Novel Biomimetic Human TLR2-Derived Peptides for Potential Targeting of Lipoteichoic Acid: An In Silico Assessment.
Nikita DevnarainAyman Y WaddadBeatriz G de la TorreFernando AlbericioThirumala GovenderPublished in: Biomedicines (2021)
Antimicrobial resistance is one of the most significant threats to health and economy around the globe and has been compounded by the emergence of COVID-19, raising important consequences for antimicrobial resistance development. Contrary to conventional targeting approaches, the use of biomimetic application via nanoparticles for enhanced cellular targeting, cell penetration and localized antibiotic delivery has been highlighted as a superior approach to identify novel targeting ligands for combatting antimicrobial resistance. Gram-positive bacterial cell walls contain lipoteichoic acid (LTA), which binds specifically to Toll-like receptor 2 (TLR2) on human macrophages. This phenomenon has the potential to be exploited for the design of biomimetic peptides for antibacterial application. In this study, we have derived peptides from sequences present in human TLR2 that bind to LTA with high affinity. In silico approaches including molecular modelling, molecular docking, molecular dynamics, and thermodynamics have enabled the identification of these crucial binding amino acids, the design of four novel biomimetic TLR2-derived peptides and their LTA binding potential. The outcomes of this study have revealed that one of these novel peptides binds to LTA more strongly and stably than the other three peptides and has the potential to enhance LTA targeting and bacterial cell penetration.
Keyphrases
- antimicrobial resistance
- toll like receptor
- molecular docking
- amino acid
- inflammatory response
- endothelial cells
- molecular dynamics
- single cell
- nuclear factor
- immune response
- cancer therapy
- induced pluripotent stem cells
- cell therapy
- healthcare
- human health
- pluripotent stem cells
- coronavirus disease
- public health
- sars cov
- molecular dynamics simulations
- type diabetes
- mental health
- stem cells
- metabolic syndrome
- binding protein
- multidrug resistant
- glycemic control