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Author: Jack Tzu-Chieh Wang Publisher: ISBN: Category : Languages : en Pages :
Book Description
Axonal degeneration is a pivotal pathological event in most CNS and PNS diseases, but the molecular mechanisms that control this process remain unclear. Expression of the Wallerian degeneration slow (WldS) transgene robustly delays axon degeneration in various injury models and attenuate disease progression in many neurodegenerative conditions, indicating a common mechanism of axonal self-destruction in traumatic injuries and chronic degenerative events. In this thesis, I examined the mechanism of WldS axon protection as a window to understand the molecular events that orchestrate this axonal self-destruction program. In the first part of my thesis, I demonstrated that continuous, local WldS enzymatic activity in the axon, independent of nuclear gene transcription, is required to confer axonal protection. Furthermore, I showed that injured axons are not immediately committed to degeneration, but rather there is a critical period of 4-5hrs after injury in which the course of degeneration can be reversed. The presence of this latency period before the injured axons irreversibly commit to degeneration suggest that axonal degeneration can be attenuated or halted altogether even long after an injury has occurred. In the second part of the thesis, I investigated the signaling events and mechanisms that are responsible for translating WldS activity into axonal protection. I showed that NAD+, a metabolite of WldS enzymatic activity and a known redox cofactor in the mitochondria, is sufficient and specific to confer WldS-like axon protection. However, WldS axonal protection does not require the axonal mitochondria or involve changes in the bioenergy levels of the axon. I further demonstrated that independently increasing expression of Ca2+ buffering proteins in subcellular compartments is sufficient to delay axonal degeneration, suggesting that enhancement of Ca2+ buffering capacity in axonal subcellular compartments may be one mechanism by which WldS activity or NAD+ confers axonal protection. Finally, comparing the metabolomics profile of WT vs. WldS neurons reveals candidates in mediating NAD+ dependent regulation of intra-axonal Ca2+, and presents potential therapeutic targets to delay axon degeneration. In the third part of my thesis, I investigated the relationship between developmental axonal outgrowth, synaptic targeting and axon regeneration. Using retinal ganglion cells (RGCs) as a model system, I profiled the developmental expression of RGC genes from early embryonic to early postnatal development, a period that was previously shown to trigger a genetic switch to significantly slow the axonal growth rate. In particular, I showed that cyp1b1, a gene implicated in congenital glaucoma, is a potent source of retinoic acid during early RGC development and enhances RGC survival by sustaining retinoic acid production. In addition, several other genes from the expression profiling have been found by others to be involved in axonal regeneration after injury. Together, the findings provide a rich database for understanding the molecular signatures that control the development of retinal ganglion cells, and help uncover genetic factors that regulate axonal growth, targeting and regeneration.
Author: Jack Tzu-Chieh Wang Publisher: ISBN: Category : Languages : en Pages :
Book Description
Axonal degeneration is a pivotal pathological event in most CNS and PNS diseases, but the molecular mechanisms that control this process remain unclear. Expression of the Wallerian degeneration slow (WldS) transgene robustly delays axon degeneration in various injury models and attenuate disease progression in many neurodegenerative conditions, indicating a common mechanism of axonal self-destruction in traumatic injuries and chronic degenerative events. In this thesis, I examined the mechanism of WldS axon protection as a window to understand the molecular events that orchestrate this axonal self-destruction program. In the first part of my thesis, I demonstrated that continuous, local WldS enzymatic activity in the axon, independent of nuclear gene transcription, is required to confer axonal protection. Furthermore, I showed that injured axons are not immediately committed to degeneration, but rather there is a critical period of 4-5hrs after injury in which the course of degeneration can be reversed. The presence of this latency period