Global ETD Search

51	A Collagen Matrix Promotes Anti-Inflammatory Healing Macrophage Function Through a miR-92a Mechanism Lister, Zachary January 2016 (has links) MicroRNAs are emerging as key players in the regulation of the post-myocardial infarction (MI) environment. We previously identified that matrix-treated hearts had down-regulated expression of miR-92a, a miRNA with inflammatory and migratory effects that is normally up-regulated after MI. We have shown that type I collagen matrix treatment at 3h post-MI leads to less inflammation and improved cardiac function, but the underlying mechanisms remain to be better characterized. The goal of this study was to elucidate a possible role of miR-92a in the anti-inflammatory/pro-wound healing effect of matrix treatment post-MI. C57BL/6J mice underwent LAD ligation to induce MI. Hearts were removed at 4h, 1d, 3d, and 7d post-MI and RNA was extracted from infarct and peri-infarct tissue. PCR analysis revealed that hearts injected with matrix at 3h post-MI resulted in significantly decreased miR-92a at 4h, 1d, and 3d compared to non-injected animals at each time point (p<0.0001) and PBS injected animals at 4h and 7d (p<0.004). Several targets of miR-92a and regulators of macrophage polarization were found to be up-regulated (p<0.05) early in MI indicating early amelioration of inflammatory processes. In vitro, macrophages cultured on matrix also had decreased expression of miR-92a compared to cultures on tissue culture poly styrene (TCPS) (p<0.001). Integrins α5 (ITGAα5) and αV (ITGAαV), involved in cell-matrix interactions, as well as inflammatory regulators S1PR1 and SIRT1 were identified as putative miR-92a targets. When miR-92a is over-expressed in macrophages, ITGα5 (p=0.0002), ITGαV (p=0.02), and S1Pr1 (p<0.0001), and SIRT1 (p=0.03) all had decreased expression. STAT3 and IL-10 were found to be moderately down-regulated. In evaluating macrophage phenotypes, M2 macrophages had reduced miR-92a expression on matrix compared to M1 macrophages. The migration of M2 macrophages into the matrix is increased compared to M1 macrophages. We report that the beneficial effects of matrix treatment post-MI may be mediated, at least in part, through its ability to regulate miR-92a and pro-wound healing mechanisms in macrophages. These results present the matrix as a novel non-pharmacological approach to locally regulate miRNAs in vivo for reducing inflammation and protecting the myocardium post-MI. Myocardial Infarction Biomaterial MicroRNA miR-92a
52	MiR-145-5p: Its Roles in Oligodendrocyte Differentiation and Its Contributions to the Pathophysiology of Demyelinating Disease Kornfeld, Samantha F. 10 June 2020 (has links) Multiple sclerosis (MS) is a debilitating disease in which demyelinated lesions form in the central nervous system (CNS). A specific microRNA, miR-145-5p, is dysregulated both in blood samples from RRMS patients and in chronic lesions from progressive MS patients. In the context of remyelination, miR-145-5p regulation may be important as it exhibits strong differential regulation in oligodendrocytes (OLs), the myelinating cells of the CNS, and is also expressed in other CNS glial cell types. Dysregulation of miR-145-5p may therefore play into pathologies observed in both relapsing-remitting (RRMS) and progressive MS. Using pre-clinical rodent models, we aimed to determine how altering normal expression of miR-145-5p specifically affects OL maturation, and how the dysregulation observed in MS may affect various aspects of disease. First using a miR-145 knockdown model in primary rat OLs, we found in vitro that miR-145-5p plays a role both in maintaining oligodendrocyte progenitor cells (OPCs) in their proliferative state and preventing premature differentiation to OLs and that knockdown of miR-145 in OLs enhanced their differentiation. These effects were due at least in part to miR-145-5p regulation of a critical myelin gene transcription factor. The effects of miR-145-5p were further assessed in a miR-145 knockout mouse model in vivo. Contrary to in vitro assays, enhanced myelination was not detectable during development in these animals, nor when remyelination was assessed using the cuprizone toxic model of acute demyelination. However, chronic cuprizone exposure resulted in striking remyelination and functional recovery in miR-145 deficient animals. Sparse remyelination in wild-type