Targeting the adaptability of heterogeneous aneuploids

Guangbo Chen; Wahid A. Mulla; Andrei Kucharavy; Boris Rubinstein; Juliana Conkright; Scott McCroskey; William D. Bradford; Lauren Weems; Jeff S. Haug; Chris W. Seidel; Judith Berman; Rong Li; Hung-Ji Tsai

doi:10.1016/j.cell.2015.01.026

Targeting the adaptability of heterogeneous aneuploids

Guangbo Chen, Wahid A. Mulla, Andrei Kucharavy, Boris Rubinstein, Juliana Conkright, Scott McCroskey, William D. Bradford, Lauren Weems, Jeff S. Haug, Chris W. Seidel, Judith Berman, Rong Li^*, Hung-Ji Tsai

^*Corresponding author for this work

Biosciences

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Abstract

Aneuploid genomes, characterized by unbalanced chromosome stoichiometry (karyotype), are associated with cancer malignancy and drug resistance of pathogenic fungi. The phenotypic diversity resulting from karyotypic diversity endows the cell population with superior adaptability. We show here, using a combination of experimental data and a general stochastic model, that the degree of phenotypic variation, thus evolvability, escalates with the degree of overall growth suppression. Such scaling likely explains the challenge of treating aneuploidy diseases with a single stress-inducing agent. Instead, we propose the design of an "evolutionary trap" (ET) targeting both karyotypic diversity and fitness. This strategy entails a selective condition "channeling" a karyotypically divergent population into one with a predominant and predictably drugable karyotypic feature. We provide a proof-of-principle case in budding yeast and demonstrate the potential efficacy of this strategy toward aneuploidy-based azole resistance in Candida albicans. By analyzing existing pharmacogenomics data, we propose the potential design of an ET against glioblastoma.

Original language	English
Pages (from-to)	771-784
Number of pages	14
Journal	Cell
Volume	160
Issue number	4
DOIs	https://doi.org/10.1016/j.cell.2015.01.026
Publication status	Published - 12 Feb 2015

ASJC Scopus subject areas

Biochemistry, Genetics and Molecular Biology(all)

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This output contributes to the following UN Sustainable Development Goals (SDGs)

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Chen_et_al_Targeting_the_adaptability_of_heterogeneous_aneuploids_Cell_2015
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Cite this

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title = "Targeting the adaptability of heterogeneous aneuploids",

abstract = "Aneuploid genomes, characterized by unbalanced chromosome stoichiometry (karyotype), are associated with cancer malignancy and drug resistance of pathogenic fungi. The phenotypic diversity resulting from karyotypic diversity endows the cell population with superior adaptability. We show here, using a combination of experimental data and a general stochastic model, that the degree of phenotypic variation, thus evolvability, escalates with the degree of overall growth suppression. Such scaling likely explains the challenge of treating aneuploidy diseases with a single stress-inducing agent. Instead, we propose the design of an {"}evolutionary trap{"} (ET) targeting both karyotypic diversity and fitness. This strategy entails a selective condition {"}channeling{"} a karyotypically divergent population into one with a predominant and predictably drugable karyotypic feature. We provide a proof-of-principle case in budding yeast and demonstrate the potential efficacy of this strategy toward aneuploidy-based azole resistance in Candida albicans. By analyzing existing pharmacogenomics data, we propose the potential design of an ET against glioblastoma.",

author = "Guangbo Chen and Mulla, {Wahid A.} and Andrei Kucharavy and Boris Rubinstein and Juliana Conkright and Scott McCroskey and Bradford, {William D.} and Lauren Weems and Haug, {Jeff S.} and Seidel, {Chris W.} and Judith Berman and Rong Li and Hung-Ji Tsai",

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AU - Chen, Guangbo

AU - Mulla, Wahid A.

AU - Kucharavy, Andrei

AU - Rubinstein, Boris

AU - Conkright, Juliana

AU - McCroskey, Scott

AU - Bradford, William D.

AU - Weems, Lauren

AU - Haug, Jeff S.

AU - Seidel, Chris W.

AU - Berman, Judith

AU - Li, Rong

AU - Tsai, Hung-Ji

PY - 2015/2/12

Y1 - 2015/2/12

N2 - Aneuploid genomes, characterized by unbalanced chromosome stoichiometry (karyotype), are associated with cancer malignancy and drug resistance of pathogenic fungi. The phenotypic diversity resulting from karyotypic diversity endows the cell population with superior adaptability. We show here, using a combination of experimental data and a general stochastic model, that the degree of phenotypic variation, thus evolvability, escalates with the degree of overall growth suppression. Such scaling likely explains the challenge of treating aneuploidy diseases with a single stress-inducing agent. Instead, we propose the design of an "evolutionary trap" (ET) targeting both karyotypic diversity and fitness. This strategy entails a selective condition "channeling" a karyotypically divergent population into one with a predominant and predictably drugable karyotypic feature. We provide a proof-of-principle case in budding yeast and demonstrate the potential efficacy of this strategy toward aneuploidy-based azole resistance in Candida albicans. By analyzing existing pharmacogenomics data, we propose the potential design of an ET against glioblastoma.

AB - Aneuploid genomes, characterized by unbalanced chromosome stoichiometry (karyotype), are associated with cancer malignancy and drug resistance of pathogenic fungi. The phenotypic diversity resulting from karyotypic diversity endows the cell population with superior adaptability. We show here, using a combination of experimental data and a general stochastic model, that the degree of phenotypic variation, thus evolvability, escalates with the degree of overall growth suppression. Such scaling likely explains the challenge of treating aneuploidy diseases with a single stress-inducing agent. Instead, we propose the design of an "evolutionary trap" (ET) targeting both karyotypic diversity and fitness. This strategy entails a selective condition "channeling" a karyotypically divergent population into one with a predominant and predictably drugable karyotypic feature. We provide a proof-of-principle case in budding yeast and demonstrate the potential efficacy of this strategy toward aneuploidy-based azole resistance in Candida albicans. By analyzing existing pharmacogenomics data, we propose the potential design of an ET against glioblastoma.

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JO - Cell

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Targeting the adaptability of heterogeneous aneuploids

Abstract

ASJC Scopus subject areas

UN SDGs

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