SemOpenAlex |

SemOpenAlex

Matches in SemOpenAlex for { <https://semopenalex.org/work/W2233933882> ?p ?o ?g. }

Showing items 1 to 100 of ±116 with 100 items per page.

W2233933882 endingPage "192" @default.
W2233933882 startingPage "184" @default.
W2233933882 abstract "The structures of membrane-bound polypeptides are intimately related to their functions and may change dramatically with the lipid environment. Circular dichroism (CD) is a rapid analytical method that requires relatively low amounts of material and no labeling. Conventional CD is routinely used to monitor the secondary structure of peptides and proteins in solution, for example, in the presence of ligands and other binding partners. In the case of membrane-active peptides and transmembrane proteins, these measurements can be applied to, and remain limited to, samples containing detergent micelles or small sonicated lipid vesicles. Such traditional CD analysis reveals only secondary structures. With the help of an oriented circular dichroism (OCD) setup, however, based on the preparation of macroscopically oriented lipid bilayers, it is possible to address the membrane alignment of a peptide in addition to its conformation. This approach has been mostly used for α-helical peptides so far, but other structural elements are conceivable as well. OCD analysis relies on Moffitt's theory, which predicts that the electronic transition dipole moments of the backbone amide bonds in helical polypeptides are polarized either parallel or perpendicular to the helix axis. The interaction of the electric field vector of the circularly polarized light with these transitions results in an OCD spectrum of a membrane-bound α-helical peptide, which exhibits a characteristic line shape and reflects the angle between the helix axis and the bilayer normal. For parallel alignment of a peptide helix with respect to the membrane surface (S-state), the corresponding fingerprint CD band around 208 nm will exhibit maximum negative amplitude. If the helix changes its alignment via an obliquely tilted (T-state) to a fully inserted transmembrane orientation (I-state), the ellipticity at 208 nm decreases and the value approaches zero due to the decreased interactions between the field and the transition dipole. Compared to conventional CD, OCD data are not only collected in the biologically relevant environment of a highly hydrated planar lipid bilayer (whose composition can be varied at will), but in addition it provides information about the tilt angle of the polypeptide in the membrane. It is the method of choice for screening numerous different conditions, such as peptide concentration, lipid composition, membrane additives, pH, temperature, and sample hydration. All these factors have been found to affect the peptide alignment in membrane, while having little or no influence on conformation. In many cases, the observed realignment could be related to biological action, such as pore formation by antimicrobial and cell-penetrating peptides, or to binding events of transmembrane segments of integral membrane proteins. Likewise, any lipid-induced conversion from α-helix to β-sheeted conformation is readily picked up by OCD and has been interpreted in terms of protein instability or amyloid-formation." @default.
W2233933882 created "2016-06-24" @default.
W2233933882 creator A5006608885 @default.
W2233933882 creator A5037635585 @default.
W2233933882 creator A5067406091 @default.
W2233933882 creator A5086605859 @default.
W2233933882 date "2016-01-12" @default.
W2233933882 modified "2023-10-05" @default.
W2233933882 title "Oriented Circular Dichroism: A Method to Characterize Membrane-Active Peptides in Oriented Lipid Bilayers" @default.
W2233933882 cites W1573986638 @default.
W2233933882 cites W1973510304 @default.
W2233933882 cites W1982113943 @default.
W2233933882 cites W1995601809 @default.
W2233933882 cites W1997332996 @default.
W2233933882 cites W2002395847 @default.
