Assignment of the 15N NMR spectra of reduced and oxidized Escherichia coli thioredoxin

As a necessary first step in the use of heteronuclear correlated spectra to obtain high resolution solution structures of the protein, assignment of the 15N NMR spectra of reduced and oxidized Escherichia coli thioredoxin (Mr 12,000) uniformly labeled with 15N has been performed. The 15N chemical shifts of backbone amide nitrogen atoms have been determined for both oxidation states of thioredoxin using 15N-1H correlated and two-dimensional heteronuclear single-quantum coherence (HSQC) TOCSY and NOESY spectra. The backbone assignments are complete, except for the proline imide nitrogen resonances and include Gly33, whose amide proton resonance is difficult to observe in homonuclear 1H spectra. The differences in the 15N chemical shift between oxidized and reduced thioredoxin, which occur mainly in the vicinity of the two active site cysteines, including residues distant in the amino acid sequence which form a hydrophobic surface close to the active site, are consistent with the differences observed for proton chemical shifts in earlier work on thioredoxin.     

Differences between the electronic environments of reduced and oxidized Escherichia coli DsbA inferred from heteronuclear magnetic resonance spectroscopy.

DsbA is the strongest protein disulfide oxidant yet known and is involved in catalyzing protein folding in the bacterial periplasm. Its strong oxidizing power has been attributed to the lowered pKa of its reactive active site cysteine and to the difference in thermodynamic stability between the oxidized and the reduced form. However, no structural data are available for the reduced state. Therefore, an NMR study of DsbA in its two redox states was undertaken. We report here the backbone 1HN, 15N, 13C(alpha) 13CO, 1H(alpha), and 13Cbeta NMR assignments for both oxidized and reduced Escherichia coli DsbA (189 residues). Ninety-nine percent of the frequencies were assigned using a combination of triple (1H-13C-15N) and double resonance (1H-15N or 1H-13C) experiments. Secondary structures were established using the CSI (Chemical Shift Index) method, NOE connectivity patterns, 3(J)H(N)H(alpha) and amide proton exchange data. Comparison of chemical shifts for both forms reveals four regions of the protein, which undergo some changes in the electronic environment. These regions are around the active site (residues 26 to 43), around His60 and Pro 151, and also around Gln97. Both the number and the amplitude of observed chemical shift variations are more substantial in DsbA than in E. coli thioredoxin. Large 13C(alpha) chemical shift variations for residues of the active site and residues Phe28, Tyr34, Phe36, Ile42, Ser43, and Lys98 suggest that the backbone conformation of these residues is affected upon reduction.     

Assignment of the proton NMR spectrum of reduced and oxidized thioredoxin: sequence-specific assignments, secondary structure, and global fold

Complete proton assignments are reported for the 1H nuclear magnetic resonance (NMR) spectrum of Escherichia coli thioredoxin in the oxidized (with active-site disulfide bridge) and reduced (with two sulfhydryl groups) states. The assignments were obtained by using an integrated assignment strategy in which spin systems were identified from a combination of relayed and multiple quantum NMR techniques prior to sequential assignment. Elements of secondary structure were identified in each protein from characteristic nuclear Overhauser effects (NOE), coupling constants, and slowly exchanging amide protons. In both oxidized and reduced thioredoxin, approximately 33% of the 108 amino acid residues participate in a beta-sheet containing four major strands (three antiparallel and one parallel). A further short beta-strand is connected in a parallel fashion at the N-terminal end of the sheet. Two of the antiparallel beta-strands are connected by a 7-residue beta-bulge loop. Three helical segments, also containing approximately 33% of the amino acid residues, are well-defined in both oxidized and reduced thioredoxin. The remaining third of the molecule apparently consists of reverse turns and loops with little defined secondary structure. The global folds of oxidized and reduced thioredoxin are shown to be essentially identical. Both NOE connectivities and chemical shift values for the two proteins are very similar, except in the immediate vicinity of the active site where significant variations in the chemical shift indicate subtle conformational changes. While the overall fold of oxidized thioredoxin is the same in solution and in the crystalline state, some small differences in local conformation are apparent.     

