Model for the Porphyrin-DNA Binding Site: ENDOR Investigations of Cu-Porphyrins Binding to DNA

Abstract

Proton ENDOR has been observed from frozen solutions (ca. 38K°) of copper meso-(4-N-tetra-methylpyridyl)porphyrin (CuTMpyP(4)) complexed with Salmon sperm DNA in water and D₂O. Lines from exchangeable protons of the DNA bases have been observed in these ENDOR spectra. Analyses of these ENDOR data show that the separations of these DNA protons from the copper atom are between 3.76 and 3.84 A with angles of 19.5 to 22.5 degrees between the Cu-H vectors and the g_z axis. A distant ENDOR response has also been observed from phosphorous nuclei in the DNA backbone. We estimate that the phosphorous atoms producing this ENDOR signal are 7.5–10 Å from the copper center of the porphyrin. These ENDOR data combined with results from an earlier NMR investigation (1) have been used to construct a computer simulated model of the binding site in which the porphyrin is partially intercalated and extends into the major groove of DNA. The two GC base pairs at this site are slightly inequivalent. For each, the G imino proton and one of the C amino protons are at appropriate positions to account for the ENDOR signals arising from exchangeable protons. It is unlikely that this inequivalence would persist at room temperature where dynamic processes would give an apparently symmetric interaction. Although the model accounts for all reported experimental data involving tetracationic porphyrin species which have been suggested to be intercalators, it is not a unique solution.     

Electron-nuclear double resonance of copper complexes of human transferrin

Electron-nuclear double resonance (ENDOR) spectroscopy has been used to study ligand and copper hyperfine interactions in Cu(II) complexes of human transferrin. A nearly isotropic superhyperfine interaction of the Cu(II) spin with a single 14N nucleus was identified, and the principal values of its tensor were estimated. All principal values of the copper hyperfine tensor were also directly measured for the first time. Resonances from at least two exchangeable protons were observed, but their origin could not be ascertained. At physiological pH, and in the presence of bicarbonate, ENDOR spectra of the two metal-binding sites were virtually indistinguishable.     

Electron nuclear double resonance of cytochrome oxidase: nitrogen and proton ENDOR from the 'copper' EPR signal.

Proton ENDOR resonances have been found from at least two different protons with fairly large and isotropic couplings of about 12 and 19 MHz. It is possible that such protons are attached to carbons that are one bond removed from the point of ligation to copper. A number of weakly coupled protons with anisotropic couplings have also been seen. None of the protons, either weakly or strongly coupled, appears to exchange with 2H2O. We have obtained nitrogen ENDOR from at least one nitrogen with a hyperfine coupling large enough for the nitrogen to be a ligand of copper. We have not yet demonstrated experimentally ENDOR characteristic of the copper nucleus itself.     

Electron nuclear double resonance (ENDOR) of the Qc.- ubisemiquinone radical in the mitochondrial electron transport chain

We present an electron nuclear double resonance (ENDOR) study of the bound Qc.- ubisemiquinone in the mitochondrial quinol cytochrome c reductase complex. An ENDOR probe specifically modified for insertion into our electron paramagnetic resonance cavity was used for this study. We observed strongly hyperfine-coupled protons whose exchangeable nature indicated they were hydrogen-bonded to the quinone oxygen(s). It is thought that such hydrogen bonds are critical in binding the ubiquinone to protein, in stabilizing its semiquinone form, and in modulating the thermodynamic properties of the bound ubiquinone in the mitochondrial quinol cytochrome c reductase complex. Additional ENDOR features were assigned to protons of the quinone ring itself and to weakly coupled protons that may be associated with nearby amino acids. From very weakly hyperfine-coupled, distant, exchangeable protons there was also ENDOR evidence to suggest proximity and accessibility of the ubiquinone site to the solvent.     

