Angelo Merli

Reactivity of ferric Aplysia and sperm whale myoglobins towards imidazole. X-ray and binding study.

Abstract Spectral and equilibrium binding properties for the reactions of sperm whale and Aplysia metmyoglobins with imidazole have been studied in solution and in single crystals, as a function of pH. Both in solution and in the crystal the high-spin forms of these two proteins show clear spectral differences, which have been correlated to the absence of the iron-bound water molecule in Aplysia metmyoglobin. On the other hand, both the hydroxyl and imidazole adducts give identical spectra for the two myoglobins. Under all the conditions explored, the binding constants for the reaction of ferric sperm whale and Aplysia myoglobins with imidazole are very similar when measured in solution and in single crystals, thus indicating that the crystalline lattice does not exert large strains on the structure of the active site. Three-dimensional difference Fourier studies of the imidazole adducts of the two proteins show that this ligand binds to the iron distal sites in a similar manner, despite the absence of the distal histidine in Aplysia myoglobin. In the case of sperm whale myoglobin, the distal histidine side-chain is displaced by the exogenous imidazole, and this fact is associated with structural changes in the sidechains mainly in the neighborhood of the heme. In both proteins the exogenous imidazole ring is approximately perpendicular to the heme plane and points towards the external part of the heme crevice along the Fe-(metinic)CHA direction.

A Spring-loaded Release Mechanism Regulates Domain Movement and Catalysis in Phosphoglycerate Kinase

Phosphoglycerate kinase (PGK) is the enzyme responsible for the first ATP-generating step of glycolysis and has been implicated extensively in oncogenesis and its development. Solution small angle x-ray scattering (SAXS) data, in combination with crystal structures of the enzyme in complex with substrate and product analogues, reveal a new conformation for the resting state of the enzyme and demonstrate the role of substrate binding in the preparation of the enzyme for domain closure. Comparison of the x-ray scattering curves of the enzyme in different states with crystal structures has allowed the complete reaction cycle to be resolved both structurally and temporally. The enzyme appears to spend most of its time in a fully open conformation with short periods of closure and catalysis, thereby allowing the rapid diffusion of substrates and products in and out of the binding sites. Analysis of the open apoenzyme structure, defined through deformable elastic network refinement against the SAXS data, suggests that interactions in a mostly buried hydrophobic region may favor the open conformation. This patch is exposed on domain closure, making the open conformation more thermodynamically stable. Ionic interactions act to maintain the closed conformation to allow catalysis. The short time PGK spends in the closed conformation and its strong tendency to rest in an open conformation imply a spring-loaded release mechanism to regulate domain movement, catalysis, and efficient product release.

Efficient electron transfer in a protein network lacking specific interactions.

In many biochemical processes, proteins need to bind partners amidst a sea of other molecules. Generally, partner selection is achieved by formation of a single-orientation complex with well-defined, short-range interactions. We describe a protein network that functions effectively in a metabolic electron transfer process but lacks such specific interactions. The soil bacterium Paracoccus denitrificans oxidizes a variety of compounds by channeling electrons into the main respiratory pathway. Upon conversion of methylamine by methylamine dehydrogenase, electrons are transported to the terminal oxidase to reduce molecular oxygen. Steady-state kinetic measurements and NMR experiments demonstrate a remarkable number of possibilities for the electron transfer, involving the cupredoxin amicyanin as well as four c-type cytochromes. The observed interactions appear to be governed exclusively by the electrostatic nature of each of the proteins. It is concluded that Paracoccus provides a pool of cytochromes for efficient electron transfer via weak, ill-defined interactions, in contrast with the view that functional biochemical interactions require well-defined molecular interactions. It is proposed that the lack of requirement for specificity in these interactions might facilitate the integration of new metabolic pathways.

Amicyanin transfers electrons from methylamine dehydrogenase to cytochrome c-551i via a ping-pong mechanism, not a ternary complex.

