Rôle des microARNs cellulaires et vésiculaires dans la régulation transcriptomique du système nerveux / Role of cellular and vesicular microRNAs in the transcriptomic regulation of the nervous system

Soula, Anaïs

01 December 2017

Ce travail consiste à étudier l’expression, le rôle et l’échange des microARNs (miARNs), dans le système nerveux (SN). Les microARNs (miARNs) sont des petits ARNs endogènes non-codants qui exercent une régulation négative sur l’expression desgènes, en s’hybridant sur la région 3’ non-codante des ARNm cibles.Dans un premier, nous avons dévoilé le rôle spécifique du miR-92a, dans lecontrôle de l’expression de la sous-unité GluA1 des récepteurs AMPA, dans un paradigme de plasticité synaptique homéostatique, dans lequel la plasticité synaptique est inhibée.Nous avons ensuite montré, par RNA-Seq que les miARNs sont différentiellement exprimés entre les structures du SN. Cette technologie nous a aussi permis de révéler la présence de nouvelles espèces de miARNs. De plus les résultats suggèrent que l’expression des miARNs (connus et nouveaux) participe à la signature transcriptomique singulière de chacune des structures.Dans un troisième temps, notre travail montre que les miARNs peuvent être échangés entre les cellules du système nerveux via les vésicules extracellulaires (EVs). Le contenu des EVs en miARNs varie en fonction de l’activité neuronale, et ces derniers ont pour cibles prédictives des protéines impliquées dans la régulation de la plasticité neuronale. Nos résultats suggèrent donc que l’échange de miARNs via les EVs est un nouveau mécanisme de modulation de la plasticité neuronale.Enfin, nous proposons un nouvel outil de purification des EVs, qui à l’avenir permettrait de purifier les EVs du SNC selon leur origine cellulaire.Pour conclure, ce travail apporte une meilleure compréhension du rôle des miARNs dans la régulation de la physiologie du SNC. / This work consists in stuying the expression, the role and the transport of microRNAs (miRNAs) in the central nervous system (CNS). microRNAs (miRNAs) are small endogenous non coding RNAs, exerting a negative regulation on gene expression.They inhibit protein translation by hybridization on the 3’ untranslated region of mRNA.First, we have revealed the specific role of miR-92a in the control of the expressionof GluA1, in an homeostatic plasticity paradigm in which the synaptic plasticity is inhibited.Second, by using RNA-Seq technology, we showed that miRNAs are differentially expressed in the different structures of the CNS. Moreover, we have discovered new species of miRNAs. Finally, our results suggest that the miRNA expression (of known and new miRNAs) participate in the singular transcriptomique signature of each structure.Third, we have shown that miRNAs are transported into EVs, and can be exchanged between the cells of the CNS. The miRNA content of EVs varies depending on neuronal activity. Target prediction of these miRNAs includes genes involved in the regulation of neuronal plasticity. Together, our results suggest that the exchange of miRNAs through EVs is a new mechanism involved in the modulation of neuronal plasticity. Finally, we propose a new tool for purifiying EVs depending on their cellular origin.To conclude, this study allows a better understanding of the role of miRNAs in the regulation of the physiology of the CNS.

