A novel beta-defensin structure: a potential strategy of big defensin for overcoming resistance by Gram-positive bacteria.

Big defensin is a 79-residue peptide derived from hemocytes of the Japanese horseshoe crab. It has antimicrobial activities against Gram-positive and -negative bacteria. The amino acid sequence of big defensin can be divided into an N-terminal hydrophobic half and a C-terminal cationic half. Interestingly, the trypsin cleaves big defensin into two fragments, the N-terminal and C-terminal fragments, which are responsible for antimicrobial activity against Gram-positive and -negative bacteria, respectively. To explore the antimicrobial mechanism of big defensin, we determined the solution structure of mature big defensin and performed a titration experiment with DPC micelles. Big defensin has a novel defensin structure; the C-terminal domain adopts a beta-defensin structure, and the N-terminal domain forms a unique globular conformation. It is noteworthy that the hydrophobic N-terminal domain undergoes a conformational change in micelle solution, while the C-terminal domain remains unchanged. Here, we propose that the N-terminal domain achieves its antimicrobial activity in a novel fashion and explain that big defensin has developed a strategy different from those of other beta-defensins to suppress the growth of Gram-positive bacteria.

Differential scanning calorimetry of a metalloprotein under controlled metal-ion activity.

In order to investigate the thermodynamics of the unfolding of metalloproteins, the thermal denaturation of bovine alpha-lactalbumin (BLA), a typical calcium-binding protein, was investigated under a wide variety of calcium ion activities by means of differential scanning calorimetry. The excess heat capacity obtained as above is composed of those of the following three reactions: (i) the release of a calcium ion from holo-BLA; (ii) the capture of the released calcium ion by the chelating reagent; and (iii) the denaturation of native apo-BLA. The results indicated that the presence of the chelating reagent had a remarkable effect on the apparent enthalpy change for the denaturation of holo-BLA. On the other hand, the influence of the chelator on the heat capacity change was shown to be negligible. Because the denaturation reaction of holo-BLA includes Reactions (i) and (iii), it had to be handled as a three-state reaction. Such an investigation of the unfolding has been scarcely found that the activity of the metal ion is controlled precisely in wide range.

Effect of ethanol on folding of hen egg-white lysozyme under acidic condition.

The equilibrium and kinetics of folding of hen egg-white lysozyme were studied by means of CD spectroscopy in the presence of varying concentrations of ethanol under acidic condition. The equilibrium transition curves of guanidine hydrochloride-induced unfolding in 13 and 26% (v/v) ethanol have shown that the unfolding significantly deviates from a two-state mechanism. The kinetics of denaturant-induced refolding and unfolding of hen egg-white lysozyme were investigated by stopped-flow CD at three ethanol concentrations: 0, 13, and 26% (v/v). Immediately after dilution of the denaturant, the refolding curves showed a biphasic time course in the far-UV region, with a burst phase with a significant secondary structure and a slower observable phase. However, when monitored by the near-UV CD, the burst phase was not observed and all refolding kinetics were monophasic. To clarify the effect of nonnative secondary structure induced by the addition of ethanol on the folding/unfolding kinetics, the kinetic m values were estimated from the chevron plots obtained for the three ethanol concentrations. The data indicated that the folding/unfolding kinetics of hen lysozyme in the presence of varying concentrations of ethanol under acidic condition is explained by a model with both on-pathway and off-pathway intermediates of protein folding.

Effects of the stabilization of the molten globule state on the folding mechanism of alpha-lactalbumin: a study of a chimera of bovine and human alpha-lactalbumin.

