Substrate binding to cytochromes P450

P450s have attracted tremendous attention owing to not only their involvement in the metabolism of drug molecules and endogenous substrates but also the unusual nature of the reaction they catalyze, namely, the oxidation of unactivated C–H bonds. The binding of substrates to P450s, which is usually viewed as the first step in the catalytic cycle, has been studied extensively via a variety of biochemical and biophysical approaches. These studies were directed towards answering different questions related to P450s, including mechanism of oxidation, substrate properties, unusual substrate oxidation kinetics, function, and active-site features. Some of the substrate binding studies extending over a period of more than 40 years of dedicated work have been summarized in this review and categorized by the techniques employed in the binding studies.

Substrate binding favors enhanced NO binding to P450cam

Ferric cytochrome P450cam from Pseudomonas putida (P450cam) in buffer solution at physiological pH 7.4 reversibly binds NO to yield the nitrosyl complex P450cam(NO). The presence of 1R-camphor affects the dynamics of NO binding to P450cam and enhances the association and dissociation rate constants significantly. In the case of the substrate-free form of P450cam, subconformers are evident and the NO binding kinetics are much slower than in the presence of the substrate. The association and dissociation processes were investigated by both laser flash photolysis and stopped-flow techniques at ambient and high pressure. Large and positive values of S and V observed for NO binding to and release from the substrate-free P450cam complex are consistent with the operation of a limiting dissociative ligand substitution mechanism, where the lability of coordinated water dominates the reactivity of the iron(III)-heme center with NO. In contrast, NO binding to P450cam in the presence of camphor displays negative activation entropy and activation volume values that support a mechanism dominated by a bond formation process. Volume profiles for the binding of NO appear to be a valuable approach to explain the differences observed for P450cam in the absence and presence of the substrate and enable the clarification of the underlying reaction mechanisms at a molecular level. Changes in spin state of the iron center during the binding/release of NO contribute significantly to the observed volume effects. The results are discussed in terms of relevance for the biological function of cytochrome P450 and in context to other investigations of the related reactions between NO and imidazole- and thiolate-ligated iron(III) hemoproteins.     

Probing sponge-derived terpenoids for human 15-lipoxygenase inhibitors

A human 15-lipoxygenase (15-HLO) assay has been employed to discover new marine-sponge-derived bioactive compounds. Extracts from two different sponges, Jaspis splendens (order Choristida, family Jaspidae) and Suberea sp. (order Verongida, family Aplysinellidae), exhibited potent IC(50) values of 0.4 and 0.1 microg/mL, respectively. Both are sources of terpenoids, and the former is a known source of (+)-jasplakinolide (7), which is inactive as a 15-HLO inhibitor. The terpenoids included (+)-(5S,6S)-subersin (1, IC(50) > 100 microM), (-)-(5R,10R)-subersic acid (2, IC(50) = 15 microM), jaspaquinol (3, IC(50) = 0.3 microM), and (-)-jaspic acid (4, IC(50) = 1.4 microM). Structure elucidations and lipoxygenase activity studies of these compounds are reported.     

Substrate binding to cyclodextrins in aqueous solution: A multicomponent self-diffusion study

It is demonstrated that substrate binding to α- and β-cyclodextrins (CD) in solution can conveniently and directly be monitored from multicomponent self-diffusion data on these solutions, using the Fourier Transform NMR pulsed-gradient spin-echo technique. Included are aromatics and a series of alcohols ranging from methanol to octanol. Experimentally it was found thatn-alcohols associate more strongly with α-CD than with β-CD. As the bulkiness of the alcohol increased, binding to β-CD was enhanced while the reverse effect was observed in the case of α-CD. For both cyclodextrins it was found thatn-alcohol complexation in the homologous series was attributable to an increment in standard free energy of complexation of ～ ?3.0 kJ/mol for each ?CH₂? group, suggesting that the binding mechanism is of a hydrophobic nature.     