Catalytic function and local proton structure at the type 2 copper of nitrite reductase: the correlation of enzymatic pH dependence,conserved residues,and proton hyperfine structure

Electron nuclear double resonance (ENDOR) of protons at Type 2 and Type 1 cupric active sites correlates with the enzymatic pH dependence, the mutation of nearby conserved, nonligating residues, and electron transfer in heterologously expressed Rhodobacter sphaeroides nitrite reductase. Wild-type enzyme showed a pH 6 activity maximum but no kinetic deuterium isotope effect, suggesting protons are not transferred in the rate-limiting step of nitrite reduction. However, protonatable Asp129 and His287, both located near the Type 2 center, modulated enzyme activity. ENDOR of the wild-type Type 2 center at pH 6.0 revealed an exchangeable proton with large hyperfine coupling. Dipolar distance estimates indicated that this proton was 2.50-2.75 or 2.25-2.45 A from Type 2 copper in the presence or absence of nitrite, respectively. This proton may provide a properly oriented hydrogen bond to enhance water formation upon nitrite reduction. This proton was eliminated at pH 5.0 and showed a diminished coupling at pH 7.5. Mutations of Asp129 and His287 reduced enzyme activity and altered the exchangeable proton hyperfine spectra. Mutation of Asp129 prevented a pH-dependent change at the Type 1 Cys167 ligand as observed by Cys C(beta) proton ENDOR, implying there is a Type 2 and pH-dependent alteration of the Type 1 center. Mutation of the Type 1 center ligand Met182 to Thr and mutation of Asp129 increased the activation energy for nitrite reduction. Involvement of both the Type 1 center and Asp129 in modulating activation energy shows that electron transfer from the Type 1 center to a nitrite-ligated Type 2 center is rate-limiting for nitrite reduction. Mutation of Ile289 to Ala and Val caused minor perturbation to enzyme activity, but as detected by ENDOR, allowed formate binding. Thus, bulky Ile289 may exclude non-nitrite ligands from the Type 2 active site.     

Nucleotide binding to tubulin-investigations by nuclear magnetic resonance spectroscopy

In an attempt to distinguish between the interaction of GTP and ATP with tubulin dimer, high-resolution ¹H- and ³¹P-NMR experiments have been carried out on the nucleotides in the presence of tubulin. The location of the ATP binding sites on the protein in relation to the GTP sites is still not clear. Using NMR spectroscopy, we have tried to address this question. Evidence for the existence of a site labelled as X-site and another site (labelled as L-site for both the nucleotides on tubulin has been obtained. It is suggested that this X-site is possibly the putative E-site. In order to gain further insight into the nature of these sites, the Mg(II at the N-site has been replaced by Mn(II and the paramagnetic effect of Mn(II on the linewidth of the proton resonances of tubulin-bound ATP and GTP has been studied. The results show that the L-site nucleotide is closer to the N-site metal ion compared to the X-site nucleotide. On the basis of these results, it is suggested that the L-site of ATP is distinct from the L-site of GTP while the X-site of both the nucleotides seems to be same. By using the paramagnetic effect of the metal ion, Mn(II), at the N-site on the relaxation rates of tubulin-bound ATP at L-site, distances of the protons of the base, sugar and phosphorous nuclei of the phosphorous moiety of ATP, from the N-site metal ion have been mapped. The base protons are 2 0.7–1 nm distant from the N-site metal ion, while the protons of the sugar are 2 0.8-1 nm from this metal ion site. On the other hand, the phosphorous nuclei of the phosphate groups are somewhat nearer (2 0.4–0.5 nm from the N-site metal ion.     

