Your search keyword '"axonal regeneration"' showing total 19 results

1. Genes in Axonal Regeneration.

Author

Wu, Wenshuang, Zhang, Jing, Chen, Yu, Chen, Qianqian, Liu, Qianyan, Zhang, Fuchao, Li, Shiying, and Wang, Xinghui

Abstract

This review explores the molecular and genetic underpinnings of axonal regeneration and functional recovery post-nerve injury, emphasizing its significance in reversing neurological deficits. It presents a systematic exploration of the roles of various genes in axonal regrowth across peripheral and central nerve injuries. Initially, it highlights genes and gene families critical for axonal growth and guidance, delving into their roles in regeneration. It then examines the regenerative microenvironment, focusing on the role of glial cells in neural repair through dedifferentiation, proliferation, and migration. The concept of "traumatic microenvironments" within the central nervous system (CNS) and peripheral nervous system (PNS) is discussed, noting their impact on regenerative capacities and their importance in therapeutic strategy development. Additionally, the review delves into axonal transport mechanisms essential for accurate growth and reinnervation, integrating insights from proteomics, genome-wide screenings, and gene editing advancements. Conclusively, it synthesizes these insights to offer a comprehensive understanding of axonal regeneration's molecular orchestration, aiming to inform effective nerve injury therapies and contribute to regenerative neuroscience. [ABSTRACT FROM AUTHOR]

Published

2024

2. Mitochondria-Endoplasmic Reticulum Contact Sites (MERCS): A New Axis in Neuronal Degeneration and Regeneration.

Author

Sathyamurthy, Vijaya Harini, Nagarajan, Yoghalakshmi, and Parvathi, Venkatachalam Deepa

Abstract

Mitochondria-Endoplasmic Reticulum Contact Sites (MERCS) are dynamic structures whose physiological interaction is vital to direct life and death of the cell. A bevy of tethering proteins, mitofusin-1/2 (Mfn-1/2), glucose-regulated protein-75 (Grp-75), voltage-dependent anion channel-1 (VDAC1), and dynamic-related protein-1 (Drp1), plays an integral role in establishing and regulating this intricate intracellular communication. Dysregulation of this interplay leads to various neurodegenerative disorders, like Alzheimer's disease (AD), Parkinson's disease (PD), stroke, traumatic brain injury (TBI), amyotrophic lateral sclerosis (ALS), and frontotemporal dementia (FTD). Although there is an absence of a well-defined molecular background that dictates the pathway of MERCS, adequate exploration has resulted in preliminary data that suggests its cardinal role in neuroregeneration. The juxtaposition of mitochondria and ER has a critical function in cell senescence, thus regulating regeneration. Axonal regeneration and brain tissue regeneration, using reactive astrocytes, are studied most extensively. Overexpression of Grp-75 promoted axonal regeneration post a nerve injury. Attempts have been made to exploit MERCS as potential therapeutic drug targets for enhancing neuroregeneration and impeding neurodegeneration. Novel strategies have been developed to aid the delivery of mitochondria into the neuronal cell body, which in turn establishes a network with the presiding ER resulting in contact site formation. The fascinating aspect of this mechanism is that despite the lack of inherent regenerative capacity in neurons, it can be induced by modifying MERCS. [ABSTRACT FROM AUTHOR]

Published

2024

3. Unleashing Axonal Regeneration Capacities: Neuronal and Non-neuronal Changes After Injuries to Dorsal Root Ganglion Neuron Central and Peripheral Axonal Branches.

