Your search keyword '"Fabian, Claire"' showing total 5 results

1. Bistable Epigenetic States Explain Age-Dependent Decline in Mesenchymal Stem Cell Heterogeneity.

Author

Hamidouche Z, Rother K, Przybilla J, Krinner A, Clay D, Hopp L, Fabian C, Stolzing A, Binder H, Charbord P, and Galle J

Subjects

Animals, Antigens, Ly metabolism, Bone Marrow Cells cytology, Cell Differentiation genetics, Cell Proliferation, Clone Cells, Gene Expression Profiling, Membrane Proteins metabolism, Mesenchymal Stem Cells cytology, Mice, Inbred C57BL, Models, Biological, Models, Genetic, Promoter Regions, Genetic, Aging genetics, Epigenesis, Genetic, Mesenchymal Stem Cells metabolism

Abstract

The molecular mechanisms by which heterogeneity, a major characteristic of stem cells, is achieved are yet unclear. We here study the expression of the membrane stem cell antigen-1 (Sca-1) in mouse bone marrow mesenchymal stem cell (MSC) clones. We show that subpopulations with varying Sca-1 expression profiles regenerate the Sca-1 profile of the mother population within a few days. However, after extensive replication in vitro, the expression profiles shift to lower values and the regeneration time increases. Study of the promoter of Ly6a unravels that the expression level of Sca-1 is related to the promoter occupancy by the activating histone mark H3K4me3. We demonstrate that these findings can be consistently explained by a computational model that considers positive feedback between promoter H3K4me3 modification and gene transcription. This feedback implicates bistable epigenetic states which the cells occupy with an age-dependent frequency due to persistent histone (de-)modification. Our results provide evidence that MSC heterogeneity, and presumably that of other stem cells, is associated with bistable epigenetic states and suggest that MSCs are subject to permanent state fluctuations. Stem Cells 2017;35:694-704., (© The Authors Stem Cells published by Wiley Periodicals, Inc. on behalf of AlphaMed Press.)

Published

2017

2. H3K4me1 marks DNA regions hypomethylated during aging in human stem and differentiated cells

Author

Jan de Boer, Manel Esteller, Agustín F. Fernández, Gustavo F. Bayón, Maria Antonietta Stazi, Flor M. Pérez-Campo, Estela G. Toraño, José A. Riancho, Clara Bueno, Mario F. Fraga, Sebastian Moran, Pablo Martínez-Camblor, Virgilia Toccaceli, Corrado Fagnani, Lorenza Nisticò, Pablo Menendez, Jesus Delgado-Calle, Cecilia Ferrero, Fabian Claire, Javier García-Castro, Alexandra Stolzing, Katia Mareschi, Rocío G. Urdinguio, Emanuela Medda, Sandra Petrus-Reurer, Anouk Mentink, María Begoña González García, Isabel Cubillo, Sonia Brescianini, Antonella Carella, Faculty of Science and Technology, Instituto de Salud Carlos III, European Regional Development Fund, Consejo Superior de Investigaciones Científicas (España), Fundación Científica AECC, Fundación Ramón Areces, Comunidad de Madrid, Ministerio de Economía y Competitividad (España), Fundación Sandra Ibarra, Fundación La Caixa, Fundación Jose Carreras, Fundación Cajastur, Universidad de Cantabria, Publica, CBITE, RS: MERLN - Cell Biology - Inspired Tissue Engineering (CBITE), Institute MERLN, Instituto de Salud Carlos III - ISCIII, European Regional Development Fund (ERDF/FEDER), and Fondo de Investigaciones Sanitarias

Subjects

Aging, METIS-308231, ADN, Stem cells, Epigenesis, Genetic, Histones, Histone methylation, Child, Promoter Regions, Genetic, RNA-Directed DNA Methylation, Genetics (clinical), Cells, Cultured, Epigenomics, Aged, 80 and over, Stem Cells, Cell Differentiation, Middle Aged, Chromatin, IR-95058, Child, Preschool, DNA methylation, Corrigendum, Metilació, Cèl·lules mare, Reprogramming, Mesenchymal stem cells, epigenetics, Adolescent, Citologia, Biology, Methylation, Young Adult, Epigenetics of physical exercise, Envelliment, Genetics, Humans, Epigenetics, Aged, Research, Sequence Analysis, DNA, Twins, Monozygotic, DNA, DNA Methylation, Microarray Analysis, Molecular biology, Cytology, Protein Processing, Post-Translational, Genètica