MicroARN

Vésicules extracellulaires

Neurosciences

RNA-Seq

MiRnome

Plasticité neuronale

MicroRNA

Extracellular vesicles

Neuroscience

RNA-Seq

MiRnome

Neuronal plasticity

Genetics of Glioma : Transcriptome and MiRNome Based Approches

Soumya, A M

January 2013

Glioma, the tumor of glial cells, is one of the common types of primary central nervous system (CNS) neoplasms. Astrocytoma is the most common of all gliomas and originates from astrocytic glial cells. Astrocytoma tumors belong to two main categories: benign tumors, comprising of grade I Pilocytic astrocytoma and malignant tumors which diffusely infiltrate throughout the brain parenchyma. Diffusely infiltrating astrocytomas are graded into diffuse astrocytoma (DA; grade II), anaplastic astrocytoma (AA; grade III) and glioblastoma (GBM; grade IV) in the order of increasing malignancy. Patients with grade II astrocytoma have a median survival time of 6 to 8 years after surgical intervention. While the more aggressive grade III (AA) and grade IV (GBM) are together called malignant astrocytomas, the treatment protocols and length of survival are distinctly different between these grades. The median survival time for grade III patients is 2 to 3 years whereas patients with grade IV have a median survival of 12-15 months. GBMs have been further divided into primary GBM and secondary GBM on the basis of clinical and histopathological criteria. Primary GBM presents in an acute de novo manner with no evidence of an antecedent lower grade tumor and it accounts for >90% of all GBMs. In contrast, secondary GBM results from the progressive malignant transformation of a grade II or grade III astrocytoma. The current WHO grading system of astrocytomas is based on the histopathological characteristics of the underlying tumor tissue. Diagnoses by pathologists are dependent on specific histologic features: increased mitosis, nuclear atypia, microvascular proliferation and/or necrosis, which associate with biologically aggressive behaviour (WHO 2007). Though grading based on histology is largely reproducible and well accepted, subjectivity involved and substantial disagreement between pathologists has remained a major concern. Because of inherent sampling problems (mainly due to tumor location in the brain) and inadequate sample size available for histological evaluation, there exists a very high possibility of error in grading. Recent studies have attempted to characterize the molecular basis for the histological and prognostic differences between grade III and grade IV astrocytoma. While reports have shown the grade specific profile of gene expression, there is no molecular signature that can accurately classify grade III and grade IV astrocytoma samples. In the current work, we have identified molecular signatures for the accurate classification of grade III and grade IV astrocytoma patients by using transcriptome and miRNome data. The receptor tyrosine kinase pathway is known to be overexpressed in 88% of glioblastoma patients. The expression and activation of the receptors is reported to be deregulated by events like amplification and activating mutations. The aberrant expression of RTKs could also be due to the deregulation of miRNAs, which, in the untransformed astrocytes regulate and fine-tune the levels of the RTKs. In the current study, we have identified that tumor suppressor miRNA miR-219-5p regulates RTK pathway by targeting EGFR and PDGFRα. Part I. Transcriptome approach: Identification of a 16-gene signature for classification of malignant astrocytomas In order to obtain a more robust molecular classifier to accurately classify grade III and grade IV astrocytoma samples, we used transcriptome data from microarray study previously performed in our laboratory. The differential regulation of 175 genes identified from microarray was validated in a cohort of grade III and grade IV patients by real-time qRT-PCR. In order to identify the classification signature that can classify grade III and grade IV astrocytoma samples, we used the expression data of 175 genes for performing Prediction Analysis of Microarrays (PAM) in the training set of grade III and grade IV astrocytoma samples. PAM analysis identified the most discriminatory 16-gene expression signature for the classification of grade III and grade IV astrocytoma. The Principal Component Analysis (PCA) of 16-genes astrocytoma patient samples revealed that the expression of 16-genes could classify grade III and grade IV astrocytoma samples into two separate clusters. In the training set, the 16-gene signature was able to classify grade III and grade IV patients with an accuracy rate of 87.9% as tested by additional analysis of Cross-Validated probability by PAM. The 16-gene signature obtained in the training set was validated in the test set with diagnostic accuracy of 89%. We further validated the 16-gene signature in three independent cohorts of patient samples from publicly available databases: GSE1993, GSE4422 and TCGA datasets and the classification signature got validated with accuracy rates of 88%, 92% and 99% respectively. To address the discordance in grading between 16-gene signature and histopathology, we looked at the clinical features (age and survival) and molecular markers (CDKN2A loss, EGFR amplification and p53 mutation) that differ substantially between grade III and grade IV in discordant grade III and grade IV samples. The grading done by 16-gene signature correlated with known clinical and molecular markers that distinguish grade III and grade IV proving the utility of the 16-gene signature in the molecular classification of grade III and grade IV. In order to identify the pathways that 16 genes of the classification signature could regulate, we performed protein-protein interaction network and subsequently pathway analysis. The pathways with highest significance were