Agnieszka Zdanowicz scite author profile

SummaryTwo modes of refractoriness to Plasmodium , ookinete lysis and melanization, are known in the malaria vector, Anopheles gambiae . Melanization, a potent insect immune response, is manifested in a genetically selected refractory strain and in susceptible mosquitoes that are depleted of specific C-type lectins (CTLs). Here we use a systematic in vivo RNA interference-mediated reverse genetic screen and other recent results to define a melanizationregulating genetic module or network. It encompasses at least 14 genes, including those that encode five Easter-like clip domain serine proteases and four Masquerade-like serine protease homologues of the mosquito CLIPB and CLIPA subfamilies respectively. We show that several but not all CLIPB genes promote Plasmodium melanization, exhibiting partial functional overlap and synergy. We also report that several CLIPA genes have contrasting roles: CLIPA8 is essential for parasite melanization, while three other CLIPAs are novel synergistic inhibitors of this response. Importantly, the roles of certain CLIPAs and CLIPBs are strain specific, indicating that this network may differ between strains. Finally, we provide evidence that in susceptible mosquitoes melanization induced by knockdown of either CTL4 or CLIPA2/CLIPA5 directly kills ookinetes, in contrast to refractory mosquitoes where it merely disposes of dead parasites.

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Drosophila miR2 Primarily Targets the m7GpppN Cap Structure for Translational Repression

Zdanowicz

Thermann

Kowalska

et al. 2009

Molecular Cell

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Understanding the molecular mechanism(s) of how miRNAs repress mRNA translation is a fundamental challenge in RNA biology. Here we use a validated cell-free system from Drosophila embryos to investigate how miR2 inhibits translation initiation. By screening a library of chemical m7GpppN cap structure analogs, we identified defined modifications of the triphosphate backbone that augment miRNA-mediated inhibition of translation initiation but are "neutral" toward general cap-dependent translation. Interestingly, these caps also augment inhibition by 4E-BP. Kinetic dissection of translational repression and miR2-induced deadenylation shows that both processes proceed largely independently, with establishment of the repressed state involving a slow step. Our data demonstrate a primary role for the m7GpppN cap structure in miRNA-mediated translational inhibition, implicate structural determinants outside the core eIF4E-binding region in this process, and suggest that miRNAs may target cap-dependent translation through a mechanism related to the 4E-BP class of translational regulators.

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Agnieszka Zdanowicz

A genetic module regulates the melanization response of Anopheles to Plasmodium

Drosophila miR2 Primarily Targets the m7GpppN Cap Structure for Translational Repression

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