Structural determinants of resveratrol for cell proliferation inhibition potency: experimental and docking studies of new analogs.

6533b82bfe1ef96bd128d963

RESEARCH PRODUCT

Structural determinants of resveratrol for cell proliferation inhibition potency: experimental and docking studies of new analogs.

Corrado Tringali Dominique Delmas Maria Wegner Jessica Gobbo Carmela Spatafora Didier J. Colin Antonio Rescifina Philippe Meunier Frédéric Mazué Dominique Fasseur Norbert Latruffe

subject

Models Molecular MESH : Hydroxides MESH : DNA MESH: Cell Cycle MESH: Tubulin Resveratrol Hydroxylation chemistry.chemical_compound 0302 clinical medicine Tubulin MESH: Stilbenes Drug Discovery Stilbenes Hydroxides MESH : Cell Proliferation Docking studies MESH : Colchicine 0303 health sciences Cell Cycle MESH: DNA Stereoisomerism General Medicine MESH : Tubulin MESH: Hydroxides 3. Good health Colon cancer Biochemistry MESH : Stereoisomerism 030220 oncology & carcinogenesis MESH: Models Molecular MESH: Cell Line Tumor Stereochemistry MESH : Models Molecular Stereoisomerism MESH : Stilbenes 03 medical and health sciences Cell Line Tumor MESH: Cell Proliferation MESH : Cell Cycle [SDV.BBM] Life Sciences [q-bio]/Biochemistry Molecular Biology Humans [SDV.BBM]Life Sciences [q-bio]/Biochemistry Molecular Biology Binding site [ SDV.BBM ] Life Sciences [q-bio]/Biochemistry Molecular Biology Tubulin polymerization 030304 developmental biology Cell Proliferation Pharmacology Combretastatin Binding Sites MESH: Humans Cell growth MESH : Cell Line Tumor Organic Chemistry MESH : Humans DNA MESH: Stereoisomerism MESH: Colchicine chemistry Polymethoxy-stilbenes MESH: Binding Sites Docking (molecular)Cell culture Resveratrol Resveratrol; Polymethoxy-stilbenes; Tubulin polymerization; Colon cancer; Docking studies Colchicine MESH : Binding Sites

description

International audience; Resveratrol is the subject of intense research because of the abundance of this compound in the human diet and as one of the most valuable natural chemopreventive agents. Further advances require new resveratrol analogs be used to identify the structural determinants of resveratrol for the inhibition potency of cell proliferation by comparing experimental and docking studies. Therefore, we synthesized new trans/(E)- and cis/(Z)-resveratrol - analogs not reported to date - by modifying the hydroxylation pattern of resveratrol and a double bond geometry. We included them in a larger panel of 14 molecules, including (Z)-3,5,4'-trimethoxystilbene, the most powerful molecule that is used as reference. Using a docking model complementary to experimental studies on the proliferation inhibition of the human colorectal tumor SW480 cell line, we show that methylation is the determinant substitution in inhibition efficacy, but only in molecules bearing a Z configuration. Most of the synthetic methylated derivatives (E or Z) stop mitosis at the M phase and lead to polyploid cells, while (E)-resveratrol inhibits cells at the S phase. Docking studies show that almost all of the docked structures of (Z)-polymethoxy isomers, but not most of the (E)-polymethoxy isomers substantially overlap the docked structure of combretastatin A-4, taken as reference ligand at the colchicine-tubulin binding site.

year	journal	country	edition	language
2010-07-01

https://hal.archives-ouvertes.fr/hal-00512371/document