Fluorescence of tryptophan residues in firefly luciferases and enzyme--substrate complexes

Quenching of tryptophan fluorescence of Luciola mingrelica (single tryptophan residue, Trp-419) and Photinus pyralis (two tryptophan residues, Trp-417 and Trp-426) luciferases with different quenchers (I-, Cs+, acrylamide) was studied. The conserved Trp-417(419) residue was shown to be not accessible to charged particles, and positively and negatively charged amino acid residues are located in close vicinity to it. We found previously unreported effective energy transfer from this tryptophan to luciferin during the quenching of the tryptophan fluorescence. The distance between the luciferin molecule and Trp-417(419) was calculated: 11-15 and 12-17 A for P. pyralis and L. mingrelica luciferases, respectively. The role of the conserved Trp residue in the catalysis is discussed. ATP and AMP are also quenchers of the tryptophan fluorescence of the luciferases. In this case, an allosteric mechanism of the interaction of Trp-417(419) with an excess of ATP (AMP) is proposed.     

Fluorescent Properties of Firefly Luciferases and Their Complexes with Luciferin

Fluorescence of luciferases from Luciola mingrelica (single tryptophanresidue, Trp-419) and Photinus pyralis (two tryptophan residues, Trp-417,Trp-426) was studied. Analysis of quenching of tryptophan fluorescenceshowed that the tryptophan residue conserved in all luciferases is notaccessible for charged quenchers, which is explained by the presence ofpositively and negatively charged amino acid residues in the close vicinityto it. An effective energy transfer from tryptophan to luciferin wasobserved during quenching of tryptophan fluorescence of both luciferaseswith luciferin. From the data on the energy transfer, the distance betweenthe luciferin molecule and Trp-417 (419) in the luciferin–luciferasecomplex was calculated: 11–15 for P. pyralis and 12–17 for L. mingrelica luciferases. The role of the conserved Trp residuein the catalysis is discussed.     

Interaction of anesthetics with the Rho GTPase regulator Rho GDP dissociation inhibitor

The physiological effects of anesthetics have been ascribed to their interaction with hydrophobic sites within functionally relevant CNS proteins. Studies have shown that volatile anesthetics compete for luciferin binding to the hydrophobic substrate binding site within firefly luciferase and inhibit its activity (Franks, N. P., and Lieb, W. R. (1984) Nature 310, 599-601). To assess whether anesthetics also compete for ligand binding to a mammalian signal transduction protein, we investigated the interaction of the volatile anesthetic, halothane, with the Rho GDP dissociation inhibitor (RhoGDIalpha), which binds the geranylgeranyl moiety of GDP-bound Rho GTPases. Consistent with the existence of a discrete halothane binding site, the intrinsic tryptophan fluorescence of RhoGDIalpha was quenched by halothane (2-bromo-2-chloro-1,1,1-trifluoroethane) in a saturable, concentration-dependent manner. Bromine quenching of tryptophan fluorescence is short-range and W192 and W194 of the RhoGDIalpha are located within the geranylgeranyl binding pocket, suggesting that halothane binds within this region. Supporting this, N-acetyl-geranylgeranyl cysteine reversed tryptophan quenching by halothane. Short chain n-alcohols ( n < 6) also reversed tryptophan quenching, suggesting that RhoGDIalpha may also bind n-alkanols. Consistent with this, E193 was photolabeled by 3-azibutanol. This residue is located in the vicinity of, but outside, the geranylgeranyl chain binding pocket, suggesting that the alcohol binding site is distinct from that occupied by halothane. Supporting this, N-acetyl-geranylgeranyl cysteine enhanced E193 photolabeling by 3-azibutanol. Overall, the results suggest that halothane binds to a site within the geranylgeranyl chain binding pocket of RhoGDIalpha, whereas alcohols bind to a distal site that interacts allosterically with this pocket.     

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.     

