Your search keyword '"pathology [Axons]"' showing total 13 results

1. Remyelination by surviving oligodendrocytes is inefficient in the inflamed mammalian cortex

Author

Mezydlo, Aleksandra, Treiber, Nils, Kerschensteiner, Martin, Ullrich Gavilanes, Emily, Eichenseer, Katharina, Ancău, Mihai, Wens, Adinda, Ares Carral, Carla, Schifferer, Martina, Snaidero, Nicolas, and Misgeld, Thomas

Subjects

Mammals, Multiple Sclerosis, pathology [Axons], General Neuroscience, oligodendrocytes, CLEM, oligodendrocyte precursor cell, Mice, myelin, remyelination, pathology [Oligodendroglia], pathology [Myelin Sheath], in vivo microscopy, Animals, ddc:610, demyelination

Abstract

In multiple sclerosis, an inflammatory attack results in myelin loss, which can be partially reversed by remyelination. Recent studies suggest that mature oligodendrocytes could contribute to remyelination by generating new myelin. Here, we show that in a mouse model of cortical multiple sclerosis pathology, surviving oligodendrocytes can indeed extend new proximal processes but rarely generate new myelin internodes. Furthermore, drugs that boost myelin recovery by targeting oligodendrocyte precursor cells did not enhance this alternate mode of myelin regeneration. These data indicate that the contribution of surviving oligodendrocytes to myelin recovery in the inflamed mammalian CNS is minor and inhibited by distinct remyelination brakes.

Published

2023

2. Concomitant gain and loss of function pathomechanisms in C9ORF72 amyotrophic lateral sclerosis

Author

Hannes Glaβ, Peter Heutink, Marcel Naumann, Arun Pal, Nicole Kreiter, Benedikt Kretner, René Günther, Masin Abo-Rady, Andreas Hermann, Ashutosh Dhingra, Tobias M. Böckers, Jared Sterneckert, Banaja P. Dash, and Julia Japtok

Subjects

0301 basic medicine, metabolism [Cytoskeleton], Health, Toxicology and Mutagenesis, Apoptosis, Plant Science, metabolism [Axons], 0302 clinical medicine, C9orf72, Loss of Function Mutation, DNA Breaks, Double-Stranded, Axon, Amyotrophic lateral sclerosis, Induced pluripotent stem cell, Cells, Cultured, Cellular Senescence, Cytoskeleton, Research Articles, Motor Neurons, Ecology, pathology [Axons], Neurodegeneration, physiopathology [Amyotrophic Lateral Sclerosis], Cell biology, DNA-Binding Proteins, genetics [Amyotrophic Lateral Sclerosis], medicine.anatomical_structure, Gain of Function Mutation, metabolism [Organelles], Research Article, Programmed cell death, TARDBP protein, human, genetics [DNA-Binding Proteins], Biology, Biochemistry, Genetics and Molecular Biology (miscellaneous), 03 medical and health sciences, ddc:570, medicine, Humans, pathology [Amyotrophic Lateral Sclerosis], genetics [C9orf72 Protein], Loss function, Repetitive Sequences, Nucleic Acid, Phenocopy, Organelles, C9orf72 Protein, Amyotrophic Lateral Sclerosis, metabolism [Motor Neurons], FUS protein, human, medicine.disease, Axons, 030104 developmental biology, nervous system, Microscopy, Fluorescence, RNA-Binding Protein FUS, Energy Metabolism, genetics [RNA-Binding Protein FUS], 030217 neurology & neurosurgery

Abstract

Axonal trafficking deficits and neurodegeneration in C9ORF72 motoneurons are mediated by GOF and LOF mechanisms with RNA foci and DPRs as upstream events, whereas DNA damage appears downstream., Intronic hexanucleotide repeat expansions (HREs) in C9ORF72 are the most frequent genetic cause of amyotrophic lateral sclerosis, a devastating, incurable motoneuron (MN) disease. The mechanism by which HREs trigger pathogenesis remains elusive. The discovery of repeat-associated non-ATG (RAN) translation of dipeptide repeat proteins (DPRs) from HREs along with reduced exonic C9ORF72 expression suggests gain of toxic functions (GOFs) through DPRs versus loss of C9ORF72 functions (LOFs). Through multiparametric high-content (HC) live profiling in spinal MNs from induced pluripotent stem cells and comparison to mutant FUS and TDP43, we show that HRE C9ORF72 caused a distinct, later spatiotemporal appearance of mainly proximal axonal organelle motility deficits concomitant to augmented DNA double-strand breaks (DSBs), RNA foci, DPRs, and apoptosis. We show that both GOFs and LOFs were necessary to yield the overall C9ORF72 pathology. Increased RNA foci and DPRs concurred with onset of axon trafficking defects, DSBs, and cell death, although DSB induction itself did not phenocopy C9ORF72 mutants. Interestingly, the majority of LOF-specific DEGs were shared with HRE-mediated GOF DEGs. Finally, C9ORF72 LOF was sufficient—albeit to a smaller extent—to induce premature distal axonal trafficking deficits and increased DSBs.

