Electron microscopic studies of spinal ganglion cells following crushing of dorsal roots in adult rat

Chromatolysis: Do injured axons regenerate poorly when ribonucleases attack rough endoplasmic reticulum, ribosomes and RNA?

After axonal injury, chromatolysis (fragmentation of Nissl substance) can occur in the soma. Electron microscopy shows that chromatolysis involves fission of the rough endoplasmic reticulum. In CNS neurons (which do not regenerate axons back to their original targets) or in motor neurons or dorsal root ganglion neurons denied axon regeneration (e.g., by transection and ligation), chromatolysis is often accompanied by degranulation (loss of ribosomes from rough endoplasmic reticulum), disaggregation of polyribosomes and degradation of monoribosomes into dust‐like particles. Ribosomes and rough endoplasmic reticulum may also be degraded in autophagic vacuoles by ribophagy and reticulophagy, respectively. In other words, chromatolysis is disruption of parts of the protein synthesis infrastructure. Whereas some neurons may show transient or no chromatolysis, severely injured neurons can remain chromatolytic and never again synthesize normal levels of protein; some may atrophy or die. Ribonuclease(s) might cause the following features of chromatolysis: fragmentation and degranulation of rough endoplasmic reticulum, disaggregation of polyribosomes and degradation of monoribosomes. For example, ribonucleases in the EndoU/PP11 family can modify rough endoplasmic reticulum; many ribonucleases can degrade mRNA causing polyribosomes to unchain and disperse, and they can disassemble monoribosomes; Ribonuclease 5 can control rRNA synthesis and degrade tRNA; Ribonuclease T2 can degrade ribosomes, endoplasmic reticulum and RNA within autophagic vacuoles; and Ribonuclease IRE1α acts as a stress sensor within the endoplasmic reticulum. Regeneration might be improved after axonal injury by protecting the protein synthesis machinery from catabolism; targeting ribonucleases using inhibitors can enhance neurite outgrowth and could be a profitable strategy in vivo. © 2018 Wiley Periodicals, Inc. Develop Neurobiol, 2018

Satellite glial cell proliferation in the trigeminal ganglia after chronic constriction injury of the infraorbital nerve

We have examined satellite glial cell (SGC) proliferation in trigeminal ganglia following chronic constriction injury of the infraorbital nerve. Using BrdU labeling combined with immunohistochemistry for SGC specific proteins we positively confirmed proliferating cells to be SGCs. Proliferation peaks at approximately 4 days after injury and dividing SGCs are preferentially located around neurons that are immunopositive for ATF-3, a marker of nerve injury. After nerve injury there is an increase GFAP expression in SGCs associated with both ATF-3 immunopositive and immunonegative neurons throughout the ganglia. SGCs also express the non-glial proteins, CD45 and CD163, which label resident macrophages and circulating leukocytes, respectively. In addition to SGCs, we found some Schwann cells, endothelial cells, resident macrophages, and circulating leukocytes were BrdU immunopositive.

Changes in compressed neurons from dogs with acute and severe cauda equina constrictions following intrathecal injection of brain-derived neurotrophic factor-conjugated polymer nanoparticles

This study established a dog model of acute multiple cauda equina constriction by experimental constriction injury (48 hours) of the lumbosacral central processes in dorsal root ganglia neurons. The repair effect of intrathecal injection of brain-derived neurotrophic factor with 15 mg encapsulated biodegradable poly(lactide-co-glycolide) nanoparticles on this injury was then analyzed. Dorsal root ganglion cells (L7) of all experimental dogs were analyzed using hematoxylin-eosin staining and immunohistochemistry at 1, 2 and 4 weeks following model induction. Intrathecal injection of brain-derived neurotrophic factor can relieve degeneration and inflammation, and elevate the expression of brain-derived neurotrophic factor in sensory neurons of compressed dorsal root ganglion. Simultaneously, intrathecal injection of brain-derived neurotrophic factor obviously improved neurological function in the dog model of acute multiple cauda equina constriction. Results verified that sustained intraspinal delivery of brain-derived neurotrophic factor encapsulated in biodegradable nanoparticles promoted the repair of histomorphology and function of neurons within the dorsal root ganglia in dogs with acute and severe cauda equina syndrome.