The accessibility of the active site and conformation states of the beta 2 subunit of tryptophan synthase studied by fluorescence quenching

The rate of quenching of the fluorescence of pyridoxal 5'-phosphate in the active site of the beta 2 subunit of tryptophan synthase from Escherichia coli was measured to estimate the accessibility of the coenzyme to the small molecules iodide and acrylamide. The alpha subunit and the substrate L-serine substantially reduced the quenching rate. For iodide, the order of decreasing quenching was: Schiff's base of N alpha-acetyl-lysine with pyridoxal 5'-phosphate greater than holo beta 2 subunit greater than holo alpha 2 beta 2 complex approximately equal to holo beta 2 subunit + L-serine greater than holo alpha 2 beta 2 complex + L-serine. The coenzyme in the beta 2 subunit is apparently freely accessible to both iodide and acrylamide (kappa approximately equal to 2 X 10(9) M-1 s-1), but the alpha subunit and L-serine decrease the rate by factors of 2-5. Quenching of the fluorescence of the single tryptophan residue of the beta 2 subunit revealed that the apo and holo forms exist in different states, whereas the alpha subunit stabilizes a third conformation. As the alpha subunit binds to the beta 2 subunit, the tryptophan residue, which is within 2.2 nm of the active site of the beta 2 subunit, probably rotates with respect to the plane of the ring of the coenzyme, such that fluorescence energy transfer from tryptophan to pyridoxal phosphate is greatly reduced. The alpha subunit strongly protects the active-site ligand indole propanol phosphate from quenching with acrylamide, consistent with the active site being deep in a cleft in the protein. Iodide induces dissociation of the holo alpha 2 beta 2 complex [E. W. Miles & M. Moriguchi (1977) J. Biol. Chem. 252, 6594-6599]. The effect of iodide on the fluorescence properties of holo alpha 2 beta 2 complex allows us to estimate an upper limit for the dissociation constant for the alpha 2 beta 2 complex of 10(-8) M, in the absence of iodide.     

Detection, characterization, and quenching of the intrinsic fluorescence of bovine heart cytochrome c oxidase

The intrinsic fluorescence of lauryl maltoside solubilized bovine heart cytochrome c oxidase has been determined to arise from tryptophan residues of the oxidase complex. The magnitude of the fluorescence is approximately 34% of that from n-acetyltryptophanamide (NATA). This level of fluorescence is consistent with an average heme to tryptophan distance of 30 A. The majority of the fluorescent tryptophan residues are in a hydrophobic environment as indicated by the fluorescence emission maximum at 328 nm and the differing effectiveness of the quenching agents: Cs+, I-, and acrylamide. Cesium was ineffective up to a concentration of 0.7 M, whereas quenching by the other surface quenching agent, iodide, was complex. Below 0.2 M, KI was ineffective whereas between 0.2 and 0.7 M 15% of the tryptophan fluorescence was found to be accessible to iodide. This pattern indicates that protein structural changes were induced by iodide and may be related to the chaotropic character of KI. Acrylamide was moderately effective as a quenching agent of the oxidase fluorescence with a Stern-Volmer constant of 2 M-1 compared with acrylamide quenching of NATA and the water-soluble enzyme aldolase having Stern-Volmer constants of 12 M-1 and 0.3 M-1, respectively. There was no effect of cytochrome c on the tryptophan emission intensity from cytochrome c oxidase under conditions where the two proteins form a tight, 1:1 complex, implying that the tryptophan residues near the cytochrome c binding site are already quenched by energy transfer to the homes of the oxidase. The lauryl maltoside concentration used to solubilize the enzyme did not affect the fluorescence of NATA.(ABSTRACT TRUNCATED AT 250 WORDS)     

The tryptophan residues of mitochondrial creatine kinase: roles of Trp-223, Trp-206, and Trp-264 in active-site and quaternary structure formation.