Author

Zhao, Qian, Jiang, Chunyi, Zhao, Li, Dai, Xiu, and Yi, Sheng

Abstract

Peripheral nerves obtain remarkable regenerative capacity while central nerves can hardly regenerate following nerve injury. Sensory neurons in the dorsal root ganglion (DRG) are widely used to decipher the dissimilarity between central and peripheral axonal regeneration as axons of DRG neurons bifurcate into the regeneration-incompetent central projections and the regeneration-competent peripheral projections. A conditioning peripheral branch injury facilitates central axonal regeneration and enables the growth and elongation of central axons. Peripheral axonal injury stimulates neuronal calcium influx, alters the start-point chromatin states, increases chromatin accessibility, upregulates the expressions of regeneration-promoting genes and the synthesis of proteins, and supports axonal regeneration. Following central axonal injury, the responses of DRG neurons are modest, resulting in poor intrinsic growth ability. Some non-neuronal cells in DRGs, for instance satellite glial cells, also exhibit diminished injury responses to central axon injury as compared with peripheral axon injury. Moreover, DRG central and peripheral axonal branches are respectively surrounded by inhibitory glial scars generated by central glial cells and a permissive microenvironment generated by Schwann cells and macrophages. The aim of this review is to look at changes of DRG neurons and non-neuronal cells after peripheral and central axon injuries and summarize the contributing roles of both neuronal intrinsic regenerative capacities and surrounding microenvironments in axonal regeneration. [ABSTRACT FROM AUTHOR]

Published

2024

4. Axonal Regeneration Mediated by a Novel Axonal Guidance Pair, Galectin-1 and Secernin-1.

Author

Yang, Ximeng and Tohda, Chihiro

Abstract

Galectin-1 (Gal-1), a member of the Galectin family, is expressed in various tissues and responsible for multiple biological activities. Previous studies reported that extracellular Gal-1 participated in axonal growth and repair, and Gal-1 knockout mice exhibited memory impairment. However, no study has demonstrated the direct contribution of intracellular Gal-1 upregulation in neurons to promoting axonal regeneration in the brain and recovering memory function. In the present study, we found that axonal growth is promoted by overexpression of Gal-1 via adeno-associated virus serotype 9 delivery in primary cultured hippocampal neurons. Moreover, Gal-1 was expressed on the membranes of growth cones in hippocampal neurons and interacted with a novel axonal guidance molecule, Secernin-1, which was secreted from prefrontal cortex (PFC) neurons. Gal-1-overexpression-driven axonal growth was enhanced when recombinant (extracellular) Secernin-1 was treated to the axonal site in a neuron device chamber. Direct binding of extracellular Secernin-1 with Gal-1 was detected through immunoprecipitation and immunocytochemistry, demonstrating that Gal-1 possibly works as an axonal guidance receptor for Secernin-1 in hippocampal neurons. In the PFC, the expression of Gal-1 in axonal shafts and terminals of hippocampal neurons was decreased in the 5XFAD mouse model of Alzheimer's disease (AD). Overexpression of Gal-1 in hippocampal neurons recovered memory deficits and induced axonal regeneration toward the PFC in 5XFAD mice. This study suggests that the enhanced interaction of Secernin-1 and Gal-1 can be harnessed as a therapeutic strategy for long-distance and direction-specific axonal regeneration in AD. [ABSTRACT FROM AUTHOR]

Published

2023

5. Collateral Sprouting of Peripheral Sensory Neurons Exhibits a Unique Transcriptomic Profile.

Author

Lemaitre, Dominique, Hurtado, Maica Llavero, De Gregorio, Cristian, Oñate, Maritza, Martínez, Gabriela, Catenaccio, Alejandra, Wishart, Thomas M., and Court, Felipe A.

Abstract

Peripheral nerve injuries result in motor and sensory dysfunction which can be recovered by compensatory or regenerative processes. In situations where axonal regeneration of injured neurons is hampered, compensation by collateral sprouting from uninjured neurons contributes to target reinnervation and functional recovery. Interestingly, this process of collateral sprouting from uninjured neurons has been associated with the activation of growth-associated programs triggered by Wallerian degeneration. Nevertheless, the molecular alterations at the transcriptomic level associated with these compensatory growth mechanisms remain to be fully elucidated. We generated a surgical model of partial sciatic nerve injury in mice to mechanistically study degeneration-induced collateral sprouting from spared fibers in the peripheral nervous system. Using next-generation sequencing and Ingenuity Pathway Analysis, we described the sprouting-associated transcriptome of uninjured sensory neurons and compare it with the activated by regenerating neurons. In vitro approaches were used to functionally assess sprouting gene candidates in the mechanisms of axonal growth. Using a novel animal model, we provide the first description of the sprouting transcriptome observed in uninjured sensory neurons after nerve injury. This collateral sprouting-associated transcriptome differs from that seen in regenerating neurons, suggesting a molecular program distinct from axonal growth. We further demonstrate that genetic upregulation of novel sprouting-associated genes activates a specific growth program in vitro, leading to increased neuronal branching. These results contribute to our understanding of the molecular mechanisms associated with collateral sprouting in vivo. The data provided here will therefore be instrumental in developing therapeutic strategies aimed at promoting functional recovery after injury to the nervous system. [ABSTRACT FROM AUTHOR]

