Myelin formation following transplantation of normal fetal glia into myelin-deficient rat spinal cord

Summary Structurally normal myelin sheaths develop in the spinal cord of juvenile myelin-deficient rats (mdr) 11 days after transplantation of normal fetal spinal cord fragments or cultured cells that do not yet express galactocerebroside. Cultures result in more extensive myelin formation, and in both cases the myelin that forms is located primarily at or near the site of transplantation.Myelin formation also occurs after transplantation of postnatal donor tissue, but the extent diminishes with donor age, and none was seen after transplantation of adult donor tissue over the two-week period studied. Injection of killed tissue, tissue derived from mouse donors or an extract of myelin also did not lead to myelin formation. The results imply that myelin formed in the host following transplantation was generated by oligodendrocytes newly differentiated from donor precursor cells rather than by donor oligodendrocytes that were already mature at the time of transplantation or by host oligodendrocytes that took up components of the injected material.We conclude that exogenous fetal glial cell precursors are able to survive, differentiate and form myelin in the environment of the juvenile mdr spinal cord.     

Transplantation of labeled fetal spinal cord fragments into juvenile myelin-deficient rat spinal cord

Minced and triturated fragments from the spinal cord of normal rat fetuses (15-18 days gestation) labeled with the fluorescent dye fast blue (FB) were successfully transplanted into juvenile myelin-deficient rat spinal cord under direct observation. Clusters of myelinated fibers were found subsequently in the recipient spinal cord, and, by fluorescence microscopy, clusters of FB-labeled cells were found at corresponding sites. The results indicate that the surgical approach used is suitable for transplantation of tissue fragments into a defined region of juvenile rat spinal cord, that FB can be used to locate the transplanted cells subsequently, and that FB does not interfere with maturation of the donor glia or with myelin formation.     

Conduction properties of spinal cord axons in the myelin-deficient rat mutant.

Spinal cords of myelin-deficient and normal age-matched (control) rats were removed and their conduction and pharmacological properties studied in an in vitro brain slice chamber. The conduction velocity of the myelin-deficient dorsal column axons was reduced to about 25% of control axons; however, the amyelinated myelin-deficient axons displayed refractory periods and the ability to sustain high-frequency action potential discharge similar to that of dorsal column axons in control rats. Pharmacological results suggest that the myelin-deficient dorsal column axons qualitatively express a normal complement of ion channels and receptors. The demonstration of a normal representation of channels and receptors on these axons supports the proposal that the oligodendrocyte, and not the axon, is the site of the primary defect in the myelin-deficient rat mutant. It is concluded that, unlike acutely demyelinated axons which display marked frequency-dependent conduction block, amyelinated axons of the myelin-deficient rat spinal cord develop compensatory mechanisms to stabilize action potential conduction.     

Myelin formation by mouse glia in myelin-deficient rats treated with cyclosporines

Summary Previous attempts to generate myelin in the myelin-deficient rat spinal cord by transplanting mouse glia were not successful. In order to determine whether this result was due to graft rejection or to interspecies mismatch of cellular or molecular components at the axoglial junction, we have repeated the experiment in cyclosporine-treated rats. Our results show that in the immunosuppressed hosts, foetal glial xenografts form an abundance of myelin within the dorsal columns at or near the injection site about two weeks after the operation. In some cases, myelination extends virtually across the entire width of the dorsal columns. Ultrastructurally, the myelin sheaths are normal in all respects, including the presence of the radial component. The lateral edges of the myelin lamellae form typical paranodal axoglial junctions, some displaying periodic transverse bands. We infer that previous mouse to rat xenograft failures reflect host immune response rather than mismatch of heterologous junctional components. We also compared foetal, early post-natal and adult xenografts. Foetal donor cells, containing an abundance of precursors but virtually no mature oligodendrocytes, are more effective than neonatal donor cells in forming myelin, and after adult grafts, we found no myelin formation. Thus, in xenografts, as in allografts, foetal precursor cells are far more suitable than glia from mature donors in generating significant amounts of myelin.     

