Photoinduced Generation of the π-Conjugated Zwitterionic State in the ESIPT Fluorophore of 2,4-Bisimidazolylphenol.

We demonstrate that 2,4-bis(4,5-diphenyl-1H-imidazol-2-yl)phenol (2,4-bImP) undergoes photoinduced conversion into the so-called "π-conjugated zwitterion" after causing an excited-state intramolecular proton transfer (ESIPT) reaction. The powder sample of 2,4-bImP exhibits largely Stokes-shifted fluorescence characteristics to ESIPT fluorophores. On the other hand, its originally colorless solutions become colored when exposed to UV light for several minutes, whose color depends on the type of solvent. In particular, the CHCl3 solution rapidly turns dark green with the absorption maximum around 700 nm, and the colored solution is nearly restored to original by alternating addition of acid and base. To explain such drastic and reversible color changes, we hypothesized that the occurrence of ESIPT (i.e., deprotonation of the phenol and protonation of the imidazolyl group at its 2-position) triggered the charge-separated structure between the negatively charged phenolate and the positively charged imidazoliumyl group at its 4-position, which allowed resonance with the neutral p-quinoid structure. The formation of this π-conjugated zwitterion was strongly supported by the results of 1H and 15N NMR and Raman measurements.

Color Changes of a Full-Color Emissive ESIPT Fluorophore in Response to Recognition of Certain Acids and Their Conjugate Base Anions.

2-(1,3-Benzothiazol-2-yl)-4-methoxy-6-(1,4,5-triphenyl-1H-imidazol-2-yl)phenol (BTImP) is an excited-state intramolecular proton transfer (ESIPT) fluorophore, containing an acid-stimuli-responsive intramolecular hydrogen bond (H-bond) that can switch from the central phenolic proton to the imidazole (Im) or benzothiazole (BT) nitrogen atoms. Here, we demonstrate that BTImP shows full-color (red, green, blue, and white) emission upon the addition of different concentrations of HClO4 or, with time, after the addition of HBF4 . It also shows thermally dependent color changes from pink through white to blue in a narrow temperature range of 25-60 °C. 1 H and 15 N NMR measurements suggest that, after the green fluorescent BTImP is protonated at its Im nitrogen atom, a conjugate base anion coordinates to the imidazolium (HIm+ ) proton, forming two types of complexes with different coordination states. One state shows a significantly Stokes-shifted red emission resulting from ESIPT at the BT side, whereas the other shows a typical Stokes-shifted blue emission, probably caused by interaction of the anion with the phenolic proton, which breaks the H-bond on the BT side. BF4- and ClO4- are effective in forming such a blue emitter, whereas Cl- and PF6- are not; this behavior depends on whether the anion can fit into the bidentate binding site consisting of HIm+ and the phenolic hydroxy group.

Lipopolysaccharide-bound structure of the antimicrobial peptide cecropin P1 determined by nuclear magnetic resonance spectroscopy.

Antimicrobial peptides (AMPs) are components of the innate immune system and may be potential alternatives to conventional antibiotics because they exhibit broad-spectrum antimicrobial activity. The AMP cecropin P1 (CP1), isolated from nematodes found in the stomachs of pigs, is known to exhibit antimicrobial activity against Gram-negative bacteria. In this study, we investigated the interaction between CP1 and lipopolysaccharide (LPS), which is the main component of the outer membrane of Gram-negative bacteria, using circular dichroism (CD) and nuclear magnetic resonance (NMR). CD results showed that CP1 formed an α-helical structure in a solution containing LPS. For NMR experiments, we expressed (15) N-labeled and (13) C-labeled CP1 in bacterial cells and successfully assigned almost all backbone and side-chain proton resonance peaks of CP1 in water for transferred nuclear Overhauser effect (Tr-NOE) experiments in LPS. We performed (15) N-edited and (13) C-edited Tr-NOE spectroscopy for CP1 bound to LPS. Tr-NOE peaks were observed at the only C-terminal region of CP1 in LPS. The results of structure calculation indicated that the C-terminal region (Lys15-Gly29) formed the well-defined α-helical structure in LPS. Finally, the docking study revealed that Lys15/Lys16 interacted with phosphate at glucosamine I via an electrostatic interaction and that Ile22/Ile26 was in close proximity with the acyl chain of lipid A.