The N-terminal half of the alpha-domain (residues 1 to 34) is more important for the stability of the acid-induced molten globule state of alpha-lactalbumin than the C-terminal half (residues 86 to 123). The refolding and unfolding kinetics of a chimera, in which the amino acid sequence of residues 1 to 34 was from human alpha-lactalbumin and the remainder of the sequence from bovine alpha-lactalbumin, were studied by stopped-flow tryptophan fluorescence spectroscopy. The chimeric protein refolded and unfolded substantially faster than bovine alpha-lactalbumin. The stability of the molten globule state formed by the chimera was greater than that of bovine alpha-lactalbumin, and the hydrophobic surface area buried inside of the molecule in the molten globule state was increased by the substitution of residues 1 to 34. Peptide fragments corresponding to the A- and B-helix of the chimera showed higher helix propensity than those of the bovine protein, indicating the contribution of local interactions to the high stability of the molten globule state of the chimera. Moreover, the substitution of residues 1-34 decreased the free energy level of the transition state and increased hydrophobic surface area buried inside of the molecule in the transition state. Our results indicate that local interactions as well as hydrophobic interactions formed in the molten globule state are important in guiding the subsequent structural formation of alpha-lactalbumin.

Characterization of kinetic folding intermediates of recombinant canine milk lysozyme by stopped-flow circular dichroism.

The intermediate in the equilibrium unfolding of canine milk lysozyme induced by a denaturant is known to be very stable with characteristics of the molten globule state. Furthermore, there are at least two kinetic intermediates during refolding of this protein: a burst-phase (first) intermediate formed within the dead time of stopped-flow measurements and a second intermediate that accumulates with a rate constant of 22 s(-)(1). To clarify the relationships of these intermediates with the equilibrium intermediate, and also to characterize the structural changes of the protein during refolding, here we studied the kinetic refolding reactions using stopped-flow circular dichroism at 10 different wavelengths and obtained the circular dichroism spectra of the intermediates. Comparison of the circular dichroism spectra of the intermediates, as well as the absence of observed kinetics in the refolding from the fully unfolded state to the equilibrium intermediate, has demonstrated that the burst-phase intermediate is equivalent to the equilibrium intermediate. The difference circular dichroism spectrum that represented changes from the kinetic intermediate to the native state had characteristics of an exciton coupling band, indicating that specific packing of tryptophan residues in this protein occurred in this phase. From these findings, we propose a schematic model of the refolding of canine milk lysozyme that is consistent with the hierarchical mechanism of protein folding.

Role of putative anion-binding sites in cytoplasmic and extracellular channels of Natronomonas pharaonis halorhodopsin.

Natronomonas (Natronobacterium) pharaonis halorhodopsin (NpHR) is an inward light-driven Cl(-) ion pump. For efficient Cl(-) transport, the existence of Cl(-)-binding or -interacting sites in both extracellular (EC) and cytoplasmic (CP) channels is postulated. Candidates include Arg123 and Thr126 in EC channels and Lys215 and Thr218 in CP channels. The roles played by these amino acid residues in anion binding and in the photocycle have been investigated by mutation of the amino acid residues at these positions. Anion binding was assayed by changes in circular dichroism and the shift in the absorption maximum upon addition of Cl(-) to anion-free NpHR. The binding affinity was affected in mutants in which certain EC residues had been replaced; this finding revealed the importance of Arg123. On the other hand, mutants in which certain residues in the CP channel were replaced (CP mutants) did not show changes in their dissociation constants. The photocycles of these mutants were also examined, and in the case of the EC mutants, the transition to the last step was greatly delayed; on the other hand, in the CP mutants, L2-photointermediate decay was significantly prolonged, except in the case of K215Q, which lacked the O-photointermediate. The importance of Thr218 for binding of Cl(-) to the CP channel was indicated by these results. On the basis of these observations, the possible anion transport mechanism of NpHR was discussed.

The binding of copper ions to glycine-rich proteins (GRPs) from Cicer arietinum.

Cicer arietinum GRP1 and GRP2 are rich in glycine interposed with histidine and tyrosine. In order to study whether or not these proteins bind Cu(2+), circular dichroism (CD) and nuclear magnetic resonance (NMR) were measured for three synthetic peptides corresponding to sections of the protein's sequences including 1, N(1)Y(2)G(3)H(4)G(5)G(6)G(7)N(8)Y(9)G(10)N(11), where all peptides were chemically blocked with an acetyl group at the N-terminus and an -NH(2) group at the C-terminus. The visible CD spectra for 1 showed a positive peak near 590 nm not at pH 6.0 but pH 7.4 in the presence of copper ions. The Cu(2+) binding induced a drastic change in the far-UV CD spectra, showing the occurrence of large conformation changes. In the 2D TOCSY NMR spectra at pH 7.4, the addition of small amounts of CuSO(4) caused a significant broadening of proton resonances of not only His4 but also Gly5, Asn8 and Asn11. CD titration experiment suggested that NYGHGGGNYGN including one repeat unit comprises the fundamental Cu(2+) binding unit.