animals with chronic cuprizone exposure was concomitant with upregulation of miR-145-5p, which was not the case with acute exposure, identifying miR-145-5p dysregulation as a unique feature of chronic demyelination. Specific assessment of miR-145-5p overexpression in OLs in vitro resulted in severe differentiation deficits and eventual apoptosis, driven molecularly by altered expression of multiple pathways critical to successful OL differentiation and subsequent myelination. Finally, we induced an inflammatory model of demyelination, experimental autoimmune encephalomyelitis (EAE), in our miR-145 knockout mouse to assess the role of miR-145-5p in autoimmune-mediated myelin damage. The clinical severity of EAE in miR-145 deficient animals was reduced, and this was accompanied by reduced loss of myelin and lessened immune cell infiltration in miR-145 knockout spinal cords. Alterations in both astrocytic and microglial activation were detected with loss of miR-145, suggesting that improved clinical outcomes in this model may be underpinned by changes in EAE-mediated neuroinflammation. Collectively, these data suggest that miR-145-5p plays differing roles in both progressive and inflammatory MS, affecting multiple glial cell types in the CNS. Excitingly, loss of miR-145 expression in our mouse model of chronic demyelination allowed extensive remyelination and functional recovery following chronic demyelination, and in EAE improved clinical outcomes driven by underlying improvements in myelin retention and altered neuroinflammatory reactions. Thus, miR-145-5p merits further investigation as a potential therapeutic target to help overcome both remyelination failure in all forms of progressive MS and inflammation-driven demyelination in RRMS and early secondary progressive MS (SPMS). Oligodendrocyte MiR-145 Myelin Multiple sclerosis
53	Evaluation of MicroRNA Mechanisms Involved in Collagen Matrix Therapy for Myocardial Infarction Chiarella-Redfern, Hélène January 2015 (has links) Myocardial infarction (MI), a late-stage event of many cardiovascular diseases (CVD), results in cardiomyocyte death, myeloid cell recruitment to promote cellular debris removal and excessive cardiac remodeling affecting architecture and function, which can ultimately lead to heart failure. Currently, the use of biomaterials to intervene on the hostile post-MI environment and promote myocardial healing is being investigated to restore cardiac function. It has been shown that an injectable collagen matrix improves cardiac repair by altering macrophage polarization, reducing cell death and enhancing angiogenesis, leading to a reduction in infarct size and improved cardiac function when delivered at 3 hours post-MI. MicroRNAs (miRNA) “fine tune” gene expression by negatively regulating the translational output of target messenger RNA (mRNA). As such, miRNAs present interesting therapeutic opportunities for the treatment of MI. However, the delivery of miRNA mimics and/or inhibitors can be complicated by degradation and off target effects. The objectives of this thesis were to determine how the matrix may regulate endogenous miRNAs and to explore the biomaterial’s ability to deliver therapeutic miRNAs. It was shown that matrix treatment of MI mouse hearts resulted in altered expression of 119 miRNAs, some of which had functions linked to the beneficial effects of matrix treatment. Of particular interest, miR-92a was down-regulated within the infarct and peri-infarct cardiac tissue 2 days after matrix treatment (delivered at 3-hours post-MI) compared to PBS treatment. In in vitro cultures, the matrix down-regulated miR-92a levels in macrophages but did not significantly alter miR-92a expression in endothelial cells, circulating angiogenic cells or fibroblasts. In addition, using an in vitro model system, it was shown that the matrix may have the potential to deliver functional therapeutic miRNAs to cells; however further experimental optimisation is required to confirm these results. Therefore, collagen matrix treatment may be a promising approach to regulate and/or deliver miRNAs for protecting the myocardial environment and improving function of the infarcted heart. MicroRNA Myocardial Infarction Biomaterial miR-92a
