One residue substitution in PcyA leads to unexpected changes in tetrapyrrole substrate binding

Phycocyanobilin:ferredoxin oxidoreductase (PcyA) catalyzes the sequential reduction of the vinyl group of the D-ring and A-ring of biliverdin IXα (BV), using reducing equivalents provided by ferredoxin. This reaction produces phycocyanobilin, a pigment used for light-harvesting and light-sensing in red algae and cyanobacteria. The crystal structure of PcyA-BV reveals that BV is specifically bound in the PcyA active pocket through extensive hydrophobic and hydrophilic interactions. During the course of a mutational study of PcyA, we observed that mutation of the V225 position, apart from the processing sites, conferred an unusual property on PcyA; V225D mutant protein could bind BV and its analog BV13, but these complexes showed a distinct UV-vis absorption spectrum from that of the wild-type PcyA-BV complex. The crystal structures of BV- and BV13-bound forms of V225D protein revealed that gross structural changes occurred near the substrate-binding pocket, and that the BV/BV13 binding manner in the pocket was dramatically altered. Protein folding in V225D-BV/BV13 was more similar to that of substrate-free PcyA than that in PcyA-BV; the “induced-fit” did not occur when BV/BV13 was bound to the V225D protein. The unexpected structural change presented here provides a cautionary note about interpreting functional data derived from a mutated protein in the absence of its exact structure.     

Structural Insights into Vinyl Reduction Regiospecificity of Phycocyanobilin:Ferredoxin Oxidoreductase (PcyA)

Phycocyanobilin:ferredoxin oxidoreductase (PcyA) is the best characterized member of the ferredoxin-dependent bilin reductase family. Unlike other ferredoxin-dependent bilin reductases that catalyze a two-electron reduction, PcyA sequentially reduces D-ring (exo) and A-ring (endo) vinyl groups of biliverdin IXα (BV) to yield phycocyanobilin, a key pigment precursor of the light-harvesting antennae complexes of red algae, cyanobacteria, and cryptophytes. To address the structural basis for the reduction regiospecificity of PcyA, we report new high resolution crystal structures of bilin substrate complexes of PcyA from Synechocystis sp. PCC6803, all of which lack exo-vinyl reduction activity. These include the BV complex of the E76Q mutant as well as substrate-bound complexes of wild-type PcyA with the reaction intermediate 18¹,18²-dihydrobiliverdin IXα (18EtBV) and with biliverdin XIIIα (BV13), a synthetic substrate that lacks an exo-vinyl group. Although the overall folds and the binding sites of the U-shaped substrates of all three complexes were similar with wild-type PcyA-BV, the orientation of the Glu-76 side chain, which was in close contact with the exo-vinyl group in PcyA-BV, was rotated away from the bilin D-ring. The local structures around the A-rings in the three complexes, which all retain the ability to reduce the A-ring of their bound pigments, were nearly identical with that of wild-type PcyA-BV. Consistent with the proposed proton-donating role of the carboxylic acid side chain of Glu-76 for exo-vinyl reduction, these structures reveal new insight into the reduction regiospecificity of PcyA.     

Phycocyanobilin:ferredoxin oxidoreductase of Anabaena sp. PCC 7120. Biochemical and spectroscopic

In cyanobacteria, the biosynthesis of the phycobiliprotein and phytochrome chromophore precursor phycocyanobilin is catalyzed by the ferredoxin-dependent enzyme phycocyanobilin:ferredoxin oxidoreductase (PcyA), which mediates an atypical four-electron reduction of biliverdin IXalpha. Here we describe the expression, affinity purification, and biochemical characterization of recombinant PcyA from Anabaena sp. PCC 7120. A monomeric protein with a native M(r) of 30,400 +/- 5,000, recombinant PcyA forms a tight and stable stoichiometric complex with its substrate biliverdin IXalpha. The enzyme exhibits a strong preference for plant type [2Fe-2S] ferredoxins; however, flavodoxin can also serve as an electron donor. HPLC analyses establish that catalysis proceeds via the two electron-reduced intermediate 18(1),18(2)-dihydrobiliverdin, indicating that exovinyl reduction precedes A-ring (endovinyl) reduction. Substrate specificity studies indicate that the arrangement of the A- and D-ring substituents alters the positioning of the bilin substrate within the enzyme, profoundly influencing the course of catalysis. Based on these observations and the apparent lack of a metal or small molecule cofactor, a radical mechanism for biliverdin IXalpha reduction by phycocyanobilin:ferredoxin oxidoreductase is envisaged.     

