1. Insights into the molecular flexibility of θ-defensins by NMR relaxation analysis
Anne C Conibear, Conan K Wang, Tao Bi, K Johan Rosengren, Julio A Camarero, David J Craik J Phys Chem B. 2014 Dec 11;118(49):14257-66. doi: 10.1021/jp507754c. Epub 2014 Nov 25.
θ-Defensins are mammalian cyclic peptides that have antimicrobial activity and show potential as stable scaffolds for peptide-based drug design. The cyclic cystine ladder structural motif of θ-defensins has been characterized using NMR spectroscopy and is important for their structure and stability. However, the effect of the pronounced elongated topology of θ-defensins on their molecular motion is not yet understood. Studies of molecular motion by NMR relaxation measurements have been facilitated by the recent development of a semirecombinant method for producing cyclic peptides that allows for isotopic labeling. Here we have undertaken a multifield (15)N NMR relaxation analysis of the anti-HIV θ-defensin, HTD-2, and interpreted the experimental data using various models of overall and internal molecular motion. We found that it was necessary to apply a model that includes internal motion to account for the variations in the experimental T1 and NOE data at different backbone amide sites in the peptide. Although an isotropic model with internal motion was the simplest model that provided a satisfactory fit with the experimental data, we cannot exclude the possibility that overall motion is anisotropic, especially considering the strikingly elongated topology of θ-defensins. The presence of flexible side chains, self-association, interactions with solvent, and internal motions are all potential contributors to the observed relaxation data. Internal motion consistent with the constraints imposed by the cyclic cystine ladder was observed in that the order parameters, S(2), show that residues in the turns are more flexible than those in the β-sheet. This study provides insights into the dynamics of θ-defensins and information that might be useful in their application as scaffolds in drug design.
2. Distinct mode of membrane interaction and disintegration by diverse class of antimicrobial peptides
Nutan Agadi, Atanu Maity, Akash Kumar Jha, Rajarshi Chakrabarti, Ashutosh Kumar Biochim Biophys Acta Biomembr. 2022 Dec 1;1864(12):184047. doi: 10.1016/j.bbamem.2022.184047. Epub 2022 Sep 12.
The exploitation of conventional antibiotics in conjunction with the adeptness of microbes has led to the emergence of multi-drug-resistant pathogens. This has posed a severe threat to combating life-threatening infectious diseases. Antimicrobial peptides (AMP), which are considered to be the first line of defense in all living organisms, are being developed for therapeutic use. Herein, we determined the NMR solution structure of Rhesus macaque Myeloid Alpha Defensin-4 (RMAD4), a defensin AMP. Additionally, the distinct modes of membrane perturbation for two structurally dissimilar classes of AMPs was studied using biophysical methods namely, Solid-state 31P NMR, DSC and cryo-TEM. The cathelicidin - Bovine myeloid antimicrobial peptide (BMAP-28 (1-18)), which adopts a helical conformation, and the defensin RMAD4 peptide that natively folds to form β-sheets appeared to engage differently with the bacterial membrane. The helical BMAP-28 (1-18) peptide initiates lipid segregation and membrane thinning followed by pore formation, while the β-stranded RMAD4 peptide demonstrates fragmentation of the bilayer by the carpet or detergent-like mechanism of action. Molecular dynamics studies sufficiently corroborated these findings. The structure and mechanism of action of the AMPs studied using experimental and computational approaches are believed to help in providing a platform for the rational design of new competent and cost-effective antimicrobial peptides for therapeutic applications.