ECM (extracellular matrix) and focal adhesion pathways, which are known to be involved in the epithelial to mesenchymal transition (EMT), correlating well with the aggressive infiltration of grade IV tumors. In addition to accurately classifying the grade III and grade IV samples, the 16-gene signature also demonstrated that genes involved in epithelial-mesenchymal transition play key role in distinguishing grade III and grade IV astrocytoma samples. Part II. miRNome approach microRNAs (miRNAs) have emerged as one of the important regulators of the interaction network that controls various cellular processes. miRNAs are short non-coding RNAs (mature RNA being 21-22nt long) that regulate the target mRNA by binding mostly in the 3’ UTR bringing about either translational repression or degradation of the target. miRNAs are shown to play key roles in cell survival, proliferation, apoptosis, migration, invasion and various other characteristic features that get altered in human cancers. miRNAs are characterized to have oncogenic or tumor suppressor role and the aberrant expression of miRNAs is reported in multiple human cancer types. Part A. Genome-wide expression profiling identifies deregulated miRNAs in malignant astrocytoma With an aim to identify the role of miRNAs in the development of in malignant astrocytoma, we performed a large-scale, genome-wide microRNA (miRNA) (n=756) expression profiling of 26 grade IV astrocytoma, 13 grade III astrocytoma and 7 normal brain samples. Using Significance Analysis of Microarrays (SAM), we identified several differentially regulated miRNAs between control normal brain and malignant astrocytoma, grade III and grade IV astrocytoma, grade III astrocytoma and grade IV secondary GBM, progressive pathway and de novo pathway of GBM development and also between primary and secondary GBM. Importantly, we identified a most discriminatory 23-miRNA expression signature, by using PAM, which precisely distinguished grade III from grade IV astrocytoma samples with an accuracy of 90%. We re-evaluated the grading of discordant samples by histopathology and identified that one of the discordant grade III samples had areas of necrosis and it was reclassified as grade IV GBM. Similarly, out of two discordant grade IV samples, one sample had oligo component and it was reclassified as grade III mixed oligoastrocytoma. Thus, after the revised grading, the prediction accuracy increased from 90% to 95%. The differential expression pattern of nine miRNAs was further validated by real-time RT-PCR in an independent set of malignant astrocytomas (n=72) and normal samples (n=7). Inhibition of two glioblastoma-upregulatedmiRNAs (miR-21 and miR-23a) and exogenous overexpression of two glioblastoma-downregulatedmiRNAs (miR-218 and miR-219-5p) resulted in reduced soft agar colony formation but showed varying effects on cell proliferation and chemosensitivity. Thus, we have identified the grade specific expression of miRNAs in malignant astrocytoma and identified a miRNA expression signature to classify grade III astrocytoma from grade IV glioblastoma. In addition, we have demonstrated the functional relevance of miRNA modulation and thus showed the miRNA involvement and their importance in astrocytoma development. Part B. miR-219-5p inhibits the receptor tyrosine kinase pathway by targeting mitogenic receptor kinases in glioblastoma The receptor tyrosine kinase (RTK) pathway, being one of the important growth promoting pathways, is known to be deregulated in 88% of the patients with glioblastoma. In order to understand the role of miRNAs in regulating the RTK pathway, we undertook a screening procedure to identify the potential miRNAs that could target different members of the RTK pathway. From the screening study involving bioinformatical prediction of miRNAs and subsequent experimental validation by modulation of miRNA levels in glioma cell lines, we identified miR-219-5p as a candidate miRNA. The overexpression of miR-219-5p reduced the protein levels of both EGFR and PDGFRα. We confirmed the binding of miR-219-5p to the 3’ UTRs by using reporter plasmids. We also confirmed the specificity of miR-219-5p binding sites in the 3’ UTR of EGFR by site directed mutagenesis of binding sites which abrogated the miRNA-UTR interaction. The expression of miR-219-5p was significantly downregulated in grade III as well as in grade IV astrocytoma samples in the miRNA microarray experiment and we further validated the downregulation in an independent cohort of grade III and grade IV astrocytoma patients by real-time qRT-PCR. The ectopic overexpression of miR-219-5p in glioma cell lines inhibited cell proliferation, colony formation, anchorage independent growth and the migration of glioma cells. In addition, overexpression of miR-219-5p decreased MAPK and PI3K pathways, in concordance with its ability to target EGFR and PDGFRα. Additionally, for the further characterization of miR-219-5p – EGFR interaction and its effect on MAPK and PI3K pathways, we used U87 glioma cells that stably overexpress wild-type EGFR and constitutively active ΔEGFR (both lacking 3’-UTR and thus being insensitive to miR-219-5p overexpression) along with U87 parental cells. In these cell lines with the overexpression of EGFR lacking 3’-UTR, miR-219-5p was unable to inhibit - MAPK and PI3K pathways and also glioma cell migration suggesting that these effects were indeed because of its ability to target EGFR. Further, in the glioblastoma patient cohort (TCGA dataset), we found significant negative correlation between EGFR protein levels, both total EGFR and phospho EGFR and miR-219-5p levels in the glioblastoma tissue samples suggesting a role of miR-219-5p in increasing the protein levels of EGFR in glioblastoma. In summary, we have identified and characterized miR-219-5p as the RTK regulating tumor suppressor miRNA in glioblastoma.

