Your search keyword '"Kothary R"' showing total 13 results

1. Dystonin loss-of-function leads to impaired autophagosome-endolysosome pathway dynamics.

Author

Lynch-Godrei A, Repentigny Y, Ferrier A, Gagnon S, and Kothary R

Subjects

Animals, Autophagosomes metabolism, Endosomes metabolism, Ganglia, Spinal metabolism, Ganglia, Spinal pathology, Lysosomes metabolism, Mice, Mice, Inbred C57BL, Mice, Knockout, Neurons metabolism, Autophagosomes pathology, Autophagy, Dystonin physiology, Endosomes pathology, Loss of Function Mutation, Lysosomes pathology, Neurons pathology

Abstract

The neuronal dystonin protein (DST-a) is a large cytoskeletal linker important for integrating the various components of the cytoskeleton. Recessive Dst mutations lead to a sensory neuropathy in mice, known as dystonia musculorum ( Dst dt ). The disease is characterized by ataxia, autonomic disturbances, and ultimately, death, which are associated with massive degeneration of the sensory neurons in the dorsal root ganglion (DRG). Recent investigation of Dst dt sensory neurons revealed an accumulation of autophagosomes and a disruption in autophagic flux, which was believed to be due to insufficient availability of motor protein. Motor protein levels and the endolysosomal pathway were assessed in pre-symptomatic (postnatal day 5; P5) and symptomatic (P15) stage wild-type and Dst dt DRGs. Levels of mRNA encoding molecular motors were reduced, although no significant reduction in the protein level was detected. An increase in lysosomal marker LAMP1 in medium-large size Dst dt-27J sensory neurons was observed, along with an accumulation of electron-light single-membraned vesicles in Dst dt-27J DRG tissue at the late stages of disease. These vesicles are likely to have been autolysosomes, and their presence in only late-stage Dst dt-27J sensory neurons is suggestive of a pathological defect in autophagy. Further investigation is necessary to confirm vesicle identity, and to determine the role of Dst-a in normal autophagic flux.

Published

2021

2. Neuronal dystonin isoform 2 is a mediator of endoplasmic reticulum structure and function.

Author

Ryan SD, Ferrier A, Sato T, O'Meara RW, De Repentigny Y, Jiang SX, Hou ST, and Kothary R

Subjects

Animals, Apoptosis, Calcium metabolism, Carrier Proteins genetics, Caspases biosynthesis, Cytoskeletal Proteins genetics, Dystonia Musculorum Deformans genetics, Dystonia Musculorum Deformans metabolism, Dystonia Musculorum Deformans pathology, Dystonin, Endoplasmic Reticulum ultrastructure, Endoplasmic Reticulum Stress, Enzyme Activation, Mice, Mice, Mutant Strains, Nerve Tissue Proteins genetics, Neurons pathology, Protein Isoforms genetics, Protein Isoforms physiology, Unfolded Protein Response, Carrier Proteins physiology, Cytoskeletal Proteins physiology, Endoplasmic Reticulum physiology, Nerve Tissue Proteins physiology, Neurons metabolism

Abstract

Dystonin/Bpag1 is a cytoskeletal linker protein whose loss of function in dystonia musculorum (dt) mice results in hereditary sensory neuropathy. Although loss of expression of neuronal dystonin isoforms (dystonin-a1/dystonin-a2) is sufficient to cause dt pathogenesis, the diverging function of each isoform and what pathological mechanisms are activated upon their loss remains unclear. Here we show that dt(27) mice manifest ultrastructural defects at the endoplasmic reticulum (ER) in sensory neurons corresponding to in vivo induction of ER stress proteins. ER stress subsequently leads to sensory neurodegeneration through induction of a proapoptotic caspase cascade. dt sensory neurons display neurodegenerative pathologies, including Ca(2+) dyshomeostasis, unfolded protein response (UPR) induction, caspase activation, and apoptosis. Isoform-specific loss-of-function analysis attributes these neurodegenerative pathologies to specific loss of dystonin-a2. Inhibition of either UPR or caspase signaling promotes the viability of cells deficient in dystonin. This study provides insight into the mechanism of dt neuropathology and proposes a role for dystonin-a2 as a mediator of normal ER structure and function.

