Unusual fluorescence of W168 in Plasmodium falciparum triosephosphate isomerase, probed by single-tryptophan mutants.

Plasmodium falciparum triosephosphate isomerase (PfTIM) contains two tryptophan residues, W11 and W168. One is positioned in the interior of the protein, and the other is located on the active-site loop 6. Two single-tryptophan mutants, W11F and W168F, were constructed to evaluate the contributions of each chromophore to the fluorescence of the wild-type (wt) protein and to probe the utility of the residues as spectroscopic reporters. A comparative analysis of the fluorescence spectra of PfTIMwt and the two mutant proteins revealed that W168 possesses an unusual, blue-shifted emission (321 nm) and exhibits significant red-edge excitation shift of fluorescence. In contrast, W11 emits at 332 nm, displays no excitation dependence of fluorescence, and behaves like a normal buried chromophore. W168 has a much shorter mean lifetime (2.7 ns) than W11 (4.6 ns). The anomalous fluorescence properties of W168 are abolished on unfolding of the protein in guanidinium chloride (GdmCl) or at low pH. Analysis of the tryptophan environment using a 1.1-A crystal structure established that W168 is rigidly held by a complex network of polar interactions including a strong hydrogen bond from Y164 to the indole NH group. The environment is almost completely polar, suggesting that electrostatic effects determine the unusually low emission wavelength of W168. To our knowledge this is a unique observation of a blue-shifted emission from a tryptophan in a polar environment in the protein. The wild-type and mutant proteins show similar levels of enzymatic activity and secondary and tertiary structure. However, the W11F mutation appreciably destabilizes the protein to unfolding by urea and GdmCl. The fluorescence of W168 is shown to be extremely sensitive to binding of the inhibitor, 2-phosphoglycolic acid.     

Characterization of two mutant lactose repressor proteins containing single tryptophans

Two mutant lactose repressors, each containing a single tryptophan, were generated by site-specific mutagenesis. Tyrosine was substituted for tryptophan to be analogous to amber suppression mutants reported previously (Sommer, H., Lu, P., and Miller, J. H. (1976) J. Biol. Chem. 251, 3774-3779). Unlike the amber suppression mutants, plasmids containing the mutant sequences produce large quantities of stable, easily isolable protein. The binding properties of the site-specific mutant repressors (W201Y, W220Y) differ from those reported for the corresponding suppression mutants (A201, A220). Whereas minimal effects on operator dissociation rate from lambda plac DNA were noted for the suppression mutants, purified W201Y and W220Y proteins exhibit 10- and 5-fold reduced affinity for a 40-base pair operator, respectively, compared with wild-type. Inducer binding of the A201 and W201Y mutants was similar to that for wild-type repressor, but the inducer affinity of W220Y was approximately 2-fold lower than A220 (approximately 30-fold lower than wild-type). Fluorescence spectra and iodide quenching of the mutant proteins were similar to the suppression mutants, but the absorption coefficient differed significantly from the values reported previously. Acrylamide and iodide quenching results indicate that Trp201 is relatively buried whereas Trp220 is exposed to solvent; inducer binding reduces quenching of Trp220 significantly. CD spectra indicate that the mutant proteins have secondary structural features similar to those of wild-type. Inducer UV difference spectra showed that the major features reported for the wild-type isopropyl beta-D-thiogalactopyranoside difference spectrum were attributable to both tryptophans. In the presence of melibiose, a new minimum appeared in the difference spectra of wild-type and W201Y which was not evident when these proteins bound isopropyl beta-D-thiogalactopyranoside. It is possible that this new feature results from Trp220 involvement in a direct contact with the second sugar in disaccharide inducer molecules such as melibiose and 1,6-allolactose.     

Resolution of the fluorescence decay of the two tryptophan residues of lac repressor using single tryptophan mutants.