Substrate binding to vanadate-dependent bromoperoxidase from Ascophyllum nodosum: a vanadium K-edge XAS approach

The EXAFS region of vanadium K-edge XAS spectra of native vanadate-dependent bromoperoxidase (isoenzyme I) from Ascophyllum nodosum in the presence of the substrate bromide can be fitted to three shells (at 1.62, 1.73-1.78 and 1.99-2.07 A) in the first coordination sphere of vanadium plus two more distant shells at 4.1A, possibly corresponding to bromide, and 4.7 A due to light scatterers stemming from the protein pocket. Bromide does not directly bind to the vanadium centre. The XANES and the EXAFS features for the enzyme are essentially reproduced by model complexes of the general composition [VO(H(2)O)(n)(ONO)] (n= 1 or 2) where ONO is the dianion of a Schiff base from bromosalicylaldehydes (Brsal; with the Br substituent in the position 3, 4, 5 or 6) and amino acids. The 3-Brsal derivatives exhibit an outer sphere shell at 3.8 A, which is traced back to intermolecular contacts. The data obtained from EXAFS are compared to those obtained from single crystal X-ray diffraction of [VO(H(2)O)(2)(4-Brsal-gly)] and [VO(H(2)O)(2)(6-Brsal-gly)] (gly = glycinate). In the complex [VOBr(2)(ONO)']] ((ONO)' is the Schiff base from o-anisole and o-hydroxyaniline), the V-Br distance is 2.44 A.     

Substrate binding to NO-ferro-naphthalene 1,2-dioxygenase studied by high-resolution Q-band pulsed 2H-ENDOR spectroscopy

The active site of naphthalene 1,2-dioxygenase (NDO) contains a Rieske Fe-S cluster and a mononuclear non-heme iron, which are contributed by different alpha-subunits in the (alphabeta)(3) structure. The enzyme catalyzes cis-dihydroxylation of aromatic substrates, in addition to numerous other adventitious oxidation reactions. High-resolution Mims (2)H-ENDOR (electron nuclear double resonance) spectra have been recorded for the NO-ferrous center of NDO bound with the substrates d(8)-naphthalene, d(2)-naphthalene, d(8)-toluene, d(3)-toluene, and d(6)-benzene; samples were prepared in a D(2)O buffer to test for solvent-derived ligands; spectra were collected for enzymes with the Rieske diiron center in both its oxidized and reduced states. A sharp quartet ENDOR pattern from a nearby deuteron of the substrate in a major binding geometry (denoted as A) was detected for all perdeuterated substrates. Examination of the sample prepared with 1,4-di-deutero-naphthalene shows that the signal arises from D1. Analysis of two-dimensional (2-D) orientation-selective ENDOR patterns collected for this sample defined the location of the D1 deuteron, with respect to the g-frame of the iron center and the orientation of the C-D1 bond. Consideration of the orientations of naphthalene that are permitted within the constraints of these results, as supported by a novel approach to simulations of orientation-selective, 2-D ENDOR patterns for the perdeuterated naphthalene sample, which summed contributions from D1/D2/D8, disclose the geometry of the naphthalene and the Fe-NO fragment. The two deuterons of the reactive carbons, D1 and D2, are closest to the Fe atom (r(Fe)(-)(D1) approximately 4.3 A, r(Fe)(-)(D2) approximately 5.0 A), whereas D8 is farther away (r(Fe)(-)(D8) approximately 5.3 A). Perhaps more instructive, D1-N and D2-N distances to the O(2) surrogate, NO, are approximately 2.4 and approximately 3.3 A, respectively, whereas the D8-N distance is approximately 3.7 A. The data show that benzene and the aromatic ring of toluene also sit within the substrate-binding pocket adjacent to the mononuclear Fe atom. These rings occupy a position similar to that of the "proximal" ring of naphthalene, with the closest ring deuteron being located at a distance of approximately 4.3-4.4 A from the Fe atom and with the Fe-D vector being slightly off the Fe-N(O) direction. In particular, comparison of the data for d(8)-toluene and methyl-d(3)-toluene shows that the methyl group of toluene points away from the Fe atom, despite observations that the oxidation of toluene occurs at the methyl group during catalysis. The Rieske cluster is reduced during both steady-state and single-turnover catalysis; therefore, the effect of its oxidation state on the geometry of substrate binding was examined. The spectra from the NDO-naphthalene complex also revealed a second binding conformation (denoted as B), in which the substrate is located approximately 0.5 A farther from the Fe atom. The relative populations of A- and B-sites are allosterically changed when the Rieske cluster is reduced. ENDOR of exchangeable protons shows that the water/hydroxide of Fe-NDO is retained upon binding NO.     

