Three-dimensional structure of horse liver alcohol dehydrogenase at 2-4 A resolution.

The crystal structure analysis of horse liver alcohol dehydrogenase has been extended to 2.4 Å resolution. From the corresponding electron density map of the apoenzyme we have determined the positions of the 374 amino acids in the polypeptide chain of each subunit.The coenzyme binding domain of the subunit comprises residues 176 to 318. 45% of these residues are helical and 32% are in the central six-stranded pleated sheet structure. The positions and orientations of the helices with respect to the pleated sheet indicate a possible folding mechanism for this part of the subunit structure. The coenzyme analogue ADP-ribose binds to this domain in a position and orientation very similar to coenzyme binding to lactate dehydrogenase. The adenine part binds in a hydrophobic pocket, the adenosine ribose is hydrogen-bonded to the side chain of Asp223, the pyrophosphate is positioned by interaction with Arg47 and the nicotinamide ribose is 6Å away from the catalytic zinc atom.The catalytic domain is mainly built up from three distinct antiparallel pleated-sheet regions. Residues within this domain provide ligands to the catalytic zinc atom; Cys46, His67 and Cys174. An approximate tetrahedral coordination of this zinc is completed by a water molecule or hydroxyl ion depending on the pH. Residues 95 to 113 form a lobe that binds the second zinc atom of the subunit. This zinc is liganded in a distorted tetrahedral arrangement by four sulphur atoms from the cysteine residues 97, 100, 103 and 111. The lobe forms one side of a significant cleft in the enzyme surface suggesting that this region might constitute a second catalytic centre of unknown function.The two domains of the subunit are separated by a crevice that contains a wide and deep hydrophobic pocket. The catalytic zinc atom is at the bottom of this pocket, with the zinc-bound water molecule projecting out into the pocket. This water molecule is hydrogen-bonded to the side chain of Ser48 which in turn is hydrogen-bonded to His51. The pocket which in all probability is the binding site for the substrate and the nicotinamide moiety of the coenzyme, is lined almost exclusively with hydrophobic side chains. Both subunits contribute residues to each of the two substrate binding pockets of the molecule. The only accessible polar groups in the vicinity of the catalytic centre are Ser48 and Thr178 apart from zinc and the zinc-bound water molecule.     

Relating structure to thermodynamics: the crystal structures and binding affinity of eight OppA-peptide complexes.

The oligopeptide-binding protein OppA provides a useful model system for studying the physical chemistry underlying noncovalent interactions since it binds a variety of readily synthesized ligands. We have studied the binding of eight closely related tripeptides of the type Lysine-X-Lysine, where X is an abnormal amino acid, by isothermal titration calorimetry (ITC) and X-ray crystallography. The tripeptides fall into three series of ligands, which have been designed to examine the effects of small changes to the central side chain. Three ligands have a primary amine as the second side chain, two have a straight alkane chain, and three have ring systems. The results have revealed a definite preference for the binding of hydrophobic residues over the positively charged side chains, the latter binding only weakly due to unfavorable enthalpic effects. Within the series of positively charged groups, a point of lowest affinity has been identified and this is proposed to arise from unfavorable electrostatic interactions in the pocket, including the disruption of a key salt bridge. Marked entropy-enthalpy compensation is found across the series, and some of the difficulties in designing tightly binding ligands have been highlighted.     

QacR-cation recognition is mediated by a redundancy of residues capable of charge neutralization

The Staphylococcus aureus multidrug binding protein QacR binds to a broad spectrum of structurally dissimilar cationic, lipophilic drugs. Our previous structural analyses suggested that five QacR glutamic acid residues are critical for charge neutralization and specification of certain drugs. For example, E57 and E58 interact with berberine and with one of the positively charged moieties of the bivalent drug dequalinium. Here we report the structural and biochemical effects of substituting E57 and E58 with alanine and glutamine. Unexpectedly, individual substitutions of these residues did not significantly affect QacR drug binding affinity. Structures of QacR(E57Q) and QacR(E58Q) bound to dequalinium indicated that E57 and E58 are redundant for charge neutralization. The most significant finding was that berberine was reoriented in the QacR multidrug binding pocket so that its positive charge was neutralized by side chain oxygen atoms and aromatic residues. Together, these data emphasize the remarkable versatility of the QacR multidrug binding pocket, illustrating that the capacity of QacR to bind myriad cationic drugs is largely governed by the presence in the pocket of a redundancy of polar, charged, and aromatic residues that are capable of electrostatic neutralization.     

