Mechanism of Protease Resistance of D-Amino Acid Residue Containing Cationic Antimicrobial Heptapeptides.

Antimicrobial peptides (AMPs) have been an alternate promising class of therapeutics in combating global antibiotic resistance threat. However, the short half-life of AMPs, owing to protease degradability, is one of the major bottlenecks in its commercial success. In this study, we have developed all-D-amino acid containing small cationic peptides P4C and P5C, which are completely protease-resistant, noncytotoxic, nonhemolytic, and potent against the ESKAPE pathogens in comparison to their L analogues.

Effect of Spacer Length Modification of the Cationic Side Chain on the Energetics of Antimicrobial Peptide Binding to Membrane-Mimetic Bilayers.

Understanding the mechanism of action of the antimicrobial peptide (AMP) in terms of its structure and energetics is the key to designing new potent and selective AMPs. Recently, we reported a membranolytic 14-residue-long lysine-rich cationic antimicrobial peptide (LL-14: NH-LKWLKKLLKWLKKL-CONH) against , , and , which is limited by cytotoxicity and expected to undergo facile protease degradation. Aliphatic side-chain-length modification of the cationic amino-acid residues (Lys and Arg) is a popular strategy for designing protease-resistant AMPs.

Bridging Thermodynamics, Antimicrobial Activity, and pH Sensitivity of Cationic Membranolytic Heptapeptides-A Computational and Experimental Study.

Understanding the thermodynamics of peptide:membrane binding and the factors that alter the stability is the key to designing potent and selective small antimicrobial peptides. Here, we report the thermodynamics, antimicrobial activity, and mechanism of a de novo designed seven residue long cationic antimicrobial peptide (P4: NH-LKWLKKL-CONH, Charge +4) and its analogs (P5: Lysine's → Arginine's; P6: Lysine's → Uncharged-Histidine's; P7: Tryptophan → Leucine) by combining computation and experiments. Computer simulations predicted the order of decreasing peptide binding affinity to the membrane-mimetic systems (micelle/bilayer) as P5 > P4 > P7 ≫ P6.

Effect of a monovalent salt on the energetics of an antimicrobial-peptide: micelle dissociation.

Antimicrobial peptides (AMPs) are promising antimicrobial and therapeutic agents. Recently, we synthesized a cationic 14 residue AMP (LL-14: LKWLKKLLKWLKKL), which showed high broad-spectrum antimicrobial activity. However, the antimicrobial activity of LL-14 was compromised in the presence of NaCl.

Effect of Leu/Val Mutation on the Energetics of Antimicrobial Peptide:Micelle Binding.

Recently, we had reported a synthetic positively charged leucine-rich 14-residue-long antimicrobial peptide (AMP, LL-14: NH-LKWLKKLLKWLKKL-CONH), which was highly active and cytotoxic relative to its valine analogue (VV-14). However, the thermodynamics underlying this differential toxicity and antimicrobial activity was unclear. Understanding the energetics of peptide binding to micelles (simplest membrane mimic, viz.

Effect of Differential Backbone Di-substitution of Gamma Amino Acid Residues on the Conformation and Assembly of their Fmoc Derivatives in Solid and Solution States.

We studied the effect of variable backbone dimethyl-substitution of γ amino acid residues (γ , γ and γ ) on the conformation and assembly, in crystals and solution of their Fmoc derivatives. The crystal structure of γ and γ derivatives showed distinct conformations (open/close for γ /γ ) that differed in torsion angles, hydrogen-bonding and most importantly the π-π Fmoc-stacking interactions (relatively favourable for γ -close). Fmoc derivatives existed in an equilibrium between major-monomeric (low energy, non-hydrogen bonded) and minor-dimeric (high energy, hydrogen bonded) populations in solution.

Effect of monovalent salt concentration and peptide secondary structure in peptide-micelle binding.

Recently, we reported a cationic 14 residue peptide LL-14 (LKWLKKLLKWLKKL) with salt-sensitive broad-spectrum antimicrobial potency. However, the mechanism of its salt (NaCl) sensitivity remained unclear. In this study, we have reported computational (∼14.

Effect of Differential Geminal Substitution of γ Amino Acid Residues at the ( + 2) Position of αγ Turn Segments on the Conformation of Template β-Hairpin Peptides.

The effect of insertion of three geminally dimethyl substituted γ amino acid residues [γ (4-amino-2,2-dimethylbutanoic acid), γ (4-amino-3,3-dimethylbutanoic acid), and γ (4-amino-4,4-dimethylbutanoic acid)] at the ( + 2) position of a two-residue αγ C turn segment in a model octapeptide sequence Leu-Phe-Val-Aib-Xxx-Leu-Phe-Val (where Xxx = γ amino acid residues) has been investigated in this study. Solution conformational studies (NMR, CD, and IR) and ab initio calculations indicated that γ and γ residues were well accommodated in the β-hairpin nucleating αγ C turns, which gave rise to well-registered hairpins, in contrast to γ, which was unable to form a tight C β-hairpin nucleating turn and promote a well-registered β-hairpin. Geminal disubstitution at the C carbon in γ led to unfavorable steric contacts, disabling its accommodation in the αγ C hairpin nucleating turn unlike the γ and γ residues.

