Perturbing dissimilar biomolecular targets from natural product scaffolds and focused chemical decoration.
Research output: Contribution to conference › Poster › Research › peer-review
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Perturbing dissimilar biomolecular targets from natural product scaffolds and focused chemical decoration. / Nielsen, John; Tung, Truong Thanh; Tim, Holm Jakobsen; Trong Tuan, Dao; Anja T., Fuglsang; Michael, Givskov; Christensen, Søren Brøgger.
2017. Poster session presented at 253rd American Chemical Society National Meeting & Exposition.Research output: Contribution to conference › Poster › Research › peer-review
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T1 - Perturbing dissimilar biomolecular targets from natural product scaffolds and focused chemical decoration.
AU - Nielsen, John
AU - Tung, Truong Thanh
AU - Tim, Holm Jakobsen
AU - Trong Tuan, Dao
AU - Anja T., Fuglsang
AU - Michael, Givskov
AU - Christensen, Søren Brøgger
PY - 2017/4/2
Y1 - 2017/4/2
N2 - Fungal plasma membrane H+-ATPase (Pma1) has recently emerged as a potential target for the discovery of new antifungal agents. This p-type pump plays a pivotal role in many physiol. functions and processes inside the cell. Therefore, inhibition of Pma1 could lead to discovery of new antifungal agents. On first attempt, by screening natural product sources we have successfully discovered that curcuminoids as potent inhibitors of p-type ATPases from diverse kingdoms of life including Pma1. On other attempt, the fungal metabolite fusaric acid was reported to reduce stomatal conductance in banana plants infected by Fursarium spp. suggesting that the agent might stimulate the H+-ATPase. The possibilities that fusaric acid could affect the H+-ATPase inspired us to design and synthesize a focused library of structural analogs. However, a no. of bioassays revealed no significant effect on the plasma membrane proton pump. To our delight, we took notice of the structure of fusaric acid being homologous to the gram-neg. quorum sensing (QS) signal mols. and to some reported quorum sensing inhibitors (QSI). This encouraged us to test the QS inhibitory activity of the fusaric acid library in three cell-based biol. screens. Consequently, we identified several compds. showing good QSI activity and a structure-activity relationship has been established. Herein, we present our story from natural product scaffolds to macromol. biol. target via focused chem. synthesis. [on SciFinder(R)]
AB - Fungal plasma membrane H+-ATPase (Pma1) has recently emerged as a potential target for the discovery of new antifungal agents. This p-type pump plays a pivotal role in many physiol. functions and processes inside the cell. Therefore, inhibition of Pma1 could lead to discovery of new antifungal agents. On first attempt, by screening natural product sources we have successfully discovered that curcuminoids as potent inhibitors of p-type ATPases from diverse kingdoms of life including Pma1. On other attempt, the fungal metabolite fusaric acid was reported to reduce stomatal conductance in banana plants infected by Fursarium spp. suggesting that the agent might stimulate the H+-ATPase. The possibilities that fusaric acid could affect the H+-ATPase inspired us to design and synthesize a focused library of structural analogs. However, a no. of bioassays revealed no significant effect on the plasma membrane proton pump. To our delight, we took notice of the structure of fusaric acid being homologous to the gram-neg. quorum sensing (QS) signal mols. and to some reported quorum sensing inhibitors (QSI). This encouraged us to test the QS inhibitory activity of the fusaric acid library in three cell-based biol. screens. Consequently, we identified several compds. showing good QSI activity and a structure-activity relationship has been established. Herein, we present our story from natural product scaffolds to macromol. biol. target via focused chem. synthesis. [on SciFinder(R)]
M3 - Poster
T2 - 253rd American Chemical Society National Meeting & Exposition
Y2 - 2 April 2017 through 6 April 2017
ER -
ID: 181172194