miRISC and the CCR4–NOT complex silence mRNA targets independently of 43S ribosomal scanning

miRNAs associate with Argonaute (AGO) proteins to silence the expression of mRNA targets by inhibiting translation and promoting deadenylation, decapping, and mRNA degradation. A current model for silencing suggests that AGOs mediate these effects through the sequential recruitment of GW182 proteins, the CCR4–NOT deadenylase complex and the translational repressor and decapping activator DDX6. An alternative model posits that AGOs repress translation by interfering with eIF4A function during 43S ribosomal scanning and that this mechanism is independent of GW182 and the CCR4–NOT complex in Drosophila melanogaster. Here, we show that miRNAs, AGOs, GW182, the CCR4–NOT complex, and DDX6/Me31B repress and degrade polyadenylated mRNA targets that are translated via scanning‐independent mechanisms in both human and Dm cells. This and additional observations indicate a common mechanism used by these proteins and miRNAs to mediate silencing. This mechanism does not require eIF4A function during ribosomal scanning.     

The interactions of GW182 proteins with PABP and deadenylases are required for both translational repression and degradation of miRNA targets

Animal miRNAs silence the expression of mRNA targets through translational repression, deadenylation and subsequent mRNA degradation. Silencing requires association of miRNAs with an Argonaute protein and a GW182 family protein. In turn, GW182 proteins interact with poly(A)-binding protein (PABP) and the PAN2–PAN3 and CCR4–NOT deadenylase complexes. These interactions are required for the deadenylation and decay of miRNA targets. Recent studies have indicated that miRNAs repress translation before inducing target deadenylation and decay; however, whether translational repression and deadenylation are coupled or represent independent repressive mechanisms is unclear. Another remaining question is whether translational repression also requires GW182 proteins to interact with both PABP and deadenylases. To address these questions, we characterized the interaction of Drosophila melanogaster GW182 with deadenylases and defined the minimal requirements for a functional GW182 protein. Functional assays in D. melanogaster and human cells indicate that miRNA-mediated translational repression and degradation are mechanistically linked and are triggered through the interactions of GW182 proteins with PABP and deadenylases.     

Specific features of the mature microrna nucleotide sequences can influence the affinity for the human Ago2 and Ago3 proteins

Mature microRNAs (miRNAs) with a length of 20–24 nucleotides are endogenous, small, non-coding RNAs. They program the RNA-induced silencing complex (RISC) to inhibit translation of the mRNAs carrying the sites complementary to these miRNAs. When the RISC contains Ago3, the mRNA translation is inhibited; however, in the case of Ago2, the mRNA can be also cleaved in the center of mRNA/miRNA heteroduplex. Using the earlier developed system ACTIVITY, we have analyzed the published data on the affinity of mature human miRNA sequences for the Ago2 and Ago3 proteins. It has been found that the higher the abundance of YRHB tetranucleotides near the miRNA 3′-end, the higher the miRNA affinity for both proteins (r = 0.613, α < 0.025) and that the miRNA binding to Ago2 increases relative to that Ago3 with the abundance of RHHK tetranucleotides near the miRNA center (r=0.501, α < 0.05). These two patterns allowed us to propose equations for predicting the affinity of mature miRNAs for the Ago2 and Ago3 proteins and to reliably predict the affinity of canonical (α < 0.00025) and noncanonical (α < 0.05) miRNAs for each protein using independent data.     

综述: 衰老相关microRNAs研究进展

microRNAs(miRNAs)是一类长度约22个核苷酸的非编码RNA.这是一种广泛存在于真核生物中的内源性单链小分子RNA,miRNAs通过部分碱基对互补方式与靶基因结合,在转录和转录后水平调节靶基因表达.最近研究发现,miRNAs可以靶向多个衰老相关信号通路,在线虫、果蝇、小鼠和人类的衰老过程中发挥了重要的调控作用.本文总结了近年来与衰老相关的miRNAs的研究进展,首先介绍衰老相关的信号通路,然后重点介绍与线虫和哺乳动物衰老有关的miRNAs,以及这些miRNAs如何调控衰老相关信号通路,从而影响细胞、组织和整个机体的衰老进程和衰老相关性疾病,最后展望该领域未来的研究方向.     

Deadenylation is a widespread effect of miRNA regulation

miRNAs silence gene expression by repressing translation and/or by promoting mRNA decay. In animal cells, degradation of partially complementary miRNA targets occurs via deadenylation by the CAF1-CCR4-NOT1 deadenylase complex, followed by decapping and subsequent exonucleolytic digestion. To determine how generally miRNAs trigger deadenylation, we compared mRNA expression profiles in D. melanogaster cells depleted of AGO1, CAF1, or NOT1. We show that ~60% of AGO1 targets are regulated by CAF1 and/or NOT1, indicating that deadenylation is a widespread effect of miRNA regulation. However, neither a poly(A) tail nor mRNA circularization are required for silencing, because mRNAs whose 3′ ends are generated by a self-cleaving ribozyme are also silenced in vivo. We show further that miRNAs trigger mRNA degradation, even when binding by 40S ribosomal subunits is inhibited in cis. These results indicate that miRNAs promote mRNA decay by altering mRNP composition and/or conformation, rather than by directly interfering with the binding and function of ribosomal subunits.     

