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Post-transcriptional gene regulation through microRNA (miRNA) has emerged as a major control mechanism of multiple biological processes, including development and function of T cells. T cells are vital components of the immune system, with conventional T cells playing a central role in adaptive immunity and unconventional T cells having additional functions reminiscent of both innate and adaptive immunity, such as involvement in stress responses and tissue homeostasis. Unconventional T cells encompass cells expressing semi-invariant T cell receptors (TCRs), such as invariant Natural Killer T (iNKT) and Mucosal-Associated Invariant T (MAIT) cells. Additionally, some T cells with diverse TCR repertoires, including γδT cells, intraepithelial lymphocytes (IEL) and regulatory T (Treg) cells, share some functional and/or developmental features with their semi-invariant unconventional counterparts. Unconventional T cells are particularly sensitive to disruption of miRNA function, both globally and on the individual miRNA level. Here, we review the role of miRNA in the development and function of unconventional T cells from an iNKT-centric point of view. The function of single miRNAs can provide important insights into shared and individual pathways for the formation of different unconventional T cell subsets.
MicroRNAs (miRs) significantly contribute to the regulation of gene expression, by virtue of their ability to interact with a broad, yet specific set of target genes. MiRs are produced and released by almost every cell type and play an important role in horizontal gene regulation in the tumor microenvironment (TME). In the TME, both tumor and stroma cells cross-communicate via diverse factors including miRs, which are taking central stage as a therapeutic target of anti-tumor therapy. One of the immune escape strategies adopted by tumor cells is to release miRs as a Trojan horse to hijack circulating or tumor-localized monocytes/macrophages to tune them for pro-tumoral functions. On the other hand, macrophage-derived miRs exert anti-tumor functions. The transfer of miRs from host to recipient cells depends on the supramolecular structure and composition of miR carriers, which determine the distinct uptake mechanism by recipient cells. In this review, we provide a recent update on the miR-mediated crosstalk between tumor cells and macrophages and their mode of uptake in the TME.
A myriad of signaling molecules in a heuristic network of the tumor microenvironment (TME) pose a challenge and an opportunity for novel therapeutic target identification in human cancers. MicroRNAs (miRs), due to their ability to affect signaling pathways at various levels, take a prominent space in the quest of novel cancer therapeutics. The role of miRs in cancer initiation, progression, as well as in chemoresistance, is being increasingly investigated. The canonical function of miRs is to target mRNAs for post-transcriptional gene silencing, which has a great implication in first-order regulation of signaling pathways. However, several reports suggest that miRs also perform non-canonical functions, partly due to their characteristic non-coding small RNA nature. Examples emerge when they act as ligands for toll-like receptors or perform second-order functions, e.g., to regulate protein translation and interactions. This review is a compendium of recent advancements in understanding the role of miRs in cancer signaling and focuses on the role of miRs as novel regulators of the signaling pathway in the TME.
MicroRNAs have been projected as promising tools for diagnostic and prognostic purposes in cancer. More recently, they have been highlighted as RNA therapeutic targets for cancer therapy. Though miRs perform a generic function of post-transcriptional gene regulation, their utility in RNA therapeutics mostly relies on their biochemical nature and their assembly with other macromolecules. Release of extracellular miRs is broadly categorized into two different compositions, namely exosomal (extracellular vesicles) and non-exosomal. This nature of miRs not only affects the uptake into target cells but also poses a challenge and opportunity for RNA therapeutics in cancer. By virtue of their ability to act as mediators of intercellular communication in the tumor microenvironment, extracellular miRs perform both, depending upon the target cell and target landscape, pro- and anti-tumor functions. Tumor-derived miRs mostly perform pro-tumor functions, whereas host cell- or stroma-derived miRs are involved in anti-tumor activities. This review deals with the recent understanding of exosomal and non-exosomal miRs in the tumor microenvironment, as a tool for pro- and anti-tumor activity and prospective exploit options for cancer therapy.
