Purpose To investigate the characteristics of intraocular growth of mice embryonic stem cells (ESC) in nude mice. Methods The undifferentiated murine ESC in vitro were transplanted into the eyes of nude mice.Mophological and immunohistochemical examinations were implemented. Results Two to three days after transplantation,yellowish-white granules and masses were seen inside the anterior chamber and vitreous cavity and enlarged gradually.Morphological examination showed that there were undifferentiated cells and differentiated cells in anterior chamber and vitreous cavity.The morphology and alignment of some differentiated cells were similar to those of the retina of nude mice.The cells were highly positive in NSE staining. Conclusion The transplanted ESC could grow in the eyes of nude mice and differentiate into neurons and retina-like structure. (Chin J Ocul Fundus Dis,2000,16:213-284)
OBJECTIVE: To investigate the protective effect of tumor necrosis factor-alpha(TNF-alpha) on spinal motor neurons after peripheral nerve injury. METHODS: Twenty Wistar rats were divided into two groups, the right sciatic nerves of 20 Wistar rats were transected, the proximal stumps were inserted into a single blind silicone tube. 16 microliters of normal saline(NS) and TNF-alpha(30 U/ml) were injected into the silicone tubes. After 2 weeks, the 4th, 5th lumbar spinal cord were taken for examination. Enzyme histochemical technique and image analysis were used to show acetylcholinesterase(AChE) and nitric oxide synthase(NOS) activity of spinal motor neurons. RESULTS: The number of AChE and NOS staining neurons were 8.65 +/- 1.98 and 5.92 +/- 1.36 in the experimental group and 6.37 +/- 1.42 and 8.67 +/- 1.45 in the control group respectively, there were significant difference between the two groups(P lt; 0.01). CONCLUSION: It suggests that TNF-alpha has protective effect on motor neurons after peripheral nerve injury.
OBJECTIVE Following the delayed repair of peripheral nerve injury, the cell number of anterior horn of the spinal cord and its ultrastructural changes, motorneuron and its electrophysiological changes were investigated. METHODS In 16 rabbits the common peroneal nerves of both sides being transected one year later were divided into four groups randomly: the degeneration group and regeneration of 1, 3 and 5 months groups. Another 4 rabbits were used for control. All transected common peroneal nerves underwent epineural suture except for the degeneration group the electrophysiological examination was carried out at 1, 3 and 5 months postoperatively. Retrograde labelling of the anterior horn cells was demonstrated and the cells were observed under light and electronmicroscope. RESULTS 1. The number of labelled anterior horn cell in the spinal cord was 45% of the normal population after denervation for one year (P lt; 0.01). The number of labelled cells increased steadily from 48% to 57% and 68% of normal values at 1, 3 and 5 months following delayed nerve repair (P lt; 0.01). 2. The ultrastructure of the anterior horn cells of the recover gradually after repair. 3. With the progress of regeneration the latency become shortened, the conduction velocity was increased, the amplitude of action potential was increased. CONCLUSION Following delayed repair of injury of peripheral nerve, the morphology of anterior horn cells of spinal cord and electrophysiological display all revealed evidence of regeneration, thus the late repair of injury of peripheral nerve was valid.
In order to investigate the effect of nerve compression on neurons, the commonly used model of chronic nerve compression was produced in 48 SD rats. The rats were sacrificed in 1, 2, 3, 4, 5 and 6 months after compression, respectively. The number of neuron and ultrashruchure of alpha-motor neurons and ganglion cells of the corresponding spinal segment were examined. The results showed as following: After the sciatic nerve were crushed, the number of neuron and ultrastructure of alpha-motor neurons and ganglion cells might undergo ultrastructural changes, and even the death might occur. These changes might be aggravated as the time of crushing was prolonged and the compression force was increased. It was concluded that for nerve compression, decompression should be done as early as possible in order to avoid or minimize the ultructural changes of the neuron.
