Christian Bailly scite author profile

Antibodies and related products are the fastest growing class of therapeutic agents. By analysing the regulatory approvals of IgG-based biotherapeutic agents in the past 10 years, we can gain insights into the successful strategies used by pharmaceutical companies so far to bring innovative drugs to the market. Many challenges will have to be faced in the next decade to bring more efficient and affordable antibody-based drugs to the clinic. Here, we discuss strategies to select the best therapeutic antigen targets, to optimize the structure of IgG antibodies and to design related or new structures with additional functions.

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DNA Sequence- and Structure-Selective Alkylation of Guanine N2 in the DNA Minor Groove by Ecteinascidin 743, a Potent Antitumor Compound from the Caribbean Tunicate Ecteinascidia turbinata

Pommier

et al. 1996

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Ecteinascidin 743 is one of several related marine alkaloids isolated from the Caribbean tunicate Ecteinascidia turbinata. It is remarkably active and potent in a variety of in vitro and in vivo systems and has been selected for development as an anticancer agent. The present study investigates the interactions of ecteinascidin 743 with DNA. Ecteinascidin 743 retarded the electrophoretic migration of both supercoiled and relaxed simian virus 40 DNA even in the presence of sodium dodecyl sulfate and after ethanol precipitation, consistent with covalent DNA modifications. Similar results were obtained in a DNA oligonucleotide derived from ribosomal DNA. However, DNA denaturation reversed the DNA modifications. The homopolymeric oligonucleotide dG/dC was modified while neither the dI/dC nor the dA/dT oligonucleotides were, consistent with covalent attachment of ecteinascidin 743 to the exocyclic amino group at position 2 of guanine. Ecteinascidin 743 was then compared to another known DNA minor groove alkylating agent, anthramycin, which has also been shown to alkylate guanine N2. Footprinting analyses with DNase I and 1,10-phenanthroline-copper and exonuclease III digestions showed that ecteinascidin 743 covers three to five bases of DNA and exhibits a different sequence specificity than anthramycin in the Escherichia coli tyrosine tRNA promoter (tyrT DNA). The binding of ecteinascidin to DNA was abolished when guanines were substituted with inosines in this promoter. A band shift assay was designed to evaluate the influence of the bases flanking a centrally located guanine in an oligonucleotide containing inosines in place of guanines elsewhere. Ecteinascidin 743 and anthramycin showed similarities as well as differences in sequence selectivity. Ecteinascidin 743-guanine adducts appeared to require at least one flanking guanine and were strongest when the flanking guanine was 3' to the targeted guanine. These data indicate that ecteinascidin 743 is a novel DNA minor groove, guanine-specific alkylating agent.

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Contemporary Challenges in the Design of Topoisomerase II Inhibitors for Cancer Chemotherapy

2012

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Sequence-Specific DNA Minor Groove Binders. Design and Synthesis of Netropsin and Distamycin Analogues

1998

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Glycyrrhizin: An alternative drug for the treatment of COVID-19 infection and the associated respiratory syndrome?

Bailly

Vergoten

2020

Pharmacology & Therapeutics

227

183

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Safe and efficient drugs to combat the current COVID-19 pandemic are urgently needed. In this context, we have analyzed the anti-coronavirus potential of the natural product glycyrrhizic acid (GLR), a drug used to treat liver diseases (including viral hepatitis) and specific cutaneous inflammation (such as atopic dermatitis) in some countries. The properties of GLR and its primary active metabolite glycyrrhetinic acid are presented and discussed. GLR has shown activities against different viruses, including SARS-associated Human and animal coronaviruses. GLR is a non-hemolytic saponin and a potent immuno-active anti-inflammatory agent which displays both cytoplasmic and membrane effects. At the membrane level, GLR induces cholesterol-dependent disorganization of lipid rafts which are important for the entry of coronavirus into cells. At the intracellular and circulating levels, GLR can trap the high mobility group box 1 protein and thus blocks the alarmin functions of HMGB1. We used molecular docking to characterize further and discuss both the cholesterol-and HMG boxbinding functions of GLR. The membrane and cytoplasmic effects of GLR, coupled with its long-established medical use as a relatively safe drug, make GLR a good candidate to be tested against the SARS-CoV-2 coronavirus, alone and in combination with other drugs. The rational supporting combinations with (hydroxy)chloroquine and tenofovir (two drugs active against SARS-CoV-2) is also discussed. Based on this analysis, we conclude that GLR should be further considered and rapidly evaluated for the treatment of patients with COVID-19.

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Topoisomerase I Poisons and Suppressors as Anticancer Drugs

Bailly

2000

CMC

255

166

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Inhibitors of topoisomerase I constitute a novel family of antitumor agents. The camptothecin derivatives topotecan and irinotecan represent new weapons in our arsenal for battling human cancer. These two drugs act specifically at the level of the topoisomerase I-DNA complex and stimulate DNA cleavage. This mechanism of action is not restricted to the camptothecins. Numerous topoisomerase I poisons including DNA minor groove binders such as Hoechst 33258 and DNA intercalators such as benzophenanthridine alkaloids and indolocarbazole derivatives have been discovered and developed. Another important group of topoisomerase I inhibitors contains drugs which prevent or reverse topoisomerase I-DNA complex formation. Many of these topoisomerase I suppressors are natural products (beta-lapachone, diospyrin, topostatin, topostin, flavonoids) which are believed to interact directly with the enzyme. This review is concerned with the different families of topoisomerase I poisons and suppressors. Their origin, chemical nature and mechanism of action are presented. The relationships between drug binding to DNA and topoisomerase I inhibition are discussed.

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Anti‐proliferative and apoptotic effects of anandamide in human prostatic cancer cell lines: Implication of epidermal growth factor receptor down‐regulation and ceramide production

Mimeault¹,

Pommery²,

Wattez³

et al. 2003

The Prostate

170

142

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F14512, a Potent Antitumor Agent Targeting Topoisomerase II Vectored into Cancer Cells via the Polyamine Transport System

Barret¹,

Kruczynski²,

Vispé³

et al. 2008

134

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The polyamine transport system (PTS) is an energy-dependent machinery frequently overactivated in cancer cells with a high demand for polyamines. We have exploited the PTS to selectively deliver a polyamine-containing drug to cancer cells. F14512 combines an epipodophyllotoxin core-targeting topoisomerase II with a spermine moiety introduced as a cell delivery vector. The polyamine tail supports three complementary functions: (a) facilitate formulation of a watersoluble compound, (b) increase DNA binding to reinforce topoisomerase II inhibition, and (c) facilitate selective uptake by tumor cells via the PTS. F14512 is 73-fold more cytotoxic to Chinese hamster ovary cells compared with CHO-MG cells with a reduced PTS activity. A decreased sensitivity of L1210 leukemia cells to F14512 was observed in the presence of putrescine, spermidine, and spermine. In parallel, the spermine moiety considerably enhances the drug-DNA interaction, leading to a reinforced inhibition of topoisomerase II. The spermine tail of F14512 serves as a cell delivery vehicle as well as a DNA anchor, and this property translates at the cellular level into a distinct pharmacologic profile. Twentynine human solid or hematologic cell lines were used to characterize the high cytotoxic potential of F14512 (median IC 50 of 0.18 Mmol/L). Finally, the potent antitumor activity of F14512 in vivo was evidenced with a MX1 human breast tumor xenograft model, with partial and complete tumor regressions. This work supports the clinical development of F14512 as a novel targeted cytotoxic drug and sheds light on the concept of selective delivery of drugs to tumor cells expressing the PTS. [Cancer Res 2008;68(23):9845-53]

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