The effect of tryptophanyl substitution on folding and structure of myoglobin.

Mammalian myoglobins contain two tryptophanyl residues at the invariant positions 7 (A-5) and 14 (A-12) in the N-terminal region (A helix) of the protein molecule. The crucial role of tryptophanyl residues has been investigated by site-directed mutagenesis and molecular dynamics simulation. The apomyoglobin mutants with a double W-->F substitution were found to be not correctly folded and therefore not expressed as holoprotein. The introduction of a tyrosyl residue at position 7, that is, W7YW14F, resulted in the expression of a correctly folded myoglobin. Not correctly folded apomyoglobins were found with the following mutants: W7FW14Y, W7EW14F, W7FW14E, W7KW14F, W7FW14K. Moreover, in all these cases, very low levels of expression were observed. The acid-induced denaturation curves of wild-type and folded mutant W7YW14F, obtained following the fluorescence variation of the extrinsic fluorophore 1-anilino-8-naphthalenesulfonate, revealed that the stability of the native state of mutant apoprotein is decreased, thus indicating that the replacement W-->Y in position 7 is able to restore a correct folding but not the same stability. Molecular dynamics simulation indicated that both tryptophans are involved in forming favorable, specific tertiary interactions in the native apomyoglobin structure. The lack of some of these interactions caused by tryptophanyl replacement affects the overall protein structure and may provide an explanation for the observed stability decrease. In the case of the double W-->F substitution, the simulated structure shows conclusively the domain formed by helices A, G and H to be not correctly folded. This effect is attenuated if at least one of the two residues is conserved or a tyrosyl residue replaces W7.     

Role of residues 143 and 278 of the human nuclear Vitamin D receptor in the full-length and Delta165-215 deletion mutant

Most of the actions of 1,25-dihydroxyvitamin D(3) [1,25(OH)(2)D(3)] are mediated by binding to the Vitamin D nuclear receptor (VDR). The crystal structure of a deletion mutant (Delta165-215) of the VDR ligand-binding domain (LBD) bound to 1,25(OH)(2)D(3) indicates that amino acid residues tyrosine-143 and serine-278 form hydrogen bonding interactions with the 3-hydroxyl group of 1,25(OH)(2)D(3). Studies of VDR and three mutants (Y143F, S278A, and Y143F/S278A) did not indicate any differences in the binding affinity between the variant receptors and the wild-type receptor. This might indicate that the 3-hydroxyl group binds differently to the full-length VDR than the to deletion mutant. To further investigate, four deletion VDR mutants were constructed: VDR(Delta165-215), VDR(Delta165-215) (Y143F), VDR(Delta165-215) (S278A), VDR(Delta165-215) (Y143F/S278A). There were no significant differences in binding affinity between the wild-type receptor and the deletion mutants except for VDR(Delta165-215) (Y143F/S278A). In gene activation assays, VDR constructs with the single mutation Y143F and the double mutation Y143F/S278A, but not the single mutation S278A required higher doses of 1,25(OH)(2)D(3) for half-maximal response. This suggests that there are some minor structural and functional differences between the wild-type VDR and the Delta165-215 deletion mutant and that Y143 residue is more important for receptor function than residue S278.     

Cooperation of multiple CCR5 coreceptors is required for infections by human immunodeficiency virus type 1

