Co-reporter:Weibing Dong, Zhe Dong, Xiaoman Mao, Yue Sun, Fei Li, Dejing Shang
Acta Biomaterialia 2016 Volume 37() pp:59-68
Publication Date(Web):June 2016
DOI:10.1016/j.actbio.2016.04.003
Abstract
Chensinin-1b shows a potent and broad-spectrum bactericidal activity and no hemolytic activity and thus is a potential therapeutic agent against bacterial infection. The NMR structure of chensinin-1b consists of a partially α-helical region (residues 8–14) in a membrane-mimic environment that is distinct from other common antimicrobial peptides. However, further analysis of the structural features of chensinin-1b is required to better understand its bactericidal activity. In this study, a series of N- and C-terminally truncated or amino acid-substituted chensinin-1b analogues were synthesized. Next, the bactericidal activity and bacterial membrane effects of the analogues were investigated. The results indicated that the N-terminal residues play a more significant role than the C-terminal residues in the antimicrobial activity of chensinin-1b. The removal of five amino acids from the C-terminus of chensinin-1b did not affect its biological properties, but helix disruption significantly decreased bactericidal activity. The substitution of positively charged residues increased the helicity and antimicrobial activity of the peptide. We also identified a novel analogue [R4,R10]C1b(3–13) that exhibited similar bactericidal properties with its parent peptide chensinin-1b. Electrostatic interactions between the selected analogues and lipopolysaccharides or cells were detected using isothermal titration calorimetry or zeta potential. The thermodynamic parameters ΔH and ΔS for [R4,R10]C1b(3–13) were −20.48 kcal mol−1 and −0.0408 kcal mol−1 deg−1, respectively. Chensinin-1b yielded similar results of −26.36 kcal mol−1 and −0.0559 kcal mol−1 deg−1 for ΔH and ΔS, respectively. These results are consistence with their antimicrobial activities. Lastly, membrane depolarization studies showed that selected analogues exerted bactericidal activity by damaging the cytoplasmic membrane.
Statement of Significance
Antimicrobial peptide chensinin-1b is a candidate for the development of new drugs and a template for the design of synthetic analogues. It mainly exhibits a random coil conformation in membrane environment, and in this manuscript, we characterized the structure of chensinin-1b using NMR spectroscopy, its structure is different than the structures of magainin 2, which has an α-helical conformation and indolicidin, which has a random coil structure. The structural features of chensinin-1b that are required for its potent bactericidal activity were also elucidated. Based on these data, we can fully understand the structure-activity relationship of such peptide and identified a novel analogue with properties that make it an attractive topic for future therapeutic research.
Co-reporter:Dejing Shang, Qian Zhang, Weibing Dong, Hao Liang, Xiaonan Bi
Acta Biomaterialia 2016 Volume 33() pp:153-165
Publication Date(Web):15 March 2016
DOI:10.1016/j.actbio.2016.01.019
Abstract
A series of synthesized Trp-containing antimicrobial peptides showed significantly different antimicrobial activity against Gram-negative bacteria despite having similar components and amino acid sequences and the same net positive charge and hydrophobicity. Lipopolysaccharide (LPS) in the outer membrane is a permeability barrier to prevent antimicrobial peptides from crossing into Gram-negative bacteria. We investigated the interaction of five Trp-containing peptides, I1W, I4W, L5W, L11W and L12W, with LPS using circular dichroism (CD), IR spectroscopy, isothermal titration calorimetry (ITC), dynamic light scattering (DLS), zeta-potential measurements and confocal laser scanning microscopy, to address whether bacterial LPS is responsible for the different susceptibilities of Gram-negative bacteria to Trp-containing peptides. Our data indicate that I1W and I4W penetrated the LPS layer and killed Gram-negative bacteria by a “self-promoted uptake” pathway in which the peptides first approach LPS by electrostatic forces and then dissociate LPS micelle. This process results in disorganization of the LPS leaflet and promotes the ability of the peptide to cross the outer membrane into the inner membrane and disrupt the cytoplasmic membrane. Although L5W, L11W and L12W strongly bind to LPS bilayers and depolarize bacterial cytoplasmic membranes, similar to I1W and I4W, they are unable to destabilize LPS aggregates and traverse through the tightly packed LPS molecules. This study increases our understanding of the mechanism of action of these peptides in the LPS outer membrane and will help in the development of a potent broad-spectrum antibiotic for future therapeutic purposes.
