Energetic roles of hydrogen bonds at the ureido oxygen binding pocket in the streptavidin-biotin complex

The high-affinity streptavidin-biotin complex is characterized by an extensive hydrogen-bonding network. A study of hydrogen-bonding energetics at the ureido oxygen of biotin has been conducted with site-directed mutations at Asn 23, Ser 27, and Tyr 43. A new competitive biotin binding assay was developed to provide direct equilibrium measurements of the alterations in Kd. S27A, Y43F, Y43A, N23A, and N23E mutants display DeltaDeltaG degrees at 37 degrees C relative to wild-type streptavidin of 2.9, 1.2, 2.6, 3.5, and 2.6 kcal/mol, respectively. The equilibrium-binding enthalpies for all of the mutants were measured by isothermal titration calorimetry, and the Y43A and N23A mutants display large decreases in the equilibrium binding enthalpy at 25 degrees C of 8.9 and 6.9 kcal/mol, respectively. The S27A and N23E mutants displayed small decreases in binding enthalpy of 1.6 and 0.9 kcal/mol relative to wild-type, while the Y43F mutant displayed a -2.6 kcal/mol increase in the binding enthalpy at 25 degrees C. At 37 degrees C, the Y43A and N23A mutants display decreases of 7.8 and 7.9 kcal/mol, respectively, while the S27A, N23E, and Y43F mutants displayed decreases of 4.9, 3.7, and 1.2 kcal/mol relative to wild-type. Kinetic analyses were also conducted to probe the contributions of the hydrogen bonds to the activation barrier. Wild-type streptavidin at 37 degrees C displays a koff of (4.1 +/- 0.3) x 10(-5) s-1, and the conservative Y43F, S27A, and N23A mutants displayed increases in koff to (20 +/- 1) x 10(-5) s-1, (660 +/- 40) x 10(-5) s-1, and (1030 +/- 220) x 10(-)5 s-1, respectively. The Y43A and N23E mutants displayed 93-fold and 188-fold increases in koff, respectively. Activation energies and enthalpies for each of the mutants were determined by transition-state analysis of the dissociation rate temperature dependence. All of the mutants except Y43F display large reductions in the activation enthalpy. The Y43F mutant has a more positive activation enthalpy, and thus a more favorable activation entropy that underlies the overall reduction in the activation barrier. For the most conservative mutant at each ureido oxygen hydrogen-bonding position, bound-state alterations account for most of the energetic changes in a single transition-state model, suggesting that the ureido oxygen hydrogen-bonding interactions are broken in the dissociation transition state.     

An engineered cation site in cytochrome c peroxidase alters the reactivity of the redox active tryptophan

The crystal structures of cytochrome c peroxidase and ascorbate peroxidase are very similar, including the active site architecture. Both peroxidases have a tryptophan residue, designated the proximal Trp, located directly adjacent to the proximal histidine heme ligand. During the catalytic cycle, the proximal Trp in cytochrome c peroxidase is oxidized to a cation radical. However, in ascorbate peroxidase, the porphyrin is oxidized, not the proximal Trp, despite the close similarity between the two peroxidase active site structures. A cation located approximately 8 A from the proximal Trp in ascorbate peroxidase but absent in cytochrome c peroxidase is thought to be one reason why ascorbate peroxidase does not form a Trp radical. Site-directed mutagenesis has been used to introduce the ascorbate peroxidase cation binding site into cytochrome c peroxidase. Crystal structures show that mutants now bind a cation. Electron paramagnetic resonance spectroscopy shows that the cation-containing mutants of cytochrome c peroxidase no longer form a stable Trp radical. The activity of the cation mutants using ferrocytochrome c as a substrate is < 1% of wild type levels, while the activity toward a small molecule substrate, guaiacol, increases. These results demonstrate that long range electrostatic effects can control the reactivity of a redox active amino acid side chain and that oxidation/reduction of the proximal Trp is important in the oxidation of ferrocytochrome c.     

