Browsing by Author "Dong, Shengzhang"

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    Broad spectrum immunomodulatory effects of Anopheles gambiae microRNAs and their use for transgenic suppression of Plasmodium
    Dong, Shengzhang; Fu, Xiaonan; Dong, Yuemei; Simoes, Maria L.; Zhu, Jinsong; Dimopoulos, George (2020-04)
    Malaria, caused by the protozoan parasite Plasmodium and transmitted by Anopheles mosquitoes, represents a major threat to human health. Plasmodium's infection cycle in the Anopheles vector is critical for transmission of the parasite between humans. The midgut-stage bottleneck of infection is largely imposed by the mosquito's innate immune system. microRNAs (miRNAs, small noncoding RNAs that bind to target RNAs to regulate gene expression) are also involved in regulating immunity and the anti-Plasmodium defense in mosquitoes. Here, we characterized the mosquito's miRNA responses to Plasmodium infection using an improved crosslinking and immunoprecipitation (CLIP) method, termed covalent ligation of endogenous Argonaute-bound RNAs (CLEAR)-CLIP. Three candidate miRNAs' influence on P. falciparum infection and midgut microbiota was studied through transgenically expressed miRNA sponges (miR-SPs) in midgut and fat body tissues. MiR-SPs mediated conditional depletion of aga-miR-14 or aga-miR-305, but not aga-miR-8, increased mosquito resistance to both P. falciparum and P. berghei infection, and enhanced the mosquitoes' antibacterial defenses. Transcriptome analysis revealed that depletion of aga-miR-14 or aga-miR-305 resulted in an increased expression of multiple immunity-related and anti-Plasmodium genes in mosquito midguts. The overall fitness cost of conditionally expressed miR-SPs was low, with only one of eight fitness parameters being adversely affected. Taken together, our results demonstrate that targeting mosquito miRNA by conditional expression of miR-SPs may have potential for the development of malaria control through genetically engineered mosquitoes. Author summary Malaria is caused by the Plasmodium parasite that is transmitted by Anopheles mosquitoes. The mosquito's innate immune system plays an important role in controlling parasite infection. We have identified mosquito microRNAs (miRNAs) that are involved in regulating mosquito immunity to parasite infection. Transgenic mosquitoes that deplete the immunity-related miRNAs aga-miR-14 or aga-miR-305 through miRNA sponges, show increased resistance to both human and rodent parasite infection, and enhanced antibacterial defenses. Depletion of aga-miR-14 or aga-miR-305 resulted in an increased expression of multiple immunity-related and anti-Plasmodium genes, and the overall fitness cost of transgenic mosquitoes upon depletion of aga-miR-14 or aga-miR-305 was negligible. We show that targeting mosquito miRNA by transgenic expression of miRNA sponges may have potential for the development of malaria control through genetically engineered mosquitoes.
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    Pleiotropic Odorant-Binding Proteins Promote Aedes aegypti Reproduction and Flavivirus Transmission
    Dong, Shengzhang; Ye, Zi; Tikhe, Chinmay Vijay; Tu, Zhijian Jake; Zwiebel, Laurence J.; Dimopoulos, George (American Society for Microbiology, 2021-09-01)
    Insect odorant-binding proteins (OBPs) are small soluble proteins that have been assigned roles in olfaction, but their other potential functions have not been extensively explored. Using CRISPR/Cas9-mediated disruption of Aedes aegypti Obp10 and Obp22, we demonstrate the pleiotropic contribution of these proteins to multiple processes that are essential for vectorial capacity. Mutant mosquitoes have impaired host-seeking and oviposition behavior, reproduction, and arbovirus transmission. Here, we show that Obp22 is linked to the male-determining sex locus (M) on chromosome 1 and is involved in male reproduction, likely by mediating the development of spermatozoa. Although OBP10 and OBP22 are not involved in flavivirus replication, abolition of these proteins significantly reduces transmission of dengue and Zika viruses through a mechanism affecting secretion of viral particles into the saliva. These results extend our current understanding of the role of insect OBPs in insect reproduction and transmission of human pathogens, making them essential determinants of vectorial capacity. IMPORTANCE Aedes aegypti is the major vector for many arthropod-borne viral diseases, such as dengue, Zika, and chikungunya viruses. Previous studies suggested that odorant-binding proteins (OBPs) may have diverse physiological functions beyond the olfactory system in mosquitoes; however, these hypothesized functions have not yet been demonstrated. Here, we have used CRISPR/Cas9-based genome editing to functionally delete (knock out) Obp10 and Obp22 in Aedes aegypti. We showed that disruption of Obp10 or Obp22 significantly impairs female and male reproductive capacity by adversely affecting blood feeding, oviposition, fecundity and fertility, and the development of spermatozoa. We also showed that disruption of Obp10 or Obp22 significantly reduces the transmission of dengue and Zika viruses through a mechanism affecting secretion of viral particles into the saliva. Thus, our study is not only significant in understanding the functions of OBPs in mosquito biology, but also shows that OBPs may represent potent flavivirus transmission-blocking targets. Our study is in this regard particularly timely and important from a translational and public health perspective.