Redox-dependent conformational selection in a Cys4Fe2S2 ferredoxin.

Putidaredoxin (Pdx), a Cys4Fe2S2 ferredoxin from Pseudomonas putida, exhibits redox-dependent binding to its physiological redox partner, cytochrome P450(cam) (CYP101), with the reduced form of Pdx (Pdx(r)) binding with greater affinity to oxidized camphor-bound CYP101 than the oxidized form, Pdx(o). It has been previously shown that Pdx(o) is more dynamic than Pdx(r) on all accessible time scales, and it has been proposed that Pdx(r) samples only a fraction of the conformational substates populated by Pdx(o) on a time average. It is postulated that the ensemble subset populated by Pdx(r) is the same subset that binds CYP101, providing a mechanism for coupling the Pdx oxidation state to binding affinity for CYP101. Evidence from a variety of sources, including redox-dependent shifts of 15N and 13C resonances, indicates that the metal cluster binding loop of Pdx is the primary determinant of redox-dependent conformational selection. Patterns of paramagnetic effects suggest that the metal cluster binding loop contracts around the metal cluster upon reduction, possibly due to the strengthening of hydrogen bonds between the sulfur atoms of the metal cluster and the surrounding polypeptide NH and OH groups. Effects of this perturbation are then transmitted mechanically to other affected regions of the protein. A specific mutation has been introduced into the metal binding loop of Pdx, G40N, that slows conformational exchange sufficiently that the ensemble of conformational substates in Pdx(o) are directly observable as severe broadenings or splittings in affected NMR resonances. Many of the residues most affected by the mutation also show significant exchange contributions to 15N T(2) relaxation in wild-type Pdx(o). As predicted, G40N Pdx(r) shows a collapse of many of these multiplets and broadened lines to form much sharper resonances that are essentially identical to those observed in wild-type Pdx(r), indicating that Pdx(r) occupies fewer conformational substates than does Pdx(o). This is the first direct observation of such redox-dependent ensembles at slow exchange on the chemical shift time scale. These results confirm that conformational selection within the Fe2S2 cluster binding loop is the primary source of redox-dependent changes in protein dynamics in Pdx.

Mechanistic studies of two dioxygenases in the methionine salvage pathway of Klebsiella pneumoniae.

Two dioxygenases (ARD and ARD') were cloned from Klebsiella pneumoniae that catalyze different oxidative decomposition reactions of an advanced aci-reductone intermediate, CH(3)SCH(2)CH(2)COCH(OH)=CH(OH) (I), in the methionine salvage pathway. The two enzymes are remarkable in that they have the same polypeptide sequence but bind different metal ions (Ni(2+) and Fe(2+), respectively). ARD converts I to CH(3)SCH(2)CH(2)COOH, CO, and HCOOH. ARD' converts I to CH(3)SCH(2)CH(2)COCOOH and HCOOH. Kinetic analyses suggest that both ARD and ARD' have ordered sequential mechanisms. A model substrate (II), a dethio analogue of I, binds to the enzyme first as evidenced by its lambda(max) red shift upon binding. The dianion formation from II causes the same lambda(max) red shift, suggesting that II bind to the enzyme as a dianion. The electron-rich II dianion likely reacts with O(2) to form a peroxide anion intermediate. Previous (18)O(2) and (14)C tracer experiments established that ARD incorporates (18)O(2) into C(1) and C(3) of II and C(2) is released as CO. ARD' incorporates (18)O(2) into C(1) and C(2) of II. The product distribution seems to necessitate the formation of a five-membered cyclic peroxide intermediate for ARD and a four-membered cyclic peroxide intermediate for ARD'. A model chemical reaction demonstrates the chemical and kinetic competency of the proposed five-membered cyclic peroxide intermediate. The breakdown of the four-membered and five-membered cyclic peroxide intermediates gives the ARD' and ARD products, respectively. The nature of the metal ion appears to dictate the attack site of the peroxide anion and, consequently, the different cyclic peroxide intermediates and the different oxidative cleavages of II. A cyclopropyl substrate analogue inactivates both enzymes after multiple turnovers, providing evidence that a radical mechanism may be involved in the formation of the peroxide anion intermediate.