Temperature dependence of NMR chemical shifts: Tracking and statistical analysis

Isotropic chemical shifts measured by solution nuclear magnetic resonance (NMR) spectroscopy offer extensive insights into protein structure and dynamics. Temperature dependences add a valuable dimension; notably, the temperature dependences of amide proton chemical shifts are valuable probes of hydrogen bonding, temperature‐dependent loss of structure, and exchange between distinct protein conformations. Accordingly, their uses include structural analysis of both folded and disordered proteins, and determination of the effects of mutations, binding, or solution conditions on protein energetics. Fundamentally, these temperature dependences result from changes in the local magnetic environments of nuclei, but correlations with global thermodynamic parameters measured via calorimetric methods have been observed. Although the temperature dependences of amide proton and nitrogen chemical shifts are often well approximated by a linear model, deviations from linearity are also observed and may be interpreted as evidence of fast exchange between distinct conformational states. Here, we describe computational methods, accessible via the Shift‐T web server, including an automated tracking algorithm that propagates initial (single temperature) ¹H? ¹⁵N cross peak assignments to spectra collected over a range of temperatures. Amide proton and nitrogen temperature coefficients (slopes determined by fitting chemical shift vs. temperature data to a linear model) are subsequently calculated. Also included are methods for the detection of systematic, statistically significant deviation from linearity (curvature) in the temperature dependences of amide proton chemical shifts. The use and utility of these methods are illustrated by example, and the Shift‐T web server is freely available at http://meieringlab.uwaterloo.ca/shiftt .     

1H, 13C and 15N resonance assignments of wild-type Bacillus subtilis Lipase A and its mutant evolved towards thermostability

Previously, we evolved Lipase A from Bacillus subtilis towards increased thermostability. The resulting mutant retains significant catalytic activity upon heating above 60 °C (and up to 100 °C) and cooling down, whereas wild-type lipase precipitates irreversibly and does not show significant activity in these conditions. Kinetic thermostability of proteins has not been characterized well on the molecular structure level so far, therefore our aim is to study it using NMR spectroscopy. Here, nearly complete ¹H, ¹³C and ¹⁵N resonance assignments are reported for wild-type and mutant Lipase A. Chemical shifts were used to predict secondary structure elements of both Lipase A variants.     

31P NMR spectra of oligodeoxyribonucleotide duplex lac operator-repressor headpiece complexes: importance of phosphate ester backbone flexibility in protein-DNA recognition.

The 31P NMR spectra of various 14-base-pair lac operators bound to both wild-type and mutant lac repressor headpiece proteins were analyzed to provide information on the backbone conformation in the complexes. The 31P NMR spectrum of a wild-type symmetrical operator, d(TGTGAGCGCTCACA)2, bound to the N-terminal 56-residue headpiece fragment of a Y7I mutant repressor was nearly identical to the spectrum of the same operator bound to the wild-type repressor headpiece. In contrast, the 31P NMR spectrum of the mutant operator, d(TATAGAGCGCTCATA)2, wild-type headpiece complex was significantly perturbed relative to the wild-type repressor-operator complex. The 31P chemical shifts of the phosphates of a second mutant operator, d(TGTGTGCGCACACA)2, showed small but specific changes upon complexation with either the wild-type or mutant headpiece. The 31P chemical shifts of the phosphates of a third mutant operator, d(TCTGAGCGCTCAGA)2, showed no perturbations upon addition of the wild-type headpiece. The 31P NMR results provide further evidence for predominant recognition of the 5'-strand of the 5'-TGTGA/3'-ACACT binding site in a 2:1 protein to headpiece complex. It is proposed that specific, strong-binding operator-protein complexes retain the inherent phosphate ester conformational flexibility of the operator itself, whereas the phosphate esters are conformationally restricted in the weak-binding operator-protein complexes. This retention of backbone torsional freedom in strong complexes is entropically favorable and provides a new (and speculative) mechanism for protein discrimination of different operator binding sites. It demonstrates the potential importance of phosphate geometry and flexibility on protein recognition and binding.     

13C-, 15N- and 31P-NMR studies of oxidized and reduced low molecular mass thioredoxin reductase and some mutant proteins.

