A Radio-telemetric System to Monitor Cardiovascular Function in Rats with Spinal Cord Transection and Embryonic Neural Stem Cell Grafts

High thoracic or cervical spinal cord injury (SCI) can lead to cardiovascular dysfunction. To monitor cardiovascular parameters, we implanted a catheter connected to a radio transmitter into the femoral artery of rats that underwent a T4 spinal cord transection with or without grafting of embryonic brainstem-derived neural stem cells expressing green fluorescent protein. Compared to other methods such as cannula insertion or tail-cuff, telemetry is advantageous to continuously monitor blood pressure and heart rate in freely moving animals. It is also capable of long term multiple data acquisitions. In spinal cord injured rats, basal cardiovascular data under unrestrained condition and autonomic dysreflexia in response to colorectal distension were successfully recorded. In addition, cardiovascular parameters before and after SCI can be compared in the same rat if a transmitter is implanted before a spinal cord transection. One limitation of the described telemetry procedure is that implantation in the femoral artery may influence the blood supply to the ipsilateral hindlimb.     

Upregulation of G-protein Coupled Receptor 120 in Rats Following Spinal Cord Injury

Neurochemical Research - G protein-coupled receptors (GPCRs) are fundamental mediators of a wide array of processes including proliferation, immune cell function and neural signaling. GPR120 is a...     

Fas and FasL Expression in the Spinal Cord Following Cord Hemisection in the Monkey

The changes of endogenous Fas/FasL in injured spinal cord, mostly in primates, are not well known. In this study, we investigated the temporal changes in the expression of Fas and FasL and explored their possible roles in the ventral horn of the spinal cord and associated precentral gyrus following T(11) spinal cord hemisection in the adult rhesus monkey. A significant functional improvement was seen with the time going on in monkeys subjected to cord hemisection. Apoptotic cells were also seen in the ventral horn of injured spinal cord with TUNEL staining, and a marked increase presents at 7 days post operation (dpo). Simultaneously, the number of Fas and FasL immunoreactive neurons in the spinal cords caudal and rostral to injury site and their intracellular optical density (OD) in the ipsilateral side of injury site at 7 dpo increased significantly more than that of control group and contralateral sides. This was followed by a decrease and returned to normal level at 60 dpo. No positive neurons were observed in precentral gyrus. The present results may provide some insights to understand the role of Fas/FasL in the spinal cord but not motor cortex with neuronal apoptosis and neuroplasticity in monkeys subjected to hemisection spinal cord injury.     

Mesenchymal Stem Cells from Rat Bone Marrow Downregulate Caspase-3-mediated Apoptotic Pathway After Spinal Cord Injury in Rats

Mesenchymal stem cells have been intensively studied for their potential use in reparative strategies for neurodegenerative diseases and traumatic injuries. We used mesenchymal stem cells (rMSC) from rat bone marrow to evaluate the therapeutic potential after spinal cord injury (SCI). Immunohistochemistry confirmed a large number of apoptotic neurons and oligodendrocytes in caudal segments 2 mm away from the lesion site. Expression of caspase-3 on both neurons and oligodendrocytes after SCI was significantly downregulated by rMSC. Caspase-3 downregulation by rMSC involves increased expression of FLIP and XIAP in the cytosol and inhibition of PARP cleavage in the nucleus. Animals treated with rMSC had higher Basso, Beattie, Bresnahan (BBB) locomotor scoring and better recovery of hind limb sensitivity. Treatment with rMSC had a positive effect on behavioral outcome and histopathological assessment after SCI. The ability of rMSC to incorporate into the spinal cord, differentiate and to improve locomotor recovery hold promise for a potential cure after SCI. Special issue in honor of Naren Banik.     

Cell Lineage and Regional Identity of Cultured Spinal Cord Neural Stem Cells and Comparison to Brain-Derived Neural Stem Cells

Neural stem cells (NSCs) can be isolated from different regions of the central nervous system. There has been controversy whether regional differences amongst stem and progenitor cells are cell intrinsic and whether these differences are maintained during expansion in culture. The identification of inherent regional differences has important implications for the use of these cells in neural repair. Here, we compared NSCs derived from the spinal cord and embryonic cortex. We found that while cultured cortical and spinal cord derived NSCs respond similarly to mitogens and are equally neuronogenic, they retain and maintain through multiple passages gene expression patterns indicative of the region from which they were isolated (e.g Emx2 and HoxD10). Further microarray analysis identified 229 genes that were differentially expressed between cortical and spinal cord derived neurospheres, including many Hox genes, Nuclear receptors, Irx3, Pace4, Lhx2, Emx2 and Ntrk2. NSCs in the cortex express LeX. However, in the embryonic spinal cord there are two lineally related populations of NSCs: one that expresses LeX and one that does not. The LeX negative population contains few markers of regional identity but is able to generate LeX expressing NSCs that express markers of regional identity. LeX positive cells do not give rise to LeX-negative NSCs. These results demonstrate that while both embryonic cortical and spinal cord NSCs have similar self-renewal properties and multipotency, they retain aspects of regional identity, even when passaged long-term in vitro. Furthermore, there is a population of a LeX negative NSC that is present in neurospheres derived from the embryonic spinal cord but not the cortex.     