Interaction of dopamine and acetylcholine with an amphiphilic resorcinarene receptor in aqueous micelle system.

The molecular recognition of neurotransmitters, dopamine and acetylcholine with an amphiphilic resorcinarene receptor was investigated in an aqueous sodium dodecylsulfate (SDS) micelle system by 1H NMR measurements. The interaction distances of these neurotransmitters from the hydrophilic cavity of the amphiphilic receptor were estimated based on the calculation of the ring current shift using the atomic coordinates obtained from molecular dynamics calculation.

Effect of hydrostatic pressure on conformational changes of canine milk lysozyme between the native, molten globule, and unfolded states.

The effect of pressure on the unfolding of the native (N) and molten globule (MG) state of canine milk lysozyme (CML) was examined using ultraviolet (UV) spectroscopy at pH 4.5 and 2.0, respectively. It appeared that the thermally induced unfolding was promoted by the increase of pressure from atmospheric to 100 MPa, which indicates that both the N and MG states of CML unfolded with the decrease of the partial molar volume change (DeltaV). The volume changes needed for unfolding were estimated from the free energy change vs. pressure plots, and these volume changes became less negative from 20 to 60 degrees C. The DeltaV values at 25 degrees C were obtained for the N-MG (-46 cm3/mol) and MG-unfolded-state (U) transition (-40 cm3/mol). With regards to the MG-U transition, this value is contrastive to that of bovine alpha-lactalbumin (BLA) (0.9 cm3/mol), which is homologous to CML. Previous studies revealed that the MG state of CML was significantly more stable, and closer to the N state in structure, than that of BLA. In contrast to the swollen hydrophobic core of the MG state of BLA, our results suggest that the MG state of CML possesses a tightly packed hydrophobic core into which water molecules cannot penetrate.

The Gly-Gly linker region of the insect cytokine growth-blocking peptide is essential for activity.

Growth-blocking peptide (GBP) is a 25-amino acid cytokine isolated from the lepidopteran insect Pseudaletia separata. GBP exhibits various biological activities such as regulation of larval growth of insects, proliferation of a few kinds of cultured cells, and stimulation of a class of insect immune cells called plasmatocytes. The tertiary structure of GBP consists of a well structured core domain and disordered N and C termini. Our previous studies revealed that, in addition to the structured core, specific residues in the unstructured N-terminal region (Glu1 and Phe3) are also essential for the plasmatocyte-stimulating activity. In this study, a number of deletion, insertion, and site-directed mutants targeting the unstructured N-terminal residues of GBP were constructed to gain more detailed insight into the mode of interaction between the N-terminal region and GBP receptor. Alteration of the backbone length of the linker region between the core structure and N-terminal domain reduced plasmatocyte-stimulating activity. The substitutions of Gly5 or Gly6 in this linker region with more bulky residues, such as Phe and Pro, also remarkably reduced this activity. We conclude that the interaction of GBP with its receptor depends on the relative position of the N-terminal domain to the core structure, and therefore the backbone flexibility of Gly residues in the linker region is necessary for adoption of a proper conformation suited to receptor binding. Additionally, antagonistic experiments using deletion mutants confirmed that not only the core domain but also the N-terminal region of GBP are required for "receptor-binding," and furthermore Phe3 is a binding determinant of the N-terminal domain.

A non-native alpha-helix is formed in the beta-sheet region of the molten globule state of canine milk lysozyme.