We have studied the time-resolved intrinsic tryptophan fluorescence of the lac repressor (a symmetric tetramer containing two tryptophan residues per monomer) and two single-tryptophan mutant repressors obtained by site-directed mutagenesis, lac W201Y and lac W220Y. These mutant repressor proteins have tyrosine substituted for tryptophan at positions 201 and 220, respectively, leaving a single tryptophan residue per monomeric subunit at position 220 for the W201Y mutant and at position 201 in the W220Y mutant. It was found that the two decay rates recovered from the analysis of the wild type data do not correspond to the rates recovered from the analysis of the decays of the mutant proteins. Each of these residues in the mutant repressors displays at least two decay rates. Global analysis of the multiwavelength data from all three proteins, however, yielded results consistent with the fluorescence decay of the wild type lac repressor corresponding simply to the weighted linear combination of the decays from the mutant proteins. The effect of ligation by the antagonistic ligands, inducer and operator DNA, was similar for all three proteins. The binding of the inducer sugar resulted in a quenching of the long-lived species, while binding by the operator decreased the lifetime of the short components. Investigation of the time-resolved anisotropy of the intrinsic tryptophan fluorescence in these three proteins revealed that the depolarization of fluorescence resulted from a fast motion and the global tumbling of the macromolecule. Results from the simultaneous global analysis of the frequency domain data sets from the three proteins revealed anisotropic rotations for the macromolecule, consistent with the known elongated shape of the repressor tetramer. In addition, it appears that the excited-state dipole of tryptophan 220 is alighed with the long axis of the repressor.     

Impact of template overhang-binding region of HIV-1 RT on the binding and orientation of the duplex region of the template-primer

Fingers domain of HIV-1 RT is one of the constituents of the dNTP-binding pocket that is involved in binding of both dNTP and the template-primer. In the ternary complex of HIV-1 RT, two residues Trp-24 and Phe-61 located on the β1 and β3, respectively, are seen interacting with N + 1 to N + 3 nucleotides in the template overhang. We generated nonconservative and conservative mutant derivatives of these residues and examined their impact on the template-primer binding and polymerase function of the enzyme. We noted that W24A, F61A, and F61Y and the double mutant (W24A/F61A) were significantly affected in their ability to bind template-primer and also to catalyze the polymerase reaction while W24F remained unaffected. Using a specially designed template-primer with photoactivatable bromo-dU base in the duplex region at the penultimate position to the primer terminus, we demonstrated that F61A, W24A, F61Y as well as the double mutant were also affected in their cross-linking ability with the duplex region of the template-primer. We also isolated the E–TP covalent complexes of these mutants and examined their ability to catalyze single dNTP incorporation onto the immobilized primer terminus. The E–TP covalent complexes from W24F mutant displayed wild-type activity while those from W24A, F61A, F61Y, and the double mutant (W24A/F61A) were significantly impaired in their ability to catalyze dNTP incorporation onto the immobilized primer terminus. This unusual observation indicated that amino acid residues involved in the positioning of the template overhang may also influence the binding and orientation of the duplex region of the template-primer. Molecular modeling studies based on our biochemical results suggested that conformation of both W24 and F61 are interdependent on their interactions with each other, which together are required for proper positioning of the +1 template nucleotide in the binary and ternary complexes.     

Carbohydrate binding module recognition of xyloglucan defined by polar contacts with branching xyloses and CH‐Π interactions

Engineering of novel carbohydrate‐binding proteins that can be utilized in various biochemical and biotechnical applications would benefit from a deeper understanding of the biochemical interactions that determine protein‐carbohydrate specificity. In an effort to understand further the basis for specificity we present the crystal structure of the multi‐specific carbohydrate‐binding module (CBM) X‐2 L110F bound to a branched oligomer of xyloglucan (XXXG). X‐2 L110F is an engineered CBM that can recognize xyloglucan, xylans and β‐glucans. The structural observations of the present study compared with previously reported structures of X‐2 L110F in complex with linear oligomers, show that the π‐surface of a phenylalanine, F110, allows for interactions with hydrogen atoms on both linear (xylopentaose and cellopentaose) and branched ligands (XXXG). Furthermore, X‐2 L110F is shown to have a relatively flexible binding cleft, as illustrated in binding to XXXG. This branched ligand requires a set of reorientations of protein side chains Q72, N31, and R142, although these residues have previously been determined as important for binding to xylose oligomers by mediating polar contacts. The loss of these polar contacts is compensated for in binding to XXXG by polar interactions mediated by other protein residues, T74, R115, and Y149, which interact mainly with the branching xyloses of the xyloglucan oligomer. Taken together, the present study illustrates in structural detail how CH‐π interactions can influence binding specificity and that flexibility is a key feature for the multi‐specificity displayed by X‐2 L110F, allowing for the accommodation of branched ligands. Proteins 2014; 82:3466–3475. © 2014 Wiley Periodicals, Inc.     