Site-directed mutagenesis of the phosphocholine-binding site of human C-reactive protein: role of Thr76 and Trp67

We have reported previously that residues Lys57, Arg58, and Trp67 of human C-reactive protein (CRP) contribute to the structure of the phosphocholine (PCh)-binding site. In this study, based on the three-dimensional structures of human CRP and serum amyloid P, we constructed an additional mutant, T76Y, to probe the structural determinants of the PCh-binding site of CRP. Binding properties of four mutant CRPs, K57Q/R58G, W67K, K57Q/R58G/W67K, and T76Y were compared. Wild-type (wt) and all mutant CRPs were purified by affinity chromatography on PCh-, pneumococcal C-polysaccharide (PnC)-, or phosphoethanolamine-conjugated agarose columns. Purified mutant CRPs, K57Q/R58G/W67K and T76Y failed to bind to solid phase, PCh-substituted BSA. They did, however, bind to immobilized PnC, although with substantially decreased avidity compared with wt CRP. W67K, K57Q/R58G/W67K, and T76Y CRP required a 10-fold higher Ca2+ concentration than wt CRP to bind PnC and exhibited decreased avidity for mAb EA4.1, which recognizes a Ca2+-dependent epitope. We conclude that Thr76 is a determinant of the PCh-binding site, probably interacting with the choline group. This conclusion is supported by recent crystallographic data indicating that this residue participates in the formation of a hydrophobic pocket that constitutes the binding site for choline. Trp67, Lys57, and Arg58 do not directly contact PCh, but appear to be required for the proper conformation of the binding site.     

Probing the roles of active site residues in phosphatidylinositol-specific phospholipase C from Bacillus cereus by site-directed mutagenesis

The role of amino acid residues located in the active site pocket of phosphatidylinositol-specific phospholipase C (PI-PLC) from Bacillus cereus[Heinz, D. W., Ryan, M., Bullock, T., & Griffith, O. H. (1995) EMBO J. 14, 3855-3863] was investigated by site-directed mutagenesis, kinetics, and crystal structure analysis. Twelve residues involved in catalysis and substrate binding (His32, Arg69, His82, Gly83, Lys115, Glu117, Arg163, Trp178, Asp180, Asp198, Tyr200, and Asp274) were individually replaced by 1-3 other amino acids, resulting in a total number of 21 mutants. Replacements in the mutants H32A, H32L, R69A, R69E, R69K, H82A, H82L, E117K, R163I, D198A, D198E, D198S, Y200S, and D274S caused essentially complete inactivation of the enzyme. The remaining mutants (G83S, K115E, R163K, W178Y, D180S, Y200F, and D274N) exhibited reduced activities up to 57% when compared with wild-type PI-PLC. Crystal structures determined at a resolution ranging from 2.0 to 2.7 A for six mutants (H32A, H32L, R163K, D198E, D274N, and D274S) showed that significant changes were confined to the site of the respective mutation without perturbation of the rest of the structure. Only in mutant D198E do the side chains of two neighboring arginine residues move across the inositol binding pocket toward the newly introduced glutamic acid. An analysis of these structure-function relationships provides new insight into the catalytic mechanism, and suggests a molecular explanation of some of the substrate stereospecificity and inhibitor binding data available for this enzyme.     

Elementary [Ca2+]i signals generated by electroporation functionally mimic those evoked by hormonal stimulation

Tryptophan residues in chitosanase from Streptomyces sp. N174 (Trp28, Trp101, and Trp227) were mutated to phenylalanine, and thermal unfolding experiments of the proteins were done in order to investigate the role of tryptophan residues in thermal stability. Four types of mutants (W28F, W101F, W227F and W28F/W101F) were produced in sufficient quantity in our expression system using Streptomyces lividans TK24. Each unfolding curve obtained by CD at 222 nm did not exhibit a two-state transition profile, but exhibited a biphasic profile: a first cooperative phase and a second phase that is less cooperative. The single tryptophan mutation decreased the midpoint temperature (Tm) of the first transition phase by about 7 degrees C, and the double mutation by about 11 degrees C. The second transition phase in each mutant chitosanase was more distinct and extended than that in the wild-type. On the other hand, each unfolding curve obtained by tryptophan fluorescence exhibited a typical two-state profile and agreed with the first phase of transition curves obtained by CD. Differential scanning calorimetry profiles of the proteins were consistent with the data obtained by CD. These data suggested that the mutation of individual tryptophan residues would partly collapse the side chain interactions, consequently decreasing Tm and enhancing the formation of a molten globule-like intermediate in the thermal unfolding process. The tryptophan side chains are most likely to play important roles in cooperative stabilization of the protein.     

