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3. In Vivo Non-Invasive Tracking of Macrophage Recruitment to Experimental Stroke.

Author

Marion Selt, Annette Tennstaedt, Andreas Beyrau, Melanie Nelles, Gabriele Schneider, Clemens Löwik, and Mathias Hoehn

Subjects
Medicine, Science
Abstract

Brain-infiltrating monocyte-derived macrophages are one of the key players in the local immune response after stroke. It is now widely accepted that the inflammatory response is not an exclusively destructive process. However, the underlying molecular mechanisms needed for proper regulation still remain to be elucidated. Here, we propose an in vitro labelling strategy for multimodal in vivo observation of macrophage dynamics distinguished from brain-residing microglia response. Prior to intracerebral transplantation into the striatum of recipient mice or systemic administration, monocytes and macrophages, isolated from luciferase-expressing mice, were labelled with superparamagnetic iron oxide particles. Temporo-spatial localization was monitored by magnetic resonance imaging, whereas survival of grafted cells was investigated using bioluminescence imaging. The labelling procedure of the isolated cells did not significantly influence cell characteristics and resulted in detection of as few as 500 labelled cells in vivo. Two weeks after stereotactic transplantation, the luciferase signal was sustained traceable, with approximately 18% of the original luciferase signal detectable for monocytes and about 30% for macrophages. Hypointensity in MRI of the graft appeared unaltered in spatial location. In a therapeutically relevant approach, systemic cell administration after stroke resulted in accumulation mostly in thoracic regions, as could be visualized with BLI. For detection of homing to ischemic brain tissue more cells need to be administered. Nevertheless, during parallel MRI sessions recruitment of i.v. injected cells to the lesion site could be detected by day 2 post stroke as scattered hypointense signal voids. With further increase in sensitivity, our multi-facetted labelling strategy will provide the basis for in vivo tracking and fate specification of tissue-infiltrating macrophages and their distinct role in stroke-related neuro-inflammation.

Published
2016
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4. In Vivo Fate Imaging of Intracerebral Stem Cell Grafts in Mouse Brain.

Author

Annette Tennstaedt, Alfonso Mastropietro, Melanie Nelles, Andreas Beyrau, and Mathias Hoehn

Subjects
Medicine, Science
Abstract

We generated transgenic human neural stem cells (hNSCs) stably expressing the reporter genes Luciferase for bioluminescence imaging (BLI) and GFP for fluorescence imaging, for multimodal imaging investigations. These transgenic hNSCs were further labeled with a clinically approved perfluoropolyether to perform parallel 19F MRI studies. In vitro validation demonstrated normal cell proliferation and differentiation of the transgenic and additionally labeled hNSCs, closely the same as the wild type cell line, making them suitable for in vivo application. Labeled and unlabeled transgenic hNSCs were implanted into the striatum of mouse brain. The time profile of their cell fate after intracerebral grafting was monitored during nine days following implantation with our multimodal imaging approach, assessing both functional and anatomical condition. The 19F MRI demarcated the graft location and permitted to estimate the cell number in the graft. BLI showed a pronounce cell loss during this monitoring period, indicated by the decrease of the viability signal. The in vivo obtained cell fate results were further validated and confirmed by immunohistochemistry. We could show that the surviving cells of the graft continued to differentiate into early neurons, while the severe cell loss could be explained by an inflammatory reaction to the graft, showing the graft being surrounded by activated microglia and macrophages. These results are different from earlier cell survival studies of our group where we had implanted the identical cells into the same mouse strain but in the cortex and not in the striatum. The cortical transplanted cells did not show any loss in viability but only pronounced and continuous neuronal differentiation.

Published
2015
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8. Transcranial direct current stimulation promotes the mobility of engrafted NSCs in the rat brain

Author

Anton Pikhovych, Michael Schroeter, Markus Aswendt, Annette Tennstaedt, Gereon R. Fink, Mathias Hoehn, Dirk Wiedermann, Steffen Rotthues, Meike Hedwig Keuters, and Maria Adele Rueger

Subjects
Microglia, Transcranial direct-current stimulation, business.industry, medicine.medical_treatment, Endogeny, Corpus callosum, Neural stem cell, Cortex (botany), medicine.anatomical_structure, nervous system, medicine, Molecular Medicine, Radiology, Nuclear Medicine and imaging, business, Neuroscience, Spectroscopy, Neuroinflammation, Ex vivo
Abstract

Transcranial direct current stimulation (tDCS) is used in numerous clinical studies and considered an effective and versatile add-on therapy in neurorehabilitation. To date, however, the underlying neurobiological mechanisms remain elusive. In a rat model of tDCS, we recently observed a polarity-dependent accumulation of endogenous neural stem cells (NSCs) in the stimulated cortex. Based upon these findings, we hypothesized that tDCS may exert a direct migratory effect on endogenous NSCs towards the stimulated cortex. Using noninvasive imaging, we here investigated whether tDCS may also cause a directed migration of engrafted NSCs. Murine NSCs were labeled with superparamagnetic particles of iron oxide (SPIOs) and implanted into rat striatum and corpus callosum. MRI was performed (i) immediately after implantation and (ii) after 10 tDCS sessions of anodal or cathodal polarity. Sham-stimulated rats served as control. Imaging results were validated ex vivo using immunohistochemistry. Overall migratory activity of NSCs almost doubled after anodal tDCS. However, no directed migration within the electric field (i.e. towards or away from the electrode) could be observed. Rather, an undirected outward migration from the center of the graft was detected. Xenograft transplantation induced a neuroinflammatory response that was significantly enhanced following cathodal tDCS. This inflammatory response did not impact negatively on the survival of implanted NSCs. Data suggest that anodal tDCS increases the undirected migratory activity of implanted NSCs. Since the electric field did not guide implanted NSCs over large distances, previously observed polarity-dependent accumulation of endogenous NSCs in the cortex might have originated from local proliferation. Results enhance our understanding of the neurobiological mechanisms underlying tDCS, and may thereby help to develop a targeted and sustainable application of tDCS in clinical practice. Copyright © 2014 John Wiley & Sons, Ltd.