Thioredoxin reductase (TrxR) from Escherichia coli, the mutant proteins E159Y and C138S, and the mutant protein C138S treated with phenylmercuric acetate were reconstituted with [U-(13)C(17),U-(15)N(4)]FAD and analysed, in their oxidized and reduced states, by (13)C-, (15)N- and (31)P-NMR spectroscopy. The enzymes studied showed very similar (31)P-NMR spectra in the oxidized state, consisting of two peaks at -9.8 and -11.5 p.p.m. In the reduced state, the two peaks merge into one apparent peak (at -9.8 p.p.m.). The data are compared with published (31)P-NMR data of enzymes closely related to TrxR. (13)C and (15)N-NMR chemical shifts of TrxR and the mutant proteins in the oxidized state provided information about the electronic structure of the protein-bound cofactor and its interactions with the apoproteins. Strong hydrogen bonds exist between protein-bound flavin and the apoproteins at C(2)O, C(4)O, N(1) and N(5). The N(10) atoms in the enzymes are slightly out of the molecular plane of the flavin. Of the ribityl carbon atoms C(10alpha,gamma,delta) are the most affected upon binding to the apoprotein and the large downfield shift of the C(10gamma) atom indicates strong hydrogen bonding with the apoprotein. The hydrogen bonding pattern observed is in excellent agreement with X-ray data, except for the N(1) and the N(3) atoms where a reversed situation was observed. Some chemical shifts observed in C138S deviate considerably from those of the other enzymes. From this it is concluded that C138S is in the FO conformation and the others are in the FR conformation, supporting published data. In the reduced state, strong hydrogen bonding interactions are observed between C(2)O and C(4)O and the apoprotein. As revealed by the (15)N chemical shifts and the N(5)H coupling constant the N(5) and the N(10) atom are highly sp(3) hybridized. The calculation of the endocyclic angles for the N(5) and the N(10) atoms shows the angles to be approximately 109 degrees, in perfect agreement with X-ray data showing that the flavin assumes a bent conformation along the N(10)/N(5) axis of the flavin. In contrast, the N(1) is highly sp(2) hybridized and is protonated, i.e. in the neutral state. Upon reduction of the enzymes, the (13)C chemical shifts of some atoms of the ribityl side chain undergo considerable changes also indicating conformational rearrangements of the side-chain interactions with the apoproteins. The chemical shifts between native TrxR and C138S are now rather similar and differ from those of the two other mutant proteins. This strongly indicates that the former enzymes are in the FO conformation and the other two are in the FR conformation. The data are discussed briefly in the context of published NMR data obtained with a variety of flavoproteins.     

The catalytic mechanism of glucose 6-phosphate dehydrogenases: assignment and 1H NMR spectroscopy pH titration of the catalytic histidine residue in the 109 kDa Leuconostoc mesenteroides enzyme

The chemical shifts of the C(epsilon1) and C(delta2) protons of His-240 from the 109 kDa Leuconostoc mesenteroides glucose 6-phosphate dehydrogenase (G6PD) were assigned by comparing 1H and 13C spectra of the wild-type and mutant G6PDs containing the His-240 to asparagine mutation (H240N). Unambiguous assignment of the His-240 1H(epsilon1) resonance was obtained from comparing 13C-1H heteronuclear multiple quantum coherence NMR spectra of wild-type and H240N G6PDs that were selectively labeled with 13C(epsilon1) histidine. The results from NOESY experiments with wild-type and H240N variants were consistent with these assignments and the three-dimensional structure of G6PD. pH titrations show that His-240 has a pK(a) of 6.4. This value is, within experimental error, identical to the value of 6.3 derived from the pH dependence of kcat [Viola, R. E. (1984) Arch. Biochem. Biophys. 228, 415-424], suggesting that the pK(a) of His-240 is unperturbed in the apoenzyme despite being part of a His-Asp catalytic dyad. The results obtained for this 109 kDa enzyme indicate that 1H NMR spectroscopy in combination with heteronuclear methods can be a useful tool for functional analysis of large proteins.     

