Crystal structure of an electron-transfer complex between methylamine dehydrogenase and amicyanin.

The crystal structure of the complex between the quinoprotein methylamine dehydrogenase (MADH) and the type I blue copper protein amicyanin, both from Paracoccus denitrificans, has been determined at 2.5-A resolution using molecular replacement. The search model was MADH from Thiobacillus versutus. The amicyanin could be located in an averaged electron density difference map and the model improved by refinement and model building procedures. Nine beta-strands are observed within the amicyanin molecule. The copper atom is located between three antiparallel strands and is about 2.5 A below the protein surface. The major intermolecular interactions occur between amicyanin and the light subunit of MADH where the interface is largely hydrophobic. The copper atom of amicyanin and the redox cofactor of MADH are about 9.4 A apart. One of the copper ligands, His 95, lies between the two redox centers and may facilitate electron transfer between them.     

Complex formation between methylamine dehydrogenase and amicyanin from Paracoccus denitrificans

Two proteins isolated from Paracoccus denitrificans, the copper-containing electron carrier amicyanin and the pyrroloquinoline quinone-containing enzyme methylamine dehydrogenase, have been shown to form a complex. Complex formation between methylamine dehydrogenase and either oxidized or reduced amicyanin resulted in alterations in the absorbance spectrum of the pyrroloquinoline quinone prosthetic group of methylamine dehydrogenase. Binding of amicyanin to the enzyme exhibited positive cooperativity. Complex formation with methylamine dehydrogenase shifted the oxidation-reduction midpoint potential of amicyanin by 73 mV, from +294 to +221 mV, making electron transfer from amicyanin to cytochrome c551 (Em = +190 mV) thermodynamically possible.     

Chemical cross-linking study of complex formation between methylamine dehydrogenase and amicyanin from Paracoccus denitrificans

Two soluble periplasmic redox proteins from Paracoccus denitrificans, the quinoprotein methylamine dehydrogenase and the copper protein amicyanin, form a weakly associated complex that is critical to their physiological function in electron transport [Gray, K. A., Davidson, V. L., & Knaff, D. B. (1988) J. Biol. Chem. 263, 13987-13990]. The specific interactions between methylamine dehydrogenase and amicyanin have been studied by using the water-soluble cross-linking agent 1-ethyl-3-[3-(dimethylamino)propyl]carbodiimide (EDC). Treatment of methylamine dehydrogenase alone with EDC caused no intermolecular cross-linking but did cause intramolecular cross-linking of this alpha 2 beta 2 oligomeric enzyme. The primary product that was formed contained one large and one small subunit. Methylamine dehydrogenase and amicyanin were covalently cross-linked in the presence of EDC to form at least two distinct species, which were identified by nondenaturing polyacrylamide gel electrophoresis (PAGE). The formation of these cross-linked species was dependent on ionic strength, and the ionic strength dependence was much greater at pH 6.5 than at pH 7.5. The effects of pH and ionic strength were different for the different cross-linked products. SDS-PAGE and Western blot analysis of these cross-linked species indicated that the primary site of interaction for amicyanin was the large subunit of methylamine dehydrogenase and that this association could be stabilized by hydrophobic interactions. In light of these results a scheme is proposed for the interaction of amicyanin with methylamine dehydrogenase that is consistent with previous data on the physical, kinetic, and redox properties of this complex.     

A single methionine residue dictates the kinetic mechanism of interprotein electron transfer from methylamine dehydrogenase to amicyanin

Amicyanin is a type 1 copper protein that is the natural electron acceptor for the quinoprotein methylamine dehydrogenase (MADH). A P52G amicyanin mutation increased the Kd for complex formation and caused the normally true electron transfer (ET) reaction from O-quinol MADH to amicyanin to become a gated ET reaction (Ma, J. K., Carrell, C. J., Mathews, F. S., and Davidson, V. L. (2006) Biochemistry 45, 8284-8293). One consequence of the P52G mutation was to reposition the side chain of Met51, which is present at the MADH-amicyanin interface. To examine the precise role of Met51 in this interprotein ET reaction, Met51 was converted to Ala, Lys, and Leu. The Kd for complex formation of M51A amicyanin was unchanged but the experimentally determined electronic coupling increased from 12 cm-1 to 142 cm-1, and the reorganization energy increased from 2.3 to 3.1 eV. The rate and salt dependence of the proton transfer-gated ET reaction from N-quinol MADH to amicyanin is also changed by the M51A mutation. These changes in ET parameters and rates for the reactions with M51A amicyanin were similar to those caused by the P52G mutation and indicated that the ET reaction had become gated by a similar process, most likely a conformational rearrangement of the protein ET complex. The results of the M51K and M51L mutations also have consequences on the kinetic mechanism of regulation of the interprotein ET with effects that are intermediate between what is observed for the reaction of the native amicyanin and M51A amicyanin. These data indicate that the loss of the interactions involving Pro52 were primarily responsible for the change in Kd for P52G amicyanin, while the interactions involving the Met51 side chain are entirely responsible for the change in ET parameters and conversion of the true ET reaction of native amicyanin into a conformationally gated ET reaction.     