Published

2020

3. Modeling chemotherapy induced neurotoxicity with human induced pluripotent stem cell (iPSC) -derived sensory neurons

Author

Petra Huehnchen, Matthias Endres, Dieter Beule, Yangfan Peng, Andranik Ivanov, Christian Schinke, Valeria Fernandez Vallone, Peter Körtvelyessy, Luca Nolte, Harald Stachelscheid, and Wolfgang Boehmerle

Subjects

0301 basic medicine, Vincristine, Sensory Receptor Cells, Cell Survival, drug effects [Cell Survival], physiology [Cell Survival], Replacement, Induced Pluripotent Stem Cells, Neurosciences. Biological psychiatry. Neuropsychiatry, Antineoplastic Agents, Lithium, Pharmacology, 3R, Time-Lapse Imaging, Neuroprotection, Cell Line, toxicity [Antineoplastic Agents], Induced pluripotent stem cell derived sensory neurons (iPSC-DSN), 03 medical and health sciences, 0302 clinical medicine, ddc:570, medicine, Humans, Doxorubicin, Viability assay, drug effects [Axons], Induced pluripotent stem cell, Cisplatin, pathology [Axons], Dose-Response Relationship, Drug, drug effects [Induced Pluripotent Stem Cells], pathology [Sensory Receptor Cells], Bortezomib, business.industry, methods [Time-Lapse Imaging], Neurotoxicity, pathology [Induced Pluripotent Stem Cells], medicine.disease, Axons, 030104 developmental biology, Neurology, Chemotherapy induced neuropathy, drug effects [Sensory Receptor Cells], Transcriptome, business, 030217 neurology & neurosurgery, RC321-571, medicine.drug

Abstract

Chemotherapy-induced peripheral neuropathy (CIPN) is a frequent, potentially irreversible adverse effect of cytotoxic chemotherapy often leading to a reduction or discontinuation of treatment which negatively impacts patients' prognosis. To date, however, neither predictive biomarkers nor preventive treatments for CIPN are available, which is partially due to a lack of suitable experimental models. We therefore aimed to evaluate whether sensory neurons derived from induced pluripotent stem cells (iPSC-DSN) can serve as human disease model system for CIPN. Treatment of iPSC-DSN for 24 h with the neurotoxic drugs paclitaxel, bortezomib, vincristine and cisplatin led to axonal blebbing and a dose dependent decline of cell viability in clinically relevant IC50 ranges, which was not observed for the non-neurotoxic compounds doxorubicin and 5-fluorouracil. Paclitaxel treatment effects were less pronounced after 24 h but prominent when treatment was applied for 72 h. Global transcriptome analyses performed at 24 h, i.e. before paclitaxel-induced cell death occurred, revealed the differential expression of genes of neuronal injury, cellular stress response, and sterol pathways. We further evaluated if known neuroprotective strategies can be reproduced in iPSC-DSN and observed protective effects of lithium replicating findings from rodent dorsal root ganglia cells. Comparing sensory neurons derived from two different healthy donors, we found preliminary evidence that these cell lines react differentially to neurotoxic drugs as expected from the variable presentation of CIPN in patients. In conclusion, iPSC-DSN are a promising platform to study the pathogenesis of CIPN and to evaluate neuroprotective treatment strategies. In the future, the application of patient-specific iPSC-DSN could open new avenues for personalized medicine with individual risk prediction, choice of chemotherapeutic compounds and preventive treatments.

Published

2021

4. Can injured adult CNS axons regenerate by recapitulating development?

Author

Hilton, Brett J, Hilton, Brett Jason, and Bradke, Frank

Subjects

Central Nervous System, 0301 basic medicine, Aging, physiopathology [Central Nervous System], growth & development [Mammals], Central nervous system, Biology, Models, Biological, 03 medical and health sciences, Myelin, pathology [Aging], ddc:570, Extracellular, medicine, Animals, Axon, Growth cone, Molecular Biology, Mammals, pathology [Axons], Regeneration (biology), Anatomy, Axons, Nerve Regeneration, 030104 developmental biology, medicine.anatomical_structure, nervous system, Axoplasmic transport, pathology [Central Nervous System], Neuroscience, Intracellular, Developmental Biology

Abstract

In the adult mammalian central nervous system (CNS), neurons typically fail to regenerate their axons after injury. During development, by contrast, neurons extend axons effectively. A variety of intracellular mechanisms mediate this difference, including changes in gene expression, the ability to form a growth cone, differences in mitochondrial function/axonal transport and the efficacy of synaptic transmission. In turn, these intracellular processes are linked to extracellular differences between the developing and adult CNS. During development, the extracellular environment directs axon growth and circuit formation. In adulthood, by contrast, extracellular factors, such as myelin and the extracellular matrix, restrict axon growth. Here, we discuss whether the reactivation of developmental processes can elicit axon regeneration in the injured CNS.