The first crystal structure of a ternary redox protein complex was comprised of the enzyme methylamine dehydrogenase (MADH) and two electron transfer proteins, amicyanin and cytochrome c-551i from Paracoccus denitrificans [Chen et al. Science 1994, 264, 86-90]. The arrangement of the proteins suggested possible electron transfer from the active site of MADH via the amicyanin copper ion to the cytochrome heme iron, although the distance between the metals is large. We studied the interactions between these proteins in solution. A titration followed by NMR spectroscopy shows that amicyanin binds cytochrome c-551i. The interface comprises the hydrophobic and positive patches of amicyanin, not the binding site observed in the ternary complex. NMR experiments further show that amicyanin binds tightly to MADH with an interface that matches the one observed in the crystal structure and that mostly overlaps with the binding site for cytochrome c-551i. Upon addition of cytochrome c-551i, no changes in the NMR spectrum of MADH-bound amicyanin are observed, suggesting that a possible interaction of the cytochrome with the binary complex must be very weak, with a dissociation constant higher than 2 mM. Reconstitution of the entire redox chain in vitro demonstrates that amicyanin can react rapidly with cytochrome c-551i, but that association of amicyanin with MADH inhibits this reaction. It is concluded that electron transfer from MADH to cytochrome c-551i does not involve a ternary complex but occurs via a ping-pong mechanism in which amicyanin uses the same interface for the reactions with MADH and cytochrome c-551i.

Structural and energetic basis of isopropylmalate dehydrogenase enzyme catalysis

The three‐dimensional structure of the enzyme 3‐isopropylmalate dehydrogenase from the bacterium Thermus thermophilus in complex with Mn2+, its substrate isopropylmalate and its co‐factor product NADH at 2.0 Å resolution features a fully closed conformation of the enzyme. Upon closure of the two domains, the substrate and the co‐factor are brought into precise relative orientation and close proximity, with a distance between the C2 atom of the substrate and the C4N atom of the pyridine ring of the co‐factor of approximately 3.0 Å. The structure further shows binding of a K+ ion close to the active site, and provides an explanation for its known activating effect. Hence, this structure is an excellent mimic for the enzymatically competent complex. Using high‐level QM/MM calculations, it may be demonstrated that, in the observed arrangement of the reactants, transfer of a hydride from the C2 atom of 3‐isopropylmalate to the C4N atom of the pyridine ring of NAD+ is easily possible, with an activation energy of approximately 15 kcal·mol−1. The activation energy increases by approximately 4–6 kcal·mol−1 when the K+ ion is omitted from the calculations. In the most plausible scenario, prior to hydride transfer the ε‐amino group of Lys185 acts as a general base in the reaction, aiding the deprotonation reaction of 3‐isopropylmalate prior to hydride transfer by employing a low‐barrier proton shuttle mechanism involving a water molecule.

Atomic level description of the domain closure in a dimeric enzyme: Thermus thermophilus 3-isopropylmalate dehydrogenase

The domain closure associated with the catalytic cycle is described at an atomic level, based on pairwise comparison of the X-ray structures of homodimeric Thermus thermophilus isopropylmalate dehydrogenase (IPMDH), and on their detailed molecular graphical analysis. The structures of the apo-form without substrate and in complex with the divalent metal-ion to 1.8 Å resolution, in complexes with both Mn(2+) and 3-isopropylmalate (IPM), as well as with both Mn(2+) and NADH, were determined at resolutions ranging from 2.0 to 2.5 Å. Single crystal microspectrophotometric measurements demonstrated the presence of a functionally competent protein conformation in the crystal grown in the presence of Mn(2+) and IPM. Structural comparison of the various complexes clearly revealed the relative movement of the two domains within each subunit and allowed the identification of two hinges at the interdomain region: hinge 1 between αd and βF as well as hinge 2 between αh and βE. A detailed analysis of the atomic contacts of the conserved amino acid side-chains suggests a possible operational mechanism of these molecular hinges upon the action of the substrates. The interactions of the protein with Mn(2+) and IPM are mainly responsible for the domain closure: upon binding into the cleft of the interdomain region, the substrate IPM induces a relative movement of the secondary structural elements βE, βF, βG, αd and αh. A further special feature of the conformational change is the movement of the loop bearing the amino acid Tyr139 that precedes the interacting arm of the subunit. The tyrosyl ring rotates and moves by at least 5 Å upon IPM-binding. Thereby, new hydrophobic interactions are formed above the buried isopropyl-group of IPM. Domain closure is then completed only through subunit interactions: a loop of one subunit that is inserted into the interdomain cavity of the other subunit extends the area with the hydrophobic interactions, providing an example of the cooperativity between interdomain and intersubunit interactions.