Structural and mechanistic insight into the ferredoxin-mediated two-electron reduction of bilins

PEB (phycoerythrobilin) is one of the major open-chain tetrapyrrole molecules found in cyanobacterial light-harvesting phycobiliproteins. In these organisms, two enzymes of the ferredoxin-dependent bilin reductase family work in tandem to reduce BV (biliverdin IXα) to PEB. In contrast, a single cyanophage-encoded enzyme of the same family has been identified to catalyse the identical reaction. Using UV-visible and EPR spectroscopy we investigated the two individual cyanobacterial enzymes PebA [15,16-DHBV (dihydrobiliverdin):ferredoxin oxidoreductase] and PebB (PEB:ferredoxin oxidoreductase) showing that the two subsequent reactions catalysed by the phage enzyme PebS (PEB synthase) are clearly dissected in the cyanobacterial versions. Although a highly conserved aspartate residue is critical for both reductions, a second conserved aspartate residue is only involved in the A-ring reduction of the tetrapyrrole in PebB and PebS. The crystal structure of PebA from Synechococcus sp. WH8020 in complex with its substrate BV at a 1.55 ? (1 ?=0.1 nm) resolution revealed further insight into the understanding of enzyme evolution and function. Based on the structure it becomes obvious that in addition to the importance of certain catalytic residues, the shape of the active site and consequently the binding of the substrate highly determines the catalytic properties.     

Phycoerythrobilin synthase (PebS) of a marine virus. Crystal structures of the biliverdin complex and the substrate-free form

The reddish purple open chain tetrapyrrole pigment phycoerythrobilin (PEB; A(lambdamax) approximately 550 nm) is an essential chromophore of the light-harvesting phycobiliproteins of most cyanobacteria, red algae, and cryptomonads. The enzyme phycoerythrobilin synthase (PebS), recently discovered in a marine virus infecting oceanic cyanobacteria of the genus Prochlorococcus (cyanophage PSSM-2), is a new member of the ferredoxin-dependent bilin reductase (FDBR) family. In a formal four-electron reduction, the substrate biliverdin IXalpha is reduced to yield 3Z-PEB, a reaction that commonly requires the action of two individual FDBRs. The first reaction catalyzed by PebS is the reduction of the 15,16-methine bridge of the biliverdin IXalpha tetrapyrrole system. This reaction is exclusive to PEB biosynthetic enzymes. The second reduction site is the A-ring 2,3,3(1),3(2)-diene system, the most common target of FDBRs. Here, we present the first crystal structures of a PEB biosynthetic enzyme. Structures of the substrate complex were solved at 1.8- and 2.1-A resolution and of the substrate-free form at 1.55-A resolution. The overall folding revealed an alpha/beta/alpha-sandwich with similarity to the structure of phycocyanobilin:ferredoxin oxidoreductase (PcyA). The substrate-binding site is located between the central beta-sheet and C-terminal alpha-helices. Eight refined molecules with bound substrate, from two different crystal forms, revealed a high flexibility of the substrate-binding pocket. The substrate was found to be either in a planar porphyrin-like conformation or in a helical conformation and is coordinated by a conserved aspartate/asparagine pair from the beta-sheet side. From the alpha-helix side, a conserved highly flexible aspartate/proline pair is involved in substrate binding and presumably catalysis.     

Insight into the radical mechanism of phycocyanobilin-ferredoxin oxidoreductase (PcyA) revealed by X-ray crystallography and biochemical measurements

