Progression of NMR studies of membrane-active peptides from lipid bilayers to live cells

被引:17
|
作者
Sani, M. -A. [1 ]
Separovic, F. [1 ]
机构
[1] Univ Melbourne, Sch Chem, Inst Bio21, Melbourne, Vic 3010, Australia
来源
JOURNAL OF MAGNETIC RESONANCE | 2015年 / 253卷
基金
澳大利亚研究理事会;
关键词
Solid-state NMR; Antimicrobial peptides; Amyloid peptides; Phospholipid bilayers; Oriented bilayers; MAS; REDOR; Lipid-peptide interactions; SOLID-STATE NMR; NUCLEAR-MAGNETIC-RESONANCE; AUSTRALIAN TREE FROGS; GRAMICIDIN-A; ANTIMICROBIAL PEPTIDES; ROTATING SOLIDS; PHOSPHOLIPID-MEMBRANES; STAPHYLOCOCCUS-AUREUS; MODEL MEMBRANES; P-31; NMR;
D O I
10.1016/j.jmr.2014.11.016
中图分类号
Q5 [生物化学];
学科分类号
071010 ; 081704 ;
摘要
Understanding the structure of membrane-active peptides faces many challenges associated with the development of appropriate model membrane systems as the peptide structure depends strongly on the lipid environment. This perspective provides a brief overview of the approach taken to study antimicrobial and amyloid peptides in phospholipid bilayers using oriented bilayers and magic angle spinning techniques. In particular, Boltzmann statistics REDOR and maximum entropy analysis of spinning side bands are used to analyse systems where multiple states of peptide or lipid molecules may co-exist. We propose that in future, rather than model membranes, structural studies in whole cells are feasible. (C) 2014 Elsevier Inc. All rights reserved.
引用
收藏
页码:138 / 142
页数:5
相关论文
共 50 条
  • [21] Lipid-Protein Nanodiscs Offer New Perspectives for Structural and Functional Studies of Water-Soluble Membrane-Active Peptides
    Shenkarev, Z. O.
    Lyukmanova, E. N.
    Paramonov, A. S.
    Panteleev, P. V.
    Balandin, S. V.
    Shulepko, M. A.
    Mineev, K. S.
    Ovchinnikova, T. V.
    Kirpichnikov, M. P.
    Arseniev, A. S.
    ACTA NATURAE, 2014, 6 (02): : 84 - 94
  • [22] Alginate as an auxiliary bacterial membrane: binding of membrane-active peptides by polysaccharides
    Chan, C
    Burrows, LL
    Deber, CM
    JOURNAL OF PEPTIDE RESEARCH, 2005, 65 (03): : 343 - 351
  • [23] Membrane-Active Peptides Derived from Picornavirus 2B Viroporin
    Sanchez-Martinez, Silvia
    Madan, Vanesa
    Carrasco, Luis
    Nieva, Jose L.
    CURRENT PROTEIN & PEPTIDE SCIENCE, 2012, 13 (07) : 632 - 643
  • [24] Membrane-Active Peptides Attack Cell Membranes in a Lipid-Regulated Curvature-Generating Mode
    Deng, Zhixiong
    You, Xin
    Lin, Zhao
    Dong, Xuewei
    Yuan, Bing
    Yang, Kai
    JOURNAL OF PHYSICAL CHEMISTRY LETTERS, 2023, 14 (28) : 6422 - 6430
  • [25] DAPTOMYCIN, its membrane-active mechanism vs. that of other antimicrobial peptides
    Huang, Huey W.
    BIOCHIMICA ET BIOPHYSICA ACTA-BIOMEMBRANES, 2020, 1862 (10):
  • [26] How lipids influence the mode of action of membrane-active peptides
    Sevcsik, E.
    Pabst, G.
    Jilek, A.
    Lohner, K.
    BIOCHIMICA ET BIOPHYSICA ACTA-BIOMEMBRANES, 2007, 1768 (10): : 2586 - 2595
  • [27] Recent Advances in Computational Modeling of α-Helical Membrane-Active Peptides
    Polyansky, Anton A.
    Chugunov, Anton O.
    Vassilevski, Alexander A.
    Grishin, Eugene V.
    Efremov, Roman G.
    CURRENT PROTEIN & PEPTIDE SCIENCE, 2012, 13 (07) : 644 - 657
  • [28] Antimicrobial peptides: natural templates for synthetic membrane-active compounds
    Giuliani, A.
    Pirri, G.
    Bozzi, A.
    Di Giulio, A.
    Aschi, M.
    Rinaldi, A. C.
    CELLULAR AND MOLECULAR LIFE SCIENCES, 2008, 65 (16) : 2450 - 2460
  • [29] Antimicrobial peptides: natural templates for synthetic membrane-active compounds
    A. Giuliani
    G. Pirri
    A. Bozzi
    A. Di Giulio
    M. Aschi
    A. C. Rinaldi
    Cellular and Molecular Life Sciences, 2008, 65 : 2450 - 2460
  • [30] Topoisomeric Membrane-Active Peptides: A Review of the Last Two Decades
    Carrera-Aubesart, Adam
    Gallo, Maria
    Defaus, Sira
    Todorovski, Toni
    Andreu, David
    PHARMACEUTICS, 2023, 15 (10)
12345