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.     

Conversion of methylamine dehydrogenase to a long-chain amine dehydrogenase by mutagenesis of a single residue

Methylamine dehydrogenase (MADH) is a tryptophan tryptophylquinone (TTQ) dependent enzyme that catalyzes the oxidative deamination of primary amines. Amino acid residues of both the TTQ-bearing beta subunit and the noncatalytic alpha subunit line a substrate channel that leads from the protein surface to the enzyme active site. Phe55 of the alpha subunit is located at the opening of the active site. Conversion of alphaPhe55 to alanine dramatically alters the substrate preference of MADH. The K(m) for methylamine increases from 9 microM to 15 mM. The preferred substrates are now primary amines with chain lengths of at least seven carbons. The K(m) for 1, 10-diaminodecane is 11 microM, compared to 1.2 mM for wild-type MADH. Despite the large variation in K(m) values, k(cat) values are relatively unaffected by the mutation. Molecular modeling of substrates into the crystal structure of the enzyme active site and substrate channel provides an explanation for the dramatic changes in substrate specificity caused by this mutation of a single amino acid residue.     

Probing mechanisms of catalysis and electron transfer by methylamine dehydrogenase by site-directed mutagenesis of alpha Phe55

Methylamine dehydrogenase (MADH) possesses an alpha(2)beta(2) subunit structure with each smaller beta subunit possessing a tryptophan tryptophylquinone (TTQ) prosthetic group. Phe(55) of the alpha subunit is located where the substrate channel from the enzyme surface opens into the active site. Site-directed mutagenesis studies have revealed several roles for this residue in catalysis and electron transfer (ET) by MADH. Site-directed mutagenesis of either alpha Phe(55) or beta Ile(107) (a residue in the beta subunit which interacts with alpha Phe(55)) converts MADH into enzymes with specificities for long-chain amines, amylamine or propylamine. Mutation of alpha Phe(55) also affects monovalent cation binding to the active site. alpha F55A MADH exhibits an increased K(d) for cation-dependent spectral changes and a decreased K(d) for cation-dependent stimulation of the rate of gated ET from N-quinol MADH to amicyanin. These results demonstrate that alpha Phe(55) is able to directly participate in a wide range of biochemical processes not typically observed for a phenylalanine residue.     

pH-dependent semiquinone formation by methylamine dehydrogenase from Paracoccus denitrificans. Evidence for intermolecular electron transfer between quinone cofactors

The quinonoid confactors of Paracoccus denitrificans methylamine dehydrogenase exhibited a pH-dependent redistribution of electrons from the 50% reduced plus 50% oxidized to the 100% semiquinone redox form. This phenomenon was only observed at pH values greater than 7.5. The semiquinone was not readily reduced by addition of methylamine, consistent with the view that this substrate donates two electrons at a time to each cofactor during catalysis. Once formed at pH 9.0, no change in redox state from 100% semiquinone was observed when the pH was shifted to 7.5, suggesting that the requirement of high pH was for formation and not stability of the semiquinone. The rate of semiquinone formation exhibited a first-order dependence on the concentration of methylamine dehydrogenase, indicating that this phenomenon was a bimolecular process involving intermolecular electron transfer between reduced and oxidized cofactors. The rate of semiquinone formation decreased with decreasing ionic strength, suggesting a role for hydrophobic interactions in facilitating electron transfer between methylamine dehydrogenase molecules. Methylamine dehydrogenase was covalently modified with norleucine methyl ester in the presence of 1-ethyl-3-[3-(dimethylamino)propyl]carbodiimide (EDC). This modification did not affect the catalytic activity of the enzyme but greatly inhibited the intermolecular redistribution of electrons at high pH. This modification also prevented subsequent cross-linking by EDC of the large subunit of methylamine dehydrogenase to amicyanin, the natural electron acceptor for this enzyme.(ABSTRACT TRUNCATED AT 250 WORDS)     

Mutation of alphaPhe55 of methylamine dehydrogenase alters the reorganization energy and electronic coupling for its electron transfer reaction with amicyanin

