Re-establishing the regenerative potential of central nervous system axons in postnatal mice

At a certain point in development, axons in the mammalian central nervous system lose their ability to regenerate after injury. Using the optic nerve model, we show that this growth failure coincides with two developmental events: the loss of Bcl-2 expression by neurons and the maturation of astrocytes. Before postnatal day 4, when astrocytes are immature, overexpression of Bcl-2 alone supported robust and rapid optic nerve regeneration over long distances, leading to innervation of brain targets by day 4 in mice. As astrocytes matured after postnatal day 4, axonal regeneration was inhibited in mice overexpressing Bcl-2. Concurrent induction of Bcl-2 and attenuation of reactive gliosis reversed the failure of CNS axonal re-elongation in postnatal mice and led to rapid axonal regeneration over long distances and reinnervation of the brain targets by a majority of severed optic nerve fibers up to 2 weeks of age. These results suggest that an early postnatal downregulation of Bcl-2 and post-traumatic reactive gliosis are two important elements of axon regenerative failure in the CNS.

[1]  K. O’Malley,et al.  Overexpression of Bcl-2 in a murine dopaminergic neuronal cell line leads to neurite outgrowth , 1996, Neuroscience Letters.

[2]  F. Gage,et al.  Regenerating the damaged central nervous system , 2000, Nature.

[3]  B. Bregman Regeneration in the spinal cord , 1998, Current Opinion in Neurobiology.

[4]  H. Manji,et al.  Support of retinal ganglion cell survival and axon regeneration by lithium through a Bcl-2-dependent mechanism. , 2003, Investigative ophthalmology & visual science.

[5]  C. Holt,et al.  Ephrin-B2 and EphB1 Mediate Retinal Axon Divergence at the Optic Chiasm , 2003, Neuron.

[6]  G. Schneider,et al.  Intrinsic changes in developing retinal neurons result in regenerative failure of their axons. , 1995, Proceedings of the National Academy of Sciences of the United States of America.

[7]  S. Ryazantsev,et al.  Activated microglia in cortex of mouse models of mucopolysaccharidoses I and IIIB , 2003, Proceedings of the National Academy of Sciences of the United States of America.

[8]  C. Babinet,et al.  Mice lacking vimentin develop and reproduce without an obvious phenotype , 1994, Cell.

[9]  B. Barres,et al.  The relationship between neuronal survival and regeneration. , 2000, Annual review of neuroscience.

[10]  A. Fournier,et al.  Repulsive factors and axon regeneration in the CNS , 2001, Current Opinion in Neurobiology.

[11]  Stacey P. Memberg,et al.  Regeneration of adult axons in white matter tracts of the central nervous system , 1997, Nature.

[12]  A. Davies,et al.  Bcl-2 influences axonal growth rate in embryonic sensory neurons , 1997, Current Biology.

[13]  M. Bentivoglio,et al.  Co-induction of nitric oxide synthase, Bcl-2 and growth-associated protein-43 in spinal motoneurons during axon regeneration in the lizard tail , 2000, Neuroscience.

[14]  C. Spenger,et al.  Nogo‐receptor gene activity: Cellular localization and developmental regulation of mRNA in mice and humans , 2002, The Journal of comparative neurology.

[15]  Jeffrey L Goldberg,et al.  Amacrine-Signaled Loss of Intrinsic Axon Growth Ability by Retinal Ganglion Cells , 2002, Science.

[16]  G. Schneider,et al.  Bcl-2 promotes regeneration of severed axons in mammalian CNS , 1997, Nature.

[17]  L. Maffei,et al.  Bcl‐2 overexpression per se does not promote regeneration of neonatal crushed optic fibers , 2001, The European journal of neuroscience.

[18]  G. Ivy,et al.  Selective ablation of astrocytes by intracerebral injections of α‐aminoadipate , 1996 .

[19]  R. Coffin,et al.  The Nogo receptor, its ligands and axonal regeneration in the spinal cord; A review , 2002, Journal of neurocytology.

[20]  S. Tonegawa,et al.  Why do mature CNS neurons of mammals fail to re-establish connections following injury–functions of Bcl-2 , 1998, Cell Death and Differentiation.

[21]  B. Castellano,et al.  Understanding glial abnormalities associated with myelin deficiency in the jimpy mutant mouse , 1998, Brain Research Reviews.

[22]  L. Maffei,et al.  Protection of Retinal Ganglion Cells from Natural and Axotomy-Induced Cell Death in Neonatal Transgenic Mice Overexpressing bcl-2 , 1996, The Journal of Neuroscience.

