Literature DB >> 2424516

Vibrational analysis of the structure of gramicidin A. I. Normal mode analysis.

V M Naik, S Krimm.   

Abstract

Normal mode frequencies have been calculated for single-stranded beta 4.4 and beta 6.3 and for double-stranded increases decreases beta 5.6, increases decreases beta 7.2, increases increases beta 5.6, and increases increases beta 7.2 helices that are possible models for the structure of gramicidin A. The force field used in the calculations is one that reproduces the frequencies of model polypeptide chain structures to about +/- 5 cm-1, and is therefore expected to provide meaningful distinctions between these conformations. The calculations predict significant differences in the infrared and Raman spectra of these beta-helices, suggesting that they should be identifiable from their spectra (which is shown in the following paper to be the case). The most sensitive region is that of the amide I frequencies, where the predicted patterns of intense infrared mode, infrared splittings, and intense Raman mode provide a characteristic identification of each of the above structures.

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Year:  1986        PMID: 2424516      PMCID: PMC1329697          DOI: 10.1016/S0006-3495(86)83742-0

Source DB:  PubMed          Journal:  Biophys J        ISSN: 0006-3495            Impact factor:   4.033


  44 in total

1.  Ion-bond forms of the gramicidin a transmembrane channel.

Authors:  B A Wallace
Journal:  Biophys J       Date:  1984-01       Impact factor: 4.033

2.  Vibrational analysis of peptides, polypeptides, and proteins. XXXII. alpha-Poly(L-glutamic acid).

Authors:  P K Sengupta; S Krimm
Journal:  Biopolymers       Date:  1985-08       Impact factor: 2.505

3.  Conformation of peptide chains containing both L- & D-residues. I. Helical structures with alternating L- & D-residues with special reference to the LD-ribbon & the LD-helices.

Authors:  G N Ramachnandran; R Chandrasekaran
Journal:  Indian J Biochem Biophys       Date:  1972-03       Impact factor: 1.918

4.  Normal vibrations of crystalline polyglycine I.

Authors:  Y Abe; S Krimm
Journal:  Biopolymers       Date:  1972       Impact factor: 2.505

5.  Freezing and melting of lipid bilayers and the mode of action of nonactin, valinomycin, and gramicidin.

Authors:  S Krasne; G Eisenman; G Szabo
Journal:  Science       Date:  1971-10-22       Impact factor: 47.728

6.  Conformation of the gramicidin A transmembrane channel: A 13C nuclear magnetic resonance study of 13C-enriched gramicidin in phosphatidylcholine vesicles.

Authors:  S Weinstein; B A Wallace; J S Morrow; W R Veatch
Journal:  J Mol Biol       Date:  1980-10-15       Impact factor: 5.469

7.  A double-stranded beta-helix with antiparallel chains in a crystalline oligo-L-D-peptide.

Authors:  E Benedetti; B Di Blasio; C Pedone; G P Lorenzi; L Tomasic; V Gramlich
Journal:  Nature       Date:  1979-12-06       Impact factor: 49.962

8.  Correlation analysis of electrical noise in lipid bilayer membranes: kinetics of gramicidin A channels.

Authors:  H A Kolb; P Läuger; E Bamberg
Journal:  J Membr Biol       Date:  1975       Impact factor: 1.843

9.  Simultaneous fluorescence and conductance studies of planar bilayer membranes containing a highly active and fluorescent analog of gramicidin A.

Authors:  W R Veatch; R Mathies; M Eisenberg; L Stryer
Journal:  J Mol Biol       Date:  1975-11-25       Impact factor: 5.469

10.  Is the gramicidin a transmembrane channel single-stranded or double-stranded helix? A simple unequivocal determination.

Authors:  D W Urry; T L Trapane; K U Prasad
Journal:  Science       Date:  1983-09-09       Impact factor: 47.728
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  13 in total

1.  Modulation of concentration fluctuations in phase-separated lipid membranes by polypeptide insertion.

Authors:  S Fahsel; E-M Pospiech; M Zein; T L Hazlet; E Gratton; Roland Winter
Journal:  Biophys J       Date:  2002-07       Impact factor: 4.033

2.  Gramicidin channel selectivity. Molecular mechanics calculations for formamidinium, guanidinium, and acetamidinium.

Authors:  B Turano; M Pear; D Busath
Journal:  Biophys J       Date:  1992-07       Impact factor: 4.033

3.  Spectroscopic [correction of eSpectroscopic] and structural properties of valine gramicidin A in monolayers at the air-water interface.

Authors:  Hugo Lavoie; Daniel Blaudez; David Vaknin; Bernard Desbat; Benjamin M Ocko; Christian Salesse
Journal:  Biophys J       Date:  2002-12       Impact factor: 4.033

4.  Peptide model helices in lipid membranes: insertion, positioning, and lipid response on aggregation studied by X-ray scattering.

Authors:  Philipp E Schneggenburger; André Beerlink; Britta Weinhausen; Tim Salditt; Ulf Diederichsen
Journal:  Eur Biophys J       Date:  2010-12-23       Impact factor: 1.733

5.  Time-correlation analysis of simulated water motion in flexible and rigid gramicidin channels.

Authors:  S W Chiu; E Jakobsson; S Subramaniam; J A McCammon
Journal:  Biophys J       Date:  1991-07       Impact factor: 4.033

6.  Vibrational analysis of the structure of gramicidin A. II. Vibrational spectra.

Authors:  V M Naik; S Krimm
Journal:  Biophys J       Date:  1986-06       Impact factor: 4.033

Review 7.  Gramicidin A--phospholipid model systems.

Authors:  B Cornell
Journal:  J Bioenerg Biomembr       Date:  1987-12       Impact factor: 2.945

8.  The normal modes of the gramicidin-A dimer channel.

Authors:  B Roux; M Karplus
Journal:  Biophys J       Date:  1988-03       Impact factor: 4.033

9.  The double pi pi 5.6 helix of gramicidin A predominates in unsaturated lipid membranes.

Authors:  S V Sychev; L I Barsukov; V T Ivanov
Journal:  Eur Biophys J       Date:  1993       Impact factor: 1.733

10.  Solvent history dependence of gramicidin-lipid interactions: a Raman and infrared spectroscopic study.

Authors:  M Bouchard; M Auger
Journal:  Biophys J       Date:  1993-12       Impact factor: 4.033
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