https://www.selleckchem.com/products/icrt14.html Microketides A and B (1 and 2), a pair of new C-11 epimeric polyketides, were obtained from the gorgonian-derived fungus Microsphaeropsis sp. RA10-14 collected from the South China Sea. The absolute configurations of 1 and 2 were assigned by the modified Mosher's method, TDDFT-ECD, and NMR calculations. Compounds 1 and 2 were evaluated for antibacterial, antifungal, and growth inhibition of marine phytoplankton activities. Microketide A (1) exhibited promising inhibitory activity against Pseudomonas aeruginosa, Nocardia brasiliensis, Kocuria rhizophila, and Bacillus anthraci with the same MIC value as ciprofloxacin (0.19 μg/mL).Molecular mechanics force fields have been shown to differ in their predictions of biomolecular processes such as protein folding. To test how force field differences affect predicted polypeptide behavior, we created a mechanically perturbed model of the β-stranded I91 titin domain with the A-strand detached from the fold based on atomic force spectroscopy data and examined its refolding behavior using six different force fields. We found that different force fields varied significantly in their ability to refold the mechanically perturbed I91 domain. Examination of the perturbed I91 unfolded state revealed that all five Amber force fields over-sample a specific region of the Ramachandran plot thereby creating unfolded state intermediates which are not predicted by the Charmm 22* force field. Simulations of perturbed I91 refolding with Amber FB15 revealed that Amber FB15 destabilizes stable portions of I91 thereby contradicting experimental stability analyses. Finally, inspection of the perturbed I91 unfolded state along with equilibration simulations of the Ac-(AAQAA)3-NH2 peptide suggest that high dihedral torsional barriers cause the Amber ff14SB force field to predict higher helical lifetimes relative to other force fields. These results suggest that using mechanically perturbed models can