Patients with type 2 diabetes (T2D) are threatened by excessive cardiovascular morbidity and mortality. While accelerated arterial stiffening may represent a critical mechanistic factor driving cardiovascular risk in T2D, specific therapies to contain the underlying diabetic arterial remodeling have been elusive. The present translational study investigates the role of microRNA-29b (miR-29b) as a driver and therapeutic target of diabetic aortic remodeling and stiffening. Using a murine model (db/db mice), as well as human aortic tissue samples, we find that diabetic aortic remodeling and stiffening is associated with medial fibrosis, as well as fragmentation of aortic elastic layers. miR-29b is significantly downregulated in T2D and miR-29b repression is sufficient to induce both aortic medial fibrosis and elastin breakdown through upregulation of its direct target genes COL1A1 and MMP2 thereby increasing aortic stiffness. Moreover, antioxidant treatment restores aortic miR-29b levels and counteracts diabetic aortic remodeling. Concluding, we identify miR-29b as a comprehensive—and therefore powerful—regulator of aortic remodeling and stiffening in T2D that moreover qualifies as a (redox-sensitive) target for therapeutic intervention.
Over the last years, many microRNAs (miRNAs) have been identified that regulate the formation of bioactive lipid mediators such as prostanoids and leukotrienes. Many of these miRNAs are involved in complex regulatory circuits necessary for the fine-tuning of biological functions including inflammatory processes or cell growth. A better understanding of these networks will contribute to the development of novel therapeutic strategies for the treatment of inflammatory diseases and cancer. In this review, we provide an overview of the current knowledge of miRNA regulation in eicosanoid pathways with special focus on novel miRNA functions and regulatory circuits of leukotriene and prostaglandin biosynthesis.
Ischemic injuries of the cardiovascular system are still the leading cause of death worldwide. They are often accompanied by loss of cardiomyocytes (CM) and their replacement by non-functional heart tissue. Cardiac fibroblasts (CF) play a major role in the recovery after ischemic injury and in the scar formation. In the last few years researchers were able to reprogram fibroblasts into CM in vitro and in murine models of myocardial infarction using various protocols including a cocktail of microRNAs (miRs). These miRs can target hundreds of messenger RNAs and inhibit their translation into proteins, potentially regulating multiple cellular signaling pathways. Because of this, there has been a rising interest in the use of miRs for therapeutic purposes. However, as different miRs have different effects in different cells, there is the danger of causing serious side effects. These could be alleviated by enacting a cell-specific transport of miRs, for example by using aptamers. Aptamers are usually short strands of DNA or RNA, which can fold into a specific three-dimensional confirmation which allows them to bind specifically to target molecules. Aptamers are commonly selected from a large library for their ability to bind to target molecules using a procedure called SELEX. Aptamers have already been used to transport miRs into cancer cells.
In this thesis, we first established the transport of miRs into cells of the cardiovascular system using aptamers. MiR-126 is an important part of the signaling in endothelial cells (EC), protects from atherosclerosis and supports angiogenesis, which is why we chose it as a candidate to transport into the vasculature. We first tested two aptamers for their ability to internalize into EC and fibroblasts. Both the aptamer for the ubiquitously expressed transferrin receptor (TRA) and a general internalizing RNA motif, but not a control construct, could internalize efficiently into all cell types tested. We then designed three chimeras (Ch) using different strategies to connect TRA to miR-126. While all chimeras could internalize efficiently, only Ch3, which connects TRA to Pre-miR-126 using a sticky bridge structure, had functional effects in EC. Ch3 reduced the protein expression of VCAM-1 in EC and increased the VEGF induced sprouting of EC in a spheroid-sprouting assay. Treatment of breast cancer cells with Ch3 emulated the effects of treatment with classical miR-126-3p and miR-126-5p mimics. In the SK-BR3 cell line Ch3 and miR-126-3p reduce the viability of the cells while they reduce recruitment of EC by the MCF7 cell line. miR-126-5p had no apparent effect in the SK-BR3 line, but increased viability of MCF7 cells, as did Ch3. This implies that Ch3 can be processed to both functional miR-126-3p and miR-126-5p in treated cells.
