Increase of interleukin-1β mRNA and protein in the spinal cord following experimental traumatic injury in the rat

Interleukin-1 beta (IL-1β) is a major mediator of inflammation and a growth promoter for many cell types that could play an important role in the consequences of traumatic spinal cord injury (SCI). In the present study, the expression of IL-1β and its mRNA was determined in the rat spinal cord following a standardized contusion injury. IL-1β mRNA, measured with quantitative RT-PCR, was significantly increased in the lesion site by 1 h after SCI (35.2±5.9 vs. 9.1±2.1 pg/mg RNA, n=3, P<0.05) and remained significantly higher than in the normal spinal cord for at least 72 h post-injury (p.i.). IL-1β mRNA levels in tissue immediately caudal to the lesion site did not change after the injury. IL-1β protein levels, measured by an ELISA, were determined at the lesion site and in cerebrospinal fluid (CSF) and serum samples. IL-1β levels in the CSF and serum were much lower than in the spinal cord. At the lesion site, IL-1β was increased significantly by 1 h p.i., peaked at 8 h (32.3±0.1 vs. 7.6±1.9, ng/g tissue, n=5, P<0.05) and remained significantly higher than normal through at least 7 days p.i. These results suggest that the increased IL-1β mRNA and protein levels are an early and local response at the lesion site that could trigger other, later, responses to traumatic SCI.     

betaII-tubulin and GAP 43 mRNA expression in chronically injured neurons of the red nucleus after a second spinal cord injury

Regeneration by chronically injured supraspinal neurons is enhanced by treatment of a spinal cord lesion site with a variety of neurotrophic and growth factors. The removal of scar tissue, with subsequent reinjury of the spinal cord, is necessary for injured axons to access tissue transplants placed into the lesion to support axon regrowth. The present study examined chronically injured and reinjured rubrospinal tract (RST) neurons to determine if changes in gene expression could explain the failure of these neurons to regenerate without exogenous trophic factor support. Adult female rats were subjected to a right full hemisection lesion via aspiration of the cervical level 3 spinal cord. Using radioactive cDNA probes and in situ hybridization, RST neurons in the contralateral red nucleus were examined for changes in mRNA levels of betaII-tubulin and GAP 43 in an acute injury period (6 h-3 days), a chronic injury period (28 days after spinal cord injury (SCI)) and following a second lesion of the chronic injury site (6 h-7 days). Based upon the analysis of gene expression in single cells, GAP-43 mRNA levels were increased as early as 1 day following the initial SCI, but were no different than uninjured control levels at 28 days postoperative (dpo). The response to relesion was more rapid and higher than that detected after the initial injury with a significant increase in GAP 43 mRNA at 6 h that was maintained for at least 7 days. betaII-tubulin mRNA levels remained unchanged until 3 days after an acute injury followed by a decrease in expression to 30% below uninjured control values at 28 dpo. The expression of betaII-tubulin mRNA was significantly higher within 6 h after a second injury, where it remained stable for 5 days before a second increase occurred at 7 days after reinjury of the spinal cord. Thus, neurons in a chronic injury state retain the ability to respond to a traumatic injury and, in fact, neurons subjected to a second injury exhibit a significantly heightened expression of regeneration-associated genes.     

NGF message and protein distribution in the injured rat spinal cord

Nerve growth factor (NGF) content of the spinal cord is increased after cord injury. NGF can cause central sprouting of sensory fibers after spinal cord injury (SCI), leading to autonomic dysfunction and pain. NGF also can promote the death of oligodendroglia after SCI. Knowing the source of intraspinal NGF would benefit strategies for minimizing abnormal plasticity and cell death after SCI. We identified these sources, using RNA in situ hybridization to detect NGF mRNA and double-labeling immunocytochemistry for NGF and cell-marking antigens. In uninjured and sham-injured rats, we identified NGF mRNA in leptomeningeal cells and in neurons in the intermediate grey matter, whereas NGF protein was observed only in leptomeningeal cells. At 3-7 days after transection or clip-compression SCI, NGF mRNA and protein were expressed in the lesion and throughout the intermediate grey matter and white matter rostral and caudal to the injury site. Transection-SCI was used to permit comparisons to previous studies; clip-compression injury was used as a more clinically relevant model. mRNA and protein in adjacent sections were expressed in ramified microglia, astrocytes, intermediate grey neurons, pial cells, and leptomeningeal and Schwann cells in the lateral white matter and the lesion site. Rounded macrophages in the lesion were immunoreactive (Ir) for NGF, but the cells expressing NGF mRNA were not in the same areas of the lesion and were not stained by a macrophage marker. Our data demonstrate that glia, neurons, meningeal cells and Schwann cells but not macrophages contribute to the increased intraspinal NGF after SCI.     