The life span of ganglionic glia in murine sensory ganglia estimated by uptake of bromodeoxyuridine

Studies of ganglionic glia turnover in the sensory nervous system have implications for understanding nervous system maintenance and repair. These glial cells of the sensory ganglia in the peripheral nervous system (PNS) comprise satellite cells (SCs) and, to a lesser extent, Schwann cells. SCs proliferate in response to trauma such as axotomy; however, the half-life of these glial cells under normal circumstances has not been estimated. To estimate the half-life of sensory ganglionic glial cells, we employed the DNA precursor analog 5-bromo-2'-deoxyuridine (BrdU) to measure the rate of turnover of these cells. BrdU was administered to inbred C57BL6 and outbred Swiss white mice via their drinking water. BrdU incorporation into ganglionic glia in the PNS was estimated by immunofluorescent staining of nervous tissue sections, and the fraction of ganglionic glial cells that acquired BrdU label was measured as a function of time. Mathematical modeling of the rate of uptake of BrdU into murine ganglionic glia enables calculation of the half-life of these cells. The kinetics of BrdU uptake is linear, consistent with ganglionic glia being a homogenous population. The value of the proliferation rate (p) plus death rate (d) derived from the slope of BrdU uptake as a function of time is approximately 2.4 x 10(-3) cells per day. Assuming that p = d (because ganglionic glial numbers are in equilibrium and they are assumed to neither emigrate from, or immigrate into, sensory ganglia), then the daily death rate is d = 1.2 x 10(-3) cells/day, which implies a half-life for ganglionic glia of about 600 days. Thus murine ganglionic glia in the untraumatized state appear to behave as a homogenous, slowly replicating population.

Pathology of lumbar nerve root compression. Part 2: morphological and immunohistochemical changes of dorsal root ganglion

STUDY DESIGN

This study is to investigate the changes of dorsal root ganglion (DRG) induced by mechanical compression using in vivo model.

OBJECTIVES

The effect of axonal flow disturbance induced by nerve root compression was determined in DRG.

SUMMARY OF BACKGROUND DATA

The dorsal root ganglion should not be overlooked when considering the mechanism of low back pain and sciatica, so it is important to understand the morphologic and functional changes that occur in primary sensory neurons of the dorsal root ganglion as a result of nerve root compression. However, few studies have looked at changes of neurons within the dorsal root ganglion caused by disturbance of axonal flow and the axon reaction as a result of mechanical compression of the dorsal root through which the central branches of the primary sensory nerves pass.

METHODS

In mongrel dogs, the seventh lumbar nerve root was compressed for 24 h, one week, or three weeks using a clip with a pressure of 7.5 gf. Morphologic changes of the primary sensory neurons in the dorsal root ganglion secondary to the axon reaction were examined by light and electron microscopy. Changes of immunostaining for substance P (SP), calcitonin gene-related peptide (CGRP), and somatostatin (SOM) in the primary sensory neurons affected by central chromatolysis after nerve root compression were also examined.

RESULTS

Light microscopy showed central chromatolysis of neurons in the dorsal root ganglion from one week after the start of compression. Electron microscopy of the affected neurons revealed movement of the nucleus to the cell periphery and the loss of rough endo-plasmic reticulum and mitochondria from the central region. Immunohistochemical studies showed a marked decrease of SP, CGRP, and SOM staining in small ganglion cells with central chromatolysis when compared with cells from control ganglia.

CONCLUSION

It is important to be aware that in patients with nerve root compression due to lumbar disc herniation or lumbar canal stenosis, dysfunction is not confined to degeneration at the site of compression, but also extends to the primary sensory neurons within the dorsal root ganglion as a result of the axon reaction. Patients with sensory disturbance should therefore be fully informed of the fact that these symptoms will not resolve immediately after surgery.