Interaction between tachyplesin I, an antimicrobial peptide derived from horseshoe crab, and lipopolysaccharide.

Lipopolysaccharide (LPS) is a major constituent of the outer membrane of Gram-negative bacteria and is the very first site of interactions with antimicrobial peptides (AMPs). In order to gain better insight into the interaction between LPS and AMPs, we determined the structure of tachyplesin I (TP I), an antimicrobial peptide derived from horseshoe crab, in its bound state with LPS and proposed the complex structure of TP I and LPS using a docking program. CD and NMR measurements revealed that binding to LPS slightly extends the two ß-strands of TP I and stabilizes the whole structure of TP I. The fluorescence wavelength of an intrinsic tryptophan of TP I and fluorescence quenching in the presence or absence of LPS indicated that a tryptophan residue is incorporated into the hydrophobic environment of LPS. Finally, we succeeded in proposing a structural model for the complex of TP I and LPS by using a docking program. The calculated model structure suggested that the cationic residues of TP I interact with phosphate groups and saccharides of LPS, whereas hydrophobic residues interact with the acyl chains of LPS.

Efficient production of a correctly folded mouse α-defensin, cryptdin-4, by refolding during inclusion body solubilization.

Mammalian α-defensins contribute to innate immunity by exerting antimicrobial activity against various pathogens. To perform structural and functional analysis of α-defensins, large amounts of α-defensins are essential. Although many expression systems for the production of recombinant α-defensins have been developed, attempts to obtain large amounts of α-defensins have been only moderately successful. Therefore, in this study, we applied a previously developed aggregation-prone protein coexpression method for the production of mouse α-defensin cryptdin-4 (Crp4) in order to enhance the formation of inclusion bodies in Escherichia coli expression system. By using this method, we succeeded in obtaining a large amount of Crp4 in the form of inclusion bodies. Moreover, we attempted to refold Crp4 directly during the inclusion-body solubilization step under oxidative conditions. Surprisingly, even without any purification, Crp4 was efficiently refolded during the solubilization step of inclusion bodies, and the yield was better than that of the conventional refolding method. NMR spectra of purified Crp4 suggested that it was folded into its correct tertiary structure. Therefore, the method described in this study not only enhances the expression of α-defensin as inclusion bodies, but also eliminates the cumbersome and time-consuming refolding step.

Molecular mechanisms of the cytotoxicity of human α-lactalbumin made lethal to tumor cells (HAMLET) and other protein-oleic acid complexes.

Although HAMLET (human α-lactalbumin made lethal to tumor cells), a complex formed by human α-lactalbumin and oleic acid, has a unique apoptotic activity for the selective killing of tumor cells, the molecular mechanisms of expression of the HAMLET activity are not well understood. Therefore, we studied the molecular properties of HAMLET and its goat counterpart, GAMLET (goat α-lactalbumin made lethal to tumor cells), by pulse field gradient NMR and 920-MHz two-dimensional NMR techniques. We also examined the expression of HAMLET-like activities of complexes between oleic acid and other proteins that form a stable molten globule state. We observed that both HAMLET and GAMLET at pH 7.5 were heterogeneous, composed of the native protein, the monomeric molten globule-like state, and the oligomeric species. At pH 2.0 and 50 °C, HAMLET and GAMLET appeared in the monomeric state, and we identified the oleic acid-binding site in the complexes by two-dimensional NMR. Rather surprisingly, the binding site thus identified was markedly different between HAMLET and GAMLET. Furthermore, canine milk lysozyme, apo-myoglobin, and ß2-microglobulin all formed the HAMLET-like complex with the anti-tumor activity, when the protein was treated with oleic acid under conditions in which their molten globule states were stable. From these results, we conclude that the protein portion of HAMLET, GAMLET, and the other HAMLET-like protein-oleic acid complexes is not the origin of their cytotoxicity to tumor cells and that the protein portion of these complexes plays a role in the delivery of cytotoxic oleic acid molecules into tumor cells across the cell membrane.

NMR basis for interprotein electron transfer gating between cytochrome c and cytochrome c oxidase.