The WEE1 regulators CPEB1 and miR-15b switch from inhibitor to activators at G2/M

MicroRNAs (miRNAs) in the AGO-containing RISC complex control messenger RNA (mRNA) translation by binding to mRNA 3′ untranslated region (3′UTR). The relationship between miRNAs and other regulatory factors that also bind to mRNA 3′UTR, such as CPEB1 (cytoplasmic polyadenylation element-binding protein), remains elusive. We found that both CPEB1 and miR-15b control the expression of WEE1, a key mammalian cell cycle regulator. Together, they repress WEE1 protein expression during G1 and S-phase. Interestingly, the 2 factors lose their inhibitory activity at the G2/M transition, at the time of the cell cycle when WEE1 expression is maximal, and, moreover, rather activate WEE1 translation in a synergistic manner. Our data show that translational regulation by RISC and CPEB1 is essential in cell cycle control and, most importantly, is coordinated, and can be switched from inhibition to activation during the cell cycle.     

Evaluation of reference genes for quantitative real-time PCR analysis of messenger RNAs and microRNAs in rainbow trout Oncorhynchus mykiss under heat stress

We assessed the expression stability of several messenger (m)RNAs and micro (mi)RNAs from liver and head kidney of rainbow trout Oncorhynchus mykiss using high-throughput RNA sequencing (RNA-seq) and miRNA-seq data. Additionally, four commonly used reference genes and one small non-coding RNA (u6) were also selected to identify ideal reference mRNAs and miRNAs for quantitative real-time (qrt)-PCR analysis of heat stress responses. GeNorm, NormFinder, BestKeeper and comparative ΔC_t were employed for analysis of qrt-PCR data to systematically assess the expression stability of candidate mRNAs and miRNAs and stability was ranked using geometric means. β-actin and ef1-α were the most stably expressed reference mRNAs in liver and head kidney, respectively and ssa-mir-26a-5p and ssa-mir-462b-5p were the most stably expressed miRNAs in these tissues. This is the first identification of appropriate reference mRNAs and miRNAs for qrt-PCR analysis of O. mykiss under heat stress.     

Interaction of long noncoding RNA MEG3 with miRNAs: A reciprocal regulation

The competitive endogenous RNA (ceRNA) hypothesis suggests that a long noncoding RNA (lncRNA) can function as sinks for pools of microRNAs (miRNAs); thereby, in the presence of ceRNA, messenger RNAs (mRNAs) targeted by specific miRNAs can liberate and translate to protein. Maternally expressed gene 3 (MEG3) is a lncRNA, which its expression has been detected in various normal tissues, while it is lost or downregulated in human tumors. The MEG3 is an imprinted gene which, is methylated and suppressed by DNA methyltransferases (DNMTs) family. Also, miRNAs are involved in the regulation of MEG3 gene expression. Interestingly, the lncRNA MEG3 (lnc-MEG3), as a ceRNA affects various cell processes such as proliferation, apoptosis, and angiogenesis by sponging miRNAs. These miRNAs, in turn, regulate different mRNAs in different pathways. This review focuses on the interaction between lnc-MEG3 and experimentally validated miRNAs. In addition, the discussion supplemented by some data obtained from mirPath (v.3) and TarBase (v.8) databanks to provide more details about the pathways affected by this ceRNA.     

Simple gene silencing using the trans‐acting siRNA pathway

In plants, particular micro‐RNAs (miRNAs) induce the production of a class of small interfering RNAs (siRNA) called trans‐acting siRNA (ta‐siRNA) that lead to gene silencing. A single miRNA target is sufficient for the production of ta‐siRNAs, which target can be incorporated into a vector to induce the production of siRNAs, and ultimately gene silencing. The term miRNA‐induced gene silencing (MIGS) has been used to describe such vector systems in Arabidopsis. Several ta‐siRNA loci have been identified in soybean, but, prior to this work, few of the inducing miRNAs have been experimentally validated, much less used to silence genes. Nine ta‐siRNA loci and their respective miRNA targets were identified, and the abundance of the inducing miRNAs varies dramatically in different tissues. The miRNA targets were experimentally verified by silencing a transgenic GFP gene and two endogenous genes in hairy roots and transgenic plants. Small RNAs were produced in patterns consistent with the utilization of the ta‐siRNA pathway. A side‐by‐side experiment demonstrated that MIGS is as effective at inducing gene silencing as traditional hairpin vectors in soybean hairy roots. Soybean plants transformed with MIGS vectors produced siRNAs and silencing was observed in the T1 generation. These results complement previous reports in Arabidopsis by demonstrating that MIGS is an efficient way to produce siRNAs and induce gene silencing in other species, as shown with soybean. The miRNA targets identified here are simple to incorporate into silencing vectors and offer an effective and efficient alternative to other gene silencing strategies.