54	MiR-9-5p Down-Regulates PiT2, but Not PiT1 in Human Embryonic Kidney 293 Cells Paiva, D. P., Keasey, M., Oliveira, J. R.M. 01 May 2017 (has links) Inorganic phosphate (Pi) is an essential component for structure and metabolism. PiT1 (SLC20A1) and PiT2 (SLC20A2) are members of the mammalian type-III inorganic phosphate transporters. SLC20A2 missense variants are associated with primary brain calcification. MicroRNAs (miRNAs) are endogenous noncoding regulatory RNAs, which play important roles in post-transcriptional gene regulation. MicroRNA-9 (miR-9) acts at different stages of neurogenesis, is deeply rooted in gene networks controlling the regulation of neural progenitor proliferation, and is also linked with cancers outside the nervous system. We evaluated possible interactions between miR-9 and the phosphate transporters (PiT1 and PiT2). SLC20A2, platelet-derived growth factor receptor beta (PDGFRB) and Fibrillin-2 (FBN2) showed binding sites with high affinity for mir-9, in silico. miR-9 mimic was transfected into HEK293 cells and expression confirmed by RT-qPCR. Overexpression of miR-9 in these cells caused a significant reduction in PiT2 and FBN2. PDGFRB appeared to be decreased, but was not significantly down-regulated in our hands. PiT1 showed no significant difference relative to controls. The down-regulation of PiT2 protein by miR-9 was confirmed by western blotting. In conclusion, we showed miR-9 can down-regulate PiT2, in HEK293 cells. HEK293 cells miR-9 PiT2 Biomedical Sciences
55	ROLE OF MICRORNA-155 IN B-CELL LEUKEMIAS/LYMPHOMAS Sandhu, Sukhinder K. 26 September 2011 (has links) No description available. Molecular Biology miR-155 leukemia hdac4, bcl6
56	Zur Rolle von epigenetisch dysregulierten microRNAs beim klarzelligen Nierenzellkarzinom Liep, Julia 04 July 2016 (has links) Etwa 25 % der Nierenzellkarzinome (RCC) weisen bei Diagnosestellung bereits Metastasen auf. Aufgrund der schlechten Prognose des metastasierten RCC besteht ein dringender Bedarf an neuen Therapieformen sowie an prognostischen und diagnostischen Markern. microRNAs (miRNAs) bieten sich dabei als vielversprechende molekulare Biomarker an. Für den klarzelligen RCC-Subtypen (ccRCC) wurde bereits ein umfangreiches miRNA Expressionsprofil erstellt, mit dem ccRCC-relevante, vorwiegend herunterregulierte miRNAs identifiziert werden konnten. In der vorliegenden Arbeit wurde gezeigt, dass die Expression der miR-141 und miR-145 in RCC-Zelllinien durch epigenetische Mechanismen gehemmt ist und die Promotorbereiche dieser miRNAs stark methyliert vorliegen. In RCC-Zellen konnte eine tumorsuppressive Wirkung dieser miRNAs durch Hemmung der Migration (beide) und Invasion (miR-141) nachgewiesen werden. Durch die gleichzeitige Überexpression der beiden miRNAs kam es zu einer kooperativen Wirkung und so zu einer verstärkten Hemmung der Zellmigration. Weitere Untersuchungen konnten eine Reihe neuer onkogener Targets der miR 141 und miR 145 identifizieren. Dabei zeigte sich ein kooperativer Effekt durch Kombination beider miRNAs auf die Expression der Targets HS6ST2 und LOX. Die Targets LOX und MAP4K4 waren in ccRCC Gewebe auf mRNA-Ebene stark überexprimiert im Vergleich zum umliegenden Normalgewebe. Bei der anschließenden Tissue-Mikroarray-Analyse der Expression auf Proteinebene zeigte sich zudem ein prognostisches Potenzial der Targets LOX und MAP4K4 für das Gesamtüberleben von ccRCC Patienten. Diese Daten verdeutlichen den enormen Einfluss von epigenetisch dysregulierten miRNAs und deren spezifischen Targets auf tumorassoziierte Prozesse. Zudem bietet das Netzwerk aus Epigenetik, miRNAs und deren jeweiligen Targets nicht nur eine Reihe von diagnostischen und prognostischen Möglichkeiten, sondern liefert auch viele Ansatzpunkte für die Entwicklung von neuen therapeutischen Strategien. / Approximately 25 % of diagnosed renal cell carcinoma (RCC) have already metastasized. Due to poor prognosis of metastatic RCC, there is an urgent need for new therapies and prognostic and diagnostic markers to identify high-risk patients. Here microRNAs (miRNAs) might be promising new molecular biomarkers. For the clear cell RCC subtype (ccRCC) a comprehensive miRNA expression profile was already established. In this profiling several ccRCC-associated, predominantly down-regulated miRNAs were identified. In the present study, epigenetic mechanisms were identified to play a significant role in the down regulation of miR-141 and miR-145 in RCC cell lines. In addition, a strong methylation of the corresponding promoter regions was detected at