The X-ray crystal structure of the substrate-free form of phycocyanobilin (PCB)-ferredoxin oxidoreductase (PcyA; EC 1.3.7.5) from the cyanobacterium Nostoc sp. PCC7120 has been solved at 2.5 A resolution. A comparative analysis of this structure with those recently reported for substrate-bound and substrate-free forms of PcyA from the cyanobacterium Synechocystis sp. PCC6803 (Hagiwara et al. (2006) Proc. Natl. Acad. Sci. U.S.A. 103, 27-32; Hagiwara et al. (2006) FEBS Lett. 580, 3823-3828) provides a compelling picture of substrate-induced changes in the PcyA enzyme and the chemical basis of PcyA's catalytic activity. On the basis of these structures and the biochemical analysis of site-directed mutants of Nostoc PcyA, including mutants reported in recent studies (Tu et al. (2006) J. Biol. Chem. 281, 3127-3136) as well as mutants described in this study, a revised mechanism for the PcyA-mediated four-electron reduction of biliverdin IXalpha to 3E/3Z-phycocyanobilin via enzyme-bound bilin radical intermediates is proposed. The mechanistic insight of these studies, along with homology modeling, have provided new insight into the catalytic mechanisms of other members of the ferredoxin-dependent bilin reductase family that are widespread in oxygenic photosynthetic organisms.     

His74 conservation in the bilin reductase PcyA family reflects an important role in protein-substrate structure and dynamics

Phycocyanobilin:ferredoxin oxidoreductase (PcyA) catalyzes the proton-coupled four-electron reduction of biliverdin IXα’s two vinyl groups to produce phycocyanobilin, an essential chromophore for phytochromes, cyanobacteriochromes and phycobiliproteins. Previous site directed mutagenesis studies indicated that the fully conserved residue His74 plays a critical role in the H-bonding network that permits proton transfer. Here, we exploit X-ray crystallography, enzymology and molecular dynamics simulations to understand the functional role of this invariant histidine. The structures of the H74A, H74E and H74Q variants of PcyA reveal that a “conserved” buried water molecule that bridges His74 and catalytically essential His88 is not required for activity. Despite distinct conformations of Glu74 and Gln74 in the H74E and H74Q variants, both retain reasonable activity while the H74A variant is inactive, suggesting smaller residues may generate cavities that increase flexibility, thereby reducing enzymatic activity. Molecular dynamic simulations further reveal that the crucial active site residue Asp105 is more dynamic in H74A compared to wild-type PcyA and the two other His74 variants, supporting the conclusion that the Ala74 mutation has increased the flexibility of the active site.     

Insights into phycoerythrobilin biosynthesis point toward metabolic channeling

Phycoerythrobilin is a linear tetrapyrrole molecule found in cyanobacteria, red algae, and cryptomonads. Together with other bilins such as phycocyanobilin it serves as a light-harvesting pigment in the photosynthetic light-harvesting structures of cyanobacteria called phycobilisomes. The biosynthesis of both pigments starts with the cleavage of heme by heme oxygenases to yield biliverdin IXalpha, which is further reduced at specific positions by ferredoxin-dependent bilin reductases (FDBRs), a new family of radical enzymes. The biosynthesis of phycoerythrobilin requires two subsequent two-electron reductions, each step being catalyzed by one FDBR. This is in contrast to the biosynthesis of phycocyanobilin, where the FDBR phycocyanobilin: ferredoxin oxidoreductase (PcyA) catalyzes a four-electron reduction. The first reaction in phycoerythrobilin biosynthesis is the reduction of the 15,16-double bond of biliverdin IXalpha by 15,16-dihydrobiliverdin:ferredoxin oxidoreductase (PebA). This reaction reduces the conjugated pi -electron system thereby blue-shifting the absorbance properties of the linear tetrapyrrole. The second FDBR, phycoerythrobilin:ferredoxin oxidoreductase (PebB), then reduces the A-ring 2,3,3(1),3(2)-diene structure of 15,16-dihydrobiliverdin to yield phycoerythrobilin. Both FDBRs from the limnic filamentous cyanobacterium Fremyella diplosiphon and the marine cyanobacterium Synechococcus sp. WH8020 were recombinantly produced in Escherichia coli and purified, and their enzymatic activities were determined. By using various natural bilins, the substrate specificity of each FDBR was established, revealing conformational preconditions for their unique specificity. Preparation of the semi-reduced intermediate, 15,16-dihydrobiliverdin, enabled us to perform steady state binding experiments indicating distinct spectroscopic and fluorescent properties of enzyme.bilin complexes. A combination of substrate/product binding analyses and gel permeation chromatography revealed evidence for metabolic channeling.     

