Impact of mosquito gene drive on malaria elimination in a computational model with explicit spatial and temporal dynamics

Eckhoff, PA; Wenger, EA; Godfray, H. Charles J.; Burt, Austin

doi:10.1073/pnas.1611064114

Cited by 175 publications

(244 citation statements)

References 53 publications

(92 reference statements)

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“…, Wu et al 2016) of the gene drive construct, either of which could be inserted elsewhere in the genome and could spread by natural selection. If no resistant, suppressor, or mutator allele was released, the nuclease will impose a load upon the population, which can lead to population suppression, or even elimination—yet another way to reduce disease transmission (Burt 2003; Deredec et al 2008, 2011; Eckhoff et al 2017). The possibility of eventually combining population suppression and population modification approaches should be considered.…”

Section: Discussionmentioning

confidence: 99%

Requirements for Driving Antipathogen Effector Genes into Populations of Disease Vectors by Homing

et al. 2017

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There is a need for new interventions against the ongoing burden of vector-borne diseases such as malaria and dengue. One suggestion has been to develop genes encoding effector molecules that block parasite development within the vector, and then use the nuclease-based homing reaction as a form of gene drive to spread those genes through target populations. If the effector gene reduces the fitness of the mosquito and does not contribute to the drive, then loss-of-function mutations in the effector will eventually replace functional copies, but protection may nonetheless persist sufficiently long to provide a public health benefit. Here, we present a quantitative model allowing one to predict the duration of protection as a function of the probabilities of different molecular processes during the homing reaction, various fitness effects, and the efficacy of the effector in blocking transmission. Factors that increase the duration of protection include reducing the frequency of pre-existing resistant alleles, the probability of nonrecombinational DNA repair, the probability of homing-associated loss of the effector, the fitness costs of the nuclease and effector, and the completeness of parasite blocking. For target species that extend over an area much larger than the typical dispersal distance, the duration of protection is expected to be highest at the release site, and decrease away from there, eventually falling to zero, as effector-less drive constructs replace effector-containing ones. We also model an alternative strategy of using the nuclease to target an essential gene, and then linking the effector to a sequence that restores the essential function and is resistant to the nuclease. Depending upon parameter values, this approach can prolong the duration of protection. Our models highlight the key design criteria needed to achieve a desired level of public health benefit.

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Section: Discussionmentioning

confidence: 99%

Requirements for Driving Antipathogen Effector Genes into Populations of Disease Vectors by Homing

et al. 2017

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“…arabiensis to quickly replace entire natural populations of these species. The aim being to limit mosquito populations ( e.g ., by engineering all male offspring) or to spread genes that make the mosquitoes resistant to Plasmodium spp …”

Section: Introductionmentioning

confidence: 99%

A review of progress toward field application of transgenic mosquitocidal entomopathogenic fungi

Lovett

Bilgo

Diabaté

et al. 2019

Pest Management Science

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In Africa, adult mosquito populations are primarily controlled with insecticide‐impregnated bed nets and residual insecticide sprays. This coupled with widespread applications of pesticides in agriculture has led to increasing insecticide resistance in mosquito populations. We have developed multiple alternative strategies for exploiting transgenic Metarhizium spp. directed at: (i) shortening the lifespan of adult mosquitoes; (ii) reducing transmission potential of Plasmodium spp.; (iii) reducing vector competence via pre‐lethal effects. The present challenge is to convert this promising strategy into a validated public health intervention by resolving outstanding issues related to the release of genetically modified organisms. © 2019 Society of Chemical Industry

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“…11, 2017; 3 raises biosafety concerns [9], and calls for confinement strategies to prevent unintentional escape and spread of the gene drive constructs [22]. While various genetic design or containment strategies have been discussed [9,20,23,24], and a few computational simulations were conducted [17,18,25], the spatial spreading of the gene drive alleles has received less attention.To understand such phenomena in a spatial context, we will exploit a methodology developed by N. Barton and collaborators, originally in an e↵ort to understand adaptation and speciation of diploid sexually reproducing organisms in genetic hybrid zones [26][27][28].We apply these techniques to a spatial generalization of a model of diploid CRISPR/Cas9 population genetics proposed by Unckless et al [29], and highlight two distinct ways in which gene drive alleles can spread spatially. The non-Mendelian (or "super-Mendelian" [30]) population genetics of gene drives are remarkable because individuals homozygous for a gene drive can in fact spread into wild-type populations even if they carry a positive selective disadvantage s. First, for small selective disadvantages (0 < s < 0.5 in our case), the spatial spreading proceeds via a well-known Fisher-Kolmogorov-Petrovsky-Piskunov wave [31,32].…”