Published

2020

6. Ancestral Folate Promotes Neuronal Regeneration in Serial Generations of Progeny.

Author

Patel, Nirav J., Hogan, Kirk J., Rizk, Elias, Stewart, Krista, Madrid, Andy, Vadakkadath Meethal, Sivan, Alisch, Reid, Borth, Laura, Papale, Ligia A., Ondoma, Solomon, Gorges, Logan R., Weber, Kara, Lake, Wendell, Bauer, Andrew, Hariharan, Nithya, Kuehn, Thomas, Cook, Thomas, Keles, Sunduz, Newton, Michael A., and Iskandar, Bermans J.

Abstract

Folate supplementation in F0 mating rodents increases regeneration of injured spinal axons in vivo in 4 or more generations of progeny (F1–F4) in the absence of interval folate administration to the progeny. Transmission of the enhanced regeneration phenotype to untreated progeny parallels axonal growth in neuron culture after in vivo folate administration to the F0 ancestors alone, in correlation with differential patterns of genomic DNA methylation and RNA transcription in treated lineages. Enhanced axonal regeneration phenotypes are observed with diverse folate preparations and routes of administration, in outbred and inbred rodent strains, and in two rodent genera comprising rats and mice, and are reversed in F4–F5 progeny by pretreatment with DNA demethylating agents prior to phenotyping. Uniform transmission of the enhanced regeneration phenotype to progeny together with differential patterns of DNA methylation and RNA expression is consistent with a non-Mendelian mechanism. The capacity of an essential nutritional co-factor to induce a beneficial transgenerational phenotype in untreated offspring carries broad implications for the diagnosis, prevention, and treatment of inborn and acquired disorders. [ABSTRACT FROM AUTHOR]

Published

2020

7. An Antagonistic Axon-Dendrite Interplay Enables Efficient Neuronal Repair in the Adult Zebrafish Central Nervous System.

Author

Beckers, An, Van Dyck, Annelies, Bollaerts, Ilse, Van houcke, Jessie, Lefevere, Evy, Andries, Lien, Agostinone, Jessica, Van Hove, Inge, Di Polo, Adriana, Lemmens, Kim, and Moons, Lieve

Abstract

Neural insults and neurodegenerative diseases typically result in permanent functional deficits, making the identification of novel pro-regenerative molecules and mechanisms a primary research topic. Nowadays, neuroregenerative research largely focuses on improving axonal regrowth, leaving the regenerative properties of dendrites largely unstudied. Moreover, whereas developmental studies indicate a strict temporal separation of axogenesis and dendritogenesis and thus suggest a potential interdependency of axonal and dendritic outgrowth, a possible axon-dendrite interaction during regeneration remains unexplored. To unravel the inherent dendritic response of vertebrate neurons undergoing successful axonal regeneration, regeneration-competent adult zebrafish of either sex, subjected to optic nerve crush (ONC), were used. A longitudinal study in which retinal ganglion cell (RGC) dendritic remodeling and axonal regrowth were assessed side-by-side after ONC, revealed that—as during development—RGC axogenesis precedes dendritogenesis during central nervous system (CNS) repair. Moreover, dendrites majorly shrank before the start of axonal regrowth and were only triggered to regrow upon RGC target contact initiation, altogether suggestive for a counteractive interplay between axons and dendrites after neuronal injury. Strikingly, both retinal mechanistic target of rapamycin (mTOR) and broad-spectrum matrix metalloproteinase (MMP) inhibition after ONC consecutively inhibited RGC synapto-dendritic deterioration and axonal regrowth, thus invigorating an antagonistic interplay wherein mature dendrites restrain axonal regrowth. Altogether, this work launches dendritic shrinkage as a prerequisite for efficient axonal regrowth of adult vertebrate neurons, and indicates that molecular/mechanistic analysis of dendritic responses after damage might represent a powerful target-discovery platform for neural repair. [ABSTRACT FROM AUTHOR]