Methylamine dehydrogenase (MADH) possesses an alpha(2)beta(2) structure with each smaller beta subunit possessing a tryptophan tryptophylquinone (TTQ) prosthetic group. Phe55 of the alpha subunit is located where the substrate channel from the enzyme surface opens into the active site. Site-directed mutagenesis of alphaPhe55 has revealed roles for this residue in determining substrate specificity and binding monovalent cations at the active site. It is now shown that the alphaF55A mutation also increases the rate of the true electron transfer (ET) reaction from O-quinol MADH to amicyanin. The reorganization energy associated with the ET reaction is decreased from 2.3 to 1.8 eV. The electronic coupling associated with the ET reaction is decreased from 12 to 3 cm(-1). The crystal structure of alphaF55A MADH in complex with its electron acceptors, amicyanin and cytochrome c-551i, has been determined. Little difference in the overall structure is seen, relative to the native complex; however, there are significant changes in the solvent content of the active site and substrate channel. The crystal structure of alphaF55A MADH has also been determined with phenylhydrazine covalently bound to TTQ in the active site. Phenylhydrazine binding significantly perturbs the orientation of the TTQ rings relative to each other. The ET results are discussed in the context of the new and old crystal structures of the native and mutant enzymes.     

Sperm-specific glyceraldehyde-3-phosphate dehydrogenase is stabilized by additional proline residues and an interdomain salt bridge

Sperm-specific glyceraldehyde-3-phosphate dehydrogenase (GAPDS) exhibits enhanced stability compared to the somatic isoenzyme (GAPD). A comparative analysis of the structures of these isoenzymes revealed characteristic features, which could be important for the stability of GAPDS: six specific proline residues and three buried salt bridges. To evaluate the impact of these structural elements into the stability of this isoenzyme, we obtained two series of mutant GAPDS: 1) six mutants each containing a substitution of one of the specific prolines by alanine, and 2) three mutants each containing a mutation breaking one of the salt bridges. Stability of the mutants was evaluated by differential scanning calorimetry and by their resistance towards guanidine hydrochloride (GdnHCl). The most effect on thermostability was observed for the mutants P326A and P164A: the T_m values of the heat-absorption curves decreased by 6.0 and 3.3 °C compared to the wild type protein, respectively. The resistance towards GdnHCl was affected most by the mutation D311N breaking the salt bridge between the catalytic and NAD⁺-binding domains: the inactivation rate constant in the presence of GdnHCl increased six-fold, and the value of GdnHCl concentration corresponding to the protein half-denaturation decreased from 1.83 to 1.35 M. Besides, the mutation D311N enhanced the enzymatic activity of the protein two-fold. The results suggest that the residues P164 (β-turn), P326 (first position of α-helix), and the interdomain salt bridge D311–H124 are significant for the enhanced stability of GAPDS. The salt bridge D311–H124 enhances stability of the active site of GAPDS at the expense of the catalytic activity.     

Cloning, sequencing and expression studies of the genes encoding amicyanin and the beta-subunit of methylamine dehydrogenase from Thiobacillus versutus.

The genes encoding amicyanin and the beta-subunit of methylamine dehydrogenase (MADH) from Thiobacillus versutus have been cloned and sequenced. The organization of these genes makes it likely that they are coordinately expressed and it supports earlier findings that the blue copper protein amicyanin is involved in electron transport from methylamine to oxygen. The amino acid sequence deduced from the nucleotide sequence of the amicyanin-encoding gene is in agreement with the published protein sequence. The gene codes for a pre-protein with a 25-amino-acid-long signal peptide. The amicyanin gene could be expressed efficiently in Escherichia coli. The protein was extracted with the periplasmic fraction, indicating that pre-amicyanin is translocated across the inner membrane of E. coli. Sequence studies on the purified beta-subunit of MADH confirm the amino acid sequence deduced from the nucleotide sequence of the corresponding gene. The latter codes for a pre-protein with an unusually long (56 amino acids) leader peptide. The sequencing results strongly suggest that pyrroloquinoline quinone (PQQ) or pro-PQQ is not the co-factor of MADH.     