molecular level. In RCC cells a tumor suppressive effect of these miRNAs was shown by decreasing migration (both) and invasion (miR-141) and furthermore, co overexpression of both miRNAs resulted in a cooperative effect with increased inhibition of cell migration. Several new oncogenic targets of miR-141 and miR-145 were identified by further investigations. Here the two miRNAs again showed a cooperative effect, as demonstrated by a significantly increased inhibition of HS6ST2 and LOX expression. In ccRCC tissue the expression of LOX and MAP4K4 was strongly enhanced on mRNA level compared to normal tissue. In the subsequent tissue microarray analysis of protein expression, LOX and MAP4K4 showed a prognostic impact for the overall survival of patients with ccRCC. These results illustrate a huge impact of epigenetically dysregulated miRNAs and of their specific targets on tumor-associated processes. Furthermore, the network of epigenetics, miRNAs and their respective targets will offer a number of diagnostic and prognostic capabilities, but will also provide many opportunities for the development of new therapeutic strategies. microRNA Nierenzellkarzinom miR-141 miR-145 LOX MAP4K4 microRNA renal cell carcinoma miR-141 miR-145 LOX MAP4K4 570 Biologie 32 Biologie WG 3700 ddc:570
57	Regulation of colony stimulating factor-1 expression and ovarian cancer cell behavior in vitro by miR-128 and miR-152 Woo, Ho-Hyung, Laszlo, Csaba, Greco, Stephen, Chambers, Setsuko January 2012 (has links) BACKGROUND:Colony stimulating factor-1 (CSF-1) plays an important role in ovarian cancer biology and as a prognostic factor in ovarian cancer. Elevated levels of CSF-1 promote progression of ovarian cancer, by binding to CSF-1R (the tyrosine kinase receptor encoded by c-fms proto-oncogene).Post-transcriptional regulation of CSF-1 mRNA by its 3' untranslated region (3'UTR) has been studied previously. Several cis-acting elements in 3'UTR are involved in post-transcriptional regulation of CSF-1 mRNA. These include conserved protein-binding motifs as well as miRNA targets. miRNAs are 21-23nt single strand RNA which bind the complementary sequences in mRNAs, suppressing translation and enhancing mRNA degradation.RESULTS:In this report, we investigate the effect of miRNAs on post-transcriptional regulation of CSF-1 mRNA in human ovarian cancer. Bioinformatics analysis predicts at least 14 miRNAs targeting CSF-1 mRNA 3'UTR. By mutations in putative miRNA targets in CSF-1 mRNA 3'UTR, we identified a common target for both miR-128 and miR-152. We have also found that both miR-128 and miR-152 down-regulate CSF-1 mRNA and protein expression in ovarian cancer cells leading to decreased cell motility and adhesion in vitro, two major aspects of the metastatic potential of cancer cells.CONCLUSION:The major CSF-1 mRNA 3'UTR contains a common miRNA target which is involved in post-transcriptional regulation of CSF-1. Our results provide the evidence for a mechanism by which miR-128 and miR-152 down-regulate CSF-1, an important regulator of ovarian cancer. miR-128 miR-152 CSF-1 mRNA Post-transcriptional regulation motility and adhesion
58	Transcriptional activation by Sp1 and post-transcriptional repression by muscle-specific microRNA miR-133 of expression of human ERG1 and KCNQ1 genes and potential implication in arrhythmogenesis Luo, Xiaobin January 2007 (has links) Mémoire numérisé par la Direction des bibliothèques de l'Université de Montréal. HERG1 KCNQ1 Canaux potassiques Sp1 MicroARNs miR-1 miR-133 Arythmies Différences régionales Repolarisation
59	Role of miR-155 and miR-146a in Mast Cell Function Abdul Qayum, Amina 01 January 2017 (has links) Mast cells are resident immune cells abundantly found in the tissue at the host-environment interface, where they play a critical role in inflammatory allergic responses. Mast cell responses may be regulated by the cytokine milieu at the site of inflammation. Recent studies have revealed microRNAs to be important in altering cytokine signaling in immune cells. Here, we demonstrate for the first time that IL-10 and IL-33 induce miR-155 and miR-146a, respectively, to alter mast cell functions. We report that IL-10 enhanced IgE induced activation of mast cells. IL-10 effects are dependent on Stat3 activation, which elicits miR-155 expression, resulting in a loss of suppressor of cytokine signaling-1 (SOCS-1). The importance of miR-155 was