Your search keyword '"Peter D. Currie"' showing total 96 results

1. Standardization of zebrafish drug testing parameters for muscle diseases

Author

Muthukumar Karuppasamy, Katherine G. English, Clarissa A. Henry, M. Chiara Manzini, John M. Parant, Melissa A. Wright, Avnika A. Ruparelia, Peter D. Currie, Vandana A. Gupta, James J. Dowling, Lisa Maves, and Matthew S. Alexander

Subjects

zebrafish, drug discovery, standardization, drug screening parameters, drug library, Medicine, Pathology, RB1-214

Published

2024

2. Machine learning discriminates a movement disorder in a zebrafish model of Parkinson's disease

Author

Gideon L. Hughes, Michael A. Lones, Matthew Bedder, Peter D. Currie, Stephen L. Smith, and Mary Elizabeth Pownall

Subjects

dj-1, park7, artificial intelligence, gene targeting, video capture, parkinson's disease, Medicine, Pathology, RB1-214

Abstract

Animal models of human disease provide an in vivo system that can reveal molecular mechanisms by which mutations cause pathology, and, moreover, have the potential to provide a valuable tool for drug development. Here, we have developed a zebrafish model of Parkinson's disease (PD) together with a novel method to screen for movement disorders in adult fish, pioneering a more efficient drug-testing route. Mutation of the PARK7 gene (which encodes DJ-1) is known to cause monogenic autosomal recessive PD in humans, and, using CRISPR/Cas9 gene editing, we generated a Dj-1 loss-of-function zebrafish with molecular hallmarks of PD. To establish whether there is a human-relevant parkinsonian phenotype in our model, we adapted proven tools used to diagnose PD in clinics and developed a novel and unbiased computational method to classify movement disorders in adult zebrafish. Using high-resolution video capture and machine learning, we extracted novel features of movement from continuous data streams and used an evolutionary algorithm to classify parkinsonian fish. This method will be widely applicable for assessing zebrafish models of human motor diseases and provide a valuable asset for the therapeutics pipeline. In addition, interrogation of RNA-seq data indicate metabolic reprogramming of brains in the absence of Dj-1, adding to growing evidence that disruption of bioenergetics is a key feature of neurodegeneration. This article has an associated First Person interview with the first author of the paper.

Published

2020

3. Loss of Tropomodulin4 in the zebrafish mutant träge causes cytoplasmic rod formation and muscle weakness reminiscent of nemaline myopathy

Author

Joachim Berger, Hakan Tarakci, Silke Berger, Mei Li, Thomas E. Hall, Anders Arner, and Peter D. Currie

Subjects

Myofibrillogenesis, Nemaline myopathy, Neuromuscular disorder, Sarcomere assembly, tmod, Tropomodulin, Medicine, Pathology, RB1-214

Abstract

Nemaline myopathy is an inherited muscle disease that is mainly diagnosed by the presence of nemaline rods in muscle biopsies. Of the nine genes associated with the disease, five encode components of striated muscle sarcomeres. In a genetic zebrafish screen, the mutant träge (trg) was isolated based on its reduction in muscle birefringence, indicating muscle damage. Myofibres in trg appeared disorganised and showed inhomogeneous cytoplasmic eosin staining alongside malformed nuclei. Linkage analysis of trg combined with sequencing identified a nonsense mutation in tropomodulin4 (tmod4), a regulator of thin filament length and stability. Accordingly, although actin monomers polymerize to form thin filaments in the skeletal muscle of tmod4trg mutants, thin filaments often appeared to be dispersed throughout myofibres. Organised myofibrils with the typical striation rarely assemble, leading to severe muscle weakness, impaired locomotion and early death. Myofibrils of tmod4trg mutants often featured thin filaments of various lengths, widened Z-disks, undefined H-zones and electron-dense aggregations of various shapes and sizes. Importantly, Gomori trichrome staining and the lattice pattern of the detected cytoplasmic rods, together with the reactivity of rods with phalloidin and an antibody against actinin, is reminiscent of nemaline rods found in nemaline myopathy, suggesting that misregulation of thin filament length causes cytoplasmic rod formation in tmod4trg mutants. Although Tropomodulin4 has not been associated with myopathy, the results presented here implicateTMOD4 as a novel candidate for unresolved nemaline myopathies and suggest that the tmod4trg mutant will be a valuable tool to study human muscle disorders.

Published

2014

4. Zebrafish models flex their muscles to shed light on muscular dystrophies

Author

Joachim Berger and Peter D. Currie

Subjects

Medicine, Pathology, RB1-214

Abstract

Muscular dystrophies are a group of genetic disorders that specifically affect skeletal muscle and are characterized by progressive muscle degeneration and weakening. To develop therapies and treatments for these diseases, a better understanding of the molecular basis of muscular dystrophies is required. Thus, identification of causative genes mutated in specific disorders and the study of relevant animal models are imperative. Zebrafish genetic models of human muscle disorders often closely resemble disease pathogenesis, and the optical clarity of zebrafish embryos and larvae enables visualization of dynamic molecular processes in vivo. As an adjunct tool, morpholino studies provide insight into the molecular function of genes and allow rapid assessment of candidate genes for human muscular dystrophies. This unique set of attributes makes the zebrafish model system particularly valuable for the study of muscle diseases. This review discusses how recent research using zebrafish has shed light on the pathological basis of muscular dystrophies, with particular focus on the muscle cell membrane and the linkage between the myofibre cytoskeleton and the extracellular matrix.

Published

2012

5. FKRP-dependent glycosylation of fibronectin regulates muscle pathology in muscular dystrophy

Author

Christoph Krisp, Carmen Sonntag, L. Hersey, A.J. Wood, Sara Gibertini, Alex J. Fulcher, Patricia R. Jusuf, A. Siegel, Marina Mora, Chi-Hung Lin, Peter D. Currie, Stefanie Dudczig, Sara Alaei, Nicolle H. Packer, M. Li, K. Nishtala, Lee B. Miles, Paul J. Conroy, and Fernando J. Rossello

Subjects

0301 basic medicine, Male, Glycosylation, Glycobiology, General Physics and Astronomy, Skeletal muscle, medicine.disease_cause, Basement Membrane, Muscular Dystrophies, Extracellular matrix, chemistry.chemical_compound, Gene Knockout Techniques, 0302 clinical medicine, Muscular dystrophy, Zebrafish, Uncategorized, Mutation, Multidisciplinary, biology, Neuromuscular disease, Phenotype, Cell biology, musculoskeletal diseases, Myoblasts, Skeletal, Science, General Biochemistry, Genetics and Molecular Biology, Article, Cell Line, 03 medical and health sciences, medicine, Animals, Humans, Pentosyltransferases, Muscle, Skeletal, Glycosyltransferases, General Chemistry, Muscular Dystrophy, Animal, Zebrafish Proteins, medicine.disease, biology.organism_classification, Fukutin, Fibronectins, Fibronectin, Disease Models, Animal, 030104 developmental biology, chemistry, Muscular Dystrophies, Limb-Girdle, biology.protein, 030217 neurology & neurosurgery

Abstract

The muscular dystrophies encompass a broad range of pathologies with varied clinical outcomes. In the case of patients carrying defects in fukutin-related protein (FKRP), these diverse pathologies arise from mutations within the same gene. This is surprising as FKRP is a glycosyltransferase, whose only identified function is to transfer ribitol-5-phosphate to α-dystroglycan (α-DG). Although this modification is critical for extracellular matrix attachment, α-DG’s glycosylation status relates poorly to disease severity, suggesting the existence of unidentified FKRP targets. Here we reveal that FKRP directs sialylation of fibronectin, a process essential for collagen recruitment to the muscle basement membrane. Thus, our results reveal that FKRP simultaneously regulates the two major muscle-ECM linkages essential for fibre survival, and establishes a new disease axis for the muscular dystrophies., FKRP mutations cause muscular dystrophies with varied clinical presentations. The target of FKRP is α-dystroglycan, but here the authors show that FKRP also directs sialylation of fibronectin, a process that is essential for recruitment o collagen to the muscle basement membrane.

Published

2021

6. Macrophages provide a transient muscle stem cell niche via NAMPT secretion

Author

Carmen Sonntag, Laura A. Galvis, Phong D. Nguyen, Fernando J. Rossello, Jeroen Bakkers, Christophe Marcelle, Kelly L. Rogers, Verena C. Wimmer, Ziad Julier, Abdulsalam I. Isiaku, Thomas Boudier, Mikaël M. Martino, Dhanushika Ratnayake, Silke Berger, Jean Tan, Graham J. Lieschke, A.J. Wood, Peter D. Currie, Viola Oorschot, and Hubrecht Institute for Developmental Biology and Stem Cell Research

Subjects

0301 basic medicine, Male, Nicotinamide phosphoribosyltransferase, Inbred C57BL, Myoblasts, chemistry.chemical_compound, Mice, 0302 clinical medicine, Single-cell analysis, Receptors, Myocyte, Macrophage, PAX7 Transcription Factor/metabolism, RNA-Seq, Stem Cell Niche, Nicotinamide Phosphoribosyltransferase, Zebrafish, Receptors, CCR5/genetics, Multidisciplinary, PAX7 Transcription Factor, Matrix Metalloproteinase 9/genetics, Cell biology, medicine.anatomical_structure, Matrix Metalloproteinase 9, Skeletal/cytology, 030220 oncology & carcinogenesis, Muscle, Zebrafish/immunology, Stem cell, Single-Cell Analysis, Regeneration/physiology, Receptors, CCR5, Nicotinamide Phosphoribosyltransferase/genetics, Biology, 03 medical and health sciences, medicine, Regeneration, Animals, Humans, Progenitor cell, Muscle, Skeletal, Cell Proliferation, Innate immune system, Animal, Macrophages, Skeletal muscle, Macrophages/cytology, CCR5/genetics, Mice, Inbred C57BL, Disease Models, Animal, 030104 developmental biology, chemistry, Muscle, Skeletal/cytology, Disease Models, Myoblasts/cytology

Abstract

Skeletal muscle regenerates through the activation of resident stem cells. Termed satellite cells, these normally quiescent cells are induced to proliferate by wound-derived signals1. Identifying the source and nature of these cues has been hampered by an inability to visualize the complex cell interactions that occur within the wound. Here we use muscle injury models in zebrafish to systematically capture the interactions between satellite cells and the innate immune system after injury, in real time, throughout the repair process. This analysis revealed that a specific subset of macrophages 'dwell' within the injury, establishing a transient but obligate niche for stem cell proliferation. Single-cell profiling identified proliferative signals that are secreted by dwelling macrophages, which include the cytokine nicotinamide phosphoribosyltransferase (Nampt, which is also known as visfatin or PBEF in humans). Nampt secretion from the macrophage niche is required for muscle regeneration, acting through the C-C motif chemokine receptor type 5 (Ccr5), which is expressed on muscle stem cells. This analysis shows that in addition to their ability to modulate the immune response, specific macrophage populations also provide a transient stem-cell-activating niche, directly supplying proliferation-inducing cues that govern the repair process that is mediated by muscle stem cells. This study demonstrates that macrophage-derived niche signals for muscle stem cells, such as NAMPT, can be applied as new therapeutic modalities for skeletal muscle injury and disease.

Published

2021

7. Effect of Ataluren on dystrophin mutations

Author

Silke Berger, Jeanette Rientjes, Joachim Berger, Michelle Meilak, Peter D. Currie, and Mei Li

Subjects

Duchenne muscular dystrophy, musculoskeletal diseases, 0301 basic medicine, muscle, PTC124, Mutant, Pharmacology, dystrophin, 03 medical and health sciences, chemistry.chemical_compound, Ataluren, 0302 clinical medicine, Animals, Protein Isoforms, Medicine, RNA, Messenger, Muscle, Skeletal, Zebrafish, Oxadiazoles, biology, business.industry, Homozygote, Translation (biology), Exons, Original Articles, Cell Biology, zebrafish, medicine.disease, biology.organism_classification, Dystrophin gene, Stop codon, Phenotype, 030104 developmental biology, chemistry, Codon, Nonsense, 030220 oncology & carcinogenesis, Mutation, dmd, biology.protein, Molecular Medicine, Original Article, business, Dystrophin

Abstract

Duchenne muscular dystrophy is a severe muscle wasting disease caused by mutations in the dystrophin gene (dmd). Ataluren has been approved by the European Medicines Agency for treatment of Duchenne muscular dystrophy. Ataluren has been reported to promote ribosomal read‐through of premature stop codons, leading to restoration of full‐length dystrophin protein. However, the mechanism of Ataluren action has not been fully described. To evaluate the efficacy of Ataluren on all three premature stop codons featuring different termination strengths (UAA > UAG > UGA), novel dystrophin‐deficient zebrafish were generated. Pathological assessment of the muscle by birefringence quantification, a tool to directly measure muscle integrity, did not reveal a significant effect of Ataluren on any of the analysed dystrophin‐deficient mutants at 3 days after fertilization. Functional analysis of the musculature at 6 days after fertilization by direct measurement of the generated force revealed a significant improvement by Ataluren only for the UAA‐carrying mutant dmdta222a. Interestingly however, all other analysed dystrophin‐deficient mutants were not affected by Ataluren, including the dmdpc3 and dmdpc2 mutants that harbour weaker premature stop codons UAG and UGA, respectively. These in vivo results contradict reported in vitro data on Ataluren efficacy, suggesting that Ataluren might not promote read‐through of premature stop codons. In addition, Ataluren had no effect on dystrophin transcript levels, but mild adverse effects on wild‐type larvae were identified. Further assessment of N‐terminally truncated dystrophin opened the possibility of Ataluren promoting alternative translation codons within dystrophin, thereby potentially shifting the patient cohort applicable for Ataluren.

