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15 results on '"Pascal de Boer"'

1. Large-scale electron microscopy database for human type 1 diabetes

Author

Pascal de Boer, Nicole M. Pirozzi, Anouk H. G. Wolters, Jeroen Kuipers, Irina Kusmartseva, Mark A. Atkinson, Martha Campbell-Thompson, and Ben N. G. Giepmans

Subjects
Science
Abstract

Type 1 diabetes is associated with autoimmune destruction of pancreatic beta-cells. Here the authors compose a large-scale electron microscopy image data base of pancreatic organ donor tissue to enable data mining and further understanding of the disease.

Published
2020
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2. State‐of‐the‐art microscopy to understand islets of Langerhans: what to expect next?

Author

Pascal de Boer and Ben N G Giepmans

Subjects
0301 basic medicine, Computer science, Immunology, Reviews, large‐scale electron microscopy, multimodal imaging, Microscopic description, CA2+ DYNAMICS, model systems, 03 medical and health sciences, Islets of Langerhans, AGE, 0302 clinical medicine, data management and analysis, Special Feature Review, Insulin-Secreting Cells, intravital microscopy, ABLATION, Immunology and Allergy, Animals, large&#8208, Electron microscopic, Pancreas, ELECTRON-MICROSCOPY, geography, Microscopy, geography.geographical_feature_category, ZEBRAFISH, IN-SITU, Cellular imaging, ORGANELLES, Cell Biology, Islet, scale electron microscopy, Functional imaging, biobank, 030104 developmental biology, Diabetes Mellitus, Type 1, RESOLUTION, TISSUE, SPECIAL FEATURE to celebrate 100 years since the discovery of insulin, PANCREATIC BETA-CELLS, %22">Fish , Spatiotemporal resolution, Beta cell, Neuroscience, 030215 immunology
Abstract

The discovery of Langerhans and microscopic description of islets in the pancreas were crucial steps in the discovery of insulin. Over the past 150 years, many discoveries in islet biology and type 1 diabetes have been made using powerful microscopic techniques. In the past decade, combination of new probes, animal and tissue models, application of new biosensors and automation of light and electron microscopic methods and other (sub)cellular imaging modalities have proven their potential in understanding the beta cell under (patho)physiological conditions. The imaging evolution, from fluorescent jellyfish to real‐time intravital functional imaging, the revolution in automation and data handling and the increased resolving power of analytical imaging techniques are now converging. Here, we review innovative approaches that address islet biology from new angles by studying cells and molecules at high spatiotemporal resolution and in live models. Broad implementation of these cellular imaging techniques will shed new light on cause/consequence of (mal)function in islets of Langerhans in the years to come., Innovative microscopic approaches that allow to address islet biology from new angles by studying cells and molecules at high spatiotemporal resolution and in live models are reviewed in this article. Broad implementation of these cellular imaging techniques will shed new light into the cause/consequence of (mal)function of islet of Langerhans in the years to come.

Published
2021

3. Pancreatic beta cell autophagy is impaired in type 1 diabetes

Author

Amelia K. Linnemann, Charanya Muralidharan, Abass M. Conteh, Pascal de Boer, Jeroen Kuipers, Michelle Marasco, and Justin J. Crowder

Subjects
Adult, Male, 0301 basic medicine, Autophagosome, medicine.medical_specialty, Adolescent, Endocrinology, Diabetes and Metabolism, Autophagy-Related Proteins, Nod, Article, Young Adult, 03 medical and health sciences, 0302 clinical medicine, Mice, Inbred NOD, Insulin-Secreting Cells, Internal medicine, Diabetes mellitus, Macroautophagy, Internal Medicine, medicine, Autophagy, Animals, Humans, NOD mice, Proinsulin, Type 1 diabetes, business.industry, Autoantibody-positive, medicine.disease, Lysosome, Disease Models, Animal, Diabetes Mellitus, Type 1, 030104 developmental biology, Endocrinology, Crinophagy, Case-Control Studies, Female, Beta cell, Lysosomes, business, 030217 neurology & neurosurgery, Signal Transduction
Abstract