In addition to the primary cell surface receptor CD4, CCR5 or another coreceptor is necessary for infections by human immunodeficiency virus type 1 (HIV-1), yet the mechanisms of coreceptor function and their stoichiometries in the infection pathway remain substantially unknown. To address these issues, we studied the effects of CCR5 concentrations on HIV-1 infections using wild-type CCR5 and two attenuated mutant CCR5s, one with the mutation Y14N at a critical tyrosine sulfation site in the amino terminus and one with the mutation G163R in extracellular loop 2. The Y14N mutation converted a YYT sequence at positions 14 to 16 to an NYT consensus site for N-linked glycosylation, and the mutant protein was shown to be glycosylated at that position. The relationships between HIV-1 infectivity values and CCR5 concentrations took the form of sigmoidal (S-shaped) curves, which were dramatically altered in different ways by these mutations. Both mutations shifted the curves by factors of approximately 30- to 150-fold along the CCR5 concentration axis, consistent with evidence that they reduce affinities of virus for the coreceptor. In addition, the Y14N mutation specifically reduced the maximum efficiencies of infection that could be obtained at saturating CCR5 concentrations. The sigmoidal curves for all R5 HIV-1 isolates were quantitatively consistent with a simple mathematical model, implying that CCR5s reversibly associate with cell surface HIV-1 in a concentration-dependent manner, that approximately four to six CCR5s assemble around the virus to form a complex needed for infection, and that both mutations inhibit assembly of this complex but only the Y14N mutation also significantly reduces its ability to successfully mediate HIV-1 infections. Although several alternative models would be compatible with our data, a common feature of these alternatives is the cooperation of multiple CCR5s in the HIV-1 infection pathway. This cooperativity will need to be considered in future studies to address in detail the mechanism of CCR5-mediated HIV-1 membrane fusion.     

Peroxynitrite-induced nitration of tyrosine hydroxylase: identification of tyrosines 423, 428, and 432 as sites of modification by matrix-assisted laser desorption ionization time-of-flight mass spectrometry and tyrosine-scanning mutagenesis

Tyrosine hydroxylase (TH), the initial and rate-limiting enzyme in the biosynthesis of the neurotransmitter dopamine, is inactivated by peroxynitrite. The sites of peroxynitrite-induced tyrosine nitration in TH have been identified by matrix-assisted laser desorption time-of-flight mass spectrometry and tyrosine-scanning mutagenesis. V8 proteolytic fragments of nitrated TH were analyzed by matrix-assisted laser desorption time-of-flight mass spectrometry. A peptide of 3135.4 daltons, corresponding to residues V410-E436 of TH, showed peroxynitrite-induced mass shifts of +45, +90, and +135 daltons, reflecting nitration of one, two, or three tyrosines, respectively. These modifications were not evident in untreated TH. The tyrosine residues (positions 423, 428, and 432) within this peptide were mutated to phenylalanine to confirm the site(s) of nitration and assess the effects of mutation on TH activity. Single mutants expressed wild-type levels of TH catalytic activity and were inactivated by peroxynitrite while showing reduced (30-60%) levels of nitration. The double mutants Y423F,Y428F, Y423F,Y432F, and Y428F,Y432F showed trace amounts of tyrosine nitration (7-30% of control) after exposure to peroxynitrite, and the triple mutant Y423F,Y428F,Y432F was not a substrate for nitration, yet peroxynitrite significantly reduced the activity of each. When all tyrosine mutants were probed with PEO-maleimide activated biotin, a thiol-reactive reagent that specifically labels reduced cysteine residues in proteins, it was evident that peroxynitrite resulted in cysteine oxidation. These studies identify residues Tyr(423), Tyr(428), and Tyr(432) as the sites of peroxynitrite-induced nitration in TH. No single tyrosine residue appears to be critical for TH catalytic function, and tyrosine nitration is neither necessary nor sufficient for peroxynitrite-induced inactivation. The loss of TH catalytic activity caused by peroxynitrite is associated instead with oxidation of cysteine residues.     

