Project description:Maturation of canonical microRNA (miRNA) is initiated by DROSHA that cleaves the primary transcript (pri-miRNA). Over 1,800 miRNA loci are annotated in humans, but it remains largely unknown if and at which sites the pri-miRNAs are cleaved by DROSHA. Here we performed in vitro processing on a full set of human pri-miRNAs (miRBase v21) followed by sequencing. This comprehensive profiling enabled us to classify miRNAs based on DROSHA-dependence and map their cleavage sites with respective processing efficiency measures. Only 758 pri-miRNAs are confidently processed by DROSHA, while the majority may be non-canonical or false entries. Analyses of the DROSHA-dependent pri-miRNAs show key cis-elements for processing. We observe widespread alternative processing as well as unproductive cleavage events such as “nick” or “inverse” processing. SRSF3 is a broad-acting auxiliary factor modulating alternative processing and suppressing unproductive processing. The profiling data and methods developed in this study will allow systematic analyses of miRNA regulation.

Project description:MicroRNA (miRNA) maturation is initiated by DROSHA, a double-stranded RNA (dsRNA)-specific RNase III enzyme. By cleaving primary miRNAs (pri-miRNAs) at specific positions, DROSHA serves as a main determinant of miRNA sequences and a highly selective gate-keeper for the canonical miRNA pathway. However, the sites of DROSHA-mediated processing have not been annotated on a genomic scale, and it remains unclear to what extent DROSHA functions outside the miRNA pathway. Here we establish a protocol termed ‘formaldehyde crosslinking and immunoprecipitation followed by sequencing (fCLIP-seq)’ that allows identification of DROSHA cleavage sites at single nucleotide resolution. fCLIP identifies numerous cleavage sites that do not match the ends of annotated mature miRNAs, particularly at the 3′ termini, suggesting widespread end modifications during miRNA maturation such as trimming and tailing. fCLIP also finds many pri-miRNAs undergoing alternative processing, yielding multiple miRNA isoforms. Moreover, we discover dozens of novel substrates that are bound and cleaved by DROSHA. These substrates are processed less efficiently than canonical pri-miRNAs, and produce only minute amounts of small RNAs. Depletion of DROSHA results in an increase of the hairpin-containing transcripts. Thus, the hairpins may serve mainly as cis-elements for DROSHA-mediated gene regulation rather than as miRNA genes. fCLIP-seq not only accurately maps the cleavage sites of DROSHA and suggests noncanonical functions of DROSHA, but also could be a general tool for investigating interactions between dsRNA binding proteins and structured RNAs.

Project description:MicroRNA (miRNA) maturation is initiated by DROSHA, a double-stranded RNA (dsRNA)-specific RNase III enzyme. By cleaving primary miRNAs (pri-miRNAs) at specific positions, DROSHA serves as a main determinant of miRNA sequences and a highly selective gate-keeper for the canonical miRNA pathway. However, the sites of DROSHA-mediated processing have not been annotated on a genomic scale, and it remains unclear to what extent DROSHA functions outside the miRNA pathway. Here we establish a protocol termed ‘formaldehyde crosslinking and immunoprecipitation followed by sequencing (fCLIP-seq)’ that allows identification of DROSHA cleavage sites at single nucleotide resolution. fCLIP identifies numerous cleavage sites that do not match the ends of annotated mature miRNAs, particularly at the 3′ termini, suggesting widespread end modifications during miRNA maturation such as trimming and tailing. fCLIP also finds many pri-miRNAs undergoing alternative processing, yielding multiple miRNA isoforms. Moreover, we discover dozens of novel substrates that are bound and cleaved by DROSHA. These substrates are processed less efficiently than canonical pri-miRNAs, and produce only minute amounts of small RNAs. Depletion of DROSHA results in an increase of the hairpin-containing transcripts. Thus, the hairpins may serve mainly as cis-elements for DROSHA-mediated gene regulation rather than as miRNA genes. fCLIP-seq not only accurately maps the cleavage sites of DROSHA and suggests noncanonical functions of DROSHA, but also could be a general tool for investigating interactions between dsRNA binding proteins and structured RNAs.