Gliomas

Glioma

Malignant Astrocytoma

Glioblastoma

miRNome Approach

miRNA

Receptor Tyrosine Kinase (RTK) Pathway

MiRNome-MicroRNAs(MiRNAs) - Glioma

MiRNAs

Transciptome, Glioma

EMT Pathway

miRNome Approach

Molecular Biology

Analyse comparative du transcriptome et miRNone des cancers de l'oropharynx en fonction du statut HPV16 / Comparative analysis of the transcriptome and mirnome of oropharyngeal cancers according to HPV16 status

Mirghani, Haitham

15 September 2014

Avec plus de 600 000 nouveaux cas par an, les cancers des voies aéro-digestives supérieures (VADS) se classent au sixième rang mondial. Ces cancers, traditionnellement causés par la consommation chronique de tabac et d’alcool, connaissent depuis une trentaine d’années de profonds changements épidémiologiques. Alors que l’incidence des cancers développés dans la cavité orale, le larynx et l’hypopharynx tend à se stabiliser voire à régresser en raison de la diminution du tabagisme, ceux développés dans l’oropharynx sont en nette augmentation. Cette augmentation est attribuée aux papillomavirus oncogènes et notamment au génotype 16 (HPV16). Les cancers de l’oropharynx (COP) HPV-induits représentent une pathologie distincte des autres cancers des VADS tant au niveau épidémiologique, clinique, histologique que biologique. Ils affectent des sujets plus jeunes, sont extrêmement lymphophiles et leur pronostic est significativement meilleur. L’émergence de ces cancers impose dès aujourd’hui de réfléchir à des stratégies diagnostiques, thérapeutiques et de surveillance spécifiques. Néanmoins, ces objectifs ne pourront être pleinement atteints qu’à condition de mieux comprendre leur histoire naturelle ainsi que leurs mécanismes oncogéniques propres. L’objectif de ce travail est de contribuer à une meilleure compréhension des mécanismes biologiques distinguant les COP HPV-induits de leurs homologues HPV-négatifs sur la base de l’analyse de leur profil d’expression génomique. A partir d’une cohorte de 38 COP, sélectionnés sur des critères stricts, nous avons identifié un set d’ARNm et de miRNA dont l’expression est exclusivement corrélée au statut HPV. L’analyse fonctionnelle de ces sets confirme que les bases biologiques des COP varient en fonction de leur statut HPV et confortent au niveau moléculaire des données cliniques et pathologiques déjà connues ou fortement suspectées (différenciation tumorale, infiltration lymphocytaire…). Cette étude souligne également le rôle potentiel de plusieurs voies de signalisation dont les dérégulations contribueraient au développement de ces tumeurs. L’exploration plus approfondie de ces voies pourrait à terme permettre de mieux comprendre ces tumeurs et avoir d’éventuelles retombées thérapeutiques. / Head and neck squamous cell carcinomas (HNSCCs) represent the sixth most common form of cancer with an annual incidence of approximately 600,000 new cases worldwide. Tobacco and alcohol abuse are the traditional risk factors. Whilst the incidence of oral cavity, larynx and hypopharynx cancers is stabilizing or falling, because of a drop in tobacco consumption, those arising in the oropharynx are on the increase. This epidemiologic change has been attributed to high-risk human papillomavirus and particularly to type 16 (HPV16), which is now recognized as a causative agent in a growing subset of oropharyngeal squamous cell carcinomas (OPSCCs).HPV-induced OPSCCs represent a distinct subgroup, separate from other HNSCCs, with unique epidemiologic, clinical, pathological and molecular characteristics. They affect young patients, are highly lymphophilic and have markedly improved survival outcomes compared to those with HPV-negative HNSCC. The emergence of these cancers demands special attention, as in the coming years diagnosis, treatment and follow up in HNSCC may vary according to HPV status. However, these objectives will not be fully achieved without a better understanding of their natural history and specific oncogenic mechanisms. The goal of this work is to contribute to a better understanding of the biological basis that differentiates HPV-induced OPSCCs from their HPV-negative counterparts. To this end, we have investigated global changes in gene expression in a cohort of 38 strictly selected OPSCCs. We have identified a set of mRNA and miRNA that discriminated between OPSCCs solely according to HPV16 status. The functional analysis of these 2 sets confirms that the biological basis of OPSCCs varies according to their HPV status and consolidates at the molecular level known or suspected clinical and pathological data (e.g tumoral differentiation, lymphoid infiltrations…). This study highlights the potential role of several pathways that, once deregulated, could contribute to the development of HPV-induced OPSCC. Further investigation is required for a more comprehensive understanding of the biological properties of HPV related OPSCCs. These properties may be exploited to develop novel therapeutic agents.