Crystal structures of substrate-free and nitrosyl cytochrome p450cin: implications for o(2) activation

The crystal structure of the P450cin substrate-bound nitric oxide complex and the substrate-free form have been determined revealing a substrate-free structure that adopts an open conformation relative to the substrate-bound structure. The region of the I helix that forms part of the O(2) binding pocket shifts from an α helix in the substrate-free form to a π helix in the substrate-bound form. Unique to P450cin is an active site residue, Asn242, in the I helix that H-bonds with the substrate. In most other P450s this residue is a Thr and plays an important role in O(2) activation by participating in an H-bonding network required for O(2) activation. The π/α I helix transition results in the carbonyl O atom of Gly238 moving in to form an H-bond with the water/hydroxide ligand in the substrate-free form. The corresponding residue, Gly248, in the substrate-free P450cam structure experiences a similar motion. Most significantly, in the oxy-P450cam complex Gly248 adopts a position midway between the substrate-free and -bound states. A comparison between these P450cam and the new P450cin structures provides insights into differences in how the two P450s activate O(2). The structure of P450cin complexed with nitric oxide, a close mimic of the O(2) complex, shows that Gly238 is likely to form tighter interactions with ligands than the corresponding Gly248 in P450cam. Having a close interaction between an H-bond acceptor, the Gly238 carbonyl O atom, and the distal oxygen atom of O(2) will promote protonation and hence further reduction of the oxy complex to the hydroperoxy intermediate resulting in heterolytic cleavage of the peroxide O-O bond and formation of the active ferryl intermediate required for substrate hydroxylation.     

Substrate-induced conformational change of a coenzyme B12-dependent enzyme: crystal structure of the substrate-free form of diol dehydratase

Substrate binding triggers catalytic radical formation through the cobalt-carbon bond homolysis in coenzyme B12-dependent enzymes. We have determined the crystal structure of the substrate-free form of Klebsiella oxytoca diol dehydratase*cyanocobalamin complex at 1.85 A resolution. The structure contains two units of the heterotrimer consisting of alpha, beta, and gamma subunits. As compared with the structure of its substrate-bound form, the beta subunits are tilted by approximately 3 degrees and cobalamin is also tilted so that pyrrole rings A and D are significantly lifted up toward the substrate-binding site, whereas pyrrole rings B and C are only slightly lifted up. The structure revealed that the potassium ion in the substrate-binding site of the substrate-free enzyme is also heptacoordinated; that is, two oxygen atoms of two water molecules coordinate to it instead of the substrate hydroxyls. A modeling study in which the structures of both the cobalamin moiety and the adenine ring of the coenzyme were superimposed onto those of the enzyme-bound cyanocobalamin and the adenine ring-binding pocket, respectively, demonstrated that the distortions of the Co-C bond in the substrate-free form are already marked but slightly smaller than those in the substrate-bound form. It was thus strongly suggested that the Co-C bond becomes largely activated (labilized) when the coenzyme binds to the apoenzyme even in the absence of substrate and undergoes homolysis through the substrate-induced conformational changes of the enzyme. Kinetic coupling of Co-C bond homolysis with hydrogen abstraction from the substrate shifts the equilibrium to dissociation.     

A ferredoxin bridge connects the two arms of plant mitochondrial complex I

Mitochondrial complex I is the main site for electron transfer to the respiratory chain and generates much of the proton gradient across the inner mitochondrial membrane. Complex I is composed of two arms, which form a conserved L-shape. We report the structures of the intact, 47-subunit mitochondrial complex I from Arabidopsis thaliana and the 51-subunit complex I from the green alga Polytomella sp., both at around 2.9 Å resolution. In both complexes, a heterotrimeric γ-carbonic anhydrase domain is attached to the membrane arm on the matrix side. Two states are resolved in A. thaliana complex I, with different angles between the two arms and different conformations of the ND1 (NADH dehydrogenase subunit 1) loop near the quinol binding site. The angle appears to depend on a bridge domain, which links the peripheral arm to the membrane arm and includes an unusual ferredoxin. We propose that the bridge domain participates in regulating the activity of plant complex I.

An unusual ferredoxin completes a protein bridge that links the two arms of plant mitochondrial complex I and adjusts their angle in an open or closed conformation.     

