Rational engineering of a fluorescein-binding anticalin for improved ligand affinity

The anticalin FluA is an artificial lipocalin with novelspecificity for the fluorescein group, which was engineered from an insect bilin-binding protein by targeted random mutagenesis and selection. Based on the crystal structure of FluA, an attempt was made to improve the complementarity of its ligand pocket to fluorescein by rational protein design. Several side chains participating in sub-optimal interactions with the ligand were identified and replaced by residues that promised a better steric fit. As a result, the substitution of Ala45 by Ile and of Ser114 by Thr or Arg led to a tight affinity of ca. 1 nM, which is approximately 30-fold better than that of the parental anticalin. Similar to the original FluA, the improved version shows almost complete quenching of the bound ligand fluorescence. Interestingly, the quenching effect was significantly reduced when Trp129 was replaced by Tyr, thus supporting the previously postulated role of this residue, which closely packs against the bound ligand, for efficient electron transfer to the excited fluorescein. Circular dichroism spectra revealed that all variants investigated had retained the lipocalin fold. Corresponding thermal unfolding experiments confirmed similar folding stabilities, with melting temperatures ranging from 52.9 to 60.5 degrees C (i.e., for the high-affinity variant).     

Exposure and electronic interaction of tyrosine and tryptophan residues in human apolipoprotein A-IV

We have investigated the exposure and electronic interaction of tyrosine and tryptophan residues in human apolipoprotein A-IV (apo A-IV). Differential absorption spectroscopy and chemical titration demonstrated that human apo A-IV contains six tyrosine residues, four of which are buried in the hydrophobic interior of the protein and two of which are exposed on the protein surface. Denaturation of the protein by guanidinium chloride caused progressive exposure of the buried tyrosines. The fluorescence emission spectra of apo A-IV were characterized by a blue-shifted tryptophan emission with a low relative quantum yield of 0.37 and a tyrosine emission with a relative quantum yield of 0.62. Fluorescence quenching studies demonstrated a low fractional exposure of tryptophan in the native state. Denaturation of apo A-IV was accompanied by an increase in the relative quantum yield which peaked at the denaturation midpoint. Fluorescence excitation techniques demonstrated energy transfer from tyrosine residues with a transfer efficiency of 0.40 in the native state; the efficiency was conformation dependent and decreased with protein unfolding. Fluorescence studies of tetranitromethane-modified apo A-IV suggested that a significant fraction of energy transfer proceeds from the exposed tyrosine residues. These data demonstrate the existence of intramolecular fluorescence energy transfer and tryptophan quenching in human apolipoprotein A-IV and suggest that the amino terminus of this protein is situated in a hydrophobic domain within energy-transfer range of nonvicinal tyrosine residues.     

M-DNA: A novel metal ion complex of DNA studied by fluorescence techniques

M-DNA, a complex formed in solution between divalent metal ions (M) and duplex DNA, has been studied extensively using fluorescence quenching. This review examines the methods used to examine the formation of M-DNA, and its ability to serve as a pathway for electron transfer between donor and acceptor chromaphores. A mass action model for M-DNA formation is presented based upon the results of fluorescence quenching studies using fluorescein/QSY-7 labeled duplexes. From the mass action analysis, it was determined that approximately 1.4 protons are released per base pair, with k(eq) on the order of 10(-8), indicative of a strong interaction. As resonance energy transfer is shown to be unlikely over the distances involved in this work, the observed quenching in M-DNA is discussed in terms of an electron hopping mechanism for electron transfer, with k(hop)=2.5 x 10(11)s(-1).     