Published

2020

8. Examining Muscle Regeneration in Zebrafish Models of Muscle Disease

Author

Avnika A. Ruparelia, Peter D. Currie, and Margo Montandon

Subjects

0301 basic medicine, Embryo, Nonmammalian, Genotype, General Chemical Engineering, Biology, General Biochemistry, Genetics and Molecular Biology, 03 medical and health sciences, 0302 clinical medicine, Muscular Diseases, medicine, Myocyte, Animals, Regeneration, Muscular dystrophy, Myopathy, Muscle, Skeletal, Zebrafish, General Immunology and Microbiology, Regeneration (biology), General Neuroscience, Skeletal muscle, biology.organism_classification, medicine.disease, Cell biology, Disease Models, Animal, 030104 developmental biology, medicine.anatomical_structure, 030220 oncology & carcinogenesis, Larva, Laminin, medicine.symptom, Stem cell, Developmental biology

Abstract

Skeletal muscle has a remarkable ability to regenerate following injury, which is driven by obligate tissue resident muscle stem cells. Following injury, the muscle stem cell is activated and undergoes cell proliferation to generate a pool of myoblasts, which subsequently differentiate to form new muscle fibers. In many muscle wasting conditions, including muscular dystrophy and ageing, this process is impaired resulting in the inability of muscle to regenerate. The process of muscle regeneration in zebrafish is highly conserved with mammalian systems providing an excellent system to study muscle stem cell function and regeneration, in muscle wasting conditions such as muscular dystrophy. Here, we present a method to examine muscle regeneration in zebrafish models of muscle disease. The first step involves the use of a genotyping platform that allows the determination of the genotype of the larvae prior to eliciting an injury. Having determined the genotype, the muscle is injured using a needle stab, following which polarizing light microscopy is used to determine the extent of muscle regeneration. We therefore provide a high throughput pipeline which allows the examination of muscle regeneration in zebrafish models of muscle disease.

Published

2021

9. Machine learning discriminates a movement disorder in a zebrafish model of Parkinson's disease

Author

Matthew Bedder, Stephen L. Smith, Gideon L. Hughes, Peter D. Currie, Michael A. Lones, and Mary Elizabeth Pownall

Subjects

Parkinson's disease, Movement disorders, Protein Deglycase DJ-1, Medicine (miscellaneous), lcsh:Medicine, computer.software_genre, gene targeting, Machine Learning, Immunology and Microbiology (miscellaneous), Genome editing, CRISPR, Zebrafish, Movement Disorders, biology, Brain, Gene targeting, Parkinson Disease, artificial intelligence, dj-1, medicine.symptom, Algorithms, Research Article, lcsh:RB1-214, Movement, Neuroscience (miscellaneous), Machine learning, General Biochemistry, Genetics and Molecular Biology, medicine, lcsh:Pathology, Animals, Alleles, park7, Base Sequence, Cas9, business.industry, Dopaminergic Neurons, Gene Expression Profiling, lcsh:R, PARK7, video capture, Zebra, medicine.disease, biology.organism_classification, Disease Models, Animal, Mutation, parkinson's disease, Artificial intelligence, business, computer

Abstract

Animal models of human disease provide an in vivo system that can reveal molecular mechanisms by which mutations cause pathology, and, moreover, have the potential to provide a valuable tool for drug development. Here, we have developed a zebrafish model of Parkinson's disease (PD) together with a novel method to screen for movement disorders in adult fish, pioneering a more efficient drug-testing route. Mutation of the PARK7 gene (which encodes DJ-1) is known to cause monogenic autosomal recessive PD in humans, and, using CRISPR/Cas9 gene editing, we generated a Dj-1 loss-of-function zebrafish with molecular hallmarks of PD. To establish whether there is a human-relevant parkinsonian phenotype in our model, we adapted proven tools used to diagnose PD in clinics and developed a novel and unbiased computational method to classify movement disorders in adult zebrafish. Using high-resolution video capture and machine learning, we extracted novel features of movement from continuous data streams and used an evolutionary algorithm to classify parkinsonian fish. This method will be widely applicable for assessing zebrafish models of human motor diseases and provide a valuable asset for the therapeutics pipeline. In addition, interrogation of RNA-seq data indicate metabolic reprogramming of brains in the absence of Dj-1, adding to growing evidence that disruption of bioenergetics is a key feature of neurodegeneration. This article has an associated First Person interview with the first author of the paper., Summary: Using computational analyses to harness artificial intelligence, we have tested a genetic model of Parkinson's disease and reveal a distinct movement phenotype in adult zebrafish lacking Dj-1.

Published

2020

10. Macrophages provide a transient muscle stem cell niche via NAMPT secretion

Author

Thomas Boudier, Mikaël M. Martino, Graham J. Lieschke, Laura A. Galvis, Phong D. Nguyen, Jeroen Bakkers, Abdulsalam I. Isiaku, Verena C. Wimmer, Kelly L. Rogers, Christophe Marcelle, Fernando J. Rossello, Ziad Julier, Dhanushika Ratnayake, A.J. Wood, Viola Oorschot, and Peter D. Currie

Subjects

medicine.medical_treatment, Cell, Nicotinamide phosphoribosyltransferase, Skeletal muscle, Biology, biology.organism_classification, Cell biology, chemistry.chemical_compound, Chemokine receptor, medicine.anatomical_structure, Cytokine, chemistry, medicine, Secretion, Stem cell, Zebrafish

Abstract

Skeletal muscle is paradigmatic of a regenerative tissue that repairs itself via the activation of a resident stem cell1. Termed the satellite cell, these normally quiescent cells are induced to proliferate by ill-defined wound-derived signals2. Identifying the source and nature of these pro-regenerative cues has been hampered by an inability to visualise the complex cellular interactions that occur within the wound environment. We therefore developed a zebrafish muscle injury model to systematically capture satellite cell interactions within the injury site, in real time, throughout the repair process. This analysis identified that a specific subset of macrophages ‘dwells’ within the injury, establishing a transient but obligate stem cell niche required for stem cell proliferation. Single cell profiling identified specific signals secreted from dwelling macrophages that include the cytokine, Nicotinamide phosphoribosyltransferase (NAMPT/Visfatin/PBEF). Here we show that NAMPT secretion from the macrophage niche is required for muscle regeneration, acting through the C-C motif chemokine receptor type 5 (CCR5) expressed on muscle stem cells. This analysis reveals that along with their well-described ability to modulate the pro-inflammatory and anti-inflammatory phases of wound repair, specific macrophage populations also provide a transient stem cell-activating niche, directly supplying pro-proliferative cues that govern the timing and rate of muscle stem cell-mediated repair processes.

Published

2020

11. A Low-Cost Pulse Generator for Exacerbating Muscle Fiber Detachment Phenotypes in Zebrafish

Author

Carmen Sonntag, Danilo Fernandes Pires, A.J. Wood, Ana Beatriz Delavia Thomasi, Antonio L Benci, Peter D. Currie, and David A Zuidema

Subjects

0301 basic medicine, Bioelectric Energy Sources, Muscle Fibers, Skeletal, 030105 genetics & heredity, Biology, Animals, Genetically Modified, 03 medical and health sciences, Laminin, medicine, Animals, Myotendinous junction, Muscle fibre, Muscular dystrophy, Zebrafish, Pulse generator, Muscular Dystrophy, Animal, Zebrafish Proteins, biology.organism_classification, medicine.disease, Phenotype, Electric Stimulation, Cell biology, Tendon, 030104 developmental biology, medicine.anatomical_structure, Larva, Mutation, biology.protein, Animal Science and Zoology, Developmental Biology

Abstract

Muscle fiber detachment from myoseptal boundaries is a common finding in zebrafish models of muscular dystrophies. In some instances, there is a weakening of the interaction between muscle fiber and myosepta, which is yet to manifest as a fiber detachment phenotype. Therefore, to push the fiber detachment of muscle, mutant fish but not their wild-type siblings, beyond their binding threshold, a series of small electrical pulses can be applied to the larvae to create a maximal force contraction and ultimately fiber detachment. To do this, we built a digital pulse generator which delivers four 8 ms 30 V pulses in quick succession, and it has the advantage over older analog approaches to pulse generation because it improves accuracy and is appreciably less expensive. Our pulse generator significantly increases fiber detachment in the laminin-α2 deficient, congenital muscular dystrophy type 1a (MDC1a) model lama2

Published

2018

12. Phosphorylation of Lbx1 controls lateral myoblast migration into the limb

Author

Wouter Masselink, Megumi Masaki, Peter D. Currie, Christophe Marcelle, and Daniel Sieiro

Subjects

0301 basic medicine, Apical ectodermal ridge, medicine.medical_specialty, Fibroblast Growth Factor 8, PAX3, Chick Embryo, Biology, Myoblasts, Mice, Phosphoserine, 03 medical and health sciences, Limb bud, 0302 clinical medicine, Species Specificity, Cell Movement, Internal medicine, medicine, Animals, Humans, Myocyte, Limb development, Amino Acid Sequence, Myoblast migration, Phosphorylation, Extracellular Signal-Regulated MAP Kinases, Molecular Biology, Cells, Cultured, Zebrafish, Sequence Homology, Amino Acid, Extremities, Cell Biology, Zebrafish Proteins, Recombinant Proteins, Cell biology, body regions, 030104 developmental biology, Endocrinology, Somites, Zone of polarizing activity, Mutation, Homeobox, Protein Processing, Post-Translational, Sequence Alignment, 030217 neurology & neurosurgery, Transcription Factors, Developmental Biology

Abstract

The migration of limb myogenic precursors from limb level somites to their ultimate site of differentiation in the limb is a paradigmatic example of a set of dynamic and orchestrated migratory cell behaviours. The homeobox containing transcription factor ladybird homeobox 1 (Lbx1) is a central regulator of limb myoblast migration, null mutations of Lbx1 result in severe disruptions to limb muscle formation, particularly in the distal region of the limb in mice (Gross et al., 2000). As such Lbx1 has been hypothesized to control lateral migration of myoblasts into the distal limb anlage. It acts as a core regulator of the limb myoblast migration machinery, controlled by Pax3. A secondary role for Lbx1 in the differentiation and commitment of limb musculature has also been proposed (Brohmann et al., 2000; Uchiyama et al., 2000). Here we show that lateral migration, but not differentiation or commitment of limb myoblasts, is controlled by the phosphorylation of three adjacent serine residues of LBX1. Electroporation of limb level somites in the chick embryo with a dephosphomimetic form of Lbx1 results in a specific defect in the lateral migration of limb myoblasts. Although the initial delamination and migration of myoblasts is unaffected, migration into the distal limb bud is severely disrupted. Interestingly, myoblasts undergo normal differentiation independent of their migratory status, suggesting that the differentiation potential of hypaxial muscle is not regulated by the phosphorylation state of LBX1. Furthermore, we show that FGF8 and ERK mediated signal transduction, both critical regulators of the developing limb bud, have the capacity to induce the phosphorylation of LBX1 at these residues. Overall, this suggests a mechanism whereby the phosphorylation of LBX1, potentially through FGF8 and ERK signalling, controls the lateral migration of myoblasts into the distal limb bud.