The 5 tryptophan residues of chicken sarcomeric mitochondrial creatine kinase (Mib-CK) were individually replaced by phenylalanine or cysteine using site-directed mutagenesis. The mutant proteins were analyzed by enzyme kinetics, fluorescence spectroscopy, circular dichroism, and conformational stability studies. In the present work, Trp-223 is identified as an active-site residue whose replacement even by phenylalanine resulted in > or = 96% inactivation of the enzyme. Trp-223 is responsible for a strong (18-21%) fluorescence quenching effect occurring upon formation of a transition state-analogue complex (TSAC;Mib-CK.creatine.MgADP.NO3-), and Trp-223 is probably required for the conformational change leading to the TSAC-induced octamer dissociation of Mib-CK. Replacement of Trp-206 by cysteine led to a destabilization of the active-site structure, solvent exposure of Trp-223, and to the dissociation of the Mib-CK dimers into monomers. However, this dimer dissociation was counteracted by TSAC formation or the presence of ADP alone. Trp-264 is shown to be located at the dimer-dimer interfaces within the Mib-CK octamer, being the origin of another strong (25%) fluorescence quenching effect, which was observed upon the TSAC-induced octamer dissociation. Substitution of Trp-264 by cysteine drastically accelerated the TSAC-induced dissociation and destabilized the octameric structure by one-fourth of the total free interaction energy, probably by weakening hydrophobic contacts. The roles of the other 2 tryptophan residues, Trp-213 and Trp-268, could be less well assigned.     

Evidence that inhibitors of anion exchange induce a transmembrane conformational change in band 3

The transport inhibitor, eosin 5-maleimide, reacts specifically at an external site on the membrane-bound domain of the anion exchange protein, Band 3, in the human erythrocyte membrane. The fluorescence of eosin-labeled resealed ghosts or intact cells was found to be resistant to quenching by CsCl, whereas the fluorescence of labeled inside-out vesicles was quenched by about 27% at saturating CsCl concentrations. Since both Cs+ and eosin maleimide were found to be impermeable to the red cell membrane and the vesicles were sealed, these results indicate that after binding of the eosin maleimide at the external transport site of Band 3, the inhibitor becomes exposed to ions on the cytoplasmic surface. The lifetime of the bound eosin maleimide was determined to be 3 ns both in the absence and presence of CsCl, suggesting that quenching is by a static rather than a dynamic (collisional) mechanism. Intrinsic tryptophan fluorescence of erythrocyte membranes was also investigated using anion transport inhibitors which do not appreciably absorb light at 335 nm. Eosin maleimide caused a 25% quenching and 4,4'-dibenzamidodihydrostilbene-2,2'-disulfonate) caused a 7% quenching of tryptophan fluorescence. Covalent labeling of red cells by either eosin maleimide or BIDS (4-benzamido-4'-isothiocyanostilbene-2,2'-disulfonate) caused an increase in the susceptibility of membrane tryptophan fluorescence to quenching by CsCl. The quenching constant was similar to that for the quenching of eosin fluorescence and was unperturbed by the presence of 0.5 M KCl. Neither NaCl nor Na citrate produced a large change in the relative magnitude of the tryptophan emission. The tryptophan residues that can be quenched by CsCl appear to be different from those quenched by eosin or BIDS and are possibly located on the cytoplasmic domain of Band 3. The results suggest that a conformational change in the Band 3 protein accompanies the binding of certain anion transport inhibitors to the external transport site of Band 3 and that the inhibitors become exposed on the cytoplasmic side of the red cell membrane.     

Binding of retinoids and beta-carotene to beta-lactoglobulin. Influence of protein modifications

The binding of retinol, retinyl acetate, retinoic acid and beta-carotene to native, esterified and alkylated beta-lactoglobulin was followed by quenching of tryptophan fluorescence. Three studied retinoids bind to native or modified beta-lactoglobulin in 1:1 molar ratios, with apparent dissociation constants in the range of 10(-8) M. The maximum tryptophan fluorescence quenching of unmodified beta-lactoglobulin by beta-carotene is observed at the ligand/protein ratio of 1:2. Esterification and alkylation of beta-lactoglobulin shift the ratio of beta-carotene/protein to 1:1. In all the cases, except for retinoic acid binding to N-ethyllysyl-BLG, the performed chemical modifications of beta-lactoglobulin enhance protein binding affinity. Measured apparent dissociation constants of beta-carotene complexes with native and modified beta-lactoglobulin are an order of magnitude lower from binding constants of other studied retinoids.     

