Engineering of the pH optimum of Bacillus cereus beta-amylase: conversion of the pH optimum from a bacterial type to a higher-plant type

The optimum pH of Bacillus cereus beta-amylase (BCB, pH 6.7) differs from that of soybean beta-amylase (SBA, pH 5.4) due to the substitution of a few amino acid residues near the catalytic base residue (Glu 380 in SBA and Glu 367 in BCB). To explore the mechanism for controlling the optimum pH of beta-amylase, five mutants of BCB (Y164E, Y164F, Y164H, Y164Q, and Y164Q/T47M/Y164E/T328N) were constructed and characterized with respect to enzymatic properties and X-ray structural crystal analysis. The optimum pH of the four single mutants shifted to 4.2-4.8, approximately 2 pH units and approximately 1 pH unit lower than those of BCB and SBA, respectively, and their k(cat) values decreased to 41-3% of that of the wild-type enzyme. The X-ray crystal analysis of the enzyme-maltose complexes showed that Glu 367 of the wild type is surrounded by two water molecules (W1 and W2) that are not found in SBA. W1 is hydrogen-bonded to both side chains of Glu 367 and Tyr 164. The mutation of Tyr 164 to Glu and Phe resulted in the disruption of the hydrogen bond between Tyr 164 Oeta and W1 and the introduction of two additional water molecules near position 164. In contrast, the triple mutant of BCB with a slightly decreased pH optimum at pH 6.0 has no water molecules (W1 and W2) around Glu 367. These results suggested that a water-mediated hydrogen bond network (Glu 367...W1...Tyr 164...Thr 328) is the primary requisite for the increased pH optimum of wild-type BCB. This strategy is completely different from that of SBA, in which a hydrogen bond network (Glu 380...Thr 340...Glu 178) reduces the optimum pH in a hydrophobic environment.     

Molecular origin of the pH dependence of tyrosine D oxidation kinetics and radical stability in photosystem II

A role for redox-active tyrosines has been demonstrated in many important biological processes, including water oxidation carried out by photosystem II (PSII) of oxygenic photosynthesis. The rates of tyrosine oxidation and reduction and the Tyr/Tyr reduction potential are undoubtedly controlled by the immediate environment of the tyrosine, with the coupling of electron and proton transfer, a critical component of the kinetic and redox behavior. It has been demonstrated by Faller et al. that the rate of oxidation of tyrosine D (Tyr(D)) at room temperature and the extent of Tyr(D) oxidation at cryogenic temperatures, following flash excitation, dramatically increase as a function of pH with a pK(a) of approximately 7.6 [Faller et al. 2001 Proc. Natl. Acad. Sci. USA 98, 14368-14373; Faller et al. 2001 Biochemistry 41, 12914-12920]. In this work, we investigated, using FTIR difference spectroscopy, the mechanistic reasons behind this large pH dependence. These studies were carried out on Mn-depleted PSII core complexes isolated from Synechocystis sp. PCC 6803, WT unlabeled and labeled with (13)C(6)-, or (13)C(1)(4)-labeled tyrosine, as well as on the D2-Gln164Glu mutant. The main conclusions of this work are that the pH-induced changes involve the reduced Tyr(D) state and not the oxidized Tyr(D)() state and that Tyr(D) does not exist in the tyrosinate form between pH 6 and 10. We can also exclude a change in the protonation state of D2-His189 as being responsible for the large pH dependence of Tyr(D) oxidation. Indeed, our data are consistent with D2-His189 being neutral both in the Tyr(D) and Tyr(D)() states in the whole pH6-10 range. We show that the interactions between reduced Tyr(D) and D2-His189 are modulated by the pH. At pH greater than 7.5, the nu(CO) mode frequency of Tyr(D) indicates that Tyr(D) is involved in a strong hydrogen bond, as a hydrogen bond donor only, in a fraction of the PSII centers. At pH below 7.5, the hydrogen-bonding interaction formed by Tyr(D) is weaker and Tyr(D) could be also involved as a hydrogen bond acceptor, according to calculations performed by Takahashi and Noguchi [J. Phys. Chem. B 2007 111, 13833-13844]. The involvement of Tyr(D) in this strong hydrogen-bonding interaction correlates with the ability to oxidize Tyr(D) at cryogenic temperatures and rapidly at room temperature. A strong hydrogen-bonding interaction is also observed at pH 6 in the D2-Gln164Glu mutant, showing that the residue at position D2-164 regulates the properties of Tyr(D.) The IR data point to the role of a protonatable group(s) (with a pK(a) of approximately 7) other than D2-His189 and Tyr(D), in modifying the characteristics of the Tyr(D) hydrogen-bonding interactions, and hence its oxidation properties. It remains to be determined whether the strong hydrogen-bonding interaction involves D2-His189 and if Tyr(D) oxidation involves the same proton transfer route at low and at high pH.     