ObjectiveTo observe the morphological and functional changes of retinal degeneration in mice with CLN7 neuronal ceroid-lipofuscinosis, and the therapeutic effects of glial cell derived neurotrophic factor (GDNF) and/or ciliary neurotrophic factor (CNTF) based on neural stem cells (NSC) on mouse photoreceptor cells. MethodsA total of 100 CLN7 mice aged 14 days were randomly divided into the experimental group and the control group, with 80 and 20 mice respectively. Twenty C57BL/6J mice aged 14 days were assigned as wild-type group (WT group). Mice in control group and WT group did not receive any interventions. At 2, 4, and 6 months of age, immunohistochemical staining was conducted to examine alterations in the distribution and quantity of cones, rod-bipolar cells, and cone-bipolar cells within the retinal of mice while electroretinography (ERG) examination was utilized to record scotopic a and b-waves and photopic b-wave amplitudes. At 14 days of age, the mice in the experimental group were intravitreally injected with 2 μl of CNTF-NSC, GDNF-NSC, and a 1:1 cell mixture of CNTF-NSC and GDNF-NSC (GDNF/CNTF-NSC). Those mice were then subdivided into the CNTF-NSC group, the GDNF-NSC group, and the GDNF/CNTF-NSC group accordingly. The contralateral eyes of the mice were injected with 2 μl of control NSC without neurotrophic factor (NTF) as their own control group. At 2 and 4 months of age, the rows of photoreceptor cells in mice was observed by immunohistochemical staining while ERG was performed to record amplitudes. At 4 months of age, the differentiation of grafted NSC and the expression of NTF were observed. Statistical comparisons between the groups were performed using a two-way ANOVA. ResultsCompared with WT group, the density of cones in the peripheral region of the control group at 2, 4 and 6 months of age (F=285.10), rod-bipolar cell density in central and peripheral retina (F=823.20, 346.20), cone-bipolar cell density (F=356.30, 210.60) and the scotopic amplitude of a and b waves (F=1 911.00, 387.10) in central and peripheral retina were significantly decreased, with statistical significance (P<0.05). At the age of 4 and 6 months, the density of retinal cone cells (F=127.30) and b-wave photopic amplitude (F=51.13) in the control group were significantly decreased, and the difference was statistically significant (P<0.05). Immunofluorescence microscopy showed that the NSC transplanted in the experimental group preferentially differentiated into astrocytes, and stably expressed CNTF and GDNF at high levels. Comparison of retinal photoreceptor nucleus lines in different treatment subgroups of the experimental group at different ages: CNTF-NSC group, at 2 months of age: the whole, central and peripheral regions were significantly different (F=31.73, 75.06, 75.06; P<0.05); 4 months of age: The difference between the whole area and the peripheral region was statistically significant (F=12.27, 12.27; P<0.05). GDNF/CNTF-NSC group, 2 and 4 months of age: the whole (F=27.26, 27.26) and the peripheral area (F=16.01, 13.55) were significantly different (P<0.05). In GDNF-NSC group, there was no statistical significance at all in the whole, central and peripheral areas at different months of age (F=0.00, 0.01, 0.02; P>0.05). ConclusionsCLN7 neuronal ceroid-lipofuscinosis mice exhibit progressively increasing degenerative alterations in photoreceptor cells and bipolar cells with age growing, aligning with both morphological and functional observations. Intravitreal administration of stem cell-based CNTF as well as GDNF/CNTF show therapeutic potential in rescuing photoreceptor cells. Nevertheless, the combined application of GDNF/CNTF-NSC do not demonstrate the anticipated synergistic protective effect. GDNF has no therapeutic effect on the retinal morphology and function in CLN7 neuronal ceroid-lipofuscinosis mice.