Published
2014
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9. HtrA1-dependent proteolysis of TGF-β controls both neuronal maturation and developmental survival

Author

Séverine Launay, Denis Vivien, Cecilia Gabriel, Michael Ehrmann, Alfonso Baldi, Marie-Claude Potier, Mara Campioni, Luce Dauphinot, Eric Maubert, Fabian Docagne, Nathalie Lebeurrier, Annette Tennstaedt, Launay, S, Maubert, E, Lebeurrier, N, Tennstaedt, A, Campioni, M, Docagne, F, Gabriel, C, Ehrmann, M, Baldi, Alfonso, and Vivien, D.

Subjects
Cell Survival, Excitotoxicity, Synaptogenesis, Mice, Transgenic, Biology, Serpin, medicine.disease_cause, Transforming Growth Factor beta1, Mice, medicine, Animals, Molecular Biology, Cells, Cultured, Neurons, Serine Endopeptidases, Wild type, Brain, Serine Protease HTRA1, High-Temperature Requirement A Serine Peptidase 1, Cell Biology, Molecular biology, Up-Regulation, Cell biology, Signal transduction, Biologie, Plasminogen activator, Signal Transduction, Transforming growth factor
Abstract

Transforming growth factor-beta (TGF-beta) signalling controls a number of cerebral functions and dysfunctions including synaptogenesis, amyloid-beta accumulation, apoptosis and excitotoxicity. Using cultured cortical neurons prepared from either wild type or transgenic mice overexpressing a TGF-beta-responsive luciferase reporter gene (SBE-Luc), we demonstrated a progressive loss of TGF-beta signalling during neuronal maturation and survival. Moreover, we showed that neurons exhibit increasing amounts of the serine protease HtrA1 (high temperature responsive antigen 1) and corresponding cleavage products during both in vitro neuronal maturation and brain development. In parallel of its ability to promote degradation of TGF-beta1, we demonstrated that blockage of the proteolytic activity of HtrA1 leads to a restoration of TGF-beta signalling, subsequent overexpression of the serpin type -1 plasminogen activator inhibitor (PAI-1) and neuronal death. Altogether, we propose that the balance between HtrA1 and TGF-beta could be one of the critical events controlling both neuronal maturation and developmental survival.

Published
2008
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10. Dynamic Modulation of Microglia/Macrophage Polarization by miR-124 after Focal Cerebral Ischemia

Author

Claudia Green, Somayyeh Hamzei Taj, Markus Aswendt, Widuri Kho, Joanna Adamczak, Mathias Hoehn, Annette Tennstaedt, and Franziska M. Collmann

Subjects
0301 basic medicine, Male, Microglia/macrophage polarization, Immunology, Ischemia, Neuroscience (miscellaneous), Brain Ischemia, 03 medical and health sciences, 0302 clinical medicine, Immune system, miRNA-124, Neuroinflammation, microRNA, medicine, Immunology and Allergy, Animals, Stroke, Balance (ability), Injections, Intraventricular, Pharmacology, Microglia, business.industry, Macrophages, Cell Polarity, medicine.disease, Phenotype, Mice, Inbred C57BL, MicroRNAs, Pro-inflammatory and anti-inflammatory phenotypes, 030104 developmental biology, medicine.anatomical_structure, Original Article, business, 030217 neurology & neurosurgery
Abstract

Mononuclear phagocytes respond to ischemic stroke dynamically, undergoing an early anti-inflammatory and protective phenotype followed by the pro-inflammatory and detrimental type. These dual roles of microglia/macrophages suggest the need of subtle adjustment of their polarization state instead of broad suppression. The most abundant brain-specific miRNA, miR-124, promotes neuronal differentiation but can also modulate microglia activation and keeps them in a quiescent state. We addressed whether the intracerebral injection of miR-124 in a mouse model of ischemic stroke before or after the peak phase of the pro-inflammatory polarization modifies the pro−/anti- inflammatory balance. In the sub-acute phase, 48 h after stroke, liposomated miR-124 shifted the predominantly pro-inflammatory polarized microglia/macrophages toward the anti-inflammatory phenotype. The altered immune response improved neurological deficit at day 6 after stroke. When miR-124 was injected 10 days after stroke, the pro−/anti- inflammatory ratio was still significantly reduced although to a lower degree and had no effect on recovery at day 14. This study indicates that miR-124 administration before the peak of the pro-inflammatory process of stroke is most effective in support of increasing the rehabilitation opportunity in the sub-acute phases of stroke. Our findings highlight the important role of immune cells after stroke and the therapeutic relevance of their polarization balance. Electronic supplementary material The online version of this article (doi:10.1007/s11481-016-9700-y) contains supplementary material, which is available to authorized users.

Published
2016

11. In Vivo Fate Imaging of Intracerebral Stem Cell Grafts in Mouse Brain

Author

Melanie Nelles, Annette Tennstaedt, Andreas Beyrau, Alfonso Mastropietro, and Mathias Hoehn

Subjects
Male, Pathology, medicine.medical_specialty, Fluorine Radioisotopes, Science, Cellular differentiation, Green Fluorescent Proteins, Transplantation, Heterologous, Mice, Nude, Biology, Cell fate determination, Multimodal Imaging, Cell Line, Neural Stem Cells, In vivo, Luciferases, Firefly, medicine, Bioluminescence imaging, Animals, Humans, Transgenes, Cell Proliferation, Cerebral Cortex, Multidisciplinary, Cell growth, Cell Differentiation, Magnetic Resonance Imaging, Neural stem cell, Luminescent Measurements, Medicine, Stem cell, Preclinical imaging, Research Article
Abstract

We generated transgenic human neural stem cells (hNSCs) stably expressing the reporter genes Luciferase for bioluminescence imaging (BLI) and GFP for fluorescence imaging, for multimodal imaging investigations. These transgenic hNSCs were further labeled with a clinically approved perfluoropolyether to perform parallel 19F MRI studies. In vitro validation demonstrated normal cell proliferation and differentiation of the transgenic and additionally labeled hNSCs, closely the same as the wild type cell line, making them suitable for in vivo application. Labeled and unlabeled transgenic hNSCs were implanted into the striatum of mouse brain. The time profile of their cell fate after intracerebral grafting was monitored during nine days following implantation with our multimodal imaging approach, assessing both functional and anatomical condition. The 19F MRI demarcated the graft location and permitted to estimate the cell number in the graft. BLI showed a pronounce cell loss during this monitoring period, indicated by the decrease of the viability signal. The in vivo obtained cell fate results were further validated and confirmed by immunohistochemistry. We could show that the surviving cells of the graft continued to differentiate into early neurons, while the severe cell loss could be explained by an inflammatory reaction to the graft, showing the graft being surrounded by activated microglia and macrophages. These results are different from earlier cell survival studies of our group where we had implanted the identical cells into the same mouse strain but in the cortex and not in the striatum. The cortical transplanted cells did not show any loss in viability but only pronounced and continuous neuronal differentiation.