Published

2019

8. TAT-PEP Enhanced Neurobehavioral Functional Recovery by Facilitating Axonal Regeneration and Corticospinal Tract Projection After Stroke.

Author

Deng, Bin, Li, Liya, Gou, Xingchun, Xu, Hao, Zhao, Zhaohua, Wang, Qiang, and Xu, Lixian

Abstract

Paired immunoglobulin-like receptor B (PirB) has been identified as a new receptor for myelin-associated inhibitory (MAI) proteins, which may play important role in axonal regeneration and corticospinal tract (CST) projection associated with neurobehavioral function recovery after stroke. Here, we found that the expression of PirB was increased in the cortical penumbra from 1 to 28 days after transient focal cerebral ischemic reperfusion of rats. Then, transactivator of transcription-PirB extracellular peptide (TAT-PEP) was generated that might block the interactions between MAIs and PirB. The results showed that TAT-PEP displayed high affinity for MAIs and ameliorated their inhibitory effect on neurite growth. Furthermore, TAT-PEP can widely distribute in the penumbra after intraperitoneal injection. Then, we found that TAT-PEP enhanced neurite growth and alleviated growth cone collapse after oxygen glucose deprivation (OGD) injury. In addition, TAT-PEP promoted long-term neurobehavioral functional recovery through enhancing axonal regeneration and CST projection. Finally, the observations demonstrated that POSH/RhoA/growth-associated protein 43 (GAP43) as PirB-associated downstream signaling molecules played important role in neurobehavioral functional recovery after stroke. Moreover, the underlying mechanism associated with TAT-PEP-mediated promoting axonal regeneration and CST projection was by intervening in the expression of POSH, RhoA, and GAP43. These studies suggest that TAT-PEP may represent an attractive therapeutic strategy against stroke. [ABSTRACT FROM AUTHOR]

Published

2018

9. Comparison of RNAi NgR and NEP1-40 in Acting on Axonal Regeneration After Spinal Cord Injury in Rat Models.

Author

Xu, Jing, He, Jian, He, Huang, Peng, Renjun, and Xi, Jian

Abstract

This study was intended to compare the therapeutic efficacies of NEP1-40 and SiNgR199 on treating spinal cord injury (SCI). Nogo-A, growth associated protein 43 (GAP-43), microtubule associated protein 2 (MAP-2), and amyloid βA4 precursor protein (APP) expressions were determined using western blot and quantitative PCR. Neurite outgrowth detected the growth of neurites, and BDA anterograde tracing was used to label the regenerated axonal. Rats' behavior was assessed with Basso, Beattie, and Bresnahan locomotor rating scale (BBB). Somatosensory evoked potentials (SEPs) and motor evoked potentials (MEPs) were recorded to evaluate the recovery of the sensory and motor systems. Successful establishment of SCI model was verified by immunocytochemical analysis. The increased expression of APP, as well as the decreased expression of GAP-43 and MAP-2, was observed in the SCI model group, but the trends were reversed after the treatments of NEP1-40, siNgR199, and NEP1-40 + siNgR199. Compared with the SCI group, the average neurite length and the BDA-positive fibers were increased in the NEP1-40, siNgR199, and NEP1-40 + siNgR199 groups. The rats in the siNgR199 group and the NEP1-40 + siNgR199 group both showed significantly higher BBB scores than SCI model group and NEP1-40 group. Suggested by electrophysiological evaluation, both the latency and the amplitude of SEPs as well as MEPs had recovered in the NEP1-40, siNgR199, and NEP1-40 + siNgR199 groups after SCI. Both NEP1-40 and siNgR had repairing effects on SCI, suggesting their role in facilitating axonal regeneration after SCI. [ABSTRACT FROM AUTHOR]

