To optimize the antitumor activity of oncrasin-1, a small molecule RNA polymerase II inhibitor, we evaluated 69 oncrasin-1 analogues for their cytotoxic activity against normal human epithelial cells and K-Ras mutant tumor cells. About 40 of those compounds were as potent as or more potent than oncrasin-1 in tumor cells and had a minimal cytotoxic effect on normal cells. Structure-activity relationship analysis revealed that most of the active compounds contained either a hydroxymethyl group or an aldehyde group as a substitute at the 3-position of the indole. Both electron-donating and electron-withdrawing groups in the benzene ring were well tolerated. The hydroxymethyl compounds ranged from equipotent with to 100 times as potent as the corresponding aldehyde compounds. We tested three active analogues' effect on RNA polymerase phosphorylation and found that they all inhibited phosphorylation of the C-terminal domain of RNA polymerase II, suggesting that the active compounds might act through the same mechanisms as oncrasin-1.
To optimize the antitumor activity of n class="Chemical">oncrasin-1, a small molecule RNA polymerase II inhibitor, we evaluated 69 oncrasin-1 analogues for their cytotoxic activity against normal human epithelial cells and K-Ras mutant tumor cells. About 40 of those compounds were as potent as or more potent than oncrasin-1 in tumor cells and had a minimal cytotoxic effect on normal cells. Structure-activity relationship analysis revealed that most of the active compounds contained either a hydroxymethyl group or an aldehyde group as a substitute at the 3-position of the indole. Both electron-donating and electron-withdrawing groups in the benzene ring were well tolerated. The hydroxymethyl compounds ranged from equipotent with to 100 times as potent as the corresponding aldehyde compounds. We tested three active analogues' effect on RNA polymerase phosphorylation and found that they all inhibited phosphorylation of the C-terminal domain of RNA polymerase II, suggesting that the active compounds might act through the same mechanisms as oncrasin-1.
Authors: S Larochelle; J Chen; R Knights; J Pandur; P Morcillo; H Erdjument-Bromage; P Tempst; B Suter; R P Fisher Journal: EMBO J Date: 2001-07-16 Impact factor: 11.598
Authors: Sylvie Wittmann; Purva Bali; Sreenivasa Donapaty; Ramadevi Nimmanapalli; Fei Guo; Hirohito Yamaguchi; Mei Huang; Richard Jove; Hong Gang Wang; Kapil Bhalla Journal: Cancer Res Date: 2003-01-01 Impact factor: 12.701
Authors: Xiaoying Liu; Wei Guo; Shuhong Wu; Li Wang; Ji Wang; Bingbing Dai; Edward S Kim; John V Heymach; Michael Wang; Luc Girard; John Minna; Jack A Roth; Stephen G Swisher; Bingliang Fang Journal: Biochem Pharmacol Date: 2012-02-22 Impact factor: 5.858
Authors: Shuhong Wu; Li Wang; Xiao Huang; Mengru Cao; Jing Hu; Hongyu Li; Hui Zhang; Xiaoping Sun; Qing H Meng; Wayne L Hofstetter; Jack A Roth; Stephen G Swisher; Bingliang Fang Journal: Bioorg Med Chem Date: 2014-08-14 Impact factor: 3.641
Authors: Xiao Huang; Mengru Cao; Li Wang; Shuhong Wu; Xiaoying Liu; Hongyu Li; Hui Zhang; Rui-Yu Wang; Xiaoping Sun; Caimiao Wei; Keith A Baggerly; Jack A Roth; Michael Wang; Stephen G Swisher; Bingliang Fang Journal: Oncotarget Date: 2015-01-01