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231.
Chul Kim Seung Bin Baek Do Hun Kim Sung Chul Lim Hyeong Ju Lee Hee Cheon Lee 《Journal of peptide science》2009,15(5):353-358
The temperature dependence of the partition of a neuropeptide, substance P (SP), in isotropic (q = 0.5) bicelles was investigated by using pulsed field gradient NMR diffusion technique. The partition coefficient decreases as the temperature is increased from 295 to 325 K, indicating a favorable (negative) enthalpy change upon partitioning of the peptide. Thermodynamic analysis of the data shows that the partitioning of SP at 300 K is driven by the enthalpic term (ΔH) with the value of ? 4.03 kcal mol?1, while it is opposed by the entropic term (?TΔS) by approximately 1.28 kcal mol?1 with a small negative change in heat capacity (ΔCp). The enthalpy‐driven process for the partition of SP in bicelles is the same as in dodecylphosphocholine (DPC) micelles, however, the negative entropy change in bicelles of flat bilayer surface is in sharp contrast with the positive entropy change in DPC micelles of highly curved surface, indicating that the curvature of the membrane surface might play a significant role in the partitioning of peptides. Copyright © 2009 European Peptide Society and John Wiley & Sons, Ltd. 相似文献
232.
Woon Ki Baek Hyun Sung Lee Man Hwan Oh Myung Jin Koh Kun-Soo Kim Sang Ho Choi 《Journal of microbiology (Seoul, Korea)》2009,47(5):624-632
Pathogens have evolved sophisticated mechanisms to survive oxidative stresses imposed by host defense systems, and the mechanisms
are closely linked to their virulence. In the present study, ahpCl, a homologue of Escherichia coli ahpC encoding a peroxiredoxin, was identified among the Vibrio vulnificus genes specifically induced by exposure to H2O2. In order to analyze the role of AhpCl in the pathogenesis of V. vulnificus, a mutant, in which the ahpCl gene was disrupted, was constructed by allelic exchanges. The ahpCl mutant was hypersusceptable to killing by reactive oxygen species (ROS) such as H2O2 and t-BOOH, which is one of the most commonly used hydroperoxides in vitro. The purified AhpCl reduced H2O2 in the presence of AhpF and NADH as a hydrogen donor, indicating that V. vulnificus AhpCl is a NADH-dependent peroxiredoxin and constitutes a peroxide reductase system with AhpF. Compared to wild type, the
ahpCl mutant exhibited less cytotoxicity toward INT-407 epithelial cells in vitro and reduced virulence in a mouse model. In addition, the ahpCl mutant was significantly diminished in growth with INT-407 epithelial cells, reflecting that the ability of the mutant to
grow, survive, and persist during infection is also impaired. Consequently, the combined results suggest that AhpCl and the
capability of resistance to oxidative stresses contribute to the virulence of V. vulnificus by assuring growth and survival during infection. 相似文献
233.
Betulinic and oleanolic acids isolated from Forsythia suspensa
Vahl inhibit urease activity of Helicobacter pylori 总被引:1,自引:0,他引:1
Seung-Jung Shin Chan-El Park Nam-In Baek In Sik Chung Chang-Ho Park 《Biotechnology and Bioprocess Engineering》2009,14(2):140-145
Sixteen medicinal herbs were selected from a database on traditional herbal materials as well as literature on Korean plant
resources. Then ethanol (70%, v/v) extracts of these herbs were tested for inhibition of the urease activity of Helicobacter pylori. The urease activity of H. pylori was strongly (82%) inhibited by extract of Forsythia suspensa
Vahl. Active compounds in extract of Forsythia suspensa
Vahl were first separated by batch mode solvent extraction, followed by purification by silica gel and octadecyl silica gel column
chromatography using solvents of different polarity. According to NMR analysis of the last chromatographic fraction, we identified
the presence of betulinic acid and oleanolic acid, which are known to have anti-inflammatory, anti-cancer, and anti-HIV viral
activities. 相似文献
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238.
Philippe Noriel Q. Pascua Min-Suk Song Jun Han Lee Kuk Jin Park Hyeok-il Kwon Yun Hee Baek Seung-Pyo Hong Jong-Bok Rho Chul-Joong Kim Haryoung Poo Thomas S. Ryoo Moon-Hee Sung Young Ki Choi 《PloS one》2009,4(12)
The current pandemic (H1N1) 2009 virus remains transmissible among humans worldwide with cases of reverse zoonosis, providing opportunities to produce more pathogenic variants which could pose greater human health concerns. To investigate whether recent seasonal human or swine H1N1 vaccines could induce cross-reactive immune responses against infection with the pandemic (H1N1) 2009 virus, mice, ferrets or mini-pigs were administered with various regimens (once or twice) and antigen content (1.77, 3.5 or 7.5 µg HA) of a-Brsibane/59/07, a-CAN01/04 or RgCA/04/09xPR8 vaccine. Receipt of a-CAN01/04 (2-doses) but not a-Brisbane/59/07 induced detectable but modest (20–40 units) cross-reactive serum antibody against CA/04/09 by hemagglutinin inhibition (HI) assays in mice. Only double administration (7.5 µg HA) of both vaccine in ferrets could elicit cross-reactivity (30–60 HI titers). Similar antigen content of a-CAN01/04 in mini-pigs also caused a modest ∼30 HI titers (twice vaccinated). However, vaccine-induced antibody titers could not suppress active virus replication in the lungs (mice) or virus shedding (ferrets and pigs) of immunized hosts intranasally challenged with CA/04/09. Furthermore, neither ferrets nor swine could abrogate aerosol transmission of the virus into naïve contact animals. Altogether, these results suggest that neither recent human nor animal H1N1 vaccine could provide complete protectivity in all animal models. Thus, this study warrants the need for strain-specific vaccines that could yield the optimal protection desired for humans and/or animals. 相似文献
239.
