes in the pi-electron density of the porphyrin depend upon a common heme-globin interaction. The quaternary-structure-induced changes in the vibrational modes associated with the heme demonstrate that there is extensive communication between the heme and the globin and impact on models for the energetics of cooperativity. The local interactions of the iron-histidine mode are energetically small and destabilize the deoxy heme in the T structure with respect to the R structure. Therefore, these interactions must be larger in the ligated protein than in the deoxy protein to obtain a negative free energy of cooperativity. Additionally, our data imply that the deprotonation of the proximal histidine does not play a major role in the energetics of cooperativity. On the other hand, models for cooperativity that require conformational changes in the iron-histidine bond or direct interaction between the porphyrin and the protein are qualitatively consistent with the observed variation of heme electronic structure in concert with protein quaternary structure.     

Cobalt-substituted hemoglobin Zürich (alpha 2 beta 263His leads Arg). Oxygen equilibria and EPR spectra.

Cobalt hemoglobin Zürich (alpha 2 beta 263His leads to Arg) has been successfully reconstituted from the apohemoglobin Zürich and cobaltous protoporphyrin IX. The oxygen affinity of cobalt hemoglobin Zurich, as well as that of iron hemoglobin Zürich, were measured in the absence and presence of organic phosphate and Cl-. The overall oxygen affinity of cobalt hemoglobin Zürich was found to be higher and the cooperativity as measured by the n value was smaller than those of cobalt hemoglobin A. Organic phosphate and Cl- affect the oxygen equilibrium properties of cobalt hemoglobin Zürich in a manner similar to that of cobalt hemoglobin A, but to a lesser extant than cobalt hemoglobin A. The EPR spectrum of oxy cobalt hemoglobin Zürich is less sensitive to the replacement of the buffer system from H2O to 2H2O, indicating that the hydrogen bond between the distal amino acid residue and the bound oxygen is not formed in the abnormal beta subunits. The deoxy EPR spectrum of cobalt hemoglobin Zürich is similar to that of deoxy cobalt hemoglobin A, suggesting that the deoxy cobalt hemoglobin Zürich is predominantly in the deoxy quaternary structure (T state).     

Recombinant hemoglobins with low oxygen affinity and high cooperativity

By introducing an additional H-bond in the alpha(1)beta(2) subunit interface or altering the charge properties of the amino acid residues in the alpha(1)beta(1) subunit interface of the hemoglobin molecule, we have designed and expressed recombinant hemoglobins (rHbs) with low oxygen affinity and high cooperativity. Oxygen-binding measurements of these rHbs under various experimental conditions show interesting properties in response to pH (Bohr effect) and allosteric effectors. Proton nuclear magnetic resonance studies show that these rHbs can switch from the oxy (or CO) quaternary structure (R) to the deoxy quaternary structure (T) without changing their ligation states upon addition of an allosteric effector, inositol hexaphosphate, and/or reduction of the ambient temperature. These results indicate that if we can provide extra stability to the T state of the hemoglobin molecule without perturbing its R state, we can produce hemoglobins with low oxygen affinity and high cooperativity. Some of these rHbs are also quite stable against autoxidation compared to many of the known abnormal hemoglobins with altered oxygen affinity and cooperativity. These results have provided new insights into the structure-function relationship in hemoglobin.     

Spin equilibrium and quaternary structure change in hemoglobin A. Experiments on a quantitative probe of the stereochemical mechanism of hemoglobin cooperativity