Role of the coordinating histidine in altering the mixed valency of Cu(A): an electron nuclear double resonance-electron paramagnetic resonance investigation

The binuclear Cu(A) site engineered into Pseudomonas aeruginosa azurin has provided a Cu(A)-azurin with a well-defined crystal structure and a CuSSCu core having two equatorial histidine ligands, His120 and His46. The mutations His120Asn and His120Gly were made at the equatorial His120 ligand to understand the histidine-related modulation to Cu(A), notably to the valence delocalization over the CuSSCu core. For these His120 mutants Q-band electron nuclear double resonance (ENDOR) and multifrequency electron paramagnetic resonance (EPR) (X, C, and S-band), all carried out under comparable cryogenic conditions, have provided markedly different electronic measures of the mutation-induced change. Q-band ENDOR of cysteine C(beta) protons, of weakly dipolar-coupled protons, and of the remaining His46 nitrogen ligand provided hyperfine couplings that were like those of other binuclear mixed-valence Cu(A) systems and were essentially unperturbed by the mutation at His120. The ENDOR findings imply that the Cu(A) core electronic structure remains unchanged by the His120 mutation. On the other hand, multifrequency EPR indicated that the H120N and H120G mutations had changed the EPR hyperfine signature from a 7-line to a 4-line pattern, consistent with trapped-valence, Type 1 mononuclear copper. The multifrequency EPR data imply that the electron spin had become localized on one copper by the His120 mutation. To reconcile the EPR and ENDOR findings for the His120 mutants requires that either: if valence localization to one copper has occurred, the spin density on the cysteine sulfurs and the remaining histidine (His46) must remain as it was for a delocalized binuclear Cu(A) center, or if valence delocalization persists, the hyperfine coupling for one copper must markedly diminish while the overall spin distribution on the CuSSCu core is preserved.     

Studies of interactions of porphyrins with transfer RNA by high-resolution NMR

The interactions of tetra-4N-methylpyridyl porphyrin and its zinc(II), copper(II) and manganese(III) complexes with brewer's yeast type V phenylalanine specific tRNA have been evaluated by high-resolution NMR. Differences in chemical shifts have been noted for three proton resonances in response to the presence of small quantities of the free base and the zinc and copper complexes. The protons giving rise to these signals are located on bases T54 and psi 55, both of which are involved in the primary intraloop and interloop hydrogen bonds that hold the D and T psi C loops together in the tertiary structure. In addition, broadening of specific resonances due to hydrogen bonding protons in the D stem at low ratios of porphyrin to tRNA indicates that the association of porphyrins increases the rate of imino proton exchange. The titration of the tRNA with the manganese(III) complex did not reveal shifts or specific broadening comparable to the other porphyrins at low ratios. The changes induced in the NMR spectrum of tRNA by porphyrins define their site of interaction with the polynucleotide. This site, at the outside of the elbow-bend in the tRNA 'L', is different from the locus of binding in tRNA for other classical DNA intercalators. Furthermore, a new mode of binding may be involved that is neither intercalative nor simply electrostatic.     

Iron binding to horse spleen apoferritin: a vanadyl ENDOR spin probe study.

The role of the protein shell in the formation of the hydrous ferric oxide core of ferritin is poorly understood. A VO2+ spin probe study was undertaken to characterize the initial complex of Fe2+ with horse spleen apoferritin (96% L-subunits). A competitive binding study of VO2+ and Fe2+ showed that the two metals compete 1:1 for binding at the same site or region of the protein. Curve fitting of the binding data showed that the affinity of VO2+ for the protein was 15 times that of Fe2+. Electron nuclear double resonance (ENDOR) measurements on the VO(2+)-apoferritin complex showed couplings from two nitrogen nuclei, tentatively ascribed to the N1 and N3 nitrogens of the imidazole ligand of histidine. The possibility that the observed nitrogen couplings are from two different ligands is not precluded by the data, however. A pair of exchangeable proton lines with a coupling of approximately 1 MHz is tentatively assigned to the NH proton of the coordinated nitrogen. A 30-40% reduction in the intensity of the 1H matrix ENDOR line upon D2O-H2O exchange indicates that the metal-binding site is accessible to solvent and, therefore, to molecular oxygen as well. The ENDOR data provide the first evidence for a principle iron(II)-binding site with nitrogen coordination in an L-subunit ferritin. The site may be important in Fe2+ oxidation during the beginning stages of core formation.     

Thermodynamic and kinetic analysis of porphyrin binding to Trichosanthes cucumerina seed lectin.