Distribution of tryptophan groups in molecules of troponin T, troponin I-troponin T complex, and alpha-actinin

The method of fluorescence quenching was used to experimentally determine the distribution of tryptophan residues in molecules of troponin T, troponin T-troponin I complexes, and alpha-actinin. Iodide and cesium ions, and acrylamide were used as quenchers. It was shown that cesium ions decrease the fluorescence intensity of troponin T and its complex with troponin I by the mode of dynamic quenching. For alpha-actinin such a dynamic quencher is anionic iodide. By using the modified Stern-Volmer equation, the quenching was found to be about 90% of total fluorescence intensity for troponin T, approximately 70% for the troponin T-troponin I complexes, and 20% for alpha-actinin. The penetration of cesium ions to tryptophan 206 (tryptophan 204) in the troponin T-troponin I complex is hindered, probably due to the participation of this tryptophan in the formation of bonds between troponin subunits.     

Interaction of lipoprotein lipase and apolipoprotein C-II with sonicated vesicles of 1,2-ditetradecylphosphatidylcholine: comparison of binding constants

The interaction of lipoprotein lipase (LpL) and its activator protein, apolipoprotein C-II (apoC-II), with a nonhydrolyzable phosphatidylcholine, 1,2-ditetradecyl-rac-glycero-3-phosphocholine (C14-ether-PC), was studied by fluorescence spectroscopy. A complex of 320 molecules of C14-ether-PC per LpL was isolated by density gradient ultracentrifugation in KBr. The intrinsic tryptophan fluorescence emission spectrum of LpL was shifted from 336 nm in the absence of lipid to 330 nm in the LpL-lipid complex; the shift was associated with a 40% increase in fluorescence intensity. Addition of C14-ether-PC vesicles to apoC-II caused a 2.5-fold increase in intrinsic tryptophan fluorescence and a shift in emission maximum from 340 to 317 nm. LpL and apoC-II/C14-ether-PC stoichiometries and binding constants were determined by measuring the increase in the intrinsic tryptophan fluorescence as a function of lipid and protein concentrations; for LpL the rate and magnitude of the fluorescence increases were relatively independent of temperature in the range 4-37 degrees C. A stoichiometry of 270 PC per LpL for the LpL-lipid complex compares favorably with the value obtained in the isolated complex. The dissociation constant (Kd) of the complex is 4.3 X 10(-8) M. For apoC-II, the stoichiometry of the complex is 18 PC per apoprotein, and the Kd is 3.0 X 10(-6) M. These data suggest that LpL binds more strongly than apoC-II to phosphatidylcholine interfaces.     

Site-site interaction in the phospholipid activation of D-beta-hydroxybutyrate dehydrogenase

