Gene expression profiling reveals that peripheral nerve regeneration is a consequence of both novel injury‐dependent and reactivated developmental processes

Bosse, Frank; Hasenpusch‐Theil, Kerstin; Küry, Patrick; Müller, Hans

doi:10.1111/j.1471-4159.2005.03635.x

Cited by 113 publications

(121 citation statements)

References 66 publications

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“…Axons begin to grow into the distal endoneurial tubes 1 week after nerve injury [6,39,45] ; Schwann cell/axon contacts are re-established and remyelination occurs at about 2 weeks; and the proper target tissues are reinnervated at about 4 weeks after sciatic nerve injury. In this process, a large number of genes with marked up-or down-regulation were differentially expressed, indicating sustained regulation at consecutive time points, meaning regeneration/repair by means of a continuously progressive program [4,10,35] .…”

Section: Discussionmentioning

confidence: 99%

“…In this process, a large number of genes with marked up-or down-regulation were differentially expressed, indicating sustained regulation at consecutive time points, meaning regeneration/repair by means of a continuously progressive program [4,10,35] . Nerve regeneration mainly consists of nerve repair and tissue re-innervation after injury [45,46] . The activated injury-dependent process is regulated initially following the genetic response featuring degeneration and regeneration.…”

Section: Discussionmentioning

confidence: 99%

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Expression changes and bioinformatic analysis of Wallerian degeneration after sciatic nerve injury in rat

Yao

Shen

et al. 2013

Neurosci. Bull.

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Wallerian degeneration (WD) remains an important research topic. Many genes are differentially expressed during the process of WD, but the precise mechanisms responsible for these differentiations are not completely understood. In this study, we used microarrays to analyze the expression changes of the distal nerve stump at 0, 1, 4, 7, 14, 21 and 28 days after sciatic nerve injury in rats. The data revealed 6 076 differentially-expressed genes, with 23 types of expression, specifically enriched in genes associated with nerve development and axonogenesis, cytokine biosynthesis, cell differentiation, cytokine/chemokine production, neuron differentiation, cytokinesis, phosphorylation and axon regeneration. Kyoto Encyclopedia of Genes and Genomes pathway analysis gave findings related mainly to the MAPK signaling pathway, the Jak-STAT signaling pathway, the cell cycle, cytokine-cytokine receptor interaction, the p53 signaling pathway and the Wnt signaling pathway. Some key factors were NGF, MAG, CNTF, CTNNA2, p53, JAK2, PLCB1, STAT3, BDNF, PRKC, collagen II, FGF, THBS4, TNC and c-Src, which were further validated by real-time quantitative PCR, Western blot, and immunohistochemistry. Our findings contribute to a better understanding of the functional analysis of differentially-expressed genes in WD and may shed light on the molecular mechanisms of nerve degeneration and regeneration.

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Section: Discussionmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

Expression changes and bioinformatic analysis of Wallerian degeneration after sciatic nerve injury in rat

Yao

Shen

et al. 2013

Neurosci. Bull.

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“…However, what is critical for the biology of regeneration and for a possible regeneration therapeutic agent is whether the underlying molecular profile of CNS regeneration recapitulates the molecular profile of neurodevelopment. Initial transcriptional profiling of neurons that form new connections after stroke, retinal ganglion cells that regenerate an injured axon in the optic nerve, or dorsal root ganglion cells that regrow a connection after peripheral nerve injury suggest some overlap with genes that are active in the developing nervous system, but overall a distinct set of genes that is regulated in these injury responses 11, 122. However, direct comparison of the transcriptome of neurons exposed to a regenerating stimulus after stroke and the transcriptomes of neurons at several stages of neuronal development from many different laboratories clearly indicates that the molecular expression profile of regeneration is statistically and fairly dramatically distinct from the developmental transcriptome 13.…”

