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Dicer and Drosha are the major enzymes involved in microRNA processing. Using siRNA targeting Dicer and Drosha, thereby downregulating a substantial number of microRNAs in EC, we demonstrate a crucial role of both enzymes in angiogenic processes. Interestingly, Dicer inhibition exerts more profound effects on processes like migration and viability of EC in comparison to Drosha inhibition. Moreover, Dicer effects in vivo angiogenesis, a process which is unaffected by Drosha. This discrepancy might be partially due to the involvement of Dicer in other cellular processes like heterochromatin formation and to the fact that Dicer and Drosha target mainly different subsets of microRNAs. In addition, we identified miR-92a as a novel endogenous repressor of the angiogenic program in EC, which impairs their angiogenic functions in vitro and in vivo. Consistent with these data, blocking miR-92a by systemic infusion of antagomirs enhances neovascularization and functional recovery after ischemia in vivo. At first sight, the anti-angiogenic function of miR-92a in EC appears to contradict the previously identified anti-apoptotic and pro-angiogenic activities of the miR-17~92 cluster in tumor cells. However, this apparent discrepancy might be well rationalized by a predominant function of miR-18a and miR-19a in tumor cells, which are responsible for the tumorigenic and non-cell autonomous pro-angiogenic functions of the miR-17~92 cluster. Instead, miR-92a expression is specifically upregulated in ischemic tissues and appears to cell-autonomously repress the angiogenic potential of EC. Among the various targets and verified regulated genes identified by microarray, we confirmed the downregulation of Integrin a5 in vitro and in vivo. The relevance of this miR-92a target is evidenced by severe vascular defects in the absence of Integrin a5. In addition, endothelial miR-92a interferes with the expression pattern of genes controlling key EC functions at various levels, some of which, e.g. eNOS, might be secondarily affected by directly targeted genes. Obviously, our data do not formally exclude effects of antagomir-92a on perivascular and other cell types, but surely include effects on EC. Regardless of this, the capacity of miR-92a to target various downstream effectors might be an advantage of miRNA-based therapeutic strategies and may overcome the limited therapeutic capacity of single growth factor or single gene therapies in ischemic diseases, since the highly organized process of vessel growth, maturation and functional maintenance is well known to require the fine-tuned regulation of a set of genes.
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.