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Design of Lipid-Protein Conjugates Using Amphiphilic Peptide Substrates of Microbial Transglutaminase.

Mari TakaharaRie WakabayashiKosuke MinamihataMasahiro GotoNoriho Kamiya
Published in: ACS applied bio materials (2018)
Lipid modification of proteins plays a significant role in regulating the cellular environment. Mimicking natural lipidated proteins is a key technique for assessing the function of proteins modified with lipids and also to render self-assembly of lipids to a target protein. Herein, we report a facile method of conjugating proteins with lipid-fused peptides under homogeneous physiological conditions by using the microbial transglutaminase (MTG) reaction. MTG catalyzes the cross-linking reaction between a specific glutamine (Q) in a protein and a lysine (K) in newly designed lipid-fused peptides. The water-soluble peptide substrates for lipid modification, C 14 -X-MRHKGS, were newly synthesized, where C 14 , X, and MRHKGS represent myristic acid, linker peptides composed of G, P, or S, and MTG-reactive K surrounded with basic amino acids, respectively. The MTG-mediated cross-linking reaction between a protein fused with LLQG at the C-terminus and C 14 -X-MRHKGS (5 molar eq) dissolved in a phosphate saline solution resulted in lipid-protein conjugates with yields of 70 to 100%. The anchoring ability of the obtained lipid-protein conjugates to cell membranes was dependent on the number of G residues in the G n S linker, suggesting that self-assembly and hydrophobicity of the G n S motif serves to enhance membrane anchoring of lipid-protein conjugates.
Keyphrases
  • amino acid
  • fatty acid
  • protein protein
  • binding protein
  • microbial community
  • cancer therapy
  • water soluble
  • small molecule
  • cell therapy
  • bone marrow
  • metal organic framework