Alamethicin
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Category | Antibiotics |
Catalog number | BBF-04141 |
CAS | 27061-78-5 |
Molecular Weight | 1964.30 |
Molecular Formula | C92H150N22O25 |
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Description
Alamethicin, an antibiotic peptide compound, could be obtained from the fungus Trichoderma viride and is commonly used in studing ion channel assembly and peptide-membrane interactions.
Specification
Sequence | XPXAXAQXVXGLXPVXXEQF |
Storage | Store at -20°C (dark) |
IUPAC Name | (4S)-4-[[2-[[2-[[(2S)-2-[[(2S)-1-[2-[[(2S)-2-[[2-[[2-[[(2S)-2-[[2-[[(2S)-2-[[(2S)-2-[[2-[[(2S)-2-[[2-[[(2S)-1-(2-acetamido-2-methylpropanoyl)pyrrolidine-2-carbonyl]amino]-2-methylpropanoyl]amino]propanoyl]amino]-2-methylpropanoyl]amino]propanoyl]amino]-5-amino-5-oxopentanoyl]amino]-2-methylpropanoyl]amino]-3-methylbutanoyl]amino]-2-methylpropanoyl]amino]acetyl]amino]-4-methylpentanoyl]amino]-2-methylpropanoyl]pyrrolidine-2-carbonyl]amino]-3-methylbutanoyl]amino]-2-methylpropanoyl]amino]-2-methylpropanoyl]amino]-5-[[(2S)-5-amino-1-[[(2R)-1-hydroxy-3-phenylpropan-2-yl]amino]-1,5-dioxopentan-2-yl]amino]-5-oxopentanoic acid |
Canonical SMILES | CC(C)CC(C(=O)NC(C)(C)C(=O)N1CCCC1C(=O)NC(C(C)C)C(=O)NC(C)(C)C(=O)NC(C)(C)C(=O)NC(CCC(=O)O)C(=O)NC(CCC(=O)N)C(=O)NC(CC2=CC=CC=C2)CO)NC(=O)CNC(=O)C(C)(C)NC(=O)C(C(C)C)NC(=O)C(C)(C)NC(=O)C(CCC(=O)N)NC(=O)C(C)NC(=O)C(C)(C)NC(=O)C(C)NC(=O)C(C)(C)NC(=O)C3CCCN3C |
InChI | InChI=1S/C92H150N22O25/c1-47(2)43-58(72(127)108-92(24,25)84(139)113-41-29-33-59(113)73(128)103-65(48(3)4)75(130)111-90(20,21)82(137)112-89(18,19)80(135)102-56(37-40-64(120)121)70(125)101-55(35-38-61(93)117)69(124)98-54(46-115)44-53-31-27-26-28-32-53)99-63(119)45-95-77(132)85(10,11)110-76(131)66(49(5)6)104-81(136)88(16,17)107-71(126)57(36-39-62(94)118)100-67(122)50(7)96-78(133)86(12,13)106-68(123)51(8)97-79(134)87(14,15)109-74(129)60-34-30-42-114(60)83(138)91(22,23)105-52(9)116/h26-28,31-32,47-51,54-60,65-66,115H,29-30,33-46H2,1-25H3,(H2,93,117)(H2,94,118)(H,95,132)(H,96,133)(H,97,134)(H,98,124)(H,99,119)(H,100,122)(H,101,125)(H,102,135)(H,103,128)(H,104,136)(H,105,116)(H,106,123)(H,107,126)(H,108,127)(H,109,129)(H,110,131)(H,111,130)(H,112,137)(H,120,121)/t50-,51-,54+,55-,56-,57-,58-,59-,60-,65-,66-/m0/s1 |
InChI Key | LGHSQOCGTJHDIL-UTXLBGCNSA-N |
Source | Trichoderma viride |
Properties
Appearance | Off-white to Beige Powder |
Application | Can mimic nerve action potential across artificial membranes. |
Boiling Point | 2090.0±65.0°C at 760 mmHg |
Melting Point | 252-272°C |
Density | 1.2±0.1 g/cm3 |
Solubility | Soluble in DMSO, Methanol, Ethanol |
Reference Reading
1. The mechanism of channel formation by alamethicin as viewed by molecular dynamics simulations
H J Berendsen, D P Tieleman, M S Sansom Novartis Found Symp . 1999;225:128-41; discussion 141-5. doi: 10.1002/9780470515716.ch9.