Appearance of T cells in the bursa of Fabricius and cecal tonsils during the acute phase of infectious bursal disease virus infection in chickens

Presteady and steady-state kinetic results on the interactions of a wild-type, and the mutant glucoamylases Trp52-->Phe and Trp317-->Phe, from Aspergillus niger with maltose, maltotriose and maltotetraose have been obtained and analyzed. The results are compared with previous ones on the mutants, Trp120-->Phe and Glu180-->Gln, and with results obtained from structure energy minimization calculations based on known three-dimensional structural data. All results are in accordance with a three-step reaction model involving two steps in the substrate binding and a rate-determining catalytic step. Trp317 and Glu180 belong to different subsites, but are placed on the same flank of the active site (beta-flank). The Trp317-->Phe and the Glu180-->Gln mutants show almost identical kinetic results: weakening of the substrate binding, mainly caused by changes in the second reaction step, and practically no change of the catalytic rate. Structure energy minimization calculations show that the same loss of Arg305 and Glu180 hydrogen bonds to the substrate occurs in the Michaelis complexes of each of these mutants. These results indicate that important interactions of the active site may be better understood from a consideration of its flanks rather than of its subsites. The results further indicate differences in the substrate binding mode of maltose and of longer substrates. Trp52 and Trp120 each interact with the catalytic acid, Glu179, and are placed on the flank (alpha-flank) of the active site opposite to Trp317, Arg305 and Glu180. Also the Trp52-->Phe and Trp120-->Phe mutants show kinetic results similar to each other. The catalytic rates are strongly reduced and the substrates are bound more strongly, mainly as a result of the formation of a more stable complex in the second reaction step. All together, the substrate binding mechanism seems to involve an initial enzyme-substrate complex, in which the beta-flank plays a minor role, except for maltose binding; this is followed by a conformational change, in which hydrogen bonds to Arg305 and Glu180 of the beta-flank are established and the correct alignment on the alpha-flank of Glu179, the general acid catalyst, governed by its flexible interactions with Trp52 and Trp120, occurs.     

Localized solution structure refinement of an F45W variant of ubiquitin using stochastic boundary molecular dynamics and NMR distance restraints

The local structure within an 8-A radius around residue 45 of a recombinant F45W variant of human ubiquitin has been determined using 67 interproton distance restraints measured by two-dimensional proton NMR. Proton chemical shift evidence indicates that structural perturbations due to the F45W mutation are minimal and limited to the immediate vicinity of the site of mutation. Simulated annealing implemented with stochastic boundary molecular dynamics was applied to refine the structure of Trp 45 and 10 neighboring residues. The stochastic boundary method allowed the entire protein to be reassembled from the refined coordinates and the outlying unrefined coordinates with little distortion at the boundary. Refinement began with four low-energy indole ring orientations of F45W-substituted wild-type (WT) ubiquitin crystal coordinates. Distance restraints were derived from mostly long-range NOE cross peaks with 51 restraints involving the Trp 45 indole ring. Tandem refinements of 64 structures were done using either (1) upper and lower bounds derived from qualitative inspection of NOE crosspeak intensities or (2) quantitative analysis of cross-peak heights using the program MARDIGRAS. Though similar to those based on qualitative restraint, structures obtained using quantitative NOE analysis were superior in terms of precision and accuracy as measured by back-calculated sixth-root R factors. The six-membered portion of the indole ring is nearly coincident with the phenyl ring of the WT and the indole NH is exposed to solvent. Accommodation of the larger ring is accompanied by small perturbations in the backbone and a 120 degrees rotation of the chi 2 dihedral angle of Leu 50.     

Structural interactions between horseradish peroxidase C and the substrate benzhydroxamic acid determined by X-ray crystallography