Toward tailoring the specificity of the S1 pocket of subtilisin B. lentus: chemical modification of mutant enzymes as a strategy for removing specificity limitations.

In both protein chemistry studies and organic synthesis applications, it is desirable to have available a toolbox of inexpensive proteases with high selectivity and diverse substrate preferences. Toward this goal, we have generated a series of chemically modified mutant enzymes (CMMs) of subtilisin B. lentus (SBL) possessing expanded S(1) pocket specificity. Wild-type SBL shows a marked preference for substrates with large hydrophobic P(1) residues, such as the large Phe P(1) residue of the standard suc-AAPF-pNA substrate. To confer more universal P(1) specificity on S(1), a strategy of chemical modification in combination with site-directed mutagenesis was applied. For example, WT-SBL does not readily accept small uncharged P(1) residues such as the -CH(3) side chain of alanine. Accordingly, with a view to creating a S(1) pocket that would be of reduced volume providing a better fit for small P(1) side chains, a large cyclohexyl group was introduced by the CMM approach at position S166C with the aim of partially filling up the S(1) pocket. The S166C-S-CH(2)-c-C(6)H(11) CMM thus created showed a 2-fold improvement in k(cat)/K(M) with the suc-AAPA-pNA substrate and a 51-fold improvement in suc-AAPA-pNA/suc-AAPF-pNA selectivity relative to WT-SBL. Furthermore, WT-SBL does not readily accept positively or negatively charged P(1) residues. Therefore, to improve SBL's specificity toward positively and negatively charged P(1) residues, we applied the CMM methodology to introduce complementary negatively and positively charged groups, respectively, at position S166C in S(1). A series of mono-, di-, and trinegatively charged CMMs were generated and all showed improved k(cat)/K(M)s with the positively charged P(1) residue containing substrate, suc-AAPR-pNA. Furthermore, virtually arithmetic improvements in k(cat)/K(M) were exhibited with increasing number of negative charges on the S166C-R side chain. These increases culminated in a 9-fold improvement in k(cat)/K(M) for the suc-AAPR-pNA substrate and a 61-fold improvement in suc-AAPR-pNA/suc-AAPF-pNA selectivity compared to WT-SBL for the trinegatively charged S166C-S-CH(2)CH(2)C(COO(-))(3) CMM. Conversely, the positively charged S166C-S-CH(2)CH(2)NH(3)(+) CMM generated showed a 19-fold improvement in k(cat)/K(M) for the suc-AAPE-pNA substrate and a 54-fold improvement in suc-AAPE-pNA/suc-AAPF-pNA selectivity relative to WT-SBL.     

Structural insight into repair of alkylated DNA by a new superfamily of DNA glycosylases comprising HEAT-like repeats

3-methyladenine DNA glycosylases initiate repair of cytotoxic and promutagenic alkylated bases in DNA. We demonstrate by comparative modelling that Bacillus cereus AlkD belongs to a new, fifth, structural superfamily of DNA glycosylases with an alpha-alpha superhelix fold comprising six HEAT-like repeats. The structure reveals a wide, positively charged groove, including a putative base recognition pocket. This groove appears to be suitable for the accommodation of double-stranded DNA with a flipped-out alkylated base. Site-specific mutagenesis within the recognition pocket identified several residues essential for enzyme activity. The results suggest that the aromatic side chain of a tryptophan residue recognizes electron-deficient alkylated bases through stacking interactions, while an interacting aspartate-arginine pair is essential for removal of the damaged base. A structural model of AlkD bound to DNA with a flipped-out purine moiety gives insight into the catalytic machinery for this new class of DNA glycosylases.     