Published

2017

10. Matrix Metalloproteinases During Axonal Regeneration, a Multifactorial Role from Start to Finish.

Author

Andries, Lien, Van Hove, Inge, Moons, Lieve, and De Groef, Lies

Abstract

By proteolytic cleavage, matrix metalloproteinases (MMPs) not only remodel the extracellular matrix (ECM) but they also modify the structure and activity of other proteinases, growth factors, signaling molecules, cell surface receptors, etc. Their vast substrate repertoire adds a complex extra dimension of biological control and turns MMPs into important regulatory nodes in the protease web. In the central nervous system (CNS), the detrimental impact of elevated MMP activities has been well-described for traumatic injuries and many neurodegenerative diseases. Nonetheless, there is ample proof corroborating MMPs as fine regulators of CNS physiology, and well-balanced MMP activity is instrumental to development, plasticity, and repair. In this manuscript, we review the emerging evidence for MMPs as beneficial modulators of axonal regeneration in the mammalian CNS. By exploring the multifactorial causes underlying the inability of mature axons to regenerate, and describing how MMPs can help to overcome these hurdles, we emphasize the benign actions of these Janus-faced proteases. [ABSTRACT FROM AUTHOR]

Published

2017

11. Collateral Sprouting of Peripheral Sensory Neurons Exhibits a Unique Transcriptomic Profile

Author

Maritza Oñate, Gabriela Martínez, Thomas M. Wishart, Dominique Lemaitre, Maica Llavero Hurtado, Cristian De Gregorio, Alejandra Catenaccio, and Felipe A. Court

Subjects

0301 basic medicine, Nervous system, Nerve injury, Wallerian degeneration, Sensory Receptor Cells, Neurogenesis, Neuroscience (miscellaneous), Compensatory growth (organ), Sciatic nerve, Biology, 03 medical and health sciences, Cellular and Molecular Neuroscience, 0302 clinical medicine, Peripheral Nerve Injuries, Ganglia, Spinal, medicine, Animals, Peripheral Nerves, Myelin Sheath, Cell Proliferation, Collateral sprouting, Lumbar Vertebrae, Gene Expression Profiling, Sciatic nerve injury, medicine.disease, Sciatic Nerve, Mice, Inbred C57BL, 030104 developmental biology, medicine.anatomical_structure, Gene Expression Regulation, nervous system, Neurology, Peripheral nervous system, Female, medicine.symptom, Wallerian Degeneration, Axonal regeneration, Transcriptome, Neuroscience, 030217 neurology & neurosurgery, Reinnervation

Abstract

Background: Peripheral nerve injuries result in motor and sensory dysfunction which can be recovered by compensatory or regenerative processes. In situations where axonal regeneration of injured neurons is hampered, compensation by collateral sprouting from uninjured neurons contributes to target reinnervation and functional recovery. Interestingly, this process of collateral sprouting from uninjured neurons has been associated with the activation of growth-associated programs triggered by Wallerian degeneration. Nevertheless, the molecular alterations at the transcriptomic level associated with these compensatory growth mechanisms remain to be fully elucidated. Methods: We generated a surgical model of partial sciatic nerve injury in mice to mechanistically study degeneration-induced collateral sprouting from spared fibers in the peripheral nervous system. Using next-generation sequencing and Ingenuity Pathway Analysis we described the sprouting-associated transcriptome of uninjured sensory neurons and compare it with the activated by regenerating neurons. In vitro approaches were used to functionally assessed sprouting genes candidates in the mechanisms of axonal growth.Results: Using a novel animal model we provide the first description of the sprouting transcriptome observed in uninjured sensory neurons after nerve injury. This collateral sprouting-associated transcriptome differs from that seen in regenerating neurons, suggesting a molecular program distinct from axonal growth. We further demonstrate that genetic upregulation of novel sprouting associated genes activates a specific growth program in vitro, leading to increased neuronal branching.Conclusions: These results contribute to our understanding of the molecular mechanisms associated with collateral sprouting in vivo. The data provided here will therefore be instrumental in developing therapeutic strategies aimed at promoting functional recovery after injury to the nervous system.

