Potential roles for short RNAs in lymphocytes

RNA interference (RNAi) is an ancient and evolutionarily conserved process. In some eukaryotes, RNAi silences parasitic genetic elements. In plants, RNAi serves as an immune system against RNA viruses and transgenes and in worms, RNAi silences transposons. In mammals, RNAi has yet unknown functions. However, emerging roles for short RNAs and the factors that interact with them in other eukaryotes include chromatin modification, DNA deletion and DNA methylation, which may provide clues to the roles for short RNA function in mammals. For example, antigen receptor expression in lymphocytes is a highly regulated process and although much is known about chromatin modification and DNA deletion in the immune system, several molecular details of chromatin regulation remain elusive. This review compares emerging roles for short RNA function to processes required for antigen receptor expression in mammalian lymphocytes and predicts that short RNAs direct events required for successful lymphocyte-restricted gene expression.     

Inputs and outputs for chromatin-targeted RNAi

Plant gene silencing is targeted to transposons and repeated sequences by small RNAs from the RNA interference (RNAi) pathway. Like classical RNAi, RNA-directed chromatin silencing involves the cleavage of double-stranded RNA by Dicer endonucleases to create small interfering RNAs (siRNAs), which bind to the Argonaute protein. The production of double-stranded RNA (dsRNA) must be carefully controlled to prevent inappropriate silencing. A plant-specific RNA polymerase IV (Pol IV) initiates siRNA production at silent heterochromatin, but Pol IV-independent mechanisms for making dsRNA also exist. Downstream of siRNA biogenesis, multiple chromatin marks might be targeted by Argonaute-siRNA complexes, yet mechanisms of chromatin modification remain poorly understood. Genomic studies of siRNA target loci promise to reveal novel biological functions for chromatin-targeted RNAi.     

Uncovering RNAi mechanisms in plants: biochemistry enters the foray

In plants, the RNA interference (RNAi) machinery responds to a variety of triggers including viral infection, transgenes, repeated elements and transposons. All of these triggers lead to silencing outcomes ranging from mRNA degradation to translational repression to chromatin remodeling. Thus, plants offer us a potentially unique opportunity to understand the full range of RNAi effector mechanisms. In this review, we discuss the recent developments in our understanding of plant RNAi mechanisms from a biochemical perspective.     

RNA干扰与染色质沉默——生物体内精密的网络调控机制

基因表达受不同层次的调控.RNA干扰通过产生双链小RNA诱导同源mRNA序列降解,从而在转录后抑制特定基因的表达.最新的研究成果显示：RNA干扰产生的双链小RNA可通过与染色质中的重复序列DNA及组蛋白甲基化酶相互作用,引起组蛋白H3 Lys9的甲基化,进一步与异染色质形成相关蛋白结合,导致染色质沉默.综述了RNA干扰,小RNA,组蛋白修饰,染色质沉默及基因表达调控之间存在着精密的网络调控机制.     

The long and the short of it: RNA-directed chromatin asymmetry in mammalian X-chromosome inactivation

Mammalian X-chromosome inactivation is controlled by a multilayered silencing pathway involving both short and long non-coding RNAs, which differentially recruit the epigenetic machinery to establish chromatin asymmetries. In response to developmentally regulated small RNAs, dicer, a key effector of RNA interference, locally silences Xist on the active X-chromosome and establishes the heterochromatin conformation along the silent X-chromosome. The 1.6 kb RepA RNA initiates silencing by targeting the PRC2 polycomb complex to the inactive X-chromosome. In addition, the nuclear microenvironment is implicated in the initiation and maintenance of X-chromosome asymmetries. Here we review new findings involving these various RNA species in terms of understanding Xist gene regulation and the establishment of X-chromosome inactivation.     

RNAi-independent de novo DNA methylation revealed in Arabidopsis mutants of chromatin remodeling gene DDM1

Methylation of histone H3 lysine 9 (H3K9me) and small RNAs are associated with constitutively silent chromatin in diverse eukaryotes including plants. In plants, silent transposons are also marked by cytosine methylation, especially at non‐CpG sites. Transposon‐specific non‐CpG methylation in plants is controlled by small RNAs and H3K9me. Although it is often assumed that small RNA directs H3K9me, interaction between small RNA and H3K9me has not been directly demonstrated in plants. We have previously shown that a mutation in the chromatin remodeling gene DDM1 (DECREASE IN DNA METHYLATION 1) induces a global decrease but a local increase of cytosine methylation and accumulation of small RNA at a locus called BONSAI. Here we show that de novo BONSAI methylation does not depend on RNAi but does depend on H3K9me. In mutants of H3K9 methyltransferase gene KRYPTONITE or the H3K9me‐dependent DNA methyltransferase gene CHROMOMETHYALSE3, the ddm1‐induced de novo cytosine methylation was abolished for all three contexts (CpG, CpHpG and CpHpH). Furthermore, RNAi mutants showed strong developmental defects when combined with the ddm1 mutation. Our results revealed unexpected interactions of epigenetic modifications that may be conserved among diverse eukaryotes.