Influence of the protein environment on the properties of a tyrosyl radical in reaction centers from Rhodobacter sphaeroides

The influence of the local environment on the formation of a tyrosyl radical was investigated in modified photosynthetic reaction centers from Rhodobacter sphaeroides. The reaction centers contain a tyrosine residue placed approximately 10 A from a highly oxidizing bacteriochlorophyll dimer. Measurements by both optical and electron paramagnetic resonance spectroscopy revealed spectral features that are assigned as arising primarily from an oxidized bacteriochlorophyll dimer at low pH values and from a tyrosyl radical at high pH values, with a well-defined transition that occurred with a pK(a) of 6.9. A model based on the wild-type structure indicated that the Tyr at M164 is likely to form a hydrogen bond with His M193 and to interact weakly with Glu M173. Substitution of Tyr or Glu for His at M193 increased the pK(a) for the transition from 6.9 to 8.9, while substitution of Gln for His M193 resulted in a higher pK(a) value. Substitution of Glu M173 with Gln resulted in loss of the partial formation of the tyrosyl that occurs in the other mutants at low pH values. The results are interpreted in terms of the ability of the residues to act as proton acceptors for the oxidized tyrosine, with the pK(a) values reflecting those of either the putative proton acceptor or the tyrosine, in accord with general models of amino acid radicals.     

Studies of the association and conformational properties of metal-free insulin in alkaline sodium chloride solutions by one- and two-dimensional 1H NMR.

One- and two-dimensional 1H NMR spectroscopy have been employed to probe the association and subsequent conformational changes of metal-free insulin in sodium chloride solution at pH 9 and 9.4. These studies establish that the proton resonances of His(B5) and His(B10) are useful signatures of aggregation and conformation. Changes in chemical shifts and areas of resonances due to the C2 protons of His(B10) and His(B5) and transfer of magnetization experiments served to identify the association as the assembly of tetramer from dimers under our experimental conditions (pH 9.4, [insulin] greater than 1 mM, [NaCl] = 0.1 M). Sodium chloride also alters the equilibrium distribution of species in favor of a tetrameric species. The association equilibrium constant was estimated from area measurements to be approximately 5 x 10(3) M-1 at pH 9.4, 26 +/- 0.1 degrees C, and 0.1 M sodium chloride. Under conditions of 0.1 M sodium chloride concentration, nuclear Overhauser effect experiments in the one- and two-dimensional modes revealed an operative nuclear Overhauser effect between the His(B5) C2 protons and the 2,6 ring protons of a Tyr residue provisionally assigned as Tyr(B16). We conclude that this interaction is a diagnostic signature of a conformational transition whereupon an extended chain from residues B1 to B9 (T-state) is transformed into an alpha-helix (R-state) thus bringing the rings of His(B5) and Tyr(B16) from adjacent subunits across the monomer-monomer interface into van der Waals contact. This conformational flexibility is an added consideration to the discussion of the relevant structure of insulin for receptor binding.     

Tyrosylprotein sulfotransferase in rat submandibular salivary glands.

1. The transfer of sulfate ester group from 3'-phosphoadenosine 5'-phosphosulfate (PAPS) to poly-(Glu6, Ala3, Tyr1) (EAY; Mr 47 kDa) in rat submandibular salivary gland has been investigated. The highest tyrosylprotein sulfotransferase activity was obtained in the Golgi-enriched fraction in the presence of 2 mM 5'AMP, 20 mM MnCl2 and 50 mM NaF at pH 6.2. 2. The apparent Km values for EAY and PAPS were 1.6 x 10(-6) and 1.9 x 10(-6) M, respectively. 3. Inclusion of NaCl, EDTA, NEM and DTT was inhibitory for the enzyme activity. The enzyme was 28 times less susceptible to 2,6-dichloro-4-nitrophenol inhibition than to phenol sulfotransferase inhibition. 4. This study is the first report characterizing a sulfotransferase activity specific for tyrosylprotein in rat submandibular salivary glands.     

