Tropic 1808基因重组蛋白对大鼠坐骨神经再生的影响

目的观察Tropic1808基因重组蛋白对坐骨神经损伤后再生的影响。方法SD大鼠16只,分为Tropic1808基因重组蛋白组和生理盐水组,切断左侧坐骨神经,硅胶管套接后两神经断端间距10mm,再生室内注入Tropic 1808基因重组蛋白液(500μg/ml)或生理盐水13μl。术后每4周做一次足迹试验,16周时作神经干动作电位、脊髓前角运动神经元数、腓肠肌纤维截面积、硅胶管中段再生神经等检测。结果Tropic1808基因重组蛋白组SFI的恢复、神经干动作电位、脊髓前角运动神经元数、腓肠肌纤维截面积、硅胶管中段再生神经有髓神经纤维数等结果均明显优于生理盐水组,有统计学意义。电镜观察表明Tropic1808组再生轴突较NS组粗,髓鞘较生理盐水组厚。结论Tropic1808基因重组蛋白有促进大鼠坐骨神经再生的作用。     

周围神经43kD蛋白免疫化学研究

目的：制图周围神经43kD蛋白单克隆抗体,并检测该蛋白在正常及损伤坐骨神经中的表达,方法：实验用SDS－聚丙烯酰胺胺凝胶电泳系统,从周围神经中分离回收43kD蛋白作为抗原,免疫BALB／c小鼠,通过杂交瘤技术和点膜印迹法检测,获得分泌识别43kD蛋白的单克隆抗体的杂交瘤细胞株,以Westernblot方法检测单克隆抗体的特异性,并检测43kD蛋白在正常坐骨神经及损伤坐骨神经远侧端中的表达。结果：经检测获得了识别43kD蛋白的单克隆抗体,Westernblot显示在正常大鼠坐骨神经与损伤后2周的坐骨神经远侧端组织电泳图谱43kD处均出现特异的阳性反应条带,在损伤神经中43kD蛋白阳性反应产物着色较深。结论：43kD蛋白具有独特的免疫化学特性,在正常与损伤坐骨神经中的有表达,在损伤坐骨神经中表达更强。     

神经再生过程中脊髓运动神经元β管蛋白基因表达的变化

损伤大鼠右侧坐骨神经后,SDS—PAGE电泳分析双侧腹角细胞中蛋白含量变化,发现损伤侧的管蛋白相对含量较对照侧增加了17％—121％。损伤后3—14d损伤侧腹角运动神经元中β管蛋白mRNA的原位杂交信号增强了27％—70％,β管蛋白mRNA的Northern杂交分析也显示基因表达的增强。     

大鼠损伤坐骨神经远侧端CNTF表达的免疫组织化学研究

目的：探讨大鼠坐骨神经损伤后CNTF的表达和变化。方法：采用抗CNTF抗免疫组织化学方法和计算机图像处理系统定量观察大鼠正常坐骨神经与坐骨神经横断损伤后1周、2周、4周神经远侧端CNTF的表达。结果：正常大鼠坐骨神经具有高水平的CNTF免疫阳性反应,坐骨神经损伤后1周、2周、4周远侧端神经中CNTF免疫阳性反应均低于正常坐骨神经,免疫阳性反应强度为正常＞伤后1周＞伤后2周＞伤后4周,呈逐渐减弱趋势。结论：大鼠坐骨神经损伤后远侧端神经中CNTF的表达呈下调性变化。     

β-1,4半乳糖基转移酶-I在大鼠坐骨神经损伤后的表达变化

目的分析β-1,4半乳糖基转移酶-I(β-1,4-galactosyltransferase I,β-1,4-GalT-I)mRNA在正常和损伤坐骨神经髓鞘上的定位及其表达变化.方法采用RT-PCR方法,分析β-1,4-GalT-I在小鼠坐骨神经中的表达水平.将RT-PCR扩增的β-1,4-GalT-I片段,克隆到pGEM-T载体中.采用体外转录的方法合成地高辛标记的正、反义β-1,4-GalT-I RNA探针.通过原位杂交及图像分析的方法,分析β-1,4-GalT-I mRNA在正常和损伤大鼠坐骨神经的定位及其表达变化.结果检测到β-1,4-GalT-I在大鼠坐骨神经的髓鞘中有表达,并在坐骨神经损伤后1～2d内表达最高,随后表达下降.结论提示β-1,4-GalT-I可能在周围神经最主要的胶质细胞-施万细胞中表达,并在周围神经损伤后发生表达变化,这样为进一步分析β-1,4-GalT-I在周围神经再生中的调控机制奠定基础.     