Published

2017

13. Fate bias during neural regeneration adjusts dynamically without recapitulating developmental fate progression

Author

Jeremy Ng Chi Kei, Peter D. Currie, and Patricia R. Jusuf

Subjects

0301 basic medicine, Interkinetic nuclear migration, Ependymoglial Cells, Biology, Retina, lcsh:RC346-429, Neural regeneration, 03 medical and health sciences, Developmental Neuroscience, Neural Stem Cells, medicine, Animals, Cell Lineage, Zebrafish, lcsh:Neurology. Diseases of the nervous system, Neurons, Regeneration (biology), Cell Differentiation, biology.organism_classification, Neural stem cell, Nerve Regeneration, Fate specification, 030104 developmental biology, medicine.anatomical_structure, Neuron differentiation, Neuron, Muller glia, Developmental biology, Neuroscience, Fate bias, Research Article

Abstract

Background Regeneration of neurons in the central nervous system is poor in humans. In other vertebrates neural regeneration does occur efficiently and involves reactivation of developmental processes. Within the neural retina of zebrafish, Müller glia are the main stem cell source and are capable of generating progenitors to replace lost neurons after injury. However, it remains largely unknown to what extent Müller glia and neuron differentiation mirror development. Methods Following neural ablation in the zebrafish retina, dividing cells were tracked using a prolonged labelling technique. We investigated to what extent extrinsic feedback influences fate choices in two injury models, and whether fate specification follows the histogenic order observed in development. Results By comparing two injury paradigms that affect different subpopulations of neurons, we found a dynamic adaptability of fate choices during regeneration. Both injuries followed a similar time course of cell death, and activated Müller glia proliferation. However, these newly generated cells were initially biased towards replacing specifically the ablated cell types, and subsequently generating all cell types as the appropriate neuron proportions became re-established. This dynamic behaviour has implications for shaping regenerative processes and ensuring restoration of appropriate proportions of neuron types regardless of injury or cell type lost. Conclusions Our findings suggest that regenerative fate processes are more flexible than development processes. Compared to development fate specification we observed a disruption in stereotypical birth order of neurons during regeneration Understanding such feedback systems can allow us to direct regenerative fate specification in injury and diseases to regenerate specific neuron types in vivo.

Published

2017

14. Development Aspects of Zebrafish Myotendinous Junction: a Model System for Understanding Muscle Basement Membrane Formation and Failure

Author

Peter D. Currie and A.J. Wood

Subjects

0301 basic medicine, Basement membrane, Cancer Research, biology, Context (language use), Cell Biology, Anatomy, biology.organism_classification, medicine.disease, Pathology and Forensic Medicine, 03 medical and health sciences, 030104 developmental biology, 0302 clinical medicine, medicine.anatomical_structure, Development aspects, Somitogenesis, medicine, Myotendinous junction, Muscular dystrophy, Molecular Biology, Zebrafish, Process (anatomy), Neuroscience, 030217 neurology & neurosurgery

Abstract

The muscle is separated from tendons by a specialised basement membrane that acts as the structural interface of the myotendinous junction (MTJ). In zebrafish, the larval MTJ forms at the vertical myosepta, which separate the individual myomeres that arise during somitogenesis. In this review, we examine the formation of the vertical myosepta in zebrafish. We then describe insights this gains us in the context of muscle basement membrane failure, the mechanistic basis of the inherited muscle wasting condition muscular dystrophy (MD). We examine recent manuscripts that investigate how a well-orchestrated integration of MTJ components is needed during vertical myosepta development. We find the process can be divided into three stereotypical stages of its development based on specific structural properties of the developing basement membrane. This review highlights insights that have been gleaned from vertical myosepta formation in zebrafish that maybe of value in developing therapeutic strategies for MD.

Published

2017

15. In vivo expression of Nurr1/Nr4a2a in developing retinal amacrine subtypes in zebrafishTg(nr4a2a:eGFP)transgenics

Author

Jie He, Patricia R. Jusuf, Peter D. Currie, William A. Harris, A.J. Wood, and Liana Maree Goodings

Subjects

0301 basic medicine, Regulation of gene expression, Retina, biology, General Neuroscience, Cellular differentiation, Neurogenesis, In situ hybridization, biology.organism_classification, Cell biology, Gene expression profiling, 03 medical and health sciences, 030104 developmental biology, 0302 clinical medicine, medicine.anatomical_structure, Gene expression, medicine, Zebrafish, 030217 neurology & neurosurgery

Abstract

The Nuclear receptor subfamily 4 group A member 2 (Nr4a2) is crucial for the formation or maintenance of dopaminergic neurons in the central nervous system including the retina, where dopaminergic amacrine cells contribute to visual function. Little is known about which cells express Nr4a2 at which developmental stage. Furthermore, whether Nr4a2 functions in combination with other genes is poorly understood. Thus, we generated a novel transgenic to visualize Nr4a2 expression in vivo during zebrafish retinogenesis. A 4.1 kb fragment of the nr4a2a promoter was used to drive green fluorescent protein expression in this Tg(nr4a2a:eGFP) line. In situ hybridization showed that transgene expression follows endogenous RNA expression at a cellular level. Temporal expression and lineages were quantified using in vivo time-lapse imaging in embryos. Nr4a2 expressing retinal subtypes were characterized immunohistochemically. Nr4a2a:eGFP labeled multiple neuron subtypes including 24.5% of all amacrine interneurons. Nr4a2a:eGFP labels all tyrosine hydroxylase labeled dopaminergic amacrine cells, and other nondopaminergic GABAergic amacrine populations. Nr4a2a:eGFP is confined to a specific progenitor lineage identified by sequential expression of the bhlh transcription factor Atonal7 (Atoh7) and Pancreas transcription factor 1a (Ptf1a), and labels postmitotic postmigratory amacrine cells. Thus, developmental Nr4a2a expression indicates a role during late differentiation of specific amacrine interneurons. Tg(nr4a2a:eGFP) is an early marker of distinct neurons including dopaminergic amacrine cells. It can be utilized to assess consequences of gene manipulations and understand whether Nr4a2 only carries out its role in the presence of specific coexpressed genes. This will allow Nr4a2 use to be refined for regenerative approaches.

Published

2017

16. Stem cells in skeletal muscle growth and regeneration in amniotes and teleosts: Emerging themes

Author

Dhanushika Ratnayake, Avnika A. Ruparelia, and Peter D. Currie

Subjects

Organogenesis, Biology, Muscle Development, Muscle hypertrophy, 03 medical and health sciences, 0302 clinical medicine, biology.animal, medicine, Animals, Regeneration, Muscle, Skeletal, Molecular Biology, Process (anatomy), 030304 developmental biology, Mammals, 0303 health sciences, Stem Cells, Regeneration (biology), Fishes, Skeletal muscle, Vertebrate, Cell Differentiation, Cell Biology, Cell biology, medicine.anatomical_structure, Stem cell, 030217 neurology & neurosurgery, Developmental Biology, Adult stem cell

Abstract

Skeletal muscle is a contractile, postmitotic tissue that retains the capacity to grow and regenerate throughout life in amniotes and teleost. Both muscle growth and regeneration are regulated by obligate tissue resident muscle stem cells. Given that considerable knowledge exists on the myogenic process, recent studies have focused on examining the molecular markers of muscle stem cells, and on the intrinsic and extrinsic signals regulating their function. From this, two themes emerge: firstly, muscle stem cells display remarkable heterogeneity not only with regards to their gene expression profile, but also with respect to their behavior and function; and secondly, the stem cell niche is a critical regulator of muscle stem cell function during growth and regeneration. Here, we will address the current understanding of these emerging themes with emphasis on the distinct processes used by amniotes and teleost, and discuss the challenges and opportunities in the muscle growth and regeneration fields. This article is characterized under: Adult Stem Cells, Tissue Renewal, and Regeneration > Tissue Stem Cells and Niches Early Embryonic Development > Development to the Basic Body Plan Vertebrate Organogenesis > Musculoskeletal and Vascular.

Published

2019

17. Cellular rescue in a zebrafish model of congenital muscular dystrophy type 1A

Author

Nicholas J. Cole, Ophelia V. Ehrlich, Thomas E. Hall, Inken G. Huttner, Tamar E. Sztal, Mei Li, Carmen Sonntag, A.J. Wood, and Peter D. Currie

Subjects

0301 basic medicine, Programmed cell death, Cell type, Cell, Biomedical Engineering, Medicine (miscellaneous), lcsh:Medicine, Diseases, Article, 03 medical and health sciences, 0302 clinical medicine, Laminin, medicine, Genetics, Myocyte, Zebrafish, biology, lcsh:R, Skeletal muscle, Cell Biology, biology.organism_classification, medicine.disease, Cell biology, 030104 developmental biology, medicine.anatomical_structure, biology.protein, Congenital muscular dystrophy, 030217 neurology & neurosurgery, Developmental Biology

Abstract

Laminins comprise structural components of basement membranes, critical in the regulation of differentiation, survival and migration of a diverse range of cell types, including skeletal muscle. Mutations in one muscle enriched Laminin isoform, Laminin alpha2 (Lama2), results in the most common form of congenital muscular dystrophy, congenital muscular dystrophy type 1A (MDC1A). However, the exact cellular mechanism by which Laminin loss results in the pathological spectrum associated with MDC1A remains elusive. Here we show, via live tracking of individual muscle fibres, that dystrophic myofibres in the zebrafish model of MDC1A maintain sarcolemmal integrity and undergo dynamic remodelling behaviours post detachment, including focal sarcolemmal reattachment, cell extension and hyper-fusion with surrounding myoblasts. These observations imply the existence of a window of therapeutic opportunity, where detached cells may be “re-functionalised” prior to their delayed entry into the cell death program, a process we show can be achieved by muscle specific or systemic Laminin delivery. We further reveal that Laminin also acts as a pro-regenerative factor that stimulates muscle stem cell-mediated repair in lama2-deficient animals in vivo. The potential multi-mode of action of Laminin replacement therapy suggests it may provide a potent therapeutic axis for the treatment for MDC1A.

Published

2019

18. Photoreceptor ablation following ATP induced injury triggers Müller glia driven regeneration in zebrafish

Author

Patricia R. Jusuf, Stefanie Dudczig, Alice Brandli, and Peter D. Currie

Subjects

Male, Retinal Ganglion Cells, 0301 basic medicine, Retinal degeneration, Ependymoglial Cells, Apoptosis, 03 medical and health sciences, Cellular and Molecular Neuroscience, chemistry.chemical_compound, Adenosine Triphosphate, 0302 clinical medicine, Retinal Rod Photoreceptor Cells, In Situ Nick-End Labeling, medicine, Animals, Zebrafish, Cell Proliferation, Retinal regeneration, Retina, biology, Regeneration (biology), Retinal Degeneration, Retinal, biology.organism_classification, medicine.disease, Sensory Systems, Nerve Regeneration, Cell biology, Disease Models, Animal, Ophthalmology, 030104 developmental biology, medicine.anatomical_structure, chemistry, Intravitreal Injections, 030221 ophthalmology & optometry, Female, Neuroglia, Muller glia

Abstract

Retinal regeneration research offers hope to people affected by visual impairment due to disease and injury. Ongoing research has explored many avenues towards retinal regeneration, including those that utilizes implantation of devices, cells or targeted viral-mediated gene therapy. These results have so far been limited, as gene therapy only has applications for rare single-gene mutations and implantations are invasive and in the case of cell transplantation donor cells often fail to integrate with adult neurons. An alternative mode of retinal regeneration utilizes a stem cell population unique to vertebrate retina - Müller glia (MG). Endogenous MG can readily regenerate lost neurons spontaneously in zebrafish and to a very limited extent in mammalian retina. The use of adenosine triphosphate (ATP) has been shown to induce retinal degeneration and activation of the MG in mammals, but whether this is conserved to other vertebrate species including those with higher regenerative capacity remains unknown. In our study, we injected a single dose of ATP intravitreal in zebrafish to characterize the cell death and MG induced regeneration. We used TUNEL labelling on retinal sections to show that ATP caused localised death of photoreceptors and ganglion cells within 24 h. Histology of GFP-transgenic zebrafish and BrdU injected fish demonstrated that MG proliferation peaked at days 3 and 4 post-ATP injection. Using BrdU labelling and photoreceptor markers (Zpr1) we observed regeneration of lost rod photoreceptors at day 14. This study has been undertaken to allow for comparative studies between mammals and zebrafish that use the same specific induction method of injury, i.e. ATP induced injury to allow for direct comparison of across species to narrow down resulting differences that might reflect the differing regenerative capacity. The ultimate aim of this work is to recapitulate pro-neurogenesis Müller glia signaling in mammals to produce new neurons that integrate with the existing retinal circuit to restore vision.