Phage λ Cro Protein and Ci Repressor Use Two Different Patterns of Specific Protein-DNA Interactions to Achieve Sequence Specificity in Vivo

By assaying the binding of wild-type Cro to a set of 40 mutant lambda operators in vivo, we have determined that the 14 outermost base pairs of the 17 base pair, consensus lambda operator are critical for Cro binding. Cro protein recognizes 4 base pairs in a lambda operator half-site in different ways than cI repressor. The sequence determinants of Cro binding at these critical positions in vivo are nearly perfectly consistent with the model proposed by W. F. ANDERSON, D. H. OHLENDORF, Y. TAKEDA and B. W. MATTHEWS and modified by Y. TAKEDA, A. SARAI and V. M. RIVERA for the specific interactions between Cro and its operator, and explain the relative order of affinities of the six natural lambda operators for Cro. Our data call into question the idea that lambda repressor and Cro protein recognize the consensus lambda operator by nearly identical patterns of specific interactions.     

Conformational stability of CopC and roles of residues Tyr79 and Trp83

CopC is a periplasmic copper Chaperone protein that has a β‐barrel fold and two metal‐binding sites distinct for Cu(II) and Cu(I). In the article, four mutants (Y79F, Y79W, Y79WW83L, Y79WW83F) were obtained by site‐directed mutagenesis. The far‐UV CD spectra of the proteins were similar, suggesting that mutations did not bring any significant changes in secondary structures. Meanwhile the effects of mutations on the protein's function were manifested by Cu(II) binding. Fluorescence lifetime measurement and quenching of tryptophan fluorescence by acrylamide and KI showed that the microenvironment around Trp83 was more hydrophobic than that around Tyr79 in apoCopC. Unfolding experiments induced by guanidinium chloride (GdnHCl), urea provided the conformational stability of each protein. The Δ<ΔG⁰_element> obtained using the model of structural elements was used to show the role of Tyr79 and Trp83. On the one hand, the <ΔG⁰_element> induced by urea for Y79F, Y79W have a loss of 6.51, 2.03 kJ/mol, respectively, compared with apoCopC, proving that replacement of Tyr79 by Phe or Trp all decreased the protein stability, meaning that the hydrogen bonds interactions between Tyr79 and Thr75 played an important role in stabilizing apoCopC. On the other hand, the <ΔG⁰_element> induced by urea for Y79WW83L have a loss of 11.44 kJ/mol, but for Y79WW83F did a raise of 1.82 kJ/mol compared with Y79W. The replacement of Trp83 by Phe and Leu yields opposite effects on protein stability, which suggested that the aromatic ring of Trp83 was important in maintaining the hydrophobic core of apoCopC.     

Relative substrate affinities of wild-type and mutant forms of the Escherichia coli sugar transporter GalP determined by solid-state NMR

Solid-state nuclear magnetic resonance (SSNMR) spectroscopy is used for the first time to examine the relative substrate-binding affinities of mutant forms of the Escherichia coli sugar transporter GalP in membrane preparations. The SSNMR method of (13)C cross-polarization magic-angle spinning (CP-MAS) is applied to five site-specific mutants (W56F, W239F, R316W, T336Y and W434F), which have a range of different sugar-transport activities compared to the wild-type protein. It is shown that binding of the substrate D-glucose can be detected independently of sugar transport activity using SSNMR, and that the NMR peak intensities for uniformly (13)C-labelled glucose are consistent with wild-type GalP and the mutants having different affinities for the substrate. The W239F and W434F mutants showed binding affinities similar to that of the wild-type protein, whereas the affinity of glucose-binding to the W56F mutant was reduced. The R316W mutant showed no detectable binding; this position corresponds to the second basic residue in the highly conserved (R/K)XGR(R/K) motif in the major facilitator superfamily of transport proteins and to a mutation in human GLUT1 found in individuals with GLUT1-deficiency syndrome. The T336Y mutant also showed no detectable binding; this mutation is likely to have perturbed helix structure or packing to an extent that conformational changes in the protein are hindered. The effects of the mutations on substrate-binding are discussed with reference to the putative positions of the residues in a 3D homology model of GalP based on the X-ray crystal structure of the E. coli glycerol-3-phosphate transporter GlpT.     