Published

2017

5. ADF/Cofilin-Mediated Actin Turnover Promotes Axon Regeneration in the Adult CNS

Author

Sina Stern, Kevin C. Flynn, Michele Curcio, Walter Witke, Brett J. Hilton, Christine B. Gurniak, Frank Bradke, Barbara Schaffran, Molly J.E. Larson, Claudia J. Laskowski, Sebastian Dupraz, Andrea Tedeschi, and Telma E. Santos

Subjects

0301 basic medicine, Intravital Microscopy, Regulator, genetics [Cofilin 2], metabolism [Axons], metabolism [Spinal Cord Injuries], metabolism [Cofilin 2], genetics [Nerve Regeneration], Mice, 0302 clinical medicine, pathology [Neurons], Axon, Neurons, Microscopy, Confocal, pathology [Axons], genetics [Spinal Cord Injuries], General Neuroscience, Axon extension, Cofilin, Cell biology, metabolism [Cofilin 1], medicine.anatomical_structure, metabolism [Neurons], Actin depolymerizing factor, pathology [Spinal Cord Injuries], Cofilin 1, Cofilin 2, metabolism [Actins], metabolism [Growth Cones], Growth Cones, macromolecular substances, Biology, Time-Lapse Imaging, 03 medical and health sciences, medicine, Animals, ddc:610, Actin, Spinal Cord Injuries, Regeneration (biology), genetics [Cofilin 1], Embryogenesis, pathology [Growth Cones], Actins, Axons, Nerve Regeneration, Rats, 030104 developmental biology, Destrin, metabolism [Destrin], nervous system, genetics [Destrin], 030217 neurology & neurosurgery

Abstract

Summary Injured axons fail to regenerate in the adult CNS, which contrasts with their vigorous growth during embryonic development. We explored the potential of re-initiating axon extension after injury by reactivating the molecular mechanisms that drive morphogenetic transformation of neurons during development. Genetic loss- and gain-of-function experiments followed by time-lapse microscopy, in vivo imaging, and whole-mount analysis show that axon regeneration is fueled by elevated actin turnover. Actin depolymerizing factor (ADF)/cofilin controls actin turnover to sustain axon regeneration after spinal cord injury through its actin-severing activity. This pinpoints ADF/cofilin as a key regulator of axon growth competence, irrespective of developmental stage. These findings reveal the central role of actin dynamics regulation in this process and elucidate a core mechanism underlying axon growth after CNS trauma. Thereby, neurons maintain the capacity to stimulate developmental programs during adult life, expanding their potential for plasticity. Thus, actin turnover is a key process for future regenerative interventions.

Published

2019

6. Locomotor recovery following contusive spinal cord injury does not require oligodendrocyte remyelination

Author

Jason R. Plemel, Aaron J. Moulson, Sohrab B. Manesh, Brett J. Hilton, Jie Liu, Peggy Assinck, Wolfram Tetzlaff, and Greg J. Duncan

Subjects

Male, 0301 basic medicine, Receptor, Platelet-Derived Growth Factor alpha, metabolism [Myelin Sheath], General Physics and Astronomy, pathology [Neural Stem Cells], metabolism [Axons], metabolism [Spinal Cord Injuries], myelin gene regulatory factor, mouse, Mice, Myelin, 0302 clinical medicine, Neural Stem Cells, Spinal Cord/metabolism, metabolism [Transcription Factors], lcsh:Science, Spinal cord injury, Myelin Sheath, Myelin Sheath/metabolism, Mice, Knockout, Multidisciplinary, pathology [Axons], Behavior, Animal, Cell Differentiation, genetics [Transcription Factors], Neural Stem Cells/pathology, Neural stem cell, Oligodendroglia, medicine.anatomical_structure, Spinal Cord, Female, ddc:500, pathology [Spinal Cord Injuries], metabolism [Spinal Cord], Science, Spinal Cord Injuries/metabolism, Transcription Factors/genetics, pathology [Spinal Cord], Axons/metabolism, Biology, Nerve Regeneration/physiology, Article, General Biochemistry, Genetics and Molecular Biology, metabolism [Oligodendroglia], 03 medical and health sciences, medicine, Animals, Remyelination, Spinal Cord Injuries, Cell Proliferation, Regeneration (biology), Myelin regulatory factor, General Chemistry, medicine.disease, Spinal cord, Axons, Oligodendrocyte, Nerve Regeneration, Disease Models, Animal, Oligodendroglia/metabolism, 030104 developmental biology, physiology [Remyelination], nervous system, Remyelination/physiology, physiology [Nerve Regeneration], pathology [Oligodendroglia], lcsh:Q, Neuroscience, Gene Deletion, 030217 neurology & neurosurgery, Transcription Factors

