Abstract
Arthropod-borne viruses are major causes of human and animal disease, especially in endemic low- and middle-income countries. Mosquito-borne pathogen surveillance is essential for risk assessment and vector control responses. Sentinel chicken serosurveillance (antibody testing) and mosquito pool screening (by RT-qPCR or virus isolation) are currently used to monitor arbovirus transmission, however substantial time lags of seroconversion and/or laborious mosquito identification and RNA extraction steps sacrifice their early warning value. As a consequence, timely vector control responses are compromised. Here, we report on development of a rapid arbovirus detection system whereby adding sucrose to reagents of loop-mediated isothermal amplification with displaced probes (DP-LAMP) elicits infectious mosquitoes to feed directly upon the reagent mix and expectorate viruses into the reagents during feeding. We demonstrate that RNA from pathogenic arboviruses (West Nile and Dengue viruses) transmitted in the infectious mosquito saliva was detectable rapidly (within 45 minutes) without RNA extraction. Sucrose stabilized viral RNA at field temperatures for at least 48 hours, important for transition of this system to practical use. After thermal treatment, the DP-LAMP could be reliably visualized by a simple optical image sensor to distinguish between positive and negative samples based on fluorescence intensity. Field application of this technology could fundamentally change conventional arbovirus surveillance methods by eliminating laborious RNA extraction steps, permitting arbovirus monitoring from additional sites, and substantially reducing time needed to detect circulating pathogens.
Funder
Centers for Disease Control and Prevention
Florida Department of Agriculture and Consumer Services
Publisher
Public Library of Science (PLoS)
Reference58 articles.
1. World Health Organization, Global vector control response 2017–2030. https://www.who.int/publications/i/item/9789241512978. Accessed March 3, 2023. (2017).
2. Effective mechanisms to control mosquito borne diseases: a review;MA Shaukat;Clin Neurol Neurosurg,2019
3. Revamping mosquito-borne disease control to tackle future threats;JN Fernandes;Trends Parasitol,2018
4. Improved tools and strategies for the prevention and control of arboviral diseases: A research-to-policy forum;P Olliaro;PLoS Negl Trop Dis,2018
5. Effective surveillance systems for vector-borne diseases in urban settings and translation of the data into action: a scoping review;F Fournet;Infect Dis Poverty,2018