Advances in CRISPR gene drives for mosquito population control

CRISPR-based gene drive (GD) systems bias allele inheritance during meiosis, enabling transgenes to spread at rates exceeding Mendel’s law of segregation. This capability underlies their potential as powerful tools for controlling mosquito-borne diseases. GDs can be engineered either to suppress mosquito populations or to modify them by introducing traits that block pathogen transmission. Recent advances have focused on improving evolutionary stability, with modeling studies providing insights into expected population dynamics. With a focus on the most current population modification GDs, we discuss advances in GD architectures — including integral and allelic drives, combined modification–suppression systems, and both homing and non-homing toxin–antidote designs — that expand the range of possible strategies and address limitations of early homing drives. Numerous antipathogen effectors with strong pathogen-blocking activity can now be coupled to these systems, with current efforts assessing their durability against genetically diverse pathogens. Key challenges remain, including resistance evolution, ecological impacts, and long-term stability. Nonetheless, GDs offer a promising approach for reducing disease transmission, especially in regions where conventional interventions are difficult to sustain.