Abstract B022: The polyaneuploid transition as a hedge against failures in resistance acquisition

Metastatic cancer is incurable because tumors evolve resistance to all classes of therapy, resulting the in the deaths of 10 million people each year. Therapy resistance is typically attributed to the presence of a cancer stem cell or genetic tumor cell heterogeneity. However, therapeutic resistance...

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Veröffentlicht in:Cancer research (Chicago, Ill.) Ill.), 2022-05, Vol.82 (10_Supplement), p.B022-B022
Hauptverfasser: Butler, George, Bos, Julia, Austin, Robert H., Amend, Sarah R., Pienta, Kenneth J.
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Sprache:eng
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Zusammenfassung:Metastatic cancer is incurable because tumors evolve resistance to all classes of therapy, resulting the in the deaths of 10 million people each year. Therapy resistance is typically attributed to the presence of a cancer stem cell or genetic tumor cell heterogeneity. However, therapeutic resistance can also emerge through a transient cell state: the Polyaneuploid Cancer Cell (PACC) state. The Polyaneuploid transition (PAT) is an evolutionary conserved polyploid program accessed by cancer cells in response to an external stress such as chemotherapy. Once the stress subsides, cells exit the PACC state and repopulate a non-polyploid population that is resistant to multiple classes of therapy. We hypothesize that the PAT facilitates inherited universal therapeutic resistance. We utilized the bacteria E. coli as a model system of the evolutionary conserved polyploid mechanism of resistance. The E. coli strain MG1655 was engineered to express an hupA::GFP reporter to monitor nucleoid DNA or a ibpA::GFP reporter to monitor the aggregation of misfolded proteins. We treated these cultures with ciprofloxacin at near lethal doses for 12 hours and recorded the dynamics with fluorescent time-lapse microscopy. Individual bacteria underwent a transient phase of polyploidization causing an elongated filamentous phenotype that is at least an order of magnitude bigger compared to the unstressed bacteria. During filamentation, we found that the misfolded protein aggregates are shuttled along the cell body to the tips. Eventually, the filaments bud resulting in a population of “typical” length cells. The buds that are produced by the filaments are filled with an excess of misfolded protein aggregate and, surprisingly, are commonly void of DNA. This response is unexpected in a cell that is already resistant due to the high fitness cost. However, if the cell is not resistant, then each misfolded protein may represent an attempt to solve the antibiotic puzzle and to achieve a resistant phenotype. In turn, the ability to efficiently collect and dispose of the misfolded proteins, i.e., the previous failed attempt, may be advantageous to reduce the need for protein degradation and ensure that future protein production is not impaired. Taken together, this finding suggests that antibiotic resistance might be dependent on the ability to endure repeated futile endeavors to explore the phenotypic landscape rather than selecting for individuals that already exist at an evolutionary opt
ISSN:1538-7445
1538-7445
DOI:10.1158/1538-7445.EVODYN22-B022