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MicroRNA Passenger Strand

2014; Lippincott Williams & Wilkins; Volume: 7; Issue: 4 Linguagem: Alemão

10.1161/circgenetics.114.000805

1942-325X

Connie Wu, Pankaj Arora,

Circular RNAs in diseases

HomeCirculation: Cardiovascular GeneticsVol. 7, No. 4MicroRNA Passenger Strand Free AccessResearch ArticlePDF/EPUBAboutView PDFSections ToolsAdd to favoritesDownload citationsTrack citationsPermissions ShareShare onFacebookTwitterLinked InMendeleyRedditDiggEmail Jump toFree AccessResearch ArticlePDF/EPUBMicroRNA Passenger StrandOrchestral Symphony of Paracrine Signaling Connie Wu, PhD and Pankaj Arora, MD Connie WuConnie Wu From the Cardiovascular Research Center, Massachusetts General Hospital, Harvard Medical School, Boston, MA (C.W.); and the Early Career Committee of the American Heart Association Functional Genomics and Translational Biology Council, Dallas, TX (P.A.). and Pankaj AroraPankaj Arora From the Cardiovascular Research Center, Massachusetts General Hospital, Harvard Medical School, Boston, MA (C.W.); and the Early Career Committee of the American Heart Association Functional Genomics and Translational Biology Council, Dallas, TX (P.A.). Originally published1 Aug 2014https://doi.org/10.1161/CIRCGENETICS.114.000805Circulation: Cardiovascular Genetics. 2014;7:567–568Study HypothesisDuring the past few years, increasing studies have identified microRNAs to be present in the circulation, either encapsulated in microvesicles or exosomes or associated with RNA-binding proteins or lipoproteins.1 Recent studies have suggested that circulating microRNAs may function in cell–cell communication, being transported from one cell type to another and regulating target gene expression in recipient cells.2,3 Although it has been generally thought that the passenger strand of the microRNA duplex is degraded during microRNA biogenesis and only the guide strand of the microRNA duplex is selected to become the mature functional microRNA, there is mounting evidence that passenger strand microRNAs can also target mRNAs and have biological functions in pathologies such as cancer.4,5 In the current study, Bang et al6 present evidence that exosomes produced by cardiac fibroblasts contain passenger strand microRNAs, which are transferred to cardiomyocytes and play a role in the development of fibroblast-derived cardiomyocyte hypertrophy, revealing a novel method of paracrine communication between cardiac fibroblasts and cardiomyocytes.How Was the Hypothesis Tested?The authors6 used electron microscopy to demonstrate the ability of neonatal rat cardiac fibroblasts to produce and secrete exosomes (fibroblast-derived exosomes). They further confirmed the identity of the exosomes by performing Western blotting and fluorescence-activated cell sorting analyses for the presence of an exosomal marker protein. To assess the microRNA content of fibroblast-derived exosomes, the authors used a microRNA profiling assay and, in particular, detected the presence of the passenger strand of microRNA-21 (miR-21*). Expression of miR-21* in fibroblast-derived exosomes was confirmed by quantitative real time-polymerase chain reaction and RNA sequencing. Using confocal microscopy and coculture assays, the authors investigated the ability of fibroblast-derived exosomes and microRNAs to be transported to and taken up into cardiomyocytes. Moreover, they tested whether exosome-derived miR-21* modulated cardiomyocyte cell size by incubating cardiomyocytes with exosomes isolated from the conditioned medium of fibroblasts that were transfected with a precursor of miR-21* (pre–miR-21*). To further study the role of miR-21* in cardiomyocytes, the authors performed proteome profiling in cardiomyocytes transfected with pre–miR-21* or a control microRNA to identify potential targets that are regulated by miR-21*. Proteome profiling analysis revealed that sorbin and SH3 domain-containing protein 2 (SORBS2) was strongly downregulated and PDZ and LIM domain 5 (PDLIM5), which had been previously implicated in cardiomyopathy,7 was also among the downregulated targets. The authors examined whether SORBS2 and PDLIM5 play a role in cardiomyocyte hypertrophy by using small interfering RNAs to knockdown either SORBS2 or PDLIM5 in cardiomyocytes. Finally, the authors induced a prohypertrophic condition in C57BL/6N mice by implanting osmotic angiotensin II–containing minipumps and then injected the mice with a cholesterol-modified miR-21* antagonist (miR-21* antagomir) or a scrambled control antagomir to determine the importance of miR-21* for cardiac hypertrophy in vivo.Principal FindingsElectron