Substrate binding modulates the reduction potential of DNA photolyase

The reduction potential of the (FADH-/FADH*) couple in DNA photolyase was measured, and the value was found to be significantly higher than the values estimated in the literature. In the absence of substrate, the enzyme has a reduction potential of 16 +/- 6 mV vs NHE. In the presence of excess substrate the reduction potential increases to 81 +/- 8 mV vs NHE. The increase in reduction potential has physiological relevance since it gives the catalytic state greater resistance to oxidation. This is the first measurement of a reduction potential for this class of DNA-repair enzymes and the larger family of blue-light photoreceptors.     

Substrate binding in catechol oxidase activity: biomimetic approach

A series of dicopper(II) complexes have been investigated as model systems for the catechol oxidase active site enzyme, regarding the binding of catechol substrate in the first step of the catalytic cycle. The [Cu(2)(L(R))(mu-OH)](ClO(4))(2) and [Cu(2)(L(R))(H(2)O)(2)](ClO(4))(3) complexes are based on the L(R) ligands (2,6-bis[(bis(2-pyridylmethyl)amino)methyl]-4-R-substituted phenol) with -R = -OCH(3), -CH(3), or -F. Binding studies of diphenol substrates were investigated using UV-vis and EPR spectroscopy, electrochemistry, and (19)F NMR (fluorinated derivatives). All the complexes are able to bind two ortho-diphenol substrates (tetrachlorocatechol and 3,5-di-tert-butylcatechol). Two successive fixation steps, respectively fast and slower, were evidenced for the mu-OH complexes (the bis(aqua) complexes are inactive in catalysis) by stopped-flow measurement and (19)F NMR. From the mu-OH species, the 1:1 complex/substrate adduct is the catalytically active form. In relation with the substrate specificity observed in the enzyme, different substrate/inhibitor combinations were also examined. These studies enabled us to propose that ortho-diphenol binds monodentately one copper(II) center with the concomitant cleavage of the OH bridge. This hydroxo ligand appears to be a key factor to achieve the complete deprotonation of the catechol, leading to a bridging catecholate.     

Substrate binding and activation via pendant hydrogen-bonding groups as an approach to biomimetic homogeneous catalysis

In a biomimetic approach to organometallic catalysis, pendant hydrogen-bonding groups are shown to influence the chemistry of ligand binding and activation in an iridium complex. Such groups can bind a substrate by hydrogen bonding and so offer the possibility of a biomimetic approach to catalysis where binding is controlled via molecular recognition. Because catalyst design in this area may be challenging, combinatorial and rapid screening methods may be needed to assay potential catalysts and initial progress on developing these methods for hydrosilation of alkenes and imines is described. Catalysis of aldehyde imination and the origin of pK_a changes of bound H₂ are discussed.     

alpha-bungarotoxin binding sites (acetylcholine receptors) in denervated mammalian sarcolemma

The nonsynaptic sarcolemma of denervated skeletal muscle of rat shows an abundance of approximately 15 nm intramembranous particles on the P face. These particles are either singly distributed or are in clusters, and they are essentialy lacking from the comparable freeze-fractures of the innervated sarcolemma. Autoradiographic studies using 125I-alpha-bungarotoxin (BGT) on 1 mu-thick sections, and freeze-etch studies using ferritin-alpha-BGT conjugates on membrane fractions, show that the distribution of the label corresponds to the distribution of the 15-nm particles in the nonsynaptic sarcolemma. On the basis of these results and existing physiologic and biochemical data, it is suggested that the 15-nm intramembranous particles are components of the alpha-BGT binding sites, ie, acetylcholine (Ach) receptors, in the nonsynaptic sarcolemma of denervated muscle and that the two types of distributions represent two spatial manifestations of Ach receptor molecules. The significance of these findings in relation to synapse formation in denervated muscle is discussed.     

