Last Updated: 25/11/2025

MicroRNA regulation of Anopheles immunity to Plasmodium

Objectives

The main of this study is to identify microRNAs (miRNAs) used by mosquitoes to modulate their defense against Plasmodium infection and will determine whether manipulating the levels of the selected miRNAs can lead to enhanced mosquito resistance to Plasmodium infection. This study will investigate whether these identified miRNAs affect the survival of Plasmodium parasites, when and where the regulation takes place, and which genes are regulated (directly or indirectly) by the miRNAs during midgut invasion by Plasmodium ookinetes.

The specific aims of this project are to:

Identify miRNA-mRNA interactions affected by P. falciparum infection of the midgut epithelium in An. gambiae;
Select miRNAs that play important regulatory roles in anti-Plasmodium defense; and
Use transgenic expression of miRNAs or miRNA sponges to enhance mosquito resistance to Plasmodium infection.

Principal Institution

Virginia Tech, United States

Principal Investigators / Focal Persons

Jinsong Zhu

Partner Investigators

George Dimopoulos

Rationale and Abstract

Malaria is caused by Plasmodium parasites and is transmitted to humans by female Anopheles mosquitoes. Current malaria control measures may not be sufficient to achieve effective control and elimination. There is an urgent need to advance our understanding of the vector’s biological processes that can potentially be exploited in an effort to block malaria transmission. The mosquito’s innate immunity plays a pivotal role in the interaction between the malaria parasites and the mosquito vector, and is a determining factor of vectorial capacity. miRNAs are small endogenous RNA molecules that post-transcriptionally regulate gene expression. They recognize their target mRNA transcripts through partial sequence complementarity. miRNAs have been shown to act as master regulators by targeting multiple genes involved in the same biological process. The preliminary studies clearly demonstrate that miRNAs are involved in modulating the mosquito defense response to malaria parasites. The researchers have performed a genome-wide analysis of miRNA-mRNA interactions and discovered that the transcripts of some mosquito immune genes are differentially regulated by certain miRNAs in response to Plasmodium infection. The proposed study addresses a serious gap in the understanding of miRNA function in mosquito- Plasmodium interactions, and may provide novel molecular targets for blocking malaria transmission.

Project Outputs

Article - Versatile transgenic multistage effector-gene combinations for Plasmodium falciparum suppression in Anopheles Article - Additional Feeding Reveals Differences in Immune Recognition and Growth of Plasmodium Parasites in the Mosquito Host Article - Transcriptome Profiles of Anopheles gambiae Harboring Natural Low-Level Plasmodium Infection Reveal Adaptive Advantages for the Mosquito Article - Transcriptome profiles of Anopheles gambiae harboring natural low-level Plasmodium infection reveal adaptive advantages for the mosquito Article - Targeting the mosquito prefoldin–chaperonin complex blocks Plasmodium transmission

External reference

NIH project details

Themes

Basic Science
Enabling Technologies & Assays
Genetics and Genomics

Date

Dec 2015 — Nov 2021

Total Project Funding

$3.34M

Funding Details

National Institute of Allergy and Infectious Diseases (NIAID), National Institutes of Health (NIH), United States