Abstract

Remyelination occurs after spinal cord injury (SCI) but its functional relevance is unclear. We assessed the necessity of myelin regulatory factor (Myrf) in remyelination after contusive SCI by deleting the gene from platelet-derived growth factor receptor alpha positive (PDGFRα-positive) oligodendrocyte progenitor cells (OPCs) in mice prior to SCI. While OPC proliferation and density are not altered by Myrf inducible knockout after SCI, the accumulation of new oligodendrocytes is largely prevented. This greatly inhibits myelin regeneration, resulting in a 44% reduction in myelinated axons at the lesion epicenter. However, spontaneous locomotor recovery after SCI is not altered by remyelination failure. In controls with functional MYRF, locomotor recovery precedes the onset of most oligodendrocyte myelin regeneration. Collectively, these data demonstrate that MYRF expression in PDGFRα-positive cell derived oligodendrocytes is indispensable for myelin regeneration following contusive SCI but that oligodendrocyte remyelination is not required for spontaneous recovery of stepping., The contribution of oligodendrocytes to remyelination in functional recovery after spinal cord injury is not fully understood. Here, the authors show that oligodendrocyte progenitor cell differentiation is not required for functional recovery after spinal cord injury in mice.

Published

2018

7. The DLK signalling pathway—a double‐edged sword in neural development and regeneration

Author

Frank Bradke and Andrea Tedeschi

Subjects

Central Nervous System, Nervous system, metabolism [Apoptosis Regulatory Proteins], Neurogenesis, metabolism [Calcium-Calmodulin-Dependent Protein Kinases], genetics [Mitogen-Activated Protein Kinase Kinases], Apoptosis, Review Article, metabolism [Axons], metabolism [Neurodegenerative Diseases], Biology, Mitogen-activated protein kinase kinase, Biochemistry, physiology [Regeneration], ddc:570, physiology [Signal Transduction], Genetics, medicine, Animals, Humans, Regeneration, Axon, Protein kinase A, Molecular Biology, genetics [Calcium-Calmodulin-Dependent Protein Kinases], Mitogen-Activated Protein Kinase Kinases, pathology [Axons], Regeneration (biology), pathology [Neurodegenerative Diseases], Gene Expression Regulation, Developmental, Neurodegenerative Diseases, physiology [Neurogenesis], physiology [Central Nervous System], Axons, Cell biology, genetics [Apoptosis Regulatory Proteins], Isoenzymes, Death-Associated Protein Kinases, medicine.anatomical_structure, metabolism [Isoenzymes], genetics [Neurodegenerative Diseases], Calcium-Calmodulin-Dependent Protein Kinases, Neuron, metabolism [Mitogen-Activated Protein Kinase Kinases], genetics [Isoenzymes], Apoptosis Regulatory Proteins, Neural development, Signal Transduction

Abstract

Dual leucine zipper kinase (DLK), a mitogen-activated protein kinase kinase kinase, controls axon growth, apoptosis and neuron degeneration during neural development, as well as neurodegeneration after various insults to the adult nervous system. Interestingly, recent studies have also highlighted a role of DLK in promoting axon regeneration in diverse model systems. Invertebrates and vertebrates, cold- and warm-blooded animals, as well as central and peripheral mammalian nervous systems all differ in their ability to regenerate injured axons. Here, we discuss how DLK-dependent signalling regulates apparently contradictory functions during neural development and regeneration in different species. In addition, we outline strategies to fine-tune DLK function, either alone or together with other approaches, to promote axon regeneration in the adult mammalian central nervous system.