Published
2015

12. Proof of concept of an automatic tool for bioluminescence imaging data analysis

Author

Giuseppe Baselli, Nadine Henn, Mathias Hoehn, Andreas Beyrau, Alfonso Mastropietro, and Annette Tennstaedt

Subjects
Normal Distribution, Biomedical Engineering, Mice, Nude, Neuroimaging, Health Informatics, Biology, Signal-To-Noise Ratio, Preclinical research, Neural Stem Cells, Image Processing, Computer-Assisted, Bioluminescence imaging, Animals, Humans, Segmentation, Computer vision, Signal Processing, business.industry, Brain, Mixture model, Proof of concept, Cell Tracking, Luminescent Measurements, Artificial intelligence, Molecular imaging, Signal intensity, business, Algorithms
Abstract

Bioluminescence Imaging (BLI) is an important molecular imaging tool to assess complex biological processes in vivo. BLI is a sensitive technique, which is frequently used in small-animal preclinical research, mainly in oncology and neurology. Tracking of labeled cells is one of the major applications. However, BLI data analysis for the segmentation of up-taking regions and their quantification is not trivial and it is usually an operator-dependent activity. In this work, a proof of concept of an automatic method to analyze BL images is presented which is based on a multi-step approach. Different segmentation algorithms (K-means, Gaussian Mixture Model (GMM), and GMM initialized by K-means) were evaluated and an adequate image normalization step was suggested to include the background bioluminescence in the data analysis process. K-means segmentation is the most stable and accurate approach for different levels of signal intensity.

Published
2015

13. Human neural stem cell intracerebral grafts show spontaneous early neuronal differentiation after several weeks

Author

Marie Lagouge, Gabriele Schneider, Joanna Adamczak, Markus Aswendt, Peter Kloppenburg, Dirk Wiedermann, Marion Selt, Cordula Schaefer, Nadine Henn, Ursel Collienne, Mathias Hoehn, and Annette Tennstaedt

Subjects
Male, Pathology, medicine.medical_specialty, Fluorescence-lifetime imaging microscopy, Time Factors, Human neural stem cells, Green Fluorescent Proteins, Biophysics, Synaptogenesis, Bioengineering, Biology, In vivo bioluminescence imaging, Biomaterials, Mice, Imaging, Three-Dimensional, Neural Stem Cells, Fate mapping, Computer Systems, Genes, Reporter, medicine, Bioluminescence imaging, Animals, Humans, Cell Lineage, Synapsin I promoter, Promoter Regions, Genetic, Neurons, Brain, Cell Differentiation, Doublecortin promoter, Neural stem cell, Cell biology, Electrophysiological Phenomena, Transplantation, Neuronal differentiation, Mechanics of Materials, Cell culture, Ceramics and Composites, Stem cell, Stem Cell Transplantation
Abstract

Human neural stem cells (hNSCs) hold great promise for the treatment of neurological diseases. Considerable progress has been made to induce neural differentiation in the cell culture in vitro and upon transplantation in vivo [2] in order to explore restoration of damaged neuronal circuits. However, in vivo conventional strategies are limited to post mortem analysis. Here, we apply our developed first fate mapping platform to monitor neuronal differentiation in vivo by magnetic resonance imaging, bioluminescence imaging, and fluorescence imaging. Ferritin, Luciferase and GFP under neuronal-specific promoters for immature and mature neurons, respectively, were used to generate transgenic hNSCs. Differentiation-linked imaging reporter expression was validated in vitro. The time profile of spontaneous neuronal maturation after transplantation into mouse brain cortex demonstrated early neuronal differentiation within 6 weeks. Fully mature neurons expressing synaptogenesis were observed only after three months or longer. Our trimodal fate mapping strategy represents a unique non-invasive tool to monitor the time course of neuronal differentiation of transplanted stem cells in vivo.

Published
2014

14. Human high temperature requirement serine protease A1 (HTRA1) degrades tau protein aggregates

Author

Michael Ehrmann, Tim Clausen, Patrick Hauske, Nina Schmidt, Rupert Egensperger, Robert Huber, Leif Dehmelt, Simon Pöpsel, Alfonso Baldi, Annette Tennstaedt, Linda Truebestein, Hanna Ksiezak-Reding, Roland Brandt, Anca Tirniceriu, Markus Kaiser, Anke Brockmann, Barbara Saccà, Inga Irle, Christof M. Niemeyer, Tennstaedt, A, Poepsel, S, Truebestein, L, Hauske, P, Brockmann, A, Schmidt, N, Irle, I, Sacca, B, Niemeyer, Cm, Brandt, R, Ksiezak Reding, H, Tirniceriu, Al, Egensperger, R, Baldi, Alfonso, Dehmelt, L, Kaiser, M, Huber, R, Clausen, T, and Ehrmann, M.