Published

2021

19. Muscle precursor cell movements in zebrafish are dynamic and require six-family genes

Author

Sharon L. Amacher, Phan Q. Duy, Jared C. Talbot, Dhanushika Ratnayake, Peter D. Currie, and Emily M Teets

Subjects

Flexibility (anatomy), Retinoic acid, Motility, Biology, 03 medical and health sciences, chemistry.chemical_compound, 0302 clinical medicine, Precursor cell, medicine, Animals, Muscle, Skeletal, Molecular Biology, Zebrafish, 030304 developmental biology, 0303 health sciences, Embryogenesis, Gene Expression Regulation, Developmental, Skeletal muscle, Body movement, Zebrafish Proteins, biology.organism_classification, Cell biology, medicine.anatomical_structure, Somites, chemistry, 030217 neurology & neurosurgery, Research Article, Signal Transduction, Developmental Biology

Abstract

Muscle precursors need to be correctly positioned during embryonic development for proper body movement. In zebrafish, a subset of hypaxial muscle precursors from the anterior somites undergo long-range migration, moving away from the trunk in three streams to form muscles in distal locations such as the fin. We mapped long-distance muscle precursor migrations with unprecedented resolution using live imaging. We identified conserved genes necessary for normal precursor motility ( six1a , six1b , six4a , six4b and met ). These genes are required for movement away from somites and later to partition two muscles within the fin bud. During normal development, the middle muscle precursor stream initially populates the fin bud, then the remainder of this stream contributes to the posterior hypaxial muscle. When we block fin bud development by impairing retinoic acid synthesis or Fgfr function, the entire stream contributes to the posterior hypaxial muscle indicating that muscle precursors are not committed to the fin during migration. Our findings demonstrate a conserved muscle precursor motility pathway, identify dynamic cell movements that generate posterior hypaxial and fin muscles, and demonstrate flexibility in muscle precursor fates.

Published

2019

20. Guidelines and best practices in successfully using Zebrabow for lineage tracing multiple cells within tissues

Author

Peter D. Currie and Phong D. Nguyen

Subjects

0301 basic medicine, Embryo, Nonmammalian, Guidelines as Topic, Computational biology, Neural tissues, Lineage tracing, Biochemistry, General Biochemistry, Genetics and Molecular Biology, Imaging, Animals, Genetically Modified, 03 medical and health sciences, Genes, Reporter, Labelling, medicine, Brainbow, Animals, Cell Lineage, Zebrafish, Molecular Biology, biology, Integrases, Staining and Labeling, Biochemistry, Genetics and Molecular Biology(all), biology.organism_classification, Luminescent Proteins, 030104 developmental biology, medicine.anatomical_structure, Zebrabow, Cell Tracking, Models, Animal, Genetics and Molecular Biology(all)

Abstract

Labelling cells and following their progeny, also known as lineage tracing, has provided important insights into the cellular origins of tissues. Traditional lineage tracing experiments have been limited to following single or small groups of cells with classic techniques such as dye injections and Cre/LoxP labelling of cells of interest. Brainbow is a fluorescent dependent, lineage tracing technique that allows a broader visualization and analysis of multiple cells within a tissue, initially deployed to examine lineages within neural tissues. This technique has now been adapted to zebrafish (Zebrabow) and takes advantages of the imaging capabilities that this system provides over other animal models. In this paper we shall describe how Zebrabow is performed as well as some guides on some of the common pitfalls encountered when using this labelling strategy.

Published

2018

21. Fluorescence-Activated Cell Sorting of Larval Zebrafish Muscle Stem/Progenitor Cells Following Skeletal Muscle Injury

Author

Dhanushika Ratnayake and Peter D. Currie

Subjects

0301 basic medicine, Cell type, Regeneration (biology), fungi, RNA, Skeletal muscle, Cell sorting, Biology, Embryonic stem cell, Cell biology, 03 medical and health sciences, 030104 developmental biology, 0302 clinical medicine, medicine.anatomical_structure, Real-time polymerase chain reaction, medicine, Progenitor cell, 030217 neurology & neurosurgery

Abstract

This chapter describes a protocol for the isolation of larval zebrafish muscle stem/progenitor cells by fluorescence-activated cell sorting (FACS). This method has been successfully applied to isolate pax3a expressing cells 3 days following needle stab skeletal muscle injury. The cell sorting strategy described here can easily be adapted to any cell type at embryonic or larval stages. RNA extracted from the sorted cells can be used for subsequent downstream applications such as quantitative PCR (qPCR), microarrays, or next generation sequencing.

Published

2018

22. Different Fgfs have distinct roles in regulating neurogenesis after spinal cord injury in zebrafish

Author

Patricia R. Jusuf, Ashley L. Siegel, Phong D. Nguyen, Jean Kitty K. Y. Tang, Peter D. Currie, Jan Kaslin, and Yona Goldshmit

Subjects

0301 basic medicine, Motor neuron, Neurite, Fgf3, Neurogenesis, Fgf2, Biology, Fibroblast growth factor, Axonogenesis, lcsh:RC346-429, Fgf8, Animals, Genetically Modified, Neural regeneration, 03 medical and health sciences, Developmental Neuroscience, medicine, Animals, Zebrafish, C-met, lcsh:Neurology. Diseases of the nervous system, Spinal Cord Injuries, Cell Proliferation, Motor Neurons, Zebrafish Proteins, biology.organism_classification, Islet 1, Nerve Regeneration, Fibroblast Growth Factors, 030104 developmental biology, medicine.anatomical_structure, Spinal Cord, Neuron, Neural development, Neuroscience, Neuroglia, Signal Transduction, Research Article

Abstract

Background Despite conserved developmental processes and organization of the vertebrate central nervous system, only some vertebrates including zebrafish can efficiently regenerate neural damage including after spinal cord injury. The mammalian spinal cord shows very limited regeneration and neurogenesis, resulting in permanent life-long functional impairment. Therefore, there is an urgent need to identify the cellular and molecular mechanisms that can drive efficient vertebrate neurogenesis following injury. A key pathway implicated in zebrafish neurogenesis is fibroblast growth factor signaling. Methods In the present study we investigated the roles of distinct fibroblast growth factor members and their receptors in facilitating different aspects of neural development and regeneration at different timepoints following spinal cord injury. After spinal cord injury in adults and during larval development, loss and/or gain of Fgf signaling was combined with immunohistochemistry, in situ hybridization and transgenes marking motor neuron populations in in vivo zebrafish and in vitro mammalian PC12 cell culture models. Results Fgf3 drives neurogenesis of Islet1 expressing motor neuron subtypes and mediate axonogenesis in cMet expressing motor neuron subtypes. We also demonstrate that the role of Fgf members are not necessarily simple recapitulating development. During development Fgf2, Fgf3 and Fgf8 mediate neurogenesis of Islet1 expressing neurons and neuronal sprouting of both, Islet1 and cMet expressing motor neurons. Strikingly in mammalian PC12 cells, all three Fgfs increased cell proliferation, however, only Fgf2 and to some extent Fgf8, but not Fgf3 facilitated neurite outgrowth. Conclusions This study demonstrates differential Fgf member roles during neural development and adult regeneration, including in driving neural proliferation and neurite outgrowth of distinct spinal cord neuron populations, suggesting that factors including Fgf type, age of the organism, timing of expression, requirements for different neuronal populations could be tailored to best drive all of the required regenerative processes.

Published

2018

23. Skeletal malformations of Meox1-deficient zebrafish resemble human Klippel-Feil syndrome

Author

Joachim Berger, Mervyn V. P. Dauer, and Peter D. Currie

Subjects

0301 basic medicine, Pathology, medicine.medical_specialty, Histology, Klippel–Feil syndrome, Spinal disease, Bone and Bones, Animals, Genetically Modified, 03 medical and health sciences, Gene Knockout Techniques, 0302 clinical medicine, Vertebral fusion, Scapula, medicine, Deformity, Animals, Humans, Molecular Biology, Zebrafish, Ecology, Evolution, Behavior and Systematics, Homeodomain Proteins, biology, business.industry, Cell Biology, Original Articles, Zebrafish Proteins, medicine.disease, biology.organism_classification, Disease Models, Animal, 030104 developmental biology, medicine.anatomical_structure, Klippel-Feil Syndrome, Anatomy, medicine.symptom, business, 030217 neurology & neurosurgery, Vertebral column, Developmental Biology, Cervical vertebrae

Abstract

Klippel–Feil syndrome is a congenital vertebral anomaly, which is characterised by the fusion of at least two cervical vertebrae and a clinically broad set of symptoms, including congenital scoliosis and elevated scapula (Sprengel's deformity). Klippel–Feil syndrome is associated with mutations in MEOX1. The zebrafish mutant choker (cho) carries a mutation in its orthologue, meox1. Although zebrafish is being increasingly employed as fidelitous models of human spinal disease, the vertebral column of Meox1‐deficient fish has not been assessed for defects. Here, we describe the skeletal defects of meox1 (cho) mutant zebrafish utilising alizarin red to stain bones and chemical maceration of soft tissue to detect fusions in an unbiased manner. Obtained data reveal that meox1 (cho) mutants feature aspects of a number of described symptoms of patients who suffer from Klippel–Feil syndrome and have mutations in MEOX1. These include vertebral fusion, congenital scoliosis and an asymmetry of the pectoral girdle, which resembles Sprengel's deformity. Thus, the meox1 (cho) mutant zebrafish may serve as a useful tool to study the pathogenesis of the symptoms associated with Klippel–Feil syndrome.

Published

2018

24. RGD inhibition of itgb1 ameliorates laminin-α2-deficient zebrafish fibre pathology

Author

Carmen Sonntag, Lee B. Miles, Naomi Cohen, Emily A McKaige, Ashley L. Siegel, Adam Costin, A.J. Wood, Lucy Hersey, Veronica Joshi, Mei Li, Jessica D Manneken, and Peter D. Currie

Subjects

0301 basic medicine, Pathology, medicine.medical_specialty, Mutant, Integrin, Muscle Fibers, Skeletal, Basement Membrane, Muscular Dystrophies, Extracellular matrix, 03 medical and health sciences, 0302 clinical medicine, Laminin, Genetics, medicine, Dystroglycan, Animals, Cell adhesion, Molecular Biology, Zebrafish, Genetics (clinical), Basement membrane, Mice, Knockout, biology, Protein Stability, Integrin beta1, General Medicine, biology.organism_classification, Immunohistochemistry, Disease Models, Animal, 030104 developmental biology, medicine.anatomical_structure, Phenotype, Genetic Loci, biology.protein, Collagen, Disease Susceptibility, Oligopeptides, 030217 neurology & neurosurgery, Biomarkers

Abstract

Deficiency of muscle basement membrane (MBM) component laminin-α2 leads to muscular dystrophy congenital type 1A (MDC1A), a currently untreatable myopathy. Laminin--α2 has two main binding partners within the MBM, dystroglycan and integrin. Integrins coordinate both cell adhesion and signalling; however, there is little mechanistic insight into integrin's function at the MBM. In order to study integrin's role in basement membrane development and how this relates to the MBM's capacity to handle force, an itgβ1.b-/- zebrafish line was created. Histological examination revealed increased extracellular matrix (ECM) deposition at the MBM in the itgβ1.b-/- fish when compared with controls. Surprisingly, both laminin and collagen proteins were found to be increased in expression at the MBM of the itgβ1.b-/- larvae when compared with controls. This increase in ECM components resulted in a decrease in myotomal elasticity as determined by novel passive force analyses. To determine if it was possible to control ECM deposition at the MBM by manipulating integrin activity, RGD peptide, a potent inhibitor of integrin-β1, was injected into a zebrafish model of MDC1A. As postulated an increase in laminin and collagen was observed in the lama2-/- mutant MBM. Importantly, there was also an improvement in fibre stability at the MBM, judged by a reduction in fibre pathology. These results therefore show that blocking ITGβ1 signalling increases ECM deposition at the MBM, a process that could be potentially exploited for treatment of MDC1A.

Published

2018

25. Developmental and adult characterization of secretagogin expressing amacrine cells in zebrafish retina

Author

Patricia R. Jusuf, Stefanie Dudczig, and Peter D. Currie

Subjects

0301 basic medicine, Central Nervous System, lcsh:Medicine, Calbindin, Nervous System, 0302 clinical medicine, Animal Cells, Calcium-binding protein, Medicine and Health Sciences, Enzyme-Linked Immunoassays, lcsh:Science, Zebrafish, Neurons, education.field_of_study, Multidisciplinary, Gene Expression Regulation, Developmental, Eukaryota, Cell Differentiation, Animal Models, Cell biology, medicine.anatomical_structure, Experimental Organism Systems, Osteichthyes, Inner nuclear layer, Vertebrates, Calretinin, Anatomy, Cellular Types, SECRETAGOGIN, Neuronal Differentiation, Research Article, Ocular Anatomy, Population, Biology, Research and Analysis Methods, Retina, 03 medical and health sciences, Model Organisms, Ocular System, medicine, Animals, education, Immunoassays, Immunohistochemistry Techniques, lcsh:R, Organisms, Biology and Life Sciences, Cell Biology, Inner plexiform layer, Histochemistry and Cytochemistry Techniques, 030104 developmental biology, Amacrine Cells, Fish, nervous system, Cellular Neuroscience, Immunologic Techniques, lcsh:Q, 030217 neurology & neurosurgery, Secretagogins, Neuroscience, Developmental Biology

Abstract

Calcium binding proteins show stereotypical expression patterns within diverse neuron types across the central nervous system. Here, we provide a characterization of developmental and adult secretagogin-immunolabelled neurons in the zebrafish retina with an emphasis on co-expression of multiple calcium binding proteins. Secretagogin is a recently identified and cloned member of the F-hand family of calcium binding proteins, which labels distinct neuron populations in the retinas of mammalian vertebrates. Both the adult distribution of secretagogin labeled retinal neurons as well as the developmental expression indicative of the stage of neurogenesis during which this calcium binding protein is expressed was quantified. Secretagogin expression was confined to an amacrine interneuron population in the inner nuclear layer, with monostratified neurites in the center of the inner plexiform layer and a relatively regular soma distribution (regularity index > 2.5 across central-peripheral areas). However, only a subpopulation (~60%) co-labeled with gamma-aminobutyric acid as their neurotransmitter, suggesting that possibly two amacrine subtypes are secretagogin immunoreactive. Quantitative co-labeling analysis with other known amacrine subtype markers including the three main calcium binding proteins parvalbumin, calbindin and calretinin identifies secretagogin immunoreactive neurons as a distinct neuron population. The highest density of secretagogin cells of ~1800 cells / mm2 remained relatively evenly along the horizontal meridian, whilst the density dropped of to 125 cells / mm2 towards the dorsal and ventral periphery. Thus, secretagogin represents a new amacrine label within the zebrafish retina. The developmental expression suggests a possible role in late stage differentiation. This characterization forms the basis of functional studies assessing how the expression of distinct calcium binding proteins might be regulated to compensate for the loss of one of the others.