Published

2012

3. Derivation of enriched oligodendrocyte cultures and oligodendrocyte/neuron myelinating co-cultures from post-natal murine tissues.

Author

O'Meara RW, Ryan SD, Colognato H, and Kothary R

Subjects

Animals, Cerebral Cortex cytology, Coculture Techniques, Mice, Microscopy, Fluorescence methods, Myelin Sheath metabolism, Neuroglia cytology, Neurons metabolism, Oligodendroglia metabolism, Cytological Techniques methods, Neurons cytology, Oligodendroglia cytology

Abstract

Identifying the molecular mechanisms underlying OL development is not only critical to furthering our knowledge of OL biology, but also has implications for understanding the pathogenesis of demyelinating diseases such as Multiple Sclerosis (MS). Cellular development is commonly studied with primary cell culture models. Primary cell culture facilitates the evaluation of a given cell type by providing a controlled environment, free of the extraneous variables that are present in vivo. While OL cultures derived from rats have provided a vast amount of insight into OL biology, similar efforts at establishing OL cultures from mice has been met with major obstacles. Developing methods to culture murine primary OLs is imperative in order to take advantage of the available transgenic mouse lines. Multiple methods for extraction of OPCs from rodent tissue have been described, ranging from neurosphere derivation, differential adhesion purification and immunopurification (1-3). While many methods offer success, most require extensive culture times and/or costly equipment/reagents. To circumvent this, purifying OPCs from murine tissue with an adaptation of the method originally described by McCarthy & de Vellis (2) is preferred. This method involves physically separating OPCs from a mixed glial culture derived from neonatal rodent cortices. The result is a purified OPC population that can be differentiated into an OL-enriched culture. This approach is appealing due to its relatively short culture time and the unnecessary requirement for growth factors or immunopanning antibodies. While exploring the mechanisms of OL development in a purified culture is informative, it does not provide the most physiologically relevant environment for assessing myelin sheath formation. Co-culturing OLs with neurons would lend insight into the molecular underpinnings regulating OL-mediated myelination of axons. For many OL/neuron co-culture studies, dorsal root ganglion neurons (DRGNs) have proven to be the neuron type of choice. They are ideal for co-culture with OLs due to their ease of extraction, minimal amount of contaminating cells, and formation of dense neurite beds. While studies using rat/mouse myelinating xenocultures have been published (4-6), a method for the derivation of such OL/DRGN myelinating co-cultures from post-natal murine tissue has not been described. Here we present detailed methods on how to effectively produce such cultures, along with examples of expected results. These methods are useful for addressing questions relevant to OL development/myelinating function, and are useful tools in the field of neuroscience.

Published

2011

4. Smn deficiency causes neuritogenesis and neurogenesis defects in the retinal neurons of a mouse model of spinal muscular atrophy.

Author

Liu H, Beauvais A, Baker AN, Tsilfidis C, and Kothary R

Subjects

Animals, Blotting, Western, Cells, Cultured, Disease Models, Animal, Electroretinography, Gene Expression, Gene Expression Profiling, Immunohistochemistry, In Situ Nick-End Labeling, Mice, Mice, Inbred C57BL, Mice, Mutant Strains, Muscular Atrophy, Spinal genetics, Muscular Atrophy, Spinal pathology, Neurons cytology, Optic Nerve cytology, Optic Nerve metabolism, Retina cytology, Retina pathology, Reverse Transcriptase Polymerase Chain Reaction, Survival of Motor Neuron 1 Protein genetics, Muscular Atrophy, Spinal metabolism, Neurogenesis physiology, Neurons metabolism, Retina metabolism, Survival of Motor Neuron 1 Protein metabolism