The interaction of several metallo-porphyrins with the galactose-specific lectin from Trichosanthes cucumeirna (TCSL) has been investigated. Difference absorption spectroscopy revealed that significant changes occur in the Soret band region of the porphyrins upon binding to TCSL and these changes have been monitored to obtain association constants (Ka) and stoichiometry of binding (n). The dimeric lectin binds two porphyrin molecules and the presence of the specific saccharide lactose did not affect porphyrin binding significantly, indicating that the sugar and the porphyrin bind at different sites. The Ka values obtained for the binding of different porphyrins with TCSL at 25 degrees C were in the range of 2 x 10(3)-5 x 10(5) m(-1). Association constants for meso-tetra(4-sulphonatophenyl)porphyrinato copper(II) (CuTPPS), a porphyrin bearing four negative charges and meso-tetra(4-methylpyridinium)porphyrinato copper(II) (CuTMPyP), a porphyrin with four positive charges, were determined at several temperatures; from the temperature dependence of the association constants, the thermodynamic parameters change in enthalpy (DeltaH degrees ) and change in entropy (DeltaS degrees ) associated with the binding process were estimated. The thermodynamic data indicate that porphyrin binding to TCSL is driven largely by a favourable entropic contribution; the enthalpic contribution is very small, suggesting that the binding process is governed primarily by hydrophobic forces. Stopped-flow spectroscopic measurements show that binding of CuTMPyP to TCSL takes place by a single-step process and at 20 degrees C, the association and dissociation rate constants were 1.89 x 10(4) m(-1).s(-1) and 0.29 s(-1), respectively.     

Proton electron-nuclear double-resonance spectra of molybdenum(V) in different reduced forms of xanthine oxidase

Electron-nuclear double-resonance (ENDOR) spectra of protons coupled to molybdenum(V) in reduced xanthine oxidase samples have been recorded. Under appropriate conditions these protons may be studied without interference from protons coupled to reduced iron-sulfur centers. Spectra have been obtained for the molybdenum(V) species known as Rapid, Slow, Inhibited, and Desulfo Inhibited. Resonances corresponding to at least nine protons or sets of protons are observed for all four species, with coupling constants in the range 0.08-4 MHz. Most of these protons do not exchange when 2H2O is used as solvent. Additional protons giving couplings up to 40 MHz are also detected. These correspond to EPR-detectable protons studied in earlier work. The strongly coupled protons may be replaced by 2H, through appropriate use of 2H2O or of 2H-substituted substrates, with consequent disappearance of the 1H resonances. In most cases the corresponding 2H ENDOR features have also been observed. The nature of the various coupled protons is briefly discussed. Results permit specific conclusions to be drawn about the structures of the Inhibited and Desulfo Inhibited species. In particular, the data indicate that the aldehyde residue of the Inhibited species has been oxidized and that the four protons derived from the ethylene glycol molecule in the Desulfo Inhibited species are not all equivalent. Recent assignments [Edmondson, D.E., & D'Ardenne, S.C. (1989) Biochemistry 28, 5924-5930] of the weakly coupled protons in the latter species appear not to be soundly based. The possibility of obtaining more detailed structural information from the spectra is briefly considered.(ABSTRACT TRUNCATED AT 250 WORDS)     

EPR and electron nuclear double resonance investigation of oxidized hydrogenase II (uptake) from Clostridium pasteurianum W5. Effects of carbon monoxide binding