A temperature‐dependent conformational change of NADH oxidase from Thermus thermophilus HB8

Using molecular dynamics simulations and steady‐state fluorescence spectroscopy, we have identified a conformational change in the active site of a thermophilic flavoenzyme, NADH oxidase from Thermus thermophilus HB8 (NOX). The enzyme's far‐UV circular dichroism spectrum, intrinsic tryptophan fluorescence, and apparent molecular weight measured by dynamic light scattering varied little between 25 and 75°C. However, the fluorescence of the tightly bound FAD cofactor increased approximately fourfold over this temperature range. This effect appears not to be due to aggregation, unfolding, cofactor dissociation, or changes in quaternary structure. We therefore attribute the change in flavin fluorescence to a temperature‐dependent conformational change involving the NOX active site. Molecular dynamics simulations and the effects of mutating aromatic residues near the flavin suggest that the change in fluorescence results from a decrease in quenching by electron transfer from tyrosine 137 to the flavin. Proteins 2012. © 2011 Wiley Periodicals, Inc.     

A Fluorometric Assay for DNA Cleavage Reactions Characterized with BamHI Restriction Endonuclease

Fluorescently labeled oligonucleotides and DNA fragments have promise in nucleic acid research with applications that include DNA hybridization, automated DNA sequencing, fluorescence anisotropy, and resonance energy transfer studies. Past concerns with fluorescent-labeled DNA arose from interactions between fluorophores and DNA that result in quenched fluorescence. This quenching phenomenon is most problematic in fluorescence resonance energy transfer studies because quenching of the donor fluorescence could result from either resonance energy transfer or nontransfer effects. In the present study, relief of nontransfer quenching of a 14-mer fluorescein 5-isothiocyanate (FITC)-labeled oligonucleotide containing the BamHI restriction site was characterized with both steady-state and time-resolved fluorescence techniques. The FITC-labeled single strand was best fit by a triexponential decay with lifetimes of 0.5, 2.7, and 4.2 ns. The 4.2-ns component was found to contribute more than 80% of the total steady-state intensity. Upon annealing with an unmodified complementary strand, the contribution from the 4.2-ns component was significantly decreased, resulting in twofold quenching of total fluorescence. We reasoned that this quenching phenomenon should be a reversible process and could be employed to study strand separation processes in molecular biology. Hence, cleavage of the fluorescently labeled substrate was examined using DNase I and BamHI restriction endonuclease. Our results show that the quenched fluorescence is totally recovered upon cleavage (compared to that of the single strand). The extent of cleavage measured by fluorescence was confirmed by nondenaturing polyacrylamide gel electrophoresis analysis. We believe this fluorescence "dequenching" technique may be used to quantify the kinetics of other DNA strand separation and cleavage processes in molecular biology.     

Physical studies of tyrosine and tryptophan residues in mammalian A1 heterogeneous nuclear ribonucleoprotein. Support for a segmented structure.

The mammalian heterogeneous ribonucleoprotein (hnRNP) A1 and its constituent N-terminal domain, termed UP1, have been studied by steady-state and dynamic fluorimetry, as well as phosphorescence and optically detected magnetic resonance (ODMR) spectroscopy at cryogenic temperatures. The results of these diverse techniques coincide in assigning the site of the single tryptophan residue of A1, located in the UP1 domain, to a partially solvent-exposed site distal to the protein's nucleic acid binding surface. In contrast, tyrosine fluorescence is significantly perturbed when either protein associates with single-stranded polynucleotides. Tyr to Trp energy transfer at the singlet level is found for both UP1 and A1 proteins. Single-stranded polynucleotide binding induces a quenching of their intrinsic fluorescence emission, which can be attributed to a significant reduction (greater than 50%) of the Tyr contribution, while Trp emission is only quenched by approximately 15%. Tyrosine quenching effects of similar magnitude are seen upon polynucleotide binding by either UP1 (1 Trp, 4 Tyr) or A1 (1 Trp, 12 Tyr), strongly suggesting that Tyr residues in both the N-terminal and C-terminal domain of A1 are involved in the binding process. Tyr phosphorescence emission was strongly quenched in the complexes of UP1 with various polynucleotides, and was attributed to triplet state energy transfer to nucleic acid bases located in the close vicinity of the fluorophore. These results are consistent with stacking of the tyrosine residues with the nucleic acid bases. While the UP1 Tyr phosphorescence lifetime is drastically shortened in the polynucleotide complex, no change of phosphorescence emission maximum, phosphorescence decay lifetime or ODMR transition frequencies were observed for the single Trp residue. The results of dynamic anisotropy measurements of the Trp fluorescence have been interpreted as indicative of significant internal flexibility in both UP1 and A1, suggesting a flexible linkage connecting the two sub-domains in UP1. Theoretical calculations based on amino acid sequence for chain flexibility and other secondary structural parameters are consistent with this observation, and suggest that flexible linkages between sub-domains may exist in other RNA binding proteins. While the dynamic anisotropy data are consistent with simultaneous binding of both the C-terminal and the N-terminal domains to the nucleic acid lattice, no evidence for simultaneous binding of both UP1 sub-domains was found.     