Probing the Putative Active Site of YjdL: An Unusual Proton-Coupled Oligopeptide Transporter from E. coli

YjdL from E. coli is an unusual proton-coupled oligopeptide transporter (POT). Unlike prototypical POTs, dipeptides are preferred over tripeptides, in particular dipeptides with a positively charged C-terminal residue. To further understand this difference in peptide specificity, the sequences of YjdL and YdgR, a prototypical E. coli POT, were compared in light of the crystal structure of a POT from Shewanella oneidensis. Several residues found in the putative active site were mutated and the activities of the mutated variants were assessed in terms of substrate uptake assays, and changes in specificity in terms of uptake inhibition. Most strikingly, changing the YjdL specific Asp392 to the conserved Ser in YjdL obliterated the preference for a positively charged C-terminal residue. Based on this unique finding and previously published results indicating that the dipeptide N-terminus may interact with Glu388, a preliminary orientation model of a dipeptide in the YjdL cavity is presented. Single site mutations of particularly Ala281 and Trp278 support the presented orientation. A dipeptide bound in the cavity of YjdL appears to be oriented such that the N-terminal side chain protrudes into a sub pocket that opens towards the extracellular space. The C-terminal side chain faces in the opposite direction into a sub pocket that faces the cytoplasm. These data indicated a stabilizing effect on a bulky N-terminal residue by an Ala281Phe variant and on the dipeptide backbone by Trp278. In the presented orientation model, Tyr25 and Tyr58 both appear to be in proximity of the dipeptide backbone while Lys117 appears to be in proximity of the peptide C-terminus. Mutational studies of these conserved residues highlight their functional importance.     

SCAM analysis reveals a discrete region of the pore turret that modulates slow inactivation in Kv1.5

In Kv1.5, protonation of histidine 463 in the S5-P linker (turret) increases the rate of depolarization-induced inactivation and decreases the peak current amplitude. In this study, we examined how amino acid substitutions that altered the physico-chemical properties of the side chain at position 463 affected slow inactivation and then used the substituted cysteine accessibility method (SCAM) to probe the turret region (E456-P468) to determine whether residue 463 was unique in its ability to modulate the macroscopic current. Substitutions at position 463 of small, neutral (H463G and H463A) or large, charged (H463R, H463K, and H463E) side groups accelerated inactivation and induced a dependency of the current amplitude on the external potassium concentration. When cysteine substitutions were made in the distal turret (T462C-P468C), modification with either the positively charged [2-(trimethylammonium)ethyl] methanethiosulfonate bromide (MTSET) or negatively charged sodium (2-sulfonatoethyl) methanethiosulfonate reagent irreversibly inhibited current. This inhibition could be antagonized either by the R487V mutation (homologous to T449V in Shaker) or by raising the external potassium concentration, suggesting that current inhibition by MTS reagents resulted from an enhancement of inactivation. These results imply that protonation of residue 463 does not modulate inactivation solely by an electrostatic interaction with residues near the pore mouth, as proposed by others, and that residue 463 is part of a group of residues within the Kv1.5 turret that can modulate P/C-type inactivation. electrophysiology; voltage-gated potassium channels; substituted cysteine accessibility method     

Phospholipase A2 engineering. X-ray structural and functional evidence for the interaction of lysine-56 with substrates.

