Gui n Li

Apoptosis and expression of Bcl-2 after compression trauma to rat spinal cord.

We have evaluated by in situ nick-end labeling the presence of apoptotic cells in the spinal cord of rats with compression injury at the level of Th8–9, of mild, moderate, and severe degrees resulting in no neurologic deficit, reversible paraparesis, and paraplegia, respectively. Rats with compression injury surviving 4 or 9 days showed apoptotic glial cells in the longitudinal tracts of the Th8–9, the cranial Th7, and the caudal Th10 segments. The apoptotic cells were most frequently observed in Th7. They did not express glial fibrillar acidic protein (GFAP) and their morphology was compatible with that of oligodendrocytes. Neurons of the gray matter did not present signs of apoptosis. In addition, we studied the immunohisto-chemical expression of Bcl-2, an endogenous inhibitor of apoptosis. Compression induced Bcl-2 immunoreactivity in axons of the long tracts, particularly after moderate and severe compression and 1-day survival. Neurons of dorsal root ganglia were immunoreactive but the neurons of the spinal cord were unstained. The accumulation, presumably caused by arrested axonal transport in sensory pathways, was absent in rats surviving 9 days. In conclusion, compression trauma to rat spinal cord induces signs of apoptosis in glial cells, presumably oligodendrocytes of the long tracts. This may induce delayed myelin degeneration after trauma to the spinal cord. Bcl-2 does not seem to be upregulated in oligodendrocytes

Apoptosis of oligodendrocytes occurs for long distances away from the primary injury after compression trauma to rat spinal cord

Abstract We evaluated by in situ nick end labeling the presence of apoptotic glial cells in the spinal cord of rats which have sustained a moderate and severe compression injury at the level of T8–9, resulting in a severe but reversible paraparesis and irreversible paraplegia, respectively. In a previous investigation we found apoptotic glial cells (oligodendrocytes) in the immediate vicinity of the primary lesion (T7 and T10). The present study was designed to evaluate the extent of such cells in the spinal cord even at long distances away from the primary injury. Rats sustaining a moderate and severe compression injury and surviving 4 and 9 days showed a significant increase in the number of apoptotic glial cells at the T1, T5, T7, T12 and L2 levels. At the T10 level the elevation was significant only after day 9. There was no significant increase in the number of these cells at 4 h and 1 day after moderate and severe compression. In general, the apoptotic cells were most often seen in segments adjacent to the compression. They were randomly located in the ventral, lateral and dorsal tracts but were rarely present in the gray matter of the cord. In conclusion, compression trauma to rat spinal cord induces signs of apoptosis in glial cells, presumably oligodendrocytes of the long tracts. This newly discovered type of secondary injury is widely distributed in the damaged spinal cord and occurs even at long distances remote from the initial compression injury. Apoptotic cell death of oligodendrocytes will induce myelin degeneration and cause additional disturbances of axonal function. This cell damage may be a target for future therapy since it occurs after a delay and chemical compounds are now available by which apoptotic cell death can be modified.

Changes in microtubule-associated protein 2 and amyloid precursor protein immunoreactivity following traumatic brain injury in rat: influence of MK-801 treatment

We investigated by immunohistochemistry dendritic and axonal changes occurring in the rat brain after mild focal cortical trauma produced by the weight drop technique. One and 3 days after injury, nerve cell bodies and dendrites in the perimeter of the impact site displayed decreased microtubule-associated protein 2 (MAP2) immunoreactivity. Some dendrites in the immediate adjacent region were more intensely stained and distorted. The dentate hilar region of the hippocampus showed a reduction of immunoreactive nerve cell bodies and dendrites. Twenty-one days after injury the strongly stained cortical dendrites and the reduction of immunoreactivity in the hippocampus remained, whereas the reduced staining in the perimeter of the lesion had normalised. These results indicate that there is a long-lasting disturbed dendritic organisation implicating impaired neurotransmission after this type of mild brain trauma. beta-Amyloid precursor protein (APP) immunohistochemistry revealed numerous stained axons in the ipsilateral subcortical white matter and thalamus indicating local and remote axonal injuries with disturbed axonal transport. Twenty-one days after injury, numerous small immunostained profiles appeared in the neuropil of the cortical impact site and in the ipsilateral thalamus. The axonal changes indicate disturbed connectivity between the site of the impact and other brain regions, chiefly the thalamus. The presence of beta-amyloid was investigated 21 days after trauma. There were no signs of beta-amyloid depositions in the brain after injury. Finally, we tested if the non-competitive NMDA receptor antagonist dizocilpine maleate (MK-801) could influence the observed MAP2 and APP changes. Pretreatment with this compound did not affect the early MAP2 and APP alterations. Instead, an increased expression of the APP antigen in the thalamus was observed 21 days after trauma in the MK-801-treated animals. The cause of this phenomenon is not known but may be related to a delayed neurotoxic action of MK-801 treatment.

