François Dufrasne scite author profile

A large proportion of cancer patients fail to respond to conventional chemotherapy because of the intrinsic resistance of their cancer to pro-apoptotic stimuli and/or the acquisition of a multidrug resistant (MDR) phenotype during chronic chemotherapy. A new angle in chemotherapeutics against these cancer types associated with dismal prognoses would be the targeting of specific ion channels and pumps over expressed by cancer cells as compared to normal cells. Several reports suggest that the alpha subunits of the Na(+)/K(+)-ATPase (referred as sodium pump from now on) could be such targets, using cardiotonic steroids (CS) including cardenolides and bufadienolides. A significant proportion of non-small-cell-lung cancers (NSCLCs), glioblastomas (GBMs), melanomas and kidney cancers overexpresses the alpha-1 subunit of the sodium pump as compared to corresponding normal tissues, while colon cancers overexpress the alpha-3 subunit. Thus, a deeper knowledge of the structure-activity relationship (SAR), in terms of CS-mediated anticancer effects, to the sodium pump alpha subunits might enable the identification of potent anticancer agents with limited cardiotoxicity. The current review provides an in depth SAR analysis with respect to cardenolide- versus bufadienolide-mediated anticancer effects. Moreover, pharmacological data from in vitro and in vivo experiments, as well as pre-clinical and clinical trials regarding cardenolides to combat cancers associated with dismal prognoses are presented.

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Natural Polyphenols that Display Anticancer Properties through Inhibition of Kinase Activity

Lamoral-Theys¹,

Pottier

Dufrasne³

et al. 2010

CMC

120

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Over eleven hundred publications reporting anticancer activities of polyphenols have appeared in the peerreviewed literature. In addition, a search of the PubMed database using "polyphenols -cancer -review" as keywords produced over 320 hits for review articles (July 2009). Polyphenol anticancer activities include, among others, anti-oxidative, pro-apoptotic, DNA damaging, anti-angiogenic, and immunostimulatory effects. Targeting specific protein kinases to combat cancer represents a major focus of oncology research within the so-called targeted therapy approach. An exhaustive search of the PubMed database (July 2009) using "polyphenols -cancer -kinases" as keywords resulted in more than 130 hits, half of them having been published within the past five years. Furthermore, the PubMed database contains 25 reviews on the subject of anti-kinase activity of some specific polyphenols, including mainly curcumin and the green tea polyphenol (-)-epigallocatechin 3-gallate (EGCG). However, no attempt has been made yet to review this area of research in a comprehensive, general manner. The current review therefore aims to highlight those anticancer polyphenols that target specific kinases in various types of cancer. The present review also provides an in-depth analysis of polyphenol structure-activity relationships in relation to their anticancer activities and specific kinase targeting. Lastly, a number of polyphenols are identified as potential antitumor agents that could be used to combat biologically aggressive cancers, including metastasizing cancers, through the targeting of specific kinases.

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On the Clinical Pharmacology of Reactive Oxygen Species

et al. 2020

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A survey of the mechanisms of action of anticancer transition metal complexes

Marloye

Berger

Gelbcke

et al. 2016

Future Medicinal Chemistry

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Metal complexes have been the subject of numerous investigations in oncology but, despite the plethora of newly synthesized compounds, their precise mechanisms of action remain generally unknown or, for the best, incompletely determined. The continuous development of efficient and sensitive techniques in analytical chemistry and molecular biology gives scientists new tools to gather information on how metal complexes can be effective toward cancer. This review focuses on recent findings about the anticancer mechanism of action of metal complexes and how the ligands can be used to tune their pharmacological and physicochemical properties.