Abstract

The eye is an excellent model for the study of neuronal development and pathogenesis of central nervous system disorders because of its relative ease of accessibility and the well-characterized cellular makeup. We have used this model to study spinal muscular atrophy (SMA), an autosomal recessive neuromuscular disease caused by deletions or mutations in the survival of motor neuron 1 gene (SMN1). We have investigated the expression pattern of mouse Smn mRNA and protein in the neural retina and the optic nerve of wild type mice. Smn protein is present in retinal ganglion cells and amacrine cells within the neural retina as well as in glial cells in the optic nerve. Histopathological analysis in phenotype stage SMA mice revealed that Smn deficiency is associated with a reduction in ganglion cell axon and glial cell number in the optic nerve, as well as compromised cellular processes and altered organization of neurofilaments in the neural retina. Whole mount preparation and retinal neuron primary culture provided further evidence of abnormal synaptogenesis and neurofilament accumulation in the neurites of Smn-deficient retinal neurons. A subset of amacrine cells is absent, in a cell-autonomous fashion, in the retina of SMA mice. Finally, the retinas of SMA mice have altered electroretinograms. Altogether, our study has demonstrated defects in axodendritic outgrowth and cellular composition in Smn-depleted retinal neurons, indicating a role for Smn in neuritogenesis and neurogenesis, and providing us with an insight into pathogenesis of SMA., (Copyright © 2010 Wiley Periodicals, Inc.)

Published

2011

5. Neurodevelopmental abnormalities in neurosphere-derived neural stem cells from SMN-depleted mice.

Author

Shafey D, MacKenzie AE, and Kothary R

Subjects

Animals, Apoptosis physiology, Blotting, Western, Cell Proliferation, Fluorescent Antibody Technique, In Situ Nick-End Labeling, Mice, Mice, Transgenic, Neurons metabolism, Stem Cells metabolism, Survival of Motor Neuron 1 Protein genetics, Cell Differentiation physiology, Neurons cytology, Stem Cells cytology, Survival of Motor Neuron 1 Protein metabolism

Abstract

Spinal muscular atrophy (SMA) is a genetic disorder caused by depletion of survival motor neuron (SMN) protein and characterized by degeneration of alpha-motor neurons in the spinal cord. We investigated the morphology and differentiation of neurosphere-derived neural stem cells (NSCs) generated from the brains of a hypomorphic series of SMA mice. Neurospheres from the Smn(-/-);SMN2 mice, which represent a model of very severe SMA, produced NSCs with increased proliferation during growth and differentiation. These cells produced fewer Tuj1-positive neuronal cells, which displayed morphological alterations and had fewer and shorter neurites. The decrease in the number of Tuj1-positive cells was not a result of enhanced apoptosis but was accompanied by an increase in the number of nestin-positive cells. These results provide insight into the most severe model of SMA, in which SMN is nearly completely depleted, and suggest that SMN has a role in neurodevelopment as well as in neuromaintenance. Our work raises the possibility that SMN depletion affects neurodevelopment and neuromaintenance to varying extents, leading to SMA pathogenesis., ((c) 2008 Wiley-Liss, Inc.)

Published

2008

6. A SMNDelta7 read-through product confers functionality to the SMNDelta7 protein.

Author

Mattis VB, Bowerman M, Kothary R, and Lorson CL

Subjects

Animals, Humans, Muscular Atrophy, Spinal genetics, SMN Complex Proteins, Survival of Motor Neuron 1 Protein, Survival of Motor Neuron 2 Protein, Transcription, Genetic, Transfection, Cyclic AMP Response Element-Binding Protein physiology, Nerve Tissue Proteins physiology, Neurons physiology, RNA-Binding Proteins physiology

Abstract

Spinal muscular atrophy (SMA) affects about 1 in every 6000 children born and is the leading genetic cause of infant death. SMA is a recessive disorder caused by the mutation or deletion of Survival Motor Neuron-1 (SMN1). SMN2, a nearly identical copy gene, has the potential to encode the same protein as SMN1 and is retained in all SMA patients. The majority of SMN2-derived transcripts are alternatively spliced and therefore encode a truncated isoform lacking exon 7 (SMNDelta7), which is a defective protein because it is unstable, has a reduced ability to self-associate and is unable to efficiently function in SMN cellular activities. However, we have shown that the SMN C-terminus functions non-specifically, since heterologous sequences can compensate for the exon 7 sequence. Several classes of compounds identified in SMN-inducing high throughput screens have been proposed to function through a read-through mechanism; however, a functional analysis of the SMNDelta7 read-through product has not been performed. In this report, the SMNDelta7 read-through product is characterized and compared to the SMNDelta7 protein. In a series of in vitro and cell based assays, SMNDelta7 read-through product is shown to increase protein stability, promote neurite outgrowths in SMN deficient neurons, and significantly elevate SMN-dependent UsnRNP assembly in extracts from SMA patient fibroblasts. Collectively, these results demonstrate that SMNDelta7 read-through product is more active than the SMNDelta7 protein and suggest that SMA therapeutics that specifically induce SMNDelta7 read-through may provide an alternative platform for drug discovery.

