Your search keyword '"Renzo J. M. Riemens"' showing total 7 results

1. Targeted Methylation Profiling of Single Laser-Capture Microdissected Post-Mortem Brain Cells by Adapted Limiting Dilution Bisulfite Pyrosequencing (LDBSP)

Author

Renzo J. M. Riemens, Gunter Kenis, Jennifer Nolz, Sonia C. Susano Chaves, Diane Duroux, Ehsan Pishva, Diego Mastroeni, Kristel Van Steen, Thomas Haaf, Daniël L. A. van den Hove, Basic Neuroscience 1, RS: MHeNs - R3 - Neuroscience, Psychiatrie & Neuropsychologie, and MUMC+: MA Niet Med Staf Psychiatrie (9)

Subjects

Biochemistry & Molecular Biology, OOCYTES, Chemistry, Multidisciplinary, laser-capture microdissection, Catalysis, Inorganic Chemistry, limiting dilution bisulfite pyrosequencing, Humans, HETEROGENEITY, MESSENGER-RNA EXPRESSION, Physical and Theoretical Chemistry, Molecular Biology, Spectroscopy, Science & Technology, DNA methylation, epigenetics, Lasers, Organic Chemistry, Brain, High-Throughput Nucleotide Sequencing, Neurodegenerative Diseases, General Medicine, single-cell, DNA Methylation, Computer Science Applications, DNA/methods, Chemistry, Sequence Analysis, DNA/methods, Physical Sciences, PATTERNS, Apoptosis Regulatory Proteins, Sequence Analysis, Life Sciences & Biomedicine, Molecular Chaperones

Abstract

A reoccurring issue in neuroepigenomic studies, especially in the context of neurodegenerative disease, is the use of (heterogeneous) bulk tissue, which generates noise during epigenetic profiling. A workable solution to this issue is to quantify epigenetic patterns in individually isolated neuronal cells using laser capture microdissection (LCM). For this purpose, we established a novel approach for targeted DNA methylation profiling of individual genes that relies on a combination of LCM and limiting dilution bisulfite pyrosequencing (LDBSP). Using this approach, we determined cytosine-phosphate-guanine (CpG) methylation rates of single alleles derived from 50 neurons that were isolated from unfixed post-mortem brain tissue. In the present manuscript, we describe the general workflow and, as a showcase, demonstrate how targeted methylation analysis of various genes, in this case, RHBDF2, OXT, TNXB, DNAJB13, PGLYRP1, C3, and LMX1B, can be performed simultaneously. By doing so, we describe an adapted data analysis pipeline for LDBSP, allowing one to include and correct CpG methylation rates derived from multi-allele reactions. In addition, we show that the efficiency of LDBSP on DNA derived from LCM neurons is similar to the efficiency obtained in previously published studies using this technique on other cell types. Overall, the method described here provides the user with a more accurate estimation of the DNA methylation status of each target gene in the analyzed cell pools, thereby adding further validity to this approach. https://doi.org/10.3390/ijms232415571, This research was funded by by the Joint Programme—Neurodegenerative Disease Re- search (JPND) for the EPIAD consortium (http://www.neurodegenerationresearch.eu/wp-content/ uploads/2015/10/Factsheet_EPI-AD.pdf) (DvdH). The project is supported through the following funding organizations under the aegis of JPND; The Netherlands, The Netherlands Organisation for Health Research and Development (ZonMw); United Kingdom, Medical Research Council; Germany, German Federal ministry of Education and Research (BMBF); Luxembourg, National Research Fund (FNR). This project has received funding from the European Union's Horizon 2020 research and inno- vation programme under Grant Agreement No. 643417. Additional funds have been provided by the European Union's Horizon 2020 research and innovation program under the Marie Skłodowska-Curie grant agreements No. 813533 and No. 860895, and under Grant Agreement No. 643417 (KVS).