The native and the molten globule states (N and MG states, respectively) of canine milk lysozyme (CML) were examined by CD spectroscopy and AGADIR algorithm, a helix-coil transition program. It revealed that the helical content of the MG state was higher than that of the N-state, suggesting that non-native alpha-helix is formed in the MG state of CML. Using AGADIR, it indicated the possibility of alpha-helix formation in the third beta-strand region in the MG state. To investigate this possibility, we designed a mutant, Q58P, in which the helical propensity of the MG state was significantly decreased around the third beta-strand region. It appeared that the absolute ellipticity value at 222 nm of the mutant in the MG state was smaller than that of the wild-type protein. It could be assumed that the non-native alpha-helix is formed around the third beta-strand region of wild-type CML in the MG state.

Volumetric behavior of the molten globule state of canine milk lysozyme.

The effect of pressure on the unfolding of the molten globule (MG) state of canine milk lysozyme (CML) was examined using ultraviolet spectroscopy. The volume changes of the MG-unfolded-state transition were observed at pH 2.0 and around 20 to 60 degrees C, but no volume change has been found for bovine alpha-lactalbumin, which is homologous to CML. Our results suggest that the MG state of CML possesses a tightly packed hydrophobic core.

Side chain-side chain interactions of arginine with tyrosine and aspartic acid in Arg/Gly/Tyr-rich domains within plant glycine-rich RNA binding proteins.

Plant glycine-rich RNA-binding proteins (GRRBPs) contain a glycine-rich region at the C-terminus whose structure is quite unknown. The C-terminal glycine-rich part is interposed with arginine and tyrosine (arginine/glycine/tyrosine (RGY)-rich domain). Comparative sequence analysis of forty-one GRRBPs revealed that the RGY-rich domain contains multiple repeats of Tyr-(Xaa)h-(Arg)k-(Xaa)l, where Xaa is mainly Gly, "k" is 1 or 2, and "h" and "l" range from 0 to 10. Two peptides, 1 (G1G2Y3G4G5G6R7R8D9G10) and 2 (G1G2R3R4D5G6G7Y8G9G10), corresponding to sections of the RGY-rich domain in Zea mays RAB15, were selected for CD and NMR experiments. The CD spectra indicate a unique, positive band near 228 nm in both peptides that has been ascribed to tyrosine residues in ordered structures. The pH titration by NMR revealed that a side chain-side chain interaction, presumably an H-Nepsilon...O=Cgamma hydrogen bonding interaction in the salt bridge, occurs between Arg (i) and Asp (i + 2). 1D GOESY experiments indicated the presence of NOE between the aromatic side chain proton and the arginine side chain proton in the two peptides suggesting strongly that the Arg (i) aromatic side chain interacts directly with the Tyr (i +/- 4 or i +/- 5) side chain.

Characterization of chimeric isocitrate dehydrogenases of a mesophilic nitrogen-fixing bacterium, Azotobacter vinelandii, and a psychrophilic bacterium, Colwellia maris.

Several properties of chimeric enzymes between a mesophilic isocitrate dehydrogenase (IDH) from a nitrogen-fixing bacterium, Azotobacter vinelandii, and a cold-adapted IDH isozyme (IDH-II) from a psychrophilic bacterium, Colwellia maris, were examined. Each of the genes encoding the IDHs was divided into four regions of almost equal lengths, and each region was ligated with different combinations to construct various chimeric genes. The resultant wild-type and chimeric genes were overexpressed in Escherichia coli. The wild-type and chimeric IDHs were classified into three groups based on optimum temperatures for activity of 20 degrees, 30 degrees, and 40 degrees C. The IDHs with a lower optimum temperature were more thermolabile. The optimum temperature and thermostability of the chimeric enzymes decreased on increasing the proportion derived from the cold-adapted IDH-II of C. maris. Furthermore, the C-terminal region of the C. maris IDH-II was suggested to be responsible for its psychrophilic characteristics.

Thermodynamic analysis of the activation mechanism of the GCSF receptor induced by ligand binding.

