Aberrant brain microRNA target and miRISC gene expression in the anx/anx anorexia mouse model.

The anorexia mouse model, anx/anx, carries a spontaneous mutation not yet identified and homozygous mutants are characterized by anorexia-cachexia, hyperactivity, and ataxia. In order to test if the microRNA function was altered in these mice, hypothalamus and cortex transcriptomes were evaluated and the data was analyzed taking into account the presence of microRNA target sites. Subsequent validation of the expression of a subset of miRISC coding genes and microRNA targets was performed by TaqMan real time PCR. In anx/anx hypothalamus we found that predicted microRNA targets were preferentially upregulated in a linearly dependent manner according to the number of microRNA target sites in each mRNA (p=10(-139)). Conversely, we observed that in anx/anx cortex mRNAs predicted to be targeted by microRNAs were preferentially downregulated (p<10(-74)), suggesting a de-regulation of genes targeted by microRNAs in two brain areas in anx/anx mice. A closer look to the mRNA transcriptome allowed us to identify upregulation of five miRISC genes, including Dgcr8 and Fmr1, and Ago2, which were later confirmed by real time PCR. The results suggest alteration of microRNA machinery expression in anx/anx mice and are consistent with its involvement in inflammatory/cancer-associated anorexia-cachexia. The data also support the previously reported link between microRNA machinery and ataxia. Further functional studies and the cloning of the anx gene should be pursued in order to elucidate the causality of microRNA machinery and microRNA target de-regulation, its relationship with the anx/anx phenotype and to propose this mouse as a model for microRNA research.

Slicer function of Drosophila Argonautes and its involvement in RISC formation.

Argonaute proteins play important yet distinct roles in RNA silencing. Human Argonaute2 (hAgo2) was shown to be responsible for target RNA cleavage ("Slicer") activity in RNA interference (RNAi), whereas other Argonaute subfamily members do not exhibit the Slicer activity in humans. In Drosophila, AGO2 was shown to possess the Slicer activity. Here we show that AGO1, another member of the Drosophila Argonaute subfamily, immunopurified from Schneider2 (S2) cells associates with microRNA (miRNA) and cleaves target RNA completely complementary to the miRNA. Slicer activity is reconstituted with recombinant full-length AGO1. Thus, in Drosophila, unlike in humans, both AGO1 and AGO2 have Slicer functions. Further, reconstitution of Slicer activity with recombinant PIWI domains of AGO1 and AGO2 demonstrates that other regions in the Argonautes are not strictly necessary for small interfering RNA (siRNA)-binding and cleavage activities. It has been shown that in circumstances with AGO2-lacking, the siRNA duplex is not unwound and consequently an RNA-induced silencing complex (RISC) is not formed. We show that upon addition of an siRNA duplex in S2 lysate, the passenger strand is cleaved in an AGO2-dependent manner, and nuclease-resistant modification of the passenger strand impairs RISC formation. These findings give rise to a new model in which AGO2 is directly involved in RISC formation as "Slicer" of the passenger strand of the siRNA duplex.