Published

2020

12. Ameliorative Effects of p75NTR-ED-Fc on Axonal Regeneration and Functional Recovery in Spinal Cord-Injured Rats.

Author

Wang, Yong-Tang, Lu, Xiu-Min, Zhu, Feng, Huang, Peng, Yu, Ying, Long, Zai-Yun, and Wu, Ya-Min

Abstract

As a co-receptor of Nogo-66 receptor (NgR) and a critical receptor for paired immunoglobulin-like receptor (PirB), p75 neurotrophin receptor (p75NTR) mediates the inhibitory effects of myelin-associated inhibitors on axonal regeneration after spinal cord injury. Therefore, the p75NTR antagonist, such as recombinant p75NTR protein or its homogenates may block the inhibitory effects of myelin and promote the axonal regeneration and functional recovery. The purposes of this study are to subclone and express the extracellular domain gene of human p75NTR with IgG-Fc (hp75NTR-ED-Fc) in prokaryotic expression system and investigate the effects of the recombinant protein on axonal regeneration and functional recovery in spinal cord-injured rats. The hp75NTR-ED-Fc coding sequence was amplified from pcDNA-hp75NTR-ED-Fc by polymerase chain reaction (PCR) and subcloned into vector pET32a (+), then the effects of the purified recombinant protein on neurite outgrowth of dorsal root ganglion (DRG) neurons cultured with myelin-associated glycoprotein (MAG) were determined, and the effects of the fusion protein on axonal regeneration, functional recovery, and its possible mechanisms in spinal cord-injured rats were further investigated. The results indicated that the purified infusion protein could promote neurite outgrowth of DRG neurons, promote axonal regeneration and functional recovery, and decrease RhoA activation in spinal cord-injured rats. Taken together, the findings revealed that p75NTR still may be a potential and novel target for therapeutic intervention for spinal cord injury and that the hp75NTR-ED-Fc fusion protein treatment enhances functional recovery by limiting tissue loss and stimulating axonal growth in spinal cord-injured rats, which may result from decreasing the activation of RhoA. [ABSTRACT FROM AUTHOR]

Published

2015

13. An Antagonistic Axon-Dendrite Interplay Enables Efficient Neuronal Repair in the Adult Zebrafish Central Nervous System

Author

Ilse Bollaerts, Evy Lefevere, Lieve Moons, Inge Van Hove, Kim Lemmens, Lien Andries, Annelies Van Dyck, Jessica Agostinone, An Beckers, Adriana Di Polo, and Jessie Van houcke

Subjects

Central Nervous System, Retinal Ganglion Cells, 0301 basic medicine, Optic nerve crush, Nerve Crush, Central nervous system, Neuroscience (miscellaneous), Dendrite, Matrix Metalloproteinase Inhibitors, Biology, Retina, 03 medical and health sciences, Cellular and Molecular Neuroscience, 0302 clinical medicine, Dendritic remodeling, medicine, Animals, Axon, Zebrafish, PI3K/AKT/mTOR pathway, mTOR and MMP inhibitor studies, TOR Serine-Threonine Kinases, Regeneration (biology), Dendrites, biology.organism_classification, Axons, Nerve Regeneration, 030104 developmental biology, medicine.anatomical_structure, nervous system, Neurology, Retinal ganglion cell, Optic Nerve Injuries, Axonal regeneration, Neuroscience, 030217 neurology & neurosurgery