before the injured axons irreversibly commit to degeneration suggest that axonal degeneration can be attenuated or halted altogether even long after an injury has occurred. In the second part of the thesis, I investigated the signaling events and mechanisms that are responsible for translating WldS activity into axonal protection. I showed that NAD+, a metabolite of WldS enzymatic activity and a known redox cofactor in the mitochondria, is sufficient and specific to confer WldS-like axon protection. However, WldS axonal protection does not require the axonal mitochondria or involve changes in the bioenergy levels of the axon. I further demonstrated that independently increasing expression of Ca2+ buffering proteins in subcellular compartments is sufficient to delay axonal degeneration, suggesting that enhancement of Ca2+ buffering capacity in axonal subcellular compartments may be one mechanism by which WldS activity or NAD+ confers axonal protection. Finally, comparing the metabolomics profile of WT vs. WldS neurons reveals candidates in mediating NAD+ dependent regulation of intra-axonal Ca2+, and presents potential therapeutic targets to delay axon degeneration. In the third part of my thesis, I investigated the relationship between developmental axonal outgrowth, synaptic targeting and axon regeneration. Using retinal ganglion cells (RGCs) as a model system, I profiled the developmental expression of RGC genes from early embryonic to early postnatal development, a period that was previously shown to trigger a genetic switch to significantly slow the axonal growth rate. In particular, I showed that cyp1b1, a gene implicated in congenital glaucoma, is a potent source of retinoic acid during early RGC development and enhances RGC survival by sustaining retinoic acid production. In addition, several other genes from the expression profiling have been found by others to be involved in axonal regeneration after injury. Together, the findings provide a rich database for understanding the molecular signatures that control the development of retinal ganglion cells, and help uncover genetic factors that regulate axonal growth, targeting and regeneration.
Author: Elisabetta Babetto Publisher: Humana ISBN: 9781071605844 Category : Science Languages : en Pages : 0
Book Description
This book is a collection of classical as well as innovative methods used to investigate axon degeneration with a particular focus on addressing the common challenges encountered while performing these procedures. Particular attention is devoted to the study of axon loss in several model organisms, as each poses unique challenges and provides powerful advantages. Written for the highly successful Methods in Molecular Biology series, chapters include introductions to their respective topics, lists of the necessary materials, step-by-step, readily reproducible laboratory protocols, and tips on troubleshooting and avoiding known pitfalls. Authoritative and practical, Axon Degeneration: Methods and Protocols is an ideal guide for facilitating the application and further development of these protocols, which will help the scientific community tackle important questions regarding axon degeneration. Chapters 2, 3, and 20 are available Open Access under a Creative Commons Attribution 4.0 International License via link.springer.com.
Author: Stephen G. Waxman Publisher: ISBN: 0195082931 Category : Axons Languages : en Pages : 710
Book Description
The axon, interposed between the cell body and the synaptic terminals in most neurons, plays a crucial role in connecting neurons and acting as a conduit for the transmission of information between them. This book provides a comprehensive and up-to-date compendium that brings together chapterson the structure, function, and pathophysiology of axons in both the PNS and CNS. Carefully written, well-illustrated with superb illustrations, and generously referenced, the 33 chapters and introduction have been authored by 49 world-renowned authorities. Recent advances in the molecularneurobiology of axons are carefully reviewed, and new areas, such as the molecular biology of ion channels and myelination, the role of calcium in pathophysiology and regeneration, cell adhesion molecules and their roles in axo-glial interactions and axonal guidance, and optical recording methods,are highlighted. This book will provide an essential reference for neuroscientists as well as clinicians such as neurologists, neurosurgeons, and clinical electrophysiologists interested in axons.