Nuclear magnetic resonance as a tool in drug discovery, metabolism and disposition.

Nuclear magnetic resonance techniques have become critically important in the design of new pharmaceuticals, the characterization of drug-receptor interactions and metabolite identification. Advances in solvent suppression, coherent and incoherent magnetization transfer pathway selection, isotope editing and filtering, and diffusion filtering have made it possible to examine the interactions between small molecules and proteins or nucleic acids in great detail. Multiple schemes for high-throughput lead compound identification, metabolite screening and drug disposition have been proposed and reduced to practice. In particular, the coupling of NMR with other analytical methods, especially HPLC, combine the structural and dynamic detail available from NMR methods with the resolution and sensitivity of other analytical techniques.

Solution structure and dynamics of a serpin reactive site loop using interleukin 1beta as a presentation scaffold.

Human interleukin-1beta (IL1beta) was used as a presentation scaffold for the characterization of the reactive site loop (RSL) of the serpin alpha1-antitrypsin (A1AT), the physiological inhibitor of leukocyte elastase. A chimeric protein was generated by replacement of residues 50-53 of IL1beta, corresponding to an exposed reverse turn in IL1beta, with the 10-residue P5-P5' sequence EAIPMSIPPE from A1AT. The chimera (antitrypsin-interleukin, AT-IL) inhibits elastase specifically and also binds the IL1beta receptor. Multinuclear NMR characterization of AT-IL established that, with the exception of the inserted sequence, the structure of the IL1beta scaffold is preserved in the chimera. The structure of the inserted RSL was analyzed relative to that of the isolated 10-residue RSL peptide, which was shown to be essentially disordered in solution. The chimeric RSL was also found to be solvent exposed and conformationally mobile in comparison with the IL1beta scaffold, and there was no evidence of persisting interactions with the scaffold outside of the N- and C-terminal linkages. However, AT-IL exhibits sigificant differences in chemical shift and NOE patterns relative to the isolated RSL that are consistent with local features of non-random structure. The proximity of these features to the P1-P1' residues suggests that they may be responsible for the inhibitory activity of the chimera.

Thermodynamics of interactions between amino acid side chains: experimental differentiation of aromatic-aromatic, aromatic-aliphatic, and aliphatic-aliphatic side-chain interactions in water.

A stationary phase for high-pressure liquid chromatography has been prepared by derivatizing microparticulate silica gel with functionality mimicking the side chain of isoleucine. The chromatographic retentions of a series of hydrophobic and amphiphilic amino acid analytes on this stationary phase (Ile MSP) using an aqueous mobile phase were measured as a function of temperature from 273 K to 323 K. Observed temperature dependencies are consistent with a constant change in heat capacity, DeltaC degrees P, upon binding of the analyte to the stationary phase. The curvatures of plots of retention data versus temperature (related to the magnitude of DeltaC degrees P) are distinctly different for retention of aromatic and aliphatic analytes, with retention of aliphatic analytes Val, Ile, and Leu exhibiting the characteristic signature of the hydrophobic effect, i.e., a large negative DeltaC degrees P upon desolvation from water and a maximum of retention around room temperature. Retention of aromatic analytes (Trp, Phe, and Tyr) involves smaller heat capacity changes and pronounced negative enthalpies of interaction with the stationary phase. Estimates of DeltaC degrees P for the interactions of analyte side chains with the Ile side chain were obtained by fitting the temperature dependence of retention to an expression derived from thermodynamic considerations and chromatographic theory. Similar estimates were made for interactions with the Phe side chain, using previously published data for a phenylalanine mimic stationary phase (Phe MSP) (. Protein Sci. 1:786-795). As with the Ile MSP, the retentions of aliphatic analytes show temperature dependencies markedly different from those of aromatic analytes. Data from both phases indicate that a realistic differentiation can be made between the interactions of various types of amino acid side chains tested (i.e., aliphatic/aliphatic, aliphatic/aromatic, and aromatic/aromatic) by comparison of the corresponding thermodynamic functions for pairwise interactions. The retention of leucine on the Phe MSP and that of phenylalanine on the Ile MSP showed similar DeltaC degrees P values, suggesting that the aromatic-aliphatic interaction is reasonably independent of the residue attached to the stationary phase. This result is consistent with a one-to-one interaction and suggests a simple way to estimate the column-dependent phase factor, making it possible to compare entropies and free energies of interaction obtained using different MSPs. The possibilities for using MSP-derived interaction potentials in folding simulations are discussed.

