Project description:We investigated how suppression of the most upstream microRNA–processing RNase, Drosha, affects the differentiation of human CD34+ hematopoietic stem–progenitor cells (HSPCs). We hypothesized that knock-down of Drosha would alter blood lineage development by modulating the expression of microRNAs. Lentiviral delivery to HSPCs of a short-hairpin targeting Drosha resulted in a viable phenotype with promotion of myeloid, and especially monocytic, maturation and suppression of apoptosis. Our results show that Drosha deficiency triggered a parallel upregulation of components of the RNAi machinery, including DGCR8, Dicer and Ago2. Deep sequencing analyses revealed global miRNA deficiency after Drosha short-hairpin treatment with relative maintenance of mature miR-223 expression. Restoration of miR-223 to normal levels after Drosha knock-down further enhanced monocytic maturation concomitant with the modulation of myeloid transcription factors that promoted monocytic differentiation. Our results support a miRNA accentuation model in which relative enhancement of miR-223 increases levels of PU.1 thereby promoting monocytic differentiation.

Project description:Genome-wide expression differences are compared for a normal and mutant cell line. The data compares the effect of a gene mutation on genome-wide expression. empty vector (EV), shDrosha (shDr); shDr denotes hematopoietic stem-progenitor cells (HSPCs) transduced with a short-hairpin RNA targeting the miRNA-processing enzyme Drosha

Project description:COPD is a heterogeneous condition without effective disease modifying therapies. Identification of novel inflammatory endotype markers such as extracellular vesicles (EVs), which are important intercellular messengers carrying microRNA (miRNA), may enable earlier diagnosis and disease stratification for a targeted treatment approach. Our aim was to identify differentially expressed EV miRNA in the lungs of COPD patients compared with healthy ex-smokers and determine whether they can help define inflammatory COPD endotypes. EV miRNA were isolated and sequenced from ex-smoking COPD patients and healthy ex-smoker bronchoalveolar lavage fluid. Results were validated with RT-qPCR and compared to differential inflammatory cell counts. Differential expression analysis identified five upregulated miRNA in COPD (miR-223-3p, miR-2110, miR-182-5p, miR-200b-5p and miR-625-3p) and three downregulated miRNA (miR-138-5p, miR-338-3p and miR-204-5p), all with a log2 fold change of >1/-1, FDR<0.05. These miRNAs correlated with disease defining characteristics such as FEF 25-75% (a small airways disease measure) and DLCO % (a surrogate measure of emphysema). Receiver operator curve analysis demonstrated miR-2110, miR-223-3p and miR-182-5p showed excellent combinatory predictive ability (AUC 0.91, p<0.0001) in differentiating between health and mild COPD. Furthermore, miR-223-3p and miR-338-3p correlated with airway eosinophilia and were able to distinguish “pure eosinophilic” COPD from other airway inflammatory subtypes (AUC 0.94 and 0.85 respectively). This is the first study to identify differentially expressed miRNA in COPD bronchoalveolar lavage fluid EVs. These findings suggest specific lung derived EV miRNA are a strong predictor of disease presence even in mild COPD. Furthermore, specific miRNA correlated with inflammatory cell numbers in COPD, and may have a role in defining inflammatory endotypes for future treatment stratification.

Project description:Osteolineage cells represent one of the critical bone marrow niche components that support maintenance of hematopoietic stem and progenitor cells (HSPCs). Recent studies demonstrate that extracellular vesicles (EVs) regulate stem cell development via horizontal transfer of bioactive cargo, including microRNAs (miRNAs). Here, we characterize the miRNA profile of EVs secreted by human osteoblasts and study their biological effect of on human umbilical cord blood-derived CD34+ HSPCs by sequencing, gene expression and biochemical analyses. Using next-generation sequencing we show that osteoblast-derived EVs contain highly abundant miRNAs specifically enriched in EVs, including critical regulators of hematopoietic proliferation (e.g., miR-29a). EV treatment of CD34+ HSPCs alters the expression of candidate miRNA targets, such as HBP1, BCL2 and PTEN. Furthermore, EVs enhance proliferation of CD34+ cells and their immature subsets in growth factor-driven ex vivo expansion cultures. Importantly, EV-expanded cells retain their differentiation capacity in vitro and show successful engraftment in NOD.Cg-Prkdcscid Il2rgtm1Wjl/SzJ (NSG) mice in vivo. These discoveries reveal a novel osteoblast-derived EV-mediated mechanism for regulation of HSPC proliferation and warrant consideration of EV-miRNAs for the development of expansion strategies to treat hematological disorders.