Substrate binding and sequence preference of the proteasome revealed by active-site-directed affinity probes

Background: The proteasome is a multicatalytic protease complex responsible for most cytosolic protein breakdown. The complex has several distinct proteolytic activities that are defined by the preference of each for the carboxyterminal (P1) amino acid residue. Although mutational studies in yeast have begun to define substrate specificities of individual catalytically active β subunits, little is known about the principles that govern substrate hydrolysis by the proteasome.Results: A series of tripeptide and tetrapeptide vinyl sulfones were used to study substrate binding and specificity of the proteasome. Removal of the aromatic amino-terminal cap of the potent tripeptide vinyl sulfone proteasome inhibitor 4-hydroxy-3-iodo-2-nitrophenyl-leucinyl-leucinyl-leucine vinyl sulfone resulted in the complete loss of binding and inhibition. Addition of a fourth amino acid (P4) to the tri-leucine core sequence fully restored inhibitory potency. 1251-labeled peptide vinyl sulfones were also used to examine inhibitor binding and to determine the correlation of subunit modification with inhibition of peptidase activity. Changing the amino acid in the P4 position resulted in dramatically different profiles of β-subunit modification.Conclusions: The P4 position, distal to the site of hydrolysis, is important in defining substrate processing by the proteasome. We observed direct correlations between subunit modification and inhibition of distinct proteolytic activities, allowing the assignment of activities to individual β subunits. The ability of tetrapeptides, but not tripeptide vinyl sulfones, to act as substrates for the proteasome suggests there could be a minimal length requirement for hydrolysis by the proteasome. These studies indicate that it is possible to generate inhibitors that are largely specific for individual β subunits of the proteasome by modulation of the P4 and carboxy-terminal vinyl sulfone moieties.     

Site-directed conjugation of "clicked" glycopolymers to form glycoprotein mimics: binding to mammalian lectin and induction of immunological function

Synthesis of well-defined neoglycopolymer-protein biohybrid materials and a preliminary study focused on their ability of binding mammalian lectins and inducing immunological function is reported. Crucial intermediates for their preparation are well-defined maleimide-terminated neoglycopolymers (M(n) = 8-30 kDa; M(w)/M(n) = 1.20-1.28) presenting multiple copies of mannose epitope units, obtained by combination of transition-metal-mediated living radical polymerization (TMM LRP) and Huisgen [2+3] cycloaddition. Bovine serum albumin (BSA) was employed as single thiol-containing model protein, and the resulting bioconjugates were purified following two independent protocols and characterized by circular dichroism (CD) spectroscopy, SDS PAGE, and SEC HPLC. The versatility of the synthetic strategy presented in this work was demonstrated by preparing a small library of conjugating glycopolymers that only differ from each other for their relative epitope density were prepared by coclicking of appropriate mixtures of mannopyranoside and galactopyranoside azides to the same polyalkyne scaffold intermediate. Surface plasmon resonance binding studies carried out using recombinant rat mannose-binding lectin (MBL) showed clear and dose-dependent MBL binding to glycopolymer-conjugated BSA. In addition, enzyme-linked immunosorbent assay (ELISA) revealed that the neoglycopolymer-protein materials described in this work possess significantly enhanced capacity to activate complement via the lectin pathway when compared with native unmodified BSA.     

Eicosatetraenehydroxamates: inhibitors of 5-lipoxygenase

The syntheses of 5-hydroxamyl and 5-hydroxamylmethyl-6,8,11,14,-eicosatetraenoic acids ($\text{3}$ and $\text{4}$), which possess potent 5-lipoxygenase inhibitory activity, are described.     