Spectroscopic observations of ferric enterobactin transport

We characterized the uptake of ferric enterobactin (FeEnt), the native Escherichia coli ferric siderophore, through its cognate outer membrane receptor protein, FepA, using a site-directed fluorescence methodology. The experiments first defined locations in FepA that were accessible to covalent modification with fluorescein maleimide (FM) in vivo; among 10 sites that we tested by substituting single Cys residues, FM labeled W101C, S271C, F329C, and S397C, and all these exist within surface-exposed loops of the outer membrane protein. FeEnt normally adsorbed to the fluoresceinated S271C and S397C mutant FepA proteins in vivo, which we observed as quenching of fluorescence intensity, but the ferric siderophore did not bind to the FM-modified derivatives of W101C or F329C. These in vivo fluorescence determinations showed, for the first time, consistency with radioisotopic measurements of the affinity of the FeEnt-FepA interaction; K(d) was 0.2 nm by both methods. Analysis of the FepA mutants with AlexaFluor(680), a fluorescein derivative with red-shifted absorption and emission spectra that do not overlap the absorbance spectrum of FeEnt, refuted the possibility that the fluorescence quenching resulted from resonance energy transfer. These and other data instead indicated that the quenching originated from changes in the environment of the fluor as a result of loop conformational changes during ligand binding and transport. We used the fluorescence system to monitor FeEnt uptake by live bacteria and determined its dependence on ligand concentration, temperature, pH, and carbon sources and its susceptibility to inhibition by the metabolic poisons. Unlike cyanocobalamin transport through the outer membrane, FeEnt uptake was sensitive to inhibitors of electron transport and phosphorylation, in addition to its sensitivity to proton motive force depletion.     

Flavin fluorescence dynamics and photoinduced electron transfer in Escherichia coli glutathione reductase.

Time-resolved polarized flavin fluorescence was used to study the active site dynamics of Escherichia coli glutathione reductase (GR). Special consideration was given to the role of Tyr177, which blocks the access to the NADPH binding-site in the crystal structure of the enzyme. By comparing wild-type GR with the mutant enzymes Y177F and Y177G, a fluorescence lifetime of 7 ps that accounts for approximately 90% of the fluorescence decay could be attributed to quenching by Y177. Based on the temperature invariance for this lifetime, and the very high quenching rate, electron transfer from Y177 to the light-excited isoalloxazine part of flavin adenine dinucleotide (FAD) is proposed as the mechanism of flavin fluorescence quenching. Contrary to the mutant enzymes, wild-type GR shows a rapid fluorescence depolarization. This depolarization process is likely to originate from a transient charge transfer interaction between Y177 and the light-excited FAD, and not from internal mobility of the flavin, as has previously been proposed. Based on the fluorescence lifetime distributions, the mutants Y177F and Y177G have a more flexible protein structure than wild-type GR: in the range of 223 K to 277 K in 80% glycerol, both tyrosine mutants mimic the closely related enzyme dihydrolipoyl dehydrogenase. The fluorescence intensity decays of the GR enzymes can only be explained by the existence of multiple quenching sites in the protein. Although structural fluctuations are likely to contribute to the nonexponential decay and the probability of quenching by a specific site, the concept of conformational substates need not be invoked to explain the heterogeneous fluorescence dynamics.     