A new assignment strategy for the hyperfine-shifted 13C and 15N resonances in Fe2S2 ferredoxins.

Assignment of hyperfine-shifted resonances in paramagnetic metalloproteins such as Fe2S2 ferredoxins poses a major experimental challenge due to hyperfine shifts and/or severe line broadening. We have explored the possibility of using structural data from homologous proteins as part of an assignment strategy for the sequence-specific assignment of hyperfine-shifted backbone carbonyl (13C') and nitrogen resonances (15N) in Fe2S2 ferredoxins. This strategy is based on the assignment of resonances in the paramagnetic region to particular types of amino acid residues using selective isotope labeling. Reduced metal-nuclear distances are then calculated from experimentally determined T1 relaxation times for those resonances and the calculated distances aligned with the distances of nuclei at corresponding amino acid sequence positions in the crystal structure of a structurally homologous protein. The comparative assignment approach has met with success in correctly predicting the 13C' and 15N assignments in Pdx degrees from the crystal structure data of two similar and related ferredoxins, namely bovine adrenodoxin and Anabaena ferredoxin. Sequence-specific assignments made in this fashion were verified by selective 13C'{15N} decoupling experiments.

A model for the solution structure of oxidized terpredoxin, a Fe2S2 ferredoxin from Pseudomonas.

Terpredoxin (Tdx) is a 105-residue bacterial ferredoxin consisting of a single polypeptide chain and a single Fe2S2 prosthetic group. Tdx was first identified in a strain of Pseudomonas sp. capable of using alpha-terpineol as sole carbon source. The Tdx gene, previously cloned from the plasmid-encoded terp operon, that carries genes encoding for proteins involved in terpineol catabolism, has been subcloned and expressed as the holoprotein in E. coli. Physical characterization of the expressed Tdx has been performed, and a model for the solution structure of oxidized Tdx (Tdxo) has been determined. High-resolution homo- and heteronuclear NMR data have been used for structure determination in diamagnetic regions of the protein. The structure of the metal binding site (which cannot be determined directly by NMR methods due to paramagnetic broadening of resonances) was modeled using restraints obtained from a crystal structure of the homologous ferredoxin adrenodoxin (Adx) and loose restraints determined from paramagnetic broadening patterns in NMR spectra. Essentially complete 1H and 15N NMR resonance assignments have been made for the diamagnetic region of Tdxo (ca. 80% of the protein). A large five-stranded beta-sheet and a smaller two-stranded beta-sheet were identified, along with three alpha-helices. A high degree of structural homology was observed between Tdx and two other ferredoxins with sequence and functional homology to Tdx for which structures have been determined, Adx and putidaredoxin (Pdx), a homologous Pseudomonas protein. 1H/2H exchange rates for Tdx backbone NH groups were measured for both oxidation states and are rationalized in the context of the Tdx structure. In particular, an argument is made for the importance of the residue following the third ligand of the metal cluster (Arg49 in Tdx, His49 in Pdx, His56 in Adx) in modulating protein dynamics as a function of oxidation state. Some differences between Tdx and Pdx are detected by UV-visible spectroscopy, and structural differences at the C-terminal region were also observed. Tdx exhibits only 2% of the activity of Pdx in turnover assays performed using the reconstituted camphor hydroxylase system of which Pdx is the natural component.

A refined model for the solution structure of oxidized putidaredoxin.