Published

2022

2. DNA methylation regulates the expression of the negative transcriptional regulators ID2 and ID4 during OPC differentiation

Author

Tim Vanmierlo, Niels Hellings, Daniel L.A. van den Hove, Patrick Vandormael, Assia Tiane, Jos Prickaerts, Renzo J. M. Riemens, Ben Rombaut, Melissa Schepers, Veerle Somers, Vanmierlo, Tim/0000-0003-2912-0578, RS: MHeNs - R3 - Neuroscience, and Psychiatrie & Neuropsychologie

Subjects

Biochemistry & Molecular Biology, PROTEINS, Gene Expression, Context (language use), Biology, Methylation, Epigenesis, Genetic, Mice, Cellular and Molecular Neuroscience, Myelination, Oligodendrocyte precursor cell, Gene expression, medicine, Animals, Epigenetics, Remyelination, Molecular Biology, Transcription factor, Cells, Cultured, Myelin Sheath, Inhibitor of Differentiation Protein 2, Oligodendrocyte Precursor Cells, Pharmacology, Science & Technology, MULTIPLE-SCLEROSIS LESIONS, Cell Differentiation, Cell Biology, ID2, DNA Methylation, CNS REMYELINATION, Oligodendrocyte, OLIGODENDROCYTES, Cell biology, medicine.anatomical_structure, nervous system, Gene Expression Regulation, ID4, DNA methylation, METHYLTRANSFERASE INHIBITORS, Molecular Medicine, Original Article, Inhibitor of Differentiation Proteins, Life Sciences & Biomedicine, Transcription Factors

Abstract

The differentiation of oligodendrocyte precursor cells (OPCs) into myelinating oligodendrocytes is the prerequisite for remyelination in demyelinated disorders such as multiple sclerosis (MS). Epigenetic mechanisms, such as DNA methylation, have been suggested to control the intricate network of transcription factors involved in OPC differentiation. Yet, the exact mechanism remains undisclosed. Here, we are the first to identify the DNA-binding protein inhibitors, Id2 and Id4, as targets of DNA methylation during OPC differentiation. Using state-of-the-art epigenetic editing via CRISPR/dCas9-DNMT3a, we confirm that targeted methylation of Id2/Id4 drives OPC differentiation. Moreover, we show that in the pathological context of MS, methylation and gene expression levels of both ID2 and ID4 are altered compared to control human brain samples. We conclude that DNA methylation is crucial to suppress ID2 and ID4 during OPC differentiation, a process that appears to be dysregulated during MS. Our data do not only reveal new insights into oligodendrocyte biology, but could also lead to a better understanding of CNS myelin disorders.

Published

2021

3. Targeted Molecular Analysis in Adrenocortical Carcinomas

Author

Silke Appenzeller, Andrea Gehrig, Barbara Altieri, Cristina L Ronchi, Sonja Steinhauer, Simone Rost, Silviu Sbiera, Juliane Lippert, Matthias Kroiss, Andreas Rosenwald, Martin Fassnacht, Clemens R. Mueller, Isabel Weigand, Raimunde Liang, Stefan Kircher, Renzo J. M. Riemens, Indrajit Nanda, Psychiatrie & Neuropsychologie, RS: MHeNs - R3 - Neuroscience, and Promovendi MHN

Subjects

Male, 0301 basic medicine, Oncology, Endocrinology, Diabetes and Metabolism, DNA Mutational Analysis, Clinical Biochemistry, MULTICENTER, Biochemistry, PATHWAY, 0302 clinical medicine, Endocrinology, Adrenocortical Carcinoma, Adrenocortical carcinoma, Molecular Targeted Therapy, Precision Medicine, Promoter Regions, Genetic, DNA METHYLATION, Aged, 80 and over, High-Throughput Nucleotide Sequencing, Middle Aged, CHEMOTHERAPY, Prognosis, TUMORS, CANCER, Progression-Free Survival, GENOMIC CHARACTERIZATION, 030220 oncology & carcinogenesis, DNA methylation, Female, Adult, medicine.medical_specialty, DNA Copy Number Variations, Antineoplastic Agents, CLASSIFICATION, Young Adult, 03 medical and health sciences, Germline mutation, MISMATCH-REPAIR, Internal medicine, REVEALS, Biomarkers, Tumor, medicine, Humans, Point Mutation, Progression-free survival, Survival analysis, Aged, Retrospective Studies, Receiver operating characteristic, business.industry, Point mutation, Biochemistry (medical), Precision medicine, medicine.disease, Survival Analysis, Adrenal Cortex Neoplasms, 030104 developmental biology, Adrenal Cortex, business, Follow-Up Studies