Complex formation between ferredoxin and Synechococcus ferredoxin: nitrate oxidoreductase

The ferredoxin-dependent nitrate reductase from the cyanobacterium Synechococcus sp. PCC 7942 has been shown to form a high-affinity complex with ferredoxin at low ionic strength. This complex, detected by changes in both the absorbance and circular dichroism (CD) spectra, did not form at high ionic strength. When reduced ferredoxin served as the electron donor for the reduction of nitrate to nitrite, the activity of the enzyme declined markedly as the ionic strength increased. In contrast, the activity of the enzyme with reduced methyl viologen (a non-physiological electron donor) was independent of ionic strength. These results suggest that an electrostatically stabilized complex between Synechococcus nitrate reductase and ferredoxin plays an important role in the mechanism of nitrate reduction catalyzed by this enzyme. Treatment of Synechococcus nitrate reductase with either an arginine-modifying reagent or a lysine-modifying reagent inhibited the ferredoxin-dependent activity of the enzyme but did not affect the methyl viologen-dependent activity. Treatment with these reagents also resulted in a large decrease in the affinity of the enzyme for ferredoxin. Formation of a nitrate reductase complex with ferredoxin prior to treatment with either reagent protected the enzyme against loss of ferredoxin-dependent activity. These results suggest that lysine and arginine residues are present at the ferredoxin-binding site of Synechococcus nitrate reductase. Results of experiments using site-specific, charge reversal variants of the ferredoxin from the cyanobacterium Anabaena sp. PCC 7119 as an electron donor to nitrate reductase were consistent with a role for negatively charged residues on ferredoxin in the interaction with Synechococcus nitrate reductase.     

The interaction of ferredoxin and glutamate synthase: cross-linking and immunological studies

The water-soluble carbodiimide, N-ethyl-3-(3-dimethylaminopropyl) carbodiimide (EDC) serves as an effective reagent for cross-linking spinach leaf ferredoxin and the ferredoxin-dependent spinach leaf enzyme, glutamate synthase. The cross-linked complex was functional in the absence of added ferredoxin, suggesting that ferredoxin is cross-linked to glutamate synthase at the physiological binding site on the enzyme for this iron-sulfur protein electron donor. The ferredoxin:glutamate synthase stoichiometry of the cross-linked complex was estimated to be 2:1. The absorbance spectrum of the oxidized, cross-linked complex was very similar to that of an electrostatically stabilized, noncovalent, 2:1 complex of the two proteins. An antibody raised against spinach NADP+ reductase, which recognizes a ferredoxin-binding site on glutamate synthase, does not recognize the cross-linked ferredoxin-glutamate synthase complex. This implies that the ferredoxin-binding sites on the two enzymes are structurally similar enough so that an antibody raised against one of these ferredoxin-dependent enzymes recognizes an epitope at the ferredoxin-binding site of the second enzyme. Cross-linking of ferredoxin to its binding site on glutamate synthase renders this epitope inaccessible to the antibody.     

Tryptophan fluorescence studies of ferredoxin:NADP reductase indicate the presence of tryptophan in or near the ferredoxin binding site

The tryptophan fluorescence properties of the flavoprotein ferredoxin:NADP reductase have been examined. Although not sensitive to changes in pH or salt concentration, the tryptophan fluorescence is affected by the presence of substrates for the flavoprotein. While NADP addition results in a slight quenching of the fluorescence, ferredoxin decreases the fluorescence by nearly 50%, suggesting the presence of tryptophan in or near the ferredoxin binding site. Titration of this effect gives a dissociation constant for the ferredoxin: flavoprotein complex which is similar to that obtained by spectral perturbations. This approach has also been used to demonstrate that a chemically modified ferredoxin which does not produce spectral perturbations when added to flavoprotein is capable of interacting with the flavoprotein although with a higher dissociation constant than for native ferredoxin.     

Monoclonal antibody studies of ferredoxin:NADP+ oxidoreductase.