Analysis of a conserved hydrophobic pocket important for the thermostability of Bacillus pumilus chloramphenicol acetyltransferase (CAT-86)

Site-directed mutagenesis was carried out on Bacillus pumilus chloramphenicol acetyltransferase (CAT-86) to determine the effects of substitution at a conserved hydrophobic pocket identified earlier as important for thermostability. Mutations were introduced that would substitute residues at consensus positions 33, 191 and 203 in the enzyme, both individually and in combination. Two mutants, SDM1 (CAT-86 Y33F, A203V) and SDM5 (CAT-86 A203I), were more thermostable than wild-type and two mutants, SDM4 (CAT-86 I191V) and SDM7 (CAT-86 A203G), were less stable. Reconstruction of the residues of this hydrophobic pocket to that of a more thermostable CAT-R387 enzyme pocket (as a Y33F, I191V, A203V triple mutant) increased the thermostability of the enzyme above the wild-type, but its stability was less than that of SDM1 and SDM5. The K(m) values of the mutant enzymes for chloramphenicol and acetyl-CoA were essentially unaltered (in the ranges 15-30 and 26-35 microM respectively) and the specific activity of purified enzyme was in the range 270-710 units/mg protein. The possible effects of the amino acid substitutions on the CAT-86 structure were determined by homology modelling. A reduction in conformational strain and optimized hydrophobic interactions are predicted to be responsible for the increased thermostability of the SDM1 and SDM5 mutants.     

Tyrosine Sulfation of Chemokine Receptor CCR2 Enhances Interactions with Both Monomeric and Dimeric Forms of the Chemokine Monocyte Chemoattractant Protein-1 (MCP-1)

Chemokine receptors are commonly post-translationally sulfated on tyrosine residues in their N-terminal regions, the initial site of binding to chemokine ligands. We have investigated the effect of tyrosine sulfation of the chemokine receptor CCR2 on its interactions with the chemokine monocyte chemoattractant protein-1 (MCP-1/CCL2). Inhibition of CCR2 sulfation, by growth of expressing cells in the presence of sodium chlorate, significantly reduced the potency for MCP-1 activation of CCR2. MCP-1 exists in equilibrium between monomeric and dimeric forms. The obligate monomeric mutant MCP-1(P8A) was similar to wild type MCP-1 in its ability to induce leukocyte recruitment in vivo, whereas the obligate dimeric mutant MCP-1(T10C) was less effective at inducing leukocyte recruitment in vivo. In two-dimensional NMR experiments, sulfated peptides derived from the N-terminal region of CCR2 bound to both the monomeric and dimeric forms of wild type MCP-1 and shifted the equilibrium to favor the monomeric form. Similarly, MCP-1(P8A) bound more tightly than MCP-1(T10C) to the CCR2-derived sulfopeptides. NMR chemical shift mapping using the MCP-1 mutants showed that the sulfated N-terminal region of CCR2 binds to the same region (N-loop and β3-strand) of both monomeric and dimeric MCP-1 but that binding to the dimeric form also influences the environment of chemokine N-terminal residues, which are involved in dimer formation. We conclude that interaction with the sulfated N terminus of CCR2 destabilizes the dimerization interface of inactive dimeric MCP-1, thus inducing dissociation to the active monomeric state.     

Asp-99 donates a hydrogen bond not to Tyr-14 but to the steroid directly in the catalytic mechanism of Delta 5-3-ketosteroid isomerase from Pseudomonas putida biotype B

Delta 5-3-ketosteroid isomerase (KSI) catalyzes the allylic isomerization of Delta 5-3-ketosteroids at a rate approaching the diffusion limit by an intramolecular transfer of a proton. Despite the extensive studies on the catalytic mechanism, it still remains controversial whether the catalytic residue Asp-99 donates a hydrogen bond to the steroid or to Tyr-14. To clarify the role of Asp-99 in the catalysis, two single mutants of D99E and D99L and three double mutants of Y14F/D99E, Y14F/D99N, and Y14F/D99L have been prepared by site-directed mutagenesis. The D99E mutant whose side chain at position 99 is longer by an additional methylene group exhibits nearly the same kcat as the wild-type while the D99L mutant exhibits ca. 125-fold lower kcat than that of the wild-type. The mutations made at positions 14 and 99 exert synergistic or partially additive effect on kcat in the double mutants, which is inconsistent with the mechanism based on the hydrogen-bonded catalytic dyad, Asp-99 COOH...Tyr-14 OH...C3-O of the steroid. The crystal structure of D99E/D38N complexed with equilenin, an intermediate analogue, at 1.9 A resolution reveals that the distance between Tyr-14 O eta and Glu-99 O epsilon is ca. 4.2 A, which is beyond the range for a hydrogen bond, and that the distance between Glu-99 O epsilon and C3-O of the steroid is maintained to be ca. 2.4 A, short enough for a hydrogen bond to be formed. Taken together, these results strongly support the idea that Asp-99 contributes to the catalysis by donating a hydrogen bond directly to the intermediate.     

