Using fluorescence photoablation to study the regeneration of singly cut leech axons (original) (raw)
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An Ultrastructural Study of the Early Stages of Axonal Regeneration Through Rat Nerve Grafts
Neuropathology and Applied Neurobiology, 1983
An ultrastructural study of the early stages of axonal regeneration through rat nerve grafts Segments of rat sciatic nerve 5 mm long were removed and either maintained alive in tissue culture medium or killed by freeze-drying. Twenty-four h later the nerve segments were replaced as autografts. Animals were killed 3-14 days after grafting. Grafts of cultured nerves (Cgrafts) always contained many living cells. Grafts of freeze-dried nerves (FD-grafts) contained few living cells at 3 days, but were repopulated by 7 days. A few regenerating axons were identified in the most proximal parts of 3 day C-grafts and by 14 days many myelinated axons extended to the distal ends. Axons were absent from 3 and 7 day FD-grafts, but by 14 days some non-myelinated axons extended to the distal end of such grafts. Regenerating axons were always associated with Schwann cells. Small perineurial compartments were formed at the junctional zones of all grafts and throughout the FD-grafts. Revascularization of the FD-grafts was delayed when compared to that in C-grafts. Fenestrated capillaries were observed in both types of graft. These experiments demonstrate that axons regenerate through FD-grafts that have been repopulated by cells and the grafts probably lack the normal perineurial and bloodlnerve diffusion barriers. The significance of these results is discussed in relation to the requirements for successful axonal regeneration.
Experimental Neurology, 2001
Injury to axons in the CNS leads to little regenerative repair and loss of function. Conversely, injury to axons in the PNS results in vigorous regrowth of severed axons, usually with restoration of function. This difference is generally attributed to a CNS environment that either cannot support or actively inhibits regeneration and/or a failure of CNS neurons to survive axotomy. One of the earliest responses of neurons to axotomy is the resealing of cut axons. A delay in resealing could affect a neuron's ability to survive axotomy and to regenerate a new axon. In the present experiments, using a dye exclusion technique, we demonstrate that following transection of a peripheral sensory nerve, axons reseal within 8-10 h, whereas following optic nerve transection complete resealing does not occur for more than 20 h. These results show that resealing of cut axons in a CNS environment is significantly delayed compared with axons in the PNS and suggest that this could contribute to the failure of CNS neurons to regenerate following injury.
Journal of Neurocytology, 1992
If one end of a segment of peripheral nerve is inserted into the brain or spinal cord, neuronal perikarya in the vicinity of the graft tip can be labelled with retrogradely transported tracers applied to the distal end of the graft several weeks later, showing that CNS axons can regenerate into and along such grafts. We have used transmission EM to examine some of the cellular responses that underlie this regenerative phenomenon, particularly its early stages. Segments of autologous peroneal or tibial nerve were inserted vertically into the thalamus of anaesthetized adult albino rats. The distal end of the graft was left beneath the scalp. Between five days and two months later the animals were killed and the brains prepared for ultrastructural study. Semi-thin and thin sections through the graft and surrounding brain were examined at two levels 6-7 mm apart in all animals: close to the tip of the graft in the thalamus (proximal graft) and at the top of the cerebral cortex (distal graft). In another series of animals with similar grafts, horseradish peroxidase was applied to the distal end of the graft 2448 h before death. Examination by LM of appropriately processed serial coronal sections of the brains from these animals confirmed that up to several hundred neurons were retrogradely labelled in the thalamus, particularly in the thalamic reticular nucleus.
Journal of neural transplantation & plasticity, 1991
We present a new method for creating conditions conductive to axonal growth in injured optic nerves of adult rabbits. The surgical approach consists of making a cavity in the adult rabbit optic nerve, into which a piece of nitrocellulose soaked with conditioned medium originating from regenerating fish optic nerves is implanted. In addition, daily irradiation (10 days, 5 min, 35 mW) with low energy He-Ne laser is carried out. Such a combined treatment may open a door to neurobiologists and clinicians, hoping to unravel the enigma of mammalian CNS regeneration.