Published

2013

8. CNS repair and axon regeneration: Using genetic variation to determine mechanisms

Author

Michael Costigan, Andrea Tedeschi, and Takao Omura

Subjects

0301 basic medicine, pathology [Central Nervous System Diseases], physiopathology [Central Nervous System Diseases], Central nervous system, Biology, Genome, Article, 03 medical and health sciences, 0302 clinical medicine, Developmental Neuroscience, Central Nervous System Diseases, physiology [Signal Transduction], Genetic variation, medicine, Animals, Humans, ddc:610, Axon, Gene, Organism, physiology [Axons], pathology [Axons], Regeneration (biology), Genetic Variation, genetics [Central Nervous System Diseases], genetics [Genetic Variation], Axons, Nerve Regeneration, 030104 developmental biology, medicine.anatomical_structure, Neurology, physiology [Nerve Regeneration], Signal transduction, Neuroscience, 030217 neurology & neurosurgery, Signal Transduction

Abstract

The importance of genetic diversity in biological investigation has been recognized since the pioneering studies of Gregor Johann Mendel and Charles Darwin. Research in this area has been greatly informed recently by the publication of genomes from multiple species. Genes regulate and create every part and process in a living organism, react with the environment to create each living form and morph and mutate to determine the history and future of each species. The regenerative capacity of neurons differs profoundly between animal lineages and within the mammalian central and peripheral nervous systems. Here, we discuss research that suggests that genetic background contributes to the ability of injured axons to regenerate in the mammalian central nervous system (CNS), by controlling the regulation of specific signaling cascades. We detail the methods used to identify these pathways, which include among others Activin signaling and other TGF-β superfamily members. We discuss the potential of altering these pathways in patients with CNS damage and outline strategies to promote regeneration and repair by combinatorial manipulation of neuron-intrinsic and extrinsic determinants.

Published

2016

9. The MDM4/MDM2-p53-IGF1 axis controls axonal regeneration, sprouting and functional recovery after CNS injury

Author

Gizem Inak, Luming Zhou, Jeanne Christophe Marine, Magali Cucchiarini, Arnau Hervera, Yashashree Joshi, Khizr I. Rathore, Mohamed Y. Elnaggar, Simone Di Giovanni, Giorgia Quadrato, Radhika Puttagunta, Marilia Grando Sória, Wings for Life Spinal Cord Research Foundation, and International Spinal Research Trust

Subjects

p53, metabolism [Axons], CORTICOSPINAL TRACT, metabolism [Spinal Cord Injuries], ACTIVATION, Mice, Mdm4 protein, mouse, Ubiquitin, spinal cord injury, regeneration, IGF1R, physiopathology [Spinal Cord Injuries], SPINAL-CORD-INJURY, Insulin-Like Growth Factor I, metabolism [Insulin-Like Growth Factor I], Spinal cord injury, IN-VIVO, pathology [Axons], biology, Reverse Transcriptase Polymerase Chain Reaction, metabolism [Proto-Oncogene Proteins c-mdm2], P53 PATHWAY, Proto-Oncogene Proteins c-mdm2, 11 Medical And Health Sciences, Flow Cytometry, ADULT CNS, Immunohistochemistry, FAMILY-MEMBERS, medicine.anatomical_structure, Optic nerve, Mdm2, Mdm2 protein, mouse, pathology [Spinal Cord Injuries], Life Sciences & Biomedicine, Signal Transduction, physiopathology [Optic Nerve Injuries], GROWTH CONE COLLAPSE, Nerve Crush, Ubiquitin-Protein Ligases, Central nervous system, Immunoblotting, Clinical Neurology, NEURITE OUTGROWTH, Retinal ganglion, optic nerve, 17 Psychology And Cognitive Sciences, MDM4, metabolism [Ubiquitin-Protein Ligases], MDM2, Proto-Oncogene Proteins, physiology [Signal Transduction], medicine, Animals, Immunoprecipitation, metabolism [Proto-Oncogene Proteins], ddc:610, Spinal Cord Injuries, metabolism [Optic Nerve Injuries], Science & Technology, Neurology & Neurosurgery, Regeneration (biology), Neurosciences, Computational Biology, Recovery of Function, pathology [Optic Nerve Injuries], Spinal cord, medicine.disease, insulin-like growth factor-1, mouse, spinal cord injury, Axons, Mice, Mutant Strains, Nerve Regeneration, Mice, Inbred C57BL, Disease Models, Animal, physiology [Recovery of Function], physiology [Nerve Regeneration], regeneration, Optic Nerve Injuries, biology.protein, metabolism [Tumor Suppressor Protein p53], Neurology (clinical), Neurosciences & Neurology, Tumor Suppressor Protein p53, Transcriptome, Neuroscience, OPTIC-NERVE