Effects of Embryonic Neural Stem Cell Transplantation on DNA Damage in the Brain and Spinal Cord Following Spinal Cord Injury

Embryonic neural stem cell (ENSC) transplantation is used experimentally for the improvement of spinal cord repair following spinal cord injury (SCI). However, the effects of such intervention on oxidative stress and cell death remain unknown. We used in vivo Comet assay in the acute and chronic SCI groups compared with the SCI+ENSC transplantation groups of experimental rats in order to evaluate DNA damage in the spinal cord. Chronic SCI resulted in the generation of oxidative DNA damage in the spinal cord brain and kidneys, as indicated by high Comet assay parameters, including the percentage of DNA in the tail (T%, or TD), tail moment (TM), and tail length (TL). The DNA damage levels significantly decreased after ENSC transplantation in the spinal cords of acute and chronic SCI groups within the lesion site and rostrally and caudally to the injury, and in the brains and kidneys of the chronic SCI group. Thus, ENSC transplantation is found to be an effective tool for limitation of DNA damage following spinal cord injury.     

胎鼠脊髓源性神经干细胞分离培养与鉴定

目的:研究胎鼠的脊髓源性神经干细胞的分离培养方法并观察其增殖和分化能力。方法:利用显微操作技术分离获得胎鼠脊髓组织、无血清培养技术和酶消化法结合机械法传代培养神经干细胞、免疫细胞化学方法鉴定神经干细胞和分化情况。结果:建立了胎鼠脊髓源性神经干细胞的分离、培养和鉴定的方法,观察到了脊髓源性神经干细胞具有较强的增殖能力,在添加有5ng／mlEGF和5ng／mlbFGF的无血清培养液中可贴壁分化为神经元、少突细胞和星形胶质细胞。结论:在体外培养条件下分离培养的胎鼠脊髓源性神经干细胞具有干细胞的特性即较强的增殖能力和多向分化潜能。     

Recovery of CNS Pathway Innervating the Sciatic Nerve Following Transplantation of Human Neural Stem Cells in Rat Spinal Cord Injury

Stem cell research has been attained a greater attention in most fields of medicine due to its potential for many incurable diseases through replacing or helping the regeneration of damaged cells or tissues. Here, we demonstrated the functional recovery and structural connection of the central nervous system pathway innervating the sciatic nerve after total transection of the spinal cord followed by the transplantation of human neural stem cells (hNSC) in the injured rat spinal cord site. The limb function of hNSC-treated group recovered dramatically compared with that in the sham group by Basso–Beattie–Bresnahan (BBB) scores. Transplanted hNSC differentiated into astrocytes and neurons in the injured site. In addition, immunohistochemistry for growth-associated protein 43 showed axonal regeneration in the injured spinal cord site. The pseudorabies viral-Ba (PRV-Ba) tracing method revealed that transplanted hNSC and their differentiated neurons showed positive labeling after sciatic nerve injection. In addition, the PRV-Ba labeling was also observed in several nuclei in the brain innervating the sciatic nerve. This result implies that the rat CNS motor pathway could be reconstructed by hNSC transplantation, and it may contribute to the functional recovery of the limb.     

G—CSF对大鼠脊髓损伤后神经细胞凋亡及caspase-3表达的影响

目的：通过观察粒细胞集落刺激因子（G—CSF）对大鼠急性脊髓损伤后神经细胞凋亡及Caspase-3的表达的影响,探讨其对脊髓保护的作用机制。方法：32只Vistar大鼠随机分成2组：对照组和治疗组,每组16只,采用改良的Allen’s装置制成大鼠急性脊髓损伤模型。在术前及术后对大鼠进行BBB功能评分观察大鼠的神经功能变化;用免疫荧光法检测脊髓损伤后个时间点Caspase-3表达;原位脱氧核糖核苷酸末端转移酶介导的缺口末端标记法（Tunel法）检测凋亡细胞。结果：大鼠急性脊髓损后Caspase-3表达与细胞凋亡均呈现先升高后下降的趋势,损伤后3d可见大量的Caspase-3和TUNEL阳性细胞,7d时达到高峰,此后表达逐渐减少,21d时仍可见少量阳性细胞。与对照组比较,G—CSF治疗组各时间点Caspase-3表达和细胞凋亡显著降低,功能恢复显著优于对照组,差异具有统计学意义。结论：G-CSF可以减轻大鼠脊髓损伤后的神经元凋亡,从而发挥神经保护作用,其作用可能是通过抑制Caspase-3的表达使脊髓损伤周围神经细胞凋亡显著下降而实现的。     