Project description:miR-223 is a novel regulator of murine hemogenic endothelial cell specification and endothelial-to-hematopoietic transition. miR-223-deficient mouse embryos exhibit significant increase in hemogenic endothelial cells and HSPCs.

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.

Project description:Total bone marrow (BM) from miR-223 knockout (mir-223-/-) and wildtype (miR-223+/+) mice 21 was extracted, prestimulated for 2 days. Then, the BM cells were simultaneously cotransduced with MSCV-Hoxa9-pgk-neomycin and a MSCV-Meis1-IRES-YFP by co-cultivation with irradiated (4,000 cGy) viral producers. HoxA9-Meis1 transduced cells were sorted for YFP expression and continuously selected with neomycin (1.4 mg/ml). Processing of the pre-miRNA through Dicer1 generates a miRNA duplex, consisting of a miRNA and miRNA* strand. Despite the general view that miRNA*s have no functional role, we further investigated miRNA* species in 10 deep sequencing libraries from mouse and human tissue. Comparing miRNA/miRNA* ratios across the miRNA sequence libraries revealed that 50% of the investigated miRNA duplexes exhibit a highly dominant strand. Conversely, 10% of miRNA duplexes show a comparable expression of both strands, while the remaining 40% exhibit variable ratios across the examined libraries as exemplified by miR-223/miR-223* in murine and human cell lines. Functional analyses revealed a regulatory role for miR-223* in myeloid progenitor cells, implying an active role for both arms of the miR-223 duplex. This was further underscored by the demonstration that miR-223 and miR-223* target the IGF1R/PIK3 axis and that high miR-223* levels associate with increased overall survival in acute myeloid leukemia (AML) patients. Thus, we found a supporting role for miR-223* in differentiating myeloid cells in normal as well as the leukemic cell state. The fact that the miR-223 duplex acts through both arms extends the complexity of miRNA-directed gene regulation of this myeloid key miRNA.

Project description:Total bone marrow (BM) from miR-223 knockout (mir-223-/-) and wildtype (miR-223+/+) mice 21 was extracted, prestimulated for 2 days. Then, the BM cells were simultaneously cotransduced with MSCV-Hoxa9-pgk-neomycin and a MSCV-Meis1-IRES-YFP by co-cultivation with irradiated (4,000 cGy) viral producers. HoxA9-Meis1 transduced cells were sorted for YFP expression and continuously selected with neomycin (1.4 mg/ml). Processing of the pre-miRNA through Dicer1 generates a miRNA duplex, consisting of a miRNA and miRNA* strand. Despite the general view that miRNA*s have no functional role, we further investigated miRNA* species in 10 deep sequencing libraries from mouse and human tissue. Comparing miRNA/miRNA* ratios across the miRNA sequence libraries revealed that 50% of the investigated miRNA duplexes exhibit a highly dominant strand. Conversely, 10% of miRNA duplexes show a comparable expression of both strands, while the remaining 40% exhibit variable ratios across the examined libraries as exemplified by miR-223/miR-223* in murine and human cell lines. Functional analyses revealed a regulatory role for miR-223* in myeloid progenitor cells, implying an active role for both arms of the miR-223 duplex. This was further underscored by the demonstration that miR-223 and miR-223* target the IGF1R/PIK3 axis and that high miR-223* levels associate with increased overall survival in acute myeloid leukemia (AML) patients. Thus, we found a supporting role for miR-223* in differentiating myeloid cells in normal as well as the leukemic cell state. The fact that the miR-223 duplex acts through both arms extends the complexity of miRNA-directed gene regulation of this myeloid key miRNA. 2 biological replicates

Project description:To analyze the effect of miR-223-3p expression on the mRNA level we employed whole genome microarray expression profiling to identify genes with a potential seed region targeted by miR-223-3p. A549 cells were transfected for 48h with either a mirVana miRNA mimic Control or miR-223-3p.

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.