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American Society of Clinical Oncology, Journal of Clinical Oncology, 15_suppl(39), p. 3131-3131, 2021

DOI: 10.1200/jco.2021.39.15_suppl.3131

American Association for the Advancement of Science, Science, 6497(368), p. 1386-1392, 2020

DOI: 10.1126/science.aaz4427

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Partitioning of cancer therapeutics in nuclear condensates

This paper is made freely available by the publisher.
This paper is made freely available by the publisher.

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Abstract

3131 Background: The molecules of the cell are compartmentalized into membrane- and non-membrane-bound organelles. Many non-membrane-bound organelles are phase-separated biomolecular condensates with distinct physicochemical properties that can absorb and concentrate specific proteins and nucleic acids involved in discrete biochemical processes. We reasoned that selective condensate partitioning might also occur with small molecule drugs whose targets occur within condensates, and that the therapeutic index and efficacy of such compounds might therefore relate to their ability to partition into condensates. Methods: To study the behavior of drugs within condensates, these were modeled in cells and in vitro with purified proteins and visualized by fluorescent confocal microscopy. The functional outcomes of condensate partitioning were queried in cells. Results: We found that cisplatin, tamoxifen, JQ1, THZ1, and mitoxantrone are concentrated in specific protein condensates in vitro, and that this occurs through physicochemical properties independent of the drug target. A screen of a chemically diverse fluorescent probes and mutant-protein condensates demonstrated that pi-system interactions between aromatic moieties in the protein and small molecule govern concentration in condensates. These results show that clinically important drugs partition into specific protein condensates in vitro by virtue of defined chemical properties, thereby altering their local concentration. In vitro droplet assays revealed that cisplatin is selectively concentrated in transcriptional condensates, and that this ability is required for efficient platination of target DNA. In cell studies revealed that cisplatin preferentially targets DNA contained within MED1 condensates, and disrupts the genetic regulatory elements that compose phase-separated transcriptional condensates. Live cell imaging demonstrated that transcriptional condensates are dissolved by cisplatin, whereas other condensates remain intact. Conclusions: Our results show that antineoplastic drugs partition selectively into biomolecular condensates, that this can occur through physicochemical properties independent of their molecular targets, and that drug activity may occur through condensate-related mechanisms. These results have implications for development of efficacious cancer therapeutics; effective target engagement will depend on factors such as drug partitioning in condensates. Assays of the type described here may thus help optimize condensate partitioning, target engagement, and the therapeutic index of drugs for cancer treatment.