Transcranial magnetic stimulation (TMS) as a non-invasive neuroregulatory technique has been applied in the clinical treatment of neurological and psychiatric diseases. However, the stimulation effects and neural regulatory mechanisms of TMS with different frequencies and modes are not yet clear. This article explores the effects of different frequency repetitive transcranial magnetic stimulation (rTMS) and burst transcranial magnetic stimulation (bTMS) on memory function and neuronal excitability in mice from the perspective of neuroelectrophysiology. In this experiment, 42 Kunming mice aged 8 weeks were randomly divided into pseudo stimulation group and stimulation groups. The stimulation group included rTMS stimulation groups with different frequencies (1, 5, 10 Hz), and bTMS stimulation groups with different frequencies (1, 5, 10 Hz). Among them, the stimulation group received continuous stimulation for 14 days. After the stimulation, the mice underwent new object recognition and platform jumping experiment to test their memory ability. Subsequently, brain slice patch clamp experiment was conducted to analyze the excitability of granulosa cells in the dentate gyrus (DG) of mice. The results showed that compared with the pseudo stimulation group, high-frequency (5, 10 Hz) rTMS and bTMS could improve the memory ability and neuronal excitability of mice, while low-frequency (1 Hz) rTMS and bTMS have no significant effect. For the two stimulation modes at the same frequency, their effects on memory function and neuronal excitability of mice have no significant difference. The results of this study suggest that high-frequency TMS can improve memory function in mice by increasing the excitability of hippocampal DG granule neurons. This article provides experimental and theoretical basis for the mechanism research and clinical application of TMS in improving cognitive function.
Objective To investigate the effect of olfactory ensheathing cell culture medium (OECCM) on the growth of spinal cord neurons and its protective effect on the injured neurons by H2O2, and to disscuss the probable protective mechanisms of olfactory ensheathing cells (OECs). Methods The primary olfactory ensheathing cells (OECs) were isolated from olfactory bulb of adult SD rat, and OECCM were prepared. The morphology of OECs was observed by inverted phase contrast microscope, identified by rabbit-antiratlow-affinity nerve growth factor p75 (NGFRp75), and its purity were calculated.Primary spinal cord neurons were cultured from 15 to 17 days pregnant SD rats, and injury model of neurons were prepared by H2O2. OECCM and control culture medium were added into the normal spinal neurons (groups A, B). OECCM and control culture medium were added into the injured spinal neurons by H2O2 (groups C, D). In groups A and C, 200 μL of control culture medium was used; in groups B and D, 100 μL of control culture medium and 100 μL of OECCM were used. Then the growth index such as average diameter of neuron body, the number and length of neuron axons were measured. The viabil ities of normal and injured neurons were assessed by MTT. Results OECs showed bipolar or tripolar after 6-9 days of culture. Primary spinal cord neurons were round and bigger, and neuron axons grew significantly and showed bipolar after 5-7 days of culture. The immunocytochemisty of OECs by NGFRp75 showed that membrane were stained. The degree of purity was more than 90%. Primary spinal cord neurons grew well after 6-9 days of culture, and compared with group A, neurons of group B grew b, whose cell density and diameter were bigger. The average diameter of neuron body, the number and length of neuron axons were (33.38 ± 6.80) D/μm, (1.67 ± 0.80), and (91.19 ± 62.64) L/μm in group A, and (37.39 ± 7.28) D/μm, (1.76 ± 0.82), and (121.33 ± 81.13) L/μm in group B; showing statistically significant differences (P lt; 0.05). The absorbency (A) value of neurons was 0.402 0 ± 0.586 9 in group A and 0.466 0 ± 0.479 0 in group B; showing statistically significant difference (P lt; 0.01). After 2 hours of injury by H2O2, the cell density of spinal cord neurons decreased, and neuron axons shortened. The A value of injured neurons was 0.149 0 ± 0.030 0 in group C and 0.184 0 ± 0.052 0 in group D, showing statistically significant difference (P lt; 0.01). Conclusion The results above suggest that OECCM could improve the growth of spinal cord neurons and protectthe injured neurons. The neurotrophic factors that OECs secrete play an important role in the treatment of spinal cord injury.