D-beta-Hydroxybutyrate dehydrogenase is a lipid-requiring enzyme with absolute specificity for phosphatidylcholine (PC). The enzyme devoid of lipid, the apodehydrogenase, inserts spontaneously into phospholipid vesicles where it exists as a tetramer. We now find the lipid activation to be limited by the mole fraction of PC in the total phospholipid. These studies suggest that the concentration of the enzyme-PC complex, which is essential for enzymic activity, becomes diffusion limited at lower PC concentration. The lipid activation and the tryptophan fluorescence of purified D-beta-hydroxybutyrate dehydrogenase were studied in the presence of a constant "bilayer background" of approximately 100 nonactivating phospholipid molecules/enzyme monomer. Activation by PC was half-maximal at 20 PC molecules/enzyme monomer. This value was doubled when the amount of "background" phospholipid was doubled. Activation proceeded with positive cooperativity having a Hill coefficient of approximately 2.4. These data indicate interactions between at least three PC-binding sites. The quenching of tryptophan fluorescence by the phospholipid activator, 1-palmitoyl-2-(1-pyrenyl)-decanoyl-PC (2-pyrenyl-PC), gives a saturation curve with half-maximal quenching of 6 quencher molecules/enzyme monomer. This value is equivalent to an apparent phospholipid-protein dissociation constant in the two-dimensional membrane and corresponds to approximately 6 mol % of total phospholipid. In distinct contrast to the phospholipid activation curve, the fluorescence quenching saturation curve was hyperbolic and there was no specificity for PC. The fluorescence quenching by 2-pyrenyl-PC could be diminished by using a several-fold excess of PC or other phospholipids so as to reduce the mole fraction of quencher in the bilayer. It would appear that formation of enzyme-PC complex is a dynamic process consisting of at least two discernible steps: 1) a primary interaction, as measured by tryptophan quenching, which is hyperbolic and not specific for lecithin. This interaction is independent from and precedes 2) phospholipid activation of D-beta-hydroxybutyrate dehydrogenase, which is cooperative in nature and specific for lecithin.     

Fluorescence quenching of Trp-314 of liver alcohol dehydrogenase by oxygen

The quenching of the fluorescence of liver alcohol dehydrogenase (LADH) by molecular oxygen has been studied by both fluorescence lifetime and intensity measurements. This was done in the presence of 1 M acrylamide which selectively quenches the fluorescence of the surface tryptophan residue, Trp-15, thus allowing us to focus on the quenching of the deeply buried tryptophan, Trp-314, by molecular oxygen. Such studies yielded a Stern-Volmer plot of F0/F with a greater slope than the corresponding tau o/tau plot. This indicates that both dynamic and static quenching of Trp-314 occurs. The temperature dependence of the dynamic quenching of LADH by oxygen was also studied at three temperatures, from which we determined the activation enthalpy for the quenching of Trp-314 to be about 10 kcal/mol. The oxygen quenching of a ternary complex of LADH, NAD+ and trifluoroethanol was also studied. The rate constant for dynamic quenching of Trp-314 by oxygen was found to be approximately the same in the ternary complex as that in the unliganded enzyme.     

Fluorescence studies on the role of tryptophan in heterogeneous nuclear ribonucleoprotein particles of HeLa cells.

The 40 S heterogeneous nuclear ribonucleoprotein (hnRNP) particles from HeLa cells reveal tryptophan fluorescence with a bi-exponential decay, indicating that only a few of the 'core' proteins contain tryptophan residues. The presence of tryptophan residues distinguishes hnRNP particles from nucleosomes, with which they otherwise share a number of properties. This difference, however, is not essential for protein-RNA binding, as the fluorescence decay remains unchanged when hnRNP particles are dissociated into protein and RNA. However, the Stern-Volmer quenching constant is doubled upon salt dissociation, i.e. tryptophan residues become more accessible to solvent. Thus tryptophan quenching is a useful parameter for monitoring protein-protein interactions in hnRNP particles.     

Conformation of adenosine deaminase in complexes with inhibitors: application of selective quenching of fluorescence emission