Two different hydrogenases have been isolated from Clostridium pasteurianum W5. Hydrogenase II (uptake) is active in H2 oxidation while hydrogenase I (bidirectional) is active both in H2 oxidation and evolution. Previous EPR and electron nuclear double resonance (ENDOR) studies of oxidized hydrogenase I have now been complemented by analogous studies on oxidized 57Fe-enriched hydrogenase II and its CO derivative (using 12CO and 13CO). Binding of CO greatly changes the EPR spectrum of oxidized hydrogenase II, and use of 13CO leads to resolved hyperfine splitting from interaction with a single 13CO molecule (AC approximately 34 MHz). This coupling is over 50% larger than that seen for hydrogenase I. 57Fe ENDOR disclosed two types of iron site in both oxidized hydrogenase II and its CO derivative. Combination of EPR, ENDOR, and M?ssbauer results shows that site 1 has AFe1 = 18 MHz shifting to approximately 30 MHz upon CO binding and consisting of two Fe atoms and site 2 has A2 approximately 7 MHz shifting to approximately 10 MHz and containing a single Fe. These results are very similar to those seen for hydrogenase I, which indicates that a structurally similar 3Fe cluster, believed to be the catalytically active site, is present in both. Proton ENDOR shows a solvent exchangeable resonance only in the CO derivative of hydrogenase II. This indicates a structural difference between hydrogenases I and II that is brought out by CO binding. No evidence of 14N coordination to the cluster is seen for either enzyme.     

Hydrogenases in the "active" state: determination of g-matrix axes and electron spin distribution at the active site by 1H ENDOR spectroscopy

Hydrons and electrons are substrates for the enzyme hydrogenase, but cannot be observed in X-ray crystal structures. High-resolution 1H electron nuclear double resonance (ENDOR) spectroscopy offers a means to detect the distribution of protons and unpaired electrons. ENDOR spectra were recorded from frozen solutions of the nickel-iron hydrogenases of Desulfovibrio gigas and Desulfomicrobium baculatum, in the "active" state ("Ni-C" EPR signal) and analyzed by orientationally selective simulation methods. The experimental spectra were fitted using a structural model of the nickel-iron centre based on crystallographic results, allowing for differences in electron spin distribution as well as the spatial orientation of the g-matrix ( g-tensor), and anisotropic and isotropic hyperfine couplings of the protons nearest to the nickel ion. ENDOR signals, detected after complete deuterium exchange, were assigned to six protons of the cysteines bound to nickel. The assignment took advantage of the substitution of a selenium for a sulfur ligand, which occurs naturally between the [NiFeSe] and [NiFe] hydrogenases from Dm. baculatum and D. gigas, respectively, and was found to affect just two signals. The four signals with the largest hyperfine couplings, including isotropic contributions from 4.5 to 13.5 MHz, were assigned to the beta-methylene protons of the two terminal cysteine ligands, one of which is substituted by seleno-cysteine in [NiFeSe] hydrogenase. The electron spin is delocalized onto the nickel (50%) and its sulfur ligands, with a higher proportion on the terminal than the bridging ligands. The g-matrix was found to align with the active site in such a way that the g1- g2 plane is nearly coplanar (18.3 degrees) with the plane defined by nickel and three sulfur atoms, and the g2 axis deviates by 22.9 degrees from the vector between nickel and iron. Significantly for the reaction of the enzyme, direct evidence for the binding of hydrons at the active site was obtained by the detection of H/D-exchangeable ENDOR signals.     

Proton NMR investigation of the nucleosome core particle: evidence for regions of altered hydrogen bonding

Novel 1H nuclear magnetic resonance (NMR) resonances, arising from exchangeable protons and centered at approximately 11.2 and 10.1 parts per million (ppm), have been observed in the low-field spectrum (10-15 ppm) of the chicken erythrocyte core particle [145 +/- 2 base pairs (bp)]. These peaks are located upfield from the normal adenine-thymine (A-T) and guanine-cytosine (G-C) imino peaks characteristic of B-form deoxyribonucleic acid (DNA) and are not observed in free DNA under identical conditions. The appearance of the new peaks is ionic strength dependent and temperature-reversible below 75 degrees C. At 25 degrees C, the upfield peak area represents 5% of the DNA base pairs (7 bp), while between 45 and 55 degrees C, the area increases to 18%, affecting approximately 25 bp. Area increases in the upfield resonances result in a complementary decrease in the A-T and G-C imino peaks found between 12 and 14 ppm. We believe these novel proton signals represent a histone-induced DNA conformational change which involves localized alteration of base pairing in the core particle.     