早期干预ERK在脊髓的激活可阻断外周神经损伤引起的神经病理性疼痛的发生

本文采用大鼠坐骨神经慢性压迫损伤引起的神经病理痛模型,研究脊髓背角细胞外信号调节激酶(extracellular signal-regulatedkinase,ERK)在外周神经损伤引起的神经病理疼痛发生中的作用.结果显示,单侧坐骨神经压迫性损伤后1天,大鼠损伤侧脊髓背角ERK的磷酸化(激活)水平显著上调,其下游转录因...     

周围神经损伤后神经组织中Par-3蛋白表达和分布的变化

目的观察极性蛋白Par-3在损伤后神经组织中的表达和分布,探讨Par-3蛋白在周围神经损伤后髓鞘再生中的作用。方法 32只Sprague Dawley大鼠随机分为正常对照组、损伤组(坐骨神经损伤后第1、2、4、8周)。制备坐骨神经挤压伤模型,分别于损伤后各时间点,采用免疫组织化学法检测坐骨神经损伤远端Par-3蛋白的表达和分布。结果正常大鼠坐骨神经组织中即存在Par-3蛋白,但表达量少,且仅分布于Schwann细胞核内。坐骨神经损伤后,Par-3蛋白的表达和分布发生变化。损伤后1周,Par-3蛋白表达开始升高,Par-3散在分布于Schwann细胞核和细胞浆内。损伤后2周,神经组织中的Par-3蛋白达峰值,在Schwann细胞浆内呈不对称性分布似包绕轴突,呈新月形或C形。损伤后4周和8周,Par-3蛋白表达显著降低,神经组织中Par-3蛋白主要分布于Schwann细胞核内,胞浆内很少。结果 极性蛋白Par-3可能参与周围神经损伤后Schwann细胞的髓鞘再生。     

染色体着丝粒中结构蛋白CenpB的基因在乳腺癌组织中的活跃表达

利用Northern印迹技术对31例乳腺癌组织块及每一例病人的癌旁正常(非癌性)组织块进行分析,发现多数情况下(87．1％)癌组织中着丝粒蛋白CenpB mRNA过表达;组织原位杂交分析表明,在CenpB mRNA过表达的乳腺癌组织中,呈现出比癌旁正常组织更强的杂交信号;用免疫印迹法研究同样的标本,结果与RNA水平上的研究高度一致。结果显示,CenpB基因的过表达可能与乳腺细胞恶性增殖有关。     

β-1，4半乳糖基转移酶-Ⅰ在大鼠坐骨神经损伤后的表达变化

目的分析β-1,4半乳糖基转移酶-Ⅰ(β-1,4-galactosyltransferaseⅠ,β-1,4-GalT-Ⅰ)mRNA在正常和损伤坐骨神经髓鞘上的定位及其表达变化。方法采用RT-PCR方法,分析β-1,4-GalT-Ⅰ在小鼠坐骨神经中的表达水平。将RT-PCR扩增的β-1,4-GalT_I片段,克隆到pGEM-T载体中。采用体外转录的方法合成地高辛标记的正、反义β-1,4-GalT-ⅠRNA探针。通过原位杂交及图像分析的方法,分析β-1,4-GalT-ⅠmRNA在正常和损伤大鼠坐骨神经的定位及其表达变化。结果检测到β-1,4-GalT-Ⅰ在大鼠坐骨神经的髓鞘中有表达,并在坐骨神经损伤后1～2d内表达最高,随后表达下降。结论提示β-1,4-GalT-Ⅰ可能在周围神经最主要的胶质细胞一施万细胞中表达,并在周围神经损伤后发生表达变化,这样为进一步分析β-1,4-GalT-Ⅰ在周围神经再生中的调控机制奠定基础。     