中孔分子筛SBA-15作为液相色谱固定相以及在巯基化合物分离中的应用

采用共表面活性剂法合成了孔道结构高度有序、孔径较大且粒径均匀的SBA－15颗粒，并在此基础上研究了其作为毛细管液相色谱柱的填料基体的特性。在SBA－15材料上进行C18官能团化前后，分别对4种巯基化合物即半胱氨酸、谷胱甘肽、多巴胺和6－巯基嘌呤进行了分离分析。     

Substrate turnover and inhibitor binding as selection parameters in directed evolution of blood coagulation factor Xa

A library of blood coagulation factor Xa (FXa)-trypsin hybrid proteases was generated and displayed on phage for selection of derivatives with the domain "architecture" of trypsin and the specificity of FXa. Selection based on binding to soybean trypsin inhibitor only provided enzymatically inactive derivatives, due to a specific mutation of serine 195 of the catalytic triad to a glycine, revealing a significant selection pressure for proteolytic inactive derivatives. By including a FXa peptide substrate in the selection mixture, the majority of the clones had retained serine at position 195 and were enzymatically active after selection. Further, with the inclusion of bovine pancreatic trypsin inhibitor, in addition to the peptide substrate, the selected clones also retained FXa specificity after selection. This demonstrates that affinity selection combined with appropriate deselection provides a simple strategy for selection of enzyme derivatives that catalyse a specific reaction.     

Defining CYP3A4 structural responses to substrate binding. Raman spectroscopic studies of a nanodisc-incorporated mammalian cytochrome P450

Resonance Raman (RR) spectroscopy is used to help define active site structural responses of nanodisc-incorporated CYP3A4 to the binding of three substrates: bromocriptine (BC), erythromycin (ERY), and testosterone (TST). We demonstrate that nanodisc-incorporated assemblies reveal much more well-defined active site RR spectroscopic responses as compared to those normally obtained with the conventional, detergent-stabilized, sampling strategies. While ERY and BC are known to bind to CYP3A4 with a 1:1 stoichiometry, only the BC induces a substantial conversion from low- to high-spin state, as clearly manifested in the RR spectra acquired herein. The third substrate, TST, displays significant homotropic interactions within CYP3A4, the active site binding up to 3 molecules of this substrate, with the functional properties varying in response to binding of individual substrate molecules. While such behavior seemingly suggests the possibility that each substrate binding event induces functionally important heme structural changes, up to this time spectroscopic evidence for such structural changes has not been available. The current RR spectroscopic studies show clearly that accommodation of different size substrates, and different loading of TST, do not significantly affect the structure of the substrate-bound ferric heme. However, it is here demonstrated that the nature and number of bound substrates do have an extraordinary influence on the conformation of bound exogenous ligands, such as CO or dioxygen and its reduced forms, implying an effective mechanism whereby substrate structure can impact reactivity of intermediates so as to influence function, as reflected in the diverse reactivity of this drug metabolizing cytochrome.     

Redox inactivation of human 15-lipoxygenase by marine-derived meroditerpenes and synthetic chromanes: archetypes for a unique class of selective and recyclable inhibitors

The selective inhibition of human 15-lipoxygenase (15-hLO) could serve as a promising therapeutic target for the prevention of atherosclerosis. A screening of marine sponges revealed that crude extracts of Psammocinia sp. exhibited potent 15-hLO inhibitory activity. Bioassay-guided fractionation led to the isolation of chromarols A-E (8-12) as potent and selective inhibitors of 15-hLO. An additional 22 structurally related compounds, including meroditerpenes from the same Psammocinia sp. (3, 4, 13-16) and our pure compound repository (17, 18), commercially available tocopherols (19-24), and synthetic chromanes (25-32), were evaluated for their ability to inhibit human lipoxygenases. The 6-hydroxychromane moiety found in chromarols A-D was identified as essential for the selective redox inhibition of 15-hLO. Furthermore, the oxidized form of the 6-hydroxychromane could be reduced by ascorbate, suggesting a potential regeneration pathway for these inhibitors in the body. This pharmacophore represents a promising paradigm for the development of a unique class of recyclable 15-hLO redox inhibitors for the treatment of atherosclerosis.