The final interprotein electron transfer (ET) in the mammalian respiratory chain, from cytochrome c (Cyt c) to cytochrome c oxidase (CcO) is investigated by (1)H-(15)N heteronuclear single quantum coherence spectral analysis. The chemical shift perturbation in isotope-labeled Cyt c induced by addition of unlabeled CcO indicates that the hydrophobic heme periphery and adjacent hydrophobic amino acid residues of Cyt c dominantly contribute to the complex formation, whereas charged residues near the hydrophobic core refine the orientation of Cyt c to provide well controlled ET. Upon oxidation of Cyt c, the specific line broadening of N-H signals disappeared and high field (1)H chemical shifts of the N-terminal helix were observed, suggesting that the interactions of the N-terminal helix with CcO are reduced by steric constraint in oxidized Cyt c, while the chemical shift perturbations in the C-terminal helix indicate notable interactions of oxidized Cyt c with CcO. These results suggest that the overall affinity of oxidized Cyt c for CcO is significantly, but not very much weaker than that of reduced Cyt c. Thus, electron transfer is gated by dissociation of oxidized Cyt c from CcO, the rate of which is controlled by the affinity of oxidized Cyt c to CcO for providing an appropriate electron transfer rate for the most effective energy coupling. The conformational changes in Lys13 upon CcO binding to oxidized Cyt c, shown by (1)H- and (1)H, (15)N-chemical shifts, are also expected to gate intraprotein ET by a polarity control of heme c environment.

Role of Thr218 in the light-driven anion pump halorhodopsin from Natronomonas pharaonis.

Halorhodopsin (HR) is an inward-directed light-driven halogen ion pump, and NpHR is a HR from Natronomonas pharaonis. Unphotolyzed NpHR binds halogen ion in the vicinity of the Schiff base, which links retinal to Lys256. This halogen ion is transported during the photocycle. We made various mutants of Thr218, which is located one half-turn up from the Schiff base to the cytoplasm (CP) channel, and analyzed the photocycle using a sequential irreversible model. Four photochemically defined intermediates (P(i), i = 1-4) were adequate to describe the photocycle. The third component, P3, was a quasi-equilibrium complex between the N and O intermediates, where a N ↔ O + Cl⁻ equilibrium was attained. The K(d,N↔O) values of this equilibrium for various mutants were determined, and the value of Thr (wild type) was the highest. The partial molar volume differences between N and O, ΔV(N→O), were estimated from the pressure dependence of K(d,N↔O). A comparison between K(d,N↔O) and ΔV(N→O) led to the conclusion that water entry by the F-helix opening at O may occur, which may increase K(d,N↔O). For some mutants, however, large ΔV(N→O) values were found, whereas the K(d,N↔O) values were small. This suggests that the special coordination of a water molecule with the OH group of Thr is necessary for the increase in K(d,N↔O). Mutants with a small K(d,N↔O) showed low pumping activities in the presence of inside negative membrane potential, while the mutant activities were not different in the absence of membrane potential. The effect of the mutation on the pumping activities is discussed.

Structural and mutational analyses of decarboxylated osteocalcin provide insight into its adiponectin-inducing activity.

An acidic environment in bone is essential for bone metabolism and the production of decarboxylated osteocalcin, which functions as a regulatory hormone of glucose metabolism. Here, we describe the high-resolution X-ray crystal structure of decarboxylated osteocalcin under acidic conditions. Decarboxylated osteocalcin at pH 2.0 retains the α-helix structure of native osteocalcin with three γ-carboxyglutamic acid residues at neutral pH. This implies that decarboxylated osteocalcin is stable under an acidic environment in bone. In addition, site-directed mutagenesis revealed that Glu17 and Glu21 are important for the adiponectin-inducing activity of decarboxylated osteocalcin. These findings suggest that the receptor of decarboxylated osteocalcin responds to the negative charge in helix 1 of osteocalcin.

Homotrimer formation and dissociation of pharaonis halorhodopsin in detergent system.