青岛文昌鱼S-腺苷高半胱氨酸水解酶基因的组织特异性表达

为了探索文昌鱼S-腺苷高半胱氨酸水解酶AdoHcyase基因在文昌鱼组织中的表达分布情况,利用组织原位杂交技术,以地高辛标记的反义RNA为探针,检测了文昌鱼AdoHcyase基因在组织中的表达分布特点.结果表明,AdoHcyase基因在雌性文昌鱼的卵巢、肝盲囊和后肠杂交信号十分强烈,在内柱、鳃等组织中也有微弱信号表达,...     

S-100 protein in Schwann cells of the developing human peripheral nerve

Summary From approximately 7 weeks gestational age in developing human peripheral nerve, as in adult nerve, S-100 protein was found to be expressed solely and uniformly by Schwann cells associated with axons. In embryos younger than 7 weeks S-100 was much less constant and many cells did not show clear staining. The trigger for the initial appearance of the protein at around this age remains unclear although a relationship of S-100 expression in Schwann cells to close axonal contact is suggested. The value of S-100 protein in distinguishing Schwann cells from perineurial cells in normal nerves and nerve sheath tumours remains unclear.     

Immunocytochemical localization of S-100b protein in degenerating and regenerating rat sciatic nerves

We studied the cellular and subcellular distribution of S-100b protein in normal, crushed, and transected rat sciatic nerves by an immunocytochemical procedure. In uninjured nerves, S-100b protein was restricted to the cytoplasm and membranes of Schwann cells, with no reaction product present in the nucleus or in axons. Similar images were seen from the first to the thirtieth day after the crush in activated Schwann cells during the degeneration period, i.e., up to the seventh post-lesion day, and in normal Schwann cells reappearing during the regeneration period, i.e., after the seventh post-lesion day, in the zone of the crush and proximal and distal to it. By the technique employed, there seemed to be no differences in the intensity of the immune reaction product in normal and activated Schwann cells. Also, similar images were seen in the proximal stump of transected nerves. Only a slight S-100b protein immune reaction product could be observed in the rare activated Schwann cells present in the distal stump around the seventh post-lesion day, the majority of cell types being represented by fibroblasts and elongated cells at this stage and thereafter. By immunochemical assays, similar results as those presented here have been reported and interpreted as indicative of the presence of S-100 protein in axons or, alternatively, of axonal control over expression of S-100 protein in Schwann cells. Our immunocytochemical data clearly show that the strong reduction in the S-100 protein content of the distal stump of transected nerves is owing to the paucity of Schwann cells and to the decrease in the S-100 protein content of these cells, rather than to degeneration of axons.     

Lentiviral vectors enveloped with rabies virus glycoprotein can be used as a novel retrograde tracer to assess nerve recovery in rat sciatic nerve injury models

Retrograde labeling has become the new “gold standard” technique to evaluate the recovery of injured peripheral nerves. In this study, lentiviral vectors with rabies virus glycoprotein envelop (RABV-G-LV) and RFP genes are injected into gastrocnemius muscle to determine the location of RFP in sciatic nerves. We then examine RFP expression in the L4-S1 spinal cord and sensory dorsal root ganglia and in the rat sciatic nerve, isolated Schwann cells, viral dose to expression relationship and the use of RABV-G-LV as a retrograde tracer for regeneration in the injured rat sciatic nerve. VSV-G-LV was used as control for viral envelope specificity. Results showed that RFP were positive in the myelin sheath and lumbar spinal motorneurons of the RABV-G-LV group. RFP gene could be detected both in myelinated Schwann cells and lumbar spinal motor neurons in the RABV-G-LV group. Schwann cells isolated from the RABV-G-LV injected postnatal Sprague Dawley rats were also RFP-gene positive. All the results obtained in the VSV-G-LV group were negative. Distribution of RFP was unaltered and the level of RFP expression increasing with time progressing. RABV-G-LV could assess the amount of functional regenerating nerve fibers two months post-operation in the four models. This method offers an easy-operated and consistent standardized approach for retrograde labeling regenerating peripheral nerves, which may be a significant supplement for the previous RABV-G-LV-related retrograde labeling study.     