Site-directed mutagenesis studies of bovine pancreatic phospholipase A2 (PLA2, overproduced in Escherichia coli) showed that replacement of surface residue Lys-56 by a neutral or hydrophobic amino acid residue resulted in an unexpected and significant change in the function of the enzyme. The kcat for phosphatidylcholine micelles increases 3-4-fold for K56M, K56I, and K56F and ca. 2-fold for K56N and K56T but does not change for K56R. These results suggest that the side chain of residue 56 has significant influence on the activity of PLA2. In order to probe the structural basis for the enhanced activity, the crystal structures of wild-type and K56M PLA2 were determined by X-ray crystallography to a resolution of 1.8 A. The results suggest that the mutation has not only perturbed the conformation of the side chain of Met-56 locally but also caused conformational changes in the neighboring loop (residues 60-70), resulting in the formation of a hydrophobic pocket by residues Met-56, Tyr-52, and Tyr-69. Docking of a phosphatidylcholine inhibitor analogue into the active site of K56M, according to the structure of the complex of cobra venom PLA2-phosphatidylethanolamine inhibitor analogue [White, S.P., Scott, D. L., Otwinowski, Z., Gleb, M. H., & Sigler, P. (1990) Science 250, 1560-1563], showed that the choline moiety [N(CH3)3]+ is readily accommodated into the newly formed hydrophobic pocket with a high degree of surface complementarity. This suggests a possible interaction between residue 56 and the head group of the phospholipid, explaining the enhanced activities observed when the positively charged Lys-56 is substituted by apolar residues, viz., K56M, K56I, and K56F. Further support for this interpretation comes from the 5-fold enhancement in kcat for the mutant K56E with a negatively charged side chain, where there would be an attractive electrostatic interaction between the side chain of Glu-56 and the positively charged choline moiety. Our results also refute a recent report [Tomasselli, A. G., Hui, J., Fisher, J., Zürcher-Neely, H., Reardon, I.M., Oriaku, E., Kézdy, F.J., & Heinrikson, R.L. (1989) J. Biol. Chem. 264, 10041-10047] that substrate-level acylation of Lys-56 is an obligatory step in the catalysis by PLA2.     

Crystal structure of the kringle 2 domain of tissue plasminogen activator at 2.4-A resolution.

The crystal structure of the kringle 2 domain of tissue plasminogen activator was determined and refined at a resolution of 2.43 A. The overall fold of the molecule is similar to that of prothrombin kringle 1 and plasminogen kringle 4; however, there are differences in the lysine binding pocket, and two looping regions, which include insertions in kringle 2, take on very different conformations. Based on a comparison of the overall structural homology between kringle 2 and kringle 4, a new sequence alignment for kringle domains is proposed that results in a division of kringle domains into two groups, consistent with their proposed evolutionary relation. The crystal structure shows a strong interaction between a lysine residue of one molecule and the lysine/fibrin binding pocket of a noncrystallographically related neighbor. This interaction represents a good model of a bound protein ligand and is the first such ligand that has been observed in a kringle binding pocket. The structure shows an intricate network of interactions both among the binding pocket residues and between binding pocket residues and the lysine ligand. A lysine side chain is identified as the positively charged group positioned to interact with the carboxylate of lysine and lysine analogue ligands. In addition, a chloride ion is located in the kringle-kringle interface and contributes to the observed interaction between kringle molecules.     

A model for the C5a receptor and for its interaction with the ligand [corrected]

A model of the C5a receptor was built based on the assumption that the seven membrane-spanning helices of known inward/outward direction are in an arrangement roughly similar to that in bacteriorhodopsin. Guidelines for the positioning of the helices were cysteine pairing, 'ridges into grooves' interdigitation of side chains and aromatic cluster formation. The chain segments protruding from the membrane are too short for folding into an independent ectodomain. The only longer segment (179-202) is tied down in its centre onto the membrane by a disulphide bridge and, thereby, made into two short loops as well. Ideas of the interaction of the C5a receptor with its ligand were derived mainly from the search for accommodation of the functionally essential arginine residues 40 and 74 of C5a. Asp82 is the only charged residue in a pocket approximately 20 A below the receptor surface and is conserved in the rhodopsin superfamily. It commends itself for binding Arg74 which is the tip of the flexible C-terminal chain of C5a, and rules out Arg40 in the structurally well-defined part of the molecule. The latter may bind to Glu180 at the bottom of a more shallow pocket which happens to resemble the substrate-binding site of trypsin.     