A refined model for the solution structure of oxidized putidaredoxin (Pdxo), a Cys4Fe2S2 ferredoxin, has been determined. A previous structure (Pochapsky et al. (1994) Biochemistry 33, 6424-6432; PDB entry ) was calculated using the results of homonuclear two-dimensional NMR experiments. New data has made it possible to calculate a refinement of the original Pdxo solution structure. First, essentially complete assignments for diamagnetic 15N and 13C resonances of Pdxo have been made using multidimensional NMR methods, and 15N- and 13C-resolved NOESY experiments have permitted the identification of many new NOE restraints for structural calculations. Stereospecific assignments for leucine and valine CH3 resonances were made using biosynthetically directed fractional 13C labeling, improving the precision of NOE restraints involving these residues. Backbone dihedral angle restraints have been obtained using a combination of two-dimensional J-modulated 15N,1H HSQC and 3D (HN)CO(CO)NH experiments. Second, the solution structure of a diamagnetic form of Pdx, that of the C85S variant of gallium putidaredoxin, in which a nonligand Cys is replaced by Ser, has been determined (Pochapsky et al. (1998) J. Biomol. NMR 12, 407-415), providing information concerning structural features not observable in the native ferredoxin due to paramagnetism. Third, a crystal structure of a closely related ferredoxin, bovine adrenodoxin, has been published (Müller et al. (1998) Structure 6, 269-280). This structure has been used to model the metal binding site structure in Pdx. A family of fourteen structures is presented that exhibits an rmsd of 0.51 A for backbone heavy atoms and 0.83 A for all heavy atoms. Exclusion of the modeled metal binding loop region reduces overall the rmsd to 0.30 A for backbone atoms and 0.71 A for all heavy atoms.

The solution structure of a gallium-substituted putidaredoxin mutant: GaPdx C85S.

The Fe2S2 cluster of the ferredoxin putidaredoxin (Pdx) can be replaced by a single gallium ion, giving rise to a colorless, diamagnetic protein in which, apart from the metal binding site, the major structural features of the native ferredoxin are conserved. The solution structure of the C85S variant of gallium putidaredoxin (C85S GaPdx), in which a non-ligand cysteine is replaced by a serine, has been determined via multidimensional NMR methods using uniformly 15N, 13C labeled samples of C85S GaPdx. Stereospecific assignments of leucine and valine methyl resonances were made using 13C, 1H HSQC spectra obtained with fractionally 13C-labeled samples, and backbone dihedral angle restraints were obtained using a combination of two-dimensional J-modulated 15N, 1H HSQC and three-dimensional (HN)CO(CO)NH experiments. A total of 1117 NOE-derived distance restraints were used in the calculations, including 454 short range (i-j < or = 3), 456 long range (i-j > or = 4) interresidue restraints and 207 non-trivial intraresidue restraints. 97 phi and 55 chi 1 angular restraints were also included in the calculation of a family of 20 structures using a combined distance geometry-simulated annealing protocol. Most regions of the protein are well defined in the calculations, with an RMSD of 0.525 A for backbone atoms excluding the metal binding loop (residues 34-48) and the last three C-terminal residues (residues 103-106). Where comparison is possible, these regions show an increase in dynamic behavior over the native protein, as does the loop containing residues 74-76. Structural and dynamic differences between native Pdx and GaPdx are discussed in relation to charge and packing of the metal binding site.

Structural features of the metal binding site and dynamics of gallium putidaredoxin, a diamagnetic derivative of a Cys4Fe2S2 ferredoxin.

The first reconstitution of an Fe2S2 ferredoxin with a diamagnetic prosthetic group was recently described [Kazanis et al. (1995) J. Am. Chem. Soc., 117, 6625-6626]. The replacement of the iron-sulfur cluster of the bacterial ferredoxin putidaredoxin (Pdx) by gallium (Ga3+) renders the protein diamagnetic and permits the use of high-resolution NMR methods to identify resonances near the metal binding site. We now describe structural features of the metal binding site that are not observable by standard NMR methods in native Pdx due to paramagnetic line broadening. These results provide the first example of high-resolution NMR-derived structural data concerning the metal binding domain of an Fe2S2 ferredoxin, and the first structural information of any sort for the metal binding site of a ferredoxin from this class, which includes adrenodoxin, placental ferredoxin and terpredoxin. Assignments were obtained by applying multidimensional NMR methods to a series of selectively and nonselectively 15N- and 13C/15N-labeled GaPdx samples. For most experiments, a mutant of Pdx was used in which a nonligating Cys85 is replaced by serine. All of the major structural features that were identified in native Pdx are conserved in GaPdx. The overall protein dynamics is considerably faster in GaPdx than in the native protein, as reflected by amide proton exchange rates. The C-terminal residue, Trp106, also exhibits considerable mobility, as indicated by 15N[1H] NOE and 15N T1 values of the C-terminal residue of the protein.

