Your search keyword '"Li, Xinghan"' showing total 2 results

1. Control of Aedes mosquito populations using recombinant microalgae expressing short hairpin RNAs and their effect on plankton.

Author

Fei, Xiaowen, Xiao, Sha, Huang, Xiaodan, Li, Zhijie, Li, Xinghan, He, Changhao, Li, Yajun, Zhang, Xiuxia, and Deng, Xiaodong

Subjects

HAIRPIN (Genetics), MOSQUITO vectors, MOSQUITO control, MICROALGAE, AEDES aegypti, PLANKTON

Abstract

New biocontrol strategies are urgently needed to combat vector-borne infectious diseases. This study presents a low-cost method to produce a potential mosquito insecticide that utilizes the microalgae released into suburban water sources to control mosquito populations. Chlorella microalgae are ubiquitous in local waters, which were chosen as the host for genetic transfection. This species facilitated the recombinant algae to adapt to the prevailing environmental conditions with rapid growth and high relative abundance. The procedure involved microalgae RNAi-based insecticides developed using short hairpin RNAs targeting the Aedes aegypti chitin synthase A (chsa) gene in Chlorella. These insecticides effectively silenced the chsa gene, inhibiting Aedes metamorphosis in the laboratory and simulated-field trials. This study explored the impact of recombinant microalgae on the phytoplankton and zooplankton in suburban waters. High-throughput sequencing revealed that rapid reproduction of recombinant Chlorella indirectly caused the disappearance of some phytoplankton and reduced the protozoan species. This study demonstrated that a recombinant microalgae-based insecticide could effectively reduce the population of Aedes mosquitoes in the laboratory and simulated field trials. However, the impact of this technology on the environment and ecology requires further investigation. Author summary: A new low-cost strategy was developed to control vector mosquitoes safely. Chlorella was genetically modified to produce siRNA targeting the mosquito chsa gene, inhibiting gene expression after the larval stage. The inhibition prevented metamorphosis with high larval mortality in both Aedes aegypti and Aedes albopictus. The recombinant Chlorella performed well in the simulated field trials but impacted plankton populations in the released water, which indicates that the technology requires further optimization for field use. This approach is promising for biorational mosquito control to prevent mosquito-borne diseases. [ABSTRACT FROM AUTHOR]

Published

2023

2. Effect of marker-free transgenic Chlamydomonas on the control of Aedes mosquito population and on plankton.

Author

Fei, Xiaowen, Huang, Xiaodan, Li, Zhijie, Li, Xinghan, He, Changhao, Xiao, Sha, Li, Yajun, Zhang, Xiuxia, and Deng, Xiaodong

Subjects

MOSQUITO control, PLANKTON populations, CHLAMYDOMONAS, VECTOR control, PLANKTON, AEDES albopictus, GENE expression, TRANSGENIC plants

Abstract

Background: More than half of the world's population suffers from epidemic diseases that are spread by mosquitoes. The primary strategy used to stop the spread of mosquito-borne diseases is vector control. Interference RNA (RNAi) is a powerful tool for controlling insect populations and may be less susceptible to insect resistance than other strategies. However, public concerns have been raised because of the transfer of antibiotic resistance marker genes to environmental microorganisms after integration into the recipient genome, thus allowing the pathogen to acquire resistance. Therefore, in the present study, we modified the 3-hydroxykynurenine transaminase (3hkt) and hormone receptor 3 (hr3) RNAi vectors to remove antibiotic resistance marker genes and retain the expression cassette of the inverse repeat sequence of the 3hkt/hr3 target gene. This recombinant microalgal marker-free RNAi insecticide was subsequently added to the suburban water in a simulated-field trial to test its ability to control mosquito population. Methods: The expression cassette of the 3hkt/hr3 inverted repeat sequence and a DNA fragment of the argininosuccinate lyase gene without the ampicillin resistance gene were obtained using restriction enzyme digestion and recovery. After the cotransformation of Chlamydomonas, the recombinant algae was then employed to feed Aedes albopictus larvae. Ten and 300 larvae were used in small- and large-scale laboratory Ae.albopictus feeding trials, respectively. Simulated field trials were conducted using Meishe River water that was complemented with recombinant Chlamydomonas. Moreover, the impact of recombinant microalgae on phytoplankton and zooplankton in the released water was explored via high-throughput sequencing. Results: The marker-free RNAi-recombinant Chlamydomonas effectively silenced the 3hkt/hr3 target gene, resulting in the inhibition of Ae. albopictus development and also in the high rate of Ae. albopictus larvae mortality in the laboratory and simulated field trials. In addition, the results confirmed that the effect of recombinant Chlamydomonas on plankton in the released water was similar to that of the nontransgenic Chlamydomonas, which could reduce the abundance and species of plankton. Conclusions: The marker-free RNAi-recombinant Chlamydomonas are highly lethal to the Ae. albopictus mosquito, and their effect on plankton in released water is similar to that of the nontransgenic algal strains, which reduces the abundance and species of plankton. Thus, marker-free recombinant Chlamydomonas can be used for mosquito biorational control and mosquito-borne disease prevention. [ABSTRACT FROM AUTHOR]

Published

2023