Positively charged side chains in protein farnesyltransferase enhance catalysis by stabilizing the formation of the diphosphate leaving group

Protein farnesyltransferase (FTase) requires both Zn(2+) and Mg(2+) for efficient catalysis of the formation of a thioether bond between carbon-1 of farnesyldiphosphate (FPP) and the cysteine thiolate contained in the carboxy-terminal CaaX sequence of target proteins. Millimolar concentrations of Mg(2+) accelerate catalysis by as much as 700-fold in FTase. Although FTase lacks a typical DDXXD Mg(2+) binding site found in other enzymes that use Mg(2+) for diphosphate stabilization, D352beta in FTase has been implicated in binding Mg(2+) (Pickett et al. (2003) J. Biol. Chem. 278, 51243). Structural studies demonstrate that the diphosphate (PPi) group of FPP resides in a binding pocket made up of highly positively charged side chains, including residues R291beta and K294beta, prior to formation of an active conformation. Analysis of the Mg(2+) dependence of FTase mutants demonstrates that these positively charged residues decrease the Mg(2+) affinity up to 40-fold. In addition, these residues enhance the farnesylation rate constant by almost 80-fold in the presence of Mg(2+), indicating that these residues are not simply displaced by Mg(2+) during the reaction. Mutations at R291beta increase the pK(a) observed in the magnesium affinity, suggesting that this arginine stabilizes the deprotonated form of the PPi leaving group. Furthermore, binding and catalysis data using farnesylmonophosphate (FMP) as a substrate indicate that the side chains of R291beta and K294beta interact mainly with the beta-phosphate of FPP during the chemical reaction. These results allow refinement of the model of the Mg(2+) binding site and demonstrate that positive charge stabilizes the developing charge on the diphosphate leaving group.     

Ligand specificity determined by differentially arranged common ligand-binding residues in bacterial amino acid chemoreceptors Tsr and Tar

Escherichia coli has closely related amino acid chemoreceptors with distinct ligand specificity, Tar for l-aspartate and Tsr for l-serine. Crystallography of the ligand-binding domain of Tar identified the residues interacting with aspartate, most of which are conserved in Tsr. However, swapping of the nonconserved residues between Tsr and Tar did not change ligand specificity. Analyses with chimeric receptors led us to hypothesize that distinct three-dimensional arrangements of the conserved ligand-binding residues are responsible for ligand specificity. To test this hypothesis, the structures of the apo- and serine-binding forms of the ligand-binding domain of Tsr were determined at 1.95 and 2.5 Å resolutions, respectively. Some of the Tsr residues are arranged differently from the corresponding aspartate-binding residues of Tar to form a high affinity serine-binding pocket. The ligand-binding pocket of Tsr was surrounded by negatively charged residues, which presumably exclude negatively charged aspartate molecules. We propose that all these Tsr- and Tar-specific features contribute to specific recognition of serine and aspartate with the arrangement of the side chain of residue 68 (Asn in Tsr and Ser in Tar) being the most critical.     

Refined solution structure of a liganded type 2 wheat nonspecific lipid transfer protein

