Normal microRNA Maturation and Germ-Line Stem Cell Maintenance Requires Loquacious, a Double-Stranded RNA-Binding Domain Protein

microRNAs (miRNAs) are single-stranded, 21- to 23-nucleotide cellular RNAs that control the expression of cognate target genes. Primary miRNA (pri-miRNA) transcripts are transformed to mature miRNA by the successive actions of two RNase III endonucleases. Drosha converts pri-miRNA transcripts to precursor miRNA (pre-miRNA); Dicer, in turn, converts pre-miRNA to mature miRNA. Here, we show that normal processing of Drosophila pre-miRNAs by Dicer-1 requires the double-stranded RNA-binding domain (dsRBD) protein Loquacious (Loqs), a homolog of human TRBP, a protein first identified as binding the HIV trans-activator RNA (TAR). Efficient miRNA-directed silencing of a reporter transgene, complete repression of white by a dsRNA trigger, and silencing of the endogenous Stellate locus by Suppressor of Stellate, all require Loqs. In loqs (f00791) mutant ovaries, germ-line stem cells are not appropriately maintained. Loqs associates with Dcr-1, the Drosophila RNase III enzyme that processes pre-miRNA into mature miRNA. Thus, every known Drosophila RNase-III endonuclease is paired with a dsRBD protein that facilitates its function in small RNA biogenesis

RNAi: an ever-growing puzzle

In recent years, sequence-specific gene silencing has been an area of increasing focus, both because of its interesting biology and because of its power as an experimental tool. A growing understanding of one such phenomenon, RNA interference (RNAi), has provided clues that many homology-dependent gene-silencing mechanisms share a common trigger, doublestranded RNA. Recent findings that RNAi and related pathways are involved not only in the response to exogenous pathogenic and endogenous parasitic nucleic acids but also in basic cellular processes, such as gene regulation and heterochromatin formation, have further fueled interest in this rapidly expanding field. The phenomenology of double-stranded RNA (dsRNA)induce

Biochemical specialization within Arabidopsis RNA silencing pathways

In plants, the RNA silencing machinery responds to numerous inputs, including viral infection, microRNAs, and endogenous siRNAs that may act both in trans and in cis. Additionally, the full spectrum of silencing outcomes has been demonstrated in plants, ranging from mRNA degradation to repression at the level of protein synthesis to chromatin remodeling. Genetic studies in Arabidopsis have indicated that individual response pathways are functionally compartmentalized. However, to date, no biochemical systems have been available to investigate the roles of specific proteins within silencing pathways or the effects of selected mutations on the biochemical activity of those components. Here, we describe the generation of Arabidopsis extracts that reproduce many aspects of RNA silencing reactions in vitro. We find that specific members of the Dicer and Argonaute families have distinct biochemical activities, which provides insight into their roles within RNA silencing pathways in Arabidopsis

The enemy within: intronic miR-26b represses its host gene, ctdsp2, to regulate neurogenesis

Stem cell differentiation is a highly coordinated process, and in this Perspective, Gage and colleagues highlight a study that reports a novel mechanism regulating neural differentiation (Dill and colleagues, in this issue). The authors discuss the finding that REST, a transcriptional regulator in neuronal stem cells that complexes with a CTDSP (a group of phosphatases), can be regulated by an intronic microRNA, miR-26b

Examining non-LTR retrotransposons in the context of the evolving primate brain

Abstract Researchers have long sought to understand the genetic basis of the cognitive differences between primates, with particular focus on the human brain. Although all mutational types have worked in concert with evolutionary forces to generate the current human brain, in this review we will explore the impact of mobile elements, specifically non-LTR retrotransposons. Non-LTR retrotransposons have contributed coding and regulatory sequences to the genome throughout evolution. During primate evolution there have been multiple waves of LINE retrotransposition as well as the birth of new mobile elements such as the SINEs Alu and SVA and we will explore what kinds of impacts these may have had on the evolving human brain