Traumatic brain injury in rat produces changes of β-amyloid precursor protein immunoreactivity

beta-Amyloid precursor protein immunoreactivity (APP) was studied after a mild compression contusion trauma to rat parietal cortex. Neurones in the periphery of the cortical lesion, i.e. tissue subjected to shear stress, showed markedly reduced immunoreactivity 1 and 3 days after injury. Numerous axons in the ipsilateral subcortical white matter and thalamus became immunoreactive. At 21 days, small rounded profiles appeared in the neuropil of the damaged cortex and in the thalamus. Thus, traumatic brain injury appears to induce several types of APP changes. The accumulation in neuronal processes is probably caused by disturbed axonal transport induced by trauma. Since APP is assumed to be excitoprotective, modulating intracellular Ca2+ responses, the decreased immunoreactivity noticed in the periphery of the lesion may render the neurones in this region more vulnerable to secondary injury mechanisms.

Behavioural and Morphological Outcome of Mild Cortical Contusion Trauma of the Rat Brain: Influence of NMDA-Receptor Blockade

Summary The authors studied the effect of a mild cortical contusion to the rat brain on behavioural and morphological outcome and the influence of NMDA-receptor blockade (MK-801, 0.5 mg/kg i.v. 30 min prior to trauma). Spontaneous motor activity was assessed 16–18 days post trauma. Saline treated traumatised rats showed a significant (p<0.01) hyperactive behaviour compared to animals without injury. MK-801 treated rats performed significantly better than the saline treated animals (p<0.05). For histopathological evaluation hippocampal hilar neurons were counted, cortical thickness under the impact was measured and microtubule-associated protein 2 (MAP2) immunoreactivity in the dentate hilus was quantified 1, 3 and 21 days post trauma. In traumatised rats scattered loss of nerve cells, oedema and minute haemorrhages were present at the site of the impact one and three days after injury. At day 21 there was a significant reduction of cortical thickness at the site of impact. One day after trauma there was a bilateral, significant loss of neurons and MAP2 immunostaining in the dentate hilus of the hippocampus. MK-801 pretreated rats showed similar morphological changes. The disturbed spontaneous motor behaviour may be caused by hippocampal damage and a reduction of somatosensory cortical neurons. NMDA-receptor blockade improved the outcome assessed by the functional tests but failed to influence the morphological changes, suggesting that this behavioural test is a more sensitive indicator of outcome after mild traumatic brain injury (TBI).

MAP2 and neurogranin as markers for dendritic lesions in CNS injury. An immunohistochemical study in the rat.

We compared two staining methods for the demonstration of dendrites under normal and pathological conditions of the rat central nervous system. MAP2‐ and neurogranin immunohistochemistry was applied to samples from normal tissue, spinal cord subjected to graded compression trauma, cerebral cortex following contusion trauma, and brains with focal ischemic lesions induced by occlusion of the middle cerebral artery (MCAO). Normal rats showed MAP2 immunoreactivity in nerve cell bodies and dendrites of brain and spinal cord. However, neurogranin staining was present only in nerve cell bodies and dendrites of the normal brain, and not in the spinal cord.

Vimentin and GFAP responses in astrocytes after contusion trauma to the murine brain

PURPOSE Astroglial responses after traumatic brain injury are difficult to detect with routine morphological methods. The aims for this study were to compare the temporal and spatial expression pattern of vimentin- and glial fibrillary acidic protein (GFAP) in a weight drop model of mild cerebral contusion injury in the rat. We also wanted to study the vimentin response with immunohistochemistry and vimentin mRNA RT-PCR analysis in severe cortical contusion injury produced by the controlled cortical impact in the mouse. METHODS Vimentin and GFAP immunohistochemistry (1 day, 3 days and 7 days) combined with vimentin mRNA RT-PCR analysis (1 h, 4 h, 22 h, 3 days and 7 days) were used after experimental traumatic brain injury in the rat and mouse. RESULTS Increases in post-traumatic vimentin mRNA levels in the cortex and in the hippocampus appeared together with vimentin immunoreactivity in astrocytes in the perimeter of the cortical lesion, in the subcortical white matter and in the hippocampus starting at one day after severe trauma. GFAP immunostaining revealed hypertrophic astrocytes peaking at day 3 in the perifocal cortical region. There was no significant increase in GFAP immunoreactivity in the white matter in the rat. However, in the mouse there was a slight increase in the number of GFAP positive cells in this region, 3 days after trauma. Overall the pattern of vimentin immunoreactivity was very similar in the rat and mouse. CONCLUSIONS Vimentin immunoreactivity was more sensitive than the GFAP staining method to demonstrate the distribution and time course of astrocyte reactions after a contusion injury, especially in the white matter distant from the cortical lesion.