Abstract

Corrigendum: H3K4me1 marks DNA regions hypomethylated during aging in human stem and differentiated cells. Genome Res. 2019 Apr;29(4):710.2. doi: 10.1101/gr.249417.119. PMID: 30936177. In differentiated cells, aging is associated with hypermethylation of DNA regions enriched in repressive histone post-translational modifications. However, the chromatin marks associated with changes in DNA methylation in adult stem cells during lifetime are still largely unknown. Here, DNA methylation profiling of mesenchymal stem cells (MSCs) obtained from individuals aged 2 to 92 yr identified 18,735 hypermethylated and 45,407 hypomethylated CpG sites associated with aging. As in differentiated cells, hypermethylated sequences were enriched in chromatin repressive marks. Most importantly, hypomethylated CpG sites were strongly enriched in the active chromatin mark H3K4me1 in stem and differentiated cells, suggesting this is a cell type-independent chromatin signature of DNA hypomethylation during aging. Analysis of scedasticity showed that interindividual variability of DNA methylation increased during aging in MSCs and differentiated cells, providing a new avenue for the identification of DNA methylation changes over time. DNA methylation profiling of genetically identical individuals showed that both the tendency of DNA methylation changes and scedasticity depended on nongenetic as well as genetic factors. Our results indicate that the dynamics of DNA methylation during aging depend on a complex mixture of factors that include the DNA sequence, cell type, and chromatin context involved and that, depending on the locus, the changes can be modulated by genetic and/or external factors. We thank Ronnie Lendrum for manuscript preparation and Tim Triche Jr. for his invaluable advice. This work has been financially supported by the Plan Nacional de I+D+I 2008-2011/2013-2016/FEDER (PI11/01728 to A.F.F., PI 12/0615 to J.A.R., PI10/0449 to P.M., and PI11/0119 to C.B.); the ISCIII-Subdirección General de Evaluación y Fomento de la Investigación (Miguel Servet contracts CP11/00131 to A.F.F. and CP07/0059 to C.B.); the Spanish Ministry of Health (PS09/02454 and PI12/01080 to M.F.F.); the Spanish National Research Council (CSIC; 200820I172 to M.F.F.); IUOPA (to C.F. and G.F.B.); Fundacion Cientifica de la AECC (to R.G.U. and P.M.); Fundación Ramón Areces (to M.F.F.); and FICYT (to E.G.T.). J.G.-C. receives funding from the Fondo de Investigaciones Sanitarias (FIS; PI05/2217 and PI08/0029) and the Madrid Regional Government (S-BIO-0204-2006 and S2010/BMD-2420). J.A.R. receives funding from the Fondo de Investigaciones Sanitarias (ISCIII-FIS PI 12/0615). P.M. is also supported by MINECO (SAF2013/43065), ERANET E-Rare (PI112/03112), and Fundación Sandra Ibarra. P.M. also acknowledges support from Obra Social “La Caixa/Fundacio Josep Carreras.” The IUOPA is supported by the Obra Social Cajastur, Spain. Sí

Published

2015

3. Distribution pattern following systemic mesenchymal stem cell injection depends on the age of the recipient and neuronal health.

Author

Fabian, Claire, Naaldijk, Yahaira, Leovsky, Christiane, Johnson, Adiv A., Rudolph, Lukas, Jaeger, Carsten, Arnold, Katrin, and Stolzing, Alexandra

Subjects

*MESENCHYMAL stem cells, *AGING, *ALZHEIMER'S disease, *TREATMENT effectiveness, *POLYMERASE chain reaction, *LABORATORY mice