Alamethicin is a 20-residue channel-forming peptide that forms a stable amphipathic alpha-helix in membrane and membrane-mimetic environments. This helix contains a kink induced by a central Gly-X-X-Pro sequence motif. Alamethicin channels are activated by a cis positive transbilayer voltage. Channel activation is suggested to correspond to voltage-induced insertion of alamethicin helices in the bilayer. Alamethicin forms multi-conductance channels in lipid bilayers. These channels are formed by parallel bundles of transmembrane helices surrounding a central pore. A change in the number of helices per bundle switches the single channel conductance level. Molecular dynamics simulations of alamethicin in a number of different environments have been used to explore its channel-forming properties. These simulations include: (i) alamethicin in solution in water and in methanol; (ii) a single alamethicin helix at the surface of a phosphatidylcholine bilayer; (iii) single alamethicin helices spanning a phosphatidylcholine bilayer; and (iv) channels formed by bundles of 5, 6, 7 or 8 alamethicin helices spanning a phosphatidylcholine bilayer. The total simulation time is c. 30 ns. Thus, these simulations provide a set of dynamic snapshots of a possible mechanism of channel formation by this peptide.
2. Model ion channels: gramicidin and alamethicin
G A Woolley, B A Wallace J Membr Biol . 1992 Aug;129(2):109-36. doi: 10.1007/BF00219508.
We have discussed in some detail a variety of experimental studies which were designed to elucidate the conformational and dynamic properties of gramicidin and alamethicin. Although the behavior of these peptides is by no means fully characterized, these studies have already permitted aspects of ion channel activity to be understood in molecular terms. Studies with gramicidin in a variety of organic solutions have revealed conformational heterogeneity of this peptide; at least five major isomers exist, several of which have been characterized in detail using NMR spectroscopy and X-ray crystallography. When added to lipid membranes gramicidin undergoes a further conformational conversion. Although the conformation of gramicidin in membranes is not as well characterized as the solution conformation(s) and an X-ray structure is not yet available, detailed data, particularly from solid-state NMR studies, continue to become available and a right-handed beta 6.3 helical conformation of the peptide backbone is now generally accepted. Two of these beta 6.3 helices joined at their N-termini are believed to form the conducting channel. The conformational behavior of the side-chains of gramicidin in the membrane-bound form is not well established and several NMR, CD, fluorescence and theoretical studies are now focussed on this. Although the side-chains do not directly contact the permeating ions, they can have distinct effects on conductance and selectivity by altering the electrostatic environment sensed by the ion. The dynamics of both side-chain and backbone conformations of gramicidin appear critical to a detailed understanding of the ion transport process in this channel. As the description of the membrane-bound conformation of gramicidin becomes more detailed, simulations of ion transport using computational methods are likely to improve and will further our understanding of the processes of ion transport. As well as internal motion of the backbone and side-chains, gramicidin undergoes rotational and translational motion in the plane of the membrane. These motions do not appear to be essential for the process of ion transport but can affect channel lifetime since lifetime is determined by the rate of association and dissociation of gramicidin monomers. Gramicidin-membrane interactions are also likely to be involved in the frequency of occurrence of channel subconductance states, the frequency of channel flickering and fundamentally in the stability of the membrane-bound gramicidin conformation. Alamethicin forms channels in membranes which are strongly voltage-dependent. The molecular origin of voltage-dependent conductances has been a fundamental problem in biophysics for many years.(ABSTRACT TRUNCATED AT 400 WORDS)
3. Alamethicin for using in bioavailability studies? - Re-evaluation of its effect
Sascha Rohn, Maren Vollmer, Ronald Maul, Mirko Klingebiel Toxicol In Vitro . 2017 Mar;39:111-118. doi: 10.1016/j.tiv.2016.11.015.
A major pathway for the elimination of drugs is the biliary and renal excretion following the formation of more hydrophilic secondary metabolites such as glucuronides. For in vitro investigations of the phase II metabolism, hepatic microsomes are commonly used in the combination with the pore-forming peptide alamethicin, also to give estimates for the in vivo situation. Thus, alamethicin may represent a neglected parameter in the characterization of microsomal in vitro assays. In the present study, the influence of varying alamethicin concentrations on glucuronide formation of selected phenolic compounds was investigated systematically. A correlation between the alamethicin impact and the lipophilicity of the investigated substrates was analyzed as well. Lipophilicity was determined by the logarithm of the octanol-water partition coefficient. For every substrate, a distinct alamethicin concentration could be detected leading to a maximal glucuronidation activity. Further increase of the alamethicin application led to negative effects. The differences between the maximum depletion rates with and without alamethicin addition varied between 2.7% and 18.2% depending on the substrate. A dependence on the lipophilicity could not be confirmed. Calculation of the apparent intrinsic clearance led to a more than 2-fold increase using the most effective alamethicin concentration compared to the alamethicin free control.
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Bio Calculators
* Our calculator is based on the following equation:
Concentration (start) x Volume (start) = Concentration (final) x Volume (final)
It is commonly abbreviated as: C1V1 = C2V2
* Total Molecular Weight:
g/mol
Tip: Chemical formula is case sensitive. C22H30N4O √ c22h30n40 ╳