Design, synthesis, biological evaluation and in silico study of N-(Pyrimidin-2-yl)alkyl/arylamide derivatives as quorum sensing inhibitors against Pseudomonas aeruginosa.

The emergence of bacterial resistance to antimicrobial agents poses a serious threat to the effectiveness of treating bacterial illnesses. A major factor contributing to antimicrobial resistance is biofilm formation, driven by quorum sensing (QS). QS suppression inhibits the QS signaling pathway, obstructing cell-to-cell communication. This study focuses on N-(pyrimidin-2-yl)alkyl/arylamide derivatives, which were designed, synthesized, and characterized for their QS inhibitory effects. Among the synthesized compounds (3a-j), compounds 3b, 3d, and 3h exhibited the highest QS inhibitory activity, with inhibition zones of 17.66 ± 6.17, 14.00 ± 6.24, and 17.33 ± 0.66 mm, respectively. Further, molecular docking studies revealed binding affinities between - 8.4 and - 6.3 kcal/mol, indicating strong interactions with the target proteins. Moreover, molecular dynamic simulations confirmed the stability of the protein-ligand complexes for compounds 3b and 3 h. Additionally, in-silico methods were employed to predict the physicochemical properties of these molecules. Overall, these findings underscore the potential of N-(pyrimidin-2-yl)alkyl/arylamide derivatives as QS inhibitors, offering a new perspective for developing alternative antimicrobial therapies.

Structural Characterization of DNA Binding Domain of Essential Mammalian Protein TTF 1.

Transcription Termination Factor 1 (TTF1) is a multifunctional mammalian protein with vital roles in various cellular processes, including Pol I-mediated transcription initiation and termination, pre-rRNA processing, chromatin remodelling, DNA damage repair, and polar replication fork arrest. It comprises of two distinct functional regions; the N-terminal regulatory region (1-445 aa), and the C-terminal catalytic region (445-859 aa). The Myb domain located at the C-terminal region is a conserved DNA binding domain spanning from 550 to 732 aa (183 residues). Despite its critical role in various cellular processes, the physical structure of TTF1 remains unsolved. Attempts to purify the functional TTF1 protein have been unsuccessful till date. Therefore, we focused on characterizing the Myb domain of this essential protein. We started with predicting a 3-D model of the Myb domain using homology modelling, and ab-initio method.  We then determined its stability through MD simulation in an explicit solvent. The model predicted is highly stable, which stabilizes at 200ns. To experimentally validate the computational model, we cloned and expressed the codon optimized Myb domain into a bacterial expression vector and purified the protein to homogeneity. Further, characterization of the protein shows that, Myb domain is predominantly helical (65%) and is alone sufficient to bind the Sal Box DNA. This is the first-ever study to report a complete in-silico model of the Myb domain, which is physically characterized. The above study will pave the way towards solving the atomic structure of this essential mammalian protein.