Flavins of NADPH-cytochrome P-450 reductase: evidence for structural alteration of flavins in their one-electron-reduced semiquinone states from resonance Raman spectroscopy

The mechanism of electron transfer from NADPH to cytochrome P-450 through FAD and FMN of the reductase is largely unknown. In this paper, we report the resonance Raman spectral properties of the oxidized and the semiquinonoid states of the flavins in the holoenzyme and the FMN-depleted forms, respectively, of detergent-solubilized rabbit liver microsomal NADPH-cytochrome P-450 reductase. The resonance Raman spectra of the oxidized forms [FAD; FMN] and [FAD;-] were essentially identical, indicating similar binding interactions of these flavins with the protein. To the contrary, the spectra of the semiquinonoid FADH. and FMNH. forms revealed significant spectral differences. Both O2-unstable species, characterized as [FADH.; FMNH2] and [FADH.;-] excited at 568.2 nm, have dominant spectral peaks at approximately 1611, 1539-1543, 1377, 1305, 1263, and 1226 cm-1. However, in the O2-stable [FAD; FMNH.] species, resonance Raman bands were located at 1611, 1532, 1388, 1304, 1268, and 1227 cm-1 when excited at the same wavelength. The approximately 10-cm-1 shifts of the 1532- and 1388-cm-1 bands suggest that the environments surrounding rings II and III of the isoalloxazines change upon reduction to semiquinonoid forms. It is proposed that N1 of FADH. (as a hydrogen-bond acceptor) and N5 of FMNH. (as donor) provide the distinguishing flavin-protein interactions in the semiquinonoid states. Furthermore, the resonance Raman spectra of the semiquinonoid species appear to be missing a number of bands assigned to ring I vibrations in the spectra of the oxidized flavins.(ABSTRACT TRUNCATED AT 250 WORDS)     

G33D mutant thioredoxin primarily affects the kinetics of reaction with thioredoxin reductase. Probing the structure of the mutant protein

Escherichia coli thioredoxin is a redox-active protein. A mutant protein with an aspartic acid substitution for the largely conserved glycine at position 33 (G33D) in the active site of thioredoxin has been generated to study the effects of a negatively charged residue in the active site of the protein. Despite the close proximity of the negative-charged Asp to the redox active cysteines, the effective concentration of the cysteines does not deviate significantly from that of the wild-type protein. The redox potential (E(o)') measured by the equilibrium between NADPH and the mutant thioredoxin is also close to that of the wild-type. Kinetic measurements of the reaction between thioredoxin and thioredoxin reductase show that G33D mutant and the wild-type proteins have identical kcat values. However, the Km for G33D mutant is approximately 10-fold higher than that for the wild-type protein. In vivo assay of the growth of E. coli strain carrying wild-type or G33D mutant thioredoxin on methionine sulfoxide indicates that the G33D mutant protein is a slower electron donor for methionine sulfoxide reductase. Structural stability of the oxidized protein is not altered by the G33D substitution, as illustrated by the same unfolding free energies studied by urea. The substitution does not show significant change of the near UV and far-UV circular dichroic (CD) and the fluorescence spectra for either the reduced or the oxidized protein. Therefore, the global structure of the G33D protein is not changed. However, the surface of the active site has been altered locally by G33D substitution, which accounts for the above kinetically poor behaviors. A model of G33D structure is constructed based on these studies.     

Characterization of the structure and dynamics of amyloidogenic variants of human lysozyme by NMR spectroscopy

The structures and dynamics of the native states of two mutational variants of human lysozyme, I56T and D67H, both associated with non-neuropathic systemic amyloidosis, have been investigated by NMR spectroscopy. The (1)H and (15)N main-chain amide chemical shifts of the I56T variant are very similar to those of the wild-type protein, but those of the D67H variant are greatly altered for 28 residues in the beta-domain. This finding is consistent with the X-ray crystallographic analysis, which shows that the structure of this variant is significantly altered from that of the wild-type protein in this region. The (1)H-(15)N heteronuclear NOE values show that, with the exception of V121, every residue in the wild-type and I56T proteins is located in tightly packed structures characteristic of the native states of most proteins. In contrast, D67H has a region of substantially increased mobility as shown by a dramatic decrease in heteronuclear NOE values of residues near the site of mutation. Despite this unusual flexibility, the D67H variant has no greater propensity to form amyloid fibrils in vivo or in vitro than has I56T. This finding indicates that it is the increased ability of the variants to access partially folded conformations, rather than intrinsic changes in their native state properties, that is the origin of their amyloidogenicity.     