Eleven independent monoclonal antibodies, all IgG's, have been raised against the ferredoxin:NADP+ oxidoreductase of spinach leaves. All 11 monoclonal antibodies were able to produce substantial inhibition of the NADPH to 2,6-dichlorophenol indophenol (DCPIP) diaphorase activity of the enzyme, but none of the antibodies produced any significant inhibition of electron flow from NADPH to ferredoxin catalyzed by the enzyme. Spectral perturbation assays were used to demonstrate that antibody interaction with NADP+ reductase did not interfere significantly with the binding of either ferredoxin or NADP+ to the enzyme. Ultrafiltration binding assays were used to confirm that the monoclonal antibodies did not interfere with complex formation between ferredoxin and the enzyme. These results have been interpreted in terms of the likely presence of one or more highly antigenic epitopes at the site where the nonphysiological electron acceptor, DCPIP, binds to the enzyme. Furthermore, the results suggest that the site where DCPIP is reduced differs from both of the two separate sites at which the two physiological substrates, ferredoxin and NADP+/NADPH, are bound.     

Allosteric changes in solvent accessibility observed in thrombin upon active site occupation

The solvent accessibility of thrombin in its substrate-free and substrate-bound forms has been compared by amide hydrogen/deuterium (H/(2)H) exchange. The optimized inhibitor peptide dPhe-Pro-Arg chloromethyl ketone (PPACK) was used to simulate the substrate-bound form of thrombin. These studies were motivated by the lack of observed changes in the active site of thrombin in the crystal structure of the thrombin-thrombomodulin complex. This result appeared to contradict amide exchange studies on the thrombin-thrombomodulin complex that suggested subtle changes occur in the active site loops upon thrombomodulin binding. Our results show that two active site loops, residues 214-222 and residues 126-132, undergo decreases in solvent accessibility due to steric contacts with PPACK substrate. However, we also observe two regions outside the active site undergoing solvent protection upon substrate binding. The first region corresponds to anion binding exosite 1, and the second is a beta-strand-containing loop which runs through the core of the molecule and contains Trp141 which makes critical contacts with anion binding exosite 1. These results indicate two pathways of allosteric change that connect the active site to the distal anion binding exosite 1.     

The structure of lombricine kinase: implications for phosphagen kinase conformational changes

Lombricine kinase is a member of the phosphagen kinase family and a homolog of creatine and arginine kinases, enzymes responsible for buffering cellular ATP levels. Structures of lombricine kinase from the marine worm Urechis caupo were determined by x-ray crystallography. One form was crystallized as a nucleotide complex, and the other was substrate-free. The two structures are similar to each other and more similar to the substrate-free forms of homologs than to the substrate-bound forms of the other phosphagen kinases. Active site specificity loop 309-317, which is disordered in substrate-free structures of homologs and is known from the NMR of arginine kinase to be inherently dynamic, is resolved in both lombricine kinase structures, providing an improved basis for understanding the loop dynamics. Phosphagen kinases undergo a segmented closing on substrate binding, but the lombricine kinase ADP complex is in the open form more typical of substrate-free homologs. Through a comparison with prior complexes of intermediate structure, a correlation was revealed between the overall enzyme conformation and the substrate interactions of His(178). Comparative modeling provides a rationale for the more relaxed specificity of these kinases, of which the natural substrates are among the largest of the phosphagen substrates.     

Molecular dynamics simulations of P450 BM3--examination of substrate-induced conformational change.

Cytochrome P450 BM3, of bacterial origin, is one of only five isozymes of the ubiquitous family of over 400 metabolizing heme proteins with a known crystal structure and only one of two with both substrate-free and substrate-bound forms determined. P450 BM3 is of particular interest since it has a similar function and similar substrates as mammalian P450s particularly of the 4A subfamily. Thus, the extent to which the substrate-free form of P450 BM3 undergoes a conformational change upon binding of a typical fatty acid substrate, palmitoleic acid, has been the subject of recent active experimental effort. Surprisingly, direct examination of the substrate-free (pdb2hpd.ent and pdb2bmh.ent) and substrate-bound (pdb1fag.ent) forms do not provide a clear answer to this question. The main reason for this ambiguity is that the two substrate-free monomers reported in the crystal structures themselves have significantly different conformations from each other, one with a more open substrate-access channel than the other. Since there is no way to tell to which substrate-free form the substrate binds, the effect of substrate binding cannot be deduced directly from comparisons of the experimental substrate-bound and substrate-free forms. The computational studies reported here have been designed to more robustly establish the effect of substrate binding on this isozyme. Specifically, molecular dynamics simulations were performed for each of the two substrate-free forms found in the asymmetric unit of the X-ray structure and for the two corresponding substrate-bound forms, constructed by docking palmitloeic acid into each of them. Comparisons of the results showed that palmitoleic acid binding had little effect on the conformation of the more closed substrate-free form of P450 BM3. By contrast, in the more open substrate-free form, this same substrate induced a closing of the entrance to the substrate-binding channel. The MD averaged structure of these two complexes obtained from docking of pamitoleic acid into the two asymmetric units of the substrate-free form were also compared to that obtained starting with the X-ray structure of the substrate-bound form. These results taken together led to the conclusion that, if indeed the substrate induces conformational changes in P450 BM3, the mouth of the substrate-access channel first closes down in response to the presence of the substrate, followed by rotation of the F-G domain to further optimize the P450 BM3-substrate interaction that would occur at a later stage.     

