Your search keyword '"Emma Coninx"' showing total 6 results

1. High-throughput microscopy exposes a pharmacological window in which dual leucine zipper kinase inhibition preserves neuronal network connectivity

Author

Marlies Verschuuren, Peter Verstraelen, Gerardo García-Díaz Barriga, Ines Cilissen, Emma Coninx, Mieke Verslegers, Peter H. Larsen, Rony Nuydens, and Winnok H. De Vos

Subjects

Neuronal connectivity, Neuronal network, Synapse, Calcium imaging, High-content screening, Neurodegeneration, Neurology. Diseases of the nervous system, RC346-429

Abstract

Abstract Therapeutic developments for neurodegenerative disorders are redirecting their focus to the mechanisms that contribute to neuronal connectivity and the loss thereof. Using a high-throughput microscopy pipeline that integrates morphological and functional measurements, we found that inhibition of dual leucine zipper kinase (DLK) increased neuronal connectivity in primary cortical cultures. This neuroprotective effect was not only observed in basal conditions but also in cultures depleted from antioxidants and in cultures in which microtubule stability was genetically perturbed. Based on the morphofunctional connectivity signature, we further showed that the effects were limited to a specific dose and time range. Thus, our results illustrate that profiling microscopy images with deep coverage enables sensitive interrogation of neuronal connectivity and allows exposing a pharmacological window for targeted treatments. In doing so, we revealed a broad-spectrum neuroprotective effect of DLK inhibition, which may have relevance to pathological conditions that ar.e associated with compromised neuronal connectivity.

Published

2019

2. Rosiglitazone Protects Endothelial Cells From Irradiation-Induced Mitochondrial Dysfunction

Author

Bjorn Baselet, Ronald B. Driesen, Emma Coninx, Niels Belmans, Tom Sieprath, Ivo Lambrichts, Winnok H. De Vos, Sarah Baatout, Pierre Sonveaux, and An Aerts

Subjects

ionizing radiation, endothelial cells, rosiglitazone, mitochondria, cardiovascular disease, Therapeutics. Pharmacology, RM1-950

Abstract

Background and PurposeUp to 50–60% of all cancer patients receive radiotherapy as part of their treatment strategy. However, the mechanisms accounting for increased vascular risks after irradiation are not completely understood. Mitochondrial dysfunction has been identified as a potential cause of radiation-induced atherosclerosis.Materials and MethodsAssays for apoptosis, cellular metabolism, mitochondrial DNA content, functionality and morphology were used to compare the response of endothelial cells to a single 2 Gy dose of X-rays under basal conditions or after pharmacological treatments that either reduced (EtBr) or increased (rosiglitazone) mitochondrial content.ResultsExposure to ionizing radiation caused a persistent reduction in mitochondrial content of endothelial cells. Pharmacological reduction of mitochondrial DNA content rendered endothelial cells more vulnerable to radiation-induced apoptosis, whereas rosiglitazone treatment increased oxidative metabolism and redox state and decreased the levels of apoptosis after irradiation.ConclusionPre-existing mitochondrial damage sensitizes endothelial cells to ionizing radiation-induced mitochondrial dysfunction. Rosiglitazone protects endothelial cells from the detrimental effects of radiation exposure on mitochondrial metabolism and oxidative stress. Thus, our findings indicate that rosiglitazone may have potential value as prophylactic for radiation-induced atherosclerosis.