Local structure in a tryptic fragment of performic acid oxidized ribonuclease A corresponding to a proposed polypeptide chain-folding initiation site detected by tyrosine fluorescence lifetime and proton magnetic resonance measurements

The effects of proline and X-Pro peptide bond conformations on the fluorescence properties of tyrosine in peptides corresponding to parts of a proposed chain-folding initiation site in bovine pancreatic ribonuclease A are examined by time-resolved and steady-state fluorescence spectroscopy. In peptides with Tyr-Pro sequences, the conformational constraints of proline on a preceding residue result in significant fluorescence quenching for both trans and cis peptide bond conformations. Small peptides containing Pro-Tyr sequences, on the other hand, do not exhibit fluorescence quenching compared to Ac-Tyr-NHMe. Studies of fluorescence decay in the tryptic fragment of performic acid oxidized ribonuclease corresponding to residues 105-124 (i.e., O-T-16) demonstrate the presence of at least two environments of the single tyrosine chromophore (in the sequence Asn113-Pro114-Tyr115). In these two (ensemble-averaged) environments, tyrosine has shorter and longer lifetimes, respectively, than in Ac-Tyr-NHMe. The fluorescence heterogeneity in O-T-16 does not correlate with X-Pro cis/trans conformational heterogeneity that can be detected by nuclear magnetic resonance (NMR) spectroscopy. Instead, the fluorescence heterogeneity in O-T-16 arises from the presence of multiple conformations with the same X-Pro peptide bond conformations which interconvert rapidly on the 1H NMR time scale (tau much less than 1 ms) but are distinguishable on the fluorescence lifetime time scale (tau greater than or equal to 1 ns). From comparisons with the tyrosine fluorescence decay of smaller synthetic peptides, it is concluded that the long-lifetime tyrosine fluorescence component of O-T-16 arises from interactions involving residues outside the Asn113-Pro114-Tyr115-Val116-Pro117 sequence, which either stabilize particular local conformations in the vicinity of Tyr115 or act directly to protect Tyr115 from efficient fluorescence quenching. The short-lifetime component of O-T-16 is also observed for the pentapeptide Ac-Asn-Pro-Tyr-Val-Pro-NHMe. The data provide evidence for a nonrandom polypeptide conformation of O-T-16 under conditions of solvent pH and temperature at which the complete disulfide-intact ribonuclease molecule is fully folded. Implications of this work for the interpretation of fluorescence-detected unfolding experiments are discussed.     

In vitro study on binding interaction of quinapril with bovine serum albumin (BSA) using multi-spectroscopic and molecular docking methods

The binding interaction between quinapril (QNPL) and bovine serum albumin (BSA) in vitro has been investigated using UV absorption spectroscopy, steady-state fluorescence spectroscopic, synchronous fluorescence spectroscopy, 3D fluorescence spectroscopy, Fourier transform infrared spectroscopy, circular dichroism, and molecular docking methods for obtaining the binding information of QNPL with BSA. The experimental results confirm that the quenching mechanism of the intrinsic fluorescence of BSA induced by QNPL is static quenching based on the decrease in the quenching constants of BSA in the presence of QNPL with the increase in temperature and the quenching rates of BSA larger than 10¹⁰ L mol^?1 s^?1, indicating forming QNPL–BSA complex through the intermolecular binding interaction. The binding constant for the QNPL–BSA complex is in the order of 10⁵ M^?1, indicating there is stronger binding interaction of QNPL with BSA. The analysis of thermodynamic parameters together with molecular docking study reveal that the main binding forces in the binding process of QNPL with BSA are van der Waal’s forces and hydrogen bonding interaction. And, the binding interaction of BSA with QNPL is an enthalpy-driven process. Based on Förster resonance energy transfer, the binding distance between QNPL and BSA is calculated to be 2.76 nm. The results of the competitive binding experiments and molecular docking confirm that QNPL binds to sub-domain IIA (site I) of BSA. It is confirmed there is a slight change in the conformation of BSA after binding QNPL, but BSA still retains its secondary structure α-helicity.     