Functional analysis of the GAF domain of NifA in <Emphasis Type="Italic">Azospirillum brasilense</Emphasis>: effects of Tyr→Phe mutations on NifA and its interaction with GlnB

Regulation of NifA activity in Azospirillum brasilense depends on GlnB (a PII protein), and it was previously reported that the target of GlnB activity is the N-terminal domain of NifA. Furthermore, mutation of the Tyr residue at position 18 in the N-terminal domain resulted in a NifA protein that did not require GlnB for activity under nitrogen fixation conditions. We report here that a NifA double mutant in which the Tyr residues at positions 18 and 53 of NifA N-were simultaneously replaced by Phe (NifA-Y1853F) displays high nitrogenase activity, which is still regulatable by ammonia, but not by GlnB. The yeast two-hybrid technique was used to investigate whether GlnB can physically interact with wild-type and mutant NifA proteins. GlnB was found to interact directly with the N-terminal GAF domain of wild-type NifA, but not with its central or C-terminal domain. GlnB could still bind to the single NifA mutants Y18F and Y53F. In contrast, no interaction was detected between GlnB and the double mutant NifA-Y18/53F or between GlnB and NifA-Y43.     

Structural determinants of Cys2His2 zinc fingers.

Two mutants of the zinc finger peptide Xfin-31 (Ac-YKCGLCERSFVEKSALSRHQRVHKN-CONH2) containing alterations to the conserved hydrophobic core have been constructed and their zinc-bound structures investigated by 1H NMR techniques. In the first (Xfin-31B) a double mutation R8F/F10G places the conserved core aromatic residue at position 8 rather than position 10. In the second (Xfin-31C), Phe-10 is replaced by Leu. A qualitative analysis of 1H chemical shifts, NOE connectivities and coupling constants indicates that the global folds of both mutants are similar to that of the wild-type protein. However, amide exchange rates suggest that the F10L mutant is much less stable than either the wild-type or the R8F/F10G mutant.     

Outer sphere mutations perturb metal reactivity in manganese superoxide dismutase

Tyrosine 34 and glutamine 146 are highly conserved outer sphere residues in the mononuclear manganese active site of Escherichia coli manganese superoxide dismutase. Biochemical and spectroscopic characterization of site-directed mutants has allowed functional characterization of these residues in the wild-type (wt) enzyme. X-ray crystallographic analysis of three mutants (Y34F, Q146L, and Q146H) reveal subtle changes in the protein structures. The Y34A mutant, as well as the previously reported Y34F mutant, retained essentially the full superoxide dismutase activity of the wild-type enzyme, and the X-ray crystal structure of Y34F manganese superoxide dismutase shows that mutation of this strictly conserved residue has only minor effects on the positions of active site residues and the organized water in the substrate access funnel. Mutation of the outer sphere solvent pocket residue Q146 has more dramatic effects. The Q146E mutant is isolated as an apoprotein lacking dismutase activity. Q146L and Q146H mutants retain only 5-10% of the dismutase activity of the wild-type enzyme. The absorption and circular dichroism spectra of the Q146H mutant resemble corresponding data for the superoxide dismutase from a hyperthermophilic archaeon, Pyrobaculum aerophilum, which is active in both Mn and Fe forms. Interestingly, the iron-substituted Q146H protein also exhibits low dismutase activity, which increases at lower pH. Mutation of glutamine 146 disrupts the hydrogen-bonding network in the active site and has a greater effect on protein structure than does the Y34F mutant, with rearrangement of the tyrosine 34 and tryptophan 128 side chains.     