Subjects
Protein Folding, Proteases, medicine.medical_treatment, Proteolysis, Tau protein, Nerve Tissue Proteins, tau Proteins, Protein aggregation, Protein degradation, Biochemistry, Gene Expression Regulation, Enzymologic, Neurites, medicine, Humans, Molecular Biology, Serine protease, Protease, biology, medicine.diagnostic_test, Serine Endopeptidases, Brain, High-Temperature Requirement A Serine Peptidase 1, Cell Biology, eye diseases, Cell biology, Tauopathies, Protein Synthesis and Degradation, biology.protein, Protein folding, Biologie
Abstract

Protective proteases are key elements of protein quality control pathways that are up-regulated, for example, under various protein folding stresses. These proteases are employed to prevent the accumulation and aggregation of misfolded proteins that can impose severe damage to cells. The high temperature requirement A (HtrA) family of serine proteases has evolved to perform important aspects of ATP-independent protein quality control. So far, however, no HtrA protease is known that degrades protein aggregates. We show here that human HTRA1 degrades aggregated and fibrillar tau, a protein that is critically involved in various neurological disorders. Neuronal cells and patient brains accumulate less tau, neurofibrillary tangles, and neuritic plaques, respectively, when HTRA1 is expressed at elevated levels. Furthermore, HTRA1 mRNA and HTRA1 activity are up-regulated in response to elevated tau concentrations. These data suggest that HTRA1 is performing regulated proteolysis during protein quality control, the implications of which are discussed. © 2012 by The American Society for Biochemistry and Molecular Biology, Inc.

Published
2012

15. Substrate-induced remodeling of the active site regulates human HTRA1 activity

Author

Tim Clausen, Timon Mönig, Markus Kaiser, Annette Tennstaedt, Michael Ehrmann, Linda Truebestein, Flavia Canellas, and T. Krojer

Subjects
Models, Molecular, Protein Folding, Proteases, PDZ domain, PDZ Domains, Plasma protein binding, Crystallography, X-Ray, Serine, Structural Biology, Catalytic Domain, Humans, Molecular Biology, biology, Hydrolysis, Serine Endopeptidases, Active site, Serine Protease HTRA1, High-Temperature Requirement A Serine Peptidase 1, eye diseases, Biochemistry, HTRA1, biology.protein, Biophysics, Protein folding, Biologie, Protein Binding
Abstract

Crystal structures of active and inactive conformations of the human serine protease HTRA1 reveal that substrate binding to the active site is sufficient to stimulate proteolytic activity. HTRA1 attaches to liposomes, digests misfolded proteins into defined fragments and undergoes substrate-mediated oligomer conversion. In contrast to those of other serine proteases, the PDZ domain of HTRA1 is dispensable for activation or lipid attachment, indicative of different underlying mechanistic features.

Published
2011
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16. A review of novel optical imaging strategies of the stroke pathology and stem cell therapy in stroke

Author

Aswendt, Markus, Adamczak, Joanna, and Tennstaedt, Annette

Subjects
fluorescence imaging, non-invasive, optical neuroimaging, Review Article, bioluminescence imaging, lcsh:Neurosciences. Biological psychiatry. Neuropsychiatry, stem cell therapy, stroke, lcsh:RC321-571, Neuroscience
Abstract

Transplanted stem cells can induce and enhance functional recovery in experimental stroke. Invasive analysis has been extensively used to provide detailed cellular and molecular characterization of the stroke pathology and engrafted stem cells. But post mortem analysis is not appropriate to reveal the time scale of the dynamic interplay between the cell graft, the ischemic lesion and the endogenous repair mechanisms. This review describes non-invasive imaging techniques which have been developed to provide complementary in vivo information. Recent advances were made in analyzing simultaneously different aspects of the cell graft (e.g. number of cells, viability state and cell fate), the ischemic lesion (e.g. blood brain barrier consistency, hypoxic and necrotic areas) and the neuronal and vascular network. We focus on optical methods, which permit simple animal preparation, repetitive experimental conditions, relatively medium-cost instrumentation and are performed under mild anesthesia, thus nearly under physiological conditions. A selection of recent examples of optical intrinsic imaging, fluorescence imaging (FLI) and bioluminescence imaging (BLI) to characterize the stroke pathology and engrafted stem cells are discussed. Special attention is paid to novel optimal reporter genes/probes for genetic labeling and tracking of stem cells and appropriate transgenic animal models. Requirements, advantages and limitations of these imaging platforms are critically discussed and placed into the context of other non-invasive techniques, e.g. magnetic resonance imaging (MRI) and positron emission tomography (PET), which can be joined with optical imaging in multimodal approaches.

Published
2014
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17. Transcranial direct current stimulation promotes the mobility of engrafted NSCs in the rat brain

Author

Meike Hedwig, Keuters, Markus, Aswendt, Annette, Tennstaedt, Dirk, Wiedermann, Anton, Pikhovych, Steffen, Rotthues, Gereon Rudolf, Fink, Michael, Schroeter, Mathias, Hoehn, and Maria Adele, Rueger

Subjects
Male, Cell Survival, Iron, Macrophages, Immunity, Brain, Transcranial Direct Current Stimulation, Immunohistochemistry, Magnetic Resonance Imaging, Cell Line, Mice, Neural Stem Cells, Phagocytosis, Cell Movement, Astrocytes, Animals, Microglia, Rats, Wistar, Electrodes
Abstract

Transcranial direct current stimulation (tDCS) is used in numerous clinical studies and considered an effective and versatile add-on therapy in neurorehabilitation. To date, however, the underlying neurobiological mechanisms remain elusive. In a rat model of tDCS, we recently observed a polarity-dependent accumulation of endogenous neural stem cells (NSCs) in the stimulated cortex. Based upon these findings, we hypothesized that tDCS may exert a direct migratory effect on endogenous NSCs towards the stimulated cortex. Using noninvasive imaging, we here investigated whether tDCS may also cause a directed migration of engrafted NSCs. Murine NSCs were labeled with superparamagnetic particles of iron oxide (SPIOs) and implanted into rat striatum and corpus callosum. MRI was performed (i) immediately after implantation and (ii) after 10 tDCS sessions of anodal or cathodal polarity. Sham-stimulated rats served as control. Imaging results were validated ex vivo using immunohistochemistry. Overall migratory activity of NSCs almost doubled after anodal tDCS. However, no directed migration within the electric field (i.e. towards or away from the electrode) could be observed. Rather, an undirected outward migration from the center of the graft was detected. Xenograft transplantation induced a neuroinflammatory response that was significantly enhanced following cathodal tDCS. This inflammatory response did not impact negatively on the survival of implanted NSCs. Data suggest that anodal tDCS increases the undirected migratory activity of implanted NSCs. Since the electric field did not guide implanted NSCs over large distances, previously observed polarity-dependent accumulation of endogenous NSCs in the cortex might have originated from local proliferation. Results enhance our understanding of the neurobiological mechanisms underlying tDCS, and may thereby help to develop a targeted and sustainable application of tDCS in clinical practice.

