69818-97-9Relevant academic research and scientific papers
MODIFIED PROTEINS AND PROTEIN DEGRADERS
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Paragraph 00552-00553; 00778-00780, (2021/12/08)
Provided herein are compounds, pharmaceutical compositions, and methods for binding or degrading target proteins. Further provided herein are compounds having a DNA damage-binding protein 1 (DDB1) binding moiety. Some such embodiments include a linker. Some such embodiments include a target protein binding moiety. Further provided herein are ligand-DDB1 complexes. Further provided herein are in vivo modified DDB1 proteins.
Synthesis and Antimicrobial Evaluation of Nitazoxanide-Based Analogues: Identification of Selective and Broad Spectrum Activity
Ballard, T. Eric,Wang, Xia,Olekhnovich, Igor,Koerner, Taylor,Seymour, Craig,Salamoun, Joseph,Warthan, Michelle,Hoffman, Paul S.,Macdonald, Timothy L.
experimental part, p. 362 - 377 (2012/01/11)
A library composed of nitazoxanide-based analogues was synthesized and assayed for increased antibacterial efficacy against the pyruvate-ferredoxin oxidoreductase (PFOR) using microorganisms Helicobacter pylori, Campylobacter jejuni and Clostridium difficile. Derivatives were found to recapitulate and improve activity against these organisms and select analogues were tested for their ability to disrupt the PFOR enzyme directly. The library was also screened for activity against staphylococci and resulted in the identification of analogues capable of inhibiting both staphylococci and all PFOR organisms at low micromolar minimum inhibitory concentrations with low toxicity to human foreskin cells. Hitting them where it hurts! A library of nitazoxanide-based analogues was synthesized and assayed for antibacterial efficacy against pyruvate-ferredoxin oxidoreductase (PFOR) utilizing microorganisms. Derivatives were found to recapitulate and improve activity against these organisms, and select analogues were screened for activity against staphylococci resulting in the identification of analogues capable of inhibiting both staphylococci and all PFOR organisms at low micromolar minimum inhibitory concentrations.