Project description:MicroRNA (miRNA) biogenesis begins with Drosha cleavage, the fidelity of which is critical for downstream processing and mature miRNA target specificity. To understand how pri-miRNA sequence and structure influence Drosha cleavage, we studied the processing of pri-miR-9-1 sequence variants, which encode the same mature miRNA but differ in the surrounding scaffold. We show that, in addition to previously known features, the overall structural flexibility of pri-miRNA impacts Drosha cleavage fidelity. Internal loops and nearby G·U wobble pairs on the pri-miRNA stem induce the use of non-canonical cleavage sites by Drosha, resulting in 5’ isomiR production. Here, we report the the miRNA-seq data of HEK293T cell lines transfected with different pri-miR-9 constructs.

Project description:Microprocessor (MP), cleaving primary microRNAs (pri-miRNAs) to initiate the biogenesis of thousands of miRNAs, was discovered in animals in 2004. Understanding the molecular mechanism of MP is critical for interpreting the gene-silencing roles of miRNAs in various cellular processes and human diseases. Though the molecular mechanism of human MP (hMP) has been comprehensively investigated for nearly two decades and is well understood, that of Caenorhabditis elegans MP (cMP, cDrosha-Pasha complex) is still unknown. In this study, we revealed a comprehensive molecular mechanism of cMP, distinctively from that of hMP. In the proposed mechanism, cDrosha and Pasha (DGCR8 in humans) measure ~16 bp and ~25 bp of the pri-miRNA stem, respectively, and they are coordinated in determining cleavage sites of cMP in pri-miRNAs. In addition, we also demonstrated the molecular basis for their substrate measurement. Our findings illustrate an unknown molecular mechanism of cMP, clarify differences between the mechanism of hMP and cMP, and provide a foundation for understanding multiple mechanisms regulating miRNA expression acting on cMP.

Project description:Maturation of canonical microRNA (miRNA) is initiated by DROSHA that cleaves the primary transcript (pri-miRNA). Over 1,800 miRNA loci are annotated in humans, but it remains largely unknown if and at which sites the pri-miRNAs are cleaved by DROSHA. Here we performed in vitro processing on a full set of human pri-miRNAs (miRBase v21) followed by sequencing. This comprehensive profiling enabled us to classify miRNAs based on DROSHA-dependence and map their cleavage sites with respective processing efficiency measures. Only 758 pri-miRNAs are confidently processed by DROSHA, while the majority may be non-canonical or false entries. Analyses of the DROSHA-dependent pri-miRNAs show key cis-elements for processing. We observe widespread alternative processing as well as unproductive cleavage events such as “nick” or “inverse” processing. SRSF3 is a broad-acting auxiliary factor modulating alternative processing and suppressing unproductive processing. The profiling data and methods developed in this study will allow systematic analyses of miRNA regulation.

Project description:Maturation of canonical microRNA (miRNA) is initiated by DROSHA that cleaves the primary transcript (pri-miRNA). Over 1,800 miRNA loci are annotated in humans, but it remains largely unknown if and at which sites the pri-miRNAs are cleaved by DROSHA. Here we performed in vitro processing on a full set of human pri-miRNAs (miRBase v21) followed by sequencing. This comprehensive profiling enabled us to classify miRNAs based on DROSHA-dependence and map their cleavage sites with respective processing efficiency measures. Only 758 pri-miRNAs are confidently processed by DROSHA, while the majority may be non-canonical or false entries. Analyses of the DROSHA-dependent pri-miRNAs show key cis-elements for processing. We observe widespread alternative processing as well as unproductive cleavage events such as “nick” or “inverse” processing. SRSF3 is a broad-acting auxiliary factor modulating alternative processing and suppressing unproductive processing. The profiling data and methods developed in this study will allow systematic analyses of miRNA regulation.