The molecular mechanism of hemoglobin cooperativity was studied kinetically by flash photolysis on mixed-state hemoglobins which consist of three ferrous carboxy subunits and one hybrid ferric subunit including fluoromet, azidomet, cyanatomet, and thiocyanatomet. The effects of conformational transitions on the hybrid subunit were detected by kinetic absorption spectroscopy after the CO was fully photodissociated from the binding sites by a large pulse of light from a tunable dye laser. The hemoglobin conformational transition rate was observed to depend on its state of ligation. At 22 degrees C, pH 7, and 0.1 M phosphate, the deoxy R yields T conformational change rate is 4 x 10(4)s-1. The rate decreases to 1.4 x 10(4)s-1 for singly ligated hemoglobin. The R yields T conformation change alters the energy separation between high- and low-spin states for azidomet, cyanatomet, and thiocyanatomet subunits by about 700, 300, and 300 cal/mol, respectively. There are two possible implications of this result: (1) the iron atom spin state is not the only major factor in the determination of its position with respect to the heme plane or (2) the change with conformation of the protein force exerted by the proximal histidine on the iron atom (for an iron to heme-plane displacement of less than 0.3 A) is less than 50% of that expected from simple models in which this motion is responsible for cooperativity.     

Mutagenic dissection of hemoglobin cooperativity: effects of amino acid alteration on subunit assembly of oxy and deoxy tetramers.

Free energies of oxygen-linked subunit assembly and cooperative interaction have been determined for 34 molecular species of human hemoglobin, which differ by amino acid alterations as a result of mutation or chemical modification at specific sites. These studies required the development of extensions to our earlier methodology. In combination with previous results they comprise a data base of 60 hemoglobin species, characterized under the same conditions. The data base was analyzed in terms of the five following issues. (1) Range and sensitivity to site modifications. Deoxy tetramers showed greater average energetic response to structural modifications than the oxy species, but the ranges are similar for the two ligation forms. (2) Structural localization of cooperative free energy. Difference free energies of dimer-tetramer assembly (oxy minus deoxy) yielded delta Gc for each hemoglobin, i.e., the free energy used for modulation of oxygen affinity over all four binding steps. A structure-energy map constructed from these results shows that the alpha 1 beta 2 interface is a unique structural location of the noncovalent bonding interactions that are energetically coupled to cooperativity. (3) Relationship of cooperativity to intrinsic binding. Oxygen binding energetics for dissociated dimers of mutants strongly indicates that cooperativity and intrinsic binding are completely decoupled by tetramer to dimer dissociation. (4) Additivity, site-site coupling and adventitious perturbations. All these are exhibited by individual-site modifications of this study. Large nonadditivity may be correlated with global (quaternary) structure change. (5) Residue position vs. chemical nature. Functional response is solely dictated by structural location for a subset of the sites, but varies with side-chain type at other sites. The current data base provides a unique framework for further analyses and modeling of fundamental issues in the structural chemistry of proteins and allosteric mechanisms.     

Proton nuclear magnetic resonance studies of hemoglobin Malm?: implications of mutations at homologous positions of the alpha and beta chains.

The abnormal human hemoglobin Malm? (beta97FG4 His leads to Gln) has been studied and its properties are compared with those of normal adult hemoglobin A. The data presented here show that the ring-current shifted proton resonances of both HbCO and HbO2 Malm? are very different from the corresponding forms of Hb A. The hyperfine shifted proton resonances of deoxy-Hb Malm? do not differ drastically from those of deoxy-Hb A. This result, together with the finding that the exchangeable proton resonances of the deoxy form of the two hemoglobins are similar, suggests that unliganded Hb Malm? can assume a deoxy-like quaternary structure both in the absence and presence of organic phosphates We have also compared the properties of Hb Malm? with those of Hb Chesapeake (alpha92FG4 Arg leads to Leu). This allows us to study the properties of two abnormal human hemoglobins with mutations at homologous positions of the alpha and beta chains in the three-dimenstional structure of the hemoglobin molecule. Our present results suggest that the mutaion at betaFG4 has its greatest effect on the teritiary structure of the heme pocket of the liganded forms of the hemoglobin while the mutation at alphaFG4 alters the deoxy structure of the hemoglogin molecule but does not alter the teriary structure of the heme pockets of the liganded form of the hemoglobin molecule. Both hemoglobins undergo a transition from the deoxy (T) to the oxy (R) quaternary structure upon ligation. The abnormally high oxygen affinities and low cooperativities of these two hemoglobins must therefore be due to either the structural differences which we have observed and/or to an altered transition between the T and R structures.     