Structural basis for flip-flop action of thiamin pyrophosphate-dependent enzymes revealed by human pyruvate dehydrogenase

The derivative of vitamin B1, thiamin pyrophosphate, is a cofactor of enzymes performing catalysis in pathways of energy production. In alpha2beta2-heterotetrameric human pyruvate dehydrogenase, this cofactor is used to cleave the Calpha-C(=O) bond of pyruvate followed by reductive acetyl transfer to lipoyl-dihydrolipoamide acetyltransferase. The dynamic nonequivalence of two, otherwise chemically equivalent, catalytic sites has not yet been understood. To understand the mechanism of action of this enzyme, we determined the crystal structure of the holo-form of human pyruvate dehydrogenase at 1.95-A resolution. We propose a model for the flip-flop action of this enzyme through a concerted approximately 2-A shuttle-like motion of its heterodimers. Similarity of thiamin pyrophosphate binding in human pyruvate dehydrogenase with functionally related enzymes suggests that this newly defined shuttle-like motion of domains is common to the family of thiamin pyrophosphate-dependent enzymes.     

Structural and thermodynamic basis for weak interactions between dihydrolipoamide dehydrogenase and subunit-binding domain of the branched-chain alpha-ketoacid dehydrogenase complex

The purified mammalian branched-chain α-ketoacid dehydrogenase complex (BCKDC), which catalyzes the oxidative decarboxylation of branched-chain α-keto acids, is essentially devoid of the constituent dihydrolipoamide dehydrogenase component (E3). The absence of E3 is associated with the low affinity of the subunit-binding domain of human BCKDC (hSBDb) for hE3. In this work, sequence alignments of hSBDb with the E3-binding domain (E3BD) of the mammalian pyruvate dehydrogenase complex show that hSBDb has an arginine at position 118, where E3BD features an asparagine. Substitution of Arg-118 with an asparagine increases the binding affinity of the R118N hSBDb variant (designated hSBDb*) for hE3 by nearly 2 orders of magnitude. The enthalpy of the binding reaction changes from endothermic with the wild-type hSBDb to exothermic with the hSBDb* variant. This higher affinity interaction allowed the determination of the crystal structure of the hE3/hSBDb* complex to 2.4-Å resolution. The structure showed that the presence of Arg-118 poses a unique, possibly steric and/or electrostatic incompatibility that could impede E3 interactions with the wild-type hSBDb. Compared with the E3/E3BD structure, the hE3/hSBDb* structure has a smaller interfacial area. Solution NMR data corroborated the interactions of hE3 with Arg-118 and Asn-118 in wild-type hSBDb and mutant hSBDb*, respectively. The NMR results also showed that the interface between hSBDb and hE3 does not change significantly from hSBDb to hSBDb*. Taken together, our results represent a starting point for explaining the long standing enigma that the E2b core of the BCKDC binds E3 far more weakly relative to other α-ketoacid dehydrogenase complexes.     

Molecular basis of melanocortin-4 receptor for AGRP inverse agonism

We have investigated receptor structural components of the melanocortin-4 receptor (MC4R) responsible for ligand-dependent inverse agonism. We utilized agouti-related protein (AGRP), an inverse agonist which reduces MC4R basal cAMP production, as a tool to determine the molecular mechanism. We tested a series of chimeric receptors and utilized MC4R and MC1R as templates, in which AGRP is an inverse agonist for MC4R but not for MC1R. Our results indicate that replacements of the extracellular loops 1, 2 and 3 of MC4R with the corresponding regions of MC1R did not affect AGRP inverse agonist activity. However, replacement of the N terminus of MC4R with the same region of MC1R decreases AGRP inverse agonism. Replacement of transmembrane domains 3, 4, 5 and 6 of MC4R with the corresponding regions of MC1R did not affect AGRP inverse agonist activity but mutation of D90A in transmembrane 2 (TM2) and D298A in TM7 abolished AGRP inverse activity. Deletion of the distal MC4R C terminus fails to maintain AGRP mediated reduction in basal cAMP production although it maintains NDP-MSH mediated cAMP production. In conclusion, our results indicate that the N terminus and the distal C terminus of MC4R do appear to play important roles in AGRP inverse agonism but not NDP-MSH mediated receptor activation. Our results also indicate that the residues D90 in TM2 and D298 in TM7 of hMC4R are involved in not only NDP-MSH mediated receptor activation but also AGRP mediated inverse agonism.     