The granulocyte colony-stimulating factor receptor (GCSFR), containing the Ig-like domain (Ig) and cytokine receptor homologous region (CRH), was prepared as a preformed dimer (Ig-CRH-Fc)(2) after fusion to the mouse Fc region via an eight-residue linker (approximately 55 A). Monomer Ig-CRH was also prepared after the Fc region was removed from (Ig-CRH-Fc)(2). GCSF binding to Ig-CRH and (Ig-CRH-Fc)(2) was investigated using light scattering and isothermal titration calorimetry. The average molecular mass determined by light scattering showed that both Ig-CRH and (Ig-CRH-Fc)(2) formed a 2:2 dimer with GCSF. Moreover, isothermal titration calorimetry showed that the thermodynamic parameters upon binding of GCSF to Ig-CRH and (Ig-CRH-Fc)(2) were comparable, suggesting a similar binding stoichiometry and interface [including similar buried surface area (5700-6000 A(2))] despite the presence of the eight-residue linker. The buried surface area is much larger than that calculated from our previous report of the crystal structure of the GCSF-CRH complex [Aritomi, M., et al. (1999) Nature 401, 713-717], suggesting a substantial contribution of the Ig domain to GCSF binding. The data also indicate that the distance (55 A) between two CRH domains in the 2:2 complex is much shorter than in our previous model (approximately 90 A) predicted from the same crystal structure of the GCSF-CRH complex.

Copper binding to plant ozone-inducible proteins (OI2-2 and OI14-3).

Ozone-inducible proteins (OI2-2 and OI14-3) from Atriplex canescens whose structure and function are unknown are rich in glycine intercepted with histidine and tyrosine with putative signal peptides at the N-terminus. OI2-2 and OI14-3 contain 8 and 10 tandem repeats of YGHGGG, respectively. In order to study whether these proteins bind Cu(2+), circular dichroism (CD), and nuclear magnetic resonance (NMR) were measured for four synthetic peptides corresponding to sections of the sequences of these proteins; 1 (HGGGY), 2 (HGGGYGH), 3 (YGHGGGY), and 4 (YGHGGGYGHGGGY), where all peptides were chemically blocked with an acetyl group at the N-terminus and an -NH(2) group at the C-terminus. Visible CD spectra of the four peptides show positive peaks near 580 and 340nm, which were observed at pH 7.4 but not pH 6.0, indicating clearly that the four peptides bind Cu(2+). The NMR spectra indicate that the addition of small amounts of CuSO(4) to 3 (Y1-G2-H3-G4-G5-G6-Y7) causes significant broadening of resonances of the side chain protons (C(beta)H, C(epsilon1)H, and C(delta2)H) of His3 and the side chain C(beta)H of Tyr1 at pH 7.4. In addition, the backbone C(alpha)H resonances of Gly2 and Gly4 were broadened more strongly than those of Gly5 and Gly6. CD titration experiment suggested that two repeats of YGHGGG comprise the fundamental Cu(2+) binding unit. Thus, the ozone-inducible proteins are capable of binding at least four or five copper ions per protein. These copper-binding proteins would function as active oxygen scavengers.

Roles of Ser130 and Thr126 in chloride binding and photocycle of pharaonis halorhodopsin.

Pharaonis halorhodopsin (phR) is an inward light-driven chloride ion pump in Natronobacterium pharaonis. In order to clarify the roles of the Ser130(phR) and Thr126(phR) residues, which correspond to Ser115(shR) and Thr111(shR) of salinarum hR (shR), with regard to their Cl(-)binding affinity and the photocycle, the wild-type phR, and S130 and T126 mutants were expressed in Escherichia coli cells. The photocycles of the wild-type phR, and S130 and T126 mutants were investigated in the presence of 1 M NaCl. Based on results of kinetic analysis involving singular value decomposition and global fitting, typical photointermediates K, L and O were identified, and the kinetic constants of decay or formation varied depending on the mutant. The photocycle scheme was linear for the wild-type phR, and S130C, S130T and T126V mutants. On the other hand, the S130A mutant showed a branched pathway between the L-hR and L-O steps. The present study revealed the following two facts with respect to the Ser130(phR) residue: 1) The OH group of this residue is important for Cl(-) ion binding next to the Schiff base nitrogen, and 2) replacement of an Ala residue, which is unable to form a hydrogen bond, results in a branched photocycle. The implication of this branching was discussed.