Electron transfer in crystals of the binary and ternary complexes of methylamine dehydrogenase with amicyanin and cytochrome c551i as detected by EPR spectroscopy

EPR studies of the methylamine dehydrogenase (MADH)–amicyanin and MADH–amicyanin–cytochrome c551i crystalline complexes have been performed on randomly oriented microcrystals before and after exposure to the substrate, methylamine, as a function of pH. The results show that EPR signals from the redox centers present in the various proteins can be observed simultaneously. These results complement and extend earlier studies of the complexes under similar conditions that utilized single-crystal polarized absorption microspectrophotometry. The binary complex shows a blue copper axial signal, characteristic of oxidized amicyanin. After reaction of substrate with the MADH coenzyme tryptophan tryptophylquinone (TTQ), the binary complex exhibits an equilibrium mixture of oxidized copper/reduced TTQ and reduced copper/TTQ· radical, whose ratio is dependent on the pH. In the oxidized ternary complex, the same copper axial signal is observed superimposed on the low-spin ferric heme features characteristic of oxidized cytochrome c551i. After addition of substrate to the ternary complex, a decrease of the copper signal is observed, concomitant with the appearance of the radical signal derived from the semiquinone form of TTQ. The equilibrium distribution of electrons between TTQ and copper as a function of pH is similar to that observed for the binary complex. This result was essential to establish that the copper center retains its function within the crystalline ternary complex. At high pH, with time the low-spin heme EPR features disappear and the spectrum indicates that full reduction of the complex by substrate has occurred.

Catalysis and electron transfer in protein crystals: the binary and ternary complexes of methylamine dehydrogenase with electron acceptors

Polarized absorption microspectrophotometry has been used to detect catalysis and intermolecular electron transfer in single crystals of two multiprotein complexes: (1) the binary complex between Paracoccus denitrificans methylamine dehydrogenase, which contains tryptophan-tryptophylquinone (TTQ) as a cofactor, and its redox partner, the blue copper protein amicyanin; (2) the ternary complex between the same two proteins and cytochrome c-551i. Continuous wave electron paramagnetic resonance has been used to compare the state of copper in polycrystalline powders of the two systems. While catalysis and intermolecular electron transfer from reduced TTQ to copper are too fast to be accessible to our measurements, heme reduction occurs over a period of several minutes. The observed rate constant is about four orders of magnitude lower than in solution. The analysis of the temperature dependence of this apparent constant provides values for the parameters H(AB), related to electronic coupling between the two centers, and lambda, the reorganizational energy, that are compatible with electron transfer being the rate-determining step. From these parameters and the known distance between copper and heme, it is possible to calculate the parameter beta, which depends on the nature of the intervening medium, obtaining a value typical of electron transfer across a protein matrix. These findings suggest that the ternary complex in solution might achieve a higher efficiency than the rigid crystal structure thanks to an as yet unidentified role of protein dynamics.

Structural comparison of crystal and solution states of the 138 kDa complex of methylamine dehydrogenase and amicyanin from Paracoccus versutus.

Methylamine can be used as the sole carbon source of certain methylotrophic bacteria. Methylamine dehydrogenase catalyzes the conversion of methylamine into formaldehyde and donates electrons to the electron transfer protein amicyanin. The crystal structure of the complex of methylamine dehydrogenase and amicyanin from Paracoccus versutus has been determined, and the rate of electron transfer from the tryptophan tryptophylquinone cofactor of methylamine dehydrogenase to the copper ion of amicyanin in solution has been determined. In the presence of monovalent ions, the rate of electron transfer from the methylamine-reduced TTQ is much higher than in their absence. In general, the kinetics are similar to those observed for the system from Paracoccus denitrificans. The complex in solution has been studied using nuclear magnetic resonance. Signals of perdeuterated, (15)N-enriched amicyanin bound to methylamine dehydrogenase are observed. Chemical shift perturbation analysis indicates that the dissociation rate constant is approximately 250 s(-1) and that amicyanin assumes a well-defined position in the complex in solution. The most affected residues are in the interface observed in the crystal structure, whereas smaller chemical shift changes extend to deep inside the protein. These perturbations can be correlated to small differences in the hydrogen bond network observed in the crystal structures of free and bound amicyanin. This study indicates that chemical shift changes can be used as reliable indicators of subtle structural changes even in a complex larger than 100 kDa.

Single crystal absorption spectra of ascorbate oxidase from green zucchini squash

Single crystal polarized absorption spectra of the dimeric multicopper enzyme ascorbate oxidase from green zucchini squash indicate that its most relevant functional and structural properties are maintained in the crystalline state. Since the polarized absorption spectra of crystalline ascorbate oxidase are very similar, in the visible region, to those of crystalline plastocyanin, we expect that structural data will show similar orientation of the type 1 Cu2+ center with respect to the crystal axes. The selective removal of type 2 Cu2+ from the crystal has been realized and has a potential value for the identification of the copper centers in the crystallographic analysis of the enzyme. Evidence is presented for an azide binding site formed by type 2 and type 3 Cu3+, similar to the trinuclear copper center suggested to be present in laccase.