Published

2020

3. Functional Gene Analysis Reveals Cell Cycle Changes and Inflammation in Endothelial Cells Irradiated with a Single X-ray Dose

Author

An Aerts, Bjorn Baselet, Niels Belmans, Emma Coninx, Donna Lowe, Ann Janssen, Arlette Michaux, Kevin Tabury, Kenneth Raj, Roel Quintens, Mohammed A. Benotmane, Sarah Baatout, and Pierre Sonveaux

Subjects

X-ray, endothelium, atherosclerosis, cardiovascular disease, cell cycle, Therapeutics. Pharmacology, RM1-950

Abstract

Background and Purpose: Epidemiological data suggests an excess risk of cardiovascular disease (CVD) at low doses (0.05 and 0.1 Gy) of ionizing radiation (IR). Furthermore, the underlying biological and molecular mechanisms of radiation-induced CVD are still unclear. Because damage to the endothelium could be critical in IR-related CVD, this study aimed to identify the effects of radiation on immortalized endothelial cells in the context of atherosclerosis.Material and Methods: Microarrays and RT-qPCR were used to compare the response of endothelial cells irradiated with a single X-ray dose (0.05, 0.1, 0.5, 2 Gy) measured after various post-irradiation (repair) times (1 day, 7 days, 14 days). To consolidate and mechanistically support the endothelial cell response to X-ray exposure identified via microarray analysis, DNA repair signaling (γH2AX/TP53BP1-foci quantification), cell cycle progression (BrdU/7AAD flow cytometric analysis), cellular senescence (β-galactosidase assay with CPRG and IGFBP7 quantification) and pro-inflammatory status (IL6 and CCL2) was assessed.Results: Microarray results indicated persistent changes in cell cycle progression and inflammation. Cells underwent G1 arrest in a dose-dependent manner after high doses (0.5 and 2 Gy), which was compensated by increased proliferation after 1 week and almost normalized after 2 weeks. However, at this point irradiated cells showed an increased β-Gal activity and IGFBP7 secretion, indicative of premature senescence. The production of pro-inflammatory cytokines IL6 and CCL2 was increased at early time points.Conclusions: IR induces pro-atherosclerotic processes in endothelial cells in a dose-dependent manner. These findings give an incentive for further research on the shape of the dose-response curve, as we show that even low doses of IR can induce premature endothelial senescence at later time points. Furthermore, our findings on the time- and dose-dependent response regarding differentially expressed genes, cell cycle progression, inflammation and senescence bring novel insights into the underlying molecular mechanisms of the endothelial response to X-ray radiation. This may in turn lead to the development of risk-reducing strategies to prevent IR-induced CVD, such as the use of cell cycle modulators and anti-inflammatory drugs as radioprotectors and/or radiation mitigators.

Published

2017

4. Hippocampal and cortical tissue-specific epigenetic clocks indicate an increased epigenetic age in a mouse model for Alzheimer’s disease

Author

Amelie Coolkens, Xiaojing Yang, Roel Quintens, Mieke Verslegers, Wei Guo, Yap Ching Chew, Emma Coninx, Lieve Moons, and Sarah Baatout

Subjects

Aging, Transgene, Hippocampus, Cell Biology, Human brain, Hippocampal formation, Biology, medicine.anatomical_structure, Cerebral cortex, Cortex (anatomy), DNA methylation, medicine, Epigenetics, Neuroscience

Abstract

Epigenetic clocks are based on age-associated changes in DNA methylation of CpG-sites, which can accurately measure chronological age in different species. Recently, several studies have indicated that the difference between chronological and epigenetic age, defined as the age acceleration, could reflect biological age indicating functional decline and age-associated diseases. In humans, an epigenetic clock associated Alzheimer's disease (AD) pathology with an acceleration of the epigenetic age. In this study, we developed and validated two mouse brain region-specific epigenetic clocks from the C57BL/6J hippocampus and cerebral cortex. Both clocks, which could successfully estimate chronological age, were further validated in a widely used mouse model for AD, the triple transgenic AD (3xTg-AD) mouse. We observed an epigenetic age acceleration indicating an increased biological age for the 3xTg-AD mice compared to non-pathological C57BL/6J mice, which was more pronounced in the cortex as compared to the hippocampus. Genomic region enrichment analysis revealed that age-dependent CpGs were enriched in genes related to developmental, aging-related, neuronal and neurodegenerative functions. Due to the limited access of human brain tissues, these epigenetic clocks specific for mouse cortex and hippocampus might be important in further unravelling the role of epigenetic mechanisms underlying AD pathology or brain aging in general.