The three-dimensional structure of recombinant horseradish peroxidase in complex with BHA (benzhydroxamic acid) is the first structure of a peroxidase-substrate complex demonstrating the existence of an aromatic binding pocket. The crystal structure of the peroxidase-substrate complex has been determined to 2.0 A resolution with a crystallographic R-factor of 0.176 (R-free = 0. 192). A well-defined electron density for BHA is observed in the peroxidase active site, with a hydrophobic pocket surrounding the aromatic ring of the substrate. The hydrophobic pocket is provided by residues H42, F68, G69, A140, P141, and F179 and heme C18, C18-methyl, and C20, with the shortest distance (3.7 A) found between heme C18-methyl and BHA C63. Very little structural rearrangement is seen in the heme crevice in response to substrate binding. F68 moves to form a lid on the hydrophobic pocket, and the distal water molecule moves 0.6 A toward the heme iron. The bound BHA molecule forms an extensive hydrogen bonding network with H42, R38, P139, and the distal water molecule 2.6 A above the heme iron. This remarkably good match in hydrogen bond requirements between the catalytic residues of HRPC and BHA makes the extended interaction between BHA and the distal heme crevice of HRPC possible. Indeed, the ability of BHA to bind to peroxidases, which lack a peripheral hydrophobic pocket, suggests that BHA is a general counterpart for the conserved hydrogen bond donors and acceptors of the distal catalytic site. The closest aromatic residue to BHA is F179, which we predict provides an important hydrophobic interaction with more typical peroxidase substrates.     

Thermodynamic studies on the equilibrium properties of a series of recombinant betaW37 hemoglobin mutants

In human hemoglobin (Hb) the beta37 tryptophan residue (betaW37), located at the hinge region of the alpha1beta2 interface, forms many contacts with alpha subunit residues of the opposite dimer, in both the T and R quaternary structures. We have carried out equilibrium O2 binding studies on a series of recombinant Hbs that have mutations at this residue site: betaW37Y, betaW37A, betaW37G, and betaW37E. Binding isotherms measured at high concentrations of these mutants were found to be shifted toward increased affinity and decreased cooperativity from that of the normal HbA0 tetramer. Analysis of these binding isotherms indicated that amino acid substitutions at the beta37 position could both destabilize the tetrameric form of the mutants relative to their constituent dimers and also alter cooperativity of the intact tetrameric species. These alterations from wild-type function are dependent on the particular side chain substituted, with the magnitude of change increasing as Trp is substituted by Tyr, Ala, Gly, and Glu. The dimer to tetramer assembly free energy of deoxy-betaW37E, the most perturbed mutant in the series, was measured using analytical gel chromatography to be 9 kcal/tetramer less favorable than that of deoxy HbA0. Stabilizing the betaW37E tetramer by addition of IHP, or by cross-linking at the alphaK99 positions, does not restore normal O2 binding behavior. Thermodynamic parameters of all the mutants were found to correlate with their CO binding rates and with their high-resolution X-ray crystal structures (see accompanying papers: Kwiatkowski et al. (1998) Biochemistry 37, 4325-4335; Peterson & Friedman (1998) Biochemistry 37, 4346-4357; Kavanaugh et al. (1998) Biochemistry 37, 4358-4373].     

Tryptophan substitutions surrounding the nucleotide in catalytic sites of F1-ATPase

Novel tryptophan substitutions, surrounding the nucleotide bound in catalytic sites, were introduced into Escherichia coli F1-ATPase. The mutant enzymes were purified and studied by fluorescence spectroscopy. One cluster of Trp substitutions, consisting of beta-Trp-404, beta-Trp-410, beta-Asp-158 (lining the adenine-binding pocket), and beta-Trp-153 (close to the alpha/beta-phosphates), showed the same fluorescence responses to MgADP, MgAMPPNP, and MgATP and the same nucleotide binding pattern with MgADP and MgAMPPNP, with one site of higher and two sites of lower affinity. Therefore, in absence of catalytic turnover (and of gamma-subunit rotation), sites 2 and 3 appeared similar in affinity, and the region of the catalytic site sensed by these Trp substitutions did not change conformation with different nucleotides. In contrast, alpha-Trp-291 and beta-Trp-297, both close to the gamma-phosphate, showed very different fluorescence responses to MgADP versus MgAMPPNP, and in these cases the response was due exclusively or predominantly to nucleotide binding at the first, high-affinity catalytic site, thus allowing specific detection of this site. Titration with MgATP showed that the high-affinity site was present under conditions of steady-state, Vmax MgATP hydrolysis.     