Transplantation of oligodendrocytes and Schwann cells into the spinal cord of the myelin-deficient rat

Summary Transplantation of oligodendrocytes or Schwann cells into the spinal cord of the newborn myelin-deficient (md) rat, an X-linked myelin mutant, was carried out and the extent of myelination of CNS axons studied. Dissociated glial cell suspensions, prepared from the spinal cords of female litter-mates, were injected into the lumbar spinal cord of 15 md rats and 5 normal litter-mates. In eight of the md rats examined 12 to 21 days post-transplantation patches of myelin produced by the transplanted oligodendrocytes were found in the dorsal or ventral columns. In two rats, small patches of myelination were found in more than one site. The myelin in these patches was positive on immunocytochemical staining for proteolipid protein. These observations were interpreted as evidence of the origin of this myelin from donor oligodendrocytes, as the md rat has an abnormality in synthesis of this protein. In addition, this myelin differed in its ultrastructure from host myelin, having a normal intraperiod line. Injection of cultured Schwann cells also resulted in extensive myelination of axons in the dorsal columns by these cells.     

Spinal cord injury or spinal anesthesia eliminates seizures in myelin-deficient rats

The generalized tonic seizures that occur in myelin-deficient rats can be eliminated temporarily by spinal cord injury or spinal anesthesia. These observations imply that the seizures in this mutant can be triggered by activity in the spinal cord. The results are consistent with an earlier proposal that axons in myelin-deficient CNS fiber tracts can interact to produce abnormal excitation.     

The distribution of GAP-43 in normal rat spinal cord

Summary We have studied the distribution of the growth-associated protein GAP-43 in the spinal cord of adult rats by light and electron microscopy, using a new antiserum raised against GAP-43/-galactosidase fusion protein. We show that GAP-43 is present at all vertebral levels but is more concentrated in cervical and thoracic regions. In addition to heavy staining in the corticospinal tracts of the white matter, staining can be seen at the light microscopic level throughout the grey matter and is particularly heavy around the central canal and in the superficial dorsal horn. Electron microscopic examination revealed that GAP-43 immunostaining is confined to a subpopulation of axons and axon terminals. Staining occurs in small myelinated and unmyelinated fibres and in terminals which are mainly small and make single axodendritic or axosomatic synapses. Staining in such terminals occurs in the axoplasm but is heaviest immediately adjoining the axolema. Staining was not observed in dendrites, nor in large myelinated axons or large axon terminals. Our results indicate that GAP-43 is expressed in adult rat spinal cord in a subpopulation of small diameter fibres and axon terminals. The distribution and morphology of these terminals is consistent with several different possible origins including corticospinal projection neurons, small diameter primary afferent neurons, and descending raphe-spinal serotonin containing neurons.     

Locomotor recovery following subtotal spinal cord lesions in a rat model

Locomotor function is described over 4 weeks in adult rats recovering from mid-thoracic spinal cord lesions, sparing the left lateral and/or ventral funiculus. A composite locomotor score was developed to follow changes by grading the swing and stance phases of locomotion, hindleg struggling withdrawal, and hopping. Motor recovery was more rapid in left than right hindlegs, consistent with sparing of left supraspinal pathways. Two temporal phases of recovery were noted in some animals, perhaps arising from two different recovery mechanisms. Motor recovery in the right hindleg was similar whether a left lateral or ventral funiculus was spared.     

Role of histamine in spinal cord evoked potentials and edema following spinal cord injury: Experimental observations in the rat

Inflammation Research -     

骨髓间充质干细胞移植脊髓全横断模型大鼠运动和体感诱发电位的评价

背景：临床常用皮质运动诱发电位和皮质体感诱发电位来分别评价脊髓损伤后运动传导路和感觉传导路的损伤或修复情况。 目的：以脊髓诱导电位监测骨髓间充质干细胞移植后急性脊髓完全性损伤大鼠下肢神经功能的变化。 方法：选取健康Wistar大鼠50只,分成5组,即生理盐水组、骨髓间充质干细胞移植组、脑源性神经营养因子修饰组、神经营养素3+骨髓间充质干细胞移植组和假手术组。除假手术组外,其余各组均制作Allen’s脊髓完全性损伤动物模型,造模后各组均行相应治疗。治疗后4,8和12周行大鼠后肢运动功能评分,并于造模后24 h,3,7,14 d行运动和体感诱发电位检测。 结果与结论：运动诱发电位检测结果提示,各治疗组的运动功能均有不同程度的恢复,与生理盐水组间差异均有显著性意义(P < 0.05),大鼠后肢BBB评分也证实了各治疗组后肢运动功能明显优于生理盐水组(P < 0.05)。提示经脑源性神经营养因子修饰的骨髓间充质干细胞可移植到脊髓损伤处,可改善大鼠的后肢运动,神经营养素3蛋白有可能提高骨髓间充质干细胞在体内的生存率,促进受损脊髓的轴突再生。     