We were unable to achieve a reprogramming of adult murine cardiac fibroblasts into cells resembling CM using the cocktail of 4 miRs. This indicates that the miR-mediated transdifferentiation is only possible in neonatal fibroblasts. The effects in mice after an AMI might possibly be caused by an enhanced plasticity of fibroblasts in and close to the infarcted area.
We also screened to find aptamers specifically binding to cells of the cardiovascular system. We used two oligonucleotide libraries in a cell-SELEX to select candidates which bind to CF, but not EC. We observed that only the library which contains two randomized regions of 26 bases showed an enrichment of species binding to fibroblasts. We then sequenced rounds 5-7 of the SELEX and analyzed the data bioinfomatically to select 10 candidate aptamers. All candidates showed a strong binding not only to CF, but also EC. This indicates that the selection pressure against species binding to EC was not high enough and would have to be increased to find true CF-aptamers. Four promising candidates were also analyzed for their potential to be internalized and we surprisingly found that all of them were internalized by EC and CF more efficiently than TRA. The similar behavior of the candidates implies that they possibly share a ligand, which is expressed both by EC and CF, but more prominently by the latter.
This work demonstrates the possibility of using aptamers to transport miRs into cells of the cardiovascular system. It also shows that it is possible to select aptamers for non-cancerous mammalian cells, which has not been done before. It is reasonable to assume that a refinement of the cell-SELEX will allow selection of cell-specific aptamers. Due to the failure of reprogramming of adult fibroblasts into induced cardiomyocytes we were unable to test whether a miR-mediated reprogramming might be inducible using aptamer transported-miRs. Ultimately, aptamer mediated transport of miRs is a feasible and promising therapeutic option for the treatment of cardiovascular diseases and other disorders like cancer.
The tumor-microenvironment (TME) is an amalgamation of various factors derived from malignant cells and infiltrating host cells, including cells of the immune system. One of the important factors of the TME is microRNAs (miRs) that regulate target gene expression at a post transcriptional level. MiRs have been found to be dysregulated in tumor as well as in stromal cells and they emerged as important regulators of tumorigenesis. In fact, miRs regulate almost all hallmarks of cancer, thus making them attractive tools and targets for novel anti-tumoral treatment strategies. Tumor to stroma cell cross-propagation of miRs to regulate protumoral functions has been a salient feature of the TME. MiRs can either act as tumor suppressors or oncogenes (oncomiRs) and both miR mimics as well as miR inhibitors (antimiRs) have been used in preclinical trials to alter cancer and stromal cell phenotypes. Owing to their cascading ability to regulate upstream target genes and their chemical nature, which allows specific pharmacological targeting, miRs are attractive targets for anti-tumor therapy. In this review, we cover a recent update on our understanding of dysregulated miRs in the TME and provide an overview of how these miRs are involved in current cancer-therapeutic approaches from bench to bedside.
Bei Knochendefekten kritischer Größe gestaltet sich die selbstständige Regeneration als nahezu unmöglich, weshalb es nötig ist die Therapie zu optimieren. Die Verwendung autologer Spongiosatransplantate stellt den aktuellen Goldstandard dar, was jedoch mit einer Reihe von Komplikationen, beispielsweise Schmerzen an der Entnahmestelle oder Wundheilungsstörungen verbunden ist. Das Knochen Tissue Engineering repräsentiert eine aussichtsreiche Alternative. Die Kombination eines osteokonduktiven Gerüststoffes mit regenerativen Zellen, wie zum Beispiel mononukleäre Zellen des Knochenmarks (BMC), stellt einen vielversprechenden Ansatz dar. Die BMCs haben im Vergleich zu anderen verwendbaren Zelltypen, z.B. mesenchymale Stammzellen (MSCs) oder endothelialen Vorläuferzellen (EPCs), den entscheidenden Vorteil einer kurzen Aufbereitungszeit, wodurch die definitive Frakturversorgung beschleunigt wird.
