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Coaxing injured nerve fibers to regenerate by disabling 'brakes' in the system
December 10, 2009Mouse study suggests that response to injury-induced growth factors can be revived
Brain and spinal-cord injuries typically leave people with permanent impairment because the injured nerve fibers (axons) cannot regrow. A study from Children's Hospital Boston, published in the December 10 issue of the journal Neuron, shows that axons can regenerate vigorously in a mouse model when a gene that suppresses natural growth factors is deleted.
Adding to a previous study published in Science last year (http://www.childrenshospital.org/newsroom/Site1339/mainpageS1339P1sublevel477.html), research led by Zhigang He, PhD, of the F.M. Kirby Neurobiology Center at Children's Hospital Boston provides further evidence that axon regeneration is limited by a reduced or lost responsiveness to injury-induced growth factors -- and also suggests some ways of overcoming the problem to help people recover from brain or spinal cord injury.
In the earlier study, He and colleagues used genetic techniques to delete two inhibitors of a growth pathway known as the mTOR pathway in the retinal ganglion cells of mice. (These cells constitute the optic nerve, which carries visual input from the retina to the brain.) Removing this inhibition brought about vigorous growth in injured axons, but not in uninjured axons, suggesting that something about the injury itself helps trigger axon regeneration.
In the new study, He and colleagues used a second set of genetic techniques in mice to delete a suppressor of inflammatory signaling, known as SOCS3, in retinal ganglion cells -- and again saw robust axon growth after injury. The greatest effect was seen after one week, when there were also signs that the mTOR pathway was re-activated.
In addition, soon after injury, the team observed an increase in a growth factor called CNTF (ciliary neurotrophic factor) in the retina. When CNTF was applied directly to the eye, axons grew even more than they did with SOCS3 deletion alone. However, CNTF only modestly increased growth in mice that did not have SOCS3 deleted.
"CNTF and other cytokines [cellular signaling molecules] have been tested for promoting axon regeneration previously, but with no success," notes He. "Now we know that this is due to the tight negative control of SOCS3. Inhibiting SOCS3, using small molecule compounds or RNA interference, might allow these cytokine growth factors to be functional."
Another way of promoting axon regeneration, based on the team's findings, could be to directly stimulate the signaling pathway that SOCS3 inhibits, known as JAK/STAT, adds Fang Sun, PhD, who shares first authorship of the paper with Patrice Smith, PhD (both also of the F.M. Kirby Neurobiology Center at Children's Hospital Boston). Sun is currently testing some STAT activators.
"We are very excited by these findings," says He. "First, we are testing the combined effects of manipulating both the MTOR and JAK/STAT pathways, hoping to maximize axon growth. Second and more importantly, we are testing whether these manipulations improve functional recovery after optic nerve injury and spinal cord injury."
Children's Hospital Boston
In the new study, He and colleagues used a second set of genetic techniques in mice to delete a suppressor of inflammatory signaling, known as SOCS3, in retinal ganglion cells -- and again saw robust axon growth after injury. The greatest effect was seen after one week, when there were also signs that the mTOR pathway was re-activated.
In addition, soon after injury, the team observed an increase in a growth factor called CNTF (ciliary neurotrophic factor) in the retina. When CNTF was applied directly to the eye, axons grew even more than they did with SOCS3 deletion alone. However, CNTF only modestly increased growth in mice that did not have SOCS3 deleted.
"CNTF and other cytokines [cellular signaling molecules] have been tested for promoting axon regeneration previously, but with no success," notes He. "Now we know that this is due to the tight negative control of SOCS3. Inhibiting SOCS3, using small molecule compounds or RNA interference, might allow these cytokine growth factors to be functional."
Another way of promoting axon regeneration, based on the team's findings, could be to directly stimulate the signaling pathway that SOCS3 inhibits, known as JAK/STAT, adds Fang Sun, PhD, who shares first authorship of the paper with Patrice Smith, PhD (both also of the F.M. Kirby Neurobiology Center at Children's Hospital Boston). Sun is currently testing some STAT activators.
"We are very excited by these findings," says He. "First, we are testing the combined effects of manipulating both the MTOR and JAK/STAT pathways, hoping to maximize axon growth. Second and more importantly, we are testing whether these manipulations improve functional recovery after optic nerve injury and spinal cord injury."
Children's Hospital Boston
Master regulator found for regenerating nerve fibers in live animals
Researchers at Children's Hospital Boston report that an enzyme known as Mst3b, previously identified in their lab, is essential for regenerating damaged axons (nerve fibers) in a live animal model, in both the peripheral and central nervous systems.
Finding the right connection after spinal cord injury
In a major step in spinal cord injury research, scientists at the University of California, San Diego School of Medicine have demonstrated that regenerating axons can be guided to their correct targets and re-form connections after spinal cord injury.
Bone marrow cell transplants help nerve regeneration
A study carried out by researchers at the Kyoto University School of Medicine and published in the current issue of CELL TRANSPLANTATION (Vol.16 No. 8) has shown that when transplanted bone marrow cells (BMCs) containing adult stem cells are protected by a 15mm silicon tube and nourished with bio-engineered materials, they successfully help regenerate damaged nerves.