G-CSF对大鼠脊髓损伤后神经细胞凋亡及caspase-3表达的影响

目的:通过观察粒细胞集落刺激因子(G-CSF)对大鼠急性脊髓损伤后神经细胞凋亡及Caspase-3的表达的影响,探讨其对脊髓保护的作用机制.方法:32只Vistar大鼠随机分成2组:对照组和治疗组,每组16只,采用改良的Allen's装置制成大鼠急性脊髓损伤模型.在术前及术后对大鼠进行BBB功能评分观察大鼠的神经功能变化;用免疫荧光法检测脊髓损伤后个时间点Caspase-3表达;原位脱氧核糖核苷酸末端转移酶介导的缺口末端标记法(Tunel法)检测凋亡细胞.结果:大鼠急性脊髓损后Caspase-3表达与细胞凋亡均呈现先升高后下降的趋势,损伤后3d可见大量的Caspase-3和TUNEL阳性细胞,7d时达到高峰,此后表达逐渐减少,21d时仍可见少量阳性细胞.与对照组比较,G-CSF治疗组各时间点Caspase-3表达和细胞凋亡显著降低,功能恢复显著优于对照组,差异具有统计学意义.结论:G-CSF可以减轻大鼠脊髓损伤后的神经元凋亡,从而发挥神经保护作用,其作用可能是通过抑制Caspase-3的表达使脊髓损伤周围神经细胞凋亡显著下降而实现的.     

Stem Cells Downregulate the Elevated Levels of Tissue Plasminogen Activator in Rats After Spinal Cord Injury

We investigated the involvement of tPA after SCI in rats and effect of treatment with human umbilical cord blood derived stem cells. tPA expression and activity were determined in vivo after SCI in rats and in vitro in rat embryonic spinal neurons in response to injury with staurosporine, hydrogen peroxide and glutamate. The activity and/or expression of tPA increased after SCI and reached peak levels on day 21 post-SCI. Notably, the tPA mRNA activity was upregulated by 310-fold compared to controls on day 21 post-SCI. As expected, MBP expression is minimal at the time of peak tPA activity and vice versa. Implantation of hUCB after SCI resulted in the downregulation of elevated tPA activity/expression in vivo in rats as well as in vitro in spinal neurons. Our results demonstrated the involvement of tPA in the secondary pathogenesis after SCI as well as the therapeutic potential of hUCB.     

Analysis of Gene Expression Following Sciatic Nerve Crush and Spinal Cord Hemisection in the Mouse by Microarray Expression Profiling

1. The responses of periphery (PNS) and central nervous systems (CNS) towards nerve injury are different: while injured mammalian periphery nerons can successfully undergo regeneration, axons in the central nervous system are usually not able to regenerate.2. In the present study, the genes which were differentially expressed in the PNS and CNS following nerve injury were identified and compared by microarray profiling techniques.3. Sciatic nerve crush and hemisection of the spinal cord of adult mice were used as the models for nerve injury in PNS and CNS respectively.4. It was found that of all the genes examined, 14% (80/588) showed changes in expression following either PNS or CNS injury, and only 3% (18/588) showed changes in both types of injuries.5. Among all the differentially expressed genes, only 8% (6/80) exhibited similar changes in gene expression (either up- or down-regulation) following injury in both PNS and CNS nerve injuries.6. Our results indicated that microarray expression profiling is an efficient and useful method to identify genes that are involved in the regeneration process following nerve injuries, and several genes which are differentially expressed in the PNS and/or CNS following nerve injuries were identified in the present study.     

NADPH Oxidase and Superoxide-Producing Associates in Cells of the Spinal Cord and Bone Marrow in Diabetic Rats with Spinal Cord Injury

Neurophysiology - For the first time, a method for isolation and purification of the total fraction of NOX isoforms (NOX1 + NOX2) and the total fraction of O2 – producing stable associates of...     

Effects of Alpha-Synuclein on Primary Spinal Cord Neurons Associated with Apoptosis and CNTF Expression

Spinal cord injury (SCI) often causes neurological deficits with poor recovery; the treatment, however, is far from satisfaction, and the mechanisms remain unclear. Using immunohistochemistry and western blotting analysis, we found α-synuclein (SNCA) was significantly up-regulated in the spinal caudal segment of rats subjected to spinal cord transection at 3 days post-operation. Moreover, the role of SNCA on neuronal growth and apoptosis in vitro was determined by using overexpressing and interfering SNCA recombined plasmid vectors, and the underlying mechanism was detected by QRT-PCR and western blotting. Spinal neurons transfected with SNCA-shRNA lentivirus gave rise to an optimal neuronal survival, while it results in cell apoptosis in SNCA-ORF group. In molecular level, SNCA silence induced the up-regulation of CNTF and down-regulation of Caspase7/9. Together, endogenous SNCA plays a crucial role in spinal neuronal survival, in which the underlying mechanism may be linked to the regulation both apoptotic genes (Caspase7/9) and CNTF. The present findings therefore provide novel insights into the role of SNCA in spinal cord and associated mechanism, which may provide novel cue for the treatment of SCI in future clinic trials.     