Study by PMR spectroscopy and gel chromatography of the unfolding of substituted kerateines in 8 M urea.

Various S-substituted derivatives of the reduced low sulphur and high proteins from wool have been prepared in which the substituted group is hydrogen, carboxymethyl, carboxethyl, methyl, carbamidomethyl, cyanoethyl and aminoethyl. The proton magnetic resonance (PMR) spectra and gel filtration chromatography of these proteins have been examined in 8 M urea solution as a function of pH in order to determine conditions under which the proteins occur as random coils in solution with no evidence for the occurrence of non-covalent interactions. The PMR method described in an earlier paper (1) provides an easier and much more sensitive method for the observation of non-covalent interactions in random coil proteins than does the measurement of elution volumes in gel chromatography. The results obtained by both methods are consistent and show that the widest range of pH for which unfolding occurs in 8 M urea is obtained with the S-carboxymethyl, S-carboxyethyl, S-methyl and S-carbamidomethyl derivatives.     

Various proteins modulate the kinase activity of the insulin receptor

Previous studies of the substrate specificity of the purified insulin receptor tyrosine kinase using synthetic random polymers have demonstrated that the receptor kinase phosphorylates poly (Glu, Tyr) 4:1 but not poly (Glu, Tyr) 1:1. In the present study, insulin treatment of Chinese hamster ovary cells overexpressing the human insulin receptor was found to stimulate the ability of their membrane extracts to phosphorylate poly (Glu, Tyr) 1:1. It was concluded that this activity was due to the receptor itself because: 1) it was precipitated with a monoclonal antibody to the receptor; 2) the addition of various membrane extracts to purified insulin receptor preparations stimulated the ability of these preparations to phosphorylate poly (Glu, Tyr) 1:1; and 3) certain purified proteins, including bovine serum albumin and casein, were also capable of stimulating the purified receptor to phosphorylate poly (Glu, Tyr) 1:1. The effect of albumin was dose-dependent; 0.5 and 10 mg/ml bovine serum albumin stimulated the phosphorylation of poly (Glu, Tyr) 1:1 by 2- and 230-fold, respectively. In contrast, albumin had no effect on the phosphorylation of poly (Glu, Tyr) 4:1. These results indicate that the activity of the insulin receptor kinase on certain substrates can be modulated by the presence of other proteins.     

The nuclear matrix from rat liver is capable of phosphorylating exogenous tyrosine-containing substrates

The nuclear matrix isolated from rat liver phosphorylated exogenous tyrosine-containing substrates angiotensin II and synthetic polymer (Glu, Tyr; 4:1). The phosphorylation reaction was dependent on Mn2+ or Mg2+, but the former was the preferred ion. Km values for poly(Glu,Tyr; 4:1) and ATP were 0.2 mM and 4 microM, respectively. Angiotensin II showed a lower affinity for the kinase than poly(Glu,Tyr; 4:1). The isoflavone genistein, a specific inhibitor for tyrosine phosphorylation, inhibited the tyrosine kinase activity in the nuclear matrix.     

Structural studies of metalloporphyrins. Part XIa: Complexes of water-soluble zinc(II) porphyrins with amino acids: influence of ligand-ligand interactions on the stability of the complexes

The stability constants of a series of complexes of the cationic water-soluble porphyrin ZnTMPyP with various amino acids have been determined by 1H NMR spectroscopy at pH 10.5. The following stability order has been observed: Tyr greater than Phe, Glu greater than Asp greater than Ile greater than Val greater than Gly. These results can be best rationalized by invoking complex stabilization due to ligand-ligand (e.g., stacking or electrostatic) interactions. Evidence for stacking interactions between the porphyrin ring and the aromatic ring of phenylalanine, tyrosine, and tryptophan was further provided by study of the complexation of these amino acids with the free-base porphyrin TMPyPH2. In this case, complexation constants increased in the order: Phe less than Tyr less than Trp. Attempts to form complexes of the amino acids with the anionic porphyrin ZnTCPP proved unsuccessful, indicating that electrostatic interactions play a major role in the stability of the zinc porphyrin-amino acids complexes.     