Published
2013

19. Human neural stem cell intracerebral grafts show spontaneous early neuronal differentiation after several weeks

Author

Tennstaedt, Annette, Aswendt, Markus, Adamczak, Joanna, Collienne, Ursel, Selt, Marion, Schneider, Gabriele, Henn, Nadine, Schaefer, Cordula, Lagouge, Marie, Wiedermann, Dirk, Kloppenburg, Peter, Hoehn, Mathias, Tennstaedt, Annette, Aswendt, Markus, Adamczak, Joanna, Collienne, Ursel, Selt, Marion, Schneider, Gabriele, Henn, Nadine, Schaefer, Cordula, Lagouge, Marie, Wiedermann, Dirk, Kloppenburg, Peter, and Hoehn, Mathias

Abstract

Human neural stem cells (hNSCs) hold great promise for the treatment of neurological diseases. Considerable progress has been made to induce neural differentiation in the cell culture in vitro and upon transplantation in vivo [2] in order to explore restoration of damaged neuronal circuits. However, in vivo conventional strategies are limited to post mortem analysis. Here, we apply our developed first fate mapping platform to monitor neuronal differentiation in vivo by magnetic resonance imaging, bioluminescence imaging, and fluorescence imaging. Ferritin, Luciferase and GFP under neuronal-specific promoters for immature and mature neurons, respectively, were used to generate transgenic hNSCs. Differentiation-linked imaging reporter expression was validated in vitro. The time profile of spontaneous neuronal maturation after transplantation into mouse brain cortex demonstrated early neuronal differentiation within 6 weeks. Fully mature neurons expressing synaptogenesis were observed only after three months or longer. Our trimodal fate mapping strategy represents a unique non-invasive tool to monitor the time course of neuronal differentiation of transplanted stem cells in vivo. (C) 2014 The Authors. Published by Elsevier Ltd.

Published
2015

20. Transcranial direct current stimulation promotes the mobility of engrafted NSCs in the rat brain

Author

Keuters, Meike Hedwig, Aswendt, Markus, Tennstaedt, Annette, Wiedermann, Dirk, Pikhovych, Anton, Rotthues, Steffen, Fink, Gereon Rudolf, Schroeter, Michael, Hoehn, Mathias, Rueger, Maria Adele, Keuters, Meike Hedwig, Aswendt, Markus, Tennstaedt, Annette, Wiedermann, Dirk, Pikhovych, Anton, Rotthues, Steffen, Fink, Gereon Rudolf, Schroeter, Michael, Hoehn, Mathias, and Rueger, Maria Adele

Abstract

Transcranial direct current stimulation (tDCS) is used in numerous clinical studies and considered an effective and versatile add-on therapy in neurorehabilitation. To date, however, the underlying neurobiological mechanisms remain elusive. In a rat model of tDCS, we recently observed a polarity-dependent accumulation of endogenous neural stem cells (NSCs) in the stimulated cortex. Based upon these findings, we hypothesized that tDCS may exert a direct migratory effect on endogenous NSCs towards the stimulated cortex. Using noninvasive imaging, we here investigated whether tDCS may also cause a directed migration of engrafted NSCs. Murine NSCs were labeled with superparamagnetic particles of iron oxide (SPIOs) and implanted into rat striatum and corpus callosum. MRI was performed (i) immediately after implantation and (ii) after 10 tDCS sessions of anodal or cathodal polarity. Sham-stimulated rats served as control. Imaging results were validated ex vivo using immunohistochemistry. Overall migratory activity of NSCs almost doubled after anodal tDCS. However, no directed migration within the electric field (i.e. towards or away from the electrode) could be observed. Rather, an undirected outward migration from the center of the graft was detected. Xenograft transplantation induced a neuroinflammatory response that was significantly enhanced following cathodal tDCS. This inflammatory response did not impact negatively on the survival of implanted NSCs. Data suggest that anodal tDCS increases the undirected migratory activity of implanted NSCs. Since the electric field did not guide implanted NSCs over large distances, previously observed polarity-dependent accumulation of endogenous NSCs in the cortex might have originated from local proliferation. Results enhance our understanding of the neurobiological mechanisms underlying tDCS, and may thereby help to develop a targeted and sustainable application of tDCS in clinical practice. Copyright (c) 2014 John Wiley & Sons

Published
2015

23. Noninvasive multimodal imaging of stem cell transplants in the brain using bioluminescence imaging and magnetic resonance imaging

Author

Annette, Tennstaedt, Markus, Aswendt, Joanna, Adamczak, and Mathias, Hoehn

Subjects
Diagnostic Imaging, Brain Diseases, Mice, Neural Stem Cells, Luminescent Measurements, Cell- and Tissue-Based Therapy, Animals, Brain, Magnetic Resonance Imaging, Multimodal Imaging, Stem Cell Transplantation
Abstract

Transplantation of stem cells represents a promising approach for the therapy of different brain diseases, including stroke, Parkinson's, and Huntington's disease. Tracking of stem cells with noninvasive imaging technologies provides insight into location, migration, and proliferation of the cells-key features for a possible clinical translation. This chapter describes a multimodal and noninvasive approach employing magnetic resonance imaging (MRI) and bioluminescence imaging (BLI), both of which offer the opportunity for repetitive measurements on the same individual, revealing the full temporal profile of cell dynamics. The combination of these modalities allows the simultaneous investigation of different aspects of the graft fate. We will present the detailed protocol for noninvasive multimodal tracking of labeled and transplanted neural stem cells, specifically optimized for brain applications, which allows repetitive assessment of localization as well as identification of cell viability and cell quantity after transplantation.

