Like the RNA-silencing pathway, the core function of the interfer

Like the RNA-silencing pathway, the core function of the interferon pathway lies in the recognition of viral nucleic acids, including dsRNAs, by pattern recognition receptors such as Toll-like receptors, intracellular DExD/H box https://www.selleckchem.com/products/kpt-330.html helicases (RIG-I, MDA5), and kinases. These receptors discriminate “self” from “nonself” RNA by recognizing several key features of viral RNA, including

dsRNA and 5′-triphosphorylated ssRNA, which are not normally present in mammalian cells. Whether arthropods use a combination of sequence-specific and sequence-independent mechanisms to combat viral pathogens has yet to be fully elucidated. Antiviral RNA interference (RNAi) has been most extensively studied in plants and in the model invertebrate Drosophila melanogaster [1]. RNAi is one of several modes of RNA silencing in Drosophila, which include the miRNA pathway, which regulates endogenous genes, the piRNA pathway, which represses mobile genetic elements in the germline, and the endogenous siRNA pathway, which responds to transposons in the soma. RNAi

is initiated by the RNaseIII-like enzyme Dicer-2, which generates a 21nt RNA duplex from a larger dsRNA precursor molecule, such as a viral replication intermediate [2]. The resultant small interfering RNA duplex (siRNA) is loaded onto an Argonaute (Ago) protein, Ago2, within the RNA-induced silencing complex (RISC), where one strand of the duplex Wnt inhibitor is preferentially retained, allowing it to guide RISC to cleave the complimentary

sequence on the mRNA target [3]. Under the prevailing model for the function of the antiviral RNAi pathway, viral RNAs from RNA viruses are targeted by Dicer-2 to produce virus-derived siRNAs, which are incorporated into RISC to guide the slicing of cognate viral RNAs, thereby restricting viral replication (Fig. 1B). In support of this, Drosophila with mutations in the core siRNA machinery (Dcr-2 and AGO2) display increased sensitivity to infection by an ever-increasing aminophylline array of RNA viruses [4]. Moreover, additional cellular factors that contribute to antiviral silencing have been identified, including Ars2, Cbp20, and Cbp80, which facilitate the dicing activity of Dicer-2 and are required for antiviral defense [5]. Although some of the RNA viruses used in functional studies of the Drosophila RNAi pathway are natural Drosophila pathogens, such as Drosophila C virus, many of the other viruses studied, such as Sindbis virus, do not naturally infect Drosophila but rather are classified as arboviruses, which are medically important pathogens transmitted by hematophageous arthropods to vertebrates, including humans. For example, the study of the mosquito antiviral RNAi pathway is an important area of current investigation, since an understanding of the interaction between arboviruses and their natural vector may someday be harnessed to control medically important human pathogens.

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