Abstract

Regeneration of injured central nervous system axons is highly restricted, causing neurological impairment. To date, although the lack of intrinsic regenerative potential is well described, a key regulatory molecular mechanism for the enhancement of both axonal regrowth and functional recovery after central nervous system injury remains elusive. While ubiquitin ligases coordinate neuronal morphogenesis and connectivity during development as well as after axonal injury, their role specifically in axonal regeneration is unknown. Following a bioinformatics network analysis combining ubiquitin ligases with previously defined axonal regenerative proteins, we found a triad composed of the ubiquitin ligases MDM4, MDM2 and the transcription factor p53 (encoded by TP53) as a putative central signalling complex restricting the regeneration program. Indeed, conditional deletion of MDM4 or pharmacological inhibition of MDM2/p53 interaction in the eye and spinal cord promote axonal regeneration and sprouting of the optic nerve after crush and of supraspinal tracts after spinal cord injury. The double conditional deletion of MDM4-p53 as well as MDM2 inhibition in p53-deficient mice blocks this regenerative phenotype, showing its dependence upon p53. Genome-wide gene expression analysis from ex vivo fluorescence-activated cell sorting in MDM4-deficient retinal ganglion cells identifies the downstream target IGF1R, whose activity and expression was found to be required for the regeneration elicited by MDM4 deletion. Importantly, we demonstrate that pharmacological enhancement of the MDM2/p53-IGF1R axis enhances axonal sprouting as well as functional recovery after spinal cord injury. Thus, our results show MDM4-MDM2/p53-IGF1R as an original regulatory mechanism for CNS regeneration and offer novel targets to enhance neurological recovery.media-1vid110.1093/brain/awv125_video_abstractawv125_video_abstract.

Published

2014

10. Early-onset axonal pathology in a novel P301S-Tau transgenic mouse model of frontotemporal lobar degeneration

Author

van Eersel, Janet, Stevens, Claire H, Abramowski, Dorothee, Staufenbiel, Matthias, Halliday, Glenda M, Ittner, Lars M, Przybyla, Magdalena, Gladbach, Amadeus, Stefanoska, Kristie, Chan, Chesed Kai-Xin, Ong, Wei-Yi, Hodges, John R, Sutherland, Greg T, and Kril, Jillian J

Subjects

Neurons, pathology [Axons], pathology [Frontotemporal Lobar Degeneration], Brain, Mice, Transgenic, tau Proteins, metabolism [tau Proteins], Axons, metabolism [Frontotemporal Lobar Degeneration], genetics [tau Proteins], Disease Models, Animal, Mice, metabolism [Brain], pathology [Brain], metabolism [Neurons], pathology [Neurons], Animals, ddc:610, genetics [Frontotemporal Lobar Degeneration], Frontotemporal Lobar Degeneration

Abstract

Tau becomes hyperphosphorylated in Alzheimer's disease (AD) and frontotemporal lobar degeneration (FTLD-tau), resulting in functional deficits of neurones, neurofibrillary tangle (NFT) formation and eventually dementia. Expression of mutant human tau in the brains of transgenic mice has produced different lines that recapitulate various aspects of FTLD-tau and AD. In this study, we characterized the novel P301S mutant tau transgenic mouse line, TAU58/2.Both young and aged TAU58/2 mice underwent extensive motor testing, after which brain tissue was analysed with immunohistochemistry, silver staining, electron microscopy and Western blotting. Tissue from various FTLD subtypes and AD patients was also analysed for comparison.TAU58/2 mice presented with early-onset motor deficits, which became more pronounced with age. Throughout the brains of these mice, tau was progressively hyperphosphorylated resulting in increased NFT formation with age. In addition, frequent axonal swellings that stained intensively for neurofilament (NF) were present in young TAU58/2 mice prior to NFT formation. Similar axonal pathology was also observed in human FTLD-tau and AD. Interestingly, activated microglia were found in close proximity to neurones harbouring transgenic tau, but were not associated with NF-positive axonal swellings.In TAU58/2 mice, early tau pathology induces functional deficits of neurones associated with NF pathology. This appears to be specific to tau, as similar changes are observed in FTLD-tau, but not in FTLD with TDP-43 inclusions. Therefore, TAU58/2 mice recapitulate aspects of human FTLD-tau and AD pathology, and will become instrumental in studying disease mechanisms and therapeutics in the future.

Published

2014

11. FUS-mediated alternative splicing in the nervous system: consequences for ALS and FTLD

Author

Denise Orozco and Dieter Edbauer

Subjects

Nervous system, Tau protein, Biology, metabolism [Axons], metabolism [Nervous System], Nervous System, pathology [Brain], Drug Discovery, Netrin, medicine, Animals, Humans, ddc:610, Amyotrophic lateral sclerosis, Growth cone, Genetics (clinical), metabolism [RNA-Binding Protein FUS], pathology [Axons], metabolism [Amyotrophic Lateral Sclerosis], Neurodegeneration, Alternative splicing, Amyotrophic Lateral Sclerosis, Brain, Frontotemporal lobar degeneration, pathology [Nervous System], medicine.disease, Axons, Cell biology, metabolism [Frontotemporal Lobar Degeneration], genetics [Amyotrophic Lateral Sclerosis], Alternative Splicing, medicine.anatomical_structure, Gene Expression Regulation, metabolism [Brain], biology.protein, Cancer research, Molecular Medicine, RNA-Binding Protein FUS, genetics [Frontotemporal Lobar Degeneration], Frontotemporal Lobar Degeneration