Published
2013

24. Evaluating reporter genes of different luciferases for optimized in vivo bioluminescence imaging of transplanted neural stem cells in the brain

Author

Laura, Mezzanotte, Markus, Aswendt, Annette, Tennstaedt, Rob, Hoeben, Mathias, Hoehn, and Clemens, Löwik

Subjects
Mice, HEK293 Cells, Neural Stem Cells, Cell Tracking, Genes, Reporter, Luminescent Measurements, Animals, Brain, Humans, Neuroimaging, Allografts, Luciferases, Stem Cell Transplantation
Abstract

Bioluminescence imaging (BLI) has become the method of choice for optical tracking of cells in small laboratory animals. However, the use of luciferases from different species, depending on different substrates and emitting at distinct wavelengths, has not been optimized for sensitive neuroimaging. In order to identify the most suitable luciferase, this quantitative study compared the luciferases Luc2, CBG99, PpyRE9 and hRluc. Human embryonic kidney (HEK-293) cells and mouse neural stem cells were transduced by lentiviral vector-mediated transfer to express one of the four luciferases, together with copGFP. A T2A peptide linker promoted stoichiometric expression between both imaging reporters and the comparison of cell populations upon flow cytometry. Cell dilution series were used to determine highest BLI sensitivity in vitro for Luc2. However, Coelenterazine h-dependent hRluc signals clearly exceeded d-luciferin-dependent BLI in vitro. For the quantitative in vivo analysis, cells were transplanted into mouse brain and BLI was performed including the recording of emission kinetics and spectral characteristics. Differences in light kinetics were observed for d-luciferin vs Coelenterazine h. The emission spectra of Luc2 and PpyRE9 remained almost unchanged, while the emission spectrum of CBG99 became biphasic. Most importantly, photon emission decreased in the order of Luc2, CBG99, PpyRE9 to hRluc. The feasibility of combining different luciferases for dual color and dual substrate neuroimaging was tested and discussed. This investigation provides the first complete quantitative comparison of different luciferases expressed by neural stem cells. It results in a clear recommendation of Luc2 as the best luciferase selection for in vivo neuroimaging.

Published
2013

25. Noninvasive Multimodal Imaging of Stem Cell Transplants in the Brain Using Bioluminescence Imaging and Magnetic Resonance Imaging

Author

Joanna Adamczak, Annette Tennstaedt, Mathias Hoehn, and Markus Aswendt

Subjects
Multimodal imaging, Transplantation, medicine.diagnostic_test, business.industry, medicine, Medical imaging, Bioluminescence imaging, Magnetic resonance imaging, Stem cell, business, Neuroscience, Neural stem cell, Preclinical imaging
Abstract

Transplantation of stem cells represents a promising approach for the therapy of different brain diseases, including stroke, Parkinson's, and Huntington's disease. Tracking of stem cells with noninvasive imaging technologies provides insight into location, migration, and proliferation of the cells-key features for a possible clinical translation. This chapter describes a multimodal and noninvasive approach employing magnetic resonance imaging (MRI) and bioluminescence imaging (BLI), both of which offer the opportunity for repetitive measurements on the same individual, revealing the full temporal profile of cell dynamics. The combination of these modalities allows the simultaneous investigation of different aspects of the graft fate. We will present the detailed protocol for noninvasive multimodal tracking of labeled and transplanted neural stem cells, specifically optimized for brain applications, which allows repetitive assessment of localization as well as identification of cell viability and cell quantity after transplantation.

Published
2013
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26. In Vivo Non-Invasive Tracking of Macrophage Recruitment to Experimental Stroke

Author

Andreas Beyrau, Mathias Hoehn, Clemens W.G.M. Löwik, Annette Tennstaedt, Gabriele Schneider, Melanie Nelles, and Marion Selt

Subjects
Male, 0301 basic medicine, Pathology, Cellular differentiation, Contrast Media, lcsh:Medicine, Optical Analysis, Vascular Medicine, Monocytes, Diagnostic Radiology, White Blood Cells, Mice, 0302 clinical medicine, Animal Cells, Medicine and Health Sciences, lcsh:Science, Staining, Multidisciplinary, Microglia, Radiology and Imaging, Physics, Cell Staining, Brain, Cell Differentiation, Magnetic Resonance Imaging, Stroke, medicine.anatomical_structure, Neurology, Cell Tracking, Physical Sciences, Systemic administration, Female, Cellular Types, Elementary Particles, Research Article, medicine.medical_specialty, Imaging Techniques, Cell Survival, Immune Cells, Cerebrovascular Diseases, Iron, Immunology, Mice, Transgenic, Biology, Research and Analysis Methods, Sensitivity and Specificity, 03 medical and health sciences, Immune system, Diagnostic Medicine, In vivo, medicine, Animals, Bioluminescence imaging, Particle Physics, Chemical Characterization, Ischemic Stroke, Photons, Blood Cells, Staining and Labeling, Bioluminescence Imaging, Macrophages, lcsh:R, Biology and Life Sciences, Cell Biology, Transplantation, Disease Models, Animal, 030104 developmental biology, Specimen Preparation and Treatment, Luminescent Measurements, lcsh:Q, 030217 neurology & neurosurgery, Developmental Biology, Homing (hematopoietic)
Abstract

Brain-infiltrating monocyte-derived macrophages are one of the key players in the local immune response after stroke. It is now widely accepted that the inflammatory response is not an exclusively destructive process. However, the underlying molecular mechanisms needed for proper regulation still remain to be elucidated. Here, we propose an in vitro labelling strategy for multimodal in vivo observation of macrophage dynamics distinguished from brain-residing microglia response. Prior to intracerebral transplantation into the striatum of recipient mice or systemic administration, monocytes and macrophages, isolated from luciferase-expressing mice, were labelled with superparamagnetic iron oxide particles. Temporo-spatial localization was monitored by magnetic resonance imaging, whereas survival of grafted cells was investigated using bioluminescence imaging. The labelling procedure of the isolated cells did not significantly influence cell characteristics and resulted in detection of as few as 500 labelled cells in vivo. Two weeks after stereotactic transplantation, the luciferase signal was sustained traceable, with approximately 18% of the original luciferase signal detectable for monocytes and about 30% for macrophages. Hypointensity in MRI of the graft appeared unaltered in spatial location. In a therapeutically relevant approach, systemic cell administration after stroke resulted in accumulation mostly in thoracic regions, as could be visualized with BLI. For detection of homing to ischemic brain tissue more cells need to be administered. Nevertheless, during parallel MRI sessions recruitment of i.v. injected cells to the lesion site could be detected by day 2 post stroke as scattered hypointense signal voids. With further increase in sensitivity, our multi-facetted labelling strategy will provide the basis for in vivo tracking and fate specification of tissue-infiltrating macrophages and their distinct role in stroke-related neuro-inflammation.

