IDEAS home Printed from https://ideas.repec.org/a/plo/pcbi00/1009418.html
   My bibliography  Save this article

Drug-induced resistance evolution necessitates less aggressive treatment

Author

Listed:
  • Teemu Kuosmanen
  • Johannes Cairns
  • Robert Noble
  • Niko Beerenwinkel
  • Tommi Mononen
  • Ville Mustonen

Abstract

Increasing body of experimental evidence suggests that anticancer and antimicrobial therapies may themselves promote the acquisition of drug resistance by increasing mutability. The successful control of evolving populations requires that such biological costs of control are identified, quantified and included to the evolutionarily informed treatment protocol. Here we identify, characterise and exploit a trade-off between decreasing the target population size and generating a surplus of treatment-induced rescue mutations. We show that the probability of cure is maximized at an intermediate dosage, below the drug concentration yielding maximal population decay, suggesting that treatment outcomes may in some cases be substantially improved by less aggressive treatment strategies. We also provide a general analytical relationship that implicitly links growth rate, pharmacodynamics and dose-dependent mutation rate to an optimal control law. Our results highlight the important, but often neglected, role of fundamental eco-evolutionary costs of control. These costs can often lead to situations, where decreasing the cumulative drug dosage may be preferable even when the objective of the treatment is elimination, and not containment. Taken together, our results thus add to the ongoing criticism of the standard practice of administering aggressive, high-dose therapies and motivate further experimental and clinical investigation of the mutagenicity and other hidden collateral costs of therapies.Author summary: Evolution of drug resistance to anticancer and antimicrobial therapies is widespread among cancer and pathogen cell populations. Classical theory posits strictly that genetic and phenotypic variation is generated in evolving populations independently of the selection pressure. However, recent experimental findings among antimicrobial agents, traditional cytotoxic chemotherapies and targeted cancer therapies suggest that treatment not only imposes selection but can also affect the rate of adaptation by increasing mutability. Here we analyse a model with drug-induced increase in mutation rate and explore its consequences for treatment optimisation. We argue that the true biological cost of treatment is not limited to the harmful side-effects, but instead realises even more profoundly by fundamentally changing the underlying eco-evolutionary dynamics within the microenvironment. Using the concept of evolutionary rescue, we formulate the treatment as an optimal control problem and solve the optimal elimination strategy, which minimises the probability of evolutionary rescue. We show that aggressive elimination strategies, which aim at eradication as fast as possible and which represent the current standard of care, can be detrimental even with modest drug-induced increases (fold change ≤10) to the baseline mutation rate.

Suggested Citation

  • Teemu Kuosmanen & Johannes Cairns & Robert Noble & Niko Beerenwinkel & Tommi Mononen & Ville Mustonen, 2021. "Drug-induced resistance evolution necessitates less aggressive treatment," PLOS Computational Biology, Public Library of Science, vol. 17(9), pages 1-22, September.
    • Handle: RePEc:plo:pcbi00:1009418
    DOI: 10.1371/journal.pcbi.1009418
    as

    Download full text from publisher

    File URL: https://journals.plos.org/ploscompbiol/article?id=10.1371/journal.pcbi.1009418
    Download Restriction: no
    File URL: https://journals.plos.org/ploscompbiol/article/file?id=10.1371/journal.pcbi.1009418&type=printable
    Download Restriction: no
    File URL: https://libkey.io/10.1371/journal.pcbi.1009418?utm_source=ideas
    LibKey link: if access is restricted and if your library uses this service, LibKey will redirect you to where you can use your library subscription to access this item
    ---><---

    References listed on IDEAS

    as
    1. Elsa Hansen & Jason Karslake & Robert J Woods & Andrew F Read & Kevin B Wood, 2020. "Antibiotics can be used to contain drug-resistant bacteria by maintaining sufficiently large sensitive populations," PLOS Biology, Public Library of Science, vol. 18(5), pages 1-20, May.
    2. Jingsong Zhang & Jessica J. Cunningham & Joel S. Brown & Robert A. Gatenby, 2017. "Integrating evolutionary dynamics into treatment of metastatic castrate-resistant prostate cancer," Nature Communications, Nature, vol. 8(1), pages 1-9, December.
    3. Jeff Maltas & Kevin B Wood, 2019. "Pervasive and diverse collateral sensitivity profiles inform optimal strategies to limit antibiotic resistance," PLOS Biology, Public Library of Science, vol. 17(10), pages 1-34, October.
    4. Mari Yoshida & Sabrina Galiñanes Reyes & Soichiro Tsuda & Takaaki Horinouchi & Chikara Furusawa & Leroy Cronin, 2017. "Time-programmable drug dosing allows the manipulation, suppression and reversal of antibiotic drug resistance in vitro," Nature Communications, Nature, vol. 8(1), pages 1-11, August.
    5. Angela Oliveira Pisco & Amy Brock & Joseph Zhou & Andreas Moor & Mitra Mojtahedi & Dean Jackson & Sui Huang, 2013. "Non-Darwinian dynamics in therapy-induced cancer drug resistance," Nature Communications, Nature, vol. 4(1), pages 1-11, December.
    Full references (including those not matched with items on IDEAS)

    Citations

    Citations are extracted by the CitEc Project, subscribe to its RSS feed for this item.
    as


    Cited by:

    1. Arnaud Desrosiers & Rabeb Mouna Derbali & Sami Hassine & Jérémie Berdugo & Valérie Long & Dominic Lauzon & Vincent De Guire & Céline Fiset & Luc DesGroseillers & Jeanne Leblond Chain & Alexis Vallée-B, 2022. "Programmable self-regulated molecular buffers for precise sustained drug delivery," Nature Communications, Nature, vol. 13(1), pages 1-13, December.