Aims/hypothesis Pancreatic beta cells are subjected to exogenous damaging factors such as proinflammatory cytokines or excess glucose that can cause accumulation of damage-inducing reactive oxygen species during the pathogenesis of diabetes. We and others have shown that beta cell autophagy can reduce reactive oxygen species to protect against apoptosis. While impaired islet autophagy has been demonstrated in human type 2 diabetes, it is unknown if islet autophagy is perturbed in the pathogenesis of type 1 diabetes. We hypothesised that beta cell autophagy is dysfunctional in type 1 diabetes, and that there is a progressive loss during early diabetes development. Methods Pancreases were collected from chloroquine-injected and non-injected non-obese diabetes-resistant (NOR) and non-obese diabetic (NOD) mice. Age- and BMI-matched pancreas tissue sections from human organ donors (N = 34) were obtained from the Network for Pancreatic Organ Donors with Diabetes (nPOD). Tissue sections were stained with antibodies against proinsulin or insulin (beta cell markers), microtubule-associated protein 1 light chain 3 A/B (LC3A/B; autophagosome marker), lysosomal-associated membrane protein 1 (LAMP1; lysosome marker) and p62 (autophagy adaptor). Images collected on a scanning laser confocal microscope were analysed with CellProfiler and ImageJ. Secondary lysosomes and telolysosomes were assessed in electron micrographs of human pancreatic tissue sections (n = 12), and energy dispersive x-ray analysis was performed to assess distribution of elements (n = 5). Results We observed increased autophagosome numbers in islets of diabetic NOD mice (p = 0.008) and increased p62 in islets of both non-diabetic and diabetic NOD mice (p p p p = 0.003) and non-diabetic NOD mice (p p p p p = 0.002). Conclusions/interpretation We provide evidence of islet macroautophagy/crinophagy impairment in human type 1 diabetes. We also document accumulation of telolysosomes with peripheral nitrogen in beta cells of autoantibody-positive donors, demonstrating altered lysosome content that may be associated with lysosome dysfunction before clinical hyperglycaemia. Similar macroautophagy impairments are present in the NOD mouse model of type 1 diabetes. Graphical abstract

Published
2021
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4. Electron-Beam Induced Luminescence and Bleaching in Polymer Resins and Embedded Biomaterial

Author

Pascal de Boer, Jacob P. Hoogenboom, Ben N G Giepmans, Aditi Srinivasa Raja, ​Basic and Translational Research and Imaging Methodology Development in Groningen (BRIDGE), and Center for Liver, Digestive and Metabolic Diseases (CLDM)

Subjects
Luminescence, Materials science, Polymers and Plastics, Polymers, FABRICATION, Biocompatible Materials, Bioengineering, Cathodoluminescence, Methacrylate, Fluence, law.invention, Biomaterials, law, Materials Chemistry, Electron beam processing, embedding resins, Humans, correlative light and electron microscopy, electron-beam irradiation, chemistry.chemical_classification, Microscopy, electron-beam induced luminescence, business.industry, polymer luminescence, cathodoluminescence, Polymer, chemistry, radiation damage, Optoelectronics, Durcupan, Electron microscope, business, HeLa Cells, Biotechnology
Abstract

Electron microscopy is crucial for imaging biological ultrastructure at nanometer resolution. However, electron irradiation also causes specimen damage, reflected in structural and chemical changes that can give rise to alternative signals. Here, luminescence induced by electron-beam irradiation is reported across a range of materials widely used in biological electron microscopy. Electron-induced luminescence is spectrally characterized in two epoxy (Epon, Durcupan) and one methacrylate resin (HM20) over a broad electron fluence range, from 10−4 to 103 mC cm−2, both with and without embedded biological samples. Electron-induced luminescence is pervasive in polymer resins, embedded biomaterial, and occurs even in fixed, whole cells in the absence of resin. Across media, similar patterns of intensity rise, spectral red-shifting, and bleaching upon increasing electron fluence are observed. Increased landing energies cause reduced scattering in the specimen shifting the luminescence profiles to higher fluences. Predictable and tunable electron-induced luminescence in natural and synthetic polymer media is advantageous for turning many polymers into luminescent nanostructures or to fluorescently visualize (micro)plastics. Furthermore, these findings provide perspective to direct electron-beam excitation approaches like cathodoluminescence that may be obscured by these nonspecific electron-induced signals.