Published
2016
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27. Lysine-specific molecular tweezers are broad-spectrum inhibitors of assembly and toxicity of amyloid proteins

Author

Annette Tennstaedt, Chunyu Wang, George B. Benedek, Joseph A. Loo, Dahabada H. J. Lopes, Reena Bakshi, Peter Talbiersky, Gal Bitan, Eric Pang, Aleksey Lomakin, Akila Shanmugam, Thomas Schrader, Pei-Yi Kuo, Zhenming Du, Frank-Gerrit Klärner, Kirsten McDaniel, Michael Ehrmann, and Sharmistha Sinha

Subjects
Bridged-Ring Compounds, Amyloid, Lysine, Plasma protein binding, Fibril, Biochemistry, PC12 Cells, Catalysis, Protein Structure, Secondary, Article, Colloid and Surface Chemistry, Protein structure, Animals, Binding site, Amyloid beta-Peptides, Binding Sites, Chemistry, Proteins, General Chemistry, Amyloidosis, Organophosphates, Rats, Folding (chemistry), Biologie, Molecular tweezers, Protein Binding
Abstract

Amyloidoses are diseases characterized by abnormal protein folding and self-assembly, for which no cure is available. Inhibition or modulation of abnormal protein self-assembly, therefore, is an attractive strategy for prevention and treatment of amyloidoses. We examined Lys-specific molecular tweezers and discovered a lead compound termed CLR01, which is capable of inhibiting the aggregation and toxicity of multiple amyloidogenic proteins by binding to Lys residues and disrupting hydrophobic and electrostatic interactions important for nucleation, oligomerization, and fibril elongation. Importantly, CLR01 shows no toxicity at concentrations substantially higher than those needed for inhibition. We used amyloid β-protein (Aβ) to further explore the binding site(s) of CLR01 and the impact of its binding on the assembly process. Mass spectrometry and solution-state NMR demonstrated binding of CLR01 to the Lys residues in Aβ at the earliest stages of assembly. The resulting complexes were indistinguishable in size and morphology from Aβ oligomers but were nontoxic and were not recognized by the oligomer-specific antibody A11. Thus, CLR01 binds already at the monomer stage and modulates the assembly reaction into formation of nontoxic structures. The data suggest that molecular tweezers are unique, process-specific inhibitors of aberrant protein aggregation and toxicity, which hold promise for developing disease-modifying therapy for amyloidoses.

Published
2011

29. Human neural stem cell intracerebral grafts show spontaneous early neuronal differentiation after several weeks

Author

Tennstaedt, Annette, primary, Aswendt, Markus, additional, Adamczak, Joanna, additional, Collienne, Ursel, additional, Selt, Marion, additional, Schneider, Gabriele, additional, Henn, Nadine, additional, Schaefer, Cordula, additional, Lagouge, Marie, additional, Wiedermann, Dirk, additional, Kloppenburg, Peter, additional, and Hoehn, Mathias, additional

Published
2015
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32. Human High Temperature Requirement Serine Protease A1 (HTRA1) Degrades Tau Protein Aggregates

Author

Tennstaedt, Annette, primary, Pöpsel, Simon, additional, Truebestein, Linda, additional, Hauske, Patrick, additional, Brockmann, Anke, additional, Schmidt, Nina, additional, Irle, Inga, additional, Sacca, Barbara, additional, Niemeyer, Christof M., additional, Brandt, Roland, additional, Ksiezak-Reding, Hanna, additional, Tirniceriu, Anca Laura, additional, Egensperger, Rupert, additional, Baldi, Alfonso, additional, Dehmelt, Leif, additional, Kaiser, Markus, additional, Huber, Robert, additional, Clausen, Tim, additional, and Ehrmann, Michael, additional

Published
2012
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33. Lysine-Specific Molecular Tweezers Are Broad-Spectrum Inhibitors of Assembly and Toxicity of Amyloid Proteins

Author

Sinha, Sharmistha, primary, Lopes, Dahabada H. J., additional, Du, Zhenming, additional, Pang, Eric S., additional, Shanmugam, Akila, additional, Lomakin, Aleksey, additional, Talbiersky, Peter, additional, Tennstaedt, Annette, additional, McDaniel, Kirsten, additional, Bakshi, Reena, additional, Kuo, Pei-Yi, additional, Ehrmann, Michael, additional, Benedek, George B., additional, Loo, Joseph A., additional, Klärner, Frank-Gerrit, additional, Schrader, Thomas, additional, Wang, Chunyu, additional, and Bitan, Gal, additional

Published
2011
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37. Relationship of T lymphocytes, T regulatory cells, and B lymphocytes to clinical outcome in prostate cancer

Author

Sarah Minner, Thorsten Schlomm, Hartwig Huland, L. Weisbach, Anna Flammiger, P. Tennstaedt, Carsten Bokemeyer, Guido Sauter, and Martin Trepel

Subjects
Cancer Research, Tissue microarray, business.industry, medicine.disease, Prostate cancer, Interleukin 21, Lymphatic system, medicine.anatomical_structure, Oncology, Prostate, Cancer research, Medicine, Cytotoxic T cell, Immunohistochemistry, business, Pathological
Abstract

4632 Background: Tumor-infiltrating lymphocytes are functionally important and correlate with clinical outcome in several tumor entities. In prostate cancer, systematic profiling of the number and subtype of lymphatic cells in the tumor tissue based on large patient cohorts are lacking. Methods: We explored the prognostic significance of the density of T and B lymphocytes in prostate cancer tissue in 3,261 prostate cancer tissue samples. The number of prostate cancer-infiltrating CD3-positive T cells, FOX-P3-positive T-regulatory cells (Tregs), and CD20-positive B cells per tissue spot in a tissue microarray format was determined by immunohistochemistry and was correlated with clinical and functional pathological data from the same patient cohort. Results: Patients with very low and very high numbers of CD3-positive T cells per tissue spot had a significantly shorter PSA recurrence-free survival compared to patients with intermediate numbers of T cells. The number of intraepithelial CD3-positive T cells a...

