Your search keyword '"Sánchez C HM"' showing total 4 results

1. Targeting sex determination to suppress mosquito populations.

Author

Li M, Kandul NP, Sun R, Yang T, Benetta ED, Brogan DJ, Antoshechkin I, Sánchez C HM, Zhan Y, DeBeaubien NA, Loh YM, Su MP, Montell C, Marshall JM, and Akbari OS

Subjects

Humans, Male, Animals, Mosquito Vectors genetics, Disease Vectors, Species Specificity, Aedes genetics, Infertility, Male, Zika Virus, Zika Virus Infection prevention & control

Abstract

Each year, hundreds of millions of people are infected with arboviruses such as dengue, yellow fever, chikungunya, and Zika, which are all primarily spread by the notorious mosquito Aedes aegypti . Traditional control measures have proven insufficient, necessitating innovations. In response, here we generate a next-generation CRISPR-based precision-guided sterile insect technique (pgSIT) for Ae. aegypti that disrupts genes essential for sex determination and fertility, producing predominantly sterile males that can be deployed at any life stage. Using mathematical models and empirical testing, we demonstrate that released pgSIT males can effectively compete with, suppress, and eliminate caged mosquito populations. This versatile species-specific platform has the potential for field deployment to effectively control wild populations of disease vectors., Competing Interests: ML, NK A founder of Synvect with equity interest. The terms of this arrangement have been reviewed and approved by the University of California, San Diego in accordance with its conflict of interest policies, RS, TY, EB, DB, IA, HS, YZ, ND, YL, MS, CM, JM No competing interests declared, OA A founder of Agragene, Inc with equity interest. A founder of Synvect with equity interest. The terms of this arrangement have been reviewed and approved by the University of California, San Diego in accordance with its conflict of interest policies, (© 2023, Li et al.)

Published

2024

2. Suppressing mosquito populations with precision guided sterile males.

Author

Li M, Yang T, Bui M, Gamez S, Wise T, Kandul NP, Liu J, Alcantara L, Lee H, Edula JR, Raban R, Zhan Y, Wang Y, DeBeaubien N, Chen J, Sánchez C HM, Bennett JB, Antoshechkin I, Montell C, Marshall JM, and Akbari OS

Subjects

Aedes genetics, Animals, Animals, Genetically Modified, Arboviruses, Chikungunya Fever prevention & control, Chikungunya Fever transmission, Chikungunya Fever virology, Dengue prevention & control, Dengue transmission, Dengue virology, Female, Humans, Infertility, Male genetics, Male, Models, Biological, Mosquito Vectors genetics, Yellow Fever prevention & control, Yellow Fever transmission, Yellow Fever virology, Zika Virus, Zika Virus Infection prevention & control, Zika Virus Infection transmission, Zika Virus Infection virology, Aedes virology, Infertility, Male veterinary, Mosquito Control methods, Mosquito Vectors virology

Abstract

The mosquito Aedes aegypti is the principal vector for arboviruses including dengue/yellow fever, chikungunya, and Zika virus, infecting hundreds of millions of people annually. Unfortunately, traditional control methodologies are insufficient, so innovative control methods are needed. To complement existing measures, here we develop a molecular genetic control system termed precision-guided sterile insect technique (pgSIT) in Aedes aegypti. PgSIT uses a simple CRISPR-based approach to generate flightless females and sterile males that are deployable at any life stage. Supported by mathematical models, we empirically demonstrate that released pgSIT males can compete, suppress, and even eliminate mosquito populations. This platform technology could be used in the field, and adapted to many vectors, for controlling wild populations to curtail disease in a safe, confinable, and reversible manner., (© 2021. The Author(s).)

Published

2021

3. Modeling confinement and reversibility of threshold-dependent gene drive systems in spatially-explicit Aedes aegypti populations.

Author

Sánchez C HM, Bennett JB, Wu SL, Rašić G, Akbari OS, and Marshall JM

Subjects

Animals, Models, Genetic, Queensland, Aedes genetics, Gene Drive Technology, Mosquito Control methods, Mosquito Vectors genetics

Abstract

Background: The discovery of CRISPR-based gene editing and its application to homing-based gene drive systems has been greeted with excitement, for its potential to control mosquito-borne diseases on a wide scale, and concern, for the invasiveness and potential irreversibility of a release. Gene drive systems that display threshold-dependent behavior could potentially be used during the trial phase of this technology, or when localized control is otherwise desired, as simple models predict them to spread into partially isolated populations in a confineable manner, and to be reversible through releases of wild-type organisms. Here, we model hypothetical releases of two recently engineered threshold-dependent gene drive systems-reciprocal chromosomal translocations and a form of toxin-antidote-based underdominance known as UD MEL -to explore their ability to be confined and remediated., Results: We simulate releases of Aedes aegypti, the mosquito vector of dengue, Zika, and other arboviruses, in Yorkeys Knob, a suburb of Cairns, Australia, where previous biological control interventions have been undertaken on this species. We monitor spread to the neighboring suburb of Trinity Park to assess confinement. Results suggest that translocations could be introduced on a suburban scale, and remediated through releases of non-disease-transmitting male mosquitoes with release sizes on the scale of what has been previously implemented. UD MEL requires fewer releases to introduce, but more releases to remediate, including of females capable of disease transmission. Both systems are expected to be confineable to the release site; however, spillover of translocations into neighboring populations is less likely., Conclusions: Our analysis supports the use of translocations as a threshold-dependent drive system capable of spreading disease-refractory genes into Ae. aegypti populations in a confineable and reversible manner. It also highlights increased release requirements when incorporating life history and population structure into models. As the technology nears implementation, further ecological work will be essential to enhance model predictions in preparation for field trials.

Published

2020

4. Development of a confinable gene drive system in the human disease vector Aedes aegypti .

Author

Li M, Yang T, Kandul NP, Bui M, Gamez S, Raban R, Bennett J, Sánchez C HM, Lanzaro GC, Schmidt H, Lee Y, Marshall JM, and Akbari OS

Subjects

Aedes physiology, Animals, Animals, Genetically Modified genetics, Animals, Genetically Modified physiology, CRISPR-Cas Systems genetics, Female, Male, Mosquito Vectors physiology, RNA, Guide, CRISPR-Cas Systems genetics, Aedes genetics, Gene Drive Technology, Mosquito Vectors genetics

Abstract

Aedes aegypti is the principal mosquito vector for many arboviruses that increasingly infect millions of people every year. With an escalating burden of infections and the relative failure of traditional control methods, the development of innovative control measures has become of paramount importance. The use of gene drives has sparked significant enthusiasm for genetic control of mosquitoes; however, no such system has been developed in Ae. aegypti . To fill this void, here we develop several CRISPR-based split gene drives for use in this vector. With cleavage rates up to 100% and transmission rates as high as 94%, mathematical models predict that these systems could spread anti-pathogen effector genes into wild populations in a safe, confinable and reversible manner appropriate for field trials and effective for controlling disease. These findings could expedite the development of effector-linked gene drives that could safely control wild populations of Ae. aegypti to combat local pathogen transmission., Competing Interests: ML, TY, NK, MB, SG, RR, JB, HS, GL, HS, YL, JM, OA No competing interests declared, (© 2020, Li et al.)

Published

2020