Abstract
Heat shock protein 90 (Hsp90) is an ATP dependent molecular chaperone deeply involved in the complex network of cellular signaling governing some key functions, such as cell proliferation and survival, invasion and angiogenesis. Over the past years the N-terminal protein domain has been fully investigated as attractive strategy against cancer, but despite the many efforts lavished in the field, none of the N-terminal binders (termed “classical inhibitors”), currently in clinical trials, have yet successfully reached the market, because of the detrimental heat shock response (HSR) that showed to induce; thus, recently, the selective inhibition of Hsp90 C-terminal domain has powerfully emerged as a more promising alternative strategy for anti-cancer therapy, not eliciting this cell rescue cascade. However, the structural complexity of the target protein and, mostly, the lack of a co-crystal structure of C-terminal domain-ligand, essential to drive the identification of new hits, represent the largest hurdles in the development of new selective C-terminal inhibitors. Continuing our investigations on the identification of new anticancer drug candidates, by using an orthogonal screening approach, here we describe two new potent C-terminal inhibitors able to induce cancer cell death and a considerable down-regulation of Hsp90 client oncoproteins, without triggering the undesired heat shock response.
Highlights
Heat shock proteins (Hsps), Hsp[27], Hsp[70] and Hsp[90] are powerful anti-apoptotic proteins involved in vital mechanisms of cancerous cells, such as proliferation, differentiation, metastasis and invasiveness[1,2]
Despite the above-mentioned difficulties and the lack of a convincing grasp regarding the exact structural requirements for C-terminal domain interactions, recently we reported the identification of new potent dihydropyrimidinone based Hsp[90] inhibitors that target the C-terminal binding pocket[25,26,27,28]
In order to continue our research program aimed at expanding the number of Hsp[90] C- terminal inhibitors, we decided to utilize the surface plasmon resonance (SPR)[25,26,27,28,29] assay for screening a collection of low molecular weight synthetically accessible compounds, selected in order to explore the chemical space encoded by different scaffolds
Summary
Stefania Terracciano[1], Alessandra Russo[1], Maria G. Over the past years the N-terminal protein domain has been fully investigated as attractive strategy against cancer, but despite the many efforts lavished in the field, none of the N-terminal binders (termed “classical inhibitors”), currently in clinical trials, have yet successfully reached the market, because of the detrimental heat shock response (HSR) that showed to induce; recently, the selective inhibition of Hsp[90] C-terminal domain has powerfully emerged as a more promising alternative strategy for anti-cancer therapy, not eliciting this cell rescue cascade. Despite the many progress made in the discovery and development of Hsp[90] inhibitors, and the presence of several N-terminal binders (termed “classical inhibitors”) currently in clinical trials in several tumor types, none of these molecules have yet successfully reached the market[8,9,10,11,12] It represents a challenging target for structural analysis. Despite the above-mentioned difficulties and the lack of a convincing grasp regarding the exact structural requirements for C-terminal domain interactions, recently we reported the identification of new potent dihydropyrimidinone based Hsp[90] inhibitors that target the C-terminal binding pocket[25,26,27,28]
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