Halorhodopsin from NpHR is a light-driven Cl(-) pump that forms a trimeric NpHR-bacterioruberin complex in the native membrane. In the case of NpHR expressed in Escherichia coli cell, NpHR forms a robust homotrimer in a detergent DDM solution. To identify the important residue for the homotrimer formation, we carried out mutation experiments on the aromatic amino acids expected to be located at the molecular interface. The results revealed that Phe(150) was essential to form and stabilize the NpHR trimer in the DDM solution. Further analyses for examining the structural significance of Phe(150) showed the dissociation of the trimer in F150A (dimer) and F150W (monomer) mutants. Only the F150Y mutant exhibited dissociation into monomers in an ionic strength-dependent manner. These results indicated that spatial positions and interactions between F150-aromatic side chains were crucial to homotrimer stabilization. This finding was supported by QM calculations. In a functional respect, differences in the reaction property in the ground and photoexcited states were revealed. The analysis of photointermediates revealed a decrease in the accumulation of O, which is important for Cl(-) release, and the acceleration of the decay rate in L1 and L2, which are involved in Cl(-) transfer inside the molecule, in the trimer-dissociated mutants. Interestingly, the affinity of them to Cl(-) in the photoexcited state increased rather than the trimer, whereas that in the ground state was almost the same without relation to the oligomeric state. It was also observed that the efficient recovery of the photocycle to the ground state was inhibited in the mutants. In addition, a branched pathway that was not included in Cl(-) transportation was predicted. These results suggest that the trimer assembly may contribute to the regulation of the dynamics in the excited state of NpHR.

Structural characterization of a trapped folding intermediate of pyrrolidone carboxyl peptidase from a hyperthermophile.

The refolding of cysteine-free pyrrolidone carboxyl peptidase (PCP-0SH) from a hyperthermophile is unusually slow. PCP-0SH is trapped in the denatured (D1) state at 4 °C and pH 2.3, which is different from the highly denatured state in the presence of concentrated denaturant. In order to elucidate the mechanism of the unusually slow folding, we investigated the structure of the D1 state using NMR techniques with amino acid selectively labeled PCP-0SH. The HSQC spectrum of the D1 state showed that most of the resonances arising from the 114-208 residues are broadened, indicating that conformations of the 114-208 residues are in intermediate exchange on the microsecond to millisecond time scale. Paramagnetic relaxation enhancement data indicated the lack of long-range interactions between the 1-113 and the 114-208 segments in the D1 state. Furthermore, proline scanning mutagenesis showed that the 114-208 segment in the D1 state forms a loosely packed hydrophobic core composed of α4- and α6-helices. From these findings, we conclude that the 114-208 segment of PCP-0SH folds into a stable compact structure with non-native helix-helix association in the D1 state. Therefore, in the folding process from the D1 state to the native state, the α4- and α6-helices become separated and the central ß-sheet is folded between these helices. That is, the non-native interaction between the α4- and α6-helices may be responsible for the unusually slow folding of PCP-0SH.

Expression of salinarum halorhodopsin in Escherichia coli cells: solubilization in the presence of retinal yields the natural state.

Salinarum halorhodopsin (HsHR), a light-driven chloride ion pump of haloarchaeon Halobacterium salinarum, was heterologously expressed in Escherichia coli. The expressed HsHR had no color in the E. coli membrane, but turned purple after solubilization in the presence of all-trans retinal. This colored HsHR was purified by Ni-chelate chromatography in a yield of 3-4 mg per liter culture. The purified HsHR showed a distinct chloride pumping activity by incorporation into the liposomes, and showed even in the detergent-solubilized state, its typical behaviors in both the unphotolyzed and photolyzed states. Upon solubilization, HsHR expressed in the E. coli membrane attains the proper folding and a trimeric assembly comparable to those in the native membranes.

Polyglutamine tract-binding protein-1 binds to U5-15kD via a continuous 23-residue segment of the C-terminal domain.

Polyglutamine tract-binding protein-1 (PQBP-1) is a nuclear protein that interacts with various proteins, including RNA polymerase II and the spliceosomal protein U5-15kD. PQBP-1 is known to be associated with X-linked mental retardation in which a frameshift mutation in the PQBP-1 gene occurs. In the present study, we demonstrate that PQBP-1 binds to U5-15kD via a continuous 23-residue segment within its C-terminal domain. Intriguingly, this segment is lost in the frameshift mutants of PQBP-1 associated with X-linked mental retardation. These findings suggest that the frameshift mutations in the PQBP-1 gene lead to expression of mutants lacking the ability to interact with U5-15kD.