Published

2008

7. Dystonin/Bpag1--a link to what?

Author

Young KG and Kothary R

Subjects

Amino Acid Sequence, Animals, Carrier Proteins chemistry, Carrier Proteins genetics, Cytoskeletal Proteins chemistry, Cytoskeletal Proteins genetics, Dystonin, Mice, Mice, Mutant Strains, Molecular Sequence Data, Muscles metabolism, Nerve Tissue Proteins chemistry, Nerve Tissue Proteins genetics, Neurodegenerative Diseases genetics, Neurodegenerative Diseases metabolism, Carrier Proteins physiology, Cytoskeletal Proteins physiology, Nerve Tissue Proteins physiology, Neurodegenerative Diseases etiology, Neurons metabolism

Abstract

The dystonin/Bpag1 cytoskeletal interacting proteins play important roles in maintaining cytoarchitecture integrity in skin and in the neuromuscular system. The most profound phenotype observed in the dystonin mutant dystonia musculorum (dt) mice is a severe movement disorder, attributed in large part to sensory neuron degeneration. The molecular basis for this phenotype is currently not clear, despite several studies indicating possible causes for the pathology in dt mice. Complicating the picture of what essential dystonin functions are lost in dt mice is the fact that our understanding of the very nature of what dystonin is has evolved greatly over the past decade. Elucidating the roles of dystonin most relevant to neuronal function and survival should help to shed light on some of the common mechanisms underlying neurodegeneration.

Published

2007

8. Re: "A possible cellular mechanism of neuronal loss in the dorsal root ganglia of dystonia musculorum (dt) mice".

Author

Young KG, De Repentigny Y, and Kothary R

Subjects

Animals, Cell Death, Mice, Mice, Neurologic Mutants, Dystonia Musculorum Deformans pathology, Ganglia, Spinal pathology, Neurons physiology

Published

2007

9. Smn depletion alters profilin II expression and leads to upregulation of the RhoA/ROCK pathway and defects in neuronal integrity.

Author

Bowerman M, Shafey D, and Kothary R

Subjects

Adrenal Gland Neoplasms genetics, Adrenal Gland Neoplasms pathology, Animals, Cell Differentiation, Cyclic AMP Response Element-Binding Protein genetics, Immunoblotting, Nerve Tissue Proteins genetics, Neurons pathology, PC12 Cells, Pheochromocytoma genetics, Pheochromocytoma pathology, Protein Isoforms genetics, RNA-Binding Proteins genetics, Rats, Reverse Transcriptase Polymerase Chain Reaction, SMN Complex Proteins, Survival of Motor Neuron 1 Protein, Cyclic AMP Response Element-Binding Protein deficiency, Gene Expression Regulation, Neoplastic, Nerve Tissue Proteins deficiency, Neurons physiology, Profilins genetics, rho-Associated Kinases genetics, rhoA GTP-Binding Protein genetics

Abstract

Spinal muscular atrophy (SMA) is the most common genetic disease resulting in infant mortality due to severe loss of alpha-motor neurons. SMA is caused by mutations or deletions of the ubiquitously expressed survival motor neuron (SMN) gene. However, why alpha-motor neurons of SMA patients are specifically affected is not clear. We demonstrate here that Smn knockdown in PC12 cells alters the expression pattern of profilin II, resulting in an increase in the neuronal-specific profilin IIa isoform. Moreover, the depletion of Smn, a known interacting partner of profilin IIa, further contributes to the increased profilin IIa availability. Altogether, this leads to an increased formation of ROCK/profilin IIa complex and an inappropriate activation of the RhoA/ROCK pathway, resulting in altered cytoskeletal integrity and a subsequent defect in neuritogenesis. This study represents the first description of a mechanism underlying SMA pathogenesis and highlights new targets for therapeutic intervention for this devastating disorder.