W2233933882 cites W2009785646 @default.
W2233933882 cites W2013979901 @default.
W2233933882 cites W2018296807 @default.
W2233933882 cites W2020297895 @default.
W2233933882 cites W2029737253 @default.
W2233933882 cites W2031143043 @default.
W2233933882 cites W2032977115 @default.
W2233933882 cites W2035816136 @default.
W2233933882 cites W2039456470 @default.
W2233933882 cites W2051046184 @default.
W2233933882 cites W2053518734 @default.
W2233933882 cites W2053670655 @default.
W2233933882 cites W2058771789 @default.
W2233933882 cites W2059865140 @default.
W2233933882 cites W2062005486 @default.
W2233933882 cites W2078231394 @default.
W2233933882 cites W2078415387 @default.
W2233933882 cites W2083219962 @default.
W2233933882 cites W2089055781 @default.
W2233933882 cites W2104571730 @default.
W2233933882 cites W2149040052 @default.
W2233933882 cites W2152246809 @default.
W2233933882 cites W2157796847 @default.
W2233933882 cites W2167131858 @default.
W2233933882 cites W2169700928 @default.
W2233933882 cites W2320706891 @default.
W2233933882 cites W2335396054 @default.
W2233933882 cites W428907568 @default.
W2233933882 doi "https://doi.org/10.1021/acs.accounts.5b00346" @default.
W2233933882 hasPubMedId "https://pubmed.ncbi.nlm.nih.gov/26756718" @default.
W2233933882 hasPublicationYear "2016" @default.
W2233933882 type Work @default.
W2233933882 sameAs 2233933882 @default.
W2233933882 citedByCount "86" @default.
W2233933882 countsByYear W22339338822016 @default.
W2233933882 countsByYear W22339338822017 @default.
W2233933882 countsByYear W22339338822018 @default.
W2233933882 countsByYear W22339338822019 @default.
W2233933882 countsByYear W22339338822020 @default.
W2233933882 countsByYear W22339338822021 @default.
W2233933882 countsByYear W22339338822022 @default.
W2233933882 countsByYear W22339338822023 @default.
W2233933882 crossrefType "journal-article" @default.
W2233933882 hasAuthorship W2233933882A5006608885 @default.
W2233933882 hasAuthorship W2233933882A5037635585 @default.
W2233933882 hasAuthorship W2233933882A5067406091 @default.
W2233933882 hasAuthorship W2233933882A5086605859 @default.
W2233933882 hasConcept C118892022 @default.
W2233933882 hasConcept C12554922 @default.
W2233933882 hasConcept C130316041 @default.
W2233933882 hasConcept C133571119 @default.
W2233933882 hasConcept C185592680 @default.
W2233933882 hasConcept C18903297 @default.
W2233933882 hasConcept C192157962 @default.
W2233933882 hasConcept C2778530040 @default.
W2233933882 hasConcept C2779281246 @default.
W2233933882 hasConcept C2779965526 @default.
W2233933882 hasConcept C39944091 @default.
W2233933882 hasConcept C41625074 @default.
W2233933882 hasConcept C55493867 @default.
W2233933882 hasConcept C62614982 @default.
W2233933882 hasConcept C8010536 @default.
W2233933882 hasConcept C86803240 @default.
W2233933882 hasConceptScore W2233933882C118892022 @default.
W2233933882 hasConceptScore W2233933882C12554922 @default.
W2233933882 hasConceptScore W2233933882C130316041 @default.
W2233933882 hasConceptScore W2233933882C133571119 @default.
W2233933882 hasConceptScore W2233933882C185592680 @default.
W2233933882 hasConceptScore W2233933882C18903297 @default.
W2233933882 hasConceptScore W2233933882C192157962 @default.
W2233933882 hasConceptScore W2233933882C2778530040 @default.
W2233933882 hasConceptScore W2233933882C2779281246 @default.
W2233933882 hasConceptScore W2233933882C2779965526 @default.
W2233933882 hasConceptScore W2233933882C39944091 @default.
W2233933882 hasConceptScore W2233933882C41625074 @default.
W2233933882 hasConceptScore W2233933882C55493867 @default.
W2233933882 hasConceptScore W2233933882C62614982 @default.
W2233933882 hasConceptScore W2233933882C8010536 @default.
W2233933882 hasConceptScore W2233933882C86803240 @default.
W2233933882 hasIssue "2" @default.
W2233933882 hasLocation W22339338821 @default.
W2233933882 hasLocation W22339338822 @default.
W2233933882 hasOpenAccess W2233933882 @default.