Epilepsy is a heterogeneous disease with a very complex etiological mechanism, characterized by recurrent and unpredictable abnormal neuronal discharge. Epilepsy patients mainly rely on oral antiseizure medication (ASMs) the for treatment and control of disease progression. However, about 30% patients are resistance to ASMs, leading to the inability to alleviate and cure seizures, which gradually evolve into refractory epilepsy. The most common type of intractable epilepsy is temporal lobe epilepsy. Therefore, in-depth exploration of the causes and molecular mechanisms of seizures is the key to find new methods for treating refractory epilepsy. Mitochondria are important organelles within cells, providing abundant energy to neurons and continuously driving their activity. Neurons rely on mitochondria for complex neurotransmitter transmission, synaptic plasticity processes, and the establishment of membrane excitability. The process by which the autophagy system degrades and metabolizes damaged mitochondria through lysosomes is called mitophagy. Mitophagy is a specific autophagic pathway that maintains cellular structure and function. Mitochondrial dysfunction can produce harmful reactive oxygen species, damage cell proteins and DNA, or trigger programmed cell death. Mitophagy helps maintain mitochondrial quality control and quantity regulation in various cell types, and is closely related to the occurrence and development of epilepsy. The imbalance of mitophagy regulation is one of the causes of abnormal neuronal discharge and epileptic seizures. Understanding its related mechanisms is crucial for the treatment and control of the progression of epilepsy in patients.
ObjectiveTo investigate the effects of the first neuron connection for the reconstruction of lower extremity function of complete spinal cord injury rats. MethodsForty adult female Sprague Dawley rats of 300-350 g in weight were selected to prepare the models of L1 transverse spinal cord injury. After 2 weeks of establishing model, the rats were randomly divided into control group (n=20) and experimental group (n=20). In the experimental group, the right hind limb function was reconstructed directly by the first neuron; in the control group, the other treatments were the same to the experimental group except that the distal tibial nerve and the proximal femoral nerve were not sutured. The recovery of motor function of lower extremity was observed by the Basso-Beattie-Bresnahan (BBB) scoring system on bilateral hind limbs at 7, 30, 50, and 70 days after operation. The changes of the spinal cord were observed by HE staining, neurofilament 200 immunohistochemistry staining, and the technique of horseradish peroxidase (HRP) tracing. ResultsAfter establishing models, 6 rats died. The right hind limb had no obvious recovery of the motor function, with the BBB score of 0 in 2 groups; the left hind limb motor function was recovered in different degrees, and there was no significant difference in BBB score between 2 groups (P>0.05). In the experimental group, HE staining showed that the spinal cord was reconstructed with the sciatic nerve, which was embedded in the spinal cord, and the sciatic nerve membrane was clearly identified, and there was no obvious atrophy in the connecting part of the spinal cord. In the experimental group, the expression of nerve fiber was stained with immunohistochemistry, and the axons of the spinal cord were positively by stained and the peripheral nerve was connected with the spinal cord. HRP labelled synapses were detected by HRP retrograde tracing in the experimental group, while there was no HRP labelled synapse in the control group. ConclusionDirect reconstruction of the first neurons is sufficient in the regeneration of corresponding neural circuit by the growth of residual axon; but the motor function recovery of the target muscles innervated by peripheral nerve is not observed.
The translation and translation regulation of RNA in eukaryotic cells have a significant impact on cellular gene expression and maintenance of proteomic homeostasis. Amyotrophic lateral sclerosis (ALS) is a progressive neurodegenerative disease that affects upper and lower motor neurons and leads to muscle weakness and atrophy. More and more studies have found RNA translation abnormalities in ALS. This article provides an overview of RNA translation and regulation in eukaryotic cells under physiological and stress conditions, and explores the relationship between four different ALS-related genes and translation abnormalities, providing new ideas for the treatment of ALS.