Influence of spectral heterogeneity of prodan and laurdan solutions on the transfer of electronic energy to octadecyl rhodamine B

Fluorescence quenching and resonance energy transfer have been studied by steady-state fluorescence spectroscopy. The experimental and theoretical values for the rate constants of the electronic energy transfer (kET) and critical radius (R0) were determined for prodan and laurdan as donors and octadecyl rhodamine B as acceptor. The spectroscopic data show, that prodan and laurdan in solution create an inhomogeneous spectroscopic medium in which multi-channel luminescence phenomena take place. This finding indicated that the modified form of the Stern-Volmer relation should be used for analyzing fluorescence quenching data. Results of performed studies point out, that dipole-dipole interaction is responsible for the resonance energy transfer from prodan and laurdan to octadecyl rhodamine B. The relative quenching efficiencies of both dyes depend on polarity of the medium and are higher for more polar solvent (AcN).     

Crystallographic analysis of an "anticalin" with tailored specificity for fluorescein reveals high structural plasticity of the lipocalin loop region

The artificial lipocalin FluA with novel specificity toward fluorescein was derived via combinatorial engineering from the bilin-binding protein, BBP by exchange of 16 amino acids in the ligand pocket. Here, we describe the crystal structure of FluA at 2.0 A resolution in the space group P2(1) with two protein-ligand complexes in the asymmetric unit. In both molecules, the characteristic beta-barrel architecture with the attached alpha-helix is well preserved. In contrast, the four loops at one end of the beta-barrel that form the entrance to the binding site exhibit large conformational deviations from the wild-type protein, which can be attributed to the sidechain replacements. Specificity for the new ligand is furnished by hydrophobic packing, charged sidechain environment, and hydrogen bonds with its hydroxyl groups. Unexpectedly, fluorescein is bound in a much deeper cavity than biliverdin IX(gamma) in the natural lipocalin. Triggered by the substituted residues, unmutated sidechains at the bottom of the binding site adopt conformations that are quite different from those observed in the BBP, illustrating that not only the loop region but also the hydrophobic interior of the beta-barrel can be reshaped for molecular recognition. Particularly, Trp 129 participates in a tight stacking interaction with the xanthenolone moiety, which may explain the ultrafast electron transfer that occurs on light excitation of the bound fluorescein. These structural findings support our concept of using lipocalins as a scaffold for the engineering of so-called "anticalins" directed against prescribed targets as an alternative to recombinant antibody fragments.     

Bifluorophoric molecules as fluorescent beacons for antibody-antigen binding

The quenching of fluorescence (up to 98%) by anti-fluorescein antibodies is well documented in the literature. Here we report a system where, instead of quenching, bifluorophoric molecules are designed to increase in fluorescence upon binding by an anti-fluorescein antibody. Bifluorophoric molecules are made of fluorescein (F) linked to tetramethylrhodamine (T) via varying numbers of methylene units, denoted as F-(CH(2))(n)-T. These F-(CH(2))(n)-T conjugates are almost nonfluorescent when free in solution due to intramolecular dimerization and stacking. Upon binding to an anti-fluorescein antibody, however, up to 110-fold increase in fluorescence was observed from the rhodamine moiety. This increase is believed to result from intramolecular dimer dissociation that dequenches the rhodamine fluorescence. Fluorescein fluorescence, on the other hand, remains quenched due to binding and intramolecular resonance energy transfer. Moreover, the excitation wavelength was at the absorption maxima of fluorescein, giving a Stoke's shift of about 90 nm. This system couples directly molecular recognition with a concurrent increase in fluorescence emission, obviating wash and incubation steps required by most assays. It is an important molecular reporter system for developing homogeneous assays.     