microscopic analysis revealed the presence of multivesicular bodies, structures which are formed during exosome biogenesis,8 in the cytoplasm of neonatal rat cardiac fibroblasts. The multivesicular bodies were found to fuse with the plasma membrane of cardiac fibroblasts, resulting in the release of exosomes into the extracellular fluid. The authors confirmed the identity of the exosomes by performing Western blotting and fluorescence-activated cell sorting analyses to detect the presence of the exosomal marker protein CD63. Using a microRNA profiling assay, the authors compared the expression of microRNAs from fibroblast-derived exosomes and fibroblast cells and identified 50 microRNAs to be enriched in fibroblast-derived exosomes. Of these 50 microRNAs, 26% were passenger strand microRNAs. Previous studies have reported that miR-21 is an important player in fibroblast biology.9 Interestingly, the authors found that miR-21* was among the passenger strand microRNAs that were enriched in fibroblast-derived exosomes. Both quantitative real time-polymerase chain reaction and RNA sequencing confirmed that miR-21* was enriched in fibroblast-derived exosomes, whereas miR-21 is enriched in cardiac fibroblasts.The authors showed that incubating cardiomyocytes with fluorescently labeled exosomes derived from cardiac fibroblasts resulted in the internalization of the labeled exosomes into the cytoplasm of the cardiomyocytes, as analyzed by confocal microscopy. In addition, confocal microscopic analysis of cardiomyocytes cocultured with cardiac fibroblasts transfected with a fluorescently labeled precursor microRNA revealed the presence of the labeled precursor microRNA in the cardiomyocytes. Next, the authors found an enrichment of miR-21* expression in cardiomyocytes cocultured with cardiac fibroblasts that were transfected with pre–miR-21*. Moreover, the authors observed that cardiomyocytes incubated with exosomes isolated from the conditioned medium of fibroblasts transfected with pre–miR-21* exhibited an increase in cell size. Transfection of cardiomyocytes with pre–miR-21* resulted in an increase in cardiomyocyte cell size, whereas the opposite was seen when cardiomyocytes were transfected with an inhibitor of miR-21*. Taken together, these findings suggest that fibroblast-derived exosomes containing miR-21* can be secreted from cardiac fibroblasts and taken up into cardiomyocytes, leading to the induction of cardiomyocyte hypertrophy.Proteome profiling analysis of cardiomyocytes transfected with pre–miR-21* or a control microRNA revealed that SORBS2 and PDLIM5 are downregulated after transfection of miR-21* and thus are candidate targets of miR-21* in cardiomyocytes. Transfection of cardiomyocytes with pre–miR-21* reduced the protein levels of SORBS2 and PDLIM5. Incubation of cardiomyocytes with miR-21*-transfected fibroblast exosomes also resulted in decreased mRNA levels of SORBS2 and PDLIM5 in cardiomyocytes. Of note, SORBS2 has been reported to be downregulated during cardiac pathologies10,11 and mice with a cardiomyocyte-specific deficiency of PDLIM5 develop cardiomyopathy,7 suggesting a potential role for these proteins in mediating the hypertrophic effects of miR-21* in cardiomyocytes. The authors showed that cardiomyocytes transfected with small interfering RNAs directed against SORBS2 or PDLIM5 exhibited an increase in cardiomyocyte cell size, supporting a role for SORBS2 and PDLIM5 in cardiomyocyte hypertrophy. Interestingly, the authors found that the levels of miR-21* were increased in pericardial fluid of C57BL/6N mice with transverse aortic constriction–induced cardiac hypertrophy compared with that of sham-operated mice. Furthermore, administration of miR-21* antagomir to mice with angiotensin II–induced cardiac hypertrophy resulted in reduced heart/body weight ratio and decreased cardiomyocyte diameter compared with mice with angiotensin II–induced cardiac hypertrophy treated with a scrambled control antagomir. Taken together, these results provide support for a model in which miR-21*–enriched exosomes are secreted from cardiac fibroblasts and transported to cardiomyocytes, where exosome-derived miR-21* negatively regulates the expression levels of SORBS2 and PDLIM5 to induce a cardiac hypertrophic response.ImplicationsThis study uncovers a novel exosome-mediated paracrine mechanism by which cardiac fibroblasts communicate with cardiomyocytes to induce cardiac hypertrophy. The finding that passenger strand microRNAs, specifically miR-21*, are present in fibroblast-derived exosomes and can modulate target gene expression in recipient cardiomyocytes further demonstrates that