Structure of an analog of fusion peptide from hemagglutinin

A 20-residue peptide E5 containing five glutamates, an analog of the fusion peptide of influenza virus hemagglutinin (HA) exhibiting fusion activity at acidic pH lower than 6.0-6.5 was studied by circular dichroism (CD), Fourier transform infrared, and 1H-NMR spectroscopy in water, water/trifluoroethanol (TFE) mixtures, dodecylphosphocholine (DPC) micelles, and phospholipid vesicles. E5 became structurally ordered at pH < or = 6 and the helical content in the peptide increased in the row: water < water/TFE < DPC approximately = phospholipid vesicle while the amount of beta-structure was approximately reverse. 1H-NMR data and line-broadening effect of 5-, 16-doxylstearates on proton resonances of DPC bound peptide showed E5 forms amphiphilic alpha-helix in residues 2-18, which is flexible in 11-18 part. The analysis of the proton chemical shifts of DPC bound and CD intensity at 220 nm of phospholipid bound E5 showed that the pH dependence of helical content is characterized by the same pKa approximately 5.6. Only Glu11 and Glu15 in DPC bound peptide showed such elevated pKas, presumably due to transient hydrogen bond(s) Glu11 (Glu15) deltaCOO- (H+)...HN Glu15 that dispose(s) the side chain of Glu11 (Glu15) residue(s) close to the micelle/water interface. These glutamates are present in the HA-fusion peptide and the experimental half-maximal pH of fusion for HA and E5 peptides is approximately 5.6. Therefore, a specific anchorage of these peptides onto membrane necessary for fusion is likely driven by the protonation of the carboxylate group of Glu11 (Glu15) residue(s) participating in transient hydrogen bond(s).     

Identification and purification of a cytosolic phosphotyrosyl protein phosphatase from bovine spleen

A protein tyrosine kinase with an apparent Mr of 60,000 was highly purified from bovine spleen and used to phosphorylate poly(Glu, Tyr) (4:1) on tyrosine residues for the study of phosphotyrosyl protein phosphatases from this tissue. About 70% of the phosphotyrosyl protein phosphatase activity in extracts of bovine spleen was adsorbed on DEAE-Sepharose. Chromatography of the eluted phosphotyrosyl protein phosphatases on phosphocellulose indicated the presence of at least two species, one that did not bind to the phosphocellulose and a second species that did bind and was eluted at about 0.5 M NaCl. The phosphatase that did not bind to phosphocellulose was further purified by successive chromatography on poly(L-lysine)-Sepharose, L-tyrosine-agarose, poly(Glu,Tyr)-Sepharose, and Sephacryl S-200. The enzyme had an apparent Mr of 50,000 as estimated by gel filtration and 52,000 as estimated by NaDodSO4- polyacrylamide gel electrophoresis. The phosphatase exhibited a pH optimum of 6.5-7.0, was inhibited by Zn2+ and vanadate ions, and was stimulated by EDTA. Sodium fluoride and sodium pyrophosphate, inhibitors of phosphoseryl protein phosphatases, had no effect on the enzyme. Protein inhibitors of type 1 phosphoseryl/threonyl phosphatase were also ineffective.     

Regulation of immune responses by I-J gene products. V. Heterogeneity of I-J gene products as detected by anti-I-J monoclonal antibodies

The products of I-region genes of the murine major histocompatibility complex (H-2) are intimately involved in the regulation of immune responses. In a number of antigen systems, suppressor T (Ts) cells and their factors (TsF) bear determinants of gene(s) that map to the I-J subregion of the H-2 complex. Suppression in one such system, poly(Glu50Tyr50)(GT), involves the interaction of multiple Ts subsets. Three monoclonal I-Jk-bearing GT-TsF have been identified that functionally differ from one another. We report the binding of these monoclonal GT-TsF to different anti-I-Jk monoclonal antibody columns. We find that these anti-I-Jk monoclonal antibodies display differing degrees of efficiency of GT-TsF binding. These data suggest a greater degree of heterogeneity of I-Jk gene products than has been proposed before.     