Visualization of epidermal growth factor (EGF) receptor aggregation in plasma membranes by fluorescence resonance energy transfer. Correlation of receptor activation with aggregation

Fluorescence resonance energy transfer between epidermal growth factor (EGF) molecules, labeled with fluorescent reporter groups, was used as a monitor for EGF receptor-receptor interactions in plasma membranes isolated from human epidermoid A431 cells. Epidermal growth factor molecules labeled at the amino terminus with fluorescein isothiocyanate served as donor molecules in these energy transfer measurements, while EGF molecules labeled with eosin isothiocyanate at the amino terminus served as the energy acceptors. Both of these derivatives were shown to be active in binding to membrane receptors and in the activation of the endogenous receptor/tyrosine kinase activity. We found that membranes in the absence of added metal ion activators showed relatively little energy transfer (approximately 10% donor quenching) between the labeled growth factors. However, divalent metal ion activators of the EGF receptor/tyrosine kinase caused a significant increase in the extent of energy transfer between the labeled EGF molecules. Specifically, in the presence of 20 mM MgCl2, the extent of quenching of the donor fluorescence increased to 25% (from 10% in the absence of metal), while in the presence of 4 mM MnCl2, the extent of energy transfer was increased still further to 40-50%. The addition of an excess of EDTA resulted in the reversal of the observed energy transfer to basal levels. The increased energy transfer in the presence of these divalent cations correlated well with the ability of these metals to stimulate the EGF receptor/tyrosine kinase activity. However, the extent of receptor-receptor interactions measured by energy transfer was independent of receptor autophosphorylation. Overall, these results suggest that conditions under which the EGF receptor is primed to be active as a tyrosine kinase, within a lipid milieu, result in an increased aggregation of the receptor.     

Polyene fatty acid interactions with recombinant intestinal and liver fatty acid-binding proteins. Spectroscopic studies

Binding and proximity relationships of fatty acids with recombinant rat liver fatty acid-binding protein (L-FABP) and intestinal fatty acid-binding protein (I-FABP) were studied with absorption and fluorescence spectroscopy. Protein aromatic amino acids were examined in the absence and presence of bound fatty acid. Second derivative absorbance spectroscopy of the apo- and holoproteins suggested that fatty acid binding altered the conformation of L-FABP, but not of I-FABP. Fatty acid binding also blocked the accessibility of L-FABP tyrosine and I-FABP tryptophan to Stern-Volmer quenching by acrylamide, indicating that these amino acids were present in the fatty acid-binding pocket. Forster energy transfer from I-FABP tryptophan to bound cis-parinaric acid resulted in quenching of tryptophan lifetime and appearance of sensitized lifetime of bound cis-parinaric acid. The calculated donor-acceptor distances were 16.9 +/- 0.6 and 19.2 +/- 0.3 A for I-FABP and L-FABP, respectively. Absorbance spectral shifts and ratios of fluorescence excitation maxima indicated that the parinaric acid microenvironment in the fatty acid-binding site of I-FABP was much less polar than that of L-FABP. Parinaric acids displayed similar rotational correlation time and limiting anisotropy when bound to I-FABP and to L-FABP. These results are consistent with a close proximity of bound fatty acids to the tyrosine and tryptophan residues and with immobilization of the polyene fatty acids in the fatty acid-binding site(s) of L-FABP and I-FABP. The two proteins differ in that only L-FABP has two fatty acid-binding sites and appears to undergo significant conformational change upon fatty acid binding.     