Published
2021

6. Nanotomy

Author

Ben N G Giepmans, Pascal de Boer, Anouk H G Wolters, and Jeroen Kuipers

Published
2021
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7. Pancreatic Beta Cell Autophagy is Impaired in Type 1 Diabetes

Author

Michelle Marasco, Pascal de Boer, Charanya Muralidharan, Jeroen Kuipers, Justin J. Crowder, Ben N G Giepmans, Abass M. Conteh, and Amelia K. Linnemann

Subjects
Autophagosome, medicine.medical_specialty, Type 1 diabetes, Chemistry, Autophagy, Nod, medicine.disease, Endocrinology, medicine.anatomical_structure, Lysosome, Internal medicine, medicine, Beta cell, Proinsulin, NOD mice
Abstract

Aims/hypothesisPancreatic beta cells are highly metabolic secretory cells that are subjected to exogenous damaging factors such as proinflammatory cytokines or excess glucose that can cause accumulation of damage-inducing reactive oxygen species (ROS) during the pathogenesis of diabetes. We and others have shown that beta cell autophagy can reduce ROS to protect against apoptosis both in vitro and in vivo. While impaired islet autophagy has been demonstrated in human type 2 diabetes, it is unknown if islet autophagy is perturbed in the pathogenesis of type 1 diabetes. We hypothesized that beta cell autophagy is dysfunctional in type 1 diabetes, and that there is a progressive loss during early diabetes development.MethodsMouse pancreata were collected from chloroquine injected and non-injected NOR, nondiabetic NOD, and diabetic NOD mice. Age and BMI-matched pancreas tissue sections from human organ donors (n=34) were obtained from the Network for Pancreatic Organ Donors with Diabetes (nPOD). To assess autophagic flux, we injected the mice with chloroquine to inhibit the final stages of autophagy. We analyzed tissues for markers of autophagy via immunofluorescence analysis. Tissue sections were stained with antibodies against proinsulin or insulin (beta cell markers), LC3A/B (autophagosome marker), Lamp1 (lysosome marker), and p62 (autophagy adaptor protein and marker for autophagic flux). Images were collected on a scanning laser confocal microscope then analyzed with CellProfiler and ImageJ. Secondary lysosomes and telolysosomes (formerly called lipofuscin bodies, residual bodies or tertiary lysosomes) were analyzed in electron micrographs of pancreatic tissue sections from human organ donors (nPOD; n=12) deposited in www.nanotomy.org/OA/nPOD. Energy Dispersive X-ray (EDX) analysis was also performed on these tissues to analyze distribution of elements such as nitrogen, phosphorus, and osmium in secondary lysosomes and telolysosomes of nondiabetic and autoantibody positive donor tissues (n=5).ResultsWe observed increased autophagosome numbers in islets of diabetic NOD mice (p=0.0077) and increased p62 in islets of both nondiabetic and diabetic NOD mice (pConclusions/interpretationCollectively, we provide evidence of impairment in the final degradation stages of islet macroautophagy and crinophagy in human type 1 diabetes. We also document an accumulation of telolysosomes with nitrogen accumulation at their periphery in the beta cells of autoantibody positive donors. This demonstrates clear differences in the lysosome contents of autoantibody positive donors that may be associated with lysosome dysfunction prior to clinical hyperglycemia. We observe similar impairments in macroautophagy in the diabetic NOD mouse, a model of type 1 diabetes, suggesting that this mouse model can be appropriately used to study the pathogenesis of autophagy/crinophagy loss and how it relates to disease initiation and progression. Considering these data in the context of what is known regarding the cell-protective effects of islet autophagy, we suggest targeting beta cell autophagy pathways as an approach to reduce apoptosis in individuals at risk for type 1 diabetes development.Research in contextWhat is already known about this subject?Autophagy confers a cytoprotective role in the beta cell.Autophagy is reduced in type 2 diabetes.Autophagy in the context of type 1 diabetes is unexplored.What is the key question?Is autophagy reduced during the pathogenesis of human type 1 diabetes?What are the new findings?We provide evidence of reduced autophagy and crinophagy in human type 1 diabetes.These data are supported by observations of reduced autophagy in a mouse model of autoimmune diabetes.How might this impact on clinical practice in the foreseeable future?This study provides evidence that autophagy is impaired in human type 1 diabetes. Prior studies have shown that loss of autophagy in the islet is associated with increased beta cell apoptosis, therefore we propose that therapeutic targeting of autophagy pathways may reduce beta cell death in type 1 diabetes development.