Manganese (II) electron spin resonance and cadmium-113 nuclear magnetic resonance evidence for the nature of the calcium binding site in alpha-lactalbumins

Bovine and goat alpha-lactalbumins were substituted with 113Cd(II) or Mn(II) at the strong calcium site [Murakami, K., Andree, P.J., & Berliner, L.J. (1982) Biochemistry 21, 5488-5494] and studied by 113 Cd NMR and electron spin resonance. The 113Cd chemical shifts were in the -80 to -85 ppm range vs. Cd(ClO4)2, which was almost identical with that found for several nearly octahedral (oxygen-coordinated) calcium binding proteins such as calmodulin, parvalbumin, and troponin C. The electron spin resonance spectra of bound Mn(II)-alpha-lactalbumin complexes at 9 or 35 GHz were also confirmatory of a highly symmetric (cubic) environment around the Mn(II) with only slight distortions. The near identity of this site in alpha-lactalbumin to those of calcium binding proteins containing an "EF hand domain" was remarkable despite the absence of such a domain sequence in the alpha-lactalbumin structure.     

The effect of formate on cytochrome aa3 and on electron transport in the intact respiratory chain.

1. Formate inhibits cytochrome c oxidase activity both in intact mitochondria and submitochondrial particles, and in isolated cytochrome aa3. The inhibition increases with decreasing pH, indicating that HCOOH may be the inhibitory species. 2. Formate induces a blue shift in the absorption spectrum of oxidized cytochrome aa3 (a3 + a33+) and in the half-reduced species (a2 + a33+). Comparison with cyanide-induced spectral shifts, towards the red, indicates that formate and cyanide have opposite effects on the aa3 spectrum, both in the fully oxidized and the half-reduced states. The formate spectra provide a new method of obtaining the difference spectrum of a32+ minus a33+, free of the difficulties with cyanide (which induces marked high leads to low spin spectral shifts in cytochrome a33+) and azide (which induces peak shifts of cytochrome a2+ towards the blue in both alpha- and Soret regions). 3. The rate of formate dissociation from cytochrome a2+ a33+ -HCOOH is faster than its rate of dissociation from a3+ a33+ -HCOOH, especially in the presence of cytochrome c. The Ki for formate inhibition of respiration is a function of the reduction state of the system, varying from 30 mM (100% reduction) to 1 mM (100% oxidation) at pH 7.4, 30 degrees C. 4. Succinate-cytochrome c reductase activity is also inhibited by formate, in a reaction competitive with succinate and dependent on [formate]2. 5. Formate inhibition of ascorbate plus N, N, N', N'-tetramethyl-p-phenylenediamine oxidation by intact rat liver mitochondria is partially released by uncoupler addition. Formate is permeable through the inner mitochondrial membrane and no differences in 'on' or 'off' inhibition rates were observed when intact mitochondria were compared with submitochondrial particles. 6. NADH-cytochrome c reductase activity is unaffected by formate in submitochondrial particles, but mitochondrial oxidation of glutamate plus malate is subject both to terminal inhibition at the cytochrome aa3 level and to a slow extra inhibition by formate following uncoupler addition, indicating a third site of formate action in the intact mitochondrion.     

Properties and crystal structure of a beta-barrel folding mutant

A mutant of a beta-barrel protein, rat intestinal fatty acid binding protein, was predicted to be more stable than the wild-type protein due to a novel hydrogen bond. Equilibrium denaturation studies indicated the opposite: the V60N mutant protein was less stable. The folding transitions followed by CD and fluorescence were reversible and two-state for both mutant and wild-type protein. However, the rates of denaturation and renaturation of V60N were faster. During unfolding, the initial rate was associated with 75-80% of the fluorescence and all of the CD amplitude change. A subsequent rate accounted for the remaining fluorescence change for both proteins; thus the intermediate state lacked secondary structure. During folding, one rate was detected by both fluorescence and CD after an initial burst phase for both wild-type and mutant. An additional slower folding rate was detected by fluorescence for the mutant protein. The structure of the V60N mutant has been obtained and is nearly identical to prior crystal structures of IFABP. Analysis of mean differences in hydrogen bond and van der Waals interactions did not readily account for the stability loss due to the mutation. However, significant average differences of the solvent accessible surface and crystallographic displacement factors suggest entropic destabilization.     