Molecular mechanisms of constitutive activity: mutations at position 111 of the angiotensin AT1 receptor.

A possible molecular mechanism for the constitutive activity of mutants of the angiotensin type 1 receptor (AT1) at position 111 was suggested by molecular modeling. This involves a cascade of conformational changes in spatial positions of side chains along transmembrane helix (TM3) from L112 to Y113 to F117, which in turn, results in conformational changes in TM4 (residues I152 and M155) leading to the movement of TM4 as a whole. The mechanism is consistent with the available data of site-directed mutagenesis, as well as with correct predictions of constitutive activity of mutants L112F and L112C. It was also predicted that the double mutant N111G/L112A might possess basal constitutive activity comparable with that of the N111G mutant, whereas the double mutants N111G/Y113A, N111G/F117A, and N111G/I152A would have lower levels of basal activity. Experimental studies of the above double mutants showed significant constitutive activity of N111G/L112A and N111G/F117A. The basal activity of N111G/I152A was higher than expected, and that of N111G/Y113A was not determined due to poor expression of the mutant. The proposed mechanism of constitutive activity of the AT(1) receptor reveals a novel nonsimplistic view on the general problem of constitutive activity, and clearly demonstrates the inherent complexity of the process of G protein-coupled receptor (GPCR) activation.     

Tyrosine phosphorylation within the SH3 domain regulates CAS subcellular localization, cell migration, and invasiveness

Crk-associated substrate (CAS) is a major tyrosine-phosphorylated protein in cells transformed by v-crk and v-src oncogenes and plays an important role in invasiveness of Src-transformed cells. A novel phosphorylation site on CAS, Tyr-12 (Y12) within the ligand-binding hydrophobic pocket of the CAS SH3 domain, was identified and found to be enriched in Src-transformed cells and invasive human carcinoma cells. To study the biological significance of CAS Y12 phosphorylation, phosphomimicking Y12E and nonphosphorylatable Y12F mutants of CAS were studied. The phosphomimicking mutation decreased interaction of the CAS SH3 domain with focal adhesion kinase (FAK) and PTP-PEST and reduced tyrosine phosphorylation of FAK. Live-cell imaging showed that green fluorescent protein-tagged CAS Y12E mutant is, in contrast to wild-type or Y12F CAS, excluded from focal adhesions but retains its localization to podosome-type adhesions. Expression of CAS-Y12F in cas-/- mouse embryonic fibroblasts resulted in hyperphosphorylation of the CAS substrate domain, and this was associated with slower turnover of focal adhesions and decreased cell migration. Moreover, expression of CAS Y12F in Src-transformed cells greatly decreased invasiveness when compared to wild-type CAS expression. These findings reveal an important role of CAS Y12 phosphorylation in the regulation of focal adhesion assembly, cell migration, and invasiveness of Src-transformed cells.     

Rescue of deleterious mutations by the compensatory Y30F mutation in ketosteroid isomerase