Abstract

Mutations in fused in sarcoma (FUS) in a subset of patients with amyotrophic lateral sclerosis (ALS) linked this DNA/RNA-binding protein to neurodegeneration. Most of the mutations disrupt the nuclear localization signal which strongly suggests a loss-of-function pathomechanism, supported by cytoplasmic inclusions. FUS-positive neuronal cytoplasmic inclusions are also found in a subset of patients with frontotemporal lobar degeneration (FTLD). Here, we discuss recent data on the role of alternative splicing in FUS-mediated pathology in the central nervous system. Several groups have shown that FUS binds broadly to many transcripts in the brain and have also identified a plethora of putative splice targets; however, only ABLIM1, BRAF, Ewing sarcoma protein R1 (EWSR1), microtubule-associated protein tau (MAPT), NgCAM cell adhesion molecule (NRCAM), and netrin G1 (NTNG1) have been identified in at least three of four studies. Gene ontology analysis of all putative targets unanimously suggests a role in axon growth and cytoskeletal organization, consistent with the altered morphology of dendritic spines and axonal growth cones reported upon loss of FUS. Among the axonal targets, MAPT/tau and NTNG1 have been further validated in biochemical studies. The next challenge will be to confirm changes of FUS-mediated alternative splicing in patients and define their precise role in the pathophysiology of ALS and FTLD.

Published

2013

12. Loss of ALS-associated TDP-43 in zebrafish causes muscle degeneration, vascular dysfunction, and reduced motor neuron axon outgrowth

Author

Christine Van Broeckhoven, Sebastian Hogl, Barbara Solchenberger, Alexander Hruscha, Stefan F. Lichtenthaler, Elisabeth Kremmer, Katrin Strecker, Maike Kittelmann, Dieter Edbauer, Julie van der Zee, Bettina Schmid, Laura Hasenkamp, Frauke van Bebber, Julia Banzhaf-Strathmann, Christian Haass, Marc Cruts, Mathias Teucke, Jan Hegermann, and Stefan Eimer

Subjects

metabolism [Vascular Diseases], genetics [Zebrafish Proteins], metabolism [Axons], medicine.disease_cause, Filamin, Contractile Proteins, metabolism [Zebrafish], Amyotrophic lateral sclerosis, pathology [Muscular Atrophy], Zebrafish, Motor Neurons, Mutation, Multidisciplinary, pathology [Axons], biology, Microfilament Proteins, Neurodegeneration, Zinc Finger Nuclease, Proteomics, genetics [Vascular Diseases], Frontotemporal lobar degeneration, Biological Sciences, genetics [Contractile Proteins], Cell biology, DNA-Binding Proteins, genetics [Amyotrophic Lateral Sclerosis], Muscular Atrophy, medicine.anatomical_structure, ddc:500, Engineering sciences. Technology, metabolism [Zebrafish Proteins], pathology [Motor Neurons], Filamins, TARDBP, genetics [Muscular Atrophy], mental disorders, medicine, Animals, Humans, Actin-binding protein, Vascular Diseases, pathology [Amyotrophic Lateral Sclerosis], Biology, metabolism [Contractile Proteins], metabolism [Amyotrophic Lateral Sclerosis], metabolism [Muscular Atrophy], Amyotrophic Lateral Sclerosis, nutritional and metabolic diseases, metabolism [Microfilament Proteins], metabolism [Motor Neurons], Motor neuron, Zebrafish Proteins, medicine.disease, biology.organism_classification, Axons, nervous system diseases, Protein Structure, Tertiary, biology.protein, Human medicine, genetics [Microfilament Proteins], pathology [Vascular Diseases], Neuroscience

Abstract

Mutations in the Tar DNA binding protein of 43 kDa (TDP-43; TARDBP) are associated with amyotrophic lateral sclerosis (ALS) and frontotemporal lobar degeneration with TDP-43 + inclusions (FTLD-TDP). To determine the physiological function of TDP-43, we knocked out zebrafish Tardbp and its paralogue Tardbp (TAR DNA binding protein-like), which lacks the glycine-rich domain where ALS- and FTLD-TDP–associated mutations cluster. tardbp mutants show no phenotype, a result of compensation by a unique splice variant of tardbpl that additionally contains a C-terminal elongation highly homologous to the glycine-rich domain of tardbp . Double-homozygous mutants of tardbp and tardbpl show muscle degeneration, strongly reduced blood circulation, mispatterning of vessels, impaired spinal motor neuron axon outgrowth, and early death. In double mutants the muscle-specific actin binding protein Filamin Ca is up-regulated. Strikingly, Filamin C is similarly increased in the frontal cortex of FTLD-TDP patients, suggesting aberrant expression in smooth muscle cells and TDP-43 loss-of-function as one underlying disease mechanism.