Ser-130 of Natronobacterium pharaonis halorhodopsin is important for the chloride binding.

Pharaonis halorhodopsin (phR) is an inward light-driven chloride ion pump from Natronobacterium pharaonis. In order to clarify the role of Ser-130(phR) residue which corresponds to Ser-115(shR) for salinarum hR on the anion-binding affinity, the wild-type and Ser-130 mutants substituted with Thr, Cys and Ala were expressed in E. coli cells and solubilized with 0.1% n-dodecyl beta-D-maltopyranoside The absorption maximum (lambda(max)) of the S130T mutant indicated a blue shift from that of the wild type in the absence and presence of chloride. For S130A, a large red shift (12 nm) in the absence of chloride was observed. The wild-type and all mutants showed the blue-shift of lambda(max) upon Cl(-) addition, from which the dissociation constants of Cl(-) were determined. The dissociation constants were 5, 89, 153 and 159 mM for the wild-type, S130A, S130T and S130C, respectively, at pH 7.0 and 25 degrees C. Circular dichroic spectra of the wild-type and the Ser-130 mutants exhibited an oligomerization. The present study revealed that the Ser-130 of N. pharaonis halorhodopsin is important for the chloride binding.

Low-temperature-induced structural changes in human lysozyme elucidated by three-dimensional NMR spectroscopy.

The three-dimensional solution structures of human lysozyme were determined at 35 and 4 degrees C using the heteronuclear multidimensional NMR spectroscopy, which were compared with each other to clarify the structural response of this enzyme to lowering of the temperature. Together with the data of the temperature dependence experiments of the lytic activity against Micrococcus luteus, we consider the implication of the observed structural change for the low-temperature-induced reduction of the activity of human lysozyme. The structures of human lysozyme determined at the two temperatures are found to be similar, both of which comprise four alpha-helices (A- to D-helices) and three antiparallel beta-strands (beta(1)-beta(3)), leading to the constructions of the alpha- and beta-domains as previously identified in the X-ray crystal structure. A significant structural change was observed for the "active site lobe" comprising the loop region connecting C- and D-helices and the following D-helix, which moves toward the active site cleft located between the alpha- and beta-domains so as to obstruct the cleft according to the temperature lowering. It further appeared that the total volume as well as the accessible surface area of human lysozyme decreases with lowering of the temperature, suggesting that the internal cavity of this enzyme shrinks under low temperature environment. Because in human lysozyme the region comprising the active site lobe is responsible for turnover of the enzymatic reaction against the substrate, the low-temperature-induced structural change of the active site lobe presumably controls the efficiency of the lytic activity under low temperatures.

Roles of aromatic residues in the structure and biological activity of the small cytokine, growth-blocking peptide (GBP).

Growth-blocking peptide (GBP) is a small (25 amino acids) insect cytokine with a variety of functions: controlling the larval development of lepidopteran insects, acting as a mitogen for various types of cultured cells, and stimulating insect blood cells. The aromatic residues of GBP (Phe-3, Tyr-11, and Phe-23) are highly conserved in the ENF peptide family found in lepidopteran insects. We investigated the relationship between the biological activities and structural properties of a series of GBP mutants, in which each of the three aromatic residues is replaced by a different residue. The results of the hemocytes-stimulating assays of GBP mutants indicated that Phe-3 is the key residue in this activity: Ala or Tyr replacement resulted in significant loss of the activity, but Leu replacement did not. The replacements of other aromatic residues hardly affected the activity. On the other hand, NMR analysis of the mutants suggested that Tyr-11 is a key residue for maintaining the core structure of GBP. Surprisingly, the Y11A mutant maintained its biological activity, although its native-like secondary structure was disordered. Detailed analyses of the (15)N-labeled Y11A mutant by heteronuclear NMR spectroscopy showed that the native-like beta-sheet structure of Y11A was induced by the addition of 2,2,2-trifluoroethanol. The results suggest that Y11A has a tendency to form a native-like structure, and this property may give the Y11A mutant native-like activity.