demonstrated by the inability of IL-10 to enhance anaphylaxis in miR-155–deficient mice. Additionally, we show that IL-33 treatment greatly enhances miR-146a expression in mast cells and in mast cell derived exosomes. miR-146a induction is dependent on MyD88 and NFκB and seems to negatively regulate ST2 signaling, which is demonstrated by the hyperresponsiveness of miR-146a knockout BMMC in response to IL-33. Our preliminary data suggest that miR-146a serves as a feedback negative regulator of IL-33 signaling by targeting IRAK proteins. miR-155 and miR-146a are key microRNAs that regulate a range of immune functions. Taken together, our results reveal two novel microRNA pathways that regulate mast cell IgE and IL-33 induced responses. mast cell miR-155 miR-146a IL-10 IL-33 Immunity
60	A duo implication of miR-134 microRNA and LIM Kinase1 protein in neuropathic pain modulation of the rat spinal cord / Une action concertée du microARN miR-134 et de la protéine LIM Kinase 1 dans la modulation de la douleur neuropathique dans la moelle épinière du rat Abdel Salam Ibrahim Mohamed, Sherine 27 September 2012 (has links) Les douleurs neuropathiques ayant une origine à la suite de blessures traumatiques du SNC ou du SNP sont particulièrement difficiles à traiter en utilisant les moyens thérapeutiques actuellement disponibles. Il est donc nécessaire d'identifier de nouvelles stratégies thérapeutiques. Notre objectif était donc de définir les mécanismes impliqués dans ces douleurs neuropathiques. LIMK1 est l'un des acteurs possibles de la réorganisation épinière qui caractérise les lésions nerveuses. Une fonction très caractérisé de cette protéine, est la phosphorylation d'une famille de protéines appelées « cofilines ». Sa phosphorylation, ce qui induit la réorganisation du cytosquelette d'actine. Récemment, il a été montré qu’un microARN (miARNs) nomé miR-134 régule l'expression de LIMK1 en se liant au messager de LIMK1 (ARNm), inhibant sa traduction en protéine physiologiquement active. Notre hypothèse était que la régulation de LIMK1 par miR-134 pourrait jouer un rôle essentiel dans la sensibilisation à la douleur. Cette régulation pourrait ainsi être liée non seulement à la modulation neurochimique neuronale mais aussi à la plasticité fonctionnelle associée. Au cours de cette thèse, l’HIS a montré une diminution de miR-134 chez des rats SNL (neuropathique), cette sous-expression était concomitante à une augmentation de LIMK1 illustrée par l’IHC. Il est important de noter ici que l'ISH est une méthode de détection connue récemment et qui a été identifiée pour visualiser les miARNs. Des différents protocoles de l’HIS ont également été discutés dans le cadre de cette thèse. Ce résultat a été confirmé par Le qRT-PCR . Par la suite, afin de vérifier les changements comportementaux douloureux induits par miR-134 et LIMK1. Nous avons effectués des injections intrathécales de siRNA anti-LIMK1 pour inhiber l'expression endogène de LIMK1 chez les SNL. C’était intéressant de ne pas avoir trouvé aucun changement comportemenal chez les SNL après ce type d’injection. Une surexpression artificielle de miR-134 en utilisant un précurseur de miR-134 (premiR-134) chez les SNL a montré le même effet. Ensuite, nous avons essayé d'effectuer les mêmes injections chez les Sham (control), et c’était plus intéressant de trouver que ces injections (siRNA LIMK1 et premiR-134) ont provoqué une hypersensibilité douleureuse chez les sham. Cela a été illustré au moyen de deux tests de comportement; le Von Frey (VF) et la distribution pondérale dynamique (DWB). Pour etudier l'effet inverse, nous avons inhibé miR-134 en utilisant une sonde spécifique KD (Knock-Down); une diminution significative inattendue dans le seuil de retrait a été observée avec VF et DWB. qRT-PCR dans la plupart de ces cas, a confirmé la corrélation in vivo entre miR-134 et LIMK1. Enfin, nous avons cherché un mécanisme d'action possible qui pourrait réguler cette modulation. Des données récentes publiées ont montré une implication de l'ADF/cofiline sur le trafic des récepteurs AMPA (AMPAR). En accord avec les résultats mentionnés ci-dessus, la transfection du KD de miR-134 a montré une diminution dans AMPAR adressés à la membrane plasmique. Tout ensemble ces données suggèrent que l'effet antinociceptif de KD de miR-134 et la surexpression de LIMK1 sont indirectement régulé par l'insertion des AMPAR à la membrane