Determining the landscape of resistance to gene drives in the malaria mosquito

Gene drives are engineered selfish genetic elements with the potential to spread throughout entire insect populations for sustainable vector control. Recently, a gene drive was shown to eliminate caged populations of the malaria mosquito by targeting the highly conserved female-specific exon of the doublesex gene. This caused females, homozygous for the gene drive, to develop as sterile intersex individuals, leading to the observed population crash. However, target site resistant alleles that block gene drive activity, whilst encoding a functional copy of the target gene, may halt gene drive spread in the wild. These may be naturally occurring or generated by the gene drive itself. This thesis presents a pipeline for the discovery, genetic engineering, and testing of putative drive-resistant variants. First, to investigate the potential for natural resistance, existing population genomics data were interrogated for the presence of natural single nucleotide polymorphisms (SNPs) at the highly conserved gene drive target region. To investigate the potential for drive-induced resistance, a high-throughput assay was designed to generate a high volume of mutations at the gene drive target site and screen them for their ability to restore dsx function. These methods yielded three putatively resistant SNPs: one natural polymorphism and two rare Cas9-induced mutations. These were engineered in the mosquito genome for testing, using a novel method termed CRISPR-mediated cassette exchange (CriMCE). It was confirmed that all three polymorphisms are functional and offer full, partial or no resistance to gene drive. Importantly, partial resistance to gene drive is being demonstrated for the first time. To mitigate observed resistance, gene drive systems targeting multiple sites simultaneously were developed. These showed improved drive dynamics and caused rapid elimination of caged mosquito populations within 7-8 generations. The experimental pipeline described here can be applied to pre-empt and mitigate resistance against any gene drive strategy, prior to field testing.Open Acces

CRISPR-Mediated Cassette Exchange (CriMCE): A Method to Introduce and Isolate Precise Marker-Less Edits

The introduction of small unmarked edits to the genome of insects is essential to study the molecular underpinnings of important biological traits, such as resistance to insecticides and genetic control strategies. Advances in CRISPR genome engineering have made this possible, but prohibitively laborious for most laboratories due to low rates of editing and the lack of a selectable marker. To facilitate the generation and isolation of precise marker-less edits we have developed a two-step method based on CRISPR-mediated cassette exchange (CriMCE) of a marked placeholder for a variant of interest. This strategy can be used to introduce a wider range of potential edits compared with previous approaches while consolidating the workflow. We present proof-of-principle that CriMCE is a powerful tool by engineering three single nucleotide polymorphism variants into the genome of Anopheles gambiae, with 5–41 × higher rates of editing than homology-directed repair or prime editing

Regulating the expression of gene drives is key to increasing their invasive potential and the mitigation of resistance

Homing-based gene drives use a germline source of nuclease to copy themselves at specific target sites in a genome and bias their inheritance. Such gene drives can be designed to spread and deliberately suppress populations of malaria mosquitoes by impairing female fertility. However, strong unintended fitness costs of the drive and a propensity to generate resistant mutations can limit a gene drive’s potential to spread. Alternative germline regulatory sequences in the drive element confer improved fecundity of carrier individuals and reduced propensity for target site resistance. This is explained by reduced rates of end-joining repair of DNA breaks from parentally deposited nuclease in the embryo, which can produce heritable mutations that reduce gene drive penetrance. We tracked the generation and selection of resistant mutations over the course of a gene drive invasion of a population. Improved gene drives show faster invasion dynamics, increased suppressive effect and later onset of target site resistance. Our results show that regulation of nuclease expression is as important as the choice of target site when developing a robust homing-based gene drive for population suppression

Analysis of the Genetic Variation of the Fruitless Gene within the Anopheles gambiae (Diptera: Culicidae) Complex Populations in Africa

Targeting genes involved in sexual determinism, for vector or pest control purposes, requires a better understanding of their polymorphism in natural populations in order to ensure a rapid spread of the construct. By using genomic data from An. gambiae s.l., we analyzed the genetic variation and the conservation score of the fru gene in 18 natural populations across Africa. A total of 34,339 SNPs were identified, including 3.11% non-synonymous segregating sites. Overall, the nucleotide diversity was low, and the Tajima’s D neutrality test was negative, indicating an excess of low frequency SNPs in the fru gene. The allelic frequencies of the non-synonymous SNPs were low (freq < 0.26), except for two SNPs identified at high frequencies (freq > 0.8) in the zinc-finger A and B protein domains. The conservation score was variable throughout the fru gene, with maximum values in the exonic regions compared to the intronic regions. These results showed a low genetic variation overall in the exonic regions, especially the male sex-specific exon and the BTB-exon 1 of the fru gene. These findings will facilitate the development of an effective gene drive construct targeting the fru gene that can rapidly spread without encountering resistance in wild populations