Effect of rotary motion on Fos protein expression in the vestibular-related nucleus population in a mouse model of rapid retinal degeneration

BACKGROUND： Previous studies on integration mechanisms of visual and vestibular information in the central nervous system have focused on the vestibular system. Due to the lack of an appropriate animal model, few studies have addressed the visual system with regard to visual and vestibular information. OBJECTIVE： To investigate Fos protein expression differences of vestibular-related nucleus populations in a mouse model of rapid retinal degeneration and normal wild-type Kunming mice following rotary motion, and to verify integration regions of visual and vestibular information in the central nervous system. DESIGN, TIME AND SETTING： A randomized, controlled in vitro study was performed at the Key Laboratory of Aerospace Medicine of Ministry of Education, China from March 2008 to February 2009. MATERIALS： A rotary stimulation device was re-fit to an electric, rotating chair produced by the School of Aerospace Medicine, the Fourth Military Medical University. METHODS： A total of 12 rapid retinal degeneration mice and 12 normal wild-type male Kunming mice were randomly assigned to experimental and control subgroups, respectively （n = 6）. Mice in the experimental group were exposed to rotary motion at a speed of 180°/s, 3 minutes per cycle, in an alternating clockwise/counterclockwise movement. Mice in the control group were not exposed to rotary motion. MAIN OUTCOME MEASURES： Differences in the number of Fos-positive neurons were determined in the vestibular nucleus, prepositus hypoglossal nucleus, inferior olive subnucleus beta, Kooy cap of the inferior olive medial nucleus, and the flocculus and paraflocculus of the cerebellum in rapid retinal degeneration mice and normal wild-type Kunming mice. RESULTS： The number of Fos-positive neurons was reduced in the prepositus hypoglossal nucleus and the Kooy cap of the inferior olive medial nucleus in the rapid retinal degeneration mice following 30 minutes of rotary motion in the experimental group, compared with the normal wild-type Kunming mice （P 〈 0.01）. There was no significant difference in Fos protein expression in the vestibular nucleus, inferior olive subnucleus beta, and the flocculus and paraflocculus of the cerebellum between the rapid retinal degeneration mice and normal wild-type Kunming mice. CONCLUSION： Visual information affected neuronal activation in the prepositus hypoglossal nucleus and the Kooy cap of the inferior olive medial nucleus in mice following rotary motion. The prepositus hypoglossal nucleus and the dorsal cap of Kooy of inferior olive medial nucleus were shown to be key integration regions of visual information and vestibular information in the central nervous system.

Xylene-induced Effects on Brain Neurotransmitters, Behavior and Fos Protein in Rats

Male Sprague-Dawley rats administered xylene intrapetitoneally on alternate days at a dose of 125 or 250mg/kg for 30 days exhibited no marked changes in locomotor activity, learning and memory capacity. However in rats given xylene on alternate day at a dose of 500 mg/kg for 30 days, a significant decrease in locomotor activity, deficits in leaming ability and memory loss were detected. These xylene-induced behavioral ehanges were assoryiated with a decrease in fyendorphin and leuenkaphlin concentrations in the pons-medulla. On the contrary, xylene at a dose of 500mg/kg increased the β-endorphin level in caudate and c-fos expression in hippocampus. These data suggest that the xylene-induced behavioral alterations might be associated with the expression of Fos protein in the hippocampus.

Effects of electrostimulation and administration