Statement of Significance
Tryptophan (Trp) residues show a strong preference for the interfacial region of biological membranes, and this property endows Trp-containing peptides with the unique ability to interact with the surface of bacterial cell membranes. In this manuscript, we report the membrane interaction of Trp-containing peptide to address whether bacterial LPS is responsible for the different susceptibilities of Gram-negative bacteria to Trp-containing peptides. Based on the data collected, we propose a molecular mechanism for the peptide-LPS interactions that allows the peptides to traverse or prevents them from transversing the LPS layer and the target inner membrane. The data should help in the development of a potent broad-spectrum antibiotic for future therapeutic purposes.
Co-reporter:Weibing Dong, Yue Guan and Dejing Shang
RSC Advances 2016 vol. 6(Issue 26) pp:21662-21671
Publication Date(Web):17 Feb 2016
DOI:10.1039/C6RA00322B
To acquire low dielectric constant polyimide films with good mechanical and thermal properties and low coefficient of thermal expansion (CTE) applied in microelectronic fields, as a feasible tactic, three novel diamines containing pyridine and –C(CF3)2– groups were firstly designed and synthesized to employ polymerization with 2,2′-bis(3,4-dicarboxyphenyl) hexafluoropropanedianhydride (6FDA) via a two-stage process with a heating imidization method. Three diamine monomers included one unsubstituted pyridine ring, and another two methyl-substituent groups on two pyridine rings at the 6- and 4- position. The structure–property relationships between the different pyridine rings of the fluorinated PI films, including dielectric constant, thermal stability, mechanical strength, optical transparency, and solubility, were systematically investigated. The fluorinated PI films exhibit low dielectric constant in the range of 2.36–2.52 at 1 MHz, while they still display excellent mechanical properties with tensile strengths as high as 114 MPa. Meanwhile, the PI films show good thermal stability with glass transition temperatures (Tg) in the range of 262–275 °C, low coefficients of thermal expansion (CTEs) ranging from 64 to 68 ppm °C−1 and 5% weight loss temperatures (T5%) located between 468 °C and 499 °C. Further, PI films possess outstanding solubility for easy fabrication. Therefore, these types of fluorinated PI films provide a potential application as alternative dielectric layers in future microelectronic technology.
Co-reporter:Yue Sun, Weibing Dong, Li Sun, Lijie Ma, Dejing Shang
Biomaterials 2015 37() pp: 299-311
Publication Date(Web):
DOI:10.1016/j.biomaterials.2014.10.041
Co-reporter:Weibing Dong;Yue Sun
Biopolymers 2015 Volume 103( Issue 12) pp:719-726
Publication Date(Web):
DOI:10.1002/bip.22737
ABSTRACT
Lipopolysaccharide (LPS) plays a critical role in the pathogenesis of sepsis caused by gram-negative bacterial infections. Therefore, LPS-neutralizing molecules would have important clinical applications. Chensinin-1, a novel antimicrobial peptide with atypical structural features, was found in the skin secretions of the Chinese brown frog Rana chensinensis. To understand the role of LPS in the bacterial susceptibility to chensinin-1 and to investigate its anti-endotoxin effects, the interactions of chensinin-1 with LPS were investigated in this study using circular dichroism, in situ IR, isothermal titration calorimetry, and zeta potential. This study is the first to use in situ IR spectroscopy to evaluate the secondary structural changes of this peptide. The capacity of chensinin-1 to block the LPS-dependent cytokine secretion of macrophages was also investigated. Our results show that chensinin-1 can form α-helical structures in LPS suspensions. LPS can affect the antimicrobial activity of chensinin-1, and chensinin-1 was able to mitigate the effects of LPS. These data may facilitate the development of antimicrobial peptides with potent antimicrobial and anti-endotoxin activities. © 2015 Wiley Periodicals, Inc. Biopolymers 103: 719–726, 2015.