plasmique.Il semble que miR-134 exerce un effet différent sur la douleur neuropathique que miR-103, discuté aussi dans le cadre de cette thèse. Il était demontré comme un régulateur de plusieurs cibles, les trois sous-unités formant les canaux calciques de type-L « Cav1.2 LTC ». MiR-103 a été trouvé également réprimés chez les SNL. La surexpression de miR-103 soulage la douleur neuropathique. Contrairement au miR-134, miR-103 exerce un rôle pronociceptive pendant la douleur neuropathique. / Pains having a neuropathic origin following CNS or PNS traumatic injury are particularly difficult to treat using the actually available therapeutic means. It is thus necessary to identify new therapeutic strategies. Hence, our aim was to define the mechanisms implicated in these neuropathic pains. Nervous lesions are characterised by an anatomical reorganization of the neuronal network of the dorsal horn. Neurochemical alterations are also involved. Some of the molecular mechanisms underlying the neuronal plasticity (a main feature of neuropathic pain) have been emphasized here by a variety of complementary technical approaches. LIMK1 is one of the possible actors of this reorganization. Among this protein’s known functions, and the most characterized is the phosphorylation of a family of proteins known as cofilins. Their phosphorylation induces the reorganization of actin cytoskeleton. Recently, it has been shown that a miR-134 miRNA regulates LIMK1 expression by binding to the LIMK1 messenger, inhibiting its translation into physiologically active protein. Our hypothesis is that LIMK1 regulation by miR-134 might play an essential role in pain sensitization by modulating neuron neurochemical reorganization and the associated functional neuronal plasticity. Firstly, by means of IHC and ISH, we studied miR-134/LIMK1 distribution within the dorsal horn of the spinal cord in sham animal (control group) and in neuropathic pain model (SNL model). Important to note here that ISH is a known detection method recently identified to visualize miRNA. Different protocols of ISH were discussed in a part of this thesis. ISH showed a decrease in miR-134 expression in SNL rats concomitantly with an increase in LIMK1 illustrated by IHC. This finding has been confirmed by qRT-PCR techniques. Afterward, in order to check for the possible behavioural-induced changes of miR-134 and LIMK1. We intrathecally injected an anti-LIMK1 siRNA to inhibit endogenous LIMK1 expression in SNL rats. Interestingly no significant changes in pain behaviour have been observed. Artificial overexpression of miR-134 using a PremiR-134, showed the same effect. Then we tried to perform the same injections on sham rats, and more interestingly, siRNA LIMK1 and premiR-134 evoked pain hypersensitivity in shams rats. This was illustrated by means of two behaviour tests; Von Frey (VF) and the Dynamic Weight bearing (DWB). To explore the reverse effect, we inhibited miR-134 using a specific KD probe in SNL rats; unexpectedly a significant decrease in pain withdrawal threshold was observed with VF and DWB. qRT-PCR in most cases confirmed the in vivo correlation between miR-134 and LIMK1. Finally, we searched for the possible mechanism of action that could regulate this modulation. Recent published data showed an involvement of ADF/cofilin on AMPAR trafficking. In line with the above mentioned findings, miR-134 KD transfection showed a decrease in AMPAR addressed to the plasma membrane. Altogether suggest that the antinociceptive effect of miR-134 KD and LIMK1 overexpression are mediated by AMPAR insertion at the plasma membrane. It seems that miR-134 exerts a different effect on neuropathic pain than miR-103 another miRNA discussed within the frame of this thesis. MiR-103 has been proved to regulate multiple targets, the three subunits forming Cav1.2 LTC. Pain sensitization involves Cav1.2 activation which consequently alters gene expression during this form of plasticity. MiR-103 was found downregulated also in the SNL model. Conversely to miR-134, overexpression of miR-103 partially alleviates pain. It decreases pain withdrawal threshold of the Von Frey test. Unlike miR-134, miR-103 exerts a pronociceptive role during neuropathic pain. Neuropathic Pain Spinal Cord MicroRNA MiR-134 LIMK1 Douleur Neuropathique Moelle Épinière MicroARN MiR-134 LIMK1

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