Herpes simplex virus infection of murine sensory ganglia induces proliferation of neuronal satellite cells

Herpes simplex virus (HSV) is a virtually ubiquitous human pathogen that, following cutaneous infection, latently infects neurons of sensory ganglia. Satellite cells (SCs) ensheath and provide metabolic support for these neurons, and could potentially participate in controlling HSV disease. Although SCs are restrictive for HSV replication, hypercellularity of non-neuronal cells in ganglia is prominent during HSV infection in animal models. SCs proliferate in response to trauma, e.g. nerve cut or crush, but it is not known if proliferation occurs in response to viral infection. To address this issue, cell proliferation, measured by bromodeoxyuridine (BrdU) uptake, and immune infiltrate, measured by CD45 labelling, were examined during acute infection in a mouse model. Because SCs do not express CD45, the BrdU(+) CD45(-) cell subset represents the proliferating SC population. We report that during acute ganglionic HSV infection there is a substantial increase in SC numbers. We suggest that SC proliferation in response to HSV infection may occur in order to facilitate neuronal survival.

Satellite cell reactions to axon injury of sensory ganglion neurons: increase in number of gap junctions and formation of bridges connecting previously separate perineuronal sheaths

This study investigated satellite cell changes in mouse L4 and L5 spinal ganglia 14 days after unilateral transection of sciatic and saphenous nerves. The ganglia were studied under the electron microscope in single and serial sections, and by dye injection. Satellite cell responses to axon injury of the neurons with which they are associated included the formation of bridges connecting previously separate perineuronal sheaths and the formation of new gap junctions, resulting in more extensive cell coupling. Some possible consequences of these satellite cell reactions are briefly discussed.

Satellite cell proliferation in murine sensory ganglia in response to scarification of the skin

Satellite cells (SCs) ensheathe neuronal cell bodies of sensory ganglia and provide mechanical and metabolic support for neurons. In mice, grossly detrimental stimuli such as nerve crush or cut, or explant culture of ganglia induce proliferation of SCs. It is unknown whether SC proliferation occurs in response to the less severe trauma that might commonly occur in a physiological situation. Our aim was to determine the response of SCs to mild trauma, such as scratching the skin. SC proliferation, measured by bromodeoxyuridine (BrdU) uptake, and immune cells, measured by CD45 labelling, were quantified at various times during the 7 days after scarification or abrasion of flank skin. We show that minimal skin trauma, such as scarification or light abrasion, triggers proliferation of SCs. Sections of control mice nervous tissue show <10 BrdU+ cells/ganglionic profile. In contrast, sections of traumatised mice show >50 BrdU+ cells/ganglionic profile, even after simply scratching the skin. The lack of CD45+ cells shows that the proliferating cells are not immune cells. We suggest that SCs in mice are a labile cell population able to proliferate rapidly in response to minimal nerve trauma. This finding has implications for the role of SCs in nervous system repair.

Effect of nerve crush on perikaryal number and volume of neurons in adult rat dorsal root ganglion

Assumption-free stereological methods were applied to assess the effect of nerve crush on perikaryal number and mean volume of neuronal subpopulations in adult rat dorsal root ganglion (DRG). The L5 spinal nerve of 20 Wistar rats was crushed approximately 7 mm distal to the DRG, and the contralateral spinal nerve and DRG were left intact and used as controls. After four, 15, 45, and 120 days, the rats were killed, and the tissue was fixed and processed for subsequent preparation of 30-microm-thick sections. Estimates of neuron number were obtained with the optical fractionator technique and estimates of the mean perikaryal volume with the vertical planar rotator principle. Perikaryal loss was progressive during the early study period but stabilized 45 days after nerve injury. The mean number (n) of all neurons in intact L5 DRG was 16,400 (S.D. = 2,000). The loss of perikarya was 16% (P < 0.05) after four days, 15% (P < 0.05) after 15 days, 30% (P = 0.059) after 45 days, and 34% (P < 0. 05) after 120 days. B cells were lost at an earlier time than were A cells, and the B cell loss was more pronounced (39% vs. 22%, respectively, after 120 days). For A cells, the mean perikaryal volume was initially reduced but was normalized at the end of the study. Distributions of perikaryal volume showed that the curves of both A and B cells were uniformly displaced toward smaller values 15 and 45 days after injury. Neuronal loss caused by crush seems similar to that seen in rats exposed to permanent axotomy (Vestergaard et al. [1997] J Comp Neurol 388:307-312) at the same location, indicating that survival of perikarya is not dependent on possibility for fiber growth.