Farnesyl protein transferase: identification of K164 alpha and Y300 beta as catalytic residues by mutagenesis and kinetic studies.

Farnesyl protein transferase (FPT) is an alpha/beta heterodimeric zinc enzyme that catalyzes posttranslational farnesylation of many key cellular regulatory proteins, including oncogenic Ras. On the basis of the recently reported crystal structure of FPT complexed with a CVIM peptide and alpha-hydroxyfarnesylphosphonic acid, site-directed mutagenesis of the FPT active site was performed so key residues that are responsible for substrate binding and catalysis could be identified. Eight single mutants, including K164N alpha, Y166F alpha, Y166A alpha, Y200F alpha, H201A alpha, H248A beta, Y300F beta, and Y361F beta, and a double mutant, H248A beta/Y300F beta, were prepared. Steady-state kinetic analysis along with structural evidence indicated that residues Y200 alpha, H201 alpha, H248 beta, and Y361 beta are mainly involved in substrate binding. In addition, biochemical results confirm structural observations which show that residue Y166 alpha plays a key role in stabilizing the active site conformation of several FPT residues through cation-pi interactions. Two mutants, K164N alpha and Y300F beta, have moderately decreased catalytic constants (kcat). Pre-steady-state kinetic analysis of these mutants from rapid quench experiments showed that the chemical step rate constant was reduced by 41- and 30-fold, respectively. The product-releasing rate for each dropped approximately 10-fold. In pH-dependent kinetic studies, Y300F beta was observed to have both acidic and basic pKa values shifted 1 log unit from those of the wild-type enzyme, consistent with a possible role for Y300 beta as an acid-base catalyst. K164N alpha had a pKa shift from 6.0 to 5.3, which suggests it may function as a general acid. On the basis of these results along with structural evidence, a possible FPT reaction mechanism is proposed with both Y300 beta and K164 alpha playing key catalytic roles in enhancing the reactivity of the farnesyl diphosphate leaving group.     

Variable contributions of tyrosine residues to the structural and spectroscopic properties of the factor for inversion stimulation

The diverse roles of tyrosine residues in proteins may be attributed to their dual hydrophobic and polar nature, which can result in hydrophobic and ring stacking interactions, as well as hydrogen bonding. The small homodimeric DNA binding protein, factor for inversion stimulation (FIS), contains four tyrosine residues located at positions 38, 51, 69, and 95, each involved in specific intra- or intermolecular interactions. To investigate their contributions to the stability, flexibility, and spectroscopic properties of FIS, each one was independently mutated to phenylalanine. Equilibrium denaturation experiments show that Tyr95 and Tyr51 stabilize FIS by about 2 and 1 kcal/mol, respectively, as a result of their involvement in a hydrogen bond-salt bridge network. In contrast, Tyr38 destabilizes FIS by about 1 kcal/mol due to the placement of a hydroxyl group in a hydrophobic environment. The stability of FIS was not altered when the solvent-exposed Tyr69 was mutated. Limited proteolysis with trypsin and V8 proteases was used to monitor the flexibility of the C-terminus (residues 71-98) and the dimer core (residues 26-70), respectively. The results for Y95F and Y51F FIS revealed a different proteolytic susceptibility of the dimer core compared to the C-terminus, suggesting an increased flexibility of the latter. DNA binding affinity of the various FIS mutants was only modestly affected and correlated inversely with the C-terminal flexibility probed by trypsin proteolysis. Deconvolution of the fluorescence contribution of each mutant revealed that it varies in intensity and direction for each tyrosine in WT FIS, highlighting the role of specific interactions and the local environment in determining the fluorescence of tyrosine residues. The significant changes in stability, flexibility, and signals observed for the Y51F and Y95F mutations are attributed to their coupled participation in the hydrogen bond-salt bridge network. These results highlight the importance of tyrosine hydrogen-bonding and packing interactions for the stability of FIS and demonstrate the varying roles that tyrosine residues can play on the structural and spectroscopic properties of even small proteins.     