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Na⁺/K⁺-ATPase and cancer

Mijatovic

Dufrasne

Kiss

2012

Pharmaceutical Patent Analyst

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The sodium pump, Na(+)/K(+)-ATPase, could be an important target for the development of anticancer drugs as it serves as a versatile signal transducer, plays a key role in cell adhesion and has abnormal expression and activity that are implicated in the development and progression of different cancers. Several publications have reported differing expression of Na(+)/K(+)-ATPase α- and β-subunits in malignant tissues compared with their normal tissue counterparts, thus offering a powerful diagnostic tool. A growing number of patent applications claim the invention or discovery of Na(+)/K(+)-ATPase inhibitors (e.g., cardiac glycosides) to be used to effectively treat certain cancers that are refractory to conventional chemotherapy or radiotherapy. The aims of this review are to provide an overview of the most significant patents that highlight Na(+)/K(+)-ATPase as a valuable target in anticancer therapy and which report on novel Na(+)/K(+)-ATPase inhibitors and ligands designed as potential anticancer agents.

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Myeloperoxidase as a Target for the Treatment of Inflammatory Syndromes: Mechanisms and Structure Activity Relationships of Inhibitors

Soubhye

Aldib²,

Delporte³

et al. 2016

CMC

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Inflammation is an initial response of the body to a harmful stimuli and it is achieved by the increased movement of leukocytes (especially granulocytes) from blood into injured tissues. It is required for healing wounds and infections. Despite their indispensable role in microbial killing, the inflammation reactions may also cause diseases to a host such as hay fever, atherosclerosis, and rheumatoid arthritis. The enzymes and oxidizing species released during the inflammatory process can cause damages to the host tissues which lead to inflammatory syndromes. The role of myeloperoxidase (MPO) in the inflammatory reactions is well documented. It contributes in killing the pathogens but it is also implicated in several inflammatory syndromes such as Parkinson's disease, Alzheimer's disease and atherosclerosis. Thus, this enzyme has attracted more attention of the scientists and it has become a target for drug designing. In the last decade, several reversible and irreversible MPO inhibitors were identified as very high potent inhibitors such as fluoroalkylindole, aromatic hydroxamic acid, thioxanthine and benzoic acid hydrazide derivatives. In this review, we tried to illustrate the MPO inhibitors and highlight their structure activity relationship (SAR). In this paper we also discussed the mechanism of the inhibitory effect of the most potent compounds.

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Simple di- and trivanillates exhibit cytostatic properties toward cancer cells resistant to pro-apoptotic stimuli

Lamoral-Theys

Pottier

Kerff

et al. 2010

Bioorganic & Medicinal Chemistry

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A series of 33 novel divanillates and trivanillates were synthesized and found to possess promising cyto-static rather than cytotoxic properties. Several compounds under study decreased by >50% the activity of Aurora A, B, and C, and WEE1 kinase activity at concentrations <10% of their IC50 growth inhibitory ones, accounting, at least partly, for their cytostatic effects in cancer cells and to a lesser extent in normal cells. Compounds 6b and 13c represent interesting starting points for the development of cytostatic agents to combat cancers, which are naturally resistant to pro-apoptotic stimuli, including metastatic malignancies.

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Quinone Methides and their Prodrugs: A Subtle Equilibrium Between Cancer Promotion, Prevention, and Cure

Dufrasne¹,

Gelbcke²,

Nève³

et al. 2011

CMC

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Abstract:The importance of reactive drug metabolites in the pathogenesis of drug-induced toxicity has been investigated since the early 1950s, mainly to reveal the link between toxic metabolites and chemical carcinogenesis. This review mainly focuses on biologically active compounds, which generate reactive quinone methide (QM) intermediates either directly or after bioactivation. Several examples of anticancer drugs acting through the generation of QM electrophiles are given. The use of those drugs for chemotherapeutic purposes is also discussed. The key feature of those QM-generating drugs is their reactivity toward specific nucleophilic biological targets. Modulation of their reactivity represents a challenge for medicinal chemists because, depending on the reactivity of these QM intermediates, their interaction with critical proteins can alter the function of these key proteins and induce a wide variety of responses with functional consequences. Among the possible consequences, antiproliferative effects could be exploited for chemotherapeutic purposes. Information on how such QM-generating drugs can affect individual target proteins and their functional consequences are required to help the medicinal chemist in the design of more specific QM-generating molecules for chemotherapeutic use.

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