Je-Hyun Baek Won Suk Yang Cheolju Lee Myeong-Hee Yu 《Molecular & cellular proteomics : MCP》2009,8(5):1072-1081
The native state of α1-antitrypsin (α1AT), a member of the serine protease inhibitor (serpin) family, is considered a kinetically trapped folding intermediate that converts to a more stable form upon complex formation with a target protease. Although previous structural and mutational studies of α1AT revealed the structural basis of the native strain and the kinetic trap, the mechanism of how the native molecule overcomes the kinetic barrier to reach the final stable conformation during complex formation remains unknown. We hypothesized that during complex formation, a substantial portion of the molecule undergoes unfolding, which we dubbed functional unfolding. Hydrogen-deuterium exchange coupled with ESI-MS was used to analyze this serpin in three forms: native, complexing, and complexed with bovine β-trypsin. Comparing the deuterium content at the corresponding regions of these three samples, we probed the unfolding of α1AT during complex formation. A substantial portion of the α1AT molecule unfolded transiently during complex formation, including not only the regions expected from previous structural studies, such as the reactive site loop, helix F, and the following loop, but also regions not predicted previously, such as helix A, strand 6 of β-sheet B, and the N terminus. Such unfolding of the native interactions may elevate the free energy level of the kinetically trapped native serpin sufficiently to cross the transition state during complex formation. In the current study, we provide evidence that protein unfolding has to accompany functional execution of the protein molecule.The native strain of serine protease inhibitors (serpins)1 is considered to be crucial to their biological functions, such as plasma protease inhibition (1, 2) and hormone delivery (3). Functional execution of serpins is accompanied by the conversion of the strained native structure into a more stable conformation (4). Because some of the strained native serpin structures are spontaneously converted into a more relaxed stable latent form under physiological conditions (5–7), the native structure is not the thermodynamically most stable conformation but is a kinetically trapped conformation. Upon binding a target protease, the scissile bond of the reactive site loop (RSL) is cleaved while the protease is covalently attached to the N-terminal part of the RSL (8, 9). During the conversion of the strained structure into the stable complex conformation (Fig. 1), RSL is inserted into the central β-sheet (A sheet) between strands 3 and 5 (s3A and s5A) to form strand 4 (s4A), and the covalently attached protease is concomitantly translocated to the opposite pole (10). Serpin inhibition occurs via a suicide substrate mechanism (4, 11, 12) in which serpins, upon binding proteases, partition between cleaved serpins and stable serpin-enzyme complexes.Open in a separate windowFig. 1.Structures of native α1AT and α1AT-trypsin complex. Left, structure of native α1AT (Protein Data Bank code 1QLP) illustrated with secondary structural elements (1). Right, structure of α1AT-trypsin complex (Protein Data Bank code 1EZX). The nine α-helices are colored dark gray, and the 16 β-strands are colored light gray.As a member of the serpin family, α1-antitrypsin (α1AT), which serves to modulate the activity of human leukocyte elastase in the lung, has been most extensively studied with regard to both structure and inhibition mechanism. Our previous studies with stabilizing mutations of α1AT showed that the native strain is distributed throughout the molecule and that various unfavorable structural motifs, such as hydrophobic packing, cavity in the core, and surface hydrophobic patch, appear to maintain the native strain (13, 14). Indeed stabilizing mutations localized in the region of RSL insertion during complex formation affected the inhibitory function individually by retarding the loop insertion (15). Mutations in other regions did not affect the inhibitory function individually, but collectively these mutations affected the inhibitory function when the stabilization effect reached a certain threshold (16). Maintaining the kinetic trap appears to require sustaining RSL at the hydrophobic β-barrel composed of sheet B and sheet C (B/C β-barrel) because the conversion into the stable latent conformation occurs by destabilization of the B/C β-barrel (6) as well as by the extension of RSL length (17). Thus, upon binding a target protease, RSL cleavage appears to induce a conformational conversion, and the resultant strain throughout the molecule facilitates the opening of β-sheet A and the insertion of the RSL, which is critical for the inhibitory pathway as opposed to the substrate pathway (10).Although these structural and mutational studies revealed the structural basis for maintaining the kinetic trap and its relation to the inhibitory mechanism, several questions still remain. For example, what structural changes does the native serpin molecule undergo to overcome the kinetic barrier and reach the final stable conformation during the complex formation? In the present study, to probe the structural process of overcoming the kinetic barrier during complex formation with a target protease, amide hydrogen exchange (hydrogen-deuterium exchange (H/D-EX)) was explored during the conversion of the native α1AT to the stable complex. H/D-EX coupled with ESI-MS is a powerful analytical tool for observing protein dynamics, transient conformational changes, and protein-protein interactions (18–22). These experiments demonstrated that transient structural unfolding occurred in many regions in the α1AT molecule during formation of the complex with β-trypsin, and some of this unfolding was unpredicted from previous structural studies. 相似文献
240.