passenger strand microRNAs are not passive bystanders and do have biological function, particularly in the circulation acting as key regulators in paracrine signaling networks involved in cardiac hypertrophy. Strategies designed to inhibit the function of miR-21* may be an innovative microRNA-based therapeutic approach in the treatment of cardiac hypertrophy and heart failure.AcknowledgmentsDr Arora is a member of the Early Career Committee of the American Heart Association Functional Genomics and Translational Biology Council.DisclosuresNone.FootnotesCorrespondence to Pankaj Arora, MD, Division of Cardiology, University of Alabama at Birmingham, 1808 7th Ave S, BDB 201, Birmingham, AL 35294. E-mail [email protected] References 1. Creemers EE, Tijsen AJ, Pinto YM. Circulating microRNAs: novel biomarkers and extracellular communicators in cardiovascular disease?Circ Res. 2012; 110:483–495.LinkGoogle Scholar2. Hergenreider E, Heydt S, Tréguer K, Boettger T, Horrevoets AJ, Zeiher AM, et al.. Atheroprotective communication between endothelial cells and smooth muscle cells through miRNAs.Nat Cell Biol. 2012; 14:249–256.CrossrefMedlineGoogle Scholar3. Vickers KC, Palmisano BT, Shoucri BM, Shamburek RD, Remaley AT. MicroRNAs are transported in plasma and delivered to recipient cells by high-density lipoproteins.Nat Cell Biol. 2011; 13:423–433.CrossrefMedlineGoogle Scholar4. Yang X, Du WW, Li H, Liu F, Khorshidi A, Rutnam ZJ, et al.. Both mature miR-17-5p and passenger strand miR-17-3p target TIMP3 and induce prostate tumor growth and invasion.Nucleic Acids Res. 2013; 41:9688–9704.CrossrefMedlineGoogle Scholar5. Shan SW, Fang L, Shatseva T, Rutnam ZJ, Yang X, Du W, et al.. Mature miR-17-5p and passenger miR-17-3p induce hepatocellular carcinoma by targeting PTEN, GalNT7 and vimentin in different signal pathways.J Cell Sci. 2013; 126(pt 6):1517–1530.CrossrefMedlineGoogle Scholar6. Bang C, Batkai S, Dangwal S, Gupta SK, Foinquinos A, Holzmann A, et al.. Cardiac fibroblast-derived microRNA passenger strand-enriched exosomes mediate cardiomyocyte hypertrophy.J Clin Invest. 2014; 124:2136–2146.CrossrefMedlineGoogle Scholar7. Cheng H, Kimura K, Peter AK, Cui L, Ouyang K, Shen T, et al.. Loss of enigma homolog protein results in dilated cardiomyopathy.Circ Res. 2010; 107:348–356.LinkGoogle Scholar8. Denzer K, van Eijk M, Kleijmeer MJ, Jakobson E, de Groot C, Geuze HJ. Follicular dendritic cells carry MHC class II-expressing microvesicles at their surface.J Immunol. 2000; 165:1259–1265.CrossrefMedlineGoogle Scholar9. Thum T, Gross C, Fiedler J, Fischer T, Kissler S, Bussen M, et al.. MicroRNA-21 contributes to myocardial disease by stimulating MAP kinase signalling in fibroblasts.Nature. 2008; 456:980–984.CrossrefMedlineGoogle Scholar10. Kioka N, Ueda K, Amachi T. Vinexin, CAP/ponsin, ArgBP2: a novel adaptor protein family regulating cytoskeletal organization and signal transduction.Cell Struct Funct. 2002; 27:1–7.CrossrefMedlineGoogle Scholar11. Kakimoto Y, Ito S, Abiru H, Kotani H, Ozeki M, Tamaki K, et al.. Sorbin and SH3 domain-containing protein 2 is released from infarcted heart in the very early phase: proteomic analysis of cardiac tissues from patients.J Am Heart Assoc. 2013; 2:e000565.LinkGoogle Scholar Previous Back to top Next FiguresReferencesRelatedDetailsCited By Sillivan S, Jamieson S, de Nijs L, Jones M, Snijders C, Klengel T, Joseph N, Krauskopf J, Kleinjans J, Vinkers C, Boks M, Geuze E, Vermetten E, Berretta S, Ressler K, Rutten B, Rumbaugh G and Miller C (2019) MicroRNA regulation of persistent stress-enhanced memory, Molecular Psychiatry, 10.1038/s41380-019-0432-2, 25:5, (965-976), Online publication date: 1-May-2020. Rinchetti P, Rizzuti M, Faravelli I and Corti S (2017) MicroRNA Metabolism and Dysregulation in Amyotrophic Lateral Sclerosis, Molecular Neurobiology, 10.1007/s12035-017-0537-z, 55:3, (2617-2630), Online publication date: 1-Mar-2018. Nunez Lopez Y, Coen P, Goodpaster B and Seyhan A (2017) Gastric bypass surgery with exercise alters plasma microRNAs that predict improvements in cardiometabolic risk, International Journal of Obesity, 10.1038/ijo.2017.84, 41:7, (1121-1130), Online publication date: 1-Jul-2017. Zheng L, Liao J, Wen Y, Hide G, Qu L and Lun Z (2016) Different Types of Small RNAs in Protozoa Non-coding RNAs and Inter-kingdom Communication, 10.1007/978-3-319-39496-1_11, (177-196), . August 2014Vol 7, Issue 4Article InformationMetrics © 2014 American Heart Association, Inc.https://doi.org/10.1161/CIRCGENETICS.114.000805 Originally publishedAugust 1, 2014 KeywordsmicroRNAsexosomescardiomegalyPDF download Advertisement SubjectsAnimal Models of Human DiseaseHeart Failure