    Most related items

    These are the items that most often cite the same works as this one and are cited by the same works as this one.
    1. Li You & Maximilian von Knobloch & Teresa Lopez & Vanessa Peschen & Sidney Radcliffe & Praveen Koshy Sam & Frank Thuijsman & Kateřina Staňková & Joel S. Brown, 2019. "Including Blood Vasculature into a Game-Theoretic Model of Cancer Dynamics," Games, MDPI, vol. 10(1), pages 1-22, March.
    2. Pranav I. Warman & Artem Kaznatcheev & Arturo Araujo & Conor C. Lynch & David Basanta, 2018. "Fractionated Follow-Up Chemotherapy Delays the Onset of Resistance in Bone Metastatic Prostate Cancer," Games, MDPI, vol. 9(2), pages 1-10, April.
    3. Serhii Aif & Nico Appold & Lucas Kampman & Oskar Hallatschek & Jona Kayser, 2022. "Evolutionary rescue of resistant mutants is governed by a balance between radial expansion and selection in compact populations," Nature Communications, Nature, vol. 13(1), pages 1-12, December.
    4. Francesca Menghi & Edison T. Liu, 2022. "Functional genomics of complex cancer genomes," Nature Communications, Nature, vol. 13(1), pages 1-4, December.
    5. Gregory J Kimmel & Philip Gerlee & Philipp M Altrock, 2019. "Time scales and wave formation in non-linear spatial public goods games," PLOS Computational Biology, Public Library of Science, vol. 15(9), pages 1-22, September.
    6. Nassim Nicholas Taleb & Jeffrey West, 2022. "Working With Convex Responses: Antifragility From Finance to Oncology," Papers 2209.14631, arXiv.org, revised Jan 2023.
    7. Elsa Hansen & Jason Karslake & Robert J Woods & Andrew F Read & Kevin B Wood, 2020. "Antibiotics can be used to contain drug-resistant bacteria by maintaining sufficiently large sensitive populations," PLOS Biology, Public Library of Science, vol. 18(5), pages 1-20, May.
    8. Benjamin Wölfl & Hedy te Rietmole & Monica Salvioli & Artem Kaznatcheev & Frank Thuijsman & Joel S. Brown & Boudewijn Burgering & Kateřina Staňková, 2022. "The Contribution of Evolutionary Game Theory to Understanding and Treating Cancer," Dynamic Games and Applications, Springer, vol. 12(2), pages 313-342, June.
    9. Marco Archetti, 2018. "How to Analyze Models of Nonlinear Public Goods," Games, MDPI, vol. 9(2), pages 1-15, April.
    10. Yelyzaveta Shlyakhtina & Bianca Bloechl & Maximiliano M. Portal, 2023. "BdLT-Seq as a barcode decay-based method to unravel lineage-linked transcriptome plasticity," Nature Communications, Nature, vol. 14(1), pages 1-14, December.
    11. Guillaume Harmange & Raúl A. Reyes Hueros & Dylan L. Schaff & Benjamin Emert & Michael Saint-Antoine & Laura C. Kim & Zijian Niu & Shivani Nellore & Mitchell E. Fane & Gretchen M. Alicea & Ashani T. W, 2023. "Disrupting cellular memory to overcome drug resistance," Nature Communications, Nature, vol. 14(1), pages 1-17, December.
    12. Maria Kleshnina & Sabrina Streipert & Joel S. Brown & Kateřina Staňková, 2023. "Game Theory for Managing Evolving Systems: Challenges and Opportunities of Including Vector-Valued Strategies and Life-History Traits," Dynamic Games and Applications, Springer, vol. 13(4), pages 1130-1155, December.
    13. Nicolosi, Gabriel & Friesz, Terry & Griffin, Christopher, 2022. "Approximation of optimal control surfaces for 2 × 2 skew-symmetric evolutionary game dynamics," Chaos, Solitons & Fractals, Elsevier, vol. 163(C).
    14. Péter Bayer & Jeffrey West, 2023. "Games and the Treatment Convexity of Cancer," Dynamic Games and Applications, Springer, vol. 13(4), pages 1088-1105, December.
    15. Christian Hilbe & Maria Kleshnina & Kateřina Staňková, 2023. "Evolutionary Games and Applications: Fifty Years of ‘The Logic of Animal Conflict’," Dynamic Games and Applications, Springer, vol. 13(4), pages 1035-1048, December.
    16. Neythen J Treloar & Alex J H Fedorec & Brian Ingalls & Chris P Barnes, 2020. "Deep reinforcement learning for the control of microbial co-cultures in bioreactors," PLOS Computational Biology, Public Library of Science, vol. 16(4), pages 1-18, April.

    More about this item

    Statistics

    Access and download statistics

    Corrections

    All material on this site has been provided by the respective publishers and authors. You can help correct errors and omissions. When requesting a correction, please mention this item's handle: RePEc:plo:pcbi00:1009418. See general information about how to correct material in RePEc.

    If you have authored this item and are not yet registered with RePEc, we encourage you to do it here. This allows to link your profile to this item. It also allows you to accept potential citations to this item that we are uncertain about.

    If CitEc recognized a bibliographic reference but did not link an item in RePEc to it, you can help with this form .

    If you know of missing items citing this one, you can help us creating those links by adding the relevant references in the same way as above, for each refering item. If you are a registered author of this item, you may also want to check the "citations" tab in your RePEc Author Service profile, as there may be some citations waiting for confirmation.

    For technical questions regarding this item, or to correct its authors, title, abstract, bibliographic or download information, contact: ploscompbiol (email available below). General contact details of provider: https://journals.plos.org/ploscompbiol/ .

    Please note that corrections may take a couple of weeks to filter through the various RePEc services.

    IDEAS is a RePEc service. RePEc uses bibliographic data supplied by the respective publishers.