Production of tumor necrosis factor in spinal cord following traumatic injury in rats

Production of tumor necrosis factor (TNF) in the spinal cord following traumatic injury has been studied. In these experiments, the level of TNF was examined in the homogenate of the spinal cord, cerebrospinal fluid (CSF) and serum (n = 56). TNF could be detected in the injured spinal cord but not in the normal spinal cord. The TNF level increased in the spinal cord after the injury. At the lesion site, a maximal TNF concentration was observed 1 h after the injury, and the TNF concentration remained at this level until 8 h after the injury. Thereafter, it decreased gradually. However, TNF still could be detected 72 h after the injury. No TNF could be detected in the CSF and serum, collected from rats both with and without spinal cord injury (SCI). This study thus suggests that TNF is produced locally in the spinal cord following traumatic injury, and this TNF production is caused by the injury. The present results also demonstrate that TNF production is an acute and rapid reaction in the spinal cord following traumatic injury.     

成年大鼠脊髓全横断损伤后酪氨酸激酶受体C在脊髓和大脑皮层的表达

目的 研究神经营养因子3(neurotrophin-3,NT-3)的受体-酪氨酸激酶受体C(tyrosine kinase receptor C,TrkC)在脊髓损伤(spinal cord injury,SCI)后神经重塑中的作用.方法 研究脊髓全横断损伤大鼠手术后第1、3、7和14 d时,低位胸髓节段和大脑中央前回...     

过氧化物酶体增殖物激活受体γ在大鼠脊髓损伤后继发性损伤中的表达变化

目的 观察大鼠脊髓损伤后继发性损伤中过氧化物酶体增殖物激活受体γ(PPARγ)表达的变化.方法 将72只雄性SD大鼠按照随机数字表法分为损伤组(建立大鼠脊髓损伤模型)和对照组(仅显露脊髓,不做打击伤),每组各36只.实时免疫荧光定量多聚酶链反应(FQ-PCR)检测脊髓损伤后1 d、3 d、7 d、14 d、28 d、56 dPPARγmRNA的表达变化,每个时间点取6只大鼠.蛋白印记检测脊髓损伤后1 d、3 d、7 d、14 d、28 d、56 d PPARγ的表达变化.结果 与对照组比较,损伤组脊髓组织中PPARγmRNA和PPARγ表达均明显增加,差异均有统计学意义(P＜0.05),其表达高峰在脊髓损伤后14d.结论 脊髓损伤后在继发性损伤中PPARγ的表达明显增加,表达高峰在脊髓损伤后14d.     

Pathophysiological activity in rat dorsal horn neurones in segments rostral to a chronic spinal cord injury

As a sequel of complete spinal cord injury (SCI), patients often develop chronic pain which is perceived at or just below the level of the lesion. Likewise, in animal models of SCI, spontaneous and evoked pain-related behaviour can be observed. In the present study, the hypothesis was tested that pain related behaviour after SCI in animals is at least partly due to neuronal hyperactivity in spinal segments rostral to the site of injury. In rats with a chronic transected spinal cord, the impulse activity of single dorsal horn neurones was recorded in two locations: (1) directly rostrally adjacent to the lesion, and (2) 2-3 segments more rostrally. Cord transections were made either at the thoracic or at the lumbar level. Sham-operated rats and rats which underwent no surgical interventions served as controls. Compared with both controls, in SCI animals the background activity of the neurones had a significantly higher level in both series. Often the activity showed a pathophysiological altered discharge pattern. Following SCI, there was a general increase in the mechanical responsiveness of neurones that were recorded 2-3 segments rostrally to the lesion. The results suggest that neuronal hyperactivity in spinal segments just rostral to the lesion may contribute to chronic spontaneous SCI pain. Further, there is some indication that the allodynia perceived in body regions near and above the level of the SCI may be due to increased responsiveness to weak stimuli of neurones located more rostrally to the lesion.     