Nuclear clefting in dorsal root ganglion neurons: a response to whole body vibration

Normal adult rabbits were studied in a whole body vibration model which simulates the type of environmental exposure associated with vibration-induced low back pain. This model has previously been shown to induce changes in pain-related neuropeptides in the dorsal root ganglion. Following two weeks of daily exposure to whole body vibration, dorsal root ganglia were excised from control and vibrated rabbits and prepared for ultrastructural evaluation. Of over 1,200 cells sampled, 190 appropriately sectioned cells were analyzed: 32 from immobilized controls, 44 from normal controls, and 114 from vibrated animals. Analysis of nuclear contours revealed more prevalent and more extensive clefting of the nuclear membrane in vibrated cells. The membrane lining these clefts was traversed by numerous pores; density of these pores was 46% greater than in adjacent nonclefted segments (p less than .001). Number of clefts per nucleus was increased by 39% in vibrated animals. Cleft area represented 1.19% of nuclear area in vibrated cells compared to 0.74% in controls (p less than .001). Numerous mitochondria and free ribosomes and abundant rough endoplasmic reticulum were located within the cleft spaces of vibrated cells. Pores in the cleft membrane appeared normal, supporting the conclusion that the clefts are structural alterations rather than fixation or sectioning artifacts. Changes in dorsal root ganglion neuropeptides seen in previous studies of vibrated animals may result from increased or redirected cellular synthesis. Ultrastructural changes seen in these vibrated dorsal root ganglion neurons are consistent with such an alteration in metabolism and could reflect increased synthesis of pain-related neuropeptides.

Axonal sprouting after botulinum toxin does not elicit a histological axon reaction

In an attempt to determine which elements of the axon reaction are essential for early axonal outgrowth, axonal sprouting was induced with botulinum toxin (BoTx) and the nerve cell body changes compared with those accompanying axonal growth after nerve trauma. Anterior horn cells of mice were examined histologically at times ranging from 3 days to 3 weeks after either BoTx hindlimb injection or sciatic nerve crush. After sciatic nerve crush there was dispersion of Nissl substance, increase in cell body size, and an increase in neurofilament protein staining. None of these changes were found after BoTx-induced terminal axonal sprouting, suggesting that these morphological features of the axon reaction are not essential for early axonal outgrowth.

Cell death in the adult rat dorsal root ganglion after hind limb amputation, spinal cord transection, or both operations

Cell death of embryonic neurons which are unable to attain a proper target is well established. A delayed cell death of adult neurons permanently separated from their target tissue has been demonstrated for several cell groups. Cells of the dorsal root ganglia (DRG) are unique in that a single T-shape neurite has a peripheral branch which extends (for root L5) to the hind limb and a central branch extending into the spinal cord. We found a significant loss of L5 DRG neurons 25 weeks after hind limb amputation. This finding is consistent with the hypothesis that neuron survival is dependent on connection with a suitable target. We were unable to detect cell death in the DRG of L5 after complete spinal cord transection at T9. Separation of DRG cells from their central target is unimportant to neuronal survival.

Cytological study of the cellular changes after transection of the proximal radix of the rat trigeminal ganglion

Cytological changes following transection of the proximal root of the trigeminal ganglion in adult rats were assessed by light and electron microscopy. Radices were transected about 3-5 mm from the ganglia and animals were killed from 1 to 60 days after the operation. Light microscopically, it was found that all Nissl granules became uniformly stained and evenly distributed throughout the cytoplasm within 3 days. Three types of cell alteration involving Nissl granules occurred within 3 to 12 days after the operation: 1) chromatolysis, 2) dark staining of the cytoplasm accompanied by an increase of Nissl granules, and 3) faint staining of the cytoplasm accompanied by dispersion of Nissl granules. Electron microscopically, the chromatolysis pattern was characterized by peripheral concentration of the granular endoplasmic reticulum (gER) and ribosomes in the cytoplasm. Neurons of the dark-staining type showed an increased number of polysomal complexes throughout the cytoplasm, whereas those of the faint-staining type had diffusely dispersed cisternae of the gER which were shortened and bore reduced numbers of attached ribosomes. Perinuclear localization of profiles of Golgi complexes disappeared temporarily 1-3 days after the operation, but the normal perinuclear pattern appeared to return after 1 week. Enzyme histochemistry of acid phosphatase activity revealed an increase in the number of very fine reaction products in the cytoplasm up to 14 days following the operation. Cells recovered the normal pattern of Nissl staining by 48 days. Myelin figures, which are rarely observed in normal ganglia, were still observed in dense lysosomal bodies after 30 days. Nuclear size in affected neurons steadily increased up to about 2 weeks postoperation but returned to normal by 48 days.