Proteins have evolved to compensate for detrimental mutations. However, compensatory mechanisms for protein defects are not well understood. Using ketosteroid isomerase (KSI), we investigated how second-site mutations could recover defective mutant function and stability. Previous results revealed that the Y30F mutation rescued the Y14F, Y55F and Y14F/Y55F mutants by increasing the catalytic activity by 23-, 3- and 1.3-fold, respectively, and the Y55F mutant by increasing the stability by 3.3 kcal/mol. To better understand these observations, we systematically investigated detailed structural and thermodynamic effects of the Y30F mutation on these mutants. Crystal structures of the Y14F/Y30F and Y14F/Y55F mutants were solved at 2.0 and 1.8 previoulsy solved structures of wild-type and other mutant KSIs. Structural analyses revealed that the Y30F mutation partially restored the active-site cleft of these mutant KSIs. The Y30F mutation also increased Y14F and Y14F/Y55F mutant stability by 3.2 and 4.3 kcal/mol, respectively, and the melting temperatures of the Y14F, Y55F and Y14F/Y55F mutants by 6.4°C, 5.1°C and 10.0°C, respectively. Compensatory effects of the Y30F mutation on stability might be due to improved hydrophobic interactions because removal of a hydroxyl group from Tyr30 induced local compaction by neighboring residue movement and enhanced interactions with surrounding hydrophobic residues in the active site. Taken together, our results suggest that perturbed active-site geometry recovery and favorable hydrophobic interactions mediate the role of Y30F as a secondsite suppressor.     

Mechanistic roles of Ser-114, Tyr-155, and Lys-159 in 3alpha-hydroxysteroid dehydrogenase/carbonyl reductase from Comamonas testosteroni

3alpha-hydroxysteroid dehydrogenase/carbonyl reductase (3alpha-HSD/CR) from Comamonas testosteroni, a short chain dehydrogenase/reductase, catalyzes the oxidation of androsterone with NAD+ to form androstanedione and NADH. A catalytic triad of Ser-114, Tyr-155, and Lys-159 in 3alpha-HSD/CR has been proposed based on structural analysis and sequence alignment of the short chain dehydrogenase/reductase family. The 3alpha-HSD/CR-catalyzed reaction has not been kinetically analyzed in detail, however. In this study, we combined steady-state kinetics, site-directed mutagenesis, and pH profile to explore the function of Ser-114, Tyr-155, and Lys-159 in 3alpha-HSD/CR-catalyzed reaction. The catalytic efficiency of wild-type and mutants S114A, Y155F, K159A, and Y155F/K159A is 4.3 x 10(7), 7.3 x 10(4), 1.7 x 10(4), 2.4 x 10(5), and 71 m(-1)s(-1), respectively. The values of pKa on kcat/Km for the wild-type, S114A, Y155F, K159A, and Y155F/K159A are 7.2, 7.4, 8.4, 9.1, and 10.2, respectively. Mutant S114A/Y155F exhibits a pH-independent profile with 10(-5) times of wild-type activity at pH 10.5. The activity decreases as the pH lowers, which indicates that a functional group with an apparent pKa of 7.2 is involved in the general base catalysis for wild-type 3alpha-HSD/CR. The pKa shift to 9.1 for mutant K159A suggests the role of Lys-159 is to lower the pKa of the residues involved in the general base catalysis. Because pH dependence is observed for both S114A and Y155F mutants and pH independence is observed in S114A/Y155F, Tyr-155 may be important as a general base catalysis in the wild-type, whereas Ser-114 may act as a general base on mutant Y155F to catalyze the reaction.     

Improved oligosaccharide synthesis by protein engineering of beta-glucosidase CelB from hyperthermophilic Pyrococcus furiosus

Enzymatic transglycosylation of lactose into oligosaccharides was studied using wild-type beta-glucosidase (CelB) and active site mutants thereof (M424K, F426Y, M424K/F426Y) and wild-type beta-mannosidase (BmnA) of the hyperthermophilic Pyrococcus furiosus. The effects of the mutations on kinetics, enzyme activity, and substrate specificity were determined. The oligosaccharide synthesis was carried out in aqueous solution at 95 degrees C at different lactose concentrations and pH values. The results showed enhanced synthetic properties of the CelB mutant enzymes. An exchange of one phenylalanine to tyrosine (F426Y) increased the oligosaccharide yield (45%) compared with the wild-type CelB (40%). Incorporation of a positively charged group in the active site (M424K) increased the pH optimum of transglycosylation reaction of CelB. The double mutant, M424K/F426Y, showed much better transglycosylation properties at low (10-20%) lactose concentrations compared to the wild-type. At a lactose concentration of 10%, the oligosaccharide yield for the mutant was 40% compared to 18% for the wild-type. At optimal reaction conditions, a higher ratio of tetrasaccharides to trisaccharides was obtained with the double mutant (0.42, 10% lactose) compared to the wild-type (0.19, 70% lactose). At a lactose concentration as low as 10%, only trisaccharides were synthesized by CelB wild-type. The beta-mannosidase BmnA from P. furiosus showed both beta-glucosidase and beta-galactosidase activity and in the transglycosylation of lactose the maximal oligosaccharide yield of BmnA was 44%. The oligosaccharide yields obtained in this study are high compared to those reported with other transglycosylating beta-glycosidases in oligosaccharide synthesis from lactose.     