Changes in the concentration of enolase isozymes and S-100 protein in degenerating and regenerating rat sciatic nerve

Levels of enolase isozymes (alpha alpha, alpha gamma, and gamma gamma forms) and S-100 protein in rat sciatic nerves were determined during their degeneration and regeneration processes. The sciatic nerves were unilaterally crushed or severed. The rats were killed 1, 2, 6, and 8-9 weeks later, and both the proximal and distal portions of the damaged nerves were dissected. Control samples were obtained from the untreated contralateral hindlimbs. Enolase isozymes and S-100 protein in the nerve segments were determined with the enzyme immunoassay method. The control nerves contained about 40, 90, and 30 pmol/mg protein of alpha alpha, alpha gamma, and gamma gamma enolases, respectively, and 0.85 microgram/mg protein of S-100 protein. These levels were not affected by repetitive electrical stimulation of the nerve fibers in vivo. The levels of the nervous system-specific forms of enolase (alpha gamma and gamma gamma) and S-100 protein decreased markedly within a week in the distal portion of the crushed nerve (alpha gamma, 27 pmol/mg; gamma gamma, 5.5 pmol/mg; S-100 protein, 0.36 microgram/mg) with apparently no change in the concentration of alpha alpha enolase. These levels in the proximal portion of the crushed nerve remained unaltered. The sensory and motor functions impaired by the sciatic nerve crush showed a recovery more or less after 4-9 weeks. This recovery was accompanied by a gradual regaining of the specific proteins in the distal portion of injured nerves (alpha gamma, 64 pmol/mg; gamma gamma, 13 pmol/mg; S-100 protein, 0.63 microgram/mg at the 8-9th week).     

Inhibition of Ras extracellular-signal-regulated kinase (ERK) mediated signaling promotes ciliary neurotrophic factor (CNTF) expression in Schwann cells

Ciliary neurotrophic factor (CNTF) can prevent injury-induced motor neuron death. However, it is also evident that expression of CNTF in Schwann cells is suppressed during nerve regeneration. In this report, we have addressed the mechanism underlying the down-regulation of CNTF expression in injured nerves using a mouse Schwann cell line IMS32 and mouse sciatic nerve. In IMS32 cells, activation of the Ras extracellular-signal-regulated kinase (ERK) pathway by adenoviral vector-mediated expression of dominant active MEK1 did not alter a basal level of CNTF expression, whereas inhibition of the Ras-ERK pathway by using adenoviral vectors resulted in a marked increase in CNTF expression. This inverse relation between before and after axotomy was also observed in mouse sciatic nerve. In the axotomized sciatic nerve, the phosphorylated ERK was markedly increased; in contrast, the expression of CNTF was markedly decreased. These findings suggest that an inactive state of ERK is crucial for the CNTF expression in Schwann cells, and that activation of ERK following nerve injury critically influences the expression of CNTF. This might well explain why CNTF is highly expressed in quiescent Schwann cells in the peripheral nervous system, and also why CNTF is not abundant in axotomized nerves or cultured Schwann cells in which the proliferation signal is obviously active.     

低温保存许旺细胞对周围神经再生的作用

目的：比较原代培养许旺细胞（Schwann cells,SCs)和冷冻保存的SCs移植对损伤后坐骨神经再生的作用。方法：原代培养和液氮保存的SCs分别移植到桥接缺损坐骨神经的硅胶管内。在移植后不同时间（第6和8周末）,硅胶管远端神经干内注射HRP,逆行追踪背根神经节和脊髓前角的标记神经元数量;测量再生神经纤维的复合动作电位传导速度;电镜观察再生神经纤维的髓鞘形成。结果：原代培养和冷冻保存SCs在移植后不同时间其背根神经节和脊髓前角神经元HRP标记细胞数量、再生神经纤维的复合动作电位传导速度基本一致,再生神经纤维髓鞘的形成未见明显差别。结论：冷冻保存的SCs仍具有促进损伤后周围神经再生的能力。     