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“…Remarkably, high conversion rates have already been achieved with the mutagenic chain reaction ("MCR") realized by the CRISPR/Cas9 system [1][2][3] for yeast (c yeast > 0.995) [19], fruit flies (c flies = 0.97) [20] and malaria vector mosquito, Anopheles stephensi with engineered malaria resistance (c raises biosafety concerns [9], and calls for confinement strategies to prevent unintentional escape and spread of the gene drive constructs [22]. While various genetic design or containment strategies have been discussed [9,20,23,24], and a few computational simulations were conducted [17,18,25], the spatial spreading of the gene drive alleles has received less attention.…”

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Spatial gene drives and pushed genetic waves

Tanaka

Stone

Nelson

2017

Preprint

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Gene drives have the potential to rapidly replace a harmful wild-type allele with a gene drive allele engineered to have desired functionalities. However, an accidental or premature release of a gene drive construct to the natural environment could damage an ecosystem irreversibly. Thus, it is important to understand the spatiotemporal consequences of the super-Mendelian population genetics prior to potential applications. Here, we employ a reaction-di↵usion model for sexually reproducing diploid organisms to study how a locally introduced gene drive allele spreads to replace the wild-type allele, even though it posses a selective disadvantage s > 0. Using methods developed by N. Barton and collaborators, we show that socially responsible gene drives require 0.5 < s < 0.697, a rather narrow range. In this "pushed wave" regime, the spatial spreading of gene drives will be initiated only when the initial frequency distribution is above a threshold profile called "critical propagule", which acts as a safeguard against accidental release. We also study how the spatial spread of the pushed wave can be stopped by making gene drives uniquely vulnerable ("sensitizing drive") in a way that is harmless for a wild-type allele. Finally, we show that appropriately sensitized drives in two dimensions can be stopped even by imperfect barriers perforated by a series of gaps.. CC-BY-NC 4.0 International license peer-reviewed) is the author/funder. It is made available under a The copyright holder for this preprint (which was not . http://dx.doi.org/10.1101/126722 doi: bioRxiv preprint first posted online Apr. 11, 2017; 2 The development of the CRISPR/Cas9 system [1][2][3][4], derived from an adaptive immune system in prokaryotes [5], has received much recent attention, in part due to its exceptional versatility as a gene editor in sexually-reproducing organisms, compared to similar exploitations of homologous recombination such as zinc-finger nucleases (ZFNs) and the TALENS system [4,6]. Part of the appeal is the potential for introducing a novel gene into a population, allowing control of highly pesticide-resistant crop pests and disease vectors such as mosquitoes [7][8][9][10]. Although the genetic modifications typically introduce a fitness cost or a "selective disadvantage", the non-Mendelian population genetics embodied in CRISPR/Cas9 gene drives nevertheless allows edited genes to spread, even when the fitness cost of the inserted gene is large. The idea of using constructs that bias gene transmission rates to rapidly introduce novel genes into ecosystems has been discussed for many decades [11][12][13][14][15][16]. Similar "homing endonuclease genes" (in the case of CRISPR/Cas9, the homing ability is provided by a guide RNA) were considered earlier by ecologists in the context of control of malaria in Africa [17,18].As a hypothetical example of a gene drive applied to a pathogen vector requiring both a vertebrate and insect host, consider plasmodium, carried by mosquitoes and injected with its saliva into humans. Femal...

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Impact of mosquito gene drive on malaria elimination in a computational model with explicit spatial and temporal dynamics

Cited by 175 publications

References 53 publications

Requirements for Driving Antipathogen Effector Genes into Populations of Disease Vectors by Homing

Requirements for Driving Antipathogen Effector Genes into Populations of Disease Vectors by Homing

A review of progress toward field application of transgenic mosquitocidal entomopathogenic fungi

Spatial gene drives and pushed genetic waves

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