Estimates for the potential accuracy required in realistic protein folding simulations and structure recognition experiments.

BACKGROUND: We have recently addressed the problem of the potential accuracy required for protein folding simulations using a combination of theoretical considerations and lattice model simulations. In the present study, we combine the previously developed theoretical formalism with the law of corresponding states proposed recently by Onuchic, Wolynes and collaborators and obtain estimates for the potential accuracy required for computational studies of a small helical protein. RESULTS: Our estimates suggest that effective energies of interaction between amino acid residues could be measured with an error around +/- 330 cal mol-1 for a resulting inaccurate potential still appropriate for structure recognition experiments, where the native conformation must remain the global energy minimum. For an ab initio folding simulation, where the energy of the native conformation must be sufficient to balance the entropy of the denatured state at a temperature at which the dynamics of the system are fast, the permissible error depends on the simulation temperature and can be as high as +/- 120 cal mol-1. CONCLUSIONS: The results indicate that potentials do not need to be extremely accurate in order to be useful in computational studies. Results from different groups can be interpreted as an indication that available potentials are too inaccurate for ab initio simulations but not far from the permissive limit required for structure recognition.

Redox-dependent dynamics of putidaredoxin characterized by amide proton exchange.

Multidimensional NMR methods were used to obtain 1H-15N correlations and 15N resonance assignments for amide and side-chain nitrogens of oxidized and reduced putidaredoxin (Pdx), the Fe2S2 ferredoxin, which acts as the physiological reductant of cytochrome P-450cam (CYP101). A model for the solution structure of oxidized Pdx has been determined recently using NMR methods (Pochapsky TC, Ye XM, Ratnaswamy G, Lyons TA, 1994, Biochemistry 33:6424-6432) and redox-dependent 1H NMR spectral features have been described (Pochapsky TC, Ratnaswamy G, Patera A, 1994, Biochemistry 33:6433-6441). 15N assignments were made with NOESY-(1H/15N) HMQC and TOCSY-(1H/15N) HSQC spectra obtained using samples of Pdx uniformly labeled with 15N. Local dynamics in both oxidation states of Pdx were then characterized by comparison of residue-specific amide proton exchange rates, which were measured by a combination of saturation transfer and H2O/D2O exchange methods at pH 6.4 and 7.4 (uncorrected for isotope effects). In general, where exchange rates for a given site exhibit significant oxidation-state dependence, the oxidized protein exchanges more rapidly than the reduced protein. The largest dependence of exchange rate upon oxidation state is found for residues near the metal center and in a region of compact structure that includes the loop-turn Val 74-Ser 82 and the C-terminal residues (Pro 102-Trp 106). The significance of these findings is discussed in light of the considerable dependence of the binding interaction between Pdx and CYP101 upon the oxidation state of Pdx.

A structure-based model for cytochrome P450cam-putidaredoxin interactions.

Putidaredoxin (Pdx) is a Fe2S2 ferredoxin which acts as the physiological reductant of cytochrome P-450cam (CYP101). A model for the solution structure of oxidized Pdx has been determined using NMR methods (Pochapsky et al (1994) Biochemistry 33, 6424-6432). 1H-15N correlations and redox-dependent amide exchange rates have also been described (Lyons et al (1996) Protein Sci 5, 627-639). Data obtained from mutagenesis and kinetic measurements concerning the interactions of Pdx and CYP101 are summarized. A model for the structure of the homologous ferredoxin adrenodoxin (Adx) is also described, and data concerning Adx activity are discussed in relation to this structure. The structures of Pdx and CYP101 were used as starting points for molecular modeling and molecular dynamics simulations. Close approach between the metal centers of the two proteins and interaction between aromatic residues on the surfaces of the proteins are premised. The resulting complex exhibits three intermolecular salt bridges, five intermolecular hydrogen bonds and a 12 A distance between the metal centers. The first direct observations of interaction between Pdx and CYP101 (by two-dimensional NMR of 15N-labeled Pdx in solution with CYP101) are described. The results of the NMR experiments indicate that conformational gating of the electron transfer complex between CYP101 and Pdx may be important.