Abstract

Background: Mesenchymal stem cells (MSCs) show therapeutic efficacy in many different age-related degenerative diseases, including Alzheimer's disease. Very little is currently known about whether or not aging impacts the transplantation efficiency of MSCs. Methods: In this study, we investigated the distribution of intravenously transplanted syngeneic MSCs derived from young and aged mice into young, aged, and transgenic APP/PS1 Alzheimer's disease mice. MSCs from male donors were transplanted into female mice and their distribution pattern was monitored by PCR using Y-chromosome specific probes. Biodistribution of transplanted MSCs in the brains of APP/PS1 mice was additionally confirmed by immunofluorescence and confocal microscopy. Results: Four weeks after transplantation into young mice, young MSCs were found in the lung, axillary lymph nodes, blood, kidney, bone marrow, spleen, liver, heart, and brain cortex. In contrast, young MSCs that were transplanted into aged mice were only found in the brain cortex. In both young and aged mouse recipients, transplantation of aged MSCs showed biodistribution only in the blood and spleen. Although young transplanted MSCs only showed neuronal distribution in the brain cortex in young mice, they exhibited a wide neuronal distribution pattern in the brains of APP/PS1 mice and were found in the cortex, cerebellum, hippocampus, olfactory bulb, and brainstem. The immunofluorescent signal of both transplanted MSCs and resident microglia was robust in the brains of APP/PS1 mice. Monocyte chemoattractant-1 levels were lowest in the brain cortex of young mice and were significantly increased in APP/PS1 mice. Within the hippocampus, monocyte chemoattractant-1 levels were significantly higher in aged mice compared with younger and APP/PS1 mice. Conclusions: We demonstrate in vivo that MSC biodistribution post transplantation is detrimentally affected by aging and neuronal health. Aging of both the recipient and the donor MSCs used attenuates transplantation efficiency. Clinically, our data would suggest that aged MSCs should not be used for transplantation and that transplantation of MSCs into aged patients will be less efficacious. [ABSTRACT FROM AUTHOR]

Published

2017

4. P 160 - Microglia based Alzheimer therapy.

Author

Arnold, Katrin, Fabian, Claire, and Stolzing, Alexandra

Subjects

*ALZHEIMER'S disease diagnosis, *MICROGLIA, *TRANSPLANTATION of organs, tissues, etc.

Abstract

Alzheimer's disease (AD) is an age-related neurodegenerative disease associated with the formation of amyloid plaques, tau aggregation and oxidative/inflammatory damage. Microglia play an important role in the early phase of the disease and are known to be involved in AD progression. Senescent microglia accumulate in AD causing inflammation, neuronal damage and increasing the Aß load due to a failing protein degradation system. This study examines the transplantation of in vitro derived young microglia from wild type mice (aged ~3 months) to the brain of AD mice (APP/PS1 transgenic model: >12 months). Microglia could be detected in the brain for four weeks after transplantation. Analysis of amyloid content shows a significant reduction as well as improved inflammation markers. Microglia and astrocyte morphology and activation status was analysed using histology. Changes in the short term memory of the recipient animals was analysed using a maze and found to be improved. Current analysis focuses on the quality and M1/M2 status of the microglia produced for transplantation to better understand if the therapeutic effect can be improved. [ABSTRACT FROM AUTHOR]

Published

2017

5. Biodistribution of in vitro--derived microglia applied intranasally and intravenously to mice: effects of aging.

Author

LEOVSKY, CHRISTIANE, BÖHME, JOSEPHINE, FABIAN, CLAIRE, NAALDIJK, YAHAIRA, RUDOLPH, LUKAS, STOLZING, ALEXANDRA, JÄGER, CARSTEN, and HWA JIN JANG

Subjects

*MICROGLIA, *INTRAVENOUS therapy, *AGING

Abstract

Background aims. The age of both the donor and the recipient has a potential influence on the efficacy of various cell therapies, but the underlying mechanisms are still being charted. We studied the effect of donor and recipient age in the context of microglia migration. Methods. Microglia were in vitro--differentiated from bone marrow of young (3 months) and aged (12 months) mice and transplanted into young (~3 months) and aged (~17 months) C57BI76 mice (n = 25) through intravenous and intranasal application routes. Recipients were not immune-suppressed or irradiated. Transplanted microglia were tracked through the use of a sex-mismatched setup or histologically with the use of cells from enhanced green fluorescent protein enhanced green fluorescent protein transgenic mice. Results. No acute rejections or transplant-associated toxicity was observed. After 10 days, both intravenously and intranasally transplanted cells were detected in the brain. Transplanted cells were also found in the blood and the lymph system. The applied cells were also tracked in lungs and kidney but only after intravenous injection subjected to a "pulmonary first-pass effect." After 28 days, intravenously delivered cells were also found in the bone marrow and other organs, especially in aged recipients. Whereas in young recipients the transplanted microglia did not appear to persist, in aged brains the transplanted cells could still be identified up to 28 days after transplantation. However, when cells from aged donors were used, no signals of transplanted cells could be detected in the recipients. Conclusions. This study establishes proof of principle that in Arro-derived microglia from young but not from aged donors, intravenously or intranasally transplanted, migrate to the brain in young and aged recipients. [ABSTRACT FROM AUTHOR]

Published

2015