Rhythmic motor activity in thin transverse slice preparations of the fetal rat spinal cord

Networks generating locomotor-like rhythmic motor activity are formed during the last week of the fetal period in the rat spinal cord. We investigated the coordinated rhythmic motor activity induced in transverse slice preparations of the lumbar spinal cord taken from fetal rats as early as embryonic day (E) 16.5. In slices as thin as 100 microm, bath-application of 5-hydroxytryptamine (5-HT) induced rhythmic [Ca(2+)](i) elevations in motoneurons labeled with Calcium Green-1 dextran. The rhythmic [Ca(2+)](i) elevations were similar in frequency to that in the intact lumbar spinal cord, although there was no temporal correlation between the activity in the left and right sides of 100-microm slices. Such rhythmic [Ca(2+)](i) elevations were observed in the slices taken from all lumbar segments. Moreover, the rhythmic activity was abolished by simultaneous blockade of glutamate, glycine, and GABA(A) receptors, indicating that synaptic transmission mediated by these receptors is important for the generation of the rhythm in these slices. Synchronous rhythmic activity between the left-right sides was found in slices thicker than 200 microm taken from any segmental level of the lumbar spinal cord. In these preparations, commissural neurons were activated synchronously with ipsilateral motoneurons. These results indicate that the neuronal networks sufficient to generate coordinated rhythmic activity are contained in one-half of a single lumbar segment at E16.5. Such spinal cord slices are a promising experimental model to investigate the neuronal mechanisms and the development of rhythm generation in the spinal cord.     

Human fetal spinal cord xenografts survive in the eye of athymic nude rat hosts

Summary Human fetal spinal cord tissue was recovered from elective abortions and grafted to the anterior chamber of the eye of adult athymic nude rats. The transplants slowly became vascularized from the host iris during the first months. There was a clear cut stage-dependent survival and growth along a more human time-table. Fetal spinal cord tissue from embryos younger than gestational week 8 showed a much better survival and growth than tissue from older stages. Using laminin immunohistochemistry blood vessels could be visualized in the grafts. The pattern of vascularization was, however, clearly abnormal; there were fewer vessels which had abnormally thick walls as compared to those in the normal spinal cord. Similar to rat spinal cord allografts the human spinal cord xenografts displayed a relative gliosis and were surrounded by a glial layer visualized with antibodies against glial fibrillary acidic protein. Neurofilament-immunoreactive fibres were found inside the glial layer. A variety of neurons were found including large polygonal motoneuron-shaped cells, albeit with CGRP and AChE negative cell bodies. Both Substance P and enkepha-lin-immunoreactive cells and fibres were found. It is concluded that xenografted fetal human spinal cord survives, grows and may provide a useful model for experimental studies of human spinal cord development and connectivity.     

Delayed results of transplantation of fetal neurogenic tissue in patients with consequences of spinal cord trauma

We analyzed delayed effects of transplantation of nervous and hemopoietic fetal cells to patients with consequences of spinal trauma. A decrease in neurological deficit associated with pronounced improvement of functional independence was observed in 48.9% cases. The best results were observed in patients receiving cell transplantation within the first 2 years after trauma and in younger individuals. The pattern of morphological changes in the spinal cord at site of injury, severity of damage, and the method of transplantation had no appreciable effects on its delayed results.     