Abstract

Context Adrenocortical carcinoma (ACC) has a heterogeneous prognosis, and current medical therapies have limited efficacy in its advanced stages. Genome-wide multiomics studies identified molecular patterns associated with clinical outcome. Objective Here, we aimed at identifying a molecular signature useful for both personalized prognostic stratification and druggable targets, using methods applicable in clinical routine. Design In total, 117 tumor samples from 107 patients with ACC were analyzed. Targeted next-generation sequencing of 160 genes and pyrosequencing of 4 genes were applied to formalin-fixed, paraffin-embedded (FFPE) specimens to detect point mutations, copy number alterations, and promoter region methylation. Molecular results were combined with clinical/histopathological parameters (tumor stage, age, symptoms, resection status, and Ki-67) to predict progression-free survival (PFS). Results In addition to known driver mutations, we detected recurrent alterations in genes not previously associated with ACC (e.g., NOTCH1, CIC, KDM6A, BRCA1, BRCA2). Best prediction of PFS was obtained integrating molecular results (more than one somatic mutation, alterations in Wnt/β-catenin and p53 pathways, high methylation pattern) and clinical/histopathological parameters into a combined score (P < 0.0001, χ2 = 68.6). Accuracy of prediction for early disease progress was 83.3% (area under the receiver operating characteristic curve: 0.872, 95% confidence interval 0.80 to 0.94). Furthermore, 17 potentially targetable alterations were found in 64 patients (e.g., in CDK4, NOTCH1, NF1, MDM2, and EGFR and in DNA repair system). Conclusions This study demonstrates that molecular profiling of FFPE tumor samples improves prognostication of ACC beyond clinical/histopathological parameters and identifies new potential drug targets. These findings pave the way to precision medicine in this rare disease.

Published

2018

4. Methylomic profiling in trisomy 21 identifies cognition- and Alzheimer's disease-related dysregulation

Author

Larissa Haertle, Cécile Cieuta-Walti, Tobias Müller, André Mégarbané, Per Hoffmann, Steffi G. Riedel-Heller, Daniel L. A. van de Hove, Thomas Haaf, Nady El Hajj, Marcus Dittrich, Michael Wagner, Sophie Durand, Renzo J. M. Riemens, Mathilde Roche, Roy Lardenoije, Clotilde Mircher, Anna Maierhofer, Aimé Ravel, Martin Scherer, Alfredo Ramirez, Markus Leber, Samantha Stora, Psychiatrie & Neuropsychologie, RS: MHeNs - R2 - Mental Health, RS: MHeNs - R3 - Neuroscience, and Promovendi MHN

Subjects

Oncology, Epigenomics, Male, Trisomy 21, Down syndrome, Intellectual disability, genetics [Amyloid Precursor Protein Secretases], CHILDREN, genetics [Alzheimer Disease], Epigenesis, Genetic, genetics [ADAM10 Protein], ADAM10 Protein, Infinium Methylation EPIC arrays, 0302 clinical medicine, Cognition, Germany, methods [Epigenomics], Senile plaques, DOWN-SYNDROME, Longitudinal Studies, Prospective Studies, Cognitive decline, Genetics (clinical), 0303 health sciences, DNA methylation, DEMENTIA, diagnosis [Alzheimer Disease], Alzheimer's disease, Alzheimer’s disease, Cognitive function, Trisomy, genetics [Membrane Proteins], Female, Adult, medicine.medical_specialty, IMMUNITY, 03 medical and health sciences, Young Adult, Alzheimer Disease, Internal medicine, Genetics, medicine, genetics [Down Syndrome], Dementia, Humans, Epigenetics, ddc:610, GENOME-WIDE ASSOCIATION, Molecular Biology, METAANALYSIS, 030304 developmental biology, RECEPTOR, business.industry, Research, Membrane Proteins, DNA Methylation, medicine.disease, Differentially methylated regions, Early Diagnosis, Amyloid Precursor Protein Secretases, business, 030217 neurology & neurosurgery, EPIGENETIC DYSREGULATION, Developmental Biology, Genome-Wide Association Study