Impact of aromatic residues within transmembrane helix 6 of the human gonadotropin-releasing hormone receptor upon agonist and antagonist binding.

To investigate the impact of aromatic residues within transmembrane helix 6 (TMH6) of the human gonadotropin-releasing hormone receptor (GnRH-R) on agonist and antagonist binding, residues Y(283), Y(284), W(289), Y(290), W(291), and F(292) were exchanged to alanine and analyzed comprehensively in functional reporter gene and ligand binding assays. Whereas receptor mutants Y(283)A, Y(284)A, and W(291)A were capable of neither ligand binding nor signal transduction, mutants W(289)A, Y(290)A, and F(292)A were functional: the F(292)A mutant behaved like wild-type receptor, while mutants W(289)A and Y(290)A differentiated between agonistic and antagonistic ligands. On the basis of the high-resolution X-ray structure of bovine rhodopsin as well as available data on GnRH-R mutants, models for ligand-receptor interactions are proposed. The model for D-Trp(6)-GnRH (Triptorelin) binding, representing a superagonistic ligand, is in full accordance to available data. Furthermore, new interactions are proposed: pGlu(1) interacts with N(212) in transmembrane helix 5, Tyr(5) with Y(290), and D-Trp(6) with W(289). The binding behavior of mutants W(289)A and Y(290)A corresponds to the proposed binding model for the antagonist Cetrorelix. In summary, our data as presented indicate that Y(290) plays a key function in agonist but not antagonist binding.     

Identification and characterization of peptides that bind to cyanovirin-N, a potent human immunodeficiency virus-inactivating protein

Cyanovirin-N (CV-N) exerts a potent human immunodeficiency virus (HIV)-inactivating activity against diverse strains of HIV by binding to the viral surface envelope glycoprotein gp120 and blocking its essential interactions with cellular receptors. Based on previous thermodynamic analyses, it has been speculated that discrete protein-protein interactions might play an important ancillary role in the CV-N/gp120 binding event, in addition to the interactions of CV-N with specific oligosaccharides present on gp120. Here, we report the identification and characterization of CV-N-binding peptides, which were isolated by screening of M13 phage-displayed peptide libraries. After performing three rounds of biopanning of the libraries against biotinylated CV-N, a CV-N-binding motif, X3CX6(W/F)(Y/F)CX2(Y/F), was evident. A vector was designed to express CV-N-binding peptides as a fusion with thioredoxin (Trx) containing a penta-His affinity tag. The CV-N-binding peptides fused with His-tagged Trx inhibited binding of the corresponding peptide-bearing phages to CV-N, confirming that the peptides possessed CV-N-binding activity. Optical biosensor binding studies showed that the one of the CV-N-binding peptide, TN10-1, bound to CV-N with a KD value of 1.9 microM. The results of alanine scanning mutagenesis of the peptide showed that aromatic residues at positions 11, 12, and 16, as well as the conformational structure of the peptide secured by a disulfide bond, were important for the binding interactions. A series of competitive binding assays confirmed that gp120 inhibited CV-N binding of the corresponding peptide-bearing phages, and suggested that TN10-1 peptides were mimicking the protein component of gp120 rather than mimicking specific oligosaccharides present on gp120.     

Ligand-induced changes in the conformational dynamics of a bacterial cytotoxic endonuclease

Knowledge about the conformational dynamics of a protein is key to understanding its biochemical and biophysical properties. In the present work we investigated the dynamic properties of the enzymatic domain of DNase colicins via time-resolved fluorescence and anisotropy decay analysis in combination with steady-state acrylamide quenching experiments. The dynamic properties of the apoenzyme were compared to those of the E9 DNase ligated to the transition metal ion Zn(2+) and the natural inhibitor Im9. We further investigated the contributions of each of the two tryptophans within the E9 DNase (Trp22 and Trp58) using two single-tryptophan mutants (E9 W22F and E9 W58F). Wild-type E9 DNase, E9 W22F, and E9 W58F, as well as Im9, showed multiple lifetime decays. The time-resolved and steady-state fluorescence results indicated that complexation of E9 DNase with Zn(2+) induces compaction of the E9 DNase structure, accompanied by immobilization of Trp22 along with a reduced solvent accessibility for both tryptophans. Im9 binding resulted in immobilization of Trp22 along with a decrease in the longest lifetime component. In contrast, Trp58 experienced less restriction on complexation of E9 DNase with Im9 and showed an increase in the longest lifetime component. Furthermore, the results point out that the Im9-induced changes in the conformational dynamics of E9 DNase are predominant and occur independently of the Zn(2+)-induced conformational effects.     