Mittels Inhibierung von MicroRNAs (miRNAs) mit Einfluss auf das osteogene und angiogene Potenzial der BMCs soll dieses System weiter verbessert werden. MiRNAs umfassen eine Gruppe kurzer, nicht-codierender RNAs die an der Steuerung grundlegender biologischer Prozesse beteiligt sind. Im Rahmen dieser Studie sind die MIR92A sowie MIR335 von besonderem Interesse. MIR92A blockiert die Angiogenese durch Verringerung der Expression des pro-angiogenen Proteins Integrin alpha 5 (ITGA5, CD51) sowie durch die Aktivierung des Notch-Signalweges um die Vascular endothelial growth factor (VEGF)-induzierte Blutgefäßbildung zu reduzieren. MIR335 hemmt über die Verringerung der Proteinkonzentration des Runt-related transcription factor 2 (RUNX2) die Proliferation und Differenzierung von humanen mesenchymalen Stammzellen (hMSCs) zu osteogenen Zellen. Aufgrund der erläuterten Erkenntnisse sollte in dieser Arbeit überprüft werden, ob die Neutralisation von MIR92A (Vaskularisierung) und MIR335 (osteogene Differenzierung) in BMCs mittels spezifischer antiMIR zu einer weiteren Verbesserung der BMC gestützten Therapie großer Knochendefekte führt.
Im ersten Teil der Versuche wurde das Prinzip der Lipotransfektion, zur Einbringung der Antikörper gegen die miRNAs in BMCs, optimiert und die Transfektionseffizenz bestimmt. In Abhängigkeit von der Zellsorte wurden mit 30 % - 69 % ausreichend hohe Transfektionseffizenzen erzielt, um jeweils 24 h nach Transfektion einen signifikanten Rückgang der Target-miRNA-Konzentrationen zu erreichen.
Nachdem die Wirksamkeit der Transfektion nachgewiesen war, wurden im zweiten Teil der Experimente die spezifischen Effekte der antiMIR auf die Zielgene überprüft. Der Einsatz von antiMIR92A führte nach 72 h zu einer erhöhten Genexpression von ITGA5 sowie VEGFA, zwei für die Angiogenese entscheidende Proteine. Zusätzliche konnte mittels FACS-Analyse eine signifikant gesteigerte CD51-Oberflächenexpression dokumentiert werden. Bei der Verwendung von antiMIR335 konnte eine verstärkte Expression der für die osteogene Differenzierung entscheidenden Indikatoren RUNX2 und BMP2 nachgewiesen werden. Die additionale Gabe von VEGFA (MIR92A) oder BMP2 (MIR335) konnte nach 48 h einen Trend zu verstärkter ITGA5 und VEGFA, beziehungsweise RUNX2 und BMP2 Expression erkennen lassen.
Zusammenfassend hat diese Studie verdeutlicht, dass die Inhibierung der MIR92A und MIR335 eine vielversprechende Möglichkeit bietet, das BMC gestützte Knochen Tissue Engineering weiter zu optimieren.
Myotonic dystrophy type 1 (DM1) lacks non-invasive and easy to measure biomarkers, still largely relying on semi-quantitative tests for diagnostic and prognostic purposes. Muscle biopsies provide valuable data, but their use is limited by their invasiveness. microRNA (miRNAs) are small non-coding RNAs regulating gene expression that are also present in biological fluids and may serve as diseases biomarkers. Thus, we tested plasma miRNAs in the blood of 36 DM1 patients and 36 controls. First, a wide miRNA panel was profiled in a patient subset, followed by validation using all recruited subjects. We identified a signature of nine deregulated miRNAs in DM1 patients: eight miRNAs were increased (miR-133a, miR-193b, miR-191, miR-140-3p, miR-454, miR-574, miR-885-5p, miR-886-3p) and one (miR-27b) was decreased. Next, the levels of these miRNAs were used to calculate a "DM1-miRNAs score". We found that both miR-133a levels and DM1-miRNAs score discriminated DM1 from controls significantly and Receiver-Operator Characteristic curves displayed an area under the curve of 0.94 and 0.97, respectively. Interestingly, both miR-133a levels and DM1-miRNAs score displayed an inverse correlation with skeletal muscle strength and displayed higher values in more compromised patients. In conclusion, we identified a characteristic plasma miRNA signature of DM1. Although preliminary, this study indicates miRNAs as potential DM1 humoral biomarkers.