A streptavidin mutant with altered ligand-binding specificity

The biotin-binding site of streptavidin was modified to alter its ligand-binding specificity. In natural streptavidin, the side chains of N23 and S27 make two of the three hydrogen bonds with the ureido oxygen of biotin. These two residues were mutated to severely weaken biotin binding while attempting to maintain the affinity for two biotin analogs, 2-iminobiotin and diaminobiotin. Redesigning of the biotin-binding site used the difference in local electrostatic charge distribution between biotin and these biotin analogs. Free energy calculations predicted that the introduction of a negative charge at the position of S27 plus the mutation N23A should disrupt two of the three hydrogen bonds between natural streptavidin and the ureido oxygen of biotin. In contrast, the imino hydrogen of 2-iminobiotin should form a hydrogen bond with the side chain of an acidic amino acid at position 27. This should reduce the biotin-binding affinity by approximately eight orders of magnitude, while leaving the affinities for these biotin analogs virtually unaffected. In good agreement with these predictions, a streptavidin mutant with the N23A and S27D substitutions binds 2-iminobiotin with an affinity (Ka) of 1 x 10(6) M-1, two orders of magnitude higher than that for biotin (1 x 10(4) M-1). In contrast, the binding affinity of this streptavidin mutant for diaminobiotin (2.7 x 10(4) M-1) was lower than predicted (2.9 x 10(5) M-1), suggesting the position of the diaminobiotin in the biotin-binding site was not accurately determined by modeling.     

Two-dimensional protein crystallization via metal-ion coordination by naturally occurring surface histidines

A powerful and potentially general approach to the targeting and crystallization of proteins on lipid interfaces through coordination of surface histidine residues to lipid-chelated divalent metal ions is presented. This approach, which should be applicable to the crystallization of a wide range of naturally occurring or engineered proteins, is illustrated here by the crystallization of streptavidin on a monolayer of an iminodiacetate-Cu(II) lipid spread at the air-water interface. This method allows control of the protein orientation at interfaces, which is significant for the facile production of highly ordered protein arrays and for electron density mapping in structural analysis of two-dimensional crystals. Binding of native streptavidin to the iminodiacetate-Cu lipids occurs via His-87, located on the protein surface near the biotin binding pocket. The two-dimensional streptavidin crystals show a previously undescribed microscopic shape that differs from that of crystals formed beneath biotinylated lipids.     

Two substrate interaction sites in lignin peroxidase revealed by site-directed mutagenesis

It has been shown recently that Trp171 of lignin peroxidase (LiP) is hydroxylated at the Cbeta position [Blodig, W., Doyle, W. A., Smith, A. T., Winterhalter, K., Choinowski, T., and Piontek, K. (1998) Biochemistry 37, 8832-8838]. Comparative experiments, carried out on both wild-type fungal and recombinant LiP isoenzyme H8 (LiPH8), indicate that the process of hydroxylation is autocatalytic and that Trp171 may be implicated in catalysis. The role of this residue has therefore been examined using site-directed mutagenesis to obtain recombinant enzymes with Trp171 substituted by Phe or Ser (W171F and W171S LiPH8, respectively). The wild-type recombinant enzyme (LiPH8) was analyzed in solution using 1H NMR spectroscopy and its integrity confirmed prior to the kinetic and spectroscopic characterization of LiPH8 mutants. A charge neutralization mutation in the "classical heme edge" substrate access channel of LiP, in which Glu146 was substituted by Gly (E146G LiPH8), showed substantial activity with respect to veratryl alcohol (VA) oxidation and a marked (2.4 pH units) increase in pKa for the oxidation of a negatively charged difluoroazo dye. More surprisingly, the Trp171 LiPH8 mutants W171F and W171S LiPH8 were found to have lost all activity with VA as substrate, and compounds I and II were unable to react with VA. Both mutants, however, retained substantial activity with two dye substrates. These data provide the first direct evidence for the existence of two distinct substrate interaction sites in LiP, a heme-edge site typical of those encountered in other peroxidases and a second, novel site centered around Trp171 which is required for the oxidation of VA. Stopped-flow kinetic studies showed that all the mutants examined reacted normally with hydrogen peroxide to give a porphyrin cation radical (compound I). However, the rapid phase of spontaneous compound I reduction (2.3 s-1), typical of wild-type LiP, was absent in the Trp171 mutants, strongly suggesting that an electron-transfer pathway must exist within the protein leading from the heme to a surface site in close proximity to Trp171. The kinetic competence of such a pathway is dependent on interaction of the enzyme with VA, at or near Trp171.     