Project description:MicroRNA (miRNA) biogenesis begins with Drosha cleavage, the fidelity of which is critical for downstream processing and mature miRNA target specificity. To understand how pri-miRNA sequence and structure influence Drosha cleavage, we studied the processing of three pri-miR-9 paralogs (pri-miR-9-1, pri-miR-9-2 and pri-miR-9-3), which encode the same miRNA but differ in the surrounding scaffold. We show that pri-miR-9-1 has a unique Drosha cleavage profile due to its kinked tertiary structure. Cleavage of pri-miR-9-1, but not pri-miR-9-2 or pri-miR-9-3, generates an alternative-miR-9 with a shifted seed sequence that expands the scope of its target RNAs. Here, we report the the miRNA-seq data of HEK293T and HeLa cell lines transfected with different pri-miR-9 constructs.

Project description:MicroRNAs (miRNAs) are short non-coding RNAs that play essential roles in RNA silencing and gene regulation. The human Microprocessor (MP) is the key factor to initiate miRNA biogenesis by cleaving primary microRNAs (pri-miRNAs). However, the Microprocessor alone cannot precisely and efficiently cleave all pri-miRNAs; thus, it requires cofactors to assist its cleavage. SRSF3 interacts with CNNC in pri-miRNAs, enhancing the MP cleavage. However, it is unknown if SRSF3 can function with other non-CNNC motifs and if secondary structure might influce CNNC function. In addition, function of SRSF7, a paralog of SRSF3, in the SR proteins family, in miRNA biogenesis is largely unknown. In this study, by conducting the high-throughput pri-miRNA cleavage assays for the MP with SRSF3 or SRSF7 and randomized pri-miRNAs, we discovered that SRSF7 also stimulate MP clevage. Futhermore, we found that both SRSF3 and SRSF7 can function with some non-CNNC motifs and with CNNC motifs with certain secondary structures. Furthermore, we also demonstrated that SRSF7 and SRSF3 governed the cleavage sites of the Microprocessor in human cells. Our findings disclose the roles SRSF7 in miRNA biogenesis, demonstrate a compresenhive moleucalr mechanism of SFSF3 and SRSF7 in enhancing cleavage of MP and described in more detail the RNA-binding features of SRSF7 and SRSF3.

Project description:Biogenesis of canonical microRNAs (miRNAs) involves multiple steps: nuclear processing of primary miRNA (pri-miRNA) by DROSHA, nuclear export of precursor miRNA (pre-miRNA) by Exportin 5 (XPO5), and cytoplasmic processing of pre-miRNA by DICER. To gain a deeper understanding of the contribution of each of these maturation steps, we deleted DROSHA, XPO5, and DICER in the same human cell line, and analyzed their effects on miRNA biogenesis. Canonical miRNA production was completely abolished in DROSHA-deleted cells while we detected a few DROSHA-independent miRNAs including three previously unidentified noncanonical miRNAs (miR-7706, miR-3615, and miR-1254). In contrast to DROSHA knockout, many canonical miRNAs were still detected without DICER albeit at markedly reduced levels. In the absence of DICER, pre-miRNAs are loaded directly onto AGO and trimmed at the 3′ end, yielding miRNAs from the 5′ strand (5p miRNAs). Interestingly, in XPO5 knockout cells, most miRNAs are affected only modestly, suggesting that XPO5 is necessary but not critical for miRNA maturation. Our study demonstrates an essential role of DROSHA and an important contribution of DICER in the canonical miRNA pathway, and reveals that the function of XPO5 can be complemented by alternative mechanisms. Thus, this study allows us to understand differential contributions of key biogenesis factors, and provides with valuable resources for miRNA research. Two independent sequencing experiments (set 1 and set 2, respectively) were performed using 9 samples.