Molecular dynamics complemented by site-directed mutagenesis reveals significant difference between the interdomain salt bridge networks stabilizing oligopeptidases B from bacteria and protozoa in their active conformations

Abstract

Oligopeptidases B (OpdBs) are trypsin-like peptidases from protozoa and bacteria that belong to the prolyl oligopeptidase (POP) family. All POPs consist of C-terminal catalytic domain and N-terminal β-propeller domain and exist in two major conformations: closed (active), where the domains and residues of the catalytic triad are positioned close to each other, and open (non-active), where two domains and residues of the catalytic triad are separated. The interdomain interface, particularly, one of its salt bridges (SB1), plays a role in the transition between these two conformations. However, due to double amino acid substitution (E/R and R/Q), this functionally important SB1 is absent in γ-proteobacterial OpdBs including peptidase from Serratia proteamaculans (PSP). In this study, molecular dynamics was used to analyze inter- and intradomain interactions stabilizing PSP in the closed conformation, in which catalytic H652 is located close to other residues of the catalytic triad. The 3D models of either wild-type PSP or of mutant PSPs carrying activating mutations E125A and D649A in complexes with peptide-substrates were subjected to the analysis. The mechanism that regulates transition of H652 from active to non-active conformation upon domain separation in PSP and other γ-proteobacterial OpdB was proposed. The complex network of polar interactions within H652-loop/C-terminal α-helix and between these areas and β-propeller domain, established in silico, was in a good agreement with both previously published results on the effects of single-residue mutations and new data on the effects of the activating mutations on each other and on the low active mutant PSP-K655A.

Communicated by Ramaswamy H. Sarma     

Molecular basis for defective secretion of the Z variant of human alpha-1-proteinase inhibitor: secretion of variants having altered potential for salt bridge formation between amino acids 290 and 342.

Human alpha-1-proteinase inhibitor (A1PI) deficiency, associated with the Z-variant A1PI (A1PI/Z) gene, results from defective secretion of the inhibitor from the liver. The A1PI/Z gene exhibits two point mutations which specify amino acid substitutions, Val-213 to Ala and Glu-342 to Lys. The functional importance of these substitutions in A1PI deficiency was investigated by studying the secretion of A1PI synthesized in COS cells transfected with A1PI genes altered by site-directed mutagenesis. This model system correctly duplicates the secretion defect seen in individuals homozygous for the A1PI/Z allele and shows that the substitution of Lys for Glu-342 alone causes defective secretion of A1PI. The substitution of Lys for Glu-342 eliminates the possibility for a salt bridge between residues 342 and 290, which may decrease the conformational stability of the molecule and thus account for the secretion defect. However, when we removed the potential to form a salt bridge from the wild-type inhibitor by changing Lys-290 to Glu (A1PI/SB-290Glu), secretion was not reduced to the 19% of normal level seen for A1PI/Z-342Lys; in fact, 75% of normal secretion was observed. When the potential for salt bridge formation was returned to A1PI/Z-342Lys by changing Lys-290 to Glu, only 46% of normal secretion was seen. These data indicate that the amino acid substitution at position 342, rather than the potential to form the 290-342 salt bridge, is the critical alteration leading to the defect in A1PI secretion.     

Molecular modeling of formate dehydrogenase: the formation of the Michaelis complex

The formation of the reactive enzyme–substrate complex of formate dehydrogenase has been investigated by molecular dynamics techniques accounting for different conformational states of the enzyme. Simulations revealed that the transport of substrate to the active site through the substrate channel proceeds in the open conformation of enzyme due to the crucial role of the Arg284 residue acting as a vehicle. However, formate binding in the active site of the open conformation leads to the formation of a nonproductive enzyme–substrate complex. The productive Michaelis complex is formed only in the closed enzyme conformation after the substrate and coenzyme have bound, when required rigidity of the binding site and reactive formate orientation due to interactions with Arg284, Asn146, Ile122, and His332 residues is attained. Then, the high occupancy (up to 75%) of the reactive substrate–coenzyme conformation is reached, which was demonstrated by hybrid quantum mechanics/molecular mechanics simulations using various semiempirical Hamiltonians.     

Nardilysin facilitates complex formation between mitochondrial malate dehydrogenase and citrate synthase

Gel filtration chromatography showed that nardilysin activity in a rat testis or rat brain extract exhibited an apparent molecular weight of approximately 300 kDa compared to approximately 187 kDa for the purified enzyme. The addition of purified nardilysin to a rat brain extract, but not to an E. coli extract, produced the higher molecular species. The addition of a GST fusion protein containing the acidic domain of nardilysin eliminated the higher molecular weight nardilysin forms, suggesting that oligomerization involves the acidic domain of nardilysin. Using an immobilized nardilysin column, mitochondrial malate dehydrogenase (mMDH) and citrate synthase (CS) were isolated from a fractionated rat brain extract. Porcine mMDH, but not porcine cytosolic MDH, was shown to form a heterodimer with nardilysin. Mitochondrial MDH increased nardilysin activity about 50%, while nardilysin stabilized mMDH towards heat inactivation. CS was co-immunoprecipitated with mMDH only in the presence of nardilysin showing that nardilysin facilitates complex formation.