Stable introduction of Wolbachia wPip into invasive Anopheles stephensi for potential malaria control

The spread and invasion of the urban malaria vector Anopheles stephensi has emerged as a significant threat to ongoing malaria control and elimination efforts, particularly in Africa. The successful use of the maternally inherited endosymbiotic bacterium Wolbachia for arbovirus control has inspired the exploration of similar strategies for managing malaria vectors, necessitating the establishment of a stable Wolbachia-Anopheles symbiosis. In this study, we successfully transferred Wolbachia wPip into An. stephensi, resulting in the establishment of a stable transinfected HP1 line with 100% maternal transmission efficiency. We demonstrate that wPip in the HP1 line induces nearly complete unidirectional cytoplasmic incompatibility (CI) and maintains high densities in both somatic and germline tissues. Despite a modest reduction in lifespan and female reproductive capacity, our results suggest the Wolbachia infection in the HP1 line has little impact on life history traits, body size, and male mating competitiveness, as well as the ability of its larvae to tolerate rearing temperatures up to 38°C, although wPip densities moderately decrease when larvae are exposed to a constant 33°C and diurnal cyclic temperatures of 27–36°C and 27–38°C. These findings highlight the potential of the HP1 line as a robust candidate for further development in malaria control.Author summary: Recent efforts have successfully utilized the endosymbiotic bacterium Wolbachia to control mosquito-transmitted viral diseases like dengue in multiple countries. However, similar initiatives have been limited in combating malaria, the most devastating and deadly mosquito-borne disease, which claims over half a million lives each year. This is primarily due to the difficulty in establishing a stable, maternally inheritable Wolbachia infection in Anopheles, the mosquito vector responsible for malaria transmission. A significant concern in malaria control is the invasion of the urban malaria vector Anopheles stephensi into Africa, where malaria burden is highest, and over 40% of the population resides in urban areas. Building on the previous breakthrough of establishing Wolbachia strain wAlbB in An. stephensi, the author has now achieved a second stable infection by transferring the wPip strain from Culex pipiens into this mosquito species using embryonic microinjection. The resultant transinfected HP1 line induces nearly complete cytoplasmic incompatibility when crossed with wild mosquitoes, displays robust fitness and male mating competitiveness, and exhibits strong resilience against heat stress. These advantageous traits position the HP1 line as a promising candidate for further development in malaria control.