Section: Regeneration Does Not Recapitulate Developmentmentioning

confidence: 99%

Emergent properties of neural repair: elemental biology to therapeutic concepts

Carmichael

2016

Annals of Neurology

118

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Stroke is the leading cause of adult disability. The past decade has seen advances in basic science research of neural repair in stroke. The brain forms new connections after stroke, which have a causal role in recovery of function. Brain progenitors, including neuronal and glial progenitors, respond to stroke and initiate a partial formation of new neurons and glial cells. The molecular systems that underlie axonal sprouting, neurogenesis, and gliogenesis after stroke have recently been identified. Importantly, tractable drug targets exist within these molecular systems that might stimulate tissue repair. These basic science advances have taken the field to its first scientific milestone; the elemental principles of neural repair in stroke have been identified. The next stages in this field involve understanding how these elemental principles of recovery interact in the dynamic cellular systems of the repairing brain. Emergent principles arise out of the interaction of the fundamental or elemental principles in a system. In neural repair, the elemental principles of brain reorganization after stroke interact to generate higher order and distinct concepts of regenerative brain niches in cellular repair, neuronal networks in synaptic plasticity, and the distinction of molecular systems of neuroregeneration. Many of these emergent principles directly guide the development of new therapies, such as the necessity for spatial and temporal control in neural repair therapy delivery and the overlap of cancer and neural repair mechanisms. This review discusses the emergent principles of neural repair in stroke as they relate to scientific and therapeutic concepts in this field. Ann Neurol 2016;79:895–906

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“…Lesioning the peripheral axonal branches of DRG neurons causes expression of a distinct set of genes, termed regeneration-associated genes, which are not upregulated after central lesioning (Ylera and Bradke, 2006). Interestingly, those sets of genes contain direct and indirect regulators of microtubule polymerization and stabilization, including tubulin isoforms, MAPs (microtubule- associated proteins), and arginase I (Miller et al, 1989;Moskowitz and Oblinger, 1995;Cai et al, 2002;Bosse et al, 2006), which may enhance the rapid regrowth of lesioned PNS axons. Notably, it has been demonstrated that interfering with the expression of microtubule binding proteins inhibits neurite outgrowth (Caceres et al, 1992).…”

Section: Putative Signaling Mechanisms Underlying Microtubule Disorgamentioning

confidence: 99%

Disorganized Microtubules Underlie the Formation of Retraction Bulbs and the Failure of Axonal Regeneration

Ertürk¹,

Hellal²,

Enes³

et al. 2007

J. Neurosci.

356

338

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Axons in the CNS do not regrow after injury, whereas lesioned axons in the peripheral nervous system (PNS) regenerate. Lesioned CNS axons form characteristic swellings at their tips known as retraction bulbs, which are the nongrowing counterparts of growth cones. Although much progress has been made in identifying intracellular and molecular mechanisms that regulate growth cone locomotion and axonal elongation, a comprehensive understanding of how retraction bulbs form and why they are unable to grow is still elusive. Here we report the analysis of the morphological and intracellular responses of injured axons in the CNS compared with those in the PNS. We show that retraction bulbs of injured CNS axons increase in size over time, whereas growth cones of injured PNS axons remain constant. Retraction bulbs contain a disorganized microtubule network, whereas growth cones possess the typical bundling of microtubules. Using in vivo imaging, we find that pharmacological disruption of microtubules in growth cones transforms them into retraction bulb-like structures whose growth is inhibited. Correspondingly, microtubule destabilization of sensory neurons in cell culture induces retraction bulb formation. Conversely, microtubule stabilization prevents the formation of retraction bulbs and decreases axonal degeneration in vivo. Finally, microtubule stabilization enhances the growth capacity of CNS neurons cultured on myelin. Thus, the stability and organization of microtubules define the fate of lesioned axonal stumps to become either advancing growth cones or nongrowing retraction bulbs. Our data pinpoint microtubules as a key regulatory target for axonal regeneration.

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Gene expression profiling reveals that peripheral nerve regeneration is a consequence of both novel injury‐dependent and reactivated developmental processes

Cited by 113 publications

References 66 publications

Expression changes and bioinformatic analysis of Wallerian degeneration after sciatic nerve injury in rat

Expression changes and bioinformatic analysis of Wallerian degeneration after sciatic nerve injury in rat

Emergent properties of neural repair: elemental biology to therapeutic concepts

Disorganized Microtubules Underlie the Formation of Retraction Bulbs and the Failure of Axonal Regeneration

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