STPR, a 23-amino acid tandem repeat domain, found in the human function-unknown protein ZNF821.

The STPR motif is composed of 23-amino acid repeats aligned contiguously. STPR was originally reported as the DNA-binding domain of the silkworm protein FMBP-1. ZNF821, the human protein that contains the STPR domain, is a zinc finger protein of unknown function. In this study, we prepared peptides of silkworm FMBP-1 STPR (sSTPR) and human ZNF821 STPR (hSTPR) and compared their DNA binding behaviors. This revealed that hSTPR, like sSTPR, is a double-stranded DNA-binding domain. Sequence-independent DNA binding affinities and α-helix-rich DNA-bound structures were comparable between the two STPRs, although the specific DNA sequence of hSTPR is still unclear. In addition, a subcellular expression experiment showed that the hSTPR domain is responsible for the nuclear localization of ZNF821. ZNF821 showed a much slower diffusion rate in the nucleus, suggesting the possibility of interaction with chromosomal DNA. STPR sequences are found in many proteins from vertebrates, insects, and nematodes. Some of the consensus amino acid residues would be responsible for DNA binding and concomitant increases in α-helix structure content.

C-terminal elongation of growth-blocking peptide enhances its biological activity and micelle binding affinity.

Growth-blocking peptide (GBP) is a hormone-like peptide that suppresses the growth of the host armyworm. Although the 23-amino acid GBP (1-23 GBP) is expressed in nonparasitized armyworm plasma, the parasitization by wasp produces the 28-amino acid GBP (1-28 GBP) through an elongation of the C-terminal amino acid sequence. In this study, we characterized the GBP variants, which consist of various lengths of the C-terminal region, by comparing their biological activities and three-dimensional structures. The results of an injection study indicate that 1-28 GBP most strongly suppresses larval growth. NMR analysis shows that these peptides have basically the same tertiary structures and that the extension of the C-terminal region is disordered. However, the C-terminal region of 1-28 GBP undergoes a conformational transition from a random coiled state to an alpha-helical state in the presence of dodecylphosphocholine micelles. This suggests that binding of the C-terminal region would affect larval growth activity.

Polyglutamine tract binding protein-1 is an intrinsically unstructured protein.

Polyglutamine tract binding protein-1 (PQBP-1) is a nuclear protein that interacts with disease proteins containing expanded polyglutamine repeats. PQBP-1 also interacts with RNA polymerase II and a spliceosomal protein U5-15kD. In the present study, we demonstrate that PQBP-1 is composed of a large unstructured region and a small folded core. Intriguingly, the large unstructured region encompasses two functional domains: a polar amino acid rich domain and a C-terminal domain. These findings suggest that PQBP-1 belongs to the family of intrinsically unstructured/disordered proteins. Furthermore, the binding of the target molecule U5-15kD induces only minor conformational changes into PQBP-1. Our results suggest that PQBP-1 includes high content of unstructured regions in the C-terminal domain, in spite of the binding of U5-15kD.

Redox-controlled backbone dynamics of human cytochrome c revealed by 15N NMR relaxation measurements.

Redox-controlled backbone dynamics in cytochrome c (Cyt c) were revealed by 2D 15N NMR relaxation experiments. 15N T1 and T2 values and 1H-15N NOEs of uniformly 15N-labeled reduced and oxidized Cyt c were measured, and the generalized order parameters (S2), the effective correlation time for internal motion (taue), the 15N exchange broadening contributions (Rex) for each residue, and the overall correlation time (taum) were estimated by model-free dynamics formalism. These dynamic parameters clearly showed that the backbone dynamics of Cyt c are highly restricted due to the covalently bound heme that functions as the stable hydrophobic core. Upon oxidation of the heme iron in Cyt c, the average S2 value was increased from 0.88+/-0.01 to 0.92+/-0.01, demonstrating that the mobility of the backbone is further restricted in the oxidized form. Such increases in the S2 values were more prominent in the loop regions, including amino acid residues near the thioether bonds to the heme moiety and positively charged region around Lys87. Both of the regions are supposed to form the interaction site for cytochrome c oxidase (CcO) and the electron pathway from Cyt c to CcO. The redox-dependent mobility of the backbone in the interaction site for the electron transfer to CcO suggests an electron transfer mechanism regulated by the backbone dynamics in the Cyt c-CcO system.