Characterization of active-site aromatic residues in xylanase A from Streptomyces lividans

The role of four aromatic residues (W85, Y172, W266 and W274) in the structure-function relationship in xylanase A from Streptomyces lividans (XlnA) was investigated by site-directed mutagenesis where each residue was subjected to three substitutions (W85A/H/F; W266A/H/F; W274A/H/F and Y172A/F/S). These four amino acids are highly conserved among family 10 xylanases and structural data have implicated them in substrate binding at the active site. Far-UV circular dichroism spectroscopy was used to show that the overall structure of XlnA was not affected by any of these mutations. High-performance liquid chromatographic analysis of the hydrolysis products of birchwood xylan and xylopentaose showed that mutation of these aromatic residues did not alter the enzyme's mode of action. As expected, though, it did reduce the affinity of XlnA for birchwood xylan. A comparison of the kinetic parameters of different mutants at the same position demonstrated the importance of the aromatic nature of W85, Y172 and W274 in substrate binding. Replacement of these residues by a phenylalanine resulted in mutant proteins with a K(M) closer to that of the wild-type protein in comparison with the other mutations analyzed. The kinetic analysis of the mutant proteins at position W266 indicated that this amino acid is important for both substrate binding and efficient catalysis by XlnA. These studies also demonstrated the crucial role of these active site aromatic residues for the thermal stability of XlnA.     

Structural mimicry in class A G protein-coupled receptor rotamer toggle switches: the importance of the F3.36(201)/W6.48(357) interaction in cannabinoid CB1 receptor activation

In this study, we tested the hypothesis that a CB(1) TMH3-4-5-6 aromatic microdomain, which includes F3.25(190), F3.36(201), W5.43(280), and W6.48(357), is centrally involved in CB(1) receptor activation, with the F3.36(201)/W6.48(357) interaction key to the maintenance of the CB(1)-inactive state. We have shown previously that when F3.36(201), W5.43(280), and W6.48(357) are individually mutated to alanine, a significant reduction in ligand binding affinity is observed in the presence of WIN 55,212-2 and SR141716A but not CP55,940 and anandamide. In the work presented here, we report a detailed functional analysis of the F3.36(201)A, F3.25(190)A, W5.43(280)A, and W6.48(357)A mutant receptors in stable cell lines created in HEK cells for agonist-stimulated guanosine 5'-3-O-(thio)triphosphate (GTPgammaS) binding and GIRK1/4 channel current effects in Xenopus oocytes where the mutant proteins were expressed transiently. The F3.36(201)A mutation showed statistically significant increases in ligand-independent stimulation of GTPgammaS binding versus wild type CB(1), although basal levels for the W6.48(357)A mutant were not statistically different from wild type CB(1). F3.36(201)A demonstrated a limited activation profile in the presence of multiple agonists. In contrast, enhanced agonist activation was produced by W6.48(357)A. These results suggest that a F3.36(201)/W6.48(357)-specific contact is an important constraint for the CB(1)-inactive state that may need to break during activation. Modeling studies suggest that the F3.36(201)/W6.48(357) contact can exist in the inactive state of CB(1) and be broken in the activated state via a chi(1) rotamer switch (F3.36(201) trans, W6.48(357) g+) --> (F3.36(201) g+, W6.48(357) trans). The F3.36(201)/W6.48(357) interaction therefore may represent a "toggle switch" for activation of CB(1).     