Proton nuclear magnetic resonance and biochemical studies of oxygenation of human adult hemoglobin in deuterium oxide.

The proton nuclear magnetic resonance spectrum of human adult deoxyhemoglobin in D2O in the region from 6 to 20 ppm downfield from the proton resonance of residual water shows a number of hyperfine shifted proton resonances that are due to groups on or near the alpha and beta hemes. The sensitivity of these resonances to the ligation of the heme groups and the assignment of these resonances to the alpha and beta chains provide an opportunity to investigate the cooperative oxygenation of an intact hemoglobin molecule in solution. By use of the nuclear magnetic resonance correlation spectroscopy technique, at least two resonances, one at approximately 18 ppm downfield from HDO due to the beta chain and the other at approximately 12 ppm due to the alpha chain, can be used to study the binding of oxygen to the alpha and beta chains of hemoglobin. The present results using approximately 12% hemoglobin concentration in 0.1 M Bistris buffer at pD 7 and 27 degrees C with and without organic phosphate show that there is no significant line broadening on oxygenation (from 0 to 50% saturation) to affect the determination of the intensities or areas of these resonances. It is found that the ratio of the intensity of the alpha-heme resonance at 12 ppm to that of the beta-heme resonance at 18 ppm is constant on oxygenation in the absence of organic phosphate but decreases in the presence of 2,3-diphosphoglycerate or inositol hexaphosphate, with the effect of the latter being the stronger. On oxygenation, the intensities of the alpha-heme resonance at 12 ppm and of the beta-heme resonance at 18 ppm decreases more than the total number of deoxy chains available as measured by the degree of O2 saturation of hemoglobin. This shows the sensitivity of these resonances to structural changes which are believed to occur in the unligated subunits upon the ligation of their neighbors in an intact tetrameric hemoglobin molecule. A comparison of the nuclear magnetic resonance data with the populations of the partially saturated hemoglobin tetramers (i.e., hemoglobin with one, two, or three oxygen molecules bound) leads to the conclusion that in the presence of organic phosphate the hemoglobin molecule with one oxygen bound maintains the beta-heme resonance at 18 ppm but not the alpha-heme resonance at 12 ppm. These resluts suggest that some cooperativity must exist in the deoxy quaternary structure of the hemoglobin molecule during the oxygenation process. Hence, these results are not consistent with the requirements of two-state concerted models for the oxygenation of hemoglobin. In addition, we have investigated the effect of D2O on the oxygenation of hemoglobin by measuring the oxygen dissociation curves of normal adult hemoglobin as a function of pH in D2O andH2O media. We have found that (1) the pH dependence of the oxygen equilibrium of hemoglobin (the Bohr effect) in higher pH in comparison to that in H2O medium and (2) the Hill coefficients are essentially the same in D2O and H2O media over the pH range from 6.0 to 8.2...     

Influence of oxidation and crosslinking on oxygen binding properties of mouse erythrocytes

Different chemical treatments for mouse erythrocyte modification has been used. Oxidation treatments with Ascorbate/Fe(3+), a system able to react with intracellular proteins, produced a displacement of the O(2) binding equilibrium curve to a higher affinity behaviour with loss of the haemoglobin cooperativity for oxygen binding. Incubation of mouse erythrocytes with diamide showed that at low reagent concentration (0.8 mM) no modification on oxygen binding equilibrium curves was observed. At higher reagent concentration (2.0 mM), an increased affinity and a disappearance of the cooperative behaviour can be observed. Additionally, crosslinking reactions on mouse erythrocytes with band 3 crosslinkers seemed to affect oxygen binding properties when used at a crosslinker concentration of 5 mM. Oxyhaemoglobin levels in crosslinked and diamide-treated erythrocytes are similar to those found in control cells. In contrast, ascorbate/Fe(3+) treatments produced an increment in the proportion of methaemoglobin, decreasing the oxyhaemoglobin levels in these oxidized erythrocytes.     