The influence of intercalator structure on DNA binding strength: the importance of side chain orientation

A naphthothiophene intercalator with a cationic side chain linked to the ring through an ester group (1E) has been shown to bind to DNA almost an order of magnitude more strongly than a similar compound with the side chain linked to the ring through an amide group (1A) (W.D. Wilson, et al., Biophys. Chem. 24, 101-109 (1986]. X-ray crystallographic analysis of these two compounds indicates that both the ester and amide groups are essentially planar but that the amide is twisted approximately 30 degrees out of the aromatic plane of the naphthothiophene while the ester and ring system are co-planar. Proton NMR studies of the DNA complexes of these two compounds indicate that the naphthothiophene ring is intercalated in both 1A and 1E but that the protons of the ring system near the side chain interact with DNA base pairs at the binding site significantly better in 1E than in 1A. The protons next to the ester group on the side chain of 1E are also shifted upfield significantly more on addition of DNA than those of 1A. The large planar area of 1E, thus, allows greater stacking, complex geometry optimization, and dipolar interactions of the ester group with DNA base pairs at the binding site to account for the larger binding constant of this compound relative to 1A.     

The binding of molybdate to uteroferrin. Hyperfine interactions of the binuclear center with 95Mo, 1H, and 2H

Uteroferrin, an acid phosphatase with a spin-coupled and redox-active binuclear iron center, is paramagnetic in its pink, enzymatically active, mixed-valence (S = 1/2) state. Phosphate, a product and inhibitor of the enzymatic activity of uteroferrin, converts the pink, EPR-active form of the protein to a purple, EPR-silent species. In contrast, molybdate, a tetrahedral oxyanion analog of phosphate, transforms the EPR spectrum of uteroferrin from a rhombic to an axial form. With both electron spin echo envelope modulation (ESEEM) and electron nuclear double resonance (ENDOR) spectroscopies, we observe a hyperfine interaction of [95Mo]molybdate with the S = 1/2, Fe(II)-Fe(III) center of the protein. A pair of 95Mo resonances centered at the 95Mo Larmor frequency at the applied magnetic field and separated by a hyperfine coupling constant of 1.2 MHz is evident. Therefore, a single monomeric species of molybdate is close to, and likely a ligand of, the binuclear cluster. 1H ENDOR studies on uteroferrin reveal at least six sets of lines mirrored about the 1H Larmor frequency. Two pairs of these lines become reduced in intensity when the protein is exchanged against D2O. Moreover, ESEEM and 2H ENDOR spectra display resonances at the 2H Larmor frequency. Therefore, the metal-binding region of the protein is accessible to solvent. Additional deuterium lines observable by ESEEM spectroscopy provide evidence for a population of strongly coupled, readily exchangeable protons associated with the binuclear center. The measured hyperfine coupling constants for these deuterons are orientation-dependent with splittings of nearly 4 MHz at g3 = 1.59 and less than 1 MHz at g1 = 1.94. In the presence of molybdate, ESEEM spectra of D2O-exchanged samples reveal a resonance at the 2H Larmor frequency, with no evidence of spectral components due to strongly coupled deuterons. 1H ENDOR studies of the uteroferrin-molybdate complex show at least seven pairs of lines, mirrored about the 1H Larmor frequency, of which one pair becomes attenuated in amplitude upon deuteration. The active site thus remains accessible to solvent in the presence of molybdate.     

Potentiometric and electron nuclear double resonance properties of the two spin forms of the [4Fe-4S]+ cluster in the novel ferredoxin from the hyperthermophilic archaebacterium Pyrococcus furiosus.