4D Non-uniformly sampled HCBCACON and 1 J(NCα)-selective HCBCANCO experiments for the sequential assignment and chemical shift analysis of intrinsically disordered proteins

A pair of 4D NMR experiments for the backbone assignment of disordered proteins is presented. The experiments exploit (13)C direct detection and non-uniform sampling of the indirectly detected dimensions, and provide correlations of the aliphatic proton (H(α), and H(β)) and carbon (C(α), C(β)) resonance frequencies to the protein backbone. Thus, all the chemical shifts regularly used to map the transient secondary structure motifs in the intrinsically disordered proteins (H(α), C(α), C(β), C', and N) can be extracted from each spectrum. Compared to the commonly used assignment strategy based on matching the C(α) and C(β) chemical shifts, inclusion of the H(α) and H(β) provides up to three extra resonance frequencies that decrease the chance of ambiguous assignment. The experiments were successfully applied to the original assignment of a 12.8 kDa intrinsically disordered protein having a high content of proline residues (26 %) in the sequence.     

Elimination of the disulfide bridge in the Rieske iron-sulfur protein allows assembly of the [2Fe-2S] cluster into the Rieske protein but damages the ubiquinol oxidation site in the cytochrome bc1 complex

The [2Fe-2S] cluster of the Rieske iron-sulfur protein is held between two loops of the protein that are connected by a disulfide bridge. We have replaced the two cysteines that form the disulfide bridge in the Rieske protein of Saccharomyces cerevisiae with tyrosine and leucine, and tyrosine and valine, to evaluate the effects of the disulfide bridge on assembly, stability, and thermodynamic properties of the Rieske iron-sulfur cluster. EPR spectra of the Rieske proteins lacking the disulfide bridge indicate the iron-sulfur cluster is assembled in the absence of the disulfide bridge, but there are significant shifts in all g values, indicating a change in the electronic structure of the [2Fe-2S] iron-sulfur center. In addition, the midpoint potential of the iron-sulfur cluster is lowered from 265 mV in the Rieske protein from wild-type yeast to 150 mV in the protein from the C164Y/C180L mutant and to 160 mV in the protein from the C164Y/C180V mutant. Ubiquinol-cytochrome c reductase activities of the bc(1) complexes with Rieske proteins lacking the disulfide bridge are less than 1% of the activity of the bc(1) complex from wild-type yeast, even though normal amounts of the iron-sulfur protein are present as judged by Western blot analysis. These activities are lower than the 105-115 mV decrease in the midpoint potential of the Rieske iron-sulfur cluster can account for. Pre-steady-state reduction of the bc(1) complexes with menadiol indicates that quinol is not oxidized through center P but is oxidized through center N. In addition, the levels of stigmatellin and UHDBT binding are markedly diminished, while antimycin binding is unaffected, in the bc(1) complexes with Rieske proteins lacking the disulfide bridge. Taken together, these results indicate that the ubiquinol oxidation site at center P is damaged in the bc(1) complexes with Rieske proteins lacking the disulfide bridge even though the iron-sulfur cluster is assembled into the Rieske protein.     

Flavin-protein interactions in flavocytochrome b2 as studied by NMR after reconstitution of the enzyme with 13C- and 15N-labelled flavin.

A new procedure was devised for reversibly removing the flavin from flavocytochrome b2. It allowed reconstitution with selectively enriched 13C- and 15N-labelled FMN for an NMR analysis of the chemical shifts of the enriched positions as well as that of 31P. From these measurements, it was possible to deduce information about the hydrogen-bonding pattern of FMN in the protein, the hybridization states of the nitrogen atoms and (in part) the pi-electron distribution. The carbonyl groups at C(2) and C(4) and the nitrogen atoms N(1) and N(5) form hydrogen bonds to the apoenzyme in both redox states. Nevertheless, according to 15N-chemical shifts, the bond from the protein to N(3) is very weak in both redox states, whereas that to N(5) is strong for the oxidized state, and is weakened upon flavin reduction. On the other hand, the 13C-NMR results indicate that the C(2) and C(4) carbonyl oxygens form stronger hydrogen bonds with the enzyme than most other flavoproteins in both redox states. From coupling constant measurements it is shown that the N(3) proton is not solvent accessible. Although no N-H coupling constant could be measured for N(5) in the reduced state due to lack of resolution, N(5) is clearly protonated in flavocytochrome b2 as in all other known flavoproteins. With respect to N(10), it is more sp3-hybridized in the oxidized state than in free FMN, whereas the other nitrogen atoms show a nearly planar structure. In the reduced state, N(5) and N(10) in bound FMN are both more sp3-hybridized than in free FMN, but N(5) exhibits a higher degree of sp3-hybridization than N(10), which is only slightly shifted out of the isoalloxazine plane. In addition, two-electron reduction of the enzyme leads to anion formation on N(1), as indicated by its 15N-chemical shift of N(1) and characteristic upfield shifts of the resonances of C(2), C(4) and C(4a) compared to the oxidized state, as observed for most flavoproteins. 31P-NMR measurements show that the phosphate geometry has changed in enzyme bound FMN compared to the free flavin in water, indicating a strong interaction of the phosphate group with the apoenzyme.     