Component D of chicken hemoglobin and the hemoglobin of the embryonic Tammar wallaby (Macropus eugenii) self-associate upon deoxygenation: Effect on oxygen binding

Extensive measurements of oxygen binding by some vertebrate hemoglobins (Hbs) have suggested an unusually high degree of cooperativity with reported Hill coefficients, n(H), greater than 4.0. We have reexamined this possibility of "super-cooperativity" with chicken Hb components A (alpha(A) (2)beta(2)) and D (alpha(D) (2)beta(2)). Prior studies have shown that component D but not A self-associates to dimers of tetramers upon deoxygenation. This self-association is reflected in the oxygen equilibrium of Hb D which shows a maximal n(H), greater than 4.0 at approximately 4 mM heme concentration. In contrast, component A has maximal n(H) value below 3. The value of the maximal n(H) for Hb D increases linearly with the fraction of octamer present in the deoxy Hb. We anticipate that deoxygenation-dependent self-association will be shown to be a general property of Hb D from birds and reptiles. Neither oxygen equilibria nor sedimentation measurements show any evidence that components A and D interact to form a complex when deoxygenated. We have also reexamined the oxygen equilibria of Hbs of an embryonic marsupial, the wallaby. The equilibria in red cells have been reported to have Hill coefficients as high as 5-6. Although our oxygen equilibrium measurements of solutions of unfractionated wallaby Hb at a concentration of approximately 1 mM show no n(H) values greater than approximately 3.0, sedimentation velocity measurements provide clear evidence for deoxygenation-dependent self-association.     

Tyrosine hydroxylase binds tetrahydrobiopterin cofactor with negative cooperativity, as shown by kinetic analyses and surface plasmon resonance detection.

Kinetic studies of tetrameric recombinant human tyrosine hydroxylase isoform 1 (hTH1) have revealed properties so far not reported for this enzyme. Firstly, with the natural cofactor (6R)-Lerythro-5,6,7, 8-tetrahydrobiopterin (H4biopterin) a time-dependent change (burst) in enzyme activity was observed, with a half-time of about 20 s for the kinetic transient. Secondly, nonhyperbolic saturation behaviour was found for H4biopterin with a pronounced negative cooperativity (0.39 < h < 0.58; [S]0.5 = 24 +/- 4 microM). On phosphorylation of Ser40 by protein kinase A, the affinity for H4biopterin increased ([S]0.5 = 11 +/- 2 microM) and the negative cooperativity was amplified (h = 0.27 +/- 0.03). The dimeric C-terminal deletion mutant (Delta473-528) of hTH1 also showed negative cooperativity of H4biopterin binding (h = 0.4). Cooperativity was not observed with the cofactor analogues 6-methyl-5,6,7,8-tetrahydropterin (h = 0.9 +/- 0.1; Km = 62.7 +/- 5.7 microM) and 3-methyl-5,6,7, 8-tetrahydropterin (H43-methyl-pterin)(h = 1.0 +/- 0.1; Km = 687 +/- 50 microM). In the presence of 1 mM H43-methyl-pterin, used as a competitive cofactor analogue to BH4, hyperbolic saturation curves were also found for H4biopterin (h = 1.0), thus confirming the genuine nature of the kinetic negative cooperativity. This cooperativity was confirmed by real-time biospecific interaction analysis by surface plasmon resonance detection. The equilibrium binding of H4biopterin to the immobilized iron-free apoenzyme results in a saturable positive resonance unit (DeltaRU) response with negative cooperativity (h = 0.52-0.56). Infrared spectroscopic studies revealed a reduced thermal stability both of the apo-and the holo-hTH1 on binding of H4biopterin and Lerythro-dihydrobiopterin (H2biopterin). Moreover, the ligand-bound forms of the enzyme also showed a decreased resistance to limited tryptic proteolysis. These findings indicate that the binding of H4biopterin at the active site induces a destabilizing conformational change in the enzyme which could be related to the observed negative cooperativity. Thus, our studies provide new insight into the regulation of TH by the concentration of H4biopterin which may have significant implications for the physiological regulation of catecholamine biosynthesis in neuroendocrine cells.