大鼠脊髓发育过程中神经干细胞的分化

目的:研究正常大鼠脊髓发育过程中神经干细胞的分化规律。方法:应用免疫荧光染色技术,检测Nestin、NeuN、MAP2、GFAP、CNPase阳性细胞在大鼠胚胎期及生后脊髓内的分布及变化情况。结果:胚胎发育早期,脊髓中央管、灰质、白质均可检测到Nestin阳性细胞,生后Nestin阳性细胞数量逐渐减少。大鼠脊髓神经元的发生呈现明显的背腹模式,孕14d(E14)脊髓内可检测到NeuN阳性细胞,E16 NeuN阳性细胞逐渐增多,腹侧NeuN阳性细胞核体积较大,分布较稀疏,背侧神经元细胞核体积较小,分布较密集。MAP2染色结果与NeuN一致。胶质细胞的分化、成熟在生后初期进行,P4可检测到GFAP及CNPase阳性细胞,主要分布于脊髓白质内,P30在脊髓灰质内可检测到GFAP阳性细胞,细胞分支较多且短。结论:正常大鼠脊髓发育中神经干细胞的分化呈现一定规律性,向神经元方向化较早且呈明显的背腹模式,胶质细胞的分化较晚。     

The role of inducible nitric oxide synthase following spinal cord injury in rat

Acute spinal cord injury (SCI) is two-step process that first involves the primary mechanical injury and then the secondary injury is induced by various biochemical reactions. Apoptosis is one of secondary SCI mechanisms and it is thought to play an important role for the delayed neuronal injury. The enhanced formation of nitric oxide (NO) via inducible nitric oxide synthase (iNOS) has been implicated in the pathogenesis of apoptosis in SCI. The level of .iNOS mRNA peaked at 6 hr after SCI and it declined until 72 hr after SCI in a rat model. Double-immunofluorescence staining revealed that iNOS positive cells were stained for ED-1, synaptophysin, GFAP, and oligodendrocyte marker. The terminal deoxynucleotidyl-transferase-mediated dUDP-biotin nick end-labeling (TUNEL) positive cell count was higher for the 72 hr post-SCI group than for the 24 hr post-SCI group. This cell count was also higher going in the caudal direction than in the rostral direction from the epicenter, and especially for the 72 hr group. Treatment with a selective iNOS inhibitor resulted in the reduction of TUNEL-positive cells at the lesion site. These findings suggest that nitric oxide generated by the iNOS of macrophages, neurons, oligodentrocytes, and astrocytes plays an important role for the acute secondary SCI that results from apoptotic cell death.     

Carbon filaments provide support and directionality to growing rat fetal spinal cord explants

Spinal cord explants obtained from 15 to 17-day-old fetal rats were cultured on bundles of 5-7 microns diameter carbon filaments attached to the bottom of Petri dishes. After a 3 week incubation period, the cultures were fixed and observed by light, scanning, and transmission electron microscopy. Neurites and glial processes were found to be growing both on and between the carbon filaments. The carbon filaments appeared to provide a biocompatible scaffold which promoted adhesion and gave directionality to the growing cell processes. These properties may make carbon filaments a suitable substrate for in vivo implantation into the damaged spinal cord.     

Hyperbaric oxygen therapy provides neuroprotection following spinal cord injury in a rat model

Objective: To investigate the effect of hyperbaric oxygen therapy (HBOT) on the iNOS mRNA-iNOS-NO signaling pathway and neurofunction protected in a rat spinal cord injury model. Methods: A total of 36 Sprague-Dawley rats were randomly divided into 3 groups: control group (n=12), SCI group (n=12) and SCI + HBOT group (n=12). SCI + HBOT group In the SCI group and SCI + HBOT groups, SCI was performed on rats. In the SCI + HBOT group, rats with SCI underwent HBO treatment 30 min after SCI for 24 sessions. After HBO therapy, measurement of motor evoked potential (MEP), Basso, Beattie, Bresnahan (BBB) scoring and pathological examination were done. RT-PCR and immunohistochemistry were employed to detect the mRNA and protein expression of iNOS, respectively. Diazo colorimetry was performed to detect the serum NO content. Results: The mRNA and protein expression of iNOS in the spinal cord and the serum NO content were markedly increased in the SCI group as compared to the control group (P<0.05). However, the mRNA and protein expression of iNOS and the serum NO content were dramatically reduced in the SCI + HBOT group as compared to the SCI group (P<0.05). Conclusion: HBO therapy can promote the neuroprotection following SCI, which may be related to the effect of HBO on the iNOS mRNA-iNOS-NO signaling pathway.