Roles of ES Cell-Derived Gliogenic Neural Stem/Progenitor Cells in Functional Recovery after Spinal Cord Injury

Transplantation of neural stem/progenitor cells (NS/PCs) following the sub-acute phase of spinal cord injury (SCI) has been shown to promote functional recovery in rodent models. However, the types of cells most effective for treating SCI have not been clarified. Taking advantage of our recently established neurosphere-based culture system of ES cell-derived NS/PCs, in which primary neurospheres (PNS) and passaged secondary neurospheres (SNS) exhibit neurogenic and gliogenic potentials, respectively, here we examined the distinct effects of transplanting neurogenic and gliogenic NS/PCs on the functional recovery of a mouse model of SCI. ES cell-derived PNS and SNS transplanted 9 days after contusive injury at the Th10 level exhibited neurogenic and gliogenic differentiation tendencies, respectively, similar to those seen in vitro. Interestingly, transplantation of the gliogenic SNS, but not the neurogenic PNS, promoted axonal growth, remyelination, and angiogenesis, and resulted in significant locomotor functional recovery after SCI. These findings suggest that gliogenic NS/PCs are effective for promoting the recovery from SCI, and provide essential insight into the mechanisms through which cellular transplantation leads to functional improvement after SCI.     

Promotion of Survival and Differentiation of Neural Stem Cells with Fibrin and Growth Factor Cocktails after Severe Spinal Cord Injury

Neural stem cells (NSCs) can self-renew and differentiate into neurons and glia. Transplanted NSCs can replace lost neurons and glia after spinal cord injury (SCI), and can form functional relays to re-connect spinal cord segments above and below a lesion. Previous studies grafting neural stem cells have been limited by incomplete graft survival within the spinal cord lesion cavity. Further, tracking of graft cell survival, differentiation, and process extension had not been optimized. Finally, in previous studies, cultured rat NSCs were typically reported to differentiate into glia when grafted to the injured spinal cord, rather than neurons, unless fate was driven to a specific cell type. To address these issues, we developed new methods to improve the survival, integration and differentiation of NSCs to sites of even severe SCI. NSCs were freshly isolated from embryonic day 14 spinal cord (E14) from a stable transgenic Fischer 344 rat line expressing green fluorescent protein (GFP) and were embedded into a fibrin matrix containing growth factors; this formulation aimed to retain grafted cells in the lesion cavity and support cell survival. NSCs in the fibrin/growth factor cocktail were implanted two weeks after thoracic level-3 (T3) complete spinal cord transections, thereby avoiding peak periods of inflammation. Resulting grafts completely filled the lesion cavity and differentiated into both neurons, which extended axons into the host spinal cord over remarkably long distances, and glia. Grafts of cultured human NSCs expressing GFP resulted in similar findings. Thus, methods are defined for improving neural stem cell grafting, survival and analysis of in vivo findings.     

Anti-inflammatory and Anti-apoptotic Effect of Combined Treatment with Methylprednisolone and Amniotic Membrane Mesenchymal Stem Cells After Spinal Cord Injury in Rats

This study was undertaken to investigate the synergistic effects of methylprednisolone (MP) administration and transplantation of amniotic membrane mesenchymal stem cells (AM-MSCs) following T11 spinal cord clip compressive injury in rats. The combination treatment with MP (50 mg/kg) and delayed transplantation of AM-MSCs after rat spinal cord injury, significantly reduced (1) myeloperoxidase activity, (2) the proinflammatory cytokines: tumor necrosis factor-α, interleukin (IL)-1β, IL-6, IL-17, interferon-γ and (3) the cell apoptosis [terminal deoxynucleotidyl transferase, dUTP nick end labeling (TUNEL) staining, and caspase-3, Bax and Bcl-2 expressions]; increased: (1) the levels of the anti-inflammatory cytokines (IL-10 and transforming growth factor-β1) and (2) the survival rate of AM-MSCs in the injury site. The combination therapy significantly ameliorated the recovery of limb function (evaluated by Basso, Beattie and Bresnahan score). Taken together, our results demonstrate that MP in combination with AM-MSCs transplantation is a potential strategy for reducing secondary damage and promoting functional recovery following spinal cord injury.