Pyrococcus furiosus ferredoxin contains a single [4Fe-4S] that exists in both S = 1/2 (20%) and S = 3/2 (80%) ground states in the reduced protein. We report here on the temperature-dependent potentiometric properties of the two spin forms, their stability, and on the structural features that differentiate them. The midpoint potential (Em) of the cluster in either spin state was determined at -365 mV (30 degrees C, pH 8.0). By rapidly freezing samples for EPR analyses, it was shown that the Em values of both spin states appear to change by -1.7 mV/degrees C over the range 20 degrees-80 degrees C, and by -6 mV/degrees C between 80 and 89 degrees C. The Em values and the relative amounts of the S = 1/2 and S = 3/2 forms of the cluster were unaffected by pH (6.8-10.5), even at 85 degrees C, and were unchanged by the presence of NaCl (1.0 M), sodium dodecyl sulfate (10%, w/v) or ethylene glycol (50%, v/v), even at 80 degrees C. The S = 1/2 form of the [4Fe-4S]+ cluster was found to exhibit a strongly coupled 1H ENDOR resonance (A = 22 MHz) that was exchangeable with the solvent. Such a large coupling has not been observed in any other iron-sulfur protein. Since a unique feature of this 4Fe-ferredoxin is that only 3 cysteinyl residues appear to be coordinated to the [4Fe-4S] cluster, the ENDOR data are consistent with an H2O molecule being a ligand to the unique Fe site. The S = 3/2 form of the [4Fe-4S]+ cluster exhibited a similar, strongly coupled 1H ENDOR resonance, but in this spin state it was not exchangeable with the solvent. This suggests that the [4Fe-4S]+ cluster exhibiting the S = 3/2, but not the S = 1/2 ground state, is "shielded" from the solvent, presumably by neighboring amino acid residues. In view of the pH dependence of the midpoint potential of the two spin states, the fourth ligand to the cluster and the source of the strongly coupled 1H ENDOR resonance is probably an OH- rather than H2O molecule.     

Water molecules and exchangeable hydrogen ions at the active centre of bacteriorhodopsin localized by neutron diffraction. Elements of the proton pathway?

Neutron diffraction is used to localize water molecules and/or exchangeable hydrogen ions in the purple membrane by H2O/2H2O exchange experiments at different values of relative humidity. At 100% relative humidity, differences in the hydration between protein and lipid areas are observed, accounting for an excess amount of about 100 molecules of water in the lipid domains per unit cell. A pronounced isotope effect was observed, reproducibly showing an increase in the lamellar spacing from 60 A in 2H2O to 68 A in H2O. At 15% relative humidity, the positions of exchangeable protons became visible. A dominant difference density peak corresponding to 11 +/- 2 exchangeable protons was detected in the central part of the projected structure of bacteriorhodopsin at the Schiff's base end of the chromophore. A difference density map obtained from data on purple membrane films at 15% relative humidity in 2H2O, and the same sample after complete drying in vacuum, revealed that about eight of these protons belong to four water molecules. This is direct evidence for tightly bound water molecules close to the chromophore binding site of bacteriorhodopsin, which could participate in the active steps of H+ translocation as well as in the proton pathway across this membrane protein.     

Coordination environment for the type 3 copper center of tree laccase and CuB of cytochrome c oxidase as determined by electron nuclear double resonance

A new rhombic EPR signal was recently discovered in the partially reduced type 2 copper-depleted Rhus vernicifera laccase (Reinhammar, B. (1983) J. Inorg. Biochem., in press). The signal originates from one of the type 3 Cu(II) ions that becomes EPR-detectable as a result of the selective reduction of the other copper ion in the exchange-coupled Cu(II)-Cu(II) pair. The 14N and 1H and 63,65Cu electron nuclear double resonance (ENDOR) of this uncoupled Cu(II) now have been collected and represent the first ENDOR measurements of a type 3 copper site. The data indicate that the copper is coordinated by at least three nitrogenous ligands, at least one of which is an imidazole. H/D exchange suggests a nearby H2O or OH-, perhaps as a fourth ligand. A similar EPR signal is seen for CuB of reduced cytochrome c oxidase under turnover conditions. The 14N ENDOR, and, therefore, the structure, of this site corresponds extremely closely to that of the laccase type 3 (Cu(II).