396 related articles for article (PubMed ID: 11779567)
21. Molecular Dynamics Simulations of Human Antimicrobial Peptide LL-37 in Model POPC and POPG Lipid Bilayers.
Zhao L; Cao Z; Bian Y; Hu G; Wang J; Zhou Y
Int J Mol Sci; 2018 Apr; 19(4):. PubMed ID: 29652823
[TBL] [Abstract][Full Text] [Related]
22. Membrane insertion and lateral diffusion of fluorescence-labelled cytochrome c oxidase subunit IV signal peptide in charged and uncharged phospholipid bilayers.
Frey S; Tamm LK
Biochem J; 1990 Dec; 272(3):713-9. PubMed ID: 2176475
[TBL] [Abstract][Full Text] [Related]
23. Peptide:lipid ratio and membrane surface charge determine the mechanism of action of the antimicrobial peptide BP100. Conformational and functional studies.
Manzini MC; Perez KR; Riske KA; Bozelli JC; Santos TL; da Silva MA; Saraiva GK; Politi MJ; Valente AP; Almeida FC; Chaimovich H; Rodrigues MA; Bemquerer MP; Schreier S; Cuccovia IM
Biochim Biophys Acta; 2014 Jul; 1838(7):1985-99. PubMed ID: 24743023
[TBL] [Abstract][Full Text] [Related]
24. Poly-l-lysines and poly-l-arginines induce leakage of negatively charged phospholipid vesicles and translocate through the lipid bilayer upon electrostatic binding to the membrane.
Reuter M; Schwieger C; Meister A; Karlsson G; Blume A
Biophys Chem; 2009 Sep; 144(1-2):27-37. PubMed ID: 19560854
[TBL] [Abstract][Full Text] [Related]
25. Branched phospholipids render lipid vesicles more susceptible to membrane-active peptides.
Mitchell NJ; Seaton P; Pokorny A
Biochim Biophys Acta; 2016 May; 1858(5):988-94. PubMed ID: 26514602
[TBL] [Abstract][Full Text] [Related]
26. Effect of variations in the structure of a polyleucine-based alpha-helical transmembrane peptide on its interaction with phosphatidylglycerol bilayers.
Liu F; Lewis RN; Hodges RS; McElhaney RN
Biochemistry; 2004 Mar; 43(12):3679-87. PubMed ID: 15035638
[TBL] [Abstract][Full Text] [Related]
27. Binding of oligoarginine to membrane lipids and heparan sulfate: structural and thermodynamic characterization of a cell-penetrating peptide.
Gonçalves E; Kitas E; Seelig J
Biochemistry; 2005 Feb; 44(7):2692-702. PubMed ID: 15709783
[TBL] [Abstract][Full Text] [Related]
28. Interactions of the antimicrobial peptide Ac-FRWWHR-NH(2) with model membrane systems and bacterial cells.
Rezansoff AJ; Hunter HN; Jing W; Park IY; Kim SC; Vogel HJ
J Pept Res; 2005 May; 65(5):491-501. PubMed ID: 15853943
[TBL] [Abstract][Full Text] [Related]
29. Morphological changes induced by the action of antimicrobial peptides on supported lipid bilayers.
Arouri A; Kiessling V; Tamm L; Dathe M; Blume A
J Phys Chem B; 2011 Jan; 115(1):158-67. PubMed ID: 21158379
[TBL] [Abstract][Full Text] [Related]
30. Comparative mode of action of novel hybrid peptide CS-1a and its rearranged amphipathic analogue CS-2a.
Joshi S; Bisht GS; Rawat DS; Maiti S; Pasha S
FEBS J; 2012 Oct; 279(20):3776-90. PubMed ID: 22883393
[TBL] [Abstract][Full Text] [Related]
31. Crown ether modified peptides: Length and crown ring size impact on membrane interactions.
Paquet-Côté PA; Paradis JP; Auger M; Voyer N
Biochim Biophys Acta Biomembr; 2020 Jul; 1862(7):183261. PubMed ID: 32151610
[TBL] [Abstract][Full Text] [Related]
32. Conformation and Orientation of Antimicrobial Peptides MSI-594 and MSI-594A in a Lipid Membrane.
Yang P; Guo W; Ramamoorthy A; Chen Z
Langmuir; 2023 Apr; 39(15):5352-5363. PubMed ID: 37017985
[TBL] [Abstract][Full Text] [Related]
33. Effect of lipid composition on the topography of membrane-associated hydrophobic helices: stabilization of transmembrane topography by anionic lipids.
Shahidullah K; London E
J Mol Biol; 2008 Jun; 379(4):704-18. PubMed ID: 18479706
[TBL] [Abstract][Full Text] [Related]
34. Structure and organization of hemolytic and nonhemolytic diastereomers of antimicrobial peptides in membranes.
Hong J; Oren Z; Shai Y
Biochemistry; 1999 Dec; 38(51):16963-73. PubMed ID: 10606532
[TBL] [Abstract][Full Text] [Related]
35. Role of Lipid Composition, Physicochemical Interactions, and Membrane Mechanics in the Molecular Actions of Microbial Cyclic Lipopeptides.
Balleza D; Alessandrini A; Beltrán García MJ
J Membr Biol; 2019 Jun; 252(2-3):131-157. PubMed ID: 31098678
[TBL] [Abstract][Full Text] [Related]
36. Activity and characterization of a pH-sensitive antimicrobial peptide.
Hitchner MA; Santiago-Ortiz LE; Necelis MR; Shirley DJ; Palmer TJ; Tarnawsky KE; Vaden TD; Caputo GA
Biochim Biophys Acta Biomembr; 2019 Oct; 1861(10):182984. PubMed ID: 31075228
[TBL] [Abstract][Full Text] [Related]
37. Engineering antimicrobial peptides with improved antimicrobial and hemolytic activities.
Zhao J; Zhao C; Liang G; Zhang M; Zheng J
J Chem Inf Model; 2013 Dec; 53(12):3280-96. PubMed ID: 24279498
[TBL] [Abstract][Full Text] [Related]
38. Bilayer interactions of indolicidin, a small antimicrobial peptide rich in tryptophan, proline, and basic amino acids.
Ladokhin AS; Selsted ME; White SH
Biophys J; 1997 Feb; 72(2 Pt 1):794-805. PubMed ID: 9017204
[TBL] [Abstract][Full Text] [Related]
39. Calcium binding to mixed phosphatidylglycerol-phosphatidylcholine bilayers as studied by deuterium nuclear magnetic resonance.
Macdonald PM; Seelig J
Biochemistry; 1987 Mar; 26(5):1231-40. PubMed ID: 3567169
[TBL] [Abstract][Full Text] [Related]
40. Cellular Membrane Composition Requirement by Antimicrobial and Anticancer Peptide GA-K4.
Mishig-Ochir T; Gombosuren D; Jigjid A; Tuguldur B; Chuluunbaatar G; Urnukhsaikhan E; Pathak C; Lee BJ
Protein Pept Lett; 2017; 24(3):197-205. PubMed ID: 27993125
[TBL] [Abstract][Full Text] [Related]
[Previous] [Next] [New Search]