15N-1H Residual dipolar coupling analysis of native and alkaline-K79A Saccharomyces cerevisiae cytochrome c

Residual dipolar couplings (RDCs) and pseudocontact shifts are experimentally accessible properties in nuclear magnetic resonance that are related to structural parameters and to the magnetic susceptibility anisotropy. We have determined RDCs due to field-induced orientation of oxidized-K79A and reduced cytochrome c at pH 7.0 and oxidized-K79A cytochrome c at pH 11.1 through measurements of amide (15)N-(1)H (1)J couplings at 800 and 500 MHz. The pH 7.0 RDCs for Fe(III)- and Fe(II)-cytochrome c together with available nuclear Overhauser effects were used to recalculate solution structures that were consistent with both sets of constraints. Molecular magnetic susceptibility anisotropy values were calculated for both redox states of the protein. By subtracting the residual dipolar couplings (RDCs) of the reduced form from those of the oxidized form measured at the same magnetic field (800 MHz), we found the RDC contribution of the paramagnetic metal ion in the oxidized protein. The magnetic susceptibility anisotropy, which was calculated from the structure, was found to be the same as that of the paramagnetic metal ion obtained independently from pseudocontact shifts, thereby indicating that the elements of secondary structure either are rigid or display the same mobility in both oxidation states. The residual dipolar coupling values of the alkaline-K79A form are small with respect to those of oxidized native cytochrome, whereas the pseudocontact shifts are essentially of the same magnitude, indicating local mobility. Importantly, this is the first time that mobility has been found through comparison of RDCs with pseudocontact shifts.     

Backbone dynamics and energetics of a calmodulin domain mutant exchanging between closed and open conformations.

Previous studies have suggested that the Ca2+-saturated E140Q mutant of the C-terminal domain of calmodulin exhibits equilibrium exchange between "open" and "closed" conformations similar to those of the Ca2+-free and Ca2+-saturated states of wild-type calmodulin. The backbone dynamics of this mutant were studied using15N spin relaxation experiments at three different temperatures. Measurements at each temperature of the15N rate constants for longitudinal and transverse auto-relaxation, longitudinal and transverse cross-correlation relaxation, and the1H-15N cross-relaxation afforded unequivocal identification of conformational exchange processes on microsecond to millisecond time-scales, and characterization of fast fluctuations on picosecond to nanosecond time-scales using model-free approaches. The results show that essentially all residues of the protein are involved in conformational exchange. Generalized order parameters of the fast internal motions indicate that the conformational substates are well folded, and exclude the possibility that the exchange involves a significant population of unfolded or disordered species. The temperature dependence of the order parameters offers qualitative estimates of the contribution to the heat capacity from fast fluctuations of the protein backbone, revealing significant variation between the well-ordered secondary structure elements and the more flexible regions. The temperature dependence of the conformational exchange contributions to the transverse auto-relaxation rate constants directly demonstrates that the microscopic exchange rate constants are greater than 2.7x10(3)s-1at 291 K. The conformational exchange contributions correlate with the chemical shift differences between the Ca2+-free and Ca2+-saturated states of the wild-type protein, thereby substantiating that the conformational substates are similar to the open and closed states of wild-type calmodulin. Taking the wild-type chemical shifts to represent the conformational substates of the mutant and populations estimated previously, the microscopic exchange rate constants could be estimated as 2x10(4)to 3x10(4)s-1at 291 K for a subset of residues. The temperature depen dence of the exchange allows the characterization of apparent energy barriers of the conformational transition, with results suggesting a complex process that does not correspond to a single global transition between substates.