Comparing the long-term persistence of different Wolbachia strains after the release of bacteria-carrying mosquitoes
This paper proposes a bidimensional modeling framework for Wolbachia invasion, assuming imperfect maternal transmission, incomplete cytoplasmic incompatibility, and direct infection loss due to thermal stress. Our model adapts to various Wolbachia strains and retains all properties of higher-dimensi...
- Autores:
-
Cardona Salgado, Daiver
Sepúlveda Salcedo, Lilian Sofía
Orozco-Gonzales, Jose L.
dos Santos Benedito, Antone
Pio Ferreira, Claudia
de Oliveira Florentino, Helenice
Vasilieva, Olga
- Tipo de recurso:
- Article of investigation
- Fecha de publicación:
- 2024
- Institución:
- Universidad Autónoma de Occidente
- Repositorio:
- RED: Repositorio Educativo Digital UAO
- Idioma:
- eng
- OAI Identifier:
- oai:red.uao.edu.co:10614/16205
- Acceso en línea:
- https://hdl.handle.net/10614/16205
https://doi.org/10.1016/j.mbs.2024.109190
https://red.uao.edu.co/
- Palabra clave:
- Wolbachia
Aedes aegypti
Population dynamics
Imperfect maternal transmission
Incomplete CI
Infection loss
Stable coexistence
Pitch-fork bifurcation
Dinámica poblacional
Transmisión materna imperfecta
CI incompleto
Pérdida por infección
Coexistencia estable
Bifurcación en horquilla
- Rights
- openAccess
- License
- Derechos reservados - Elsevier, 2024
| Summary: | This paper proposes a bidimensional modeling framework for Wolbachia invasion, assuming imperfect maternal transmission, incomplete cytoplasmic incompatibility, and direct infection loss due to thermal stress. Our model adapts to various Wolbachia strains and retains all properties of higher-dimensional models. The conditions for the durable coexistence of Wolbachia-carrying and wild mosquitoes are expressed using the model’s parameters in a compact closed form. When the Wolbachia bacterium is locally established, the size of the remanent wild population can be assessed by a direct formula derived from the model. The model was tested for four Wolbachia strains undergoing laboratory and field trials to control mosquito-borne diseases: wMel, wMelPop, wAlbB, and wAu. As all these bacterial strains affect the individual fitness of mosquito hosts differently and exhibit different levels of resistance to temperature variations, the model helped to conclude that: (1) the wMel strain spreads faster in wild mosquito populations; (2) the wMelPop exhibits lower resilience but also guarantees the smallest size of the remanent wild population; (3) the wAlbB strain performs better at higher ambient temperatures than others; (4) the wAu strain is not sustainable and cannot persist in the wild mosquito population despite its resistance to high temperatures |
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