Monte Carlo simulations of protein folding using inexact potentials: how accurate must parameters be in order to preserve the essential features of the energy landscape?

BACKGROUND: Monte Carlo simulations of the cubic lattice protein model with engineered sequences were performed in order to address the issue of potential accuracy required for folding. The potential used for sequence selection played the role of the 'real' potential and different levels of inaccuracy were introduced by addition of noise. RESULTS: The dependence of successful folding probability on potential noise was found to be sigmoidal and sequence-specific and can be described by an expression analytically derived from a simple theoretical model in which the density of states of the system contains a continuous region approximated by a Gaussian distribution separated from the unique native conformation by a large energy gap. CONCLUSIONS: The decrease in folding probability with potential inaccuracy results from an average decrease in the energy gap. Sequences with large energy gaps support larger inaccuracies while retaining the ability to fold properly. As the energy gap is known to correlate with thermal stability, we suggest a simple criterion for specific real sequence selection in order to maximize success probability in realistic folding simulations.

1H and 15N resonance assignments and secondary structure of the carbon monoxide complex of sperm whale myoglobin.

Sequence-specific backbone 1H and 15N resonance assignments have been made for 95% of the amino acids in sperm whale myoglobin, complexed with carbon monoxide (MbCO). Many assignments for side-chain resonances have also been obtained. Assignments were made by analysis of an extensive series of homonuclear 2D spectra, measured with unlabeled protein, and both 2D and 3D 1H-15N-correlated spectra obtained from uniformly 15N-labeled myoglobin. Patterns of medium-range NOE connectivities indicate the presence of eight helices in positions that are very similar to those found in the crystal structures of sperm whale myoglobin. The resonance assignments of MbCO form the basis for determination of the solution structure and for hydrogen-exchange measurements to probe the stability and folding pathways of myoglobin. They will also form a basis for assignment of the spectra of single-site mutants with altered ligand-binding properties.

Redox-dependent 1H NMR spectral features and tertiary structural constraints on the C-terminal region of putidaredoxin.

Putidaredoxin (Pdx) is a 106-residue Fe2S2 ferredoxin which acts as the physiological reductant and effector of cytochrome P-450cam. Pdx has two accessible oxidation states, Fe+3-Fe+3 (oxidized) and Fe+3-Fe+2 (reduced), and exhibits redox-dependent binding affinities for cytochrome P-450cam, with reduced Pdx binding over 100-fold more tightly than oxidized Pdx to the oxidized cytochrome P-450cam [Hintz, M. J., Mock, D. M., Peterson, L. L., Tuttle, K., & Peterson, J. A. (1982) J. Biol. Chem. 257, 14324-14332]. The analysis of two-dimensional 1H NMR experiments has yielded sequential 1H resonance assignments for the diamagnetic regions of the reduced form of Pdx, which are compared to those of oxidized Pdx, described previously [Ye, X. M., Pochapsky, T. C., & Pochapsky, S. S. (1992) Biochemistry 31, 1961-1968]. Increased unpaired electron-spin density on the metal cluster in reduced relative to oxidized Pdx increases the number of 1H resonances which are broadened by the metal cluster, and the pattern of paramagnetic broadening provides information concerning the placement of the metal cluster within the protein. Two-dimensional exchange experiments on half-reduced samples of Pdx indicate that electron self-exchange is slow on the chemical shift time scale, with a second-order rate constant < or = 66 M-1 s-1 at 290 K. Spectral changes unrelated to increases in unpaired electron-spin density are also observed. The largest changes of this type are observed for features structurally contiguous with the C-terminal region Pro 102-Trp 106. The C-terminal residue Trp 106 has been implicated in binding to cytochrome P-450cam.(ABSTRACT TRUNCATED AT 250 WORDS)

An NMR-derived model for the solution structure of oxidized putidaredoxin, a 2-Fe, 2-S ferredoxin from Pseudomonas.