Published

2020

5. High-throughput microscopy exposes a pharmacological window in which dual leucine zipper kinase inhibition preserves neuronal network connectivity

Author

Mieke Verslegers, Rony Nuydens, Peter Larsen, Emma Coninx, Ines Cilissen, Marlies Verschuuren, Gerardo García-Díaz Barriga, Peter Verstraelen, and Winnok H. De Vos

Subjects

0301 basic medicine, Neuronal network, Calcium imaging, Neuronal connectivity, Neuroprotection, lcsh:RC346-429, Pathology and Forensic Medicine, 03 medical and health sciences, Cellular and Molecular Neuroscience, 0302 clinical medicine, Microtubule, Microscopy, medicine, Biological neural network, Neurodegeneration, lcsh:Neurology. Diseases of the nervous system, Chemistry, Methodology Article, High-content screening, Antioxidant depletion, hTau.P301L, medicine.disease, Synapse, Cell biology, 030104 developmental biology, DUAL LEUCINE ZIPPER KINASE, Human medicine, Neurology (clinical), 030217 neurology & neurosurgery

Abstract

Therapeutic developments for neurodegenerative disorders are redirecting their focus to the mechanisms that contribute to neuronal connectivity and the loss thereof. Using a high-throughput microscopy pipeline that integrates morphological and functional measurements, we found that inhibition of dual leucine zipper kinase (DLK) increased neuronal connectivity in primary cortical cultures. This neuroprotective effect was not only observed in basal conditions but also in cultures depleted from antioxidants and in cultures in which microtubule stability was genetically perturbed. Based on the morphofunctional connectivity signature, we further showed that the effects were limited to a specific dose and time range. Thus, our results illustrate that profiling microscopy images with deep coverage enables sensitive interrogation of neuronal connectivity and allows exposing a pharmacological window for targeted treatments. In doing so, we revealed a broad-spectrum neuroprotective effect of DLK inhibition, which may have relevance to pathological conditions that ar.e associated with compromised neuronal connectivity. Electronic supplementary material The online version of this article (10.1186/s40478-019-0741-3) contains supplementary material, which is available to authorized users.

Published

2019

6. Deep coverage microscopy exposes a pharmacological window for modifiers of neuronal network connectivity

Author

Mieke Verslegers, Gerardo García-Díaz Barriga, Peter Larsen, Winnok H. De Vos, Emma Coninx, Rony Nuydens, Peter Verstraelen, Ines Cilissen, and Marlies Verschuuren

Subjects

Cell type, Pharmacological interventions, Time windows, DUAL LEUCINE ZIPPER KINASE, Synaptic plasticity, Biological neural network, Biology, Neuroprotection, Neuroscience

Abstract

BackgroundTherapeutic developments for neurodegenerative disorders are redirecting their focus to the mechanisms that contribute to synaptic plasticity and the loss thereof. Identification of novel regulators requires a method to quantify neuronal network connectivity with high accuracy and throughput. To meet this demand, we have established a microscopy-based pipeline that integrates morphological and functional correlates of connectivity in primary neuronal culture.ResultsWe unveiled a connectivity signature that was specific to the cell type and culture age. We defined a score that accurately reports on the degree of neuronal connectivity and we validated this score by targeted perturbation of microtubule stability and selective depletion of anti-oxidants. With a focused compound screen, we discovered that inhibition of dual leucine zipper kinase activity increased neuronal connectivity in otherwise unperturbed cultures and exerted neuroprotective effects in cultures grown under sub-optimal or challenged conditions.ConclusionsOur results illustrate that profiling microscopy images with deep coverage enables sensitive interrogation of neuronal connectivity and allows exposing a dose and time window for pharmacological interventions. Therefore, the current approach holds promise for identifying pathways and compounds that preserve or rescue neuronal connectivity in neurodegenerative disorders.

Published

2019