Your search keyword '"Ruff CA"' showing total 2 results

1. Neuronal c-Jun is required for successful axonal regeneration, but the effects of phosphorylation of its N-terminus are moderate.

Author

Ruff CA, Staak N, Patodia S, Kaswich M, Rocha-Ferreira E, Da Costa C, Brecht S, Makwana M, Fontana X, Hristova M, Rumajogee P, Galiano M, Bohatschek M, Herdegen T, Behrens A, and Raivich G

Subjects

Animals, Atrophy, Axons ultrastructure, Cell Death, Female, Hyaluronan Receptors metabolism, Male, Mice, Mice, Knockout, Mitogen-Activated Protein Kinase 10 genetics, Mitogen-Activated Protein Kinase 10 physiology, Mitogen-Activated Protein Kinase 8 genetics, Mitogen-Activated Protein Kinase 8 physiology, Mitogen-Activated Protein Kinase 9 genetics, Mitogen-Activated Protein Kinase 9 physiology, Motor Neurons physiology, Nerve Regeneration genetics, Neurons ultrastructure, Phosphorylation, Point Mutation physiology, Proto-Oncogene Proteins c-jun genetics, Axons physiology, Nerve Regeneration physiology, Neurons physiology, Proto-Oncogene Proteins c-jun physiology

Abstract

Although neural c-Jun is essential for successful peripheral nerve regeneration, the cellular basis of this effect and the impact of c-Jun activation are incompletely understood. In the current study, we explored the effects of neuron-selective c-Jun deletion, substitution of serine 63 and 73 phosphoacceptor sites with non-phosphorylatable alanine, and deletion of Jun N-terminal kinases 1, 2 and 3 in mouse facial nerve regeneration. Removal of the floxed c-jun gene in facial motoneurons using cre recombinase under control of a neuron-specific synapsin promoter (junΔS) abolished basal and injury-induced neuronal c-Jun immunoreactivity, as well as most of the molecular responses following facial axotomy. Absence of neuronal Jun reduced the speed of axonal regeneration following crush, and prevented most cut axons from reconnecting to their target, significantly reducing functional recovery. Despite blocking cell death, this was associated with a large number of shrunken neurons. Finally, junΔS mutants also had diminished astrocyte and microglial activation and T-cell influx, suggesting that these non-neuronal responses depend on the release of Jun-dependent signals from neighboring injured motoneurons. The effects of substituting serine 63 and 73 phosphoacceptor sites (junAA), or of global deletion of individual kinases responsible for N-terminal c-Jun phosphorylation were mild. junAA mutants showed decrease in neuronal cell size, a moderate reduction in post-axotomy CD44 levels and slightly increased astrogliosis. Deletion of Jun N-terminal kinase (JNK)1 or JNK3 showed delayed functional recovery; deletion of JNK3 also interfered with T-cell influx, and reduced CD44 levels. Deletion of JNK2 had no effect. Thus, neuronal c-Jun is needed in regeneration, but JNK phosphorylation of the N-terminus mostly appears to not be required for its function., (© 2012 The Authors. Journal of Neurochemistry © 2012 International Society for Neurochemistry.)

Published

2012

2. Neural stem cells in regenerative medicine: bridging the gap.

Author

Ruff CA and Fehlings MG

Subjects

Animals, Cell Differentiation, Cell Lineage, Cell Proliferation, Cell Survival, Clinical Trials as Topic, Humans, Nerve Regeneration, Neurons pathology, Spinal Cord Injuries pathology, Spinal Cord Injuries physiopathology, Treatment Outcome, Induced Pluripotent Stem Cells transplantation, Neurons transplantation, Regenerative Medicine, Spinal Cord Injuries surgery, Stem Cell Transplantation

Abstract

Repair of the chronically injured spinal presents with multiple challenges, including neuronal/axonal loss and demyelination as a result of primary injury (usually a physical insult), as well as secondary damage, which includes ischemia, inflammation, oxidative injury and glutamatergic toxicity. These processes cause neuronal loss, axonal disruption and lead to a cystic degeneration and an inhibitory astroglial scar. A promising therapeutic intervention for SCI is the use of neural stem cells. Cell replacement strategies using neural precursor cells (NPCs) and oligodendroglial precursor cells (OPCs) have been shown to replace lost/damaged cells, secrete trophic factors, regulate gliosis and scar formation, reduce cystic cavity size and axonal dieback, as well as to enhance plasticity, axonal elongation and neuroprotection. These progenitor cells can be obtained through a variety of sources, including adult neural tissue, embryonic blastocysts and adult somatic cells via induced pluripotent stem cell (iPSC) technology. The use of stem cell technology - especially autologous cell transplantation strategies - in regenerative therapy for SCI holds much promise; these therapies show high potential for clinical translation and for future disease treatment.

Published

2010