Multi-spectroscopic,thermodynamic and molecular docking studies to investigate the interaction of eplerenone with human serum albumin

The binding of small molecular drugs with human serum albumin (HSA) has a crucial influence on their pharmacokinetics. The binding interaction between the antihypertensive eplerenone (EPL) and HSA was investigated using multi-spectroscopic techniques for the first time. These techniques include ultraviolet-visible (UV-vis) spectroscopy, Fourier-transform infrared (FTIR), native fluorescence spectroscopy, synchronous fluorescence spectroscopy and molecular docking approach. The fluorescence spectroscopic study showed that EPL quenched HSA inherent fluorescence. The mechanism for quenching of HSA by EPL has been determined to be static in nature and confirmed by UV absorption and fluorescence spectroscopy. The modified Stern–Volmer equation was used to estimate the binding constant (K_b) as well as the number of bindings (n). The results indicated that the binding occurs at a single site (K_b = 2.238 × 10³ L mol⁻¹at 298 K). The enthalpy and entropy changes (∆H and ∆S) were 58.061 and 0.258 K J mol⁻¹, respectively, illustrating that the principal intermolecular interactions stabilizing the EPL–HSA system are hydrophobic forces. Synchronous fluorescence spectroscopy revealed that EPL binding to HSA occurred around the tyrosine (Tyr) residue and this agreed with the molecular docking study. The Förster resonance energy transfer (FRET) analysis confirmed the static quenching mechanism. The esterase enzyme activity of HSA was also evaluated showing its decrease in the presence of EPL. Furthermore, docking analysis and site-specific markers experiment revealed that EPL binds with HSA at subdomain IB (site III).     

Long range molecular wire behaviour in a metal complex of DNA

M-DNA is a complex of metal ions such as Zn(2+) with duplex DNA. Previous results showed that the fluorescence of a donor fluorophore was quenched when an acceptor fluorophore was placed at the opposite end of a short M-DNA duplex. In order to investigate further the molecular wire behaviour of M-DNA, 30-mer duplexes were constructed with fluorescein as donor and rhodamine, pyrene and the cyanine dyes, Cy5 and Cy5.5 as acceptors. Good quenching was observed in all cases even though the efficiency of resonance energy transfer was calculated to be < 5%. The distance dependence of quenching was investigated by preparing doubly-labelled duplexes ranging in length from 20 to 1,000 base pairs. Upon formation of M-DNA significant quenching of the fluorescence of the donor fluorophore was observed in duplexes up to 500 base pairs in length. The amount of quenching decreased with increasing length of the duplexes with a shallow distance dependence. The results are consistent with an electron transfer mechanism in which the electron hops between metal centers. This process can occur efficiently over long distances.     

Tyrosine as a redox-active center in electron transfer to ferryl heme in globins

A wide range of organic reductants, including many iron chelators, reduce ferryl myoglobin to its ferric states in exponential time courses whose rate constants display double hyperbolic dependencies on the reductant concentration. This concentration dependence is consistent with a mechanism in which electron transfer to the heme takes place at two independent sites where reductants appear to bind. We propose that the low-affinity site is located close to the heme edge, within the heme pocket; the maximum rate of electron transfer is highly variable depending on the nature of the reductant (0.005 to >10 s(-1)). The other site has higher apparent affinity (K(D) 0.2-50 microM) but a low maximum rate of electron transfer (0.005 to 0.01 s(-1)). By examining native and engineered proteins we have determined that the high-affinity pathway represents a through-protein electron transfer pathway that involves a specific tyrosine residue. The low apparent rate constant for electron transfer from the tyrosine to the heme (approximately 5 A) is accounted for by proposing that electron transfer occurs only in a very poorly populated protonated state of ferryl heme and tyrosine. Hemoglobin shows similar kinetics but only one subunit exhibits double rectangular hyperbolic concentration dependency. The consequence of a high-affinity through-protein electron transfer pathway to the cytotoxicity of ferryl heme is discussed.