Presentation and outcome of sporadic acute bacterial meningitis in children in the African meningitis belt: recent experience from northern Nigeria highlighting emergent factors in outcome

Peptides consisting solely of D-amino acids (D-peptides) as opposed to their L-counterparts (L-peptides) are resistant towards proteolytic degradation in the organism and may therefore be useful in future efforts to develop new stable peptide-based drugs. Using the random synthetic peptide library technique several L- and D-peptides, capable of binding to both avidin and streptavidin, were found. The L-peptides contained the previously described HPQ/M motifs, and among the D-peptides three binding motifs could be identified, of which the most frequently found one contained an N-terminal aliphatic hydrophobic amino acid (V, L or I) and an aromatic amino acid (Y or F) on the second position. At the third position in this motif several different amino acid residues were found, although N was the most frequent. Peptides representing two of the D-motifs were synthesized as well as peptides containing the HPQ/M motifs, and their binding properties were examined. Although the D-peptides were originally selected using avidin they also inhibited binding between immobilized biotin and soluble streptavidin as well as avidin. The IC50 of some of the peptides were approximately 10(5) times higher than the IC50 for biotin but some had a lower IC50 than iminobiotin. The D-peptides, which were originally selected from the library using avidin, could also inhibit the binding between streptavidin and biotin. Likewise, L-peptides selected from a library screened with streptavidin, could inhibit the binding of both streptavidin and avidin to immobilized biotin. Furthermore, the D-peptide, VFSVQSGS, as well as biotin could inhibit binding of streptavidin to an immobilized L-peptide (RYHPQSGS). This indicates that the biotin-like structure mimicked by these two seemingly very different peptides may react with the same binding sites in the streptavidin molecule.     

Tryptophan mutants of troponin C from skeletal muscle--an optical probe of the regulatory domain

We have generated a series of chicken skeletal muscle troponin C mutants to study the conformation of the regulatory domain in the N-terminal half of the molecule. These mutants each contained a single Trp at position 22 (helix A), 52 (linker of helices B and C), or 90 (central helix). Some of these mutants also contained additional mutations to introduce a single Cys at a desired position. The mutants were characterized by molecular graphics and CD and found to have a minimum of structural perturbations when compared with the native structure. They also retained the ability to regulate myofibrillar ATPase activity. The fluorescence of Trp22 was sensitive to Ca2+ binding only to the regulatory sites, whereas Trp52 and Trp90 responded to Ca2+ binding to both the regulatory and the Ca2+/Mg2+ sites. The tryptophan quantum yield (Q) of all Trp22-containing mutants was very high (0.33) in the absence of bound Ca2+, compared to that of L-tryptophan in aqueous solution (0.14). Q decreased 25% upon binding of Ca2+ to the regulatory sites. The quantum yields of Trp52 and Trp90 in apo mutants were close to 0.14. In the presence of bound Ca2+ at the regulatory sites, the quantum yield of Trp52 decreased 16%, whereas that of Trp90 increased 25%. Results from acrylamide quenching of the fluorescence of the three Trp residues indicated that Trp22 was the least exposed and Trp52 was the most exposed, consistent with other spectral data that Trp22 was in a relatively nonpolar environment and Trp52 was in a highly polar environment. The ability of Trp52 and Trp90 to sense Ca2+ binding to sites located at both domains suggests inter-domain communication in the protein. These single Trp TnC mutants provide specific signals for probing Ca2+-induced conformational changes in the regulatory domain.     

Interaction of substrate and effector binding sites in the ArsA ATPase

The ars operon of plasmid R773 confers resistance to antimonials and arsenicals in Escherichia coli by encoding an ATP-dependent extrusion system for the oxyanions. The catalytic subunit, the ArsA protein, is an ATPase with two nucleotide binding consensus sequences, one in the N-terminal half and one in the C-terminal half of the protein. The ArsA ATPase is allosterically activated by tricoordinate binding of As(3+) or Sb(3+) to three cysteine thiolates. Previous measurements suggested that the intrinsic fluorescence of tryptophans might be useful for examining binding of Mg2+ ATP and antimonite. In the present study an increase in intrinsic tryptophan fluorescence was observed upon addition of Mg2+ ATP. This enhancement was reversed by addition of antimonite. The ArsA protein contains four tryptophan residues: Trp159, Trp253, Trp522, and Trp524. The first two were altered to tyrosine residues by site-directed mutagenesis. Cells expressing both the arsAW159Y and arsAW253Y mutations retained resistance to arsenite, and the purified W159Y and W253Y proteins retained ATPase activity. While the intrinsic tryptophan fluorescence of the W253Y protein responded to addition of Mg2+ ATP, intrinsic tryptophan fluorescence in the purified W159Y protein was no longer enhanced by substrate. These results suggest that Trp159 is conformationally coupled to one or both of the nucleotide binding sites and provides a useful probe for the interaction of effector and substrate binding sites.     