Spatiotemporal patterns of postsynaptic density (PSD)-95 expression after rat spinal cord injury

Aims: Postsynaptic density (PSD)-95 is a scaffolding protein linking the N-methyl-D-aspartate receptor with neuronal nitric oxide synthase (nNOS), which contributes to many physiological and pathological actions. We here investigated whether PSD-95 was involved in the secondary response following spinal cord injury (SCI). Methods: Spinal cord contusion (SCC) and spinal cord transection (SCT) models at thoracic (T) segment 9 (T₉) were established in adults rats. Real-time polymerase chain reaction, Western blot, immunohistochemistry and immunofluorescence were used to detect the temporal profile and spatial distribution of PSD-95 after SCI. The association between PSD-95 and nNOS in the injured cords was also assessed by coimmmunoprecipation and double immunofluorescent staining. Results: The mRNA and protein for PSD-95 expression were significantly increased at 2 h or 8 h, and then gradually declined to the baseline level, ultimately up-regulated again from 5 days to 7 days for its mRNA level and at 7 days or 14 days for its protein level after either SCC or SCT. PSD-95 immunoreactivity was found in neurones, oligodendrocytes and synaptic puncta of spinal cord tissues within 5 mm from the lesion site. Importantly, injury-induced expression of PSD-95 was colabelled by active caspase-3 (apoptotic marker), Tau-1 (the marker for pathological oligodendrocytes) and nNOS. Conclusions: Accompanied by the spatio-temporal changes for PSD-95 expression, the association between PSD-95 and nNOS undergoes substantial alteration after SCI. These two molecules are likely to form a complex on apoptotic neurones and pathological oligodendrocytes, which may in turn be involved in the secondary response after SCI.     

Major vault protein promotes locomotor recovery and regeneration after spinal cord injury in adult zebrafish

In contrast to mammals, adult zebrafish recover locomotor functions after spinal cord injury (SCI), in part due to axonal regrowth and regeneration permissivity of the central nervous system. Upregulation of major vault protein (MVP) expression after spinal cord injury in the brainstem of the adult zebrafish prompted us to probe for its contribution to recovery after SCI. MVP is a multifunctional protein expressed not only in many types of tumours but also in the nervous system, where its importance for regeneration is, however, unclear. Using an established zebrafish SCI model, we found that MVP mRNA and protein expression levels were increased in ependymal cells in the spinal cord caudal to the lesion site at 6 and 11 days after SCI. Double immunolabelling showed that MVP was co‐localised with Islet‐1 or tyrosine hydroxylase around the central canal of the spinal cord in sham‐injured control fish and injured fish 11 days after surgery. MVP co‐localised with the neural stem cell marker nestin in ependymal cells after injury. By using an in vivo morpholino‐based knock‐down approach, we found that the distance moved by MVP morpholino‐treated fish was reduced at 4, 5 and 6 weeks after SCI when compared to fish treated with standard control morpholino. Knock‐down of MVP resulted in reduced regrowth of axons from brainstem neurons into the spinal cord caudal to the lesion site. These results indicate that MVP supports locomotor recovery and axonal regrowth after SCI in adult zebrafish.     

Increase in TNFalpha transport after SCI is specific for time, region, and type of lesion

The dynamic changes of the blood-brain barrier and blood-spinal cord barrier (BBB) are an important part of the CNS response to injury. This study addresses the permeability of the BBB in the acute phase of spinal cord injury (SCI) to the thoracic region. SCI by compression or by complete transection was generated in mice. BBB disruption was evaluated by spinal cord uptake of radiolabeled albumin. The BBB of the thoracic spinal cord was disrupted immediately after compression injury, lasting for 2 days. This was followed by a delayed permeability increase in the cervical spinal cord beginning 3 days after injury. After transection, BBB disruption was limited to the thoracic spinal cord and was present only immediately postinjury. The entry of TNFalpha not only was increased at the time of BBB disruption, following the same pattern, but also had secondary changes after the BBB permeability to albumin had returned to normal. The increase of TNFalpha entry, best explained by upregulation of the specific transport system for TNFalpha, was pronounced in the lumbar spinal cord as well as the thoracic region, and followed a different time course after the two types of injury. Integrating our results with those of the literature regarding the roles of inflammatory responses and the effects of TNFalpha in spinal cord regeneration, we conclude that the time-, region-, and lesion-specificity of the upregulation of TNFalpha transport is part of the regulatory changes at the BBB in response to SCI.     

PAF antagonist treatment reduces pro-inflammatory cytokine mRNA after spinal cord injury

Platelet-activating factor (PAF) is a pro-inflammatory molecule which contributes to secondary damage after spinal cord injury (SCI).To test if PAF contributes to cytokine induction following SCI, female Long-Evans rats were pretreated with the PAF antagonist WEB 2170 prior to receiving a contusion injury at spinal cord level T10 using the NYU impactor. RNase protection assay (RPA) analysis revealed that IL-1alpha mRNA peaked at I h post-injury while IL-1beta and IL-6 mRNA levels were higher and peaked at 6 h.TNF-alpha mRNA was almost undetectable. All mRNA levels approached baseline by 24 h. Treatment with WEB 2170 (1 mg/kg, i.p.) 15 min prior to injury significantly decreased mRNA levels for all three cytokines at 6 h post-injury, but not at I h post-injury. These results demonstrate a role for PAF in proinflammatory cytokine induction after SCI.     

