Abstract
In this work, we present the synthesis and biological evaluation of novel series of diamide-based benzenesulfonamides 5a–h as inhibitors of the metalloenzyme carbonic anhydrase (CA, EC 4.2.1.1) isoforms hCA I, II, IX and XII. The target tumor-associated isoforms hCA IX and XII were undeniably the most affected ones (KIs: 8.3–123.3 and 9.8–134.5 nM, respectively). Notably, diamides 5a and 5h stood out as a single-digit nanomolar hCA IX inhibitors (KIs = 8.8 and 8.3 nM). The SAR outcomes highlighted that bioisosteric replacement of the benzylidene moiety, compounds 5a–g, with the hetero 2-furylidene moiety, compound 5h, achieved the best IX/I and IX/II selectivity herein reported with SIs of 985 and 13.8, respectively. Molecular docking simulations of the prepared diamides within CA IX active site revealed the ability of 5h to establish an additional H-bond between the heterocyclic oxygen and HE/Gln67. Moreover, benzenesulfonamides 5a, 5b and 5h were evaluated for their antitumor activity against renal cancer UO-31 cell line. Compound 5h was the most potent derivative with about 1.5-fold more enhanced activity (IC50 = 4.89 ± 0.22 μM) than the reference drug Staurosporine (IC50 = 7.25 ± 0.43 μM). Moreover, 5a and 5h were able to induce apoptosis in UO-31 cells as evidenced by the significant increase in the percent of annexinV-FITC positive apoptotic cells by 22.5- and 26.5-folds, respectively.
Highlights
Carbonic anhydrases (CA) are zinc metalloenzymes that play a pivotal role in mmost lliivving organniissmmss ccaattaallyyzziinnggththeeinintetercroconnvveresrisoionnofocfacrabrobnondidoixoidxiedaenadnwd awteartetor btoicbaricbaornbaotneaatnedanpdroptornosto[n1]s
It is worth highlighting that bioisosteric replacement of the benzylidene moiety with the hetero 2-furylidene moiety, compound 5h, achieved the best IX/I and IX/II selectivity reported with SIs of 985 and 13.8, respectively
This study reports the synthesis of novel series of diamide-based benzenesulfonamides 5a–h
Summary
Carbonic anhydrases (CA) are zinc metalloenzymes that play a pivotal role in mmost lliivving organniissmmss ccaattaallyyzziinnggththeeinintetercroconnvveresrisoionnofocfacrabrobnondidoixoidxiedaenadnwd awteartetor btoicbaricbaornbaotneaatnedanpdroptornosto[n1]s. IaMteodreboyvecr,oothrde isnualtfioonnamofidietsmdoeipertyoteonngaategdesfotwrmo H(S-Obo2NndHs-:) thtoe NthHe– gproosuitpivaecltys acshdaorgneodr, wZhni(lIeI)theioSn=Ofroams actcheeptoernwzyimtheT1a9c9tiOveG1siatteo.mMaonrdeobvacekr,botnhee NsuHlfornesapmeicdtievmeloy.ieTtyheesnegbaignedsintwgofeHat-ubroensdasr:ethcoemNmHo- ngraomuponagcttshaesadctoinvoers,iwtehairlechtihteecStu=Oresasfoarcacellptthoer αw-ictlhasTs1fi9f9teOeGn 1huatmomanainsodzbyamckesb.one NH respectively. These binding features are common among the active site architectures for all the α-class fifteen human isozymes. Pursuing on our effort towards development of selective hCA IX inhibitors [10,11,12,13], we present the synthesis, and biological evaluation of novel series of diamide-based benzenesulfonamides 5a–h. The reported diamides possess a zinc anchoring moiety of the benzenesulfonamide type that was linked to benzylidene tails incorporating halogen, methyl or methoxy substituents to ensure suited SAR exploration regarding the hydrophobic region of the binding cleft.
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