Novel DNA binding motifs in the DNA repair enzyme endonuclease III crystal structure

The 1.85 A crystal structure of endonuclease III, combined with mutational analysis, suggests the structural basis for the DNA binding and catalytic activity of the enzyme. Helix-hairpin-helix (HhH) and [4Fe-4S] cluster loop (FCL) motifs, which we have named for their secondary structure, bracket the cleft separating the two alpha-helical domains of the enzyme. These two novel DNA binding motifs and the solvent-filled pocket in the cleft between them all lie within a positively charged and sequence-conserved surface region. Lys120 and Asp138, both shown by mutagenesis to be catalytically important, lie at the mouth of this pocket, suggesting that this pocket is part of the active site. The positions of the HhH motif and protruding FCL motif, which contains the DNA binding residue Lys191, can accommodate B-form DNA, with a flipped-out base bound within the active site pocket. The identification of HhH and FCL sequence patterns in other DNA binding proteins suggests that these motifs may be a recurrent structural theme for DNA binding proteins.     

Functional analysis of GnRH receptor ligand binding using biotinylated GnRH derivatives

The objective of this study was to determine whether the gonadotrophin-releasing hormone (GnRH) ligand binds to the GnRH receptor (GnRH-R) with either the N- and C-termini or the beta-II turn pointing towards the cell. The functionality of GnRH and two biotinylated GnRH derivatives, biotin [D-Lys6]GnRH and biotin [Gln1]GnRH biotinylated at positions 6 and 1, respectively was assessed. Streptavidin was also used in combination with these peptides to investigate the effects of the steric hindrance caused by this molecule on ligand binding when bound to the biotin molecules at the two positions. GnRH bound to the receptor with high affinity, which was not affected by the addition of streptavidin. Both the biotinylated derivatives bound to the receptor though with lower affinities than GnRH. The biotin [D-Lys6]GnRH-streptavidin complex bound to the receptor albeit with lower affinity compared to biotin [D-Lys6]GnRH only, although it maintained its ability to cause receptor internalisation. The ability of the biotin [Gln1]GnRH to bind to the receptor was abolished in the presence of excess streptavidin. Both GnRH and biotin [D-Lys6]GnRH stimulated total inositol phosphate production whereas biotin [Gln1]GnRH exhibited GnRH antagonist activity. It appears that the small biotin molecule can be accommodated within the binding pore when attached to position 1 of the ligand but not when complexed to streptavidin. The fact that biotin [D-Lys6]GnRH maintains functionality when complexed to streptavidin while biotin [Gln1]GnRH does not, suggests that the N- and possibly the C-termini are required for receptor binding. Thus the most likely binding orientation for the ligand is with the N- and C-termini pointing inwards with the residue at position 6 pointing away from the binding site.     

Drug distribution. The forgotten relative in clinical pharmacokinetics

The purpose of this study was to test the three-step targeting of tumors in mice using biotinylated antibody, streptavidin and radiolabeled biotin. Nude mice bearing subcutaneous LS180 human colon cancer xenografts were intravenously administered with 200 microg of the biotinylated anti-Tn monoclonal antibody MLS128, and 2 days later they got intravenous injection of 50 microg of streptavidin. They were intravenously injected 1, 4 or 7 days later with 0.5 microg of 111In-diethylenetriamine pentaacetic acid (DTPA)-biotin. The tumor uptake, determined 2 h later, was 1.4, 0.5 and 0.6% injected dose/gram of tissue (ID/g), respectively, and the blood radioactivity was 1.0, 0.2 and 0.2% ID/g, respectively. When the interval between the streptavidin and radiolabeled biotin injections was prolonged from 1 day to 7 days, the tumor-to-blood ratio 2 h after injection of 111In-labeled biotin increased from 1.5 to 4.0. Clear tumor images were obtained as early as 2 h after injection of radiolabeled biotin. In conclusion, these preliminary data suggested that the three-step method using the streptavidin-biotin system would be applicable in an experimental mouse tumor model and provides images of tumors rapidly and clearly after injection of radiolabeled biotin.