Venetoclax: a promising repurposed drug against SARS-CoV-2 main protease.

Global health care emergency caused by a new coronavirus (severe acute respiratory syndrome coronavirus 2 or SARS-CoV-2) demands urgent need to repurpose the approved pharmaceutical drugs. Main protease, M of SARS-CoV-2 draws significant attention as a drug target. Herein, we have screened FDA approved organosulfur drugs (till 2016) and our laboratory synthesized organosulfur and organoselenium compounds (L1-L306) against M-apo using docking followed by classical MD simulations.

Triazole based isatin derivatives as potential inhibitor of key cancer promoting kinases- insight from electronic structure, docking and molecular dynamics simulations.

Computer Aided Drug Design approaches have been applied to predict potential inhibitors for two different kinases, namely, cyclin-dependent kinase 2 (CDK2) and Epidermal Growth Factor Receptor (EGFR) which are known to play crucial role in cancer growth. We have designed alkyl and aryl substituted isatin-triazole ligands and performed molecular docking to rank and predict possible binding pockets in CDK2 and EGFR kinases. Best-scoring ligands in the kinase-binding pocket were selected from the docking study and subjected to molecular dynamics simulation.

A graph theoretic model to understand the behavioral difference of PPCA among its paralogs towards recognition of DXCA.

Among all the proteins of Periplasmic C type Cytochrome family obtained from cytochrome found in , only the Periplasmic C type Cytochrome A (PPCA) protein can recognize the deoxycholate (DXCA), while its other paralogs do not, as observed from the crystal structures. Though some existing works have used graph-theoretic approaches to realize the 3-D structural properties of proteins, its usage in the rationalisation of the physiochemical behavior of proteins has been very limited. To understand the driving force towards the recognition of DXCA exclusively by PPCA among its paralogs, in this work, we propose two graph theoretic models based on the combinatorial properties, namely, and , of the nucleotide bases and the amino acid residues, respectively.

Quinine-Based Semisynthetic Ion Transporters with Potential Antiproliferative Activities.

Synthetic ion transporters have attracted tremendous attention for their therapeutic potential against various ion-transport-related diseases, including cancer. Inspired by the structure and biological activities of natural products, we synthesized a small series of squaramide and thiourea derivatives of quinine and investigated their ion transport activities. The involvement of a quinuclidine moiety for the cooperative interactions of Cl and H ions with the thiourea or squaramide moiety resulted in an effectual transport of these ions across membranes.

Rationally designed antimicrobial peptides: Insight into the mechanism of eleven residue peptides against microbial infections.

The widespread abuse of antibiotics has led to the use of antimicrobial peptides (AMPs) as a replacement for the existing conventional therapeutic agents for combating microbial infections. The broad-spectrum activity and the resilient nature of AMPs has mainly aggrandized their utilization. Here, we report the design of non-toxic, non-hemolytic and salt tolerant undecapeptides (AMP21-24), derived by modification of a peptide P5 (NH2-LRWLRRLCONH) reported earlier by our group.

Dicyclohexylurea derivatives of amino acids as dye absorbent organogels and anion sensors.

Dicyclohexyl urea (DCU) derivatives of amino acids Fmoc-Phe-DCU (M1), Fmoc-Phg-DCU (M2) and Fmoc-Gaba-DCU (M3) have been shown to form phase selective, thermoreversible and mechanically robust gels in a large range of organic solvents. This is the first report of low molecular weight gelators (LMWG) from DCU derivatives of amino acids. The self-assembly mechanism of the organogels has been probed using concentration dependent 1H NMR, DMSO titration 1H NMR, fluorescence, FTIR, PXRD and FESEM techniques.

Insights into the Mechanism of Antimicrobial Activity of Seven-Residue Peptides.

Antimicrobial peptides have gained widespread attention as an alternative to the conventional antibiotics for combating microbial infections. Here, we report a detailed structure-function correlation of two nontoxic, nonhemolytic, and salt-tolerant de novo designed seven-residue leucine-lysine-based peptides, NHLKWLKKLCONH (P4) and NHLRWLRRLCONH (P5), with strong antimicrobial and antifungal activity. Biological experiments, low- and high-resolution spectroscopic techniques in conjunction with molecular dynamics simulation studies, could establish the structure-function correlation.

Computational design of model scaffold for anion recognition based on the 'C NN' motif.

The 'novel phosphate binding 'C NN' motif', consisting of three consecutive amino acid residues, usually occurs in the protein loop regions preceding a helix. Recent computational and complementary biophysical experiments on a series of chimeric peptides containing the naturally occurring 'C NN' motif at the N-terminus of a designed helix establishes that the motif segment recognizes the anion (sulfate and phosphate ions) through local interaction along with extension of the helical conformation which is thermodynamically favored even in a context-free, nonproteinaceous isolated system. However, the strength of the interaction depends on the amino acid sequence/conformation of the motif.