Adult brain cells are movers and shakers
It's a general belief that the circuitry of young brains has robust flexibility but eventually gets "hard-wired" in adulthood. As Johns Hopkins researchers and their colleagues report in the Nov. 8 issue of Neuron, however, adult neurons aren't quite as rigidly glued in place as we suspect.
Nanomedicine opens the way for nerve cell regeneration
The ability to regenerate nerve cells in the body could reduce the effects of trauma and disease in a dramatic way. In two presentations at the NSTI Nanotech 2007 Conference, researchers describe the use of nanotechnology to enhance the regeneration of nerve cells.
More Axon Regeneration Current Events and Axon Regeneration News Articles
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Growth and Regeneration of Axons in the Nervous System (Bibliotheca Anatomica; No) by M. Berry (Editor) | |
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Axonal Transport, Degeneration, and Regeneration in the Visual System of the Goldfish (Advances in Anatomy, Embryology and Cell Biology) by Hartwig Wolburg (Author) | |
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Regeneration and Plasticity in the Mammalian Visual System: Proceedings of the Retina Research Foundation Symposia, Volume Four (Bradford Books) (v. 4) by Dominic Man-Kit Lam (Editor), Garth M. Bray (Editor) This fourth volume in the Retina Research Foundation Symposia Proceedings highlights several of the strategies and experimental paradigms that are currently used to exploit and amplify the regenerative capacity of the adult mammalian visual system, and reviews the exciting advances being made in understanding the molecular basis of central nervous system regeneration. Because loss of neurons or interruptions of their connective pathways in the mammalian visual system can, in contrast to certain amphibians and fish, lead to permanent loss of vision, studies of regeneration and plasticity in this system serve as valuable models for the reconstitution of other parts of the nervous system and as potential approaches to the diverse disorders that lead to visual loss. |
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Axonal Regeneration in the Central Nervous System (Neurological Disease and Therapy) by Ingoglia/Murray (Author) New Jersey Medical School-UMDNJ, Newark. Summarizes the current state of research into regeneration of axoms in the central nervous system of vertebrates. For basic neuroscientists, clinical neurologists, surgeons, and physical therapists. |
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Axon Growth and Guidance (Advances in Experimental Medicine and Biology) by Dominique Bagnard (Editor) This book proposes an updated view of the current knowledge of the molecular and cellular mechanisms ensuring axon growth and guidance. The introductory chapter will remind the readers of all the features of a growth cone and the mechanisms controlling its growth. From there, one enters a fabulous journey with a growth cone, a Tom Thumb story filled with molecular encounters and complex interactions leading to one of the most fantastic developmental achievements: the nervous system wiring. The journey starts with a description of the classical guidance signals such as the netrins, the semaphorins, the ephrins or the Slit family. The question of the exact definition of a guidance signal is addressed in a chapter which discusses whether neurotrophic factors can be considered as guidance... |
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Nervous System Regeneration in the Invertebrates (Zoophysiology) by Stacia B. Moffet (Author) This book examines what we know about neural regeneration from studies of invertebrates. Although invertebrates exhibit a diversity of regeneration strategies, invertebrates and vertebrates share the molecular language that governs initial responses to injury, activation of repair, and the specificity of pathfinding and synaptogenesis. From coelenterates and flatworms to molluscs, arthropods and tunicates, neural systems have been discovered that are ideal for investigating phenomena underlying successful regeneration. |
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The Role of Microenvironment in Axonal Regeneration: Influences of Lesion-Induced Changes and Glial Implants on the Regeneration of the Postcommissural ... in Anatomy, Embryology and Cell Biology) by Christine C. Stichel-Gunkel (Author) This book provides a comprehensive overview of structural and molecular changes induced by an invasive CNS lesion, and their involvement in regeneration processes. It also demonstrates the strong growth-promoting actitivies of implanted glial cells; these studies could have major practical importance in the development of novel therapeutic strategies. This book also presents various analyses of lesion-induced reactions. | |
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Studies on the intra-axonal transport of acetylcholine and cholinergic enzymes in rats sciatic nerve by Per-Olof Heiwall (Author) | |
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Axonal Branching and Recovery of Coordinated Muscle Activity after Transsection of the Facial Nerve in Adult Rats (Advances in Anatomy, Embryology and Cell Biology) by Doychin N. Angelov (Author), Orlando Guntinas-Lichius (Author), Konstantin Wewetzer (Author), W.F. Neiss (Author), Michael Streppel (Author) Facial nerve surgery inevitably leads to partial pareses, abnormally associated movements and pathologically altered reflexes. The reason for this "post-paralytic syndrome" is the misdirected reinnervation of targets, which consists of two major components. First, due to malfunctioning axonal guidance, a muscle gets reinnervated by a "foreign" axon, that has been misrouted along a "wrong" fascicle. Second, the supernumerary collateral branches emerging from all transected axons simultaneously innervate antagonistic muscles and cause severe impairment of their coordinated activity. Since it is hardly possible to influence the first major component and improve the guidance of several thousands axons, the authors concentrated on the second major component and tried to reduce the collateral... |
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