IDEAS home Printed from https://ideas.repec.org/a/plo/pcbi00/1004773.html
   My bibliography  Save this article

Genetic Correlations Greatly Increase Mutational Robustness and Can Both Reduce and Enhance Evolvability

Author

Listed:
  • Sam F Greenbury
  • Steffen Schaper
  • Sebastian E Ahnert
  • Ard A Louis

Abstract

Mutational neighbourhoods in genotype-phenotype (GP) maps are widely believed to be more likely to share characteristics than expected from random chance. Such genetic correlations should strongly influence evolutionary dynamics. We explore and quantify these intuitions by comparing three GP maps—a model for RNA secondary structure, the HP model for protein tertiary structure, and the Polyomino model for protein quaternary structure—to a simple random null model that maintains the number of genotypes mapping to each phenotype, but assigns genotypes randomly. The mutational neighbourhood of a genotype in these GP maps is much more likely to contain genotypes mapping to the same phenotype than in the random null model. Such neutral correlations can be quantified by the robustness to mutations, which can be many orders of magnitude larger than that of the null model, and crucially, above the critical threshold for the formation of large neutral networks of mutationally connected genotypes which enhance the capacity for the exploration of phenotypic novelty. Thus neutral correlations increase evolvability. We also study non-neutral correlations: Compared to the null model, i) If a particular (non-neutral) phenotype is found once in the 1-mutation neighbourhood of a genotype, then the chance of finding that phenotype multiple times in this neighbourhood is larger than expected; ii) If two genotypes are connected by a single neutral mutation, then their respective non-neutral 1-mutation neighbourhoods are more likely to be similar; iii) If a genotype maps to a folding or self-assembling phenotype, then its non-neutral neighbours are less likely to be a potentially deleterious non-folding or non-assembling phenotype. Non-neutral correlations of type i) and ii) reduce the rate at which new phenotypes can be found by neutral exploration, and so may diminish evolvability, while non-neutral correlations of type iii) may instead facilitate evolutionary exploration and so increase evolvability.Author Summary: Evolutionary dynamics arise from the interplay of mutations acting on genotypes and natural selection acting on phenotypes. Understanding the structure of the genotype-phenotype (GP) map is therefore critical for understanding evolutionary processes. We address a simple question about structure: Are the genotypes positively correlated? That is, will the mutational neighbours of a genotype be more likely to map to similar phenotypes than expected from random chance? John Maynard Smith and others have argued that the intuitive answer is yes. Here we quantify these intuitions by comparing model GP maps for RNA secondary structure, protein tertiary structure, and protein quaternary structure to a random GP map. We find strong neutral correlations: Point mutations are orders of magnitude more likely than expected by random chance to link genotypes that map to the same phenotype, which vitally increases the potential for evolutionary innovation by generating neutral networks. If GP maps were uncorrelated like the random map, evolution may not even be possible. We also find correlations for non-neutral mutations: Mutational neighbourhoods are less diverse than expected by random chance. Such local heterogeneity slows down the rate at which new phenotypic variation can be found. But non-neutral correlations also enhance evolvability by lowering the probability of mutating to a deleterious non-folding or non-assembling phenotype.

Suggested Citation

  • Sam F Greenbury & Steffen Schaper & Sebastian E Ahnert & Ard A Louis, 2016. "Genetic Correlations Greatly Increase Mutational Robustness and Can Both Reduce and Enhance Evolvability," PLOS Computational Biology, Public Library of Science, vol. 12(3), pages 1-27, March.
  • Handle: RePEc:plo:pcbi00:1004773
    DOI: 10.1371/journal.pcbi.1004773
    as

    Download full text from publisher

    File URL: https://journals.plos.org/ploscompbiol/article?id=10.1371/journal.pcbi.1004773
    Download Restriction: no

    File URL: https://journals.plos.org/ploscompbiol/article/file?id=10.1371/journal.pcbi.1004773&type=printable
    Download Restriction: no

    File URL: https://libkey.io/10.1371/journal.pcbi.1004773?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. Stefano Ciliberti & Olivier C Martin & Andreas Wagner, 2007. "Robustness Can Evolve Gradually in Complex Regulatory Gene Networks with Varying Topology," PLOS Computational Biology, Public Library of Science, vol. 3(2), pages 1-10, February.
    2. Jeremy A. Draghi & Todd L. Parsons & Günter P. Wagner & Joshua B. Plotkin, 2010. "Mutational robustness can facilitate adaptation," Nature, Nature, vol. 463(7279), pages 353-355, January.
    3. Eric J. Hayden & Evandro Ferrada & Andreas Wagner, 2011. "Cryptic genetic variation promotes rapid evolutionary adaptation in an RNA enzyme," Nature, Nature, vol. 474(7349), pages 92-95, June.
    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. Rigato, Emanuele & Fusco, Giuseppe, 2020. "A heuristic model of the effects of phenotypic robustness in adaptive evolution," Theoretical Population Biology, Elsevier, vol. 136(C), pages 22-30.
    2. Miguel A Fortuna & Luis Zaman & Charles Ofria & Andreas Wagner, 2017. "The genotype-phenotype map of an evolving digital organism," PLOS Computational Biology, Public Library of Science, vol. 13(2), pages 1-20, February.