Abstract

Neural insults and neurodegenerative diseases typically result in permanent functional deficits, making the identification of novel pro-regenerative molecules and mechanisms a primary research topic. Nowadays, neuroregenerative research largely focuses on improving axonal regrowth, leaving the regenerative properties of dendrites largely unstudied. Moreover, whereas developmental studies indicate a strict temporal separation of axogenesis and dendritogenesis and thus suggest a potential interdependency of axonal and dendritic outgrowth, a possible axon-dendrite interaction during regeneration remains unexplored. To unravel the inherent dendritic response of vertebrate neurons undergoing successful axonal regeneration, regeneration-competent adult zebrafish of either sex, subjected to optic nerve crush (ONC), were used. A longitudinal study in which retinal ganglion cell (RGC) dendritic remodeling and axonal regrowth were assessed side-by-side after ONC, revealed that-as during development-RGC axogenesis precedes dendritogenesis during central nervous system (CNS) repair. Moreover, dendrites majorly shrank before the start of axonal regrowth and were only triggered to regrow upon RGC target contact initiation, altogether suggestive for a counteractive interplay between axons and dendrites after neuronal injury. Strikingly, both retinal mechanistic target of rapamycin (mTOR) and broad-spectrum matrix metalloproteinase (MMP) inhibition after ONC consecutively inhibited RGC synapto-dendritic deterioration and axonal regrowth, thus invigorating an antagonistic interplay wherein mature dendrites restrain axonal regrowth. Altogether, this work launches dendritic shrinkage as a prerequisite for efficient axonal regrowth of adult vertebrate neurons, and indicates that molecular/mechanistic analysis of dendritic responses after damage might represent a powerful target-discovery platform for neural repair. ispartof: Molecular Neurobiology vol:56 issue:5 pages:3175-3192 ispartof: location:United States status: published

Published

2018

14. FGF-2 Low Molecular Weight Selectively Promotes Neuritogenesis of Motor Neurons In Vitro.

Author

Allodi, Ilary, Casals-Díaz, Laura, Santos-Nogueira, Eva, Gonzalez-Perez, Francisco, Navarro, Xavier, and Udina, Esther

Abstract

In this study, we screened in vitro the different capabilities of trophic factors with promising effect for enhancing selective regeneration and thus promoting specific reinnervation of target organs after peripheral nerve regeneration. We found that FGF-2 (18 kDa) was the trophic factor that exerted the most selective effect in promoting neurite outgrowth of spinal motoneurons both in terms of elongation and arborization. The mechanism underlying this effect on neuritogenesis seems related to FGF-2 enhancing the interaction between FGFR-1 and PSA-NCAM. The interaction of these two receptors is important during the early stages of neuritogenesis and pathfinding, while integrin alpha7B subunit seems to play a role during neurite stabilization. [ABSTRACT FROM AUTHOR]

Published

2013

15. Neural Regeneration: Lessons from Regenerating and Non-regenerating Systems.

Author

Ferreira, Leonardo, Floriddia, Elisa, Quadrato, Giorgia, and Giovanni, Simone

Abstract

One only needs to see a salamander regrowing a lost limb to become fascinated by regeneration. However, the lack of robust axonal regeneration models for which good cellular and molecular tools exist has hampered progress in the field. Nevertheless, the nervous system has been revealed to be an excellent model to investigate regeneration. There are conspicuous differences in neuroregeneration capacity between amphibia and warm-blooded animals, as well as between the central and the peripheral nervous systems in mammals. Exploration of such discrepancies led to significant discoveries on the basic tenets of neuroregeneration in the last two decades, identifying several positive and negative regulators of axonal regeneration. Implications of these findings to the comprehension of mammalian regeneration and to the development of spinal cord injury therapies are also addressed. [ABSTRACT FROM AUTHOR]

