Novel pyridyl nitrofuranyl isoxazolines show antibacterial activity against multiple drug resistant Staphylococcus species
A novel series of pyridyl nitrofuranyl isoxazolines were synthesized and evaluated for their antibacterial activity against multiple drug resistant (MDR) Staphylococcus strains. Compounds with piperazine linker between the pyridyl group and isoxazoline ring showed better activity when compared to compounds without the piperazine linker. 3-Pyridyl nitrofuranyl isoxazoline with a piperazine linker was found to be more active than corresponding 2-and 4-pyridyl analogues with MICs in the range of 4-32µg/mL against MDR Staphylococcus strains. The eukaryotic toxicity of the compounds was tested by MTT assay and were found to be non-toxic against both non-tumour lung fibroblast WI-38 and cervical cancer cell line HeLa. The most active pyridyl nitrofuranyl isoxazoline compound showed improved activity against a panel of Staphylococcus strains compared to nitrofuran group containing antibiotic nitrofurantoin.
Although four ADCs have been approved and over sixty others are in development, the majority contain payloads belonging to two classes; tubulin inhibitors and DNA cross-linkers. Challenges in the development of ADCs include managing off-target toxicity and hydrophobicity. Some payload classes (e.g., PBD dimers) are notably hydrophobic leading to problems (e.g., aggregation) during conjugation. Thus, there is interest in developing novel payloads which retain the potency of DNA cross-linkers but have lower hydrophobicity and a wider therapeutic window when part of an ADC. The pyridinobenzodiazepines (PDDs) are a new class of sequence-selective, DNA mono-alkylating ADC payload which contain a polyheterocyclic chain with sufficient span to guide them to specific DNA sequences (e.g., transcription factor binding sites). The lead PDD payload, FGX-2-62, has a different sequence-selectivity profile to other DNA-interactive agents, spanning 8-9 base-pairs compared to 6-7 for a PBD dimer, and DNA footprinting experiments indicate a preference for 5'-XGXWWWWXX-3' sequences (X is any base; W is A/T). Transcription factor array studies have shown that the molecule inhibits DNA-binding of oncogenic transcription factors (e.g., NF-κB and GATA). In in vitro cell line studies, FGX-2-62 has low pM cytotoxicity in a diverse cell line panel, including stem cells, cells from both solid and blood cancers (e.g., 9 pM in HL-60) and MDR-resistant tumours, and arrests the cell cycle at the G0/G1 phase compared to G2-M arrest for PBD dimers. It is compatible with attachment to most linker technologies, and is significantly less hydrophobic than other payload classes. Initial MTD studies were carried out by separately conjugating (with negligible aggregation) FGX-2-62 and the PBD dimer Talirine to a THIOMAB® version of trastuzumab (DAR = 2). In female athymic nude mice, a greater tolerance was observed for the THIOMAB®-(FGX-2-62) ADC compared to the THIOMAB®-PBD dimer (i.e, MTD >8 mg.kg-1 versus 4 mg.kg-1). In an efficacy study, FGX-2-62 was conjugated to a cancer stem cell-targeting IgG1 antibody (Bstrongximab) with DAR 1.9. Initial evaluation afforded IC50 values of 0.67 nM and 0.47 nM in two antigen positive cell-lines, and an MTD of 6 mg.kg-1 in mice. In an antigen-positive embryonal carcinoma stem cell CDX mouse model, complete regression was observed at a dose of 2 mg.kg-1 (Q7Dx3). In a cholangiocarcinoma PDX model, complete tumour regression was observed out to 80 days (when experiment was terminated) at a dose of 5 mg.kg-1 (Q7Dx3), with no observed toxicity. The favourable hydrophobicity profile of the PDDs and ease of conjugation, along with their novel mechanism of action, significant in vitro cytotoxicity, in vivo efficacy and tolerability in MTD studies suggest that they represent a promising new class of ADC payloads. Citation Format: Nicolas Veillard, Paolo Andriollo, Julia Mantaj, Keith R. Fox, K Miraz Rahman, George Procopiou, Francesco Cascio, David B. Corcoran, Ilona Pysz, Patricia A. Cooper, Steven D. Shnyder, Yawen Ju, Edwin Tan, William M. Schopperle, Paul J. Jackson, David E. Thurston. Pyridinobenzodiazepines (PDDs): A new class of sequence-selective DNA mono-alkylating ADC payloads with low hydrophobicity [abstract]. In: Proceedings of the American Association for Cancer Research Annual Meeting 2018; 2018 Apr 14-18; Chicago, IL. Philadelphia (PA): AACR; Cancer Res 2018;78(13 Suppl):Abstract nr 736.
