Facilitated sprouting in a peripheral nerve injury

Abstract During regeneration of injured peripheral nerves, local conditions may influence how regenerative axon sprouts emerge from parent axons. More extensive lesions might be expected to disrupt such growth. In this work, we discovered instead that long segmental crush injuries facilitate the gro...

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Bibliographic Details
Published in:Neuroscience 2008-04, Vol.152 (4), p.877-887
Main Authors: Xu, Q.G, Midha, R, Martinez, J.A, Guo, G.F, Zochodne, D.W
Format: Article
Language:English
Subjects:
Analysis of Variance
Animals
axon regeneration
Axons - metabolism
Axons - physiology
Biological and medical sciences
Disease Models, Animal
endoneurial microenvironment
Fundamental and applied biological sciences. Psychology
Gene Expression Regulation
Glial Fibrillary Acidic Protein - metabolism
Hedgehog Proteins - metabolism
Laser-Doppler Flowmetry - methods
Male
Nerve Fibers, Myelinated - pathology
Nerve Fibers, Myelinated - physiology
Nerve Regeneration - physiology
Neurofilament Proteins - metabolism
Neurology
Neurons - metabolism
Neurons - pathology
Nitric Oxide Synthase Type II - metabolism
peripheral nerve
peripheral nerve injury
Rats
Rats, Sprague-Dawley
Receptor, Nerve Growth Factor - metabolism
Regional Blood Flow - physiology
Sciatic Neuropathy - metabolism
Sciatic Neuropathy - pathology
Sciatic Neuropathy - physiopathology
sonic hedgehog protein
Stilbamidines - metabolism
Time Factors
Vertebrates: nervous system and sense organs
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Summary:Abstract During regeneration of injured peripheral nerves, local conditions may influence how regenerative axon sprouts emerge from parent axons. More extensive lesions might be expected to disrupt such growth. In this work, we discovered instead that long segmental crush injuries facilitate the growth and maturation of substantially more axon sprouts than do classical short crush injuries (20 mm length vs. 2 mm). At identical distances from the proximal site of axon interruption there was a 45% rise in the numbers of neurofilament labeled axons extending through a long segmental crush zone by 1 week. By 2 weeks, there was a 35% greater density of regenerating myelinated axons in long compared with short crush injuries just beyond (5 mm) the proximal injury site. Moreover, despite the larger numbers of axons, their maturity was identical and they were regular, parallel, associated with Schwann cells (SCs) and essentially indistinguishable between the injuries. Backlabeling with Fluorogold indicated that despite these differences, the axons arose from similar numbers of parent motor and sensory neurons. Neither injury was associated with ischemia. Both injuries were associated with rises in GFAP (glial acidic fibrillary protein) and p75 mRNAs, markers of SC plasticity but p75, GFAP and brain-derived neurotrophic factor mRNAs did not differ between the injuries. There was a higher local mRNA level of GAP43/B50 at 7 days following injury and a higher sonic hedgehog protein (Shh) mRNA at 24 h in long crush zones. GAP43/B50 protein and SHH protein both had prominent localization within regenerating axons. Long segmental nerve trunk crush injuries do not impair regeneration but instead generate greater axon plasticity that results in larger numbers of mature myelinated axons. The changes occur without apparent change in SC activation, overall nerve architecture or nerve blood flow. While the mechanism is uncertain, the findings indicate that manipulation of the nerve microenvironment can induce substantial changes in regenerative sprouting.
ISSN:0306-4522
1873-7544
DOI:10.1016/j.neuroscience.2008.01.060