Published

2012

16. Reactive Astrogliosis after Spinal Cord Injury-Beneficial and Detrimental Effects.

Author

Karimi-Abdolrezaee, Soheila and Billakanti, Rohini

Abstract

Reactive astrogliosis is a pathologic hallmark of spinal cord injury (SCI). It is characterised by profound morphological, molecular, and functional changes in astrocytes that occur within hours of SCI and evolves as time elapses after injury. Astrogliosis is a defense mechanism to minimize and repair the initial damage but eventually leads to some detrimental effects. Reactive astrocytes secrete a plethora of both growth promoting and inhibitory factors after SCI. However, the production of inhibitory components surpasses the growth stimulating factors, thus, causing inhibitory effects. In severe cases of injury, astrogliosis results in the formation of irreversible glial scarring that acts as regeneration barrier due to the expression of inhibitory components such as chondroitin sulfate proteoglycans. Scar formation was therefore recognized from a negative perspective for many years. Accumulating evidence from pharmacological and genetic studies now signifies the importance of astrogliosis and its timing for spinal cord repair. These studies have advanced our knowledge regarding signaling pathways and molecular mediators, which trigger and modulate reactive astrocytes and scar formation. In this review, we discuss the recent advances in this field. We also review therapeutic strategies that have been developed to target astrocytes reactivity and glial scaring in the environment of SCI. Astrocytes play pivotal roles in governing SCI mechanisms, and it is therefore crucial to understand how their activities can be targeted efficiently to harness their potential for repair and regeneration after SCI. [ABSTRACT FROM AUTHOR]

Published

2012

17. Myelin-associated glycoprotein-mediated signaling in central nervous system pathophysiology.

Author

Chen, Yanan, Aulia, Selina, and Tang, Bor

Abstract

The myelin-associated glycoprotein (MAG) is a type I membrane-spanning protein expressed exclusively in oligoden drocytes and Schwann cells. It has two generally known pathophysiological roles in the central nervous system (CNS): maintenance of myelin integrity and inhibition of CNS axonal regeneration. The subtle CNS phenotype resulting from genetic ablation of MAG expression has made mechanistic analysis of its functional role in these difficult. However, the past few years have brought some major revelations, particularly in terms of mechanisms of MAG signaling through the Nogo-66 receptor (NgR) complex. Although apparently converging through NgR, a readily noticeable fact is that the neuronal growth inhibitory effect of MAG differs from that of Nogo-66. This may result from the influence of coreceptors in the form of gangliosides or from MAG-specific neuronal receptors such as NgR2. MAG has several other neuronal binding partners, and some of these may modulate its interaction with the NgR complex or downstream signaling. This article discusses new findings in MAG-forward and-reverse signaling and its role in CNS pathophysiology. [ABSTRACT FROM AUTHOR]

Published

2006

18. Actions of neurotrophic factors and their signaling pathways in neuronal survival and axonal regeneration.

Author

Cui, Qi

Abstract

Adult axons in the mammalian central nervous system do not elicit spontaneous regeneration after injury, although many affected neurons have survived the neurotrauma. However, axonal regeneration does occur under certain conditions. These conditions include: (a) modification of regrowth environment, such as supply of peripheral nerve bridges and transplantation of Schwann cells or olfactory ensheathing glia to the injury site; (b) application of neurotrophic factors at the cell soma and axon tips; (c) blockade of growth-inhibitory molecules such as Nogo-A, myelin-associated glycoprotein, and oligodendrocyte-myelin glycoprotein; (d) prevention of chondroitin-sulfate-proteoglycans-related scar tissue formation at the injury site using chondroitinase ABC; and (e) elevation of intrinsic growth potential of injured neurons via increasing intra-cellular cyclic adenosine monophosphate level. A large body of evidence suggests that these conditions achieve enhanced neuronal survival and axonal regeneration through sometimes over-lapping and sometimes distinct signal transduction mechanisms, depending on the targeted neuronal populations and intervention circumstances. This article reviews the available information on signal transduction pathways underlying neurotrophic-factor-mediated neuronal survival and neurite outgrowth/axonal regeneration. Better understanding of signaling transduction is important in helping us develop practical therapeutic approaches for encouraging neuronal survival and axonal regeneration after traumatic injury in clinical context. [ABSTRACT FROM AUTHOR]

Published

2006

19. Comparison of RNAi NgR and NEP1–40 in Acting on Axonal Regeneration After Spinal Cord Injury in Rat Models

Author

Xu, Jing, He, Jian, He, Huang, Peng, Renjun, and Xi, Jian

Published

2016