Published

2017

26. In Vivo Function of the Chaperonin TRiC in α-Actin Folding during Sarcomere Assembly

Author

Arie Jacoby, Silke Berger, Alastair G. Stewart, Joachim Berger, Peter D. Currie, Anders Arner, Mei Li, and Navid Bavi

Subjects

0301 basic medicine, Sarcomeres, Chaperonins, Protein subunit, macromolecular substances, Sarcomere, General Biochemistry, Genetics and Molecular Biology, Chaperonin, 03 medical and health sciences, medicine, Animals, Humans, lcsh:QH301-705.5, Actin, Zebrafish, Chemistry, Skeletal muscle, Actins, Cell biology, 030104 developmental biology, medicine.anatomical_structure, lcsh:Biology (General), Protein folding, sense organs, Myofibril, Biogenesis, Chaperonin Containing TCP-1

Abstract

Summary: The TCP-1 ring complex (TRiC) is a multi-subunit group II chaperonin that assists nascent or misfolded proteins to attain their native conformation in an ATP-dependent manner. Functional studies in yeast have suggested that TRiC is an essential and generalized component of the protein-folding machinery of eukaryotic cells. However, TRiC’s involvement in specific cellular processes within multicellular organisms is largely unknown because little validation of TRiC function exists in animals. Our in vivo analysis reveals a surprisingly specific role of TRiC in the biogenesis of skeletal muscle α-actin during sarcomere assembly in myofibers. TRiC acts at the sarcomere’s Z-disk, where it is required for efficient assembly of actin thin filaments. Binding of ATP specifically by the TRiC subunit Cct5 is required for efficient actin folding in vivo. Furthermore, mutant α-actin isoforms that result in nemaline myopathy in patients obtain their pathogenic conformation via this function of TRiC. : TRiC-deficient zebrafish feature specific defects in sarcomere and neurite formation. Berger et al. demonstrate a role for TRiC as a multiprotein scaffold positioned at the sarcomere’s Z-disk, where it enhances the processing of skeletal muscle α-actin. Accordingly, TRiC causes aggregation of myopathic α-actin variants in nemaline myopathy. Keywords: CCT, TRiC, chaperonin, folding, actin, zebrafish, muscle, myofibril, tubulin, nemaline myopathy

Published

2017

27. Loss of Tropomodulin4 in the zebrafish mutant träge causes cytoplasmic rod formation and muscle weakness reminiscent of nemaline myopathy

Author

Silke Berger, Anders Arner, Mei Li, Joachim Berger, Thomas E. Hall, Peter D. Currie, and Hakan Tarakci

Subjects

Male, Myofilament, Cytoplasm, Genetic Linkage, Phalloidine, Myofibrillogenesis, Neuromuscular disorder, Medicine (miscellaneous), lcsh:Medicine, Actinin, Sarcomere, Animals, Genetically Modified, 0302 clinical medicine, Nemaline myopathy, Immunology and Microbiology (miscellaneous), Myofibrils, Zebrafish, 0303 health sciences, biology, Muscles, Anatomy, Neuromuscular Diseases, Cell biology, medicine.anatomical_structure, Phenotype, medicine.symptom, Tropomodulin, lcsh:RB1-214, Sarcomeres, Neuroscience (miscellaneous), macromolecular substances, General Biochemistry, Genetics and Molecular Biology, 03 medical and health sciences, Nebulin, Muscular Diseases, medicine, lcsh:Pathology, Animals, Resource Article, Myopathy, Actin, Alleles, 030304 developmental biology, tmod, lcsh:R, Skeletal muscle, Zebrafish Proteins, medicine.disease, Actins, Sarcomere assembly, Disease Models, Animal, Mutation, biology.protein, 030217 neurology & neurosurgery

Abstract

Nemaline myopathy is an inherited muscle disease that is mainly diagnosed by the presence of nemaline rods in muscle biopsies. Of the nine genes associated with the disease, 5 encode for components of striated muscle sarcomeres. In a genetic zebrafish screen the mutant träge (trg) was isolated based on its reduction in muscle birefringence, indicating muscle damage. Myofibres in trg appeared disorganized and showed inhomogeneous cytoplasmic eosin staining alongside malformed nuclei. Linkage analysis of trg combined with sequencing identified a nonsense mutation in tropomodulin4 (tmod4), a regulator of thin filament length and stability. Accordingly, although actin monomers polymerise to form thin filaments in the skeletal muscle of tmod4trg mutants, thin filaments often appeared to be dispersed throughout myofibres. Organised myofibrils with the typical striation rarely assemble, leading to severe muscle weakness, impaired locomotion, and early death. Myofibrils of tmod4trg mutants often featured thin filaments of various lengths, widened Z-disks, undefined H-zones, and electron-dense aggregations of various shapes and sizes. Importantly, Gomori trichrome staining and the lattice pattern of the detected cytoplasmic rods together with the reactivity of rods with phalloidin and an antibody against actinin is reminiscent of nemaline rods found in nemaline myopathy, suggesting that misregulation of thin filament length causes cytoplasmic rod formation in tmod4trg mutants. Although Tropomodulin4 has not been associated with myopathy, the results presented here implicate TMOD4 as a novel candidate for unresolved nemaline myopathies and suggest that the tmod4trg mutant will be a valuable tool to study human muscle disorders.

Published

2014

28. Haematopoietic stem cell induction by somite-derived endothelial cells controlled by meox1

Author

Carmen Sonntag, Lee B. Miles, Phong D. Nguyen, Nicholas J. Cole, Thomas E. Hall, Kristine J. Fernandez, Jose M. Polo, Peter D. Currie, Georgina E Hollway, Silke Berger, Graham J. Lieschke, Robert L. Sutherland, Sara Alaei, David B. Gurevich, and Mirana Ramialison

Subjects

Cell type, Population, Chick Embryo, Mice, Cell Movement, medicine, Animals, Humans, education, Zebrafish, Aorta, Homeodomain Proteins, Genetics, education.field_of_study, Multidisciplinary, biology, Muscles, Somite specification, Endothelial Cells, Zebrafish Proteins, Hematopoietic Stem Cells, biology.organism_classification, Embryonic stem cell, Chemokine CXCL12, Cell biology, Wnt Proteins, Somite, Haematopoiesis, medicine.anatomical_structure, Somites, Mutation, Stem cell, Biomarkers, Transcription Factors

Abstract

Haematopoietic stem cells (HSCs) are self-renewing stem cells capable of replenishing all blood lineages. In all vertebrate embryos that have been studied, definitive HSCs are generated initially within the dorsal aorta (DA) of the embryonic vasculature by a series of poorly understood inductive events. Previous studies have identified that signalling relayed from adjacent somites coordinates HSC induction, but the nature of this signal has remained elusive. Here we reveal that somite specification of HSCs occurs via the deployment of a specific endothelial precursor population, which arises within a sub-compartment of the zebrafish somite that we have defined as the endotome. Endothelial cells of the endotome are specified within the nascent somite by the activity of the homeobox gene meox1. Specified endotomal cells consequently migrate and colonize the DA, where they induce HSC formation through the deployment of chemokine signalling activated in these cells during endotome formation. Loss of meox1 activity expands the endotome at the expense of a second somitic cell type, the muscle precursors of the dermomyotomal equivalent in zebrafish, the external cell layer. The resulting increase in endotome-derived cells that migrate to colonize the DA generates a dramatic increase in chemokine-dependent HSC induction. This study reveals the molecular basis for a novel somite lineage restriction mechanism and defines a new paradigm in induction of definitive HSCs.

Published

2014

29. Fgf2 improves functional recovery—decreasing gliosis and increasing radial glia and neural progenitor cells after spinal cord injury

Author

Frisca Frisca, Ashley L. Siegel, Alexander R. Pinto, Alice Pébay, Jan Kaslin, Jean-Kitty K Y Tang, Yona Goldshmit, and Peter D. Currie

Subjects

Male, Pathology, medicine.medical_specialty, Spinal Cord Regeneration, Neurite, Sox2, Neuroprotection, Glial scar, Behavioral Neuroscience, Astroglia, Mice, Neural Stem Cells, medicine, nestin, Animals, Gliosis, Spinal cord injury, Spinal Cord Injuries, Original Research, progenitors, business.industry, GFAP, Neurogenesis, Recovery of Function, medicine.disease, Neural stem cell, spinal cord injury, Pax6, Mice, Inbred C57BL, regeneration, Astrocytes, Fibroblast Growth Factor 2, medicine.symptom, business

Abstract

Objectives A major impediment for recovery after mammalian spinal cord injury (SCI) is the glial scar formed by proliferating reactive astrocytes. Finding factors that may reduce glial scarring, increase neuronal survival, and promote neurite outgrowth are of major importance for improving the outcome after SCI. Exogenous fibroblast growth factor (Fgf) has been shown to decrease injury volume and improve functional outcome; however, the mechanisms by which this is mediated are still largely unknown. Methods In this study, Fgf2 was administered for 2 weeks in mice subcutaneously, starting 30 min after spinal cord hemisection. Results Fgf2 treatment decreased the expression of TNF-a at the lesion site, decreased monocyte/macrophage infiltration, and decreased gliosis. Fgf2 induced astrocytes to adopt a polarized morphology and increased expression of radial markers such as Pax6 and nestin. In addition, the levels of chondroitin sulfate proteoglycans (CSPGs), expressed by glia, were markedly decreased. Furthermore, Fgf2 treatment promotes the formation of parallel glial processes, “bridges,” at the lesion site that enable regenerating axons through the injury site. Additionally, Fgf2 treatment increased Sox2-expressing cells in the gray matter and neurogenesis around and at the lesion site. Importantly, these effects were correlated with enhanced functional recovery of the left paretic hind limb. Conclusions Thus, early pharmacological intervention with Fgf2 following SCI is neuroprotective and creates a proregenerative environment by the modulation of the glia response.

Published

2014

30. 503unc, a small and muscle-specific zebrafish promoter

Author

Joachim Berger and Peter D. Currie

Subjects

Regulation of gene expression, biology, Transgene, fungi, Cardiac muscle, Skeletal muscle, Cell Biology, biology.organism_classification, Molecular biology, Germline, Green fluorescent protein, Endocrinology, medicine.anatomical_structure, Gene expression, Genetics, medicine, Zebrafish

Abstract

The muscle-specific UNC-45b assists in the folding of sarcomeric myosin. Analysis of the zebrafish unc-45b upstream region revealed that unc-45b promoter fragments reliably drive GFP expression after germline transmission. The muscle-specific 503-bp minimal promoter 503unc was identified to drive gene expression in the zebrafish musculature. In transgenic Tg(-503unc:GFP) zebrafish, GFP fluorescence was detected in the adaxial cells, their slow fiber descendants, and the fast muscle. At later stages, robust GFP fluorescence is eminent in the cardiac, cranial, fin, and trunk muscle, thereby recapitulating the unc-45b expression pattern. We propose that the 503unc promoter is a small and muscle-specific promoter that drives robust gene expression throughout the zebrafish musculature, making it a valuable tool for the exploration of zebrafish muscle.