The effect of inhibitors, 1-deazaadenosine (1-dAdo) and erythro-9-(2-hydroxy-3-nonyl)adenine (EHNA), on the conformation of adenosine deaminase was studied using the method of selective quenching of fluorescence emission by acrylamide, I- and Cs+. Both in free adenosine deaminase and in its complexes with the inhibitors, the wavelength maxima and half-width of the emission characterize the environment of fluorescing tryptophan residues in adenosine deaminase as weak polar with limited access to solvent. The formation of complexes with the ground state inhibitors used did not quench or change the main emission characteristics of tryptophan fluorescence in adenosine deaminase. Small blue shifts of emission maxima were observed upon quenching in all three samples. The Stern-Volmer parameters of tryptophan fluorescence quenching by acrylamide were not essentially influenced by complex formation of the enzyme with the inhibitors: in general, the folding of the enzyme molecule in the complexes is not perturbed. On the contrary, the emission quenching by charged heavy ions, I- and Cs+, in the complexes was hindered in comparison with free adenosine deaminase. In the complex with 1-deazaadenosine, the parameters for quenching by both ions evidence the essential worsening of their interaction with tryptophans. In the complex with erythro-9-(2-hydroxy-3-nonyl)adenine, along with the worse quenching by I-, complete prohibition of quenching by Cs+ was observed. These data indicate that the local environments of fluorescing tryptophan residues is substantially distorted compared with free adenosine deaminase, which leads to their screening from charged heavy ions.     

Examination of substrate-induced conformational changes in the Na+/glucose cotransporter

Conformations of the Na+/glucose cotransporter were examined using tryptophan fluorescence and substrates to induce cotransporter conformational changes. Addition of Na+ but not K+ or TMA+ resulted in a saturable quenching of tryptophan fluorescence with a K0.5 for Na+ of 28 mM. In the presence of saturating Na+ concentrations, d-glucose but not l-glucose, fructose, or phlorizin resulted in a partial return of tryptophan fluorescence to approximately 70% of the substrate-free levels. This return of tryptophan fluorescence was a saturable function of d-glucose concentration with a K0.5 of 43 microM. The three conformations were compared with respect to their sensitivity to tryptophan quench reagents. Acrylamide quenching was unaffected by substrates. In contrast, I- quenching decreased 40% in the presence of Na+, while Cs+ quenching increased 64%. Addition of saturating d-glucose concentrations resulted in the return of I- quenching to 90% of the substrate-free values and reduced Cs+ quenching to substrate-free levels. In contrast, phlorizin did not mimic the effect of d-glucose on tryptophan fluorescence. These results are interpreted in terms of a second substrate-induced cotransporter conformational change which based on similar substrate specificities appears directly related to cotransporter-mediated Na+ and d-glucose transport.     

Localization and environment of tryptophans in soluble and membrane-bound states of a pore-forming toxin from Staphylococcus aureus

The location and environment of tryptophans in the soluble and membrane-bound forms of Staphylococcus aureus alpha-toxin were monitored using intrinsic tryptophan fluorescence. Fluorescence quenching of the toxin monomer in solution indicated varying degrees of tryptophan burial within the protein interior. N-Bromosuccinimide readily abolished 80% of the fluorescence in solution. The residual fluorescence of the modified toxin showed a blue-shifted emission maximum, a longer fluorescence lifetime as compared to the unmodified and membrane-bound alpha-toxin, and a 5- to 6-nm red edge excitation shift, all indicating a restricted tryptophan environment and deeply buried tryptophans. In the membrane-bound form, the fluorescence of alpha-toxin was quenched by iodide, indicating a conformational change leading to exposure of some tryptophans. A shorter average lifetime of tryptophans in the membrane-bound alpha-toxin as compared to the native toxin supported the conclusions based on iodide quenching of the membrane-bound toxin. Fluorescence quenching of membrane-bound alpha-toxin using brominated and spin-labeled fatty acids showed no quenching of fluorescence using brominated lipids. However, significant quenching was observed using 5- and 12-doxyl stearic acids. An average depth calculation using the parallax method indicated that the doxyl-quenchable tryptophans are located at an average depth of 10 A from the center of the bilayer close to the membrane interface. This was found to be in striking agreement with the recently described structure of the membrane-bound form of alpha-toxin.     

pH-dependent changes in the tryptophan and porphyrin fluorescence of the apomyoglobin complex with protoporphyrin IX and methemoglobin

