melitten and azobenzene

melitten has been researched along with azobenzene* in 2 studies

Other Studies

2 other study(ies) available for melitten and azobenzene

Article	Year
Substituting azobenzene for proline in melittin to create photomelittin: A light-controlled membrane active peptide. Biochimica et biophysica acta. Biomembranes, 2021, 12-01, Volume: 1863, Issue:12 In this article we present the synthesis and characterization of a new form of the membrane active peptide melittin: photomelittin. This peptide was created by substituting the proline residue in melittin for a synthetic azobenzene amino acid derivative. This azobenzene altered the membrane activity of the peptide while retaining much of the secondary structure. Furthermore, the peptide demonstrates added light-dependent activity in leakage assays. There is a 1.5-fold increase in activity when exposed to UV light as opposed to visible light. The peptides further exhibit light-dependent hemolytic activity against human red blood cells. This will enable future studies optimizing photomelittin and other azobenzene-containing membrane active peptides for uses in medicine, drug delivery, and other biotechnological applications. Topics: Amino Acid Sequence; Azo Compounds; Humans; Light; Melitten; Membranes; Peptides; Proline	2021
Ion/molecule reactions of cation radicals formed from protonated polypeptides via gas-phase ion/ion electron transfer. Journal of the American Chemical Society, 2006, Sep-13, Volume: 128, Issue:36 Cation radicals formed via gas-phase electron transfer to multiply protonated polypeptides have been found to react with molecular oxygen. Such cation radicals are of interest within the context of electron transfer dissociation, a phenomenon with high utility for the characterization of peptide and protein primary structures. Most of the cation radicals show the attachment of O(2) under room temperature storage conditions in an electrodynamic ion trap. At higher temperatures and under conditions of collisional activation, the oxygen adduct species lose O(2), HO(), or HO(2)(), depending upon the identity of the side chain at the radical site. The fragments containing the C-terminus, the so-called z-ions, which are predominantly radical species, engage in reactions with molecular oxygen. This allows for the facile distinction between z-ions and their complementary even-electron c-ion counterparts. Such a capability has utility in protein identification and characterization via mass spectrometry. Intact electron transfer products also show oxygen attachment. Subsequent activation of such adducts show dissociation behavior very similar to that noted for z-ion adducts. These observations indicate that ion/radical reactions can be used to probe the locations of radical sites in the undissociated electron transfer products as well as distinguish between c- and z-type ions. Topics: Amino Acid Sequence; Azo Compounds; Cations; Free Radicals; Gases; Mass Spectrometry; Melitten; Molecular Sequence Data; Neurotensin; Nitrobenzenes; Oxygen; Peptides	2006

Article

Year

Substituting azobenzene for proline in melittin to create photomelittin: A light-controlled membrane active peptide.

Biochimica et biophysica acta. Biomembranes, 2021, 12-01, Volume: 1863, Issue:12

In this article we present the synthesis and characterization of a new form of the membrane active peptide melittin: photomelittin. This peptide was created by substituting the proline residue in melittin for a synthetic azobenzene amino acid derivative. This azobenzene altered the membrane activity of the peptide while retaining much of the secondary structure. Furthermore, the peptide demonstrates added light-dependent activity in leakage assays. There is a 1.5-fold increase in activity when exposed to UV light as opposed to visible light. The peptides further exhibit light-dependent hemolytic activity against human red blood cells. This will enable future studies optimizing photomelittin and other azobenzene-containing membrane active peptides for uses in medicine, drug delivery, and other biotechnological applications.

Topics: Amino Acid Sequence; Azo Compounds; Humans; Light; Melitten; Membranes; Peptides; Proline

2021

Ion/molecule reactions of cation radicals formed from protonated polypeptides via gas-phase ion/ion electron transfer.

Journal of the American Chemical Society, 2006, Sep-13, Volume: 128, Issue:36

Cation radicals formed via gas-phase electron transfer to multiply protonated polypeptides have been found to react with molecular oxygen. Such cation radicals are of interest within the context of electron transfer dissociation, a phenomenon with high utility for the characterization of peptide and protein primary structures. Most of the cation radicals show the attachment of O(2) under room temperature storage conditions in an electrodynamic ion trap. At higher temperatures and under conditions of collisional activation, the oxygen adduct species lose O(2), HO(*), or HO(2)(*), depending upon the identity of the side chain at the radical site. The fragments containing the C-terminus, the so-called z-ions, which are predominantly radical species, engage in reactions with molecular oxygen. This allows for the facile distinction between z-ions and their complementary even-electron c-ion counterparts. Such a capability has utility in protein identification and characterization via mass spectrometry. Intact electron transfer products also show oxygen attachment. Subsequent activation of such adducts show dissociation behavior very similar to that noted for z-ion adducts. These observations indicate that ion/radical reactions can be used to probe the locations of radical sites in the undissociated electron transfer products as well as distinguish between c- and z-type ions.

Topics: Amino Acid Sequence; Azo Compounds; Cations; Free Radicals; Gases; Mass Spectrometry; Melitten; Molecular Sequence Data; Neurotensin; Nitrobenzenes; Oxygen; Peptides

2006