Calpain activity and expression increased in activated glial and inflammatory cells in penumbra of spinal cord injury lesion

Following traumatic injury of the spinal cord, cells adjacent to the lesion are subject to ischemic cell death as a result of vascular disruption and secondary inflammatory responses. Proteases such as calcium-activated neutral proteinase (calpain) have been implicated in axon and myelin destruction following injury since they degrade structural proteins in the axon-myelin unit. To examine the role of calpain in cell death following spinal cord injury (SCI), calpain activity and translational expression were evaluated using Western blotting techniques. Calpain activity (as measured by specific substrate degradation) was significantly increased in and around the lesion site as early as 4 hr following injury with continued elevation at 48 hr compared to sham controls. Likewise, calpain expression was significantly increased in both the lesion site and penumbra at 4 and 48 hr after injury. Using double immunofluorescent labeling for calpain and cell-specific markers, this increase in calpain expression was found to be due in part to activated glial/inflammatory cells such as astrocytes, microglia, and infiltrating macrophages in these areas. Thus, since calpain degrades many myelin and axonal structural proteins, the increased activity and expression of this enzyme may be responsible for destruction of myelinated axons adjacent to the lesion site following SCI.     

Expression of CAPON after Spinal Cord Injury in Rats

The adaptor protein, carboxy-terminal PDZ ligand of nNOS (CAPON), regulates the distribution of neuronal nitric oxide synthase (nNOS) that increased after spinal cord injury (SCI) and produces the key signaling molecule nitric oxide (NO). But little is known about the role of CAPON in the pathological process of SCI. The main objective of the present study was to investigate expression of CAPON and nNOS in a spinal cord contusion model in adult rats. Real time-polymerase chain reaction (PCR) and Western blot analysis revealed that mRNA and protein for CAPON increased at 2 h after SCI and reached the peak at 8 h, gradually recovered to the baseline level at 14 days. The expression of nNOS mRNA and protein was similar to that of CAPON. During the peak expression, CAPON mRNA was found in the ventral horn, mediate zone, dorsal horn, and white matter by in situ hybridization. Immunofluorescence showed that CAPON was colocalized with nNOS in neurons, oligodendrocytes, and some astrocytes of spinal cord tissues within 5 mm from the epicenter. Interaction between CAPON and nNOS was also detected by co-immunoprecipitation. Thus, the transient expression of high levels of CAPON may provide new insight into the secondary response after SCI. Chun Cheng and Xin Li contributed equally to this work.     

Neural progenitor cells but not astrocytes respond distally to thoracic spinal cord injury in rat models

Traumatic spinal cord injury(SCI) is a detrimental condition that causes loss of sensory and motor function in an individual. Many complex secondary injury cascades occur after SCI and they offer great potential for therapeutic targeting. In this study, we investigated the response of endogenous neural progenitor cells,astrocytes, and microglia to a localized thoracic SCI throughout the neuroaxis. Twenty-five adult female Sprague-Dawley rats underwent mild-contusion thoracic SCI(n = 9), sham surgery(n = 8), or no surgery(n = 8). Spinal cord and brain tissues were fixed and cut at six regions of the neuroaxis. Immunohistochemistry showed increased reactivity of neural progenitor cell marker nestin in the central canal at all levels of the spinal cord. Increased reactivity of astrocyte-specific marker glial fibrillary acidic protein was found only at the lesion epicenter. The number of activated microglia was significantly increased at the lesion site,and activated microglia extended to the lumbar enlargement. Phagocytic microglia and macrophages were significantly increased only at the lesion site. There were no changes in nestin, glial fibrillary acidic protein,microglia and macrophage response in the third ventricle of rats subjected to mild-contusion thoracic SCI compared to the sham surgery or no surgery. These findings indicate that neural progenitor cells, astrocytes and microglia respond differently to a localized SCI, presumably due to differences in inflammatory signaling. These different cellular responses may have implications in the way that neural progenitor cells can be manipulated for neuroregeneration after SCI. This needs to be further investigated.     