Published
2011
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40. Transcranial direct current stimulation promotes the mobility of engrafted NSCs in the rat brain.

Author

Keuters MH, Aswendt M, Tennstaedt A, Wiedermann D, Pikhovych A, Rotthues S, Fink GR, Schroeter M, Hoehn M, and Rueger MA

Subjects
Animals, Astrocytes drug effects, Astrocytes metabolism, Cell Line, Cell Survival drug effects, Electrodes, Immunity drug effects, Immunohistochemistry, Iron pharmacology, Macrophages cytology, Macrophages drug effects, Magnetic Resonance Imaging, Male, Mice, Microglia drug effects, Microglia metabolism, Neural Stem Cells drug effects, Phagocytosis drug effects, Rats, Wistar, Brain metabolism, Cell Movement drug effects, Neural Stem Cells cytology, Neural Stem Cells transplantation, Transcranial Direct Current Stimulation
Abstract

Transcranial direct current stimulation (tDCS) is used in numerous clinical studies and considered an effective and versatile add-on therapy in neurorehabilitation. To date, however, the underlying neurobiological mechanisms remain elusive. In a rat model of tDCS, we recently observed a polarity-dependent accumulation of endogenous neural stem cells (NSCs) in the stimulated cortex. Based upon these findings, we hypothesized that tDCS may exert a direct migratory effect on endogenous NSCs towards the stimulated cortex. Using noninvasive imaging, we here investigated whether tDCS may also cause a directed migration of engrafted NSCs. Murine NSCs were labeled with superparamagnetic particles of iron oxide (SPIOs) and implanted into rat striatum and corpus callosum. MRI was performed (i) immediately after implantation and (ii) after 10 tDCS sessions of anodal or cathodal polarity. Sham-stimulated rats served as control. Imaging results were validated ex vivo using immunohistochemistry. Overall migratory activity of NSCs almost doubled after anodal tDCS. However, no directed migration within the electric field (i.e. towards or away from the electrode) could be observed. Rather, an undirected outward migration from the center of the graft was detected. Xenograft transplantation induced a neuroinflammatory response that was significantly enhanced following cathodal tDCS. This inflammatory response did not impact negatively on the survival of implanted NSCs. Data suggest that anodal tDCS increases the undirected migratory activity of implanted NSCs. Since the electric field did not guide implanted NSCs over large distances, previously observed polarity-dependent accumulation of endogenous NSCs in the cortex might have originated from local proliferation. Results enhance our understanding of the neurobiological mechanisms underlying tDCS, and may thereby help to develop a targeted and sustainable application of tDCS in clinical practice., (Copyright © 2014 John Wiley & Sons, Ltd.)

Published
2015
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41. Proof of concept of an automatic tool for bioluminescence imaging data analysis.

Author

Mastropietro A, Tennstaedt A, Beyrau A, Henn N, Hoehn M, and Baselli G

Subjects
Algorithms, Animals, Brain cytology, Humans, Luminescent Measurements, Mice, Nude, Neural Stem Cells transplantation, Neuroimaging, Normal Distribution, Signal-To-Noise Ratio, Cell Tracking methods, Image Processing, Computer-Assisted
Abstract

Bioluminescence Imaging (BLI) is an important molecular imaging tool to assess complex biological processes in vivo. BLI is a sensitive technique, which is frequently used in small-animal preclinical research, mainly in oncology and neurology. Tracking of labeled cells is one of the major applications. However, BLI data analysis for the segmentation of up-taking regions and their quantification is not trivial and it is usually an operator-dependent activity. In this work, a proof of concept of an automatic method to analyze BL images is presented which is based on a multi-step approach. Different segmentation algorithms (K-means, Gaussian Mixture Model (GMM), and GMM initialized by K-means) were evaluated and an adequate image normalization step was suggested to include the background bioluminescence in the data analysis process. K-means segmentation is the most stable and accurate approach for different levels of signal intensity.

Published
2015
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42. HtrA1-dependent proteolysis of TGF-beta controls both neuronal maturation and developmental survival.

Author

Launay S, Maubert E, Lebeurrier N, Tennstaedt A, Campioni M, Docagne F, Gabriel C, Dauphinot L, Potier MC, Ehrmann M, Baldi A, and Vivien D

Subjects
Animals, Brain embryology, Brain growth & development, Cell Survival, Cells, Cultured, High-Temperature Requirement A Serine Peptidase 1, Mice, Mice, Transgenic, Neurons cytology, Neurons metabolism, Signal Transduction, Transforming Growth Factor beta1 pharmacology, Up-Regulation, Brain enzymology, Neurons enzymology, Serine Endopeptidases metabolism, Transforming Growth Factor beta1 metabolism
Abstract

Transforming growth factor-beta (TGF-beta) signalling controls a number of cerebral functions and dysfunctions including synaptogenesis, amyloid-beta accumulation, apoptosis and excitotoxicity. Using cultured cortical neurons prepared from either wild type or transgenic mice overexpressing a TGF-beta-responsive luciferase reporter gene (SBE-Luc), we demonstrated a progressive loss of TGF-beta signalling during neuronal maturation and survival. Moreover, we showed that neurons exhibit increasing amounts of the serine protease HtrA1 (high temperature responsive antigen 1) and corresponding cleavage products during both in vitro neuronal maturation and brain development. In parallel of its ability to promote degradation of TGF-beta1, we demonstrated that blockage of the proteolytic activity of HtrA1 leads to a restoration of TGF-beta signalling, subsequent overexpression of the serpin type -1 plasminogen activator inhibitor (PAI-1) and neuronal death. Altogether, we propose that the balance between HtrA1 and TGF-beta could be one of the critical events controlling both neuronal maturation and developmental survival.

Published
2008
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