Changes of Fas and Fas ligand immunoreactivity after compression trauma to rat spinal cord.

Abstract This immunohistochemical study evaluated Fas and Fas ligand (FasL) in the rat nervous system and their changes in the spinal cord subjected to compression. Normal spinal cord showed a low level of Fas and FasL immunoreactivity in the white matter except in the corticospinal tracts. Fas and FasL immunoreactivity seemed to be located in axons and their myelin sheaths. Other regions of the nervous system did not show immunoreactivity to Fas and FasL. Moderate and severe compression injury of the spinal cord resulted in a reduction of Fas and FasL immunoreactivity in the white matter of injured T8–9 segments at 4 h and a complete loss at 1 day after trauma. This was seen even in the remaining white matter. In contrast, increased immunoreactivity to Fas and FasL was present in the cranial T7, caudal T10 (moderate injury) and T12 (severe injury) segments at day 4 with most intense staining were seen at day 9 after trauma. Increased Fas and FasL immunoreactivity may have pathophysiological implications for the development of secondary injuries after trauma to the spinal cord. Fas-FasL interactions may for instance be involved in apoptosis of oligodendrocytes which occurs as a delayed phenomenon after trauma to the spinal cord. The integrity of myelin sheaths may in this way be jeopardized by apoptosis of oligodendrocytes.

Expression of endothelial barrier antigen immunoreactivity in blood vessels following compression trauma to rat spinal cord. Temporal evolution and relation to the degree of the impact.

Abstract The endothelial barrier antigen (EBA) recognised by a monoclonal antibody is expressed in rat cerebral microvessels possessing blood-brain barrier properties but only weakly by fenestrated vessels. We have studied the expression of this marker in the spinal cord of control rats and compared the findings with those seen in rats subjected to compression injury at the T8–9 level with a survival period of 4 h, 24 h, 4 days and 9 days. To that end, formalin-fixed paraffin-embedded material was immunostained by the avidin-biotin-peroxidase complex method. Sections from control rats presented a distinct immunostaining at the site of the endothelial cells of almost all microvessels in the grey and white matter of the cord. The anterior and posterior spinal arteries did not show such staining. Neurons and glial cells were unstained. Rats which had survived 4 h after a moderate or severe compression trauma still showed immunoreactivity in intramedullary microvessels at the site of injury. There was a moderate reduction of vascular immunoreactivity at 24 h and a pronounced loss of such reactivity at 4 days after trauma. At 9 days after compression the expression of the endothelial barrier antigen had almost been normalised in the microvessels of the cord. In conclusion, using immunohistochemistry, EBA can be demonstrated in noninjured rat spinal cord microvessels, while the staining disappears at the site of compression trauma to the cord. The EBA marker can be used to indicate sites of vascular injury in spinal cord compression injury. The factors causing the disappearance and restitution of the antigen are unknown.

Increased expression of growth-associated protein 43 immunoreactivity in axons following compression trauma to rat spinal cord.

Abstract Growth-associated protein 43 (GAP43) is one compound used to indicate growth of axonal endings during development and regeneration, particularly of peripheral neurons. Using immunohistochemistry, we have studied the expression of GAP43 in the spinal cord of rats subjected to mild, moderate or severe compression injury and used neurofilament immunostaining to demonstrate axonal injuries. Samples removed from the compressed T8–9, the cranial T7 and the caudal T10 segments were studied at 4 h, 24 h, 4 days and 9 days after injury. Control rats showed a moderate immunostaining of neurons in dorsal root ganglia, weak staining of ventral motor neurons and, with the exception of the corticospinal tracts, a weak staining in some axons of the longitudinal tracts of the cord. Injury in the compressed region led to increased GAP43 immunoreactivity in axons of normal and expanded size. This occurred particularly 1–4 days after injury and normalized 9 days thereafter. More marked immunostaining was present in the cranial and caudal segments. The corticospinal tracts never showed such staining. The increase of GAP43 immunostaining is presumably caused by disturbed axonal transport from neurons with the capacity to synthesize and transport the GAP43 antigen. Transported material may thus be available for regeneration of axons, but this source of material may vary between different classes of axons within the cord.