Published

2007

10. Chx10 repression of Mitf is required for the maintenance of mammalian neuroretinal identity.

Author

Horsford DJ, Nguyen MT, Sellar GC, Kothary R, Arnheiter H, and McInnes RR

Subjects

Animals, Cell Lineage, Eye embryology, In Situ Hybridization, Mice, Mice, Inbred C57BL, Mice, Transgenic, Microphthalmia-Associated Transcription Factor, Microscopy, Fluorescence, Models, Biological, Mutation, Phenotype, Plasmids metabolism, Retina cytology, Retina metabolism, Time Factors, Transgenes, DNA-Binding Proteins metabolism, Gene Expression Regulation, Developmental, Homeodomain Proteins physiology, Neurons metabolism, Retina embryology, Transcription Factors metabolism, Transcription Factors physiology

Abstract

During vertebrate eye development, the cells of the optic vesicle (OV) become either neuroretinal progenitors expressing the transcription factor Chx10, or retinal pigment epithelium (RPE) progenitors expressing the transcription factor Mitf. Chx10 mutations lead to microphthalmia and impaired neuroretinal proliferation. Mitf mutants have a dorsal RPE-to-neuroretinal phenotypic transformation, indicating that Mitf is a determinant of RPE identity. We report here that Mitf is expressed ectopically in the Chx10(or-J/or-J) neuroretina (NR), demonstrating that Chx10 normally represses the neuroretinal expression of Mitf. The ectopic expression of Mitf in the Chx10(or-J/or-J) NR deflects it towards an RPE-like identity; this phenotype results not from a failure of neuroretinal specification, but from a partial loss of neuroretinal maintenance. Using Chx10 and Mitf transgenic and mutant mice, we have identified an antagonistic interaction between Chx10 and Mitf in regulating retinal cell identity. FGF (fibroblast growth factor) exposure in a developing OV has also been shown to repress Mitf expression. We demonstrate that the repression of Mitf by FGF is Chx10 dependent, indicating that FGF, Chx10 and Mitf are components of a pathway that determines and maintains the identity of the NR.

Published

2005

11. Impaired fast axonal transport in neurons of the sciatic nerves from dystonia musculorum mice.

Author

De Repentigny Y, Deschênes-Furry J, Jasmin BJ, and Kothary R

Subjects

Acetylcholinesterase metabolism, Animals, Axons enzymology, Axons pathology, Axons ultrastructure, Brain enzymology, Cytoskeletal Proteins deficiency, Cytoskeletal Proteins genetics, Cytoskeleton pathology, Cytoskeleton ultrastructure, Disease Models, Animal, Dystonic Disorders genetics, Dystonin, Ganglia, Spinal enzymology, Ligation, Mice, Mice, Neurologic Mutants, Muscle, Skeletal enzymology, Nerve Tissue Proteins deficiency, Nerve Tissue Proteins genetics, Neurons enzymology, Neurons pathology, Sciatic Nerve enzymology, Sciatic Nerve pathology, Spinal Cord enzymology, Axonal Transport genetics, Carrier Proteins, Dystonic Disorders physiopathology, Neurons metabolism, Sciatic Nerve physiopathology

Abstract

Dystonia musculorum (dt) mice suffer from a severe sensory neuropathy caused by mutations in the gene encoding the cytoskeletal cross-linker protein dystonin/bullous pemphigoid antigen 1 (Bpag1). Loss of function of dystonin/Bpag1 within neurons leads to a loss in the maintenance of cytoskeletal organization and to the development of focal axonal swellings prior to death of the neuron. In the present study, we demonstrate that neurons within the sciatic nerves of dt27J mice undergo axonal degeneration as has been previously reported for the dorsal roots. Furthermore, ultrastructural studies reveal a perturbed organization of the neurofilament and microtubule networks within the axons of sciatic nerves in dt27J mice. The disrupted cytoskeletal organization suggested that axonal transport is affected in dt mice. To address this, we assessed fast axonal transport by measuring the rate of accumulation of acetylcholinesterase (AChE) proximal and distal to a surgically introduced ligature on the sciatic nerves of normal and dt27J mice. Our findings demonstrate that axonal transport of AChE in both orthograde and retrograde directions is markedly affected, and allow us to conclude that axonal transport defects do exist in the sciatic nerves of dt27J mice.