Published

2013

31. Using Transgenic Zebrafish to Study Muscle Stem/Progenitor Cells

Author

Phong D. Nguyen and Peter D. Currie

Subjects

0301 basic medicine, biology, ved/biology, fungi, ved/biology.organism_classification_rank.species, Skeletal muscle, biology.organism_classification, Phenotype, Cell biology, Endothelial stem cell, 03 medical and health sciences, 030104 developmental biology, medicine.anatomical_structure, Live cell imaging, medicine, Stem cell, Progenitor cell, Model organism, Zebrafish

Abstract

Understanding muscle stem cell behaviors can potentially provide insights into how these cells act and respond during normal growth and diseased contexts. The zebrafish is an ideal model organism to examine these behaviors in vivo where it would normally be technically challenging in other mammalian models. This chapter will describe the procedures required to successfully conduct live imaging of zebrafish transgenics that has specifically been adapted for skeletal muscle.

Published

2017

32. Muscular dystrophy modeling in zebrafish

Author

Peter D. Currie, Sharon L. Amacher, K. J. Hromowyk, and M. Li

Subjects

0301 basic medicine, Muscle tissue, Myogenesis, Skeletal muscle, Anatomy, Biology, Muscle disorder, medicine.disease, biology.organism_classification, Phenotype, 03 medical and health sciences, 030104 developmental biology, 0302 clinical medicine, medicine.anatomical_structure, medicine, biology.protein, Muscular dystrophy, Dystrophin, Neuroscience, Zebrafish, 030217 neurology & neurosurgery

Abstract

Skeletal muscle performs an essential function in human physiology with defects in genes encoding a variety of cellular components resulting in various types of inherited muscle disorders. Muscular dystrophies (MDs) are a severe and heterogeneous type of human muscle disease, manifested by progressive muscle wasting and degeneration. The disease pathogenesis and therapeutic options for MDs have been investigated for decades using rodent models, and considerable knowledge has been accumulated on the cause and pathogenetic mechanisms of this group of human disorders. However, due to some differences between disease severity and progression, what is learned in mammalian models does not always transfer to humans, prompting the desire for additional and alternative models. More recently, zebrafish have emerged as a novel and robust animal model for the study of human muscle disease. Zebrafish MD models possess a number of distinct advantages for modeling human muscle disorders, including the availability and ease of generating mutations in homologous disease-causing genes, the ability to image living muscle tissue in an intact animal, and the suitability of zebrafish larvae for large-scale chemical screens. In this chapter, we review the current understanding of molecular and cellular mechanisms involved in MDs, the process of myogenesis in zebrafish, and the structural and functional characteristics of zebrafish larval muscles. We further discuss the insights gained from the key zebrafish MD models that have been so far generated, and we summarize the attempts that have been made to screen for small molecules inhibitors of the dystrophic phenotypes using these models. Overall, these studies demonstrate that zebrafish is a useful in vivo system for modeling aspects of human skeletal muscle disorders. Studies using these models have contributed both to the understanding of the pathogenesis of muscle wasting disorders and demonstrated their utility as highly relevant models to implement therapeutic screening regimens.

Published

2017

33. Analysis of RNA Expression in Adult Zebrafish Skeletal Muscle

Author

Peter D. Currie, Robert J. Bryson-Richardson, and Tamar E. Sztal

Subjects

0301 basic medicine, animal structures, biology, fungi, Skeletal muscle, Embryo, Model system, In situ hybridization, biology.organism_classification, Cell biology, 03 medical and health sciences, Muscle morphology, 030104 developmental biology, 0302 clinical medicine, medicine.anatomical_structure, Rna expression, embryonic structures, Gene expression, medicine, Zebrafish, 030217 neurology & neurosurgery

Abstract

The zebrafish is an excellent vertebrate model system to investigate skeletal muscle development and disease. During early muscle formation the small size of the developing zebrafish allows for the characterization of gene expression in whole embryos. However, as the zebrafish develops, access to the underlying skeletal muscle is limited, requiring the skeletal muscle to be sectioned for a more detailed examination. Here, we describe a straightforward and effective method to prepare adult zebrafish skeletal muscle sections, preserving muscle morphology, to characterize gene expression in the zebrafish adult skeletal muscle.

Published

2017

34. Muscle Stem Cells Undergo Extensive Clonal Drift during Tissue Growth via Meox1-Mediated Induction of G2 Cell-Cycle Arrest

Author

Jose M. Polo, Carmen Sonntag, Peter D. Currie, Phong D. Nguyen, David B. Gurevich, Lucy Hersey, Sara Alaei, Hieu T. Nim, Thomas E. Hall, Ashley L. Siegel, Sarah Elizabeth Boyd, and Fernando J. Rossello

Subjects

0301 basic medicine, Population, Biology, Cell Line, Myoblasts, 03 medical and health sciences, Mice, Myotome, Genetics, medicine, Animals, Cell Lineage, Cyclin B1, education, Zebrafish, Homeodomain Proteins, education.field_of_study, Skeletal muscle, Cell Biology, Cell cycle, Zebrafish Proteins, biology.organism_classification, Cell biology, Endothelial stem cell, G2 Phase Cell Cycle Checkpoints, 030104 developmental biology, medicine.anatomical_structure, Cell culture, Molecular Medicine, Stem cell, Transcription Factors

Abstract

Organ growth requires a careful balance between stem cell self-renewal and lineage commitment to ensure proper tissue expansion. The cellular and molecular mechanisms that mediate this balance are unresolved in most organs, including skeletal muscle. Here we identify a long-lived stem cell pool that mediates growth of the zebrafish myotome. This population exhibits extensive clonal drift, shifting from random deployment of stem cells during development to reliance on a small number of dominant clones to fuel the vast majority of muscle growth. This clonal drift requires Meox1, a homeobox protein that directly inhibits the cell-cycle checkpoint gene ccnb1. Meox1 initiates G2 cell-cycle arrest within muscle stem cells, and disrupting this G2 arrest causes premature lineage commitment and the resulting defects in muscle growth. These findings reveal that distinct regulatory mechanisms orchestrate stem cell dynamics during organ growth, beyond the G0/G1 cell-cycle inhibition traditionally associated with maintaining tissue-resident stem cells.

Published

2016

35. Myo18b is essential for sarcomere assembly in fast skeletal muscle

Author

Mei Li, Joachim Berger, Peter D. Currie, and Silke Berger

Subjects

0301 basic medicine, Sarcomeres, Sarcoplasm, Biology, Myosins, Sarcomere, 03 medical and health sciences, Nebulin, Myosin, Genetics, medicine, Myocyte, Animals, Humans, Muscle, Skeletal, Molecular Biology, Genetics (clinical), Actin, Zebrafish, Tumor Suppressor Proteins, Skeletal muscle, General Medicine, Cell biology, Actin Cytoskeleton, 030104 developmental biology, medicine.anatomical_structure, biology.protein, Mutant Proteins, Myofibril, Myopathies, Structural, Congenital

Abstract

Congenital myopathies are muscle degenerative disorders with a broad clinical spectrum. A number of myopathies have been associated with molecular defects within sarcomeres, the force-generating component of the muscle cell. Whereas the highly regular organization of the myofibril has been studied in detail, in vivo assembly of sarcomeres remains a poorly understood process. Therefore, a more detailed knowledge of sarcomere assembly is crucial to better understand the pathogenic mechanisms within myopathies. Recently, mutations in myosin XVIIIB (MYO18B) have been associated with cases of myopathies, although the underlying mechanism for the resulting pathology remains to be defined. To analyze the role of myosin XVIIIB in skeletal muscle disease, zebrafish mutants for myo18b were generated. Full loss of myo18b function results in a complete lack of sarcomeric structure, revealing a highly surprising and essential role for myo18b in sarcomere assembly. Importantly, scattered thin and thick filaments assemble throughout the sarcoplasm; but fail to organize into recognizable sarcomeric structures in myo18b null mutants. In myo18b partial loss-of-function mutants sarcomeric structures are assembled, but thin and thick filaments remain misaligned within these structures. These observations suggest a novel model of sarcomere assembly where Myo18b coordinates the integration of preformed thick and thin filaments into the sarcomere. Disruption of this highly coordinated process results in a block in sarcomere biogenesis and the onset of myopathic pathology.

Published

2016

36. Epistatic dissection of laminin-receptor interactions in dystrophic zebrafish muscle

Author

Tamar E. Sztal, Carmen Sonntag, Thomas E. Hall, and Peter D. Currie

Subjects

Cellular pathology, Muscle Development, Muscular Dystrophies, Receptors, Laminin, Extracellular matrix, Laminin, Genetics, Muscle attachment, medicine, Animals, Humans, Myocyte, Dystroglycans, Muscle, Skeletal, Molecular Biology, Zebrafish, Genetics (clinical), biology, Skeletal muscle, Epistasis, Genetic, General Medicine, Muscular Dystrophy, Animal, Zebrafish Proteins, biology.organism_classification, Extracellular Matrix, Cell biology, medicine.anatomical_structure, biology.protein, ITGA7, Protein Binding

Abstract

Laminins form essential components of the basement membrane and are integral to forming and maintaining muscle integrity. Mutations in the human Laminin-alpha2 (LAMA2) gene result in the most common form of congenital muscular dystrophy, MDC1A. We have previously identified a zebrafish model of MDC1A called candyfloss (caf), carrying a loss-of-function mutation in the zebrafish lama2 gene. In the skeletal muscle, laminins connect the muscle cell to the extracellular matrix (ECM) by binding either dystroglycan or integrins at the cell membrane. Through epistasis experiments, we have established that both adhesion systems individually contribute to the maintenance of fibre adhesions and exhibit muscle detachment phenotypes. However, larval zebrafish in which both adhesion systems are simultaneously genetically inactivated possess a catastrophic failure of muscle attachment that is far greater than a simple addition of individual phenotypes would predict. We provide evidence that this is due to other crucial laminins present in addition to Lama2, which aid muscle cell attachments and integrity. We have found that lama1 is important for maintaining attachments, whereas lama4 is localized and up-regulated in damaged fibres, which appears to contribute to fibre survival. Importantly, our results show that endogenous secretion of laminins from the surrounding tissues has the potential to reinforce fibre attachments and strengthen laminin-ECM attachments. Collectively these findings provide a better understanding of the cellular pathology of MDC1A and help in designing effective therapies.

Published

2012

37. Expression and Activation of EphA4 in the Human Brain After Traumatic Injury

Author

Yona Goldshmit, Catriona McLean, Tony Frugier, Peter D. Currie, David Moses, and Alison Conquest

Subjects

Adult, Lipopolysaccharides, Male, rho GTP-Binding Proteins, Time Factors, Adolescent, Traumatic brain injury, Biology, Pathology and Forensic Medicine, Interferon-gamma, Young Adult, Cellular and Molecular Neuroscience, Glial Fibrillary Acidic Protein, medicine, Humans, Immunoprecipitation, Ephrin, Cells, Cultured, Aged, Analysis of Variance, Diffuse axonal injury, Receptor, EphA4, Erythropoietin-producing hepatocellular (Eph) receptor, Brain, General Medicine, Human brain, Middle Aged, medicine.disease, Enzyme Activation, Ki-67 Antigen, Traumatic injury, medicine.anatomical_structure, Gene Expression Regulation, nervous system, Neurology, Astrocytes, Brain Injuries, Closed head injury, Female, Neurology (clinical), Ephrins, Neuroscience, Astrocyte

Abstract

Glial scars that consist predominantly of reactive astrocytes create a major barrier to neuronal regeneration after traumatic brain injury (TBI). In experimental TBI, Eph receptors and their ephrin ligands are upregulated on reactive astrocytes at injury sites and inhibit axonal regeneration, but very little is known about Eph receptors in the human brain after TBI. A better understanding of the functions of glial cells and their interactions with inflammatory cells and injured axons will allow the development of treatment strategies that may promote regeneration. We analyzed EphA4 expression and activation in postmortem brain tissue from 19 patients who died after acute closed head injury and had evidence of diffuse axonal injury and 8 controls. We also examined downstream pathways that are mediated by EphA4 in human astrocyte cell cultures. Our results indicate that, after TBI in humans, EphA4 expression is upregulated and is associated with reactive astrocytes. The expression was increased shortly after the injury and remained activated for several days. EphA4 activation induced under inflammatory conditions in vitro was inhibited using unclustered EphA4 ligand. These results suggest that blocking EphA4 activation may represent a therapeutic approach for TBI and other types of brain injuries in humans.