Although five ADCs have been approved and over sixty others are in development, the majority contain payloads belonging to two classes: tubulin inhibitors and DNA-interactive agents. Challenges in the development of ADCs include managing off-target toxicity and hydrophobicity. Some DNA-interactive payload classes [e.g. pyrolobenzodiazepine (PBD] dimers) are notably hydrophobic, leading to problems such as aggregation during conjugation, and systemic toxicities of the resultant ADCs are also beginning to emerge in clinical settings. Thus, there is interest in developing novel payloads which retain the potency of DNA cross-linking agents but have lower hydrophobicity and a wider therapeutic window when part of an ADC. The pyridinobenzodiazepines (PDDs) are a new class of sequence-selective, DNA mono-alkylating ADC payload, which contain a polyheterocyclic chain with sufficient molecular span and DNA base-pair recognition properties to guide them to specific DNA sequences (e.g. transcription factor binding sites). The favourable hydrophobicity profile of the PDDs and ease of conjugation, along with their novel mechanism of action, significant in vitro cytotoxicity and in vivo tolerability and efficacy when in an ADC format, indicate that they represent a promising new class of ADC payloads.
Although five Antibody-Drug Conjugates (ADCs) have been approved and over eighty others are in development, the majority contain payloads belonging to two classes: tubulin inhibitors and DNA interactive agents. Most DNA cross-linking payloads (e.g., the PBD dimers) have potent cytotoxicity but ADCs containing them have high hydrophobicity and a narrow therapeutic window. Thus, there is interest in developing novel payloads which benefit from a potency similar to the PBD dimers but that possess lower hydrophobicity and produce ADCs with a wider Therapeutic Index (TI). The pyridinobenzodiazepines (PDDs) are a new class of guanine-alkylating payloads, and these have been coupled to an adenine-alkylating CXI/duocarmycin pharmacophore to generate molecules that can form G-A DNA cross-links. The lead PDD-CXI payload (FGX-8-46) has a sequence-selectivity profile that differs from other DNA cross-linking agents in that it spans seven to eight base-pairs compared to six to seven for a typical PBD dimer. DNA cleavage experiments have indicated that it cleaves at discrete Adenine-containing sequences of the type 5’-XGXWWWW-3’ (X is any base; W is A/T, and the underlined bases show the cleavage points), and Transcription Factor (TF) Array studies show that it is a potent TF inhibitor, down-regulating several key oncogenic TFs (e.g., NF-κB). In in vitro cell line studies, the G-A cross-linkers have low pM cytotoxicity comparable to the PBD dimers in a wide and diverse range of cell lines, including those from both solid and haematological cancers (e.g., IC50 of ~2 pM in SW-48). This payload class is also compatible with a wide variety of linker technologies, and attachment can be made through either the PDD or CXI units. Importantly, these payloads are significantly less hydrophobic than other equivalent payload classes. ADCs have been generated by conjugating these new payloads to the EGFR-targeting antibody Cetuximab with DARs of between 1.8 and 2.2. The ADCs exhibit potent cytotoxicity in vitro, significant in vivo efficacy and substantially increased tolerability compared to other DNA cross-linking payloads (e.g., the PBD dimer Tesirine). While the G-A cross-linkers retain the cytotoxic potency of the PBD dimers, the “softer” cross-link formed compared to the G-G cross-linking PBD dimers may contribute to the enhanced tolerability profile of this molecular class. The favourable hydrophobicity profile of the PDD-CXI payloads and their ease of conjugation to antibodies, along with their significant in vitro cytotoxicity, in vivo efficacy and tolerability of ADCs produced from them, suggest that they represent a promising new class of ADC payloads. Citation Format: George Procopiou, Jennifer Auer, Daniella di Mascio, Keith R. Fox, Paolo Andriollo, Ilona Pysz, Francesco Cascio, Nicolas Veillard, K. Miraz Rahman, Paul J. Jackson, David E. Thurston. A new class of sequence-selective DNA cross-linking ADC payloads with increased in vivotolerability [abstract]. In: Proceedings of the American Association for Cancer Research Annual Meeting 2019; 2019 Mar 29-Apr 3; Atlanta, GA. Philadelphia (PA): AACR; Cancer Res 2019;79(13 Suppl):Abstract nr 211.
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