Structural basis for lipoxygenase specificity. Conversion of the human leukocyte 5-lipoxygenase to a 15-lipoxygenating enzyme species by site-directed mutagenesis

Mammalian lipoxygenases constitute a heterogeneous family of lipid-peroxidizing enzymes, and the various isoforms are categorized with respect to their positional specificity of arachidonic acid oxygenation into 5-, 8-, 12-, and 15-lipoxygenases. Structural modeling suggested that the substrate binding pocket of the human 5-lipoxygenase is 20% bigger than that of the reticulocyte-type 15-lipoxygenase; thus, reduction of the active-site volume was suggested to convert a 5-lipoxygenase to a 15-lipoxygenating enzyme species. To test this "space-based" hypothesis of the positional specificity, the volume of the 5-lipoxygenase substrate binding pocket was reduced by introducing space-filling amino acids at critical positions, which have previously been identified as sequence determinants for the positional specificity of other lipoxygenase isoforms. We found that single point mutants of the recombinant human 5-lipoxygenase exhibited a similar specificity as the wild-type enzyme but double, triple, and quadruple mutations led to a gradual alteration of the positional specificity from 5S- via 8S- toward 15S-lipoxygenation. The quadruple mutant F359W/A424I/N425M/A603I exhibited a major 15S-lipoxygenase activity (85-95%), with (8S,5Z,9E,11Z,14Z)-8-hydroperoxyeicosa-5,9 ,11, 14-tetraenoic acid being a minor side product. These data indicate the principle possibility of interconverting 5- and 15-lipoxygenases by site-directed mutagenesis and appear to support the space-based hypothesis of positional specificity.     

The unique proline of the Prochlorothrix hollandica plastocyanin hydrophobic patch impairs electron transfer to photosystem I.

A number of surface residues of plastocyanin from Prochlorothrix hollandica have been modified by site-directed mutagenesis. Changes have been made in amino acids located in the amino-terminal hydrophobic patch of the copper protein, which presents a variant structure as compared with other plastocyanins. The single mutants Y12G, Y12F, Y12W, P14L, and double mutant Y12G/P14L have been produced. Their reactivity toward photosystem I has been analyzed by laser flash absorption spectroscopy. Plots of the observed rate constant with all mutants versus plastocyanin concentration show a saturation profile similar to that with wild-type plastocyanin, thus suggesting the formation of a plastocyanin-photosystem I transient complex. The mutations do not induce relevant changes in the equilibrium constant for complex formation but induce significant variations in the electron transfer rate constant, mainly with the two mutants at proline 14. Additionally, molecular dynamics calculations indicate that mutations at position 14 yield small changes in the geometry of the copper center. The comparative kinetic analysis of the reactivity of plastocyanin mutants toward photosystem I from different organisms (plants and cyanobacteria) reveals that reversion of the unique proline of Prochlorothrix plastocyanin to the conserved leucine of all other plastocyanins at this position enhances the reactivity of the Prochlorothrix protein.     