Abstract

Abstract Background Trisomy 21 (T21) is associated with intellectual disability that ranges from mild to profound with an average intellectual quotient of around 50. Furthermore, T21 patients have a high risk of developing Alzheimer’s disease (AD) early in life, characterized by the presence of senile plaques of amyloid protein and neurofibrillary tangles, leading to neuronal loss and cognitive decline. We postulate that epigenetic factors contribute to the observed variability in intellectual disability, as well as at the level of neurodegeneration seen in T21 individuals. Materials and Methods A genome-wide DNA methylation study was performed using Illumina Infinium® MethylationEPIC BeadChips on whole blood DNA of 3 male T21 patients with low IQ, 8 T21 patients with high IQ (4 males and 4 females), and 21 age- and sex-matched control samples (12 males and 9 females) in order to determine whether DNA methylation alterations could help explain variation in cognitive impairment between individuals with T21. In view of the increased risk of developing AD in T21 individuals, we additionally investigated the T21-associated sites in published blood DNA methylation data from the AgeCoDe cohort (German study on Ageing, Cognition, and Dementia). AgeCoDe represents a prospective longitudinal study including non-demented individuals at baseline of which a part develops AD dementia at follow-up. Results Two thousand seven hundred sixteen differentially methylated sites and regions discriminating T21 and healthy individuals were identified. In the T21 high and low IQ comparison, a single CpG located in the promoter of PELI1 was differentially methylated after multiple testing adjustment. For the same contrast, 69 differentially methylated regions were identified. Performing a targeted association analysis for the significant T21-associated CpG sites in the AgeCoDe cohort, we found that 9 showed significant methylation differences related to AD dementia, including one in the ADAM10 gene. This gene has previously been shown to play a role in the prevention of amyloid plaque formation in the brain. Conclusion The differentially methylated regions may help understand the interaction between methylation alterations and cognitive function. In addition, ADAM10 might be a valuable blood-based biomarker for at least the early detection of AD.

Published

2019

5. Directing neuronal cell fate in vitro: Achievements and challenges

Author

Raul Delgado-Morales, Renzo J. M. Riemens, D.L.A. van den Hove, and Manel Esteller

Subjects

0301 basic medicine, Epigenomics, Pluripotent Stem Cells, Cell type, Malalties cerebrals, Biology, Cell fate determination, In Vitro Techniques, Regenerative medicine, ADULT HUMAN FIBROBLASTS, DIRECT CONVERSION, 03 medical and health sciences, Directed differentiation, PARKINSONS-DISEASE, MOUSE EMBRYONIC STEM, FUNCTIONAL DOPAMINERGIC-NEURONS, Animals, EPIGENETIC REGULATION, Induced pluripotent stem cell, Brain disorders, Somatic cells, Neurons, Transdifferentiation, SPINAL MOTOR-NEURONS, Drug discovery, General Neuroscience, Cell Differentiation, Epigenètica, Cellular Reprogramming, NEURAL SUBTYPE SPECIFICATION, 030104 developmental biology, Neuronal differentiation, Disease modelling, Epigenetics, Brain diseases, PLURIPOTENT STEM-CELLS, Neuroscience, Reprogramming, Transcription Factors

Abstract

Human pluripotent stem cell (PSC) technology and direct somatic cell reprogramming have opened up a promising new avenue in the field of neuroscience. These recent advances allow researchers to obtain virtually any cell type found in the human brain, making it possible to produce and study functional neurons in laboratory conditions for both scientific and medical purposes. Although distinct approaches have shown to be successful in directing neuronal cell fate in vitro, their refinement and optimization, as well as the search for alternative approaches, remains necessary to help realize the full potential of the eventually derived neuronal populations. Furthermore, we are currently limited in the number of neuronal subtypes whose induction is fully established, and different cultivation protocols for each subtype exist, making it challenging to increase the reproducibility and decrease the variances that are observed between different protocols. In this review, we summarize the progress that has been made in generating various neuronal subtypes from PSCs and somatic cells, with special emphasis on chemically defined systems, transcription factor-mediated reprogramming and epigenetic-based approaches. We also discuss the efforts that are being made to increase the efficiency of current protocols and address the potential for the use of these cells in disease modelling, drug discovery and regenerative medicine.