Knockout of p75(NTR) impairs re-myelination of injured sciatic nerve in mice

Remyelination is an important aspect of nerve regeneration after nerve injury but the underlying mechanisms are not fully understood. The neurotrophin receptor, p75(NTR), in activated Schwann cells in the Wallerian degenerated nerve is up-regulated and may play a role in the remyelination of regenerating peripheral nerves. In the present study, the role of p75(NTR) in remyelination of the sciatic nerve was investigated in p75(NTR) mutant mice. Histological results showed that the number of myelinated axons and thickness of myelin sheath in the injured sciatic nerves were reduced in mutant mice compared with wild-type mice. The myelin sheath of axons in the intact sciatic nerve of adult mutant mice is also thinner than that of wild-type mice. Real-time RT-PCR showed that mRNA levels for myelin basic protein and P0 in the injured sciatic nerves were significantly reduced in p75(NTR) mutant animals. Western blots also showed a significant reduction of P0 protein in the injured sciatic nerves of mutant animals. These results suggest that p75(NTR) is important for the myelinogenesis during the regeneration of peripheral nerves after injury.     

Expression of β‐1,4‐galactosyltransferase I in rat Schwann cells

Glycosylation is one of the most important post‐translational modifications. It is clear that the single step of β‐1,4‐galactosylation is performed by a family of β‐1,4‐galactosyltransferases (β‐1,4‐GalTs), and that each member of this family may play a distinct role in different tissues and cells. In the present study, real‐time PCR revealed that the β‐1,4‐GalT I mRNA reached peaks at 2 weeks after sciatic nerve crush and 3 days after sciatic nerve transection. Combined in situ hybridization for β‐1,4‐GalT I mRNA and immunohistochemistry for S100 showed that β‐1,4‐GalT I mRNAs were mainly located in Schwann cells after sciatic nerve injury. In conclusion, β‐1,4‐GalT I might play important roles in Schwann cells during the regeneration and degeneration of the injured sciatic nerve. In other pathology, such as inflammation, we found that LPS administration affected β‐1,4‐GalT I mRNA expression in sciatic nerve in a time‐ and dose‐dependent manner, and β‐1,4‐GalT I mRNA is expressed mainly in Schwann cells. These results indicated that β‐1,4‐GalT I plays an important role in the inflammation reaction induced by intraperitoneal injection of LPS. Similarly, we found that β‐1,4‐GalT I in Schwann cells in vitro was affected in a time‐ and concentration‐dependent manner in response to LPS stimulation. All these results suggest that β‐1,4‐GalT I play an important role in Schwann cells in vivo and vitro during pathology. In addition, β‐1,4‐GalT I production was drastically suppressed by U0126 (ERK inhibitor), SB203580 (p38 inhibitor), or SP600125 (SAPK/JNK inhibitor), which indicated that Schwann cells which regulated β‐1,4‐GalT I expression after LPS stimulation were via ERK, SAPK/JNK, and P38 MAP kinase signal pathways. J. Cell. Biochem. 108: 75–86, 2009. © 2009 Wiley‐Liss, Inc.     

Tropic1808基因的原核表达及其表达产物的生物活性

Tropic180 8基因是新近获得的一个鼠源性的cDNA .Tropic180 8基因开放阅读框架片段通过PCR方法从质粒中扩增后 ,重组入表达载体pET 2 1a中 ,转化大肠杆菌BL2 1(DE3 ) .用IPTG诱导目的蛋白的表达 ,SDS PAGE并凝胶图象分析确定目的蛋白表达水平占细菌总蛋白的 14%以上 .表达蛋白在N端融合有 16个氨基酸 ,将表达蛋白电转移至PVDF膜 .氨基酸序列分析表明 ,其N端第 17～ 2 5位氨基酸序列与Tropic180 8基因编码序列一致 .利用融合部分含T7·Tag ,通过亲和层析纯化表达蛋白 ,经Westernblot检测为目的蛋白 ,加入到无血清培养的新生SD大鼠背根神经节 (DRG)中 ,观察到表达蛋白对DRG具有促进存活和促进突起生长的作用 .