(2S,2'S,5S,5'S)-3,3'-(4,4'-(ETHANE-1,2-DIYL)BIS(4,1-PHENYLENE))BIS(2-(4-METHOXYPHENYL)-5-METHYLTHIAZOLIDIN-4-ONE)


Source	Gaulton A, Kale N, van Westen GJ, Bellis LJ, Bento AP, Davies M, Hersey A, Papadatos G, Forster M, Wege P, Overington JP. A large-scale crop protection bioassay data set. Sci Data. 2015 Jul 7;2:150032. Read more ...


Active Pharmaceutical Ingredients Bioactive chemicals	Exact Similarity SubStructure	Threshold (%) >= 70

Structure


InChI Key	NZXKMBYOABFFEY-ZRERGLNCSA-N
Smiles	COc1ccc(cc1)[C@@H]2S[C@@H](C)C(=O)N2c3ccc(CCc4ccc(cc4)N5[C@@H](S[C@@H](C)C5=O)c6ccc(OC)cc6)cc3
InChI	InChI=1S/C36H36N2O4S2/c1-23-33(39)37(35(43-23)27-11-19-31(41-3)20-12-27)29-15-7-25(8-16-29)5-6-26-9-17-30(18-10-26)38-34(40)24(2)44-36(38)28-13-21-32(42-4)22-14-28/h7-24,35-36H,5-6H2,1-4H3/t23-,24-,35-,36-/m0/s1

Physicochemical Descriptors

Property Name	Value
Molecular Formula	C36H36N2O4S2
Molecular Weight	624.81
AlogP	8.01
Hydrogen Bond Acceptor	6.0
Hydrogen Bond Donor	0.0
Number of Rotational Bond	9.0
Polar Surface Area	109.68
Molecular species	NEUTRAL
Aromatic Rings	4.0
Heavy Atoms	44.0

Assay Description	Organism	Bioactivity
Growth inhibition of Penicillium citrinum at 10 ppm after 96 hr by poisoned food technique	Penicillium citrinum	45.0 %
Growth inhibition of Penicillium citrinum at 1000 ppm after 96 hr by poisoned food technique	Penicillium citrinum	88.0 %
Growth inhibition of Penicillium citrinum at 100 ppm after 96 hr by poisoned food technique	Penicillium citrinum	69.0 %
Growth inhibition of Fusarium oxysporum at 10 ppm after 96 hr by poisoned food technique	Fusarium oxysporum	41.0 %
Growth inhibition of Fusarium oxysporum at 1000 ppm after 96 hr by poisoned food technique	Fusarium oxysporum	85.0 %
Growth inhibition of Fusarium oxysporum at 100 ppm after 96 hr by poisoned food technique	Fusarium oxysporum	62.0 %

Cross References

Resources	Reference
ChEMBL	CHEMBL2268794
PubChem	11250599

CONTENTS


PREMIER has received funding from the Innovative Medicines Initiative 2 Joint Undertaking (JU) under grant agreement No 875508. The JU receives support from the EU’s Horizon 2020 research and innovation programme and the European Federation of Pharmaceutical Industries and Associations (EFPIA). The views reflect only the authors’ perspective and the JU is not responsible for any use that may be made of the information this manuscript contains. Elements of the website have been developed under projects PREMIER and the Biocenter Finland Drug Discovery and Chemical Biology network. CSC-IT is thanked for providing computational resources. Content of the website is provided without guarantee for correctness. Data has been collected and integrated from multiple public sources, for the largest: FDA, HUGO Gene Nomenclature Committee, ChEMBL, IUPHAR/BPS guide to pharmacology, Reactome, UniProt, and Ensembl. Credit is given to Ensembl for collecting species images (provided under public domain licences such as Wikimedia and NHGRI).

PREMIER has received funding from the Innovative Medicines Initiative 2 Joint Undertaking (JU) under grant agreement No 875508. The JU receives support from the EU’s Horizon 2020 research and innovation programme and the European Federation of Pharmaceutical Industries and Associations (EFPIA). The views reflect only the authors’ perspective and the JU is not responsible for any use that may be made of the information this manuscript contains.

Elements of the website have been developed under projects PREMIER and the Biocenter Finland Drug Discovery and Chemical Biology network. CSC-IT is thanked for providing computational resources. Content of the website is provided without guarantee for correctness. Data has been collected and integrated from multiple public sources, for the largest: FDA, HUGO Gene Nomenclature Committee, ChEMBL, IUPHAR/BPS guide to pharmacology, Reactome, UniProt, and Ensembl. Credit is given to Ensembl for collecting species images (provided under public domain licences such as Wikimedia and NHGRI).