Double-tap gene drive uses iterative genome targeting to help overcome resistance alleles

Homing CRISPR gene drives could aid in curbing the spread of vector-borne diseases and controlling crop pest and invasive species populations due to an inheritance rate that surpasses Mendelian laws. However, this technology suffers from resistance alleles formed when the drive-induced DNA break is...

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Bibliographic Details
Published in:Nature communications 2022-05, Vol.13 (1), p.2595-2595, Article 2595
Main Authors: Bishop, Alena L., López Del Amo, Víctor, Okamoto, Emily M., Bodai, Zsolt, Komor, Alexis C., Gantz, Valentino M.
Format: Article
Language:English
Subjects:
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Alleles
Animals
CRISPR
CRISPR-Cas Systems - genetics
DNA damage
Gene Drive Technology
Genomes
Germ Cells
gRNA
Heredity
Humanities and Social Sciences
Infectious diseases
Introduced species
Invasive species
Mammalian cells
Mammals - genetics
Mice
multidisciplinary
Mutation
Nonnative species
Pest control
Pest resistance
Pests
Population genetics
Populations
RNA, Guide, CRISPR-Cas Systems - genetics
Science
Science (multidisciplinary)
Vector-borne diseases
Vectors (Biology)
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Description
Summary:Homing CRISPR gene drives could aid in curbing the spread of vector-borne diseases and controlling crop pest and invasive species populations due to an inheritance rate that surpasses Mendelian laws. However, this technology suffers from resistance alleles formed when the drive-induced DNA break is repaired by error-prone pathways, which creates mutations that disrupt the gRNA recognition sequence and prevent further gene-drive propagation. Here, we attempt to counteract this by encoding additional gRNAs that target the most commonly generated resistance alleles into the gene drive, allowing a second opportunity at gene-drive conversion. Our presented “double-tap” strategy improved drive efficiency by recycling resistance alleles. The double-tap drive also efficiently spreads in caged populations, outperforming the control drive. Overall, this double-tap strategy can be readily implemented in any CRISPR-based gene drive to improve performance, and similar approaches could benefit other systems suffering from low HDR frequencies, such as mammalian cells or mouse germline transformations. CRISPR gene drives are genetic elements capable of quickly spreading through populations and they offer promising solutions for curbing the spread of vector-borne diseases and controlling crop pest and invasive species populations. Here the authors present a method for overcoming resistance alleles “double-tap,” that encodes additional gRNAs in the gene drive that target the most common generated resistance alleles.
ISSN:2041-1723
2041-1723
DOI:10.1038/s41467-022-29868-3