Modeling CRISPR gene drives for suppression of invasive rodents using a supervised machine learning framework

• Main Authors: Champer, J. (Author), Champer, S.E (Author), García-Díaz, P. (Author), Messer, P.W (Author), Oakes, N. (Author), Sharma, R. (Author)
• Format: Article
• Language: English
• Published: Public Library of Science 2021
• Subjects: allele; animal; animal experiment; animal model; Animals; article; biodiversity; Biodiversity; biological model; biological pest control; clustered regularly interspaced short palindromic repeat; Clustered Regularly Interspaced Short Palindromic Repeats; demography; female; Female; gene drive technology; Gene Drive Technology; genetics; human; introduced species; Introduced Species; male; Male; Models, Genetic; nonhuman; outcome assessment; Pest Control, Biological; Population Control; population dynamics; Population Dynamics; population size; procedures; rat; Rats; rodent; sensitivity analysis; supervised machine learning; Supervised Machine Learning
• Online Access: View Fulltext in Publisher
• ISBN: 1553734X (ISSN)
• DOI: 10.1371/journal.pcbi.1009660

Invasive rodent populations pose a threat to biodiversity across the globe. When confronted with these invaders, native species that evolved independently are often defenseless. CRISPR gene drive systems could provide a solution to this problem by spreading trans-genes among invaders that induce population collapse, and could be deployed even where traditional control methods are impractical or prohibitively expensive. Here, we develop a high-fidelity model of an island population of invasive rodents that includes three types of suppression gene drive systems. The individual-based model is spatially explicit, allows for overlapping generations and a fluctuating population size, and includes variables for drive fitness, efficiency, resistance allele formation rate, as well as a variety of ecological parameters. The computational burden of evaluating a model with such a high number of parameters presents a substantial barrier to a comprehensive understanding of its outcome space. We therefore accompany our population model with a meta-model that utilizes supervised machine learning to approximate the outcome space of the underlying model with a high degree of accuracy. This enables us to conduct an exhaustive inquiry of the population model, including variance-based sensitivity analyses using tens of millions of evaluations. Our results suggest that sufficiently capable gene drive systems have the potential to eliminate island populations of rodents under a wide range of demographic assumptions, though only if resistance can be kept to a minimal level. This study highlights the power of supervised machine learning to identify the key parameters and processes that determine the population dynamics of a complex evolutionary system. Copyright: © 2021 Champer et al. This is an open access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.