Published
2020
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8. TLR3 agonists induce fibronectin aggregation by activated astrocytes

Author

Pascal de Boer, Jing Qin, Joris B. Versluijs, Arend H. Sikkema, Inge L. Werkman, Wia Baron, and Molecular Neuroscience and Ageing Research (MOLAR)

Subjects
EXPRESSION, Integrin, Central nervous system, lcsh:Medicine, EIIIA DOMAIN, Article, Proinflammatory cytokine, Multiple sclerosis, Protein Aggregates, Demyelinating disease, medicine, Cell Adhesion, EXTRACELLULAR-MATRIX, Animals, Humans, Protein Isoforms, Remyelination, Gray Matter, lcsh:Science, TOLL-LIKE RECEPTORS, Multidisciplinary, biology, Chemistry, lcsh:R, MULTIPLE-SCLEROSIS LESIONS, Fibrillogenesis, medicine.disease, CNS REMYELINATION, White Matter, OLIGODENDROCYTES, Cell biology, Fibronectins, Rats, Toll-Like Receptor 3, Fibronectin, medicine.anatomical_structure, Poly I-C, DIFFERENTIATION, PROGENITOR CELLS, Astrocytes, biology.protein, lcsh:Q, Astrocyte, Extracellular Space, INTEGRIN
Abstract

Multiple sclerosis (MS) is a chronic demyelinating disease of the central nervous system which eventually results in axonal loss mainly due to failure of remyelination. Previously we have shown that the persistent presence of stable astrocyte-derived fibronectin aggregates in MS lesions impairs OPC differentiation, and thereby remyelination. Here we set out to discern whether and, if so, how inflammatory mediators as present in MS lesions trigger astrocytes to form fibronectin aggregates. Our findings revealed that in slice cultures only upon demyelination, the TLR3 agonist Poly(I:C) evoked astrocytes to form fibronectin aggregates. Consistently, pro-inflammatory cytokine-pretreated astrocytes were more susceptible to Poly(I:C)-induced fibronectin aggregation, indicating that astrocytes form fibronectin aggregates upon a double hit by inflammatory mediators. The underlying mechanism involves disrupted fibronectin fibrillogenesis at the cell surface as a result of a cytokine-induced increase in relative mRNA levels of EIIIApos-Fn over EIIIBpos-Fn and a Poly(I:C)-mediated decrease in integrin affinity. Remarkably, fibronectin aggregation is exacerbated by white matter astrocytes compared to grey matter astrocytes, which may be a reflection of higher expression levels of EIIIApos-fibronectin in white matter astrocytes. Hence, interfering with alternative fibronectin splicing and/or TLR3-mediated signaling may prevent fibronectin aggregation and overcome remyelination failure in MS lesions.

Published
2020

11. Scanning EM of non-heavy metal stained biosamples

Author

Ben N G Giepmans, Jeroen Kuipers, Pascal de Boer, Center for Liver, Digestive and Metabolic Diseases (CLDM), and ​Basic and Translational Research and Imaging Methodology Development in Groningen (BRIDGE)

Subjects
Electron density, Scanning electron microscope, Virtual EM, Biology, Scanning transmission EM, Models, Biological, Secondary electrons, ENERGY, Transmission EM, Nanotomy, Humans, Nanotechnology, Immuno-EM, Staining and Labeling, business.industry, Scanning EM, Quantum dots, CORRELATED LIGHT, Resolution (electron density), Contrasting, ORGANELLES, Cell Biology, Immunogold labelling, RESOLUTION, Metals, Transmission electron microscopy, Quantum dot, TISSUE, CELLS, Microscopy, Electron, Scanning, Ultrastructure, Optoelectronics, Gold, business, VOLUME ELECTRON-MICROSCOPY
Abstract

Scanning electron microscopy (SEM) is increasing its application in life sciences for electron density measurements of ultrathin sections. These are traditionally analyzed with transmission electron microscopy (TEM); by most labs, SEM analysis still is associated with surface imaging only. Here we report several advantages of SEM for thin sections over TEM, both for structural inspection, as well as analyzing immuno-targeted labels such as quantum dots (QDs) and gold, where we find that QD-labeling is ten times more efficient than gold-labeling. Furthermore, we find that omitting post-staining with uranyl and lead leads to QDs readily detectable over the ultrastructure, but under these conditions ultrastructural contrast was even almost invisible in TEM examination. Importantly, imaging in SEM with STEM detection leads to both outstanding QDs and ultrastructural contrast. STEM imaging is superior over back-scattered electron imaging of these non-contrasted samples, whereas secondary electron detection cannot be used at all. We conclude that examination of ultrathin sections by SEM, which may be immunolabeled with QDs, will allow rapid and straightforward analysis of large fields with more efficient labeling than can be achieved with immunogold. The large fields of view routinely achieved with SEM, but not with TEM, allows straightforward raw data sharing using virtual microscopy, also known as nanotomy when this concerns EM data in the life sciences. (C) 2015 Elsevier Inc. All rights reserved.