Published

2012

38. Evaluation of exon-skipping strategies for Duchenne muscular dystrophy utilizing dystrophin-deficient zebrafish

Author

Joachim Berger, Silke Berger, Peter D. Currie, Arie Jacoby, and Steve D. Wilton

Subjects

musculoskeletal diseases, Duchenne muscular dystrophy, congenital, hereditary, and neonatal diseases and abnormalities, Morpholino, muscle, Bioinformatics, Real-Time Polymerase Chain Reaction, dystrophin, Animals, Genetically Modified, Exon, Utrophin, DMD, Medicine, Animals, Humans, RNA, Messenger, Zebrafish, Genetics, biology, business.industry, Cell Biology, Original Articles, Exons, biology.organism_classification, medicine.disease, zebrafish, Exon skipping, Muscular Dystrophy, Duchenne, Phenotype, biology.protein, Molecular Medicine, Dystrophin, business, ITGA7, exon skipping

Abstract

Duchenne muscular dystophy (DMD) is a severe muscle wasting disease caused by mutations in the dystrophin gene. By utilizing antisense oligonucleotides, splicing of the dystrophin transcript can be altered so that exons harbouring a mutation are excluded from the mature mRNA. Although this approach has been shown to be effective to restore partially functional dystrophin protein, the level of dystrophin protein that is necessary to rescue a severe muscle pathology has not been addressed. As zebrafish dystrophin mutants (dmd) resemble the severe muscle pathology of human patients, we have utilized this model to evaluate exon skipping. Novel dmd mutations were identified to enable the design of phenotype rescue studies via morpholino administration. Correlation of induced exon-skipping efficiency and the level of phenotype rescue suggest that relatively robust levels of exon skipping are required to achieve significant therapeutic ameliorations and that pre-screening analysis of exon-skipping drugs in zebrafish may help to more accurately predict clinical trials for therapies of DMD.

Published

2011

39. Dystrophin-deficient zebrafish feature aspects of the Duchenne muscular dystrophy pathology

Author

Silke Berger, Joachim Berger, Peter D. Currie, Thomas E. Hall, and Graham J. Lieschke

Subjects

musculoskeletal diseases, Pathology, medicine.medical_specialty, animal structures, Duchenne muscular dystrophy, Animals, Genetically Modified, Dystrophin, Utrophin, medicine, Animals, Muscular dystrophy, Muscle, Skeletal, Zebrafish, Genetics (clinical), biology, fungi, Skeletal muscle, medicine.disease, biology.organism_classification, Immunohistochemistry, Muscular Dystrophy, Duchenne, Disease Models, Animal, Phenotype, medicine.anatomical_structure, Neurology, Pediatrics, Perinatology and Child Health, biology.protein, Neurology (clinical), medicine.symptom, ITGA7, Muscle contraction

Abstract

Duchenne muscular dystrophy is caused by mutations in the dystrophin gene. As in humans, zebrafish dystrophin is initially expressed at the peripheral ends of the myofibres adjacent to the myotendinous junction and gradually shifts to non-junctional sites. Dystrophin-deficient zebrafish larvae are characterised by abundant necrotic fibres being replaced by mono-nucleated infiltrates, extensive fibrosis accompanied by inflammation, and a broader variation in muscle fibre cross-sectional areas. Muscle progenitor proliferation cannot compensate for the extensive skeletal muscle loss. Live imaging of dystrophin-deficient zebrafish larvae documents detaching myofibres elicited by muscle contraction. Correspondingly, the progressive phenotype of dystrophin-deficient zebrafish resembles many aspects of the human disease, suggesting that specific advantages of the zebrafish model system, such as the ability to undertake in vivo drug screens and real time analysis of muscle fibre loss, could be used to make novel insights relevant to understanding and treating the pathological basis of dystrophin-deficient muscular dystrophy.

Published

2010

40. Control of morphogenetic cell movements in the early zebrafish myotome

Author

Peter D. Currie, Sharon L. Amacher, David F. Daggett, and Carmen R. Domingo

Subjects

Notochord, Adaxial, Biology, cap, Article, 03 medical and health sciences, 0302 clinical medicine, Myotome, Cell Movement, medicine, Animals, Myocyte, Somite, Molecular Biology, Zebrafish, Actin, Body Patterning, 030304 developmental biology, Cuboidal Cell, Muscle Cells, 0303 health sciences, Gene Expression Regulation, Developmental, Apical constriction, Cell Biology, Anatomy, Zebrafish Proteins, biology.organism_classification, Cell biology, medicine.anatomical_structure, Somites, Mutation, Muscle, Carrier Proteins, 030217 neurology & neurosurgery, Developmental Biology

Abstract

As the vertebrate myotome is generated, myogenic precursor cells undergo extensive and coordinated movements as they differentiate into properly positioned embryonic muscle fibers. In the zebrafish, the “adaxial” cells adjacent to the notochord are the first muscle precursors to be specified. After initially differentiating into slow-twitch myosin-expressing muscle fibers, these cells have been shown to undergo a remarkable radial migration through the lateral somite, to populate the superficial layer of slow-twitch muscle of the mature myotome. Here we characterize an earlier set of adaxial cell behaviors; the transition from a roughly 4 × 5 array of cuboidal cells to a 1 × 20 stack of elongated cells, prior to the migration event. We find that adaxial cells display a highly stereotypical series of behaviors as they undergo this rearrangement. Furthermore, we show that the actin regulatory molecule, Cap1, is specifically expressed in adaxial cells and is required for the progression of these behaviors. The requirement of Cap1 for a cellular apical constriction step is reminiscent of similar requirements of Cap during apical constriction in Drosophila development, suggesting a conservation of gene function for a cell biological event critical to many developmental processes.

Published

2007

41. The zebrafish candyfloss mutant implicates extracellular matrix adhesion failure in laminin α2-deficient congenital muscular dystrophy

Author

Nicholas J. Cole, Joachim Berger, Peter D. Currie, Arie Jacoby, Robert J. Bryson-Richardson, Georgina E Hollway, Silke Berger, and Thomas E. Hall

Subjects

Myoblast proliferation, Embryo, Nonmammalian, Duchenne muscular dystrophy, Molecular Sequence Data, Muscle Fibers, Skeletal, Motor Activity, Biology, Open Reading Frames, Myoblast fusion, Sarcolemma, medicine, Animals, Amino Acid Sequence, Muscular dystrophy, Alleles, Zebrafish, Multidisciplinary, Base Sequence, Cell Death, Sequence Homology, Amino Acid, Adhesiveness, Biological Sciences, Muscular Dystrophy, Animal, Oligonucleotides, Antisense, Zebrafish Proteins, medicine.disease, Molecular biology, Muscle atrophy, Extracellular Matrix, Cell biology, Intercellular Junctions, Gene Expression Regulation, Codon, Nonsense, Congenital muscular dystrophy, Mutant Proteins, Laminin, medicine.symptom, ITGA7

Abstract

Mutations in the human laminin α 2 ( LAMA2 ) gene result in the most common form of congenital muscular dystrophy (MDC1A). There are currently three models for the molecular basis of cellular pathology in MDC1A: ( i ) lack of LAMA2 leads to sarcolemmal weakness and failure, followed by cellular necrosis, as is the case in Duchenne muscular dystrophy (DMD); ( ii ) loss of LAMA2-mediated signaling during the development and maintenance of muscle tissue results in myoblast proliferation and fusion defects; ( iii ) loss of LAMA2 from the basement membrane of the Schwann cells surrounding the peripheral nerves results in a lack of motor stimulation, leading to effective denervation atrophy. Here we show that the degenerative muscle phenotype in the zebrafish dystrophic mutant, candyfloss ( caf ) results from mutations in the laminin α 2 ( lama2 ) gene. In vivo time-lapse analysis of mechanically loaded fibers and membrane permeability assays suggest that, unlike DMD, fiber detachment is not initially associated with sarcolemmal rupture. Early muscle formation and myoblast fusion are normal, indicating that any deficiency in early Lama2 signaling does not lead to muscle pathology. In addition, innervation by the primary motor neurons is unaffected, and fiber detachment stems from muscle contraction, demonstrating that muscle atrophy through lack of motor neuron activity does not contribute to pathology in this system. Using these and other analyses, we present a model of lama2 function where fiber detachment external to the sarcolemma is mechanically induced, and retracted fibers with uncompromised membranes undergo subsequent apoptosis.

Published

2007

42. Asymmetric division of clonal muscle stem cells coordinates muscle regeneration in vivo

Author

Silke Berger, Dhanushika Ratnayake, Carmen Sonntag, Ophelia V. Ehrlich, Phong D. Nguyen, Jennifer M. N. Phan, Joachim Berger, Peter D. Currie, Lucy Hersey, David B. Gurevich, Ashley L. Siegel, Heather Verkade, and Thomas E. Hall

Subjects

0301 basic medicine, Cell division, Satellite Cells, Skeletal Muscle, Population, Biology, Muscle Development, Regenerative medicine, Animals, Genetically Modified, 03 medical and health sciences, Myosin, medicine, Myocyte, Animals, Regeneration, Transgenes, education, Muscle, Skeletal, Zebrafish, education.field_of_study, Multidisciplinary, Regeneration (biology), Skeletal muscle, Cell biology, Clone Cells, 030104 developmental biology, medicine.anatomical_structure, Cell Tracking, Immunology, Mutation, Myogenin, Myogenic Regulatory Factor 5, Stem cell, Cell Division

Abstract

Dividing asymmetrically to fix muscle Resident tissue stem cells called satellite cells repair muscle after injury. However, how satellite cells operate inside living tissue is unclear. Gurevich et al. exploited the optical clarity of zebrafish larvae and used a series of genetic approaches to study muscle injury. After injury, satellite cells divide asymmetrically to generate a progenitor pool for muscle replacement and at the same time “self-renew” the satellite stem cell. This results in regeneration that is highly clonal in nature, validating many decades of in vitro analyses examining the regenerative capacity of skeletal muscle. Science , this issue p. 136

Published

2015

43. A somitic contribution to the apical ectodermal ridge is essential for fin formation

Author

A.J. Wood, Carmen Sonntag, Thomas E. Hall, Phong D. Nguyen, Gilbert Weidinger, Naomi Cohen, Silke Berger, Peter D. Currie, Franziska Knopf, Fruzsina Fenyes, Nicholas J. Cole, and Wouter Masselink

Subjects

0301 basic medicine, Apical ectodermal ridge, Mesoderm, Cell signaling, animal structures, Limb Buds, Mesenchyme, Ectoderm, Biology, 03 medical and health sciences, medicine, Animals, Cell Lineage, Zebrafish, Multidisciplinary, Anatomy, biology.organism_classification, Biological Evolution, Cell biology, body regions, 030104 developmental biology, medicine.anatomical_structure, Somites, Animal Fins, Female, human activities, Developmental biology, Heterochrony

Abstract

The transition from fins to limbs was an important terrestrial adaptation, but how this crucial evolutionary shift arose developmentally is unknown. Current models focus on the distinct roles of the apical ectodermal ridge (AER) and the signaling molecules that it secretes during limb and fin outgrowth. In contrast to the limb AER, the AER of the fin rapidly transitions into the apical fold and in the process shuts off AER-derived signals that stimulate proliferation of the precursors of the appendicular skeleton. The differing fates of the AER during fish and tetrapod development have led to the speculation that fin-fold formation was one of the evolutionary hurdles to the AER-dependent expansion of the fin mesenchyme required to generate the increased appendicular structure evident within limbs. Consequently, a heterochronic shift in the AER-to-apical-fold transition has been postulated to be crucial for limb evolution. The ability to test this model has been hampered by a lack of understanding of the mechanisms controlling apical fold induction. Here we show that invasion by cells of a newly identified somite-derived lineage into the AER in zebrafish regulates apical fold induction. Ablation of these cells inhibits apical fold formation, prolongs AER activity and increases the amount of fin bud mesenchyme, suggesting that these cells could provide the timing mechanism proposed in Thorogood's clock model of the fin-to-limb transition. We further demonstrate that apical-fold inducing cells are progressively lost during gnathostome evolution;the absence of such cells within the tetrapod limb suggests that their loss may have been a necessary prelude to the attainment of limb-like structures in Devonian sarcopterygian fish.