Co-reporter:Xiaonan Bi, Che Wang, Weibing Dong, Wei Zhu and Dejing Shang
The Journal of Antibiotics 2014 67(5) pp:361-368
Publication Date(Web):February 5, 2014
DOI:10.1038/ja.2014.4
Tryptophan (Trp) residues reportedly exhibit a strong membrane-disruptive activity, and this property endows Trp-containing antimicrobial peptides (AMPs) with a unique ability to interact with the surface of bacterial cell membranes, possibly improving antimicrobial properties. In this study, we investigated the influence of Trp residues engineered to have a distinct preference for the interface region of lipid bilayers on antimicrobial activity. We designed two Trp-substituted AMPs (I1WL5W and I4WL5W) by replacing Ile or Leu residues with two Trp residues at different positions in the L-K6 peptide, and determined their antimicrobial activity and mechanism of membrane action. Both I1WL5W and I4WL5W exhibited significantly higher antimicrobial activity and lower cytotoxicity against Gram-negative and Gram-positive bacteria compared with L-K6. The Trp-substituted peptides had a disordered structure in aqueous solution and adopted an α-helical structure in solutions of 50% trifluoroethanol/water and 30 mM SDS. I1WL5W and I4WL5W caused a significant leakage of calcein from liposomes containing membranes that mimicked those of Escherichia coli and Staphylococcus aureus. Scanning electron microscopy analysis suggested that I1WL5W and I4WL5W killed bacteria by disrupting bacterial cell membranes. Furthermore, fluorescence and quenching data from a variety of liposomes, which mimic different cell membranes, indicated that the Trp-substituted peptides could insert into the lipid bilayers and induce blue shifts in the emission spectra of the Trp residues. I1WL5W and I4WL5W were also less susceptible to acrylamide or KI quenchers. The current work may be important for designing novel Trp-containing peptides exhibiting strong antimicrobial abilities by penetrating bacterial membranes.
Co-reporter:Dejing Shang;Xiaofan Li;Yue Sun;Che Wang;Li Sun;Shi Wei;Meng Gou
Chemical Biology & Drug Design 2012 Volume 79( Issue 5) pp:653-662
Publication Date(Web):
DOI:10.1111/j.1747-0285.2012.01363.x
Temporin-1CEb shows antimicrobial activity against Gram-positive bacteria, but its therapeutic potential is limited by its haemolysis. In this study, eight temporin-1CEb analogues with altered cationicities and hydrophobicities were synthesized. Increasing cationicity and amphipathicity by substituting neutral and non-polar amino acid residues on the hydrophilic face of the α-helix by five or six lysines increased antimicrobial potency approximately 10-fold to 40-fold, although when the number of positive charges was increased from +6 to +7, the antimicrobial potency was not additionally enhanced. The substitution of an l-lysine with a d-lysine, meanwhile maintaining the net charge and the mean hydrophobicity values, had only a minor effect on its antimicrobial activity, whereas significantly led a decrease in its haemolytic activity. Of all the peptides, l-K6 has the best potential as an antimicrobial agent because its antimicrobial activity against both Gram-positive and Gram-negative bacteria is substantial, and its haemolytic activity is negligible. l-K6 adopts an α-helix in 50% trifluoroethanol/water and 30 mm SDS solutions. l-K6 killed 99.9% of E. coli and S. aureus at 4× MIC in 60 min, and its postantibiotic effect was >5 h. l-K6 affects the integrity of E. coli and S. aureus plasma membranes by rapidly inducing membrane depolarization.
