Your search keyword '"Chinmay V. Tikhe"' showing total 2 results

1. Phage Therapy for Mosquito Larval Control: a Proof-of-Principle Study

Author

Chinmay V. Tikhe and George Dimopoulos

Subjects

Anopheles, bacteriophage, bacteriophage therapy, larval development, Microbiology, QR1-502

Abstract

ABSTRACT The mosquito microbiota has a profound impact on multiple biological processes ranging from reproduction to disease transmission. Interestingly, the adult mosquito microbiota is largely derived from the larval microbiota, which in turn is dependent on the microbiota of their water habitat. The larval microbiota not only plays a crucial role in larval development but also has a significant impact on the adult stage of the mosquito. By precisely engineering the larval microbiota, it is feasible to alter larval development and other life history traits of the mosquitoes. Bacteriophages, given their host specificity, can serve as a tool for modulating the microbiota. For this proof-of-principle study, we selected representative strains of five common Anopheles mosquito-associated bacterial genera, namely, Enterobacter, Serratia, Pseudomonas, Elizabethkingia, and Asaia. Our results with monoaxenic cultures showed that Anopheles larvae with Enterobacter and Pseudomonas displayed normal larval development with no significant mortality. However, monoaxenic Anopheles larvae with Elizabethkingia showed delayed larval development and higher mortality. Serratia and Asaia gnotobiotic larvae failed to develop past the first instar. We isolated and characterized three novel bacteriophages (EP1, SP1, and EKP1) targeting Enterobacter, Serratia, and Elizabethkingia, respectively, and utilized a previously characterized bacteriophage (GH1) targeting Pseudomonas to modulate larval water microbiota. Gnotobiotic Anopheles larvae with all five bacterial genera showed reduced survival and larval development with the addition of bacteriophages EP1 and GH1, targeting Enterobacter and Pseudomonas, respectively. The effect was synergistic when both EP1 and GH1 were added together. Our results demonstrate a novel application of bacteriophages for mosquito control. IMPORTANCE Mosquitoes are efficient vectors of multiple human and animal pathogens. The biology of mosquitoes is strongly affected by their associated microbiota. Because of the important role of the larval microbiota in mosquito biology, the microbiota can potentially serve as a target for altering mosquito life-history traits. Our study provides proof of principle that bacteriophages can be used as tools to modulate the mosquito larval habitat microbiota and can, in turn, affect larval development and survival. These results highlight the utility of bacteriophages in mosquito microbiota research and also provide a new potential mosquito control tool.

Published

2022

2. Pleiotropic Odorant-Binding Proteins Promote Aedes aegypti Reproduction and Flavivirus Transmission

Author

Shengzhang Dong, Laurence J. Zwiebel, Zhijian Jake Tu, Chinmay V. Tikhe, Zi Ye, and George Dimopoulos

Subjects

Gland, Male, Identification, Odorant binding, feeding behavior, odorant-binding proteins, Aedes aegypti, Mosquito Vectors, Dengue virus, medicine.disease_cause, Receptors, Odorant, Arbovirus, Microbiology, Zika virus, Cell Line, Flavivirus Infections, OBP22, Mosquito, Aedes, Virology, Receptors, medicine, Animals, Vector (molecular biology), Chikungunya, Genetics, Crystal-Structure, biology, dengue virus, Flavivirus, Reproduction, fungi, Anopheles-Gambiae, virus transmission, biology.organism_classification, medicine.disease, QR1-502, OBP10, Insect Proteins, Female, blood feeding, CRISPR-Cas Systems, Life Sciences & Biomedicine, 0605 Microbiology, Research Article

Abstract

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. Published version

Published

2021