Concepts and Methods for the Study of Axonal Regeneration in the CNS
Neuron, 2012
Progress in the field of axonal regeneration research has been like the process of axonal growth itself: there is steady progress toward reaching the target, but there are episodes of mistargeting, misguidance along false routes, and connections that must later be withdrawn. This primer will address issues in the study of axonal growth after central nervous system injury in an attempt to provide guidance toward the goal of progress in the field. We address definitions of axonal growth, sprouting and regeneration after injury, and the research tools to assess growth.
Regeneration of long spinal axons in the rat
Journal of Neurocytology, 1984
To investigate regeneration of long spinal axons, the right lateral column of the rat spinal cord was cut at high cervical, low cervical, midthoracic or lumbar level, and one end of an autologous sciatic nerve segment was grafted to the spinal cord at the site of incision. Three to six months after operation, the origin of axons in the grafts was traced retrogradely with horseradish peroxidase injected into the grafts and, in some cases, anterogradely with radioautography of tritiated amino acids injected into the brainstem. Axons from each of the major lateral spinal tracts arising in the brainstem as well as axons ascending from the lower spinal cord succeeded in growing into low cervical grafts. However, long descending axons rarely regenerated after midthoracic or lumbar injury; axons ascending from lumbar segments of the spinal cord usually failed to enter high cervical grafts. Differences in axonal regrowth at the four segmental levels were not simply attributable to dwindling of axonal number in fibre tracts. Axonal regeneration from Clarke's column or the red nucleus was observed only with lesions causing atrophy of many neurons.
Axonal branching following crush lesions of peripheral nerves of rat
Muscle & nerve, 1988
Branching of myelinated and unmyelinated nerve fibers in normal and regenerating personal and soleus nerves was studied by light and electron microscopy. There were at most 2% more myelinated and 13% more unmyelinated axons in the distal as compared with the proximal nerve segments. Two to four weeks after a crush lesion the distal axons became 2-3 times more numerous; thereafter their number decreased. The number of axons in the proximal nerve segment did not change. The number of myelinated sprouts in most regenerated nerves equalled the number of myelinated fibers in the proximal nerve, while the number of unmyelinated axons after 12-19 weeks was 18-60% higher than normal. Branching was not restricted to the crush region. The results indicate that following a crush lesion all axons branch but only branches of unmyelinated fibers persist for a prolonged period of time. It is tentatively suggested that regenerating axons branch when searching for a target and that when contact is m...
Emergence of axons from distal dendrites of adult mammalian neurons following a permanent axotomy
European Journal of Neuroscience, 2001
The distinctive features of axons and dendrites divide most neurons into two compartments. This polarity is fundamental to the ability of most neurons to integrate synaptic signals and transmit action potentials. It is not known, however, if the polarity of neurons in the adult mammalian nervous system is ®xed or plastic. Following axotomy, some distal dendrites of neck motoneurons in the adult cat give rise to unusual processes that, at a light microscopic level, resemble axons (Rose, P.K. & Odlozinski, M., J. Comp. Neurol., 1998, 390, 392). The goal of the present experiments was to characterize these unusual processes using well-established ultrastructural and molecular criteria that differentiate dendrites and axons. These processes were immunoreactive for growth-associated protein-43 (GAP-43), a protein that is normally con®ned to axons. In contrast, immunoreactivity for a protein that is widely used as a marker for dendrites, microtubule-associated protein (MAP)-2a/b, could not be detected in the unusual distal arborizations. At the electron microscopic level, unusual distal processes contained dense collections of neuro®laments and were frequently myelinated. These molecular and structural characteristics are typical of axons and suggest that the polarity of adult neurons in the mammalian nervous system can be disrupted by axotomy. If this transformation in neuronal polarity is common to other types of neurons, axon-like processes emerging from distal dendrites may represent a mechanism for replacing connections lost due to injury. Alternatively, the connections formed by these axons may be aberrant and therefore maladaptive.