The fluorescence of protoporphyrin IX (PPIX) complexed with sperm whale apomyoglobin as well as the tryptophan fluorescence of this complex and of metmyoglobin within the pH range of 3.5-13 was studied. It was shown that an increase in pH from 5.3 to 10.8 does not influence the fluorescence of PPIX in the complex and causes no essential changes in the fluorescence of Trp residues, which occur at more acidic and, correspondingly, alkaline pH values simultaneously with the protein denaturation. This is accompanied by a sharp increase in the quantum yield of tryptophan fluorescence due to dissociation of PPIX from the complex. Similar changes are observed in metMb at pH less than 4.3 and greater than 12 which is concomitant with absorption changes in the Soret band, thus indicating a higher stability of metMb towards the acid and alkaline denaturation as compared to the complex. In both cases, a slight alteration in the shape of the tryptophan fluorescence spectrum is observed, which precedes alkaline denaturation of the Mb molecule and is probably due to changes in the conformation of the N-terminal region caused by the break of the salt bridges stabilizing the native structure of the protein.     

Cucurbitacin delta 23-reductase from the fruit of Cucurbita maxima var. Green Hubbard. Physicochemical and fluorescence properties and enzyme-ligand interactions.

Cucurbitacin delta 23-reductase from Cucurbita maxima var. Green Hubbard fruit displays an apparent Mr of 32,000, a Stokes radius of 263 nm and a diffusion coefficient of 8.93 X 10(-7) cm2 X s-1. The enzyme appears to possess a homogeneous dimeric quaternary structure with a subunit Mr of 15,000. Two tryptophan and fourteen tyrosine residues per dimer were found. Emission spectral properties of the enzyme and fluorescence quenching by iodide indicate the tryptophan residues to be buried within the protein molecule. In the pH range 5-7, where no conformational changes were detected, protonation of a sterically related ionizable group with a pK of approx. 6.0 markedly influenced the fluorescence of the tryptophan residues. Protein fluorescence quenching was employed to determine the dissociation constants for binding of NADPH (Kd 17 microM), NADP+ (Kd 30 microM) and elaterinide (Kd 227 microM). Fluorescence energy transfer between the tryptophan residues and enzyme-bound NADPH was observed.     

The mechanism of ion selectivity of OmpF-porin pores of Escherichia coli

The OmpF porin from the outer membrane of Escherichia coli acts as a lightly cation-selective pore, allowing the diffusion of small cations and cationic molecules, whose Mr are a little larger than the threshold exclusion limit. To ascertain the mechanism of this cation selectivity, we have examined a possible influence of cationic solutes on the fluorescence emission and the circular dichroic spectrum of tryptophan residues of the porin trimer, searching for conformational change(s). The diffusion of cationic solutes was determined with the native and the amidated porins in the presence or the absence of the effector cations. The following results were obtained. (a) Cations, e.g. spermidine, caused fluorescence quenching in the native trimer, with a half-maximum fluorescence quenching at 11-18 microM. A change in the circular dichroic spectrum was also recorded at around 280 nm. (b) The dissociation constant of spermidine to the native trimer was calculated to be 16 microM as determined by the method of equilibrium dialysis. (c) The cation-caused fluorescence quenching was reversed when the carboxyl groups of the trimer were modified by the amidation reaction, though amidation of the trimer resulted in no significant change in the fluorescence intensity. (d) The diffusion rate of N-benzyloxycarbonyl-glycyl-L-prolyl-L-arginine p-nitroanilide through the native and the amidated porins was lowered in the presence and the absence, respectively, of cations. Both the extent of fluorescence quenching in the presence of cation and the rate of cation diffusion were inversely proportional to the number of amidated carboxyl residues. The relative fluorescence quenching of the porin trimer (the amidated versus the native) in the presence of cations was linearly related to the relative solute diffusion via the porin (the amidated versus the native). These results suggested that cations caused a conformational change in the trimer, resulting in an easier diffusion of the solutes. The results suggested further that a limited number of carboxyl groups in the pore interior are involved in the cation selectivity of OmpF-porin pores.