A model for the solution structure of oxidized putidaredoxin (Pdx), a 106-residue globular protein containing a Fe2S2 cluster, has been determined using homonuclear NMR methods. Pdx is the first of the class of Fe2S2Cys4 ferredoxins which act as electron-transfer partners for P-450 monooxygenases to be structurally characterized, and no crystal structure has been determined for Pdx or for any closely homologous protein. Pdx is the physiological redox partner of cytochrome P-450cam. A total of 878 NOE distance constraints, 66 phi angular constraints derived from NH-C alpha H coupling constants, and five paramagnetic broadening constraints were used in simulated annealing structural refinements to obtain a family of structures with pairwise rms deviations of 1.14 A for backbone atoms and 1.80 A for all non-hydrogen atoms. Paramagnetic broadening of resonances within a ca. 8-A radius of the metal cluster prevents the use of NMR-derived constraints in this region of the protein; structural constraints used to model the environment of the metal cluster were obtained from site-directed mutagenesis and model compounds and by comparison with known ferredoxin structures. Pdx retains a similar folding topology to other structurally characterized Fe2S2Cys4 ferredoxins but differs from the other ferredoxins in containing a significantly more compact structure in the C-terminal half of the protein.

Interpretation of hyperfine shift patterns in ferricytochromes b5 in terms of angular position of the heme: a sensitive probe for peripheral heme protein interactions.

The 1H-NMR hyperfine shift pattern of the heme in a variety of low-spin ferricytochromes b5 has been analyzed in terms of the angular position of the prosthetic group within a structurally and magnetically-conserved protein matrix. A simple model is presented in which the changes in the spread of the predominantly contact shifted methyl and predominantly dipolar shifted meso-H signals of the heme, as well as shift trends for individual signals, provide sensitive indicators of the orientation of the heme relative to the orbital hole (singly-occupied d orbital), which in turn is related to the rhombic magnetic axes. The invariance of the axial His and non-coordinated residue hyperfine shifts show that it is the heme within a relatively rigid protein matrix, rather than the magnetic coordinate system, which is displaced angularly about the heme normal in order to accommodate variations in the polypeptide, orientation of the heme about the alpha,gamma-meso axis, and the length of heme carboxylate chains. Native heme shows increased counterclockwise rotation about the heme normal in the order rat-->beef-->chicken ferricytochrome b5, which is attributed largely to increased bulk of a variable sequence hydrophobic cluster consisting of residues 23, 25 and 32. The two alternate heme orientations about the alpha,gamma-meso axis are shown to also differ by rotation about the heme normal. A semiquantitative estimate of the degree of angular accommodation based on the spread of the meso-H rhombic dipolar shifts indicate rotations of 2-10 degrees. Possible functional consequences of such angular accommodation in relation to the role of these proteins in electron transfer are discussed.

A chromatographic approach to the determination of relative free energies of interaction between hydrophobic and amphiphilic amino acid side chains.

A liquid chromatographic stationary phase was prepared by covalently binding to the surface of microparticulate silica gel functionality (benzylsilane), which mimics the side chain of the amino acid phenylalanine. The chromatographic retentions of the N-acetyl C-(N'-methyl) amides of various hydrophobic and amphiphilic amino acids on this stationary phase were measured using an aqueous mobile phase. A retention order of Gly < Ala < Cys < Val < Met < Pro < Ile < Leu < Tyr < Phe < Trp is seen at room temperature. Chromatographic retentions were used to derive free energies of adsorption of the amino acid derivatives on the chromatographic support relative to that of the glycine derivative. The temperature dependencies of the retention of aromatic and aliphatic amino acid derivatives differ in curvature, indicating a qualitative difference in the absorption mechanism. An adsorption model for retention is proposed, and arguments are made as to the suitability of an adsorption model for describing the contacts between amino acid side chains during the initial steps of protein folding.