Engineering multiple species-like genetic incompatibilities in insects

Speciation constrains the flow of genetic information between populations of sexually reproducing organisms. Gaining control over mechanisms of speciation would enable new strategies to manage wild populations of disease vectors, agricultural pests, and invasive species. Additionally, such control would provide safe biocontainment of transgenes and gene drives. Here, we demonstrate a general approach to create engineered genetic incompatibilities (EGIs) in the model insect Drosophila melanogaster. EGI couples a dominant lethal transgene with a recessive resistance allele. Strains homozygous for both elements are fertile and fecund when they mate with similarly engineered strains, but incompatible with wild-type strains that lack resistant alleles. EGI genotypes can also be tuned to cause hybrid lethality at different developmental life-stages. Further, we demonstrate that multiple orthogonal EGI strains of D. melanogaster can be engineered to be mutually incompatible with wild-type and with each other. EGI is a simple and robust approach in multiple sexually reproducing organisms.

rcs5-mediated spot blotch resistance in barley is conferred by wall-associated kinases that resist pathogen manipulation

ABSTRACTPlant biotrophic pathogen disease resistances rely on immunity receptor-mediated programmed cell death (PCD) responses, but specialized necrotrophic/hemi-biotrophic pathogens hijack these mechanisms to colonize the resulting dead tissue in their necrotrophic phase. Thus, immunity receptors can become necrotrophic pathogen dominant susceptibility targets but resistance mechanisms that resist necrotroph manipulation are recessive resistance genes. The barley rcs5 QTL imparts recessive resistance against the disease spot blotch caused by the hemi-biotrophic fungal pathogen Bipolaris sorokiniana. The rcs5 genetic interval was delimited to ~0.23 cM, representing an ~234 kb genomic region containing four wall-associated kinase (WAK) genes, designated HvWak2, Sbs1, Sbs2 (susceptibility to Bipolaris sorokiniana1&2), and HvWak5. Post-transcriptional gene silencing of Sbs1&2 in susceptible barley cultivars resulted in resistance showing dominant susceptibility function. Allele analysis of Sbs1&2 from resistant and susceptible barley cultivars identified sequence polymorphisms associated with phenotypes in their primary coding sequence and promoter regions, suggesting differential transcriptional regulation may contribute to susceptibility. Transcript analysis of Sbs1&2 showed nearly undetectable expression in resistant and susceptible cultivars prior to pathogen challenge; however, upregulation of both genes occurred specifically in susceptible cultivars post-inoculation with a virulent isolate. Apoplastic wash fluids collected from barley infected with a virulent isolate induced Sbs1, suggesting regulation by an apoplastic-secreted effector. Thus, Sbs1&2 function as B. sorokiniana susceptibility targets and non-functional alleles or alleles that resist induction by the pathogen mediate rcs5-recessive resistance. The sbs1&2 alleles underlying the rcs5 QTL that the pathogen is unable to manipulate are the first resistance genes identified against spot blotch.SIGNIFICANCE STATEMENTThe rcs5 locus in barley confers a high level of seedling resistance and a moderate level of adult plant resistance to spot blotch. It is part of a complex that has provided durable spot blotch resistance in many North American barley cultivars (cv) for more than 50 years. Genetic characterization and positional cloning of rcs5 identified the dominant susceptibility genes, Sbs1 and Sbs2 (susceptibility to Bipolaris sorokiniana 1 and 2) as wall-associated kinases. These genes are hijacked by the hemibiotrophic pathogen in its necrotrophic phase to induce programmed cell death, facilitating disease development. We report the first spot blotch resistance/susceptibility genes cloned that function via alleles that cannot be specifically induced and hijacked by virulent isolates of the pathogen.

Engineering multiple species-like genetic incompatibilities in insects

Speciation constrains the flow of genetic information between populations of sexually reproducing organisms. Gaining control over mechanisms of speciation would enable new strategies to manage wild populations of disease vectors, agricultural pests, and invasive species. Additionally, such control would provide safe biocontainment of transgenes and gene drives. Natural speciation can be driven by pre-zygotic barriers that prevent fertilization or by post-zygotic genetic incompatibilities that render the hybrid progeny inviable or sterile. Here we demonstrate a general approach to create engineered genetic incompatibilities (EGIs) in the model insect Drosophila melanogaster. Our system couples a dominant lethal transgene with a recessive resistance allele. EGI strains that are homozygous for both elements are fertile and fecund when they mate with similarly engineered strains, but incompatible with wild-type strains that lack resistant alleles. We show that EGI genotypes can be tuned to cause hybrid lethality at different developmental life-stages. Further, we demonstrate that multiple orthogonal EGI strains of D. melanogaster can be engineered to be mutually incompatible with wild-type and with each other. Our approach to create EGI organisms is simple, robust, and functional in multiple sexually reproducing organisms.