Published

2017

6. Stem Cell Technology for (Epi)genetic Brain Disorders

Author

Renzo J M, Riemens, Edilene S, Soares, Manel, Esteller, and Raul, Delgado-Morales

Subjects

Brain Diseases, Stem Cells, Induced Pluripotent Stem Cells, Drug Evaluation, Preclinical, Genetic Diseases, Inborn, Nerve Tissue Proteins, Neurodegenerative Diseases, Regenerative Medicine, Stem Cell Research, Epigenesis, Genetic, Disease Models, Animal, Fetal Tissue Transplantation, Animals, Humans, Brain Tissue Transplantation, Forecasting, Stem Cell Transplantation

Abstract

Despite the enormous efforts of the scientific community over the years, effective therapeutics for many (epi)genetic brain disorders remain unidentified. The common and persistent failures to translate preclinical findings into clinical success are partially attributed to the limited efficiency of current disease models. Although animal and cellular models have substantially improved our knowledge of the pathological processes involved in these disorders, human brain research has generally been hampered by a lack of satisfactory humanized model systems. This, together with our incomplete knowledge of the multifactorial causes in the majority of these disorders, as well as a thorough understanding of associated (epi)genetic alterations, has been impeding progress in gaining more mechanistic insights from translational studies. Over the last years, however, stem cell technology has been offering an alternative approach to study and treat human brain disorders. Owing to this technology, we are now able to obtain a theoretically inexhaustible source of human neural cells and precursors in vitro that offer a platform for disease modeling and the establishment of therapeutic interventions. In addition to the potential to increase our general understanding of how (epi)genetic alterations contribute to the pathology of brain disorders, stem cells and derivatives allow for high-throughput drugs and toxicity testing, and provide a cell source for transplant therapies in regenerative medicine. In the current chapter, we will demonstrate the validity of human stem cell-based models and address the utility of other stem cell-based applications for several human brain disorders with multifactorial and (epi)genetic bases, including Parkinson's disease (PD), Alzheimer's disease (AD), fragile X syndrome (FXS), Angelman syndrome (AS), Prader-Willi syndrome (PWS), and Rett syndrome (RTT).

Published

2017

7. Stem Cell Technology for (Epi)genetic Brain Disorders

Author

Renzo J. M. Riemens, Edilene S. Soares, Raul Delgado-Morales, and Manel Esteller

Subjects

0301 basic medicine, business.industry, Rett syndrome, Disease, Human brain, medicine.disease, Regenerative medicine, Fragile X syndrome, 03 medical and health sciences, 030104 developmental biology, medicine.anatomical_structure, medicine, Epigenetics, Stem cell, Induced pluripotent stem cell, business, Neuroscience

Abstract

Despite the enormous efforts of the scientific community over the years, effective therapeutics for many (epi)genetic brain disorders remain unidentified. The common and persistent failures to translate preclinical findings into clinical success are partially attributed to the limited efficiency of current disease models. Although animal and cellular models have substantially improved our knowledge of the pathological processes involved in these disorders, human brain research has generally been hampered by a lack of satisfactory humanized model systems. This, together with our incomplete knowledge of the multifactorial causes in the majority of these disorders, as well as a thorough understanding of associated (epi)genetic alterations, has been impeding progress in gaining more mechanistic insights from translational studies. Over the last years, however, stem cell technology has been offering an alternative approach to study and treat human brain disorders. Owing to this technology, we are now able to obtain a theoretically inexhaustible source of human neural cells and precursors in vitro that offer a platform for disease modeling and the establishment of therapeutic interventions. In addition to the potential to increase our general understanding of how (epi)genetic alterations contribute to the pathology of brain disorders, stem cells and derivatives allow for high-throughput drugs and toxicity testing, and provide a cell source for transplant therapies in regenerative medicine. In the current chapter, we will demonstrate the validity of human stem cell-based models and address the utility of other stem cell-based applications for several human brain disorders with multifactorial and (epi)genetic bases, including Parkinson’s disease (PD), Alzheimer’s disease (AD), fragile X syndrome (FXS), Angelman syndrome (AS), Prader-Willi syndrome (PWS), and Rett syndrome (RTT).

Published

2017