Co-reporter:Dejing Shang;Yue Sun;Che Wang;Shi Wei
Applied Microbiology and Biotechnology 2012 Volume 96( Issue 6) pp:1551-1560
Publication Date(Web):2012 December
DOI:10.1007/s00253-012-4148-3
Many antimicrobial peptides from amphibian skin have been purified and structurally characterized and may be developed as therapeutic agents. Here we describe the antibacterial properties and membrane interaction of chensinin-1, a cationic arginine/histidine-rich antimicrobial peptide, from the skin secretions of Rana chensinensis. The amino acid composition, sequence, and atypical structure of chensinin-1 differ from other known antimicrobial peptides from amphibian skin. Chensinin-1 exhibited selective antimicrobial activity against Gram-positive bacteria, was inactive against Gram-negative bacteria, and had no hemolytic activity on human erythrocytes. The CD spectra for chensinin-1 indicated that the peptide adopted an aperiodic structure in water and a conformational structure with 20 % β-strands, 8 % α-helices, and the remaining majority of random coils in the trifluoroethanol or SDS solutions. Time-kill kinetics against Gram-positive Bacillus cereus demonstrated that chensinin-1 was rapidly bactericidal at 2× MIC and PAE was found to be >5 h. Chensinin-1 caused rapid and large dye leakage from negatively charged model vesicles. Furthermore, membrane permeation assays on intact B. cereus indicated that chensinin-1 induced membrane depolarization in less than 1 min and followed to damage the integrity of the cytoplasmic membrane and resulted in efflux of molecules from cytoplasma. Hence, the primary target of chensinin-1 action was the cytoplasmic membrane of bacteria. Chensinin-1 was unable to overcome bacterial resistance imposed by the lipopolysaccharide leaflet, the major constituent of the outer membrane of Gram-negative bacteria. Lipopolysaccharide induced oligomerization of chensinin-1, thus preventing its translocation across the outer membrane.
Co-reporter:Dejing Shang, Jianing Zhang, Lei Wen, Yang Li and Qiao Cui
Journal of Agricultural and Food Chemistry 2009 Volume 57(Issue 17) pp:7737-7742
Publication Date(Web):August 13, 2009
DOI:10.1021/jf9019344
Inorganic selenite can be transformed into organic forms and bind to proteins and polysaccharides in Se-enriched submerged Ganoderma lucidum cultures. In the present study, a novel Se-containing polysaccharide, SeGLP-2B-1, was purified from the Se-enriched mycelia of G. lucidum and the antiproliferative activities against six human cancer cell lines were investigated. The Se content of SeGLP-2B-1 was 186.7 μg/g, which was 150-fold larger than that of the regular polysaccharide GLP-2B-1 (1.3 μg/g). SeGLP-2B-1 (1.06 × 106 Da) was composed of glucose, rhamnose, xylose, and galactose with a molar ratio of 1.000:0.652:0.443:0.227. SeGLP-2B-1 exhibited an approximately 10-fold stronger antiproliferative activity against six human cancer cell lines as compared to GLP-2B-1. Thus, Se is believed to play an important role in increasing the antiproliferative property of SeGLP-2B-1. These findings indicate that SeGLP-2B-1 may serve as a dietary Se supplement.
Co-reporter:Dejing Shang;Qiao Cui;Yang Li;Zhi Yu;Lei Wen
Frontiers in Biology 2009 Volume 4( Issue 3) pp:248-253
Publication Date(Web):2009 September
DOI:10.1007/s11515-009-0020-y
Recent studies on the inhibition of tumor growth by Se-containing polysaccharide were reviewed. Meanwhile, the possible molecular mechanisms of the inhibition of tumor cell growth through antioxidation, induction of tumor cell apoptosis, blockade of cell cycle, and enhancement of immunity by Se-containing polysaccharide were proposed. In the end, the potential application of Se-containing polysaccharide in the prevention and treatment of tumor was elucidated.
Co-reporter:
Science 1920 Vol 51(1330) pp:628-629
Publication Date(Web):25 Jun 1920
DOI:10.1126/science.51.1330.628
Co-reporter:Henry S. White
Science 1919 Vol 50(1297) pp:437-439
Publication Date(Web):07 Nov 1919
DOI:10.1126/science.50.1297.437
