A CRISPR-Cas9 sex-ratio distortion system for genetic control

Galizi, Roberto; Hammond, Andrew; Kyrou, Kyros; Taxiarchi, Chrysanthi; Bernardini, Federica; OʼLoughlin, Samantha; Papathanos, Philippos Aris; Nolan, Tony; Windbichler, Nikolai; Crisanti, Andrea

doi:10.1038/srep31139

Cited by 182 publications

(228 citation statements)

References 20 publications

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“…Assuming that m = 0.95 (consistent with the results of Galizi et al [11, 12]), and R m = 6 (consistent with the analyses of Deredec et al [10]), then the model population tends to elimination, with time course calculated from (2) and shown in Fig. 1 (assuming an initial release of h 0 = 0.05 N 0 , i.e.…”

Section: Resultssupporting

confidence: 82%

Vector control with driving Y chromosomes: modelling the evolution of resistance

Beaghton

Burt

2017

Malar J

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BackgroundThe introduction of new malaria control interventions has often led to the evolution of resistance, both of the parasite to new drugs and of the mosquito vector to new insecticides, compromising the efficacy of the interventions. Recent progress in molecular and population biology raises the possibility of new genetic-based interventions, and the potential for resistance to evolve against these should be considered. Here, population modelling is used to determine the main factors affecting the likelihood that resistance will evolve against a synthetic, nuclease-based driving Y chromosome that produces a male-biased sex ratio.MethodsA combination of deterministic differential equation models and stochastic analyses involving branching processes and Gillespie simulations is utilized to assess the probability that resistance evolves against a driving Y that otherwise is strong enough to eliminate the target population. The model considers resistance due to changes at the target site such that they are no longer cleaved by the nuclease, and due to trans-acting autosomal suppressor alleles.ResultsThe probability that resistance evolves increases with the mutation rate and the intrinsic rate of increase of the population, and decreases with the strength of drive and any pleiotropic fitness costs of the resistant allele. In seasonally varying environments, the time of release can also affect the probability of resistance evolving. Trans-acting suppressor alleles are more likely to suffer stochastic loss at low frequencies than target site resistant alleles.ConclusionsAs with any other intervention, there is a risk that resistance will evolve to new genetic approaches to vector control, and steps should be taken to minimize this probability. Two design features that should help in this regard are to reduce the rate at which resistant mutations arise, and to target sequences such that if they do arise, they impose a significant fitness cost on the mosquito.Electronic supplementary materialThe online version of this article (doi:10.1186/s12936-017-1932-7) contains supplementary material, which is available to authorized users.

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Section: Resultssupporting

confidence: 82%

Vector control with driving Y chromosomes: modelling the evolution of resistance

Beaghton

Burt

2017

Malar J

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“…These advances in genome engineering, besides enabling a wave of basic research, have also been applied with the aim of distorting inheritance in insect disease vectors. CRISPR gene drives 1,10 and sex-distorters 11 are currently being considered for their enormous potential to control harmful organisms such as insect vectors of human malaria. The CRISPR machinery now broadly employed for gene editing in many organisms, has recently been modified to manipulate the transcriptome; namely targeted gene transactivation and repression.…”

Section: Introductionmentioning

confidence: 99%

Rationally-engineered reproductive barriers using CRISPR & CRISPRa: an evaluation of the synthetic species concept in Drosophila melanogaster

Waters

Capriotti

Gaboriau

et al. 2018

Sci Rep

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The ability to erect rationally-engineered reproductive barriers in animal or plant species promises to enable a number of biotechnological applications such as the creation of genetic firewalls, the containment of gene drives or novel population replacement and suppression strategies for genetic control. However, to date no experimental data exist that explores this concept in a multicellular organism. Here we examine the requirements for building artificial reproductive barriers in the metazoan model Drosophila melanogaster by combining CRISPR-based genome editing and transcriptional transactivation (CRISPRa) of the same loci. We directed 13 single guide RNAs (sgRNAs) to the promoters of 7 evolutionary conserved genes and used 11 drivers to conduct a misactivation screen. We identify dominant-lethal activators of the eve locus and find that they disrupt development by strongly activating eve outside its native spatio-temporal context. We employ the same set of sgRNAs to isolate, by genome editing, protective INDELs that render these loci resistant to transactivation without interfering with target gene function. When these sets of genetic components are combined we find that complete synthetic lethality, a prerequisite for most applications, is achievable using this approach. However, our results suggest a steep trade-off between the level and scope of dCas9 expression, the degree of genetic isolation achievable and the resulting impact on fly fitness. The genetic engineering strategy we present here allows the creation of single or multiple reproductive barriers and could be applied to other multicellular organisms such as disease vectors or transgenic organisms of economic importance.

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“…They designed a germline transformation construct where Cas9 endonuclease coding sequence was placed in a spermatogenesis-specific β2 tubulin promoter and the CRISPR SD construct was enclosed in piggyBac transformation vector. Among four transgenic lines tested, all the lines showed a strong sex-ratio distortion, with a male bias progeny ranging from 86.1% to 94.8% of males and the hatching rates varied between 83.6% and 93.2% (54).…”

Section: Application Of Crispr/cas9 In Genome Editing Of Vector Mosqumentioning

confidence: 99%

Current status of genome editing in vector mosquitoes: A review

Reegan¹,

Ceasar

Paulraj³

et al. 2016

BST

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A CRISPR-Cas9 sex-ratio distortion system for genetic control

Cited by 182 publications

References 20 publications

Vector control with driving Y chromosomes: modelling the evolution of resistance

Vector control with driving Y chromosomes: modelling the evolution of resistance

Rationally-engineered reproductive barriers using CRISPR & CRISPRa: an evaluation of the synthetic species concept in Drosophila melanogaster

Current status of genome editing in vector mosquitoes: A review

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