Neuroprotective Effect of Endogenous Pituitary Adenylate Cyclase-Activating Polypeptide on Spinal Cord Injury

Pituitary adenylate cyclase-activating polypeptide (PACAP) is a neuroprotective peptide expressed in the central nervous system. To date, changes in the expression and effect of endogenous PACAP have not been clarified with respect to spinal cord injury (SCI). The aim of this study was to elucidate the expression pattern and function of endogenous PACAP on the contusion model of SCI using heterozygous PACAP knockout (PACAP(+/-)) and wild-type mice. Real-time polymerase chain reaction methods revealed that the level of PACAP mRNA increased gradually for 14?days after SCI and that PAC1R mRNA levels also increased for 7?days compared with intact control mice. PACAP and PAC1R immunoreactivities colabeled with a neuronal marker in the intact spinal cord. Seven days after SCI, PAC1R immunoreactivity was additionally co-expressed with an astrocyte marker. Wild-type mice gradually recovered motor function after 14?days, but PACAP(+/-) mice showed significantly impaired recovery from 3?days compared with wild-type mice. The injury volume at day?7 in PACAP(+/-) mice, and the number of single-stranded DNA-immunopositive cells as a marker of neuronal cell death at day?3 were significantly higher than values measured in wild-type mice. These data suggest that endogenous PACAP is upregulated by SCI and has a neuroprotective effect on the damaged spinal cord.     

Role of tumor necrosis factor-alpha in neuronal and glial apoptosis after spinal cord injury

We investigated the role of tumor necrosis factor (TNF)-alpha in the onset of neuronal and glial apoptosis after traumatic spinal cord crush injury in rats. A few TUNEL-positive cells were first observed within and surrounding the lesion area 4 h after injury, with the largest number observed 24-48 h after injury. Double-labeling of cells using cell type-specific markers revealed that TUNEL-positive cells were either neurons or oligodendrocytes. One hour after injury, an intense immunoreactivity to TNF-alpha was observed in neurons and glial cells in the lesion area, but also seen in cells several mm from the lesion site rostrally and caudally. The level of nitric oxide (NO) also significantly increased in the spinal cord 4 h after injury. The injection of a neutralizing antibody against TNF-alpha into the lesion site several min after injury significantly reduced both the level of NO observed 4 h thereafter as well as the number of apoptotic cells observed 24 h after spinal cord trauma. An inhibitor of nitric oxide synthase (NOS), N(G)-monomethyl-l-arginine acetate (l-NMMA), also reduced the number of apoptotic cells. This reduction of apoptotic cells was associated with a decrease in DNA laddering on agarose gel electrophoresis. These results suggest that: (i) TNF-alpha may function as an external signal initiating apoptosis in neurons and oligodendrocytes after spinal cord injury; and (ii) TNF-alpha-initiated apoptosis may be mediated in part by NO as produced by a NOS expressed in response to TNF-alpha.     

重复经颅磁刺激对急性脊髓损伤大鼠运动功能的影响

目的 探讨重复经颅磁刺激对急性脊髓损伤大鼠运动功能的影响. 方法 24只SD大鼠按照随机数字表法分为正常组、脊髓损伤对照组(对照组)、脊髓损伤高频磁刺激组(高频组)、脊髓损伤低频磁刺激组(低频组),每组6只.利用重物撞击法制作T10脊髓损伤模型.磁刺激组于手术后24 h开始给予刺激,高频组频率为10Hz,低频组频率为1 Hz,均为阈值刺激.500个脉冲,每天1次,连续4周,脊髓损伤对照组给予假刺激.各组大鼠分别于术后1 d、3d、7d、11 d、14d、21 d、28 d进行BBB行为学评分,于14、28 d时检测运动诱发电位(MEP),应用HE染色观察脊髓组织形态学变化,并应用免疫组织化学法检测神经丝蛋白(NF-200)表达变化. 结果 高频组、低频组大鼠BBB评分明显高于对照组,高频组BBB评分明显高于低频组,差异均有统计学意义(P<0.05).高频组、低频组运动诱发电位潜伏期较短,与对照组、正常组相比差异均有统计学意义(P<0.05);其中高频组较低频组短,差异有统计学意义(P<0.05).高频组、低频组NF-200表达较对照组明显升高,差异均有统计学意义(P<0.05);其中高频组较低频组高,差异有统计学意义(P<0.05).结论 重复经颅磁刺激可以促进脊髓损伤大鼠运动功能的恢复,其机制可能与促进轴突再生有关.高频组较低频组效果明显可能与调节大脑皮层兴奋性有关.