Hydroxyl groups in the (beta)beta sandwich of metallo-beta-lactamases favor enzyme activity: a computational protein design study

Metallo-beta-lactamases challenge antimicrobial therapies by their ability to hydrolyze and inactivate a broad spectrum of beta-lactam antibiotics. The potential of these enzymes to acquire enhanced catalytic efficiency through mutation is of great concern. Here, we explore the potential of computational protein design to predict mutants of the imipenemase IMP-1 that modulate the catalytic efficiency of the enzyme against a range of substrates. Focusing on the four amino acid positions 69, 121, 218, and 262, we carried out a number of design calculations. Two mutant enzymes were predicted: the single mutant S262A and the double mutant F218Y-S262A. Compared to IMP-1, the single mutant (S262A) results in the loss of a hydroxyl group and the double mutant (F218Y-S262A) results in a hydroxyl transfer from position 262 to position 218. The presence of both hydroxyl groups at positions 218 and 262 was tested by examining the mutant F218Y. Kinetic constants of IMP-1, the two computationally designed mutants (S262A and F218Y-S262A), and the hydroxyl addition mutant (F218Y) were determined with seven substrates. Catalytic efficiencies are highest for the enzyme with both hydroxyl groups (F218Y) and lowest for the enzyme lacking both hydroxyl groups (S262A). The catalytic efficiencies of the two enzymes with one hydroxyl group each are intermediate, with the F218Y-S262A double mutant exhibiting enhanced hydrolysis of nitrocefin, cephalothin, and cefotaxime relative to IMP-1.     

Rational evolution of a medium chain-specific cytochrome P-450 BM-3 variant

The single mutant F87A of cytochrome P-450 BM-3 from Bacillus megaterium was engineered by rational evolution to achieve improved hydroxylation activity for medium chain length substrates (C8-C10). Rational evolution combines rational design and directed evolution to overcome the drawbacks of these methods when applied individually. Based on the X-ray structure of the enzyme, eight mutation sites (P25, V26, R47, Y51, S72, A74, L188, and M354) were identified by modeling. Sublibraries created by site-specific randomization mutagenesis of each single site were screened using a spectroscopic assay based on omega-p-nitrophenoxycarboxylic acids (pNCA). The mutants showing activity for shorter chain length substrates were combined, and these combi-libraries were screened again for mutants with even better catalytic properties. Using this approach, a P-450 BM-3 variant with five mutations (V26T, R47F, A74G, L188K, and F87A) that efficiently hydrolyzes 8-pNCA was obtained. The catalytic efficiency of this mutant towards omega-p-nitrophenoxydecanoic acid (10-pNCA) and omega-p-nitrophenoxydodecanoic acid (12-pNCA) is comparable to that of the wild-type P-450 BM-3.     

Identification of receptor binding and activation determinants in the N-terminal and N-loop regions of the CC chemokine eotaxin

Eotaxin is a CC chemokine that specifically activates the receptor CCR3 causing accumulation of eosinophils in allergic diseases and parasitic infections. Twelve amino acid residues in the N-terminal (residues 1-8) and N-loop (residues 11-20) regions of eotaxin have been individually mutated to alanine, and the ability of the mutants to bind and activate CCR3 has been determined in cell-based assays. The alanine mutants at positions Thr(7), Asn(12), Leu(13), and Leu(20) show near wild type binding affinity and activity. The mutants T8A, N15A, and K17A have near wild type binding affinity for CCR3 but reduced receptor activation. A third class of mutants, S4A, V5A, R16A, and I18A, display significantly perturbed binding affinity for CCR3 while retaining the ability to activate or partially activate the receptor. Finally, the mutant Phe(11) has little detectable activity and 20-fold reduced binding affinity relative to wild type eotaxin, the most dramatic effect observed in both assays but less dramatic than the effect of mutating the corresponding residue in some other chemokines. Taken together, the results indicate that residues contributing to receptor binding affinity and those required for triggering receptor activation are distributed throughout the N-terminal and N-loop regions. This conclusion is in contrast to the separation of binding and activation functions between N-loop and N-terminal regions, respectively, that has been observed previously for some other chemokines.