Published

2013

13. Neuropathology in Mice Expressing Mouse Alpha-Synuclein

Author

Iwona Ksiazek, Katja Lehnhoff, Simone Danner, Philipp J. Kahle, Cindy Boden, Derya R. Shimshek, Samuel Barbieri, Heinrich Schell, Kumlesh K. Dev, Claus Rieker, Sabine Kauffmann, Markus A. Rüegg, and Herman van der Putten

Subjects

Male, Pathology, Mouse, metabolism [Neuromuscular Junction], lcsh:Medicine, Gene Expression, metabolism [Hippocampus], metabolism [Axons], physiopathology [Brain], Biochemistry, Hippocampus, Behavioral Neuroscience, Mice, chemistry.chemical_compound, 0302 clinical medicine, Ubiquitin, pathology [Brain], physiopathology [Neuromuscular Junction], metabolism [Ubiquitin], Neurobiology of Disease and Regeneration, pathology [Neurons], metabolism [Nervous System Diseases], metabolism [alpha-Synuclein], Phosphorylation, lcsh:Science, Microscopy, Immunoelectron, In Situ Hybridization, ultrastructure [Neurons], Mice, Knockout, Neurons, 0303 health sciences, Multidisciplinary, pathology [Axons], biology, Brain, Animal Models, genetics [Nervous System Diseases], Immunohistochemistry, Cell biology, physiology [Motor Activity], Spinal Cord, metabolism [Neurons], genetics [alpha-Synuclein], alpha-Synuclein, Female, Research Article, ultrastructure [Axons], Genetically modified mouse, metabolism [Spinal Cord], medicine.medical_specialty, Histology, Neurofilament, Transgene, physiopathology [Spinal Cord], Blotting, Western, Neuromuscular Junction, Mice, Transgenic, pathology [Spinal Cord], In situ hybridization, Motor Activity, pathology [Neuromuscular Junction], Protein Chemistry, 03 medical and health sciences, physiology [Maze Learning], Model Organisms, medicine, Animals, Humans, ddc:610, physiopathology [Nervous System Diseases], Maze Learning, Biology, 030304 developmental biology, Alpha-synuclein, lcsh:R, Wild type, Proteins, Axons, Mice, Inbred C57BL, pathology [Hippocampus], chemistry, metabolism [Brain], physiopathology [Hippocampus], biology.protein, lcsh:Q, Nervous System Diseases, 030217 neurology & neurosurgery, Immunostaining, Neuroscience

Abstract

α-Synuclein (αSN) in human is tightly linked both neuropathologically and genetically to Parkinson's disease (PD) and related disorders. Disease-causing properties in vivo of the wildtype mouse ortholog (mαSN), which carries a threonine at position 53 like the A53T human mutant version that is genetically linked to PD, were never reported. To this end we generated mouse lines that express mαSN in central neurons at levels reaching up to six-fold compared to endogenous mαSN. Unlike transgenic mice expressing human wildtype or mutant forms of αSN, these mαSN transgenic mice showed pronounced ubiquitin immunopathology in spinal cord and brainstem. Isoelectric separation of mαSN species revealed multiple isoforms including two Ser129-phosphorylated species in the most severely affected brain regions. Neuronal Ser129-phosphorylated αSN occurred in granular and small fibrillar aggregates and pathological staining patterns in neurites occasionally revealed a striking ladder of small alternating segments staining either for Ser129-phosphorylated αSN or ubiquitin but not both. Axonal degeneration in long white matter tracts of the spinal cord, with breakdown of myelin sheaths and degeneration of neuromuscular junctions with loss of integrity of the presynaptic neurofilament network in mαSN transgenic mice, was similar to what we have reported for mice expressing human αSN wildtype or mutant forms. In hippocampal neurons, the mαSN protein accumulated and was phosphorylated but these neurons showed no ubiquitin immunopathology. In contrast to the early-onset motor abnormalities and muscle weakness observed in mice expressing human αSN, mαSN transgenic mice displayed only end-stage phenotypic alterations that manifested alongside with neuropathology. Altogether these findings show that increased levels of wildtype mαSN does not induce early-onset behavior changes, but drives end-stage pathophysiological changes in murine neurons that are strikingly similar to those evoked by expression of human wildtype or mutant forms.

Published

2011