Published

2003

12. Dystonin is essential for maintaining neuronal cytoskeleton organization.

Author

Dalpé G, Leclerc N, Vallée A, Messer A, Mathieu M, De Repentigny Y, and Kothary R

Subjects

Animals, Animals, Newborn, Carrier Proteins genetics, Carrier Proteins physiology, Cells, Cultured, Cytoskeletal Proteins genetics, Cytoskeletal Proteins immunology, Cytoskeleton metabolism, Cytoskeleton pathology, Dystonin, Ganglia, Spinal pathology, Immune Sera chemistry, Immunohistochemistry, Mice, Mice, Neurologic Mutants, Microtubule-Associated Proteins metabolism, Molecular Weight, Nerve Tissue Proteins genetics, Nerve Tissue Proteins immunology, Nervous System metabolism, Organ Specificity, Rats, Cytoskeletal Proteins physiology, Cytoskeleton physiology, Nerve Tissue Proteins physiology, Neurons physiology

Abstract

The mouse neurological mutant dystonia musculorum (dt) suffers from a hereditary sensory neuropathy. We have previously described the cloning and characterization of the dt gene, which we named dystonin (Dst). We had shown that dystonin is a neural isoform of bullous pemphigoid antigen 1 (Bpag1) with an N-terminal actin-binding domain. It has been shown previously that dystonin is a cytoskeletal linker protein, forming a bridge between F-actin and intermediate filaments. Here, we have used two different antibody preparations against dystonin and detected a high-molecular-weight protein in immunoblot analysis of spinal cord extracts. We also show that this high-molecular-weight protein was not detectable in the nervous system of all dt alleles tested. Immunohistochemical analysis revealed that dystonin was present in different compartments of neurons--cell bodies, dendrites, and axons, regions which are rich in the three elements of the cytoskeleton (F-actin, neurofilaments, and microtubules). Ultrastructural analysis of dt dorsal root axons revealed disorganization of the neurofilament network and surprisingly also of the microtubule network. In this context it is of interest that we observed altered levels of the microtubule-associated proteins MAP2 and tau in spinal cord neurons of different dt alleles. Finally, dt dorsal root ganglion neurons formed neurites in culture, but the cytoskeleton was disorganized within these neurites. Our results demonstrate that dystonin is essential for maintaining neuronal cytoskeleton integrity but is not required for establishing neuronal morphology.

Published

1998

13. Dystonin expression in the developing nervous system predominates in the neurons that degenerate in dystonia musculorum mutant mice.

Author

Bernier G, Brown A, Dalpé G, De Repentigny Y, Mathieu M, and Kothary R

Subjects

Animals, Axonal Transport, Axons pathology, Blotting, Northern, Dystonia genetics, Dystonia pathology, Dystonin, Embryo, Mammalian, Embryonic and Fetal Development, In Situ Hybridization, Mice, Mice, Inbred Strains, Mice, Neurologic Mutants, Motor Activity, Neurons, Afferent physiology, Brain physiopathology, Carrier Proteins, Cytoskeletal Proteins biosynthesis, Dystonia physiopathology, Gene Expression Regulation, Developmental, Nerve Degeneration, Nerve Tissue Proteins biosynthesis, Neurons metabolism, Spinal Cord physiopathology

Abstract

Dystonia musculorum (dt) is an inherited neurodegenerative disorder in mice. The dt gene product, dystonin, contains the bullous pemphigoid antigen 1 coding region at its C-terminus and an actin binding domain at its N-terminus. We demonstrate that dystonin expression throughout mouse development predominates in neurons of the cranial and spinal sensory ganglia. These structures are the most severely affected in dystonic mice which could explain their severe sensory ataxia. Since we show expression in sensory neurons with small and large axoplasmic volumes, but degeneration is restricted primarily to the latter type, we suggest that caliber and size of the axon is an important factor in the disease process. Dystonin is also expressed in the extrapyramidal motor system and in the cerebellum. Functional defects in these cell types could account for the dystonic symptoms of dt mice not explained by simple sensory denervation. We also detect dystonin expression in motor neurons most of which are unaffected by the degenerative process in dt mice.

Published

1995