Changes in the amounts of cytoskeletal proteins within the perikarya and axons of regenerating frog motoneurons

Changes in the amounts of tubulin, actin, and neurofilament polypeptides were found in regenerating motoneurons of grass frogs during the period of axonal elongation. Ventral roots 9 and 10 were transected unilaterally about 7 mm from the spinal cord. 35 d later, [3H]colchicine binding had decreased in the proximal stumps to approximately one-half of contralateral control values, well before the regenerating motor axons had reinnervated skeletal muscles of the hind limb. [3H]colchicine binding did not change significantly in the operated halves of the 9th and 10th spinal cord segments over a 75-d period. The relative amounts of actin, tubulin, and neurofilament polypeptides in the operated ventral roots were measured by quantitative densitometry of stained two-dimensional electrophoretic gels. Alpha-tubulin, beta-tubulin, and the 68,000 molecular weight subunit of neurofilaments (NF68) decreased within the transected ventral roots to 78%, 57%, and less than 15% of control values, respectively. The amount of actin increased to 132% of control values within the operated ventral roots, although this change was not statistically significant. Opposite changes were found within motoneuronal cell bodies isolated from the spinal cord. The relative amounts of alpha-tubulin, beta-tubulin and NF68 within axotomized perikarya increased, respectively, to 191%, 146%, and 144% of that in control perikarya isolated from the contralateral side of the spinal cord. Thus, the changes in NF68 and tubulin did not occur uniformly throughout the injured cells. The possible structural and functional consequences of these changes are discussed.

A comparative ultrastructural study of the trigeminal ganglion in the rat and chicken

The neurons of the trigeminal ganglia of the rat and chicken were characterized by means of light microscopic, electron microscopic, and histochemical methods. Light microscopy disclosed four types of neurons, based on the characteristics of Nissl granules: (1) large neurons with diffusely distributed and very fine granules, (2) neurons containing coarse and sparsely distributed Nissl granules, (3) neurons containing dense Nissl granules of varying size, and (4) small neurons with granules concentrated peripherally. Electron microscopy allowed further definition of these four types of neurons by the length and arrangement of flattened cisterns of granular endoplasmic reticulum (gER) and the number of neurofilaments. Type 1 cells were largest, with a mean nuclear area of 139.8 +/- 28.3 micron2. Type 4 cells were smallest, with a mean nuclear area of 74.6 +/- 20.9 micron2. The mean nuclear areas of type 2 and 3 cells were intermediate to those of the type 1 and 4 cells. Type 3 and 4 neurons lacked neurofilaments. Four forms of Golgi apparatus were found: (1) large bent grains forming a network throughout the soma, (2) dispersed fine granular deposits, (3) fine or small granules, and (4) coarse bent deposits arranged confluently in the perinuclear zone. In some rat neurons, the concentration of acid phosphatase reaction products suggested a high enzymatic activity, whereas the chicken ganglion cells showed no such concentration. These findings are discussed and compared with the classifications of previous studies.

Alkaline Phosphatase distribution in the inferior vagal ganglion of the cat following vagotomy: a chronological study

The object of this study was to demonstrate sites of alkaline phosphatase activity within the cellular elements of the inferior vagal (nodosal) ganglion of the cat and chronologically observe and describe alterations in enzyme activity following vagotomy. In control tissues alkaline phosphatase activity was localized to the wall of perineuronal blood vessels and the satellite cell cytoplasm which envelops the neuronal perikarya. In the experimental tissues alkaline phosphatase activity was increased in the above locations during the first 20 days following vagotomy then gradually declined to approximate control levels by 60 days post-operatively. The functional significance of changes in alkaline phosphatase activity occurring within an altered metabolic environment induced by vagotomy is discussed.