Author: Karun K. Singh Publisher: ISBN: 9780494579275 Category : Languages : en Pages : 382
Book Description
The formation of neural connections in the mammalian nervous system is a complex process. During development, axons are initially overproduced and compete for limited quantities of target-derived growth factors. Axons which participate in functional circuits and secure appropriate amounts of growth factors are stabilized, while those axons that are either inappropriately connected or do not obtain sufficient concentrations of growth factors are eliminated in a process termed 'axon pruning'. In this thesis, I examined the mechanisms that regulate pruning of peripheral, NGF-dependent sympathetic neurons that project to the eye. I determined that pruning of these projections in vivo requires the p75 neurotrophin receptor (p75NTR) and synthesis of brain-derived neurotrophic factor (BDNF) from the activity-dependent exon IV promoter. Furthermore, analysis of an in vitro model of axon competition, which is regulated by the interplay between nerve growth factor (NGF) and neuronal activity, revealed that p75NTR and BDNF are also essential for axon competition in culture. In this model, in the presence of NGF, neural activity confers a competitive growth advantage to stimulated, active axons by enhancing downstream TrkA (NGF receptor) signaling locally in axons. More interestingly, the unstimulated, inactive axons deriving from the same and neighboring neurons acquire a "growth disadvantage" due to secreted BDNF acting through p75NTR, which induces axon degeneration by suppressing TrkA signaling that is essential for axonal integrity. These data support a model where, during developmental axon competition, successful axons secrete BDNF in an activity-dependent fashion which activates p75NTR on unsuccessful neighboring axons, suppressing TrkA signaling, and ultimately promoting pruning by a degenerative mechanism.
Author: Edward Koenig Publisher: Springer Science & Business Media ISBN: 364203019X Category : Science Languages : en Pages : 369
Book Description
Recent years have witnessed striking advances in research on axons at a cellular level that substantially impact our current understanding of axonal biology. Newer findings and their ramifications are critically reviewed in the 16 chapters of this volume by authors highly qualified by virtue of their scientific contributions to research areas they know and write about. Five basic areas (I to V) germane to axonal biology are highlighted, beginning with (I) signaling interactions mediating myelination, and differentiation of axonal membrane domains; (IIa) issues surrounding organization and transport dynamics of neurofilaments in axons, (IIb) mechanisms regulating microtubule organization and dynamics, misregulation of which causes axonal degeneration, and (IIc) the roles actin binding proteins play in regulating organization and functions of the actin filament system in mature and growing axons; (IIIa) myosin motor proteins and cargoes intrinsic to the axon compartment, (IIIb) mitochondrial transport motors, and imperatives governing transport dynamics and directional delivery, (IIIc) mechanisms mediating retrograde signaling associated with NGF’s role in trophic-dependent neuronal survival, and (IIId) potential for impaired subcellular targeting of a -synuclein as a mechanism for accumulation of Lewy body inclusions in synucleinopathies; (IVa) occurrence and organization of discrete ribosome-containing domains in axons, (IVb) endogenous mRNAs, classes of proteins translated locally, and RNP trafficking in axons, (IVc) importance of locally synthesized nuclear encoded mitochondrial proteins for maintenance, function and survival of axons, (IVd) occurrence of RNA trafficking from glial cells to axons, and significance glial RNA transcripts may play in expression in axons and axon terminals, (IVe) RNA trafficking and localization of RNA transcripts in axonal growth cones, and signaling pathways that modulate local protein synthesis for directional elongation, and (IVf) genetic and molecular defects underlying spinal muscular atrophy, and roles that SMN gene product plays as a molecular chaperone in mRNA transport and translation; (Va) injury-induced local synthesis of a protein forming a retrograde signaling complex in axons to stimulate regeneration, and (Vb) endogenous and exogenous factors that condition axonal regenerative capacity in PNS and CNS, including injury-induced activation of specific genes governing regeneration. Emergent complexities revealed in this volume compel a major revision in the traditional conceptual model of the axon’s intrinsic makeup and capacities.
Author: Jack Tzu-Chieh Wang
Author: Jack Tzu-Chieh Wang
Author: Elisabetta Babetto
Author: Stephen G. Waxman
Author: Asli Dedeagac
Author: Ryan Jefferson Watts
Author: Lawrence Kong Low
Author: Karun Singh
Author: Karun K. Singh
Author: Jens Schmidt
Author: Edward Koenig