    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. Javier Santos-Moreno & Eve Tasiudi & Hadiastri Kusumawardhani & Joerg Stelling & Yolanda Schaerli, 2023. "Robustness and innovation in synthetic genotype networks," Nature Communications, Nature, vol. 14(1), pages 1-17, December.
    2. Rigato, Emanuele & Fusco, Giuseppe, 2020. "A heuristic model of the effects of phenotypic robustness in adaptive evolution," Theoretical Population Biology, Elsevier, vol. 136(C), pages 22-30.
    3. Miguel A Fortuna & Luis Zaman & Charles Ofria & Andreas Wagner, 2017. "The genotype-phenotype map of an evolving digital organism," PLOS Computational Biology, Public Library of Science, vol. 13(2), pages 1-20, February.
    4. Anthony V Furano & Charlie E Jones & Vipul Periwal & Kathryn E Callahan & Jean-Claude Walser & Pamela R Cook, 2020. "Cryptic genetic variation enhances primate L1 retrotransposon survival by enlarging the functional coiled coil sequence space of ORF1p," PLOS Genetics, Public Library of Science, vol. 16(8), pages 1-19, August.
    5. Payne, Joshua L., 2016. "No tradeoff between versatility and robustness in gene circuit motifs," Physica A: Statistical Mechanics and its Applications, Elsevier, vol. 449(C), pages 192-199.
    6. Alicia Sanchez-Gorostiaga & Djordje Bajić & Melisa L Osborne & Juan F Poyatos & Alvaro Sanchez, 2019. "High-order interactions distort the functional landscape of microbial consortia," PLOS Biology, Public Library of Science, vol. 17(12), pages 1-34, December.
    7. Alexander J. Stewart & Joshua B. Plotkin, 2015. "The Evolvability of Cooperation under Local and Non-Local Mutations," Games, MDPI, vol. 6(3), pages 1-20, July.
    8. Zeina Shreif & Vipul Periwal, 2014. "A Network Characteristic That Correlates Environmental and Genetic Robustness," PLOS Computational Biology, Public Library of Science, vol. 10(2), pages 1-23, February.
    9. Nasimul Noman & Taku Monjo & Pablo Moscato & Hitoshi Iba, 2015. "Evolving Robust Gene Regulatory Networks," PLOS ONE, Public Library of Science, vol. 10(1), pages 1-21, January.
    10. Tobias Sikosek & Erich Bornberg-Bauer & Hue Sun Chan, 2012. "Evolutionary Dynamics on Protein Bi-stability Landscapes can Potentially Resolve Adaptive Conflicts," PLOS Computational Biology, Public Library of Science, vol. 8(9), pages 1-17, September.
    11. Emmert-Streib, Frank & Dehmer, Matthias, 2009. "Fault tolerance of information processing in gene networks," Physica A: Statistical Mechanics and its Applications, Elsevier, vol. 388(4), pages 541-548.
    12. Proulx, Stephen R., 2011. "The rate of multi-step evolution in Moran and Wright–Fisher populations," Theoretical Population Biology, Elsevier, vol. 80(3), pages 197-207.
    13. Zang, Hong & Zhang, Tonghua & Zhang, Yanduo, 2015. "Bifurcation analysis of a mathematical model for genetic regulatory network with time delays," Applied Mathematics and Computation, Elsevier, vol. 260(C), pages 204-226.
    14. Krishnan, Arun & Tomita, Masaru & Giuliani, Alessandro, 2008. "Evolution of gene regulatory networks: Robustness as an emergent property of evolution," Physica A: Statistical Mechanics and its Applications, Elsevier, vol. 387(8), pages 2170-2186.
    15. Shintaro Nagata & Macoto Kikuchi, 2020. "Emergence of cooperative bistability and robustness of gene regulatory networks," PLOS Computational Biology, Public Library of Science, vol. 16(6), pages 1-24, June.
    16. Tadamune Kaneko & Macoto Kikuchi, 2022. "Evolution enhances mutational robustness and suppresses the emergence of a new phenotype: A new computational approach for studying evolution," PLOS Computational Biology, Public Library of Science, vol. 18(1), pages 1-20, January.
    17. Rendel, Mark D., 2011. "Adaptive evolutionary walks require neutral intermediates in RNA fitness landscapes," Theoretical Population Biology, Elsevier, vol. 79(1), pages 12-18.

    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:pcbi00:1004773. 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.