Cancer de l'oropharynx

HPV

Profil d'expression génomique

Transcriptome

Mirnome

DNA-microarray

Oropharynx cancer

HPV

616.994

<b>Role of MicroRNA in Canine Diffuse Large B-Cell Lymphoma</b>

Nelly O Elshafie IV (17104207)

06 October 2023

<p dir="ltr">Lymphoma is a prevalent malignancy in dogs. Diffuse large B-cell Lymphoma (DLBCL) is the common subtype that represents about 50% of the clinically seen lymphoma cases. DLBCL diagnosis relies on cytological examination of a fine needle aspirate and histological evaluation by immunohistochemistry (IHC) in most common practices. This workflow is sufficient to confirm the diagnosis; however, it may be challenging to differentiate reactive and neoplastic forms in some controversial cases. In such cases, PCR-based clonality assays and flow cytometry (FC) can help with more conclusive diagnoses. So, finding more biomarkers that can detect and track DLBCL early and over time is a must for a final diagnosis and helps us learn more about how DLBCL starts at the molecular level. MicroRNAs (miRNAs), the small non-coding RNAs, regulate gene expression by binding to the 3'-untranslated region of protein-coding RNAs, leading to either RNA degradation or translational repression. They can switch on and off genes to regulate physiological and pathological processes. MicroRNA stability features and tissue availability make them promising biomarkers for identifying and sub-classifying patients and sequentially evaluating the disease status or the response toward a specific medicine. This dissertation investigates the small RNA sequence analysis, the differentially expressed miRNAs between healthy and DLBCL-affected lymph nodes, and the miRNA profile in DLBCL cases with different outcomes.</p>

Veterinary diagnosis and diagnostics

Diffuse large B-cell Lymphoma

miRNAs

Cancer Biomarkers

miRNome

sRNA sequencing

Canine DLBCL

Investigation of the deregulated miRNome identified during acute viral infections in a murine model of HSV-1 encephalitis

Caligiuri, Kyle

January 2013

Herpes simplex virus type 1 (HSV-1) is a double stranded DNA virus that causes epithelial skin infections and persists through the life of the host by infecting neurons, where it can switch to a latent state to evade an immune response. In rare cases during primary infection or after reactivation, instead of undergoing lytic infection at the epithelial surface, it instead travels to the brain and causes herpes simplex virus encephalitis (HSVE) which can have a ≥70% mortality rate if untreated. As the virus takes over its host cell, it gains control of the host cell machinery and manipulates host gene expression in order to evade the immune system and to pool its resources into the replication of the virus. One aspect of the dysregulated gene expression involves microRNAs (miRNAs). MiRNAs are short, non-coding RNAs that bind to the 3' untranslated region (3'UTR) of messenger RNAs (mRNAs), leading to translational repression of the target. Dysregulated miRNAs are often down-regulated during infection as the virus takes over, but many miRNAs have also been found to be up-regulated as well1–5. The aim of this study is to observe the full cellular miRNA changes in the context of an acute viral encephalitic infection using HSV-1, and to further characterize selected up-regulated miRNAs to determine their function in the context of the disease state. Of particular note were miR-141 and miR-200c which showed anti-apoptotic effects on neuronal cell culture and did not impact cell viability during an over-expression of the miRNAs. MiR-141, miR-183 and miR-200a expression was enriched within specific areas of the brain during infection. In addition, the potential for miR-150 to bind to a bioinformatically predicted target site within the shared 3'UTR of the HSV-1 UL18, UL19 and UL20 genes was explored. Examining the changes in expression of this class of regulatory RNAs and investigating their potential functions may yield new insight into the relationship between host and virus during infection.

