710350-64-4Relevant academic research and scientific papers
Experimental study and computational modelling of cruzain cysteine protease inhibition by dipeptidyl nitriles
Dos Santos, Alberto Monteiro,Cianni, Lorenzo,De Vita, Daniela,Rosini, Fabiana,Leit?o, Andrei,Laughton, Charles A.,Lameira, Jer?nimo,Montanari, Carlos A.
, p. 24317 - 24328 (2018/10/05)
Chagas disease affects millions of people in Latin America. This disease is caused by the protozoan parasite Trypanossoma cruzi. The cysteine protease cruzain is a key enzyme for the survival and propagation of this parasite lifecycle. Nitrile-based inhib
Influence of azide incorporation on binding affinity by small papain inhibitors
Wammes, Angelique E.M.,Hendriks, Tom G.,Amatdjais-Groenen, Helene I.V.,Wijdeven, Marloes A.,Van Hest, Jan C.M.,Van Delft, Floris L.,Ritschel, Tina,Rutjes, Floris P.J.T.
, p. 5593 - 5603 (2015/01/09)
In order to develop affinity-based biosensor platforms, appropriate ligands with a functional handle for immobilization onto a biosensor surface are required. To this end, a library of papain inhibitors was designed and synthesized, containing different a
Nitrile-containing enzyme inhibitors and ruthenium complexes thereof
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Paragraph 0151; 0153, (2014/04/18)
The invention provides nitrile-containing protease inhibitors caged to ruthenium compounds. The nitrile-caged ruthenium compounds provide inactivated inhibitors that can be delivered to surface or site for activation, for example, but exposure to light. The invention also provides methods for delivering protease inhibitors to subjects for the therapeutic treatment of conditions such as cancer.
Interaction of papain-like cysteine proteases with dipeptide-derived nitriles
L?ser, Reik,Schilling, Klaus,Dimmig, Elke,Gütschow, Michael
, p. 7688 - 7707 (2007/10/03)
A series of 44 dipeptide nitriles with various amino acids at the P 2 position and glycine nitrile at position P1 were prepared and evaluated as inhibitors of cysteine proteinases. With respect to the important contribution of the P2-S2 interaction to the formation of enzyme-inhibitor complexes, it was focused to introduce structural diversity into the P2 side chain. Nonproteinogenic amino acids were introduced, and systematic fluorine, bromine, and phenyl scans for phenylalanine in the P2 position were performed. Moreover, the N-terminal protection was varied. Kinetic investigations were carried out with cathepsin L, S, and K as well as papain. Changes in the backbone structure of the parent N-(tert-butoxycarbonyl)-phenylalanyl-glycine-nitrile (16), such as the introduction of an R-configured amino acid or an azaamino acid into P 2 as well as methylation of the P1 nitrogen, resulted in a drastic loss of affinity. Exemplarily, the cyano group of 16 was replaced by an aldehyde or methyl ketone function. Structure-activity relationships were discussed with respect to the substrate specificity of the target enzymes.
PROTEASE INHIBITORS
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Page/Page column 28, (2010/02/09)
A peptidyl nitrile of the general formula (I) or a pharmaceutically acceptable salt or prodrug thereof, is capable of selectively inhibiting dipeptidyl-peptidase I (DPP-I), also known as cathepsin C. A compound of the invention is useful as an active subs
Identification of dipeptidyl nitriles as potent and selective inhibitors of cathepsin B through structure-based drug design
Greenspan,Clark,Tommasi,Cowen,McQuire,Farley,Van Duzer,Goldberg,Zhou,Du,Fitt,Coppa,Fang,Macchia,Zhu,Capparelli,Goldstein,Wigg,Doughty,Bohacek,Knap
, p. 4524 - 4534 (2007/10/03)
Cathepsin B is a member of the papain superfamily of cysteine proteases and has been implicated in the pathology of numerous diseases, including arthritis and cancer. As part of an effort to identify potent, reversible inhibitors of this protease, we examined a series of dipeptidyl nitriles, starting with the previously reported Cbz-Phe-NH-CH2CN (19, IC50 = 62 μM). High-resolution X-ray crystallographic data and molecular modeling were used to optimize the P1, P2, and P3 substituents of this template. Cathepsin B is unique in its class in that it contains a carboxylate recognition site in the S2′ pocket of the active site. Inhibitor potency and selectivity were enhanced by tethering a carboxylate functionality from the carbon α to the nitrile to interact with this region of the enzyme. This resulted in the identification of compound 10, a 7 nM inhibitor of cathepsin B, with excellent selectivity over other cysteine cathepsins.