Determining sites of interaction between prenisin and its modification enzymes NisB and NisC

Although nisin is a model lantibiotic, our knowledge of the specific interactions of prenisin with its modification enzymes remains fragmentary. Here, we demonstrate that the nisin modification enzymes NisB and NisC can be pulled down in vitro from Lactococcus lactis by an engineered His-tagged prenisin. This approach enables us to determine important intermolecular interactions of prenisin with its modification machinery within L. lactis. We demonstrate that (i) NisB has stronger interactions with precursor nisin than NisC has, (ii) deletion of the propeptide part keeping the nisin leader intact leads to a lack of binding, (iii) NisB point mutants of highly conserved residues W616, F342A, Y346F and P639A are still able to dehydrate prenisin, (iv) NisB Δ(77-79)Y80F mutant decreased the levels of NisB-prenisin interactions and resulted in unmodified prenisin, (v) substitution of an active site residue H331A in NisC leads to higher amounts of the co-purified complex, (vi) NisB is present in the form of a dimer, and (vii) the region FNLD (-18 to -15) of the leader is an important site for binding not only to NisB, but also to NisC.     

Aryl–aryl interactions in designed peptide folds: Spectroscopic characteristics and optimal placement for structure stabilization

We have extended our studies of Trp/Trp to other Aryl/Aryl through‐space interactions that stabilize hairpins and other small polypeptide folds. Herein we detail the NMR and CD spectroscopic features of these types of interactions. NMR data remains the best diagnostic for characterizing the common T‐shape orientation. Designated as an edge‐to‐face (EtF or FtE) interaction, large ring current shifts are produced at the edge aryl ring hydrogens and, in most cases, large exciton couplets appear in the far UV circular dichroic (CD) spectrum. The preference for the face aryl in FtE clusters is W ? Y ≥ F (there are some exceptions in the Y/F order); this sequence corresponds to the order of fold stability enhancement and always predicts the amplitude of the lower energy feature of the exciton couplet in the CD spectrum. The CD spectra for FtE W/W, W/Y, Y/W, and Y/Y pairs all include an intense feature at 225–232 nm. An additional couplet feature seen for W/Y, W/F, Y/Y, and F/Y clusters, is a negative feature at 197–200 nm. Tyr/Tyr (as well as F/Y and F/F) interactions produce much smaller exciton couplet amplitudes. The Trp‐cage fold was employed to search for the CD effects of other Trp/Trp and Trp/Tyr cluster geometries: several were identified. In this account, we provide additional examples of the application of cross‐strand aryl/aryl clusters for the design of stable β‐sheet models and a scale of fold stability increments associated with all possible FtE Ar/Ar clusters in several structural contexts. © 2016 Wiley Periodicals, Inc. Biopolymers 105: 337–356, 2016.     

Tyrosine quenching of tryptophan phosphorescence in glyceraldehyde-3-phosphate dehydrogenase from Bacillus stearothermophilus.

Tyrosine is known to quench the phosphorescence of free tryptophan derivatives in solution, but the interaction between tryptophan residues in proteins and neighboring tyrosine side chains has not yet been demonstrated. This report examines the potential role of Y283 in quenching the phosphorescence emission of W310 of glyceraldehyde-3-phosphate dehydrogenase from Bacillus stearothermophilus by comparing the phosphorescence characteristics of the wild-type enzyme to that of appositely designed mutants in which either the second tryptophan residue, W84, is replaced with phenylalanine or Y283 is replaced by valine. Phosphorescence spectra and lifetimes in polyol/buffer low-temperature glasses demonstrate that W310, in both wild-type and W84F (Trp84-->Phe) mutant proteins, is already quenched in viscous low-temperature solutions, before the onset of major structural fluctuations in the macromolecule, an anomalous quenching that is abolished with the mutation Y283V (Tyr283-->Val). In buffer at ambient temperature, the effect of replacing Y283 with valine on the phosphorescence of W310 is to lengthen its lifetime from 50 micros to 2.5 ms, a 50-fold enhancement that again emphasizes how W310 emission is dominated by the local interaction with Y283. Tyr quenching of W310 exhibits a strong temperature dependence, with a rate constant kq = 0.1 s(-1) at 140 K and 2 x 10(4) s(-1) at 293 K. Comparison between thermal quenching profiles of the W84F mutant in solution and in the dry state, where protein flexibility is drastically reduced, shows that the activation energy of the quenching reaction is rather small, Ea < or = 0.17 kcal mol(-1), and that, on the contrary, structural fluctuations play an important role on the effectiveness of Tyr quenching. Various putative quenching mechanisms are examined, and the conclusion, based on the present results as well as on the phosphorescence characteristics of other protein systems, is that Tyr quenching occurs through the formation of an excited-state triplet exciplex.