herpes simplex virus type 1

microRNA

HSV-1

miRNA

next generation sequencing

NGS

deep sequencing

miRNome

herpes simplex virus encephalitis

HSVE

Utilization of microRNA signatures as a diagnostic tool for canine urothelial carcinoma

Mara Suzann Varvil (16624251)

20 July 2023

<p><em>Background:</em> UC is the most common urogenital cancer, comprising up to 2% of all naturally occurring neoplasia in dogs and can be challenging to diagnose. With early diagnosis, the disease can be controlled in most dogs with a good quality of life. MiRNAs are small non-coding RNAs that function by post-transcriptional regulation of gene expression. Their abundant presence and stability in the body make them promising tools for disease diagnosis. </p> <p><em>Hypothesis:</em> A microRNA (miRNA) signature can be used to differentiate canine urothelial carcinoma (UC) from other lower urinary tract diseases.</p> <p><em>Literature review:</em> There is an overlap of miRNA expression changes between normal physiologic processes, non-infectious and non-inflammatory conditions, infectious and/or inflammatory conditions, and neoplasia. Additionally, the mechanism of action of these overlapping miRNAs varies depending on the disease process. There is a lack of standardization of miRNA evaluation and consistency within a single evaluation method. Herein we evaluate three papers on miRNA expression in canine UC and compared the reported expression profile to human UC literature and identified experimentally validated targets of the dysregulated miRNA. </p> <p><em>Methods and results:</em> <strong>(Aim 1)</strong> Using reverse transcriptase quantitative PCR (RT-qPCR), we assessed the effects of sample handling on miRNA expression in formalin-fixed Paraffin-embedded (FFPE) tissue and urine sediment. We showed that the time of tissue fixation in formalin does not alter the detection of miRNA expression, but the inclusion of the muscularis layer altered the miRNA expression profile in bladder tissue. Additionally, miRNAs in urine sediment were proven to be stable despite the storage temperature for up to two weeks. <strong>(Aim 2)</strong> Using Next Generation Sequencing (NGS) with validation of findings via RT-qPCR, we evaluated differential miRNA expression in bladder tissue collected from normal canine urothelium and the invasive type of UC (iUC) to elucidate the dysregulated pathways. We found that twenty-eight miRNAs were differentially expressed (DE). The DE miRNAs were most often associated with gene silencing by miRNA, miRNAs in cancer, and miRNAs involved in DNA damage responses. Proteins involved include HRAS, KRAS, ARAF, RAF1, MAPK1, MAP2K1, MAPK3, FGFR3, EGFR, HBEGF, RASSF1, E2F2, E2F3, ERBB2, SRC, MMP1, and UP3KA. <strong>(Aim 3)</strong> Using RT-qPCR, expression of miR-214, miR-181a, miR-361, and miR-145 were evaluated. We failed to reject the null hypothesis that the relative gene expression in all groups was the same for any miRNA, nor did we find any multivariate summary that could effectively differentiate UC from inflammatory and non-neoplastic transitional cells. </p> <p><em>Conclusions:</em>   The findings within this thesis highlight the need for standardized methods for miRNA evaluation, support the use of stored samples for miRNA expression analysis, and show the importance of isolating the tissue of interest in FFPE. We defined the miRNome of iUC and investigated numerous protein pathways affected by dysregulation of differentially expressed miRNA in urothelial carcinoma. While we failed to reject our null hypothesis that the miRNA signature we evaluated could be utilized as a diagnostic tool for canine urothelial carcinoma, we showed the promise of miRNA as diagnostic tools and highlight several novel pathways that miRNA regulation affects in this disease. </p>

Veterinary diagnosis and diagnostics

Veterinary medicine (excl. urology)

Veterinary pathology

Veterinary urology

microRNA

miRNA

Urothelial carcinoma

transitional cell carcinoma

bladder cancer

canine

formalin-fixed praffin-embedded

Urine sediment

urine sediment cells

miRnome