Published

2015

44. Rapamycin increases neuronal survival, reduces inflammation and astrocyte proliferation after spinal cord injury

Author

Maria Zacs, Frisca Frisca, Alexander R. Pinto, Yona Goldshmit, Sivan Kanner, Ronit Pinkas-Kramarski, and Peter D. Currie

Subjects

Male, Programmed cell death, Time Factors, Cell Survival, Cell Count, ELAV-Like Protein 3, mTORC1, Biology, Axonogenesis, Glial scar, Cellular and Molecular Neuroscience, Mice, Glial Fibrillary Acidic Protein, medicine, Animals, Humans, Molecular Biology, Spinal cord injury, Cells, Cultured, Spinal Cord Injuries, Inflammation, Neurons, Sirolimus, CD11b Antigen, Microglia, Cell Biology, medicine.disease, Astrogliosis, Rats, Mice, Inbred C57BL, Disease Models, Animal, medicine.anatomical_structure, Ki-67 Antigen, Gene Expression Regulation, Astrocytes, Immunology, Cancer research, Immunosuppressive Agents, Astrocyte

Abstract

Spinal cord injury (SCI) frequently leads to a permanent functional impairment as a result of the initial injury followed by secondary injury mechanism, which is characterised by increased inflammation, glial scarring and neuronal cell death. Finding drugs that may reduce inflammatory cell invasion and activation to reduce glial scarring and increase neuronal survival is of major importance for improving the outcome after SCI. In the present study, we examined the effect of rapamycin, an mTORC1 inhibitor and an inducer of autophagy, on recovery from spinal cord injury. Autophagy, a process that facilitates the degradation of cytoplasmic proteins, is also important for maintenance of neuronal homeostasis and plays a major role in neurodegeneration after neurotrauma. We examined rapamycin effects on the inflammatory response, glial scar formation, neuronal survival and regeneration in vivo using spinal cord hemisection model in mice, and in vitro using primary cortical neurons and human astrocytes. We show that a single injection of rapamycin, inhibited p62/SQSTM1, a marker of autophagy, inhibited mTORC1 downstream effector p70S6K, reduced macrophage/neutrophil infiltration into the lesion site, microglia activation and secretion of TNFα. Rapamycin inhibited astrocyte proliferation and reduced the number of GFAP expressing cells at the lesion site. Finally, it increased neuronal survival and axonogenesis towards the lesion site. Our study shows that rapamycin treatment increased significantly p-Akt levels at the lesion site following SCI. Similarly, rapamycin treatment of neurons and astrocytes induced p-Akt elevation under stress conditions. Together, these findings indicate that rapamycin is a promising candidate for treatment of acute SCI condition and may be a useful therapeutic agent.

Published

2015

45. Zebrafish as a model for caveolin-associated muscle disease; caveolin-3 is required for myofibril organization and muscle cell patterning

Author

Susan J. Nixon, Brian Key, Pierre-Francois Mery, Monte Westerfield, John F. Hancock, Peter D. Currie, Charles Ferguson, Jeremy Wegner, and Robert G. Parton

Subjects

Embryo, Nonmammalian, animal structures, Caveolin 3, Myoblasts, Skeletal, Molecular Sequence Data, Biology, Caveolins, Cell Fusion, Myoblast fusion, Myofibrils, Caveolae, Genetics, medicine, Animals, Humans, Myocyte, Amino Acid Sequence, Muscle, Skeletal, Molecular Biology, Zebrafish, Genetics (clinical), Skeletal muscle, Cell Differentiation, General Medicine, biology.organism_classification, Cell biology, medicine.anatomical_structure, ITGA7, Myofibril

Abstract

Caveolae are an abundant feature of many animal cells. However, the exact function of caveolae remains unclear. We have used the zebrafish, Danio rerio, as a system to understand caveolae function focusing on the muscle-specific caveolar protein, caveolin-3 (Cav3). We have identified caveolin-1 (alpha and beta), caveolin-2 and Cav3 in the zebrafish. Zebrafish Cav3 has 72% identity to human CAV3, and the amino acids altered in human muscle diseases are conserved in the zebrafish protein. During embryonic development, cav3 expression is apparent by early segmentation stages in the first differentiating muscle precursors, the adaxial cells and slightly later in the notochord. cav3 expression appears in the somites during mid-segmentation stages and then later in the pectoral fins and facial muscles. Cav3 and caveolae are located along the entire sarcolemma of late stage embryonic muscle fibers, whereas beta-dystroglycan is restricted to the muscle fiber ends. Down-regulation of Cav3 expression causes gross muscle abnormalities and uncoordinated movement. Ultrastructural analysis of isolated muscle fibers reveals defects in myoblast fusion and disorganized myofibril and membrane systems. Expression of the zebrafish equivalent to a human muscular dystrophy mutant, CAV3P104L, causes severe disruption of muscle differentiation. In addition, knockdown of Cav3 resulted in a dramatic up-regulation of eng1a expression resulting in an increase in the number of muscle pioneer-like cells adjacent to the notochord. These studies provide new insights into the role of Cav3 in muscle development and demonstrate its requirement for correct intracellular organization and myoblast fusion.

Published

2005

46. Developmentally Restricted Actin-Regulatory Molecules Control Morphogenetic Cell Movements in the Zebrafish Gastrula

Author

Sharon L. Amacher, David F. Daggett, Christine Thisse, Phillipe Gautier, Bernard Thisse, Catherine A Boyd, Peter D. Currie, and Robert J. Bryson-Richardson

Subjects

DNA, Complementary, Molecular Sequence Data, Cell, Biology, General Biochemistry, Genetics and Molecular Biology, Fungal Proteins, 03 medical and health sciences, 0302 clinical medicine, Cell Movement, Databases, Genetic, Gene expression, Morphogenesis, medicine, Animals, Guanine Nucleotide Exchange Factors, Amino Acid Sequence, Gene, Zebrafish, In Situ Hybridization, Actin, 030304 developmental biology, 0303 health sciences, Base Sequence, Agricultural and Biological Sciences(all), Biochemistry, Genetics and Molecular Biology(all), Gene Expression Regulation, Developmental, Actin remodeling, Gastrula, Sequence Analysis, DNA, Zebrafish Proteins, biology.organism_classification, Immunohistochemistry, Actins, Cell biology, Gastrulation, Basic-Leucine Zipper Transcription Factors, medicine.anatomical_structure, Guanine nucleotide exchange factor, Carrier Proteins, General Agricultural and Biological Sciences, Sequence Alignment, 030217 neurology & neurosurgery, Transcription Factors

Abstract

Although our understanding of the regulation of cellular actin and its control during the development of invertebrates is increasing [1–9], the question as to how such actin dynamics are regulated differentially across the vertebrate embryo to effect its relatively complex morphogenetic cell movements remains poorly understood. Intercellular signaling that provides spatial and temporal cues to modulate the subcellular localization and activity of actin regulatory molecules represents one important mechanism [10–13]. Here we explore whether the localized gene expression of specific actin regulatory molecules represents another developmental mechanism. We have identified a cap1 homolog and a novel guanine nucleotide exchange factor (GEF), quattro ( quo ), that share a restricted gene expression domain in the anterior mesendoderm of the zebrafish gastrula. Each gene is required for specific cellular behaviors during the anterior migration of this tissue; furthermore, cap1 regulates cortical actin distribution specifically in these cells. Finally, although cap1 and quo are autonomously required for the normal behaviors of these cells, they are also nonautonomously required for convergence and extension movements of posterior tissues. Our results provide direct evidence for the deployment of developmentally restricted actin-regulatory molecules in the control of morphogenetic cell movements during vertebrate development.

Published

2004

47. IDENTIFICATION OF A ZEBRAFISH MODEL OF MUSCULAR DYSTROPHY

Author

David I. Bassett and Peter D. Currie

Subjects

musculoskeletal diseases, Pharmacology, Genetics, mdx mouse, biology, Physiology, Duchenne muscular dystrophy, Skeletal muscle, medicine.disease, biology.organism_classification, Cell biology, medicine.anatomical_structure, Physiology (medical), biology.protein, medicine, Muscle attachment, Muscular dystrophy, Dystrophin, ITGA7, Zebrafish

Abstract

1. Large-scale mutagenic screens of the zebrafish genome have identified a number of different classes of mutations that disrupt skeletal muscle formation. Of particular interest and relevance to human health is a class of recessive lethal mutations in which muscle differentiation occurs normally, but is followed by tissue-specific degeneration reminiscent of human muscular dystrophies. 2. We have shown that one member of this class of mutations, sapje (sap), results from mutations within the zebrafish orthologue of the human Duchenne muscular dystrophy (DMD) gene. Mutations in this locus cause Duchenne or Becker muscular dystrophies in human patients and are thought to result in a dystrophic pathology by disrupting the link between the actin cytoskeleton and the extracellular matrix in skeletal muscle cells. 3. We have found that the progressive muscle degeneration phenotype of sapje-mutant zebrafish embryos is caused by the failure of somitic muscle attachments at the embryonic myotendinous junction (MTJ). 4. Although a role for dystrophin at the MTJ has been postulated previously and MTJ structural abnormalities have been identified in the dystrophin-deficient mdx mouse model, in vivo evidence of pathology based on muscle attachment failure is thus far lacking. Therefore, the sapjre mutation may provide a model for a novel pathological mechanism of Duchenne muscular dystrophy and other muscle diseases. In the present review, we discuss this finding in light of previously postulated models of dystrophin function.

Published

2004

48. Cadherin-Mediated Differential Cell Adhesion Controls Slow Muscle Cell Migration in the Developing Zebrafish Myotome

Author

David F. Daggett, Georgina E Hollway, Peter D. Currie, Phillipe Gautier, John C. Maule, Christine Neyt, Fernando Cortes, Robert J. Bryson-Richardson, and David G Keenan

Subjects

Slow muscle cell migration, Morphogenesis, Gene Expression Regulation, Developmental, Cell migration, Cell Biology, Biology, Cadherins, General Biochemistry, Genetics and Molecular Biology, Cell biology, Muscle Fibers, Slow-Twitch, medicine.anatomical_structure, Muscle cell migration, Cell Movement, Myotome, Cell Adhesion, Mutagenesis, Site-Directed, medicine, Paraxial mesoderm, Animals, Myocyte, Muscle, Skeletal, Cell adhesion, Molecular Biology, Zebrafish, Developmental Biology

Abstract

Slow-twitch muscle fibers of the zebrafish myotome undergo a unique set of morphogenetic cell movements. During embryogenesis, slow-twitch muscle derives from the adaxial cells, a layer of paraxial mesoderm that differentiates medially within the myotome, immediately adjacent to the notochord. Subsequently, slow-twitch muscle cells migrate through the entire myotome, coming to lie at its most lateral surface. Here we examine the cellular and molecular basis for slow-twitch muscle cell migration. We show that slow-twitch muscle cell morphogenesis is marked by behaviors typical of cells influenced by differential cell adhesion. Dynamic and reciprocal waves of N-cadherin and M-cadherin expression within the myotome, which correlate precisely with cell migration, generate differential adhesive environments that drive slow-twitch muscle cell migration through the myotome. Removing or altering the expression of either protein within the myotome perturbs migration. These results provide a definitive example of homophilic cell adhesion shaping cellular behavior during vertebrate development.

Published

2003

49. The zebrafish as a model for muscular dystrophy and congenital myopathy

Author

David I. Bassett and Peter D. Currie

Subjects

Bioinformatics, Muscular Dystrophies, Mice, Muscular Diseases, Genetic model, Genetics, medicine, Muscle attachment, Animals, Humans, Muscular dystrophy, Myopathy, Molecular Biology, Zebrafish, Genetics (clinical), biology, Mechanism (biology), Skeletal muscle, General Medicine, Anatomy, medicine.disease, biology.organism_classification, Congenital myopathy, Disease Models, Animal, medicine.anatomical_structure, medicine.symptom

Abstract

The muscular dystrophies and congenital myopathies are inherited diseases of the skeletal muscle, which lead to a loss of muscle function and are often fatal. While many of the loci involved are already known, these conditions remain incurable, and genetic models are being developed in an effort to understand the pathological mechanisms involved. Recently several papers have shown that the zebrafish, which is now widely used in developmental genetic studies, will provide a useful addition to our toolkit in this regard. Here we describe these studies, including a zebrafish model of what is potentially the novel pathological mechanism of muscle attachment failure in Duchenne and other muscular dystrophies.

Published

2003

50. Stem cell dynamics in muscle regeneration: Insights from live imaging in different animal models

Author

Peter D. Currie and Dhanushika Ratnayake

Subjects

0301 basic medicine, Cell division, Biology, Time-Lapse Imaging, General Biochemistry, Genetics and Molecular Biology, Mice, 03 medical and health sciences, Live cell imaging, Morphogenesis, medicine, Animals, Humans, Regeneration, Progenitor cell, Muscle, Skeletal, Zebrafish, Progenitor, Stem Cells, Regeneration (biology), Skeletal muscle, biology.organism_classification, Cell biology, 030104 developmental biology, medicine.anatomical_structure, Models, Animal, Stem cell

Abstract

In recent years, live imaging has been adopted to study stem cells in their native environment at cellular resolution. In the skeletal muscle field, this has led to visualising the initial events of muscle repair in mouse, and the entire regenerative response in zebrafish. Here, we review recent discoveries in this field obtained from live imaging studies. Tracking of tissue resident stem cells, the satellite cells, following injury has captured the morphogenetic dynamics of stem/progenitor cells as they facilitate repair. Asymmetric satellite cell division generated a clonogenic progenitor pool, providing in vivo validation for this mechanism. Furthermore, there is an emerging role of stem/progenitor cell guidance at the injury site by cellular protrusions. This review concludes that live imaging is a critical tool for discovering the distinct processes that occur during regeneration, emphasising the importance of imaging in diverse animal models to capture the entire scope of stem cell functions. Also see the Video Abstract. Link to: https://youtube/tgUHSBD1N0g.

Published

2017