Structure-activity relationship of a novel pentapeptide with cancer cell growth-inhibitory activity.

We previously reported that yamamarin, a pentapeptide with an amidated C-terminus (DILRG-NH(2)) isolated from larvae of the silkmoth, and its palmitoylated analog (C16-DILRG-NH(2)) suppressed proliferation of rat hepatoma (liver cancer) cells. In this study, we investigated the structure-activity relationship of yamamarin by in vitro assay and spectroscopic methods (CD and NMR) for various analogs. The in vitro assay results demonstrated that the chemical structure of the C-terminal part (-RG-NH(2)) of yamamarin is essential for its activity. The CD and NMR results indicated that yamamarin and its analog adopt predominantly a random coil conformation. Moreover, a comparison of NMR spectra of DILRG-NH(2) and C16-DILRG-NH(2) revealed that the N-terminal palmitoyl group of C16-DILRG-NH(2) did not affect the conformation of the C-terminal part, which is essential for activity. Together, these results should assist in the design of more sophisticated anticancer drugs.

Effect of chloride binding on the thermal trimer-monomer conversion of halorhodopsin in the solubilized system.

Halorhodopsin from Natronomonas pharaonis (NpHR) acts an inward-directed, light-driven chloride pump and forms a homotrimer. To evaluate effect of trimeric assembly, that is, intermolecular interaction, on the control or modulation of light-driven chloride pumping activity of individual HRs, it is important to understand the thermal and chloride sensitivity of trimer dissociation and the structural stability of HR. In this study, the thermal dissociation of NpHR trimer to monomer in a dodecyl beta-d-maltoside-solubilized system was investigated, using size-exclusion chromatography and visible absorption. In the absence of Cl(-), NpHR retained the trimer assembly at 25 degrees C but dissociated to the monomer with an increase in temperature to >40 degrees C. On the other hand, in the presence of Cl(-), the trimer assembly was maintained at 40 degrees C. The dissociation of the trimer to the monomer after incubation at 40 degrees C, which was determined via size-exclusion chromatography, depended on the Cl(-) concentration and showed a sigmoidal isotherm. From this isotherm, the apparent dissociation constant for Cl(-) was estimated to be 22 mM with a Hill coefficient of 2.2. A similar isotherm was obtained when SO(4)(2-) was used instead of Cl(-) with a dissociation constant of 94 mM. On the other hand, thermal dissociation of the NpHR trimer to the monomer in the absence of Cl(-) proceeded by two components: the fast component is susceptible to the changes in temperature and detergent concentration, and the slow component is accompanied by bleaching at the same time. Activation energies of the fast and slow dissociation components and bleaching were 57.8, 35.3, and 40.5 kcal/mol, respectively. The presence of a second chloride-binding site with a Hill coefficient of approximately 2 at the surface of NpHR to control the trimer-monomer conversion was discussed.

A novel beta-defensin structure: big defensin changes its N-terminal structure to associate with the target membrane.

Big defensin is a 79-residue peptide derived from hemocytes of the Japanese horseshoe crab. The amino acid sequence of big defensin is divided into an N-terminal hydrophobic domain and a C-terminal cationic domain, which are responsible for antimicrobial activities against Gram-positive and -negative bacteria, respectively. The N-terminal domain of big defensin forms a unique globular conformation with two alpha-helices and a parallel beta-sheet, while the C-terminal domain adopts a beta-defensin-like fold. Although our previous study implied that big defensin changes its N-terminal structure in a micellar environment, due to the poor quality of the NMR spectra it remained to be resolved whether the N-terminal domain adopts any structure in the presence of micelles. In this analysis, we successfully determined the structure of the N-terminal fragment of big defensin in a micellar solution, showing that the fragment peptide forms a single alpha-helix structure. Moreover, NMR experiments using paramagnetic probes revealed that the N-terminal domain of big defensin penetrates into the micelle with a dipping at the N-terminal edge of the alpha-helix. Here, we propose a model for how big defensin associates with the target membrane.