Published
2015

12. Nanoparticle discrimination based on wavelength and lifetime-multiplexed cathodoluminescence microscopy

Author

Felipe Perona Martinez, Mathijs W.H. Garming, Pascal de Boer, I. Gerward C. Weppelman, Robert J. Moerland, Romana Schirhagl, Jacob P. Hoogenboom, Nanotechnology and Biophysics in Medicine (NANOBIOMED), and ​Basic and Translational Research and Imaging Methodology Development in Groningen (BRIDGE)

Subjects
0301 basic medicine, Photoluminescence, Materials science, Scanning electron microscope, Physics::Optics, DIAMOND, Cathodoluminescence, 02 engineering and technology, BEAM EXCITATION, law.invention, 03 medical and health sciences, MOLECULES, Optics, law, Microscopy, Electron beam processing, Physics::Atomic and Molecular Clusters, General Materials Science, SCANNING-ELECTRON-MICROSCOPE, IDENTIFICATION, business.industry, FLUORESCENT NANODIAMONDS, 021001 nanoscience & nanotechnology, NITROGEN-VACANCY CENTERS, Wavelength, 030104 developmental biology, DENSITY, Cathode ray, PHOTOLUMINESCENCE, Electron microscope, 0210 nano-technology, business, HIGH-RESOLUTION
Abstract

Nanomaterials can be identified in high-resolution electron microscopy images using spectrally-selective cathodoluminescence. Capabilities for multiplex detection can however be limited, e.g., due to spectral overlap or availability of filters. Also, the available photon flux may be limited due to degradation under electron irradiation. Here, we demonstrate single-pass cathodoluminescence-lifetime based discrimination of different nanoparticles, using a pulsed electron beam. We also show that cathodoluminescence lifetime is a robust parameter even when the nanoparticle cathodoluminescence intensity decays over an order of magnitude. We create lifetime maps, where the lifetime of the cathodoluminescence emission is correlated with the emission intensity and secondary-electron images. The consistency of lifetime-based discrimination is verified by also correlating the emission wavelength and the lifetime of nanoparticles. Our results show how cathodoluminescence lifetime provides an additional channel of information in electron microscopy.

Published
2017

13. Multi-color electron microscopy by element-guided identification of cells, organelles and molecules

Author

Kees C.W. Hagen, Jeroen Kuipers, Dasha I. Wensveen, Ben N G Giepmans, Marijke Scotuzzi, Jacob P. Hoogenboom, Pascal de Boer, Center for Liver, Digestive and Metabolic Diseases (CLDM), and ​Basic and Translational Research and Imaging Methodology Development in Groningen (BRIDGE)

Subjects
0301 basic medicine, Pathology, medicine.medical_specialty, BIOLOGICAL SCIENCES, Cells, PATHOGENESIS, Color, 02 engineering and technology, QUANTUM DOTS, Biology, Article, law.invention, 03 medical and health sciences, BETA-CELLS, law, Organelle, medicine, Molecule, Animals, Humans, FLUORESCENCE, Organelles, TRANSMISSION ELECTRON, Elemental composition, Multidisciplinary, EXOCRINE PANCREAS, CORRELATED LIGHT, Resolution (electron density), Palette (computing), Spectrometry, X-Ray Emission, DNA, X-RAY-MICROANALYSIS, 021001 nanoscience & nanotechnology, Elements, Microscopy, Electron, 030104 developmental biology, Biophysics, Ultrastructure, Identification (biology), ENERGY-LOSS, Electron microscope, 0210 nano-technology
Abstract

Cellular complexity is unraveled at nanometer resolution using electron microscopy (EM), but interpretation of macromolecular functionality is hampered by the difficulty in interpreting grey-scale images and the unidentified molecular content. We perform large-scale EM on mammalian tissue complemented with energy-dispersive X-ray analysis (EDX) to allow EM-data analysis based on elemental composition. Endogenous elements, labels (gold and cadmium-based nanoparticles) as well as stains are analyzed at ultrastructural resolution. This provides a wide palette of colors to paint the traditional grey-scale EM images for composition-based interpretation. Our proof-of-principle application of EM-EDX reveals that endocrine and exocrine vesicles exist in single cells in Islets of Langerhans. This highlights how elemental mapping reveals unbiased biomedical relevant information. Broad application of EM-EDX will further allow experimental analysis on large-scale tissue using endogenous elements, multiple stains, and multiple markers and thus brings nanometer-scale ‘color-EM’ as a promising tool to unravel molecular (de)regulation in biomedicine.

Published
2017

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