The refined structure of a wheat type 2 nonspecific lipid transfer protein (ns-LTP2) liganded with l-alpha-palmitoylphosphatidylglycerol has been determined by NMR. The (15)N-labeled protein was produced in Pichia pastoris. Physicochemical conditions and ligandation were intensively screened to obtain the best NMR spectra quality. This ns-LTP2 is a 67-residue globular protein with a diameter of about 30 A. The structure is composed of five helices forming a right superhelix. The protein presents an inner cavity, which has been measured at 341 A(3). All of the helices display hydrophobic side chains oriented toward the cavity. The phospholipid is found in this cavity. Its fatty acid chain is completely inserted in the protein, the l-alpha-palmitoylphosphatidylglycerol glycerol moiety being located on a positively charged pocket on the surface of the protein. The superhelix structure of the protein is coiled around the fatty acid chain. The overall structure shows similarities with ns-LTP1. Nevertheless, large three-dimensional structural discrepancies are observed for the H3 and H4 alpha-helices, the C-terminal region, and the last turn of the H2 helix. The lipid is orthogonal to the orientation observed in ns-LTP1. The volume of the hydrophobic cavity appears to be in the same range as the one of ns-LTP1, despite the fact that ns-LTP2 is shorter by 24 residues.     

A thermostable cysteine protease precursor from a tropical plant contains an unusual C-terminal propeptide: cDNA cloning, sequence comparison and molecular modeling studies

We report here the cloning and characterization of the entire cDNA of a papain-like cysteine protease from a tropical flowering plant. The 1098-bp ORF of the cDNA codify a protease precursor having a signal peptide of 19 amino acids, a cathepsin-L like N-terminal proregion of 114 amino acids, a mature enzyme part of 208 amino acids and a C-terminal proregion of 24 amino acids. The derived amino acid sequence of the mature part tallies with the thermostable cysteine protease Ervatamin-C--as was aimed at. The C-terminal proregion of the protease has altogether a different sequence pattern not observed in other members of the family and it contains a negatively charged helical zone. The three-dimensional model of the precursor, based on the homology modeling and X-ray structure, shows that the extended peptide stretch region of the N-terminal propeptide, covering the interdomain cleft, contains protruding side chains of positively charged residues. This study also indicates that the negatively charged zone of C-terminal propeptide may interact with the positively charged zone of the N-terminal propeptide in a cooperative manner in the maturation process of this enzyme.     

A positively charged cluster formed in the heme-distal pocket of cytochrome P450nor is essential for interaction with NADH

Arg and Lys residues are concentrated on the distal side of cytochrome P450nor (P450nor) to form a positively charged cluster facing from the outside to the inside of the distal heme pocket. We constructed mutant proteins in which the Arg and Lys residues were replaced with Glu, Gln, or Ala. The results showed that this cluster plays crucial roles in NADH interaction. We also showed that some anions such as bromide (Br(-)) perturbed the heme environment along with the reduction step in P450nor-catalyzed reactions, which was similar to the effects caused by the mutations. We determined by x-ray crystallography that a Br(-), termed an anion hole, occupies a key region neighboring heme, which is the terminus of the positively charged cluster and the terminus of the hydrogen bond network that acts as a proton delivery system. A comparison of the predicted mechanisms between the perturbations caused by Br(-) and the mutations suggested that Arg(174) and Arg(64) play a crucial role in binding NADH to the protein. These results indicated that the positively charged cluster is the unique structure of P450nor that responds to direct interaction with NADH.     

Deuterium exchange of the methyl group of pyruvate catalyzed by human serum albumin

Human serum albumin catalyzes proton exchange of the methyl group of the pyruvate molecule in heavy water. The exchange process is mainly due to the formation of bonds of a Schiff base type between six deprotonated protein amino groups and pyruvate. Both hydrated and non-hydrated forms of pyruvate interact with positively charged side amino acid residues of the polypeptide chain (most probably, with arginine) located in the hydrophobic "pockets" of the protein globule. The value of equilibrium association constants with serum albumin exceeds that for the hydrated form of pyruvate.     