On the conformation of reconstituted ferredoxin:NADP oxidoreductase in the thylakoid membrane. Studies via triplet lifetime and rotational diffusion with eosin isothiocyanate as label

Eosin isothiocyanate was covalently bound to isolated ferredoxin-NADP⁺ reductase under protection of the NADP-binding domain. The bound label did not impair the functional reconstitution of the enzyme into depleted thylakoid membranes. Laser spectrophotometric experiments were carried out on thylakoids which were reconstituted with labeled ferredoxin-NADP⁺ reductase. Bound eosin isothiocyanate was used as a spectroscopic probe for conformational changes of ferredoxin-NADP⁺ reductase in either of two ways: We studied the rotational diffusion of labeled ferredoxin-NADP⁺ reductase in the membrane by the photoselection technique, and we studied the triplet lifetime of bound eosin, which measures polypeptide chain flexibility (via access of oxygen) around the binding site. The latter technique was complemented by measurements of the librational motion of bound dye. We observed: (1) When ferredoxin is absent, ferredoxin-NADP⁺ reductase undergoes very rapid rotational diffusion in the thylakoid membrane (correlation time less than 1 μs at 10°C). This is drastically slowed down (40 μs) upon addition of water-soluble ferredoxin. We propose that ferredoxin mediates the formation of a ternary complex with ferredoxin-NADP⁺ reductase and the Photosystem I complex. According to our data, this complex would live longer than required for the photoreduction of ferredoxin-NADP⁺ reductase by Photosystem I via ferredoxin. (2) Under the given incubation conditions, the binding sites for eosin isothiocyanate were located in the FAD domain of ferredoxin-NADP⁺ reductase. We found increased chain flexibility in this domain upon addition of NADP. This suggests induced fit for the binding of NADP and allosteric control of the FAD domain by the remote NADP domain. (3) Acidification of the internal phase of thylakoids decreased the chain flexibility in the FAD domain. This is of particular interest, since ferredoxin-NADP⁺ reductase is a peripheral external membrane protein. It suggests the existence of a binding protein for the oxidoreductase which spans the membrane and senses the internal pH     

Electrostatic Interaction of Phytochromobilin Synthase and Ferredoxin for Biosynthesis of Phytochrome Chromophore

In plants, phytochromobilin synthase (HY2) synthesize the open chain tetrapyrrole chromophore for light-sensing phytochromes. It catalyzes the double bond reduction of a heme-derived tetrapyrrole intermediate biliverdin IXα (BV) at the A-ring diene system. HY2 is a member of ferredoxin-dependent bilin reductases (FDBRs), which require ferredoxins (Fds) as the electron donors for double bond reductions. In this study, we investigated the interaction mechanism of FDBRs and Fds by using HY2 and Fd from Arabidopsis thaliana as model proteins. We found that one of the six Arabidopsis Fds, AtFd2, was the preferred electron donor for HY2. HY2 and AtFd2 formed a heterodimeric complex that was stabilized by chemical cross-linking. Surface-charged residues on HY2 and AtFd2 were important in the protein-protein interaction as well as BV reduction activity of HY2. These surface residues are close to the iron-sulfur center of Fd and the HY2 active site, implying that the interaction promotes direct electron transfer from the Fd to HY2-bound BV. In addition, the C12 propionate group of BV is important for HY2-catalyzed BV reduction. A possible role for this functional group is to mediate the electron transfer by interacting directly with AtFd2. Together, our biochemical data suggest a docking mechanism for HY2:BV and AtFd2.