[23]  V. Dietz,et al.  Improving axonal growth and functional recovery after experimental spinal cord injury by neutralizing myelin associated inhibitors , 2001, Brain Research Reviews.

[24]  S. Strittmatter,et al.  The Nogo-66 receptor: focusing myelin inhibition of axon regeneration , 2003, Trends in Neurosciences.

[25]  T. Hattori,et al.  Fine structural changes in the rat brain after local injections of gliotoxin, alpha-aminoadipic acid. , 1986, Histology and histopathology.

[26]  J. Steeves,et al.  Modulating astrogliosis after neurotrauma , 2001, Journal of neuroscience research.

[27]  E. Strettoi,et al.  Optic Nerve Crush: Axonal Responses in Wild-Type and bcl-2 Transgenic Mice , 1999, The Journal of Neuroscience.

[28]  P. Carmeliet,et al.  Under stress, the absence of intermediate filaments from Müller cells in the retina has structural and functional consequences , 2004, Journal of Cell Science.

[29]  C. Betsholtz,et al.  Mice lacking glial fibrillary acidic protein display astrocytes devoid of intermediate filaments but develop and reproduce normally. , 1995, The EMBO journal.

[30]  Mark Ellisman,et al.  Absence of Glial Fibrillary Acidic Protein and Vimentin Prevents Hypertrophy of Astrocytic Processes and Improves Post-Traumatic Regeneration , 2004, The Journal of Neuroscience.

[31]  E. Lazarides Intermediate filaments: a chemically heterogeneous, developmentally regulated class of proteins. , 1982, Annual review of biochemistry.

[32]  A. Privat,et al.  Axonal plasticity and functional recovery after spinal cord injury in mice deficient in both glial fibrillary acidic protein and vimentin genes , 2003, Proceedings of the National Academy of Sciences of the United States of America.

[33]  J. Silver,et al.  Robust Regeneration of Adult Sensory Axons in Degenerating White Matter of the Adult Rat Spinal Cord , 1999, The Journal of Neuroscience.

[34]  M. Pekny,et al.  Astrocyte intermediate filaments in CNS pathologies and regeneration , 2004, The Journal of pathology.

[35]  G. Ivy,et al.  Selective ablation of astrocytes by intracerebral injections of alpha-aminoadipate. , 1996, Glia.

[36]  S. Korsmeyer,et al.  Bcl-2 gene family in the nervous system. , 1997, Annual review of neuroscience.

[37]  G. Schneider,et al.  Initial stages of retinofugal axon development in the hamster: evidence for two distinct modes of growth , 2004, Experimental Brain Research.

[38]  K. Weber,et al.  Vimentin, the 57 000 molecular weight protein of fibroblast filaments, is the major cytoskeletal component in immature glia. , 1981, European journal of cell biology.

[39]  A. Harvey,et al.  Macrophage-Derived Factors Stimulate Optic Nerve Regeneration , 2003, The Journal of Neuroscience.

[40]  S. Korsmeyer,et al.  bcl-2 protein expression is widespread in the developing nervous system and retained in the adult PNS. , 1994, Development.

[41]  U. Lendahl,et al.  Abnormal Reaction to Central Nervous System Injury in Mice Lacking Glial Fibrillary Acidic Protein and Vimentin , 1999, The Journal of cell biology.

[42]  L. Andersson,et al.  BCL2 regulates neural differentiation. , 1996, Proceedings of the National Academy of Sciences of the United States of America.

[43]  Jean-Claude Martinou,et al.  Overexpression of BCL-2 in transgenic mice protects neurons from naturally occurring cell death and experimental ischemia , 1994, Neuron.

[44]  G. Raisman,et al.  Transplanted Olfactory Ensheathing Cells Promote Regeneration of Cut Adult Rat Optic Nerve Axons , 2003, The Journal of Neuroscience.

[45]  G. Schneider,et al.  Oligodendrocytes and myelin formation along the optic tract of the developing hamster: An immunohistochemical study using the rip antibody , 1992, Glia.

[46]  R. Neve,et al.  Bcl‐2 enhances Ca2+ signaling to support the intrinsic regenerative capacity of CNS axons , 2005, The EMBO journal.

[47]  D. Chen,et al.  Robust neural integration from retinal transplants in mice deficient in GFAP and vimentin , 2003, Nature Neuroscience.

[48]  J. Silver Inhibitory molecules in development and regeneration , 1994, Journal of Neurology.

[49]  J. Fawcett,et al.  Chondroitin sulphate proteoglycans in the CNS injury response. , 2002, Progress in brain research.