A hydrophobic pocket in the active site of glycolytic aldolase mediates interactions with Wiskott-Aldrich syndrome protein

Aldolase plays essential catalytic roles in glycolysis and gluconeogenesis. However, aldolase is a highly abundant protein that is remarkably promiscuous in its interactions with other cellular proteins. In particular, aldolase binds to highly acidic amino acid sequences, including the C terminus of the Wiskott-Aldrich syndrome protein, an actin nucleation-promoting factor. Here we report the crystal structure of tetrameric rabbit muscle aldolase in complex with a C-terminal peptide of Wiskott-Aldrich syndrome protein. Aldolase recognizes a short, four-residue DEWD motif (residues 498-501), which adopts a loose hairpin turn that folds around the central aromatic residue, enabling its tryptophan side chain to fit into a hydrophobic pocket in the active site of aldolase. The flanking acidic residues in this binding motif provide further interactions with conserved aldolase active site residues Arg-42 and Arg-303, aligning their side chains and forming the sides of the hydrophobic pocket. The binding of Wiskott-Aldrich syndrome protein to aldolase precludes intramolecular interactions of its C terminus with its active site and is competitive with substrate as well as with binding by actin and cortactin. Finally, based on this structure, a novel naphthol phosphate-based inhibitor of aldolase was identified, and its structure in complex with aldolase demonstrated mimicry of the Wiskott-Aldrich syndrome protein-aldolase interaction. The data support a model whereby aldolase exists in distinct forms that regulate glycolysis or actin dynamics.     

Side-chain flexibility in proteins upon ligand binding

Ligand binding may involve a wide range of structural changes in the receptor protein, from hinge movement of entire domains to small side-chain rearrangements in the binding pocket residues. The analysis of side chain flexibility gives insights valuable to improve docking algorithms and can provide an index of amino-acid side-chain flexibility potentially useful in molecular biology and protein engineering studies. In this study we analyzed side-chain rearrangements upon ligand binding. We constructed two non-redundant databases (980 and 353 entries) of "paired" protein structures in complexed (holo-protein) and uncomplexed (apo-protein) forms from the PDB macromolecular structural database. The number and identity of binding pocket residues that undergo side-chain conformational changes were determined. We show that, in general, only a small number of residues in the pocket undergo such changes (e.g., approximately 85% of cases show changes in three residues or less). The flexibility scale has the following order: Lys > Arg, Gln, Met > Glu, Ile, Leu > Asn, Thr, Val, Tyr, Ser, His, Asp > Cys, Trp, Phe; thus, Lys side chains in binding pockets flex 25 times more often then do the Phe side chains. Normalizing for the number of flexible dihedral bonds in each amino acid attenuates the scale somewhat, however, the clear trend of large, polar amino acids being more flexible in the pocket than aromatic ones remains. We found no correlation between backbone movement of a residue upon ligand binding and the flexibility of its side chain. These results are relevant to 1. Reduction of search space in docking algorithms by inclusion of side-chain flexibility for a limited number of binding pocket residues; and 2. Utilization of the amino acid flexibility scale in protein engineering studies to alter the flexibility of binding pockets.     

Binding of metal cyanide complexes to bovine liver rhodanese in the crystalline state

Bovine liver rhodanese, which catalyzes the transfer of sulfur atoms between a variety of sulfur donor and sulfur acceptor substrates, is inhibited by metal cyanide complexes [Volini, M., Van Sweringen, B., & Chen, F.-Sh. (1978) Arch. Biochem. Biophys. 191, 205-215]. Crystallographic studies are described which reveal the binding mode of four different metal cyanides to bovine liver rhodanese: Na[Au(CN2], K2[Pt(CN)4], K2[Ni(CN)4], and K2[Zn(CN)4]. It appears that these complexes bind at one common site at the entrance of the active site pocket, interacting with the positively charged side chains of Arg-186 and Lys-249. This observation explains the inhibition of rhodanese by this class of compounds. For the platinum and nickel cyanide complexes virtually no other binding sites are observed. The gold complex binds, however, to three additional cysteine residues, thereby also displacing the extra sulfur atom which was bound to the essential Cys-247 in the sulfur-rhodanese complex. The zinc complex binds to completely different additional sites and forms complexes with the side chains of Asp-101 and His-203. Possible reasons for these different binding modes are discussed in terms of the preference for "hard" and "soft" ligands of these four metal ions.