Interaction between tyrosineZ and substrate water in active photosystem II

In the field of photosynthetic water oxidation it has been under debate whether Tyrosine(Z) (Tyr(Z)) acts as a hydrogen or an electron acceptor from water. In the former concept, direct contact of Tyr(Z) with substrate water has been assumed. However, there is no direct evidence for the interaction between Tyr(Z) and substrate water in active Photosystem II (PSII), instead most experiments have been performed on inhibited PSII. Here, this problem is tackled in active PSII by combining low temperature EPR measurements and quantum chemistry calculations. EPR measurements observed that the maximum yield of Tyr(Z) oxidation at cryogenic temperature in the S(0) and S(1) states was around neutral pH and was essentially pH-independent. The yield of Tyr(Z) oxidation decreased at acidic and alkaline pH, with pKs at 4.7-4.9 and 7.7, respectively. The observed pH-dependent parts at low and high values of pH can be explained as due to sample inactivation, rather than active PSII. The reduction kinetics of Tyr(Z)(.) in the S(0) and S(1) states were pH independent at pH range from 4.5 to 8. Therefore, the change of the pH in bulk solution probably has no effect on the Tyr(Z) oxidation and Tyr(Z)(.) reduction at cryogenic temperature in the S(0) and S(1) states of the active PSII. Theoretical calculations indicate that Tyr(Z) becomes more difficult to oxidize when a H(2)O molecule interacts directly with it. It is suggested that Tyr(Z) is probably located in a hydrophobic environment with no direct interaction with the substrate H(2)O in active PSII. These results provide new insights on the function and mechanism of water oxidation in PSII.     

Chemical rescue of a mutant protein-tyrosine kinase

Protein-tyrosine kinases contain a catalytic loop Arg residue located either two or four positions downstream of a highly conserved Asp residue. In this study, the role of this Arg (Arg-318) in the protein-tyrosine kinase C-terminal Src kinase (Csk) was investigated. The observed k(cat) for phosphorylation of the random copolymer poly(Glu,Tyr) substrate by Csk R318A is approximately 3000-fold smaller compared with that of wild type Csk, whereas the K(m) values for ATP and poly(Glu,Tyr) are only mildly affected. The k(cat) value for poly(Glu,Tyr) phosphorylation by the Csk double mutant A316R,R318A is 100-fold greater than the k(cat) value for the single R318A mutant, suggesting that an Arg positioned at the alternative location fulfills a similar function as in wild type. Csk R318A kinase activity can also be partially recovered by several exogenous small molecules including guanidinium and imidazole. These molecules contain key features whose roles in catalysis can be rationalized from a known x-ray structure of the insulin receptor tyrosine kinase. Imidazole is the best of these activators, enhancing phosphorylation rates by Csk R318A up to 100-fold for poly(Glu,Tyr) and significantly stimulating Csk R318A phosphorylation of the physiologic substrate Src. This chemical rescue of mutant protein kinase activity might find applications in cell signal transduction experiments.     

Localization of bound water in the solution structure of the immunoglobulin binding domain of streptococcal protein G. Evidence for solvent-induced helical distortion in solution.

The presence of bound water in the solution structure of the IgG binding domain of streptococcal protein G has been investigated by nuclear magnetic resonance using three-dimensional 1H rotating frame Overhauser 1H-15N multiple quantum coherence spectroscopy. The backbone amide protons of three residues, Ala20, Gln32 and Tyr33, are found to be in close proximity to bound water. Examination of the three-dimensional structure of the IgG binding domain indicates that in the vicinity of these three residues there are no backbone groups that do not already participate in hydrogen bonding and there are no suitably placed side-chain groups available for hydrogen bonding with water. As the lifetime of the bound water detected in this nuclear magnetic resonance experiment is greater than about one nanosecond, it is likely that the two bound water molecules participate in a bifurcating hydrogen bonding network comprising a CO-NH hydrogen bonded pair, such that the water molecule accepts a hydrogen bond from the NH proton and donates one to the carbonyl oxygen with the result that the amide proton is involved in a three center hydrogen bond. On the basis of the structure, one water molecule participates in such an interaction with the Ala20(NH)-Met1(CO) hydrogen bonded pair at the beginning of an anti-parallel beta-sheet, and the other with the Tyr33(NH)-Val29(CO) hydrogen bonded pair in the single alpha-helix. The latter, which is external and solvent accessible, is associated with a distortion in the alpha-helix centered around Tyr33 which consists of a significant increase in the CO(i-4)-N(i) and CO(i-4)-NH(i) distances relative to those in the rest of the helix, as well as a significant departure in the phi, psi angles of Tyr33 relative to regular helical geometry. Such solvent induced distortions in alpha-helices have been previously noticed in crystal structures and were postulated as possible folding intermediates for helical structures. The present observation of this phenomenon in solution indicates, however, that these water molecules are tightly bound and represent an integral part of the protein framework.     

Refined X-ray structure of the low pH form of ribonuclease T1-2'-guanylic acid complex at 1.9 A resolution

The three-dimensional X-ray structure of the RNase T1[EC 3.1.27.3]-2'GMP complex crystallized at low pH value (4.0) was determined, and refined to 1.9 A resolution to give a final R value of 0.203. The refined model includes 781 protein atoms, 24 inhibitor atoms, and 43 solvent molecules. The imidazole rings of His27 and His40 interact with the carboxyl side chains of Glu82 and Glu58, respectively, whereas that of His92 is in contact with the main chain carbonyl oxygen of Ala75. In the complex, the ribose ring of the 2'GMP molecule adopts a C2'-endo puckering, and the exocyclic conformation is gauche(-)-gauche(+). The glycosyl torsion angle is in the syn range with an intramolecular hydrogen bond between N3 and O5', and the 2'-phosphate orientation is trans-gauche(-). The guanine base of the inhibitor is tightly bound to the base recognition site with five hydrogen bonds (N1--Glu46O epsilon 2, N2---Asn98O,O6---Asn44N, and N7 ---Asn43N delta 2/Asn43N) and is sandwiched between the phenolic ring portions of Tyr42 and Tyr45 by stacking interactions. The 2'-phosphate group interacts with Arg77N eta 2, Glu58O episilon 2, and Tyr 38O eta but not with any of the histidine residues. Arg77N eta 2 also interacts with Tyr38O eta. There is no interaction between the ribose moiety of the inhibitor and the enzyme.     

Implications for an ionized alkyl-enzyme intermediate during StEH1-catalyzed trans-stilbene oxide hydrolysis

The catalytic mechanism of epoxide hydrolase (EC 3.3.2.3) involves acid-assisted ring opening of the oxirane during the alkylation half-reaction of hydrolysis. Two tyrosyl residues in the active site of epoxide hydrolases have been shown to contribute to the catalysis of enzyme alkylation, but their mechanism of action has not been fully described. We have investigated the involvement of the active site Tyr154 and Tyr235 during S,S-trans-stilbene oxide hydrolysis catalyzed by potato epoxide hydrolase StEH1. Tyr phenol ionizations of unliganded enzyme as well as under pre-steady-state conditions during catalysis were studied by direct absorption spectroscopy. A transient UV absorption, indicative of tyrosinate formation, was detected during the lifetime of the alkyl-enzyme intermediate. The apparent pKa of Tyr ionization was 7.3, a value more than 3 pH units below the estimated pKa of protein Tyr residues in the unliganded enzyme. In addition, the pH dependencies of microscopic kinetic rates of catalyzed S,S-trans-stilbene oxide hydrolysis were determined. The alkylation rate increased with pH and displayed a pKa value identical to that of Tyr ionization (7.3), whereas the reverse (epoxidation) reaction did not display any pH dependence. The rate of alkyl-enzyme hydrolysis was inversely dependent on tyrosinate formation, decreasing with its buildup in the active site. Since alkyl-enzyme hydrolysis is the rate-limiting step of the overall reaction, kcat displayed the same decrease with pH as the hydrolysis rate. The compiled results suggested that the role of the Tyr154/Tyr235 pair was not as ultimate proton donor to the alkoxide anion but to stabilize the negatively charged alkyl-enzyme through electrophilic catalysis via hydrogen bonding.     

Quantitative analysis of helix-coil transition of block copolypeptide, Glu12-Ala12, by combined use of CD and NMR spectroscopy

To investigate helix-coil transition mechanisms, conformations of Glu12-Ala12, EA, in aqueous solution have been studied in detail over the pH range from 2 to 8 and the temperature range from 20 to 60 degrees C using CD and NMR spectroscopy. The 750-MHz NMR spectra displayed excellent dispersion of the backbone amide proton signals, and permitted essentially complete sequence-specific resonance assignments. These assignments, together with short- and medium-range nuclear Overhauser effect (NOE) constraints and coupling constants, enable us to analyze conformational characteristics of all the residues in the EA peptide individually. A combined use of CD and NMR techniques reveals that the EA peptide assumes a stable alpha-helix from Glu12 to Ala19 in 0.1 M NaCl solution at 20 degrees C above pH 7. The alpha-helix is getting longer as decreasing pH. Below pH 4, the peptide assumes the longest alpha-helix from Glu3 to Ala23. The important observation of the present study is that the helix-coil transition occurs stepwise, residue by residue, from both the N- and C-termini of the alpha-helix. No conformational equilibrium between the helical and random-coil states is detected for the residues in the central region of the alpha-helix. Quantitative analysis of temperature-induced helix-to-coil transitions at various pHs provides a pH-independent residual enthalpy change delta H(r) = 0.95 kcal res(-1). Similar values have been reported for a 50-residue alanine-rich peptide (1.2 kcal res(-1)), poly-L-glutamate (1.1 kcal res(-1)), poly-L-lysine (1.1 kcal res(-1)), and poly-L-alanine (0.86 kcal res(-1)). Those investigations, along with our present result, suggest that delta H(r) is mainly determined by the transformation of the backbone associated with the disruption of the intramolecular hydrogen bond. These results should increase our understanding of the helix-coil transition.     

Proton NMR studies of Cucurbita maxima trypsin inhibitors: evidence for pH-dependent conformational change and His25-Tyr27 interaction.

A pH-dependent His25-Tyr27 interaction was demonstrated in the case of Cucurbita maxima trypsin inhibitors (CMTI-I and CMTI-III) by means of nuclear magnetic resonance (NMR) spectroscopy. pH titration, line widths, peak shapes, deuterium exchange kinetics, and two-dimensional nuclear Overhauser effect spectroscopy (NOESY) were employed to characterize a conformational change involving Tyr27, which was shown to be triggered by deprotonation of His25 around pH 6. A hydrogen bond is proposed to be formed between N epsilon of His25 and OH of Tyr27, as a distance between the atoms, His25 N epsilon and Tyr27 OH, of 3.02 A is consistent with a model built with NOE-derived distance constraints. Both the X-ray [Bode, W., Greyling, J.H., Huber, R., Otlewski, J., & Wilusz, T. (1989) FEBS Lett. 242, 282-292] and NMR [Holak, T.A., Gondol, D., Otlewski, J., & Wilusz, T. (1989) J. Mol. Biol. 210, 635-648] structures of CMTI-I at low pH (4.7-5.3) rule out such an interaction between the two aromatic rings, as the ring planes are oriented about 10 A away from each other. The presently characterized relative orientations of His25 and Tyr27 are of functional significance, as these residues make contact with the enzyme in the enzyme-inhibitor complex. Furthermore, trypsin assay and inhibitor-binding studies showed that conformations of trypsin and the squash inhibitor were functionally relevant only in the pH range 6-8. The pKa of His25 was determined and found to be influenced by Glu9/Lys substitution and by the hydrolysis of the reactive-site peptide bond between Arg5 and Ile6.(ABSTRACT TRUNCATED AT 250 WORDS)     

High-resolution study of the helix–coil transition of poly(L-glutamic acid): Spectroscopic data correlation and the discovery of a new transition

This article reports on both (1) the precision and capability of a computerized multidimensional spectrophotometric system recently developed in our laboratory and (2) the high-resolution study of the helix–coil transition of poly(L-glutamic acid)[poly(Glu)], especially with regard to the discovery of an overlooked transition which is attributable to order–disorder rearrangement of the poly(Glu) side chain in the α-helical conformation. This study was made possible by the high performance of the system used. The simultaneous and continuous measurement of the circular dichroism, the absorbance and light-scattering intensity, and the pH titration curve of poly(Glu) in aqueous salt solution was carried out under continuous scanning of pH ranging from 8 to 2. Besides the well-known random coil to α-helix transition that occurs at about pH 5.5, a highly cooperative transition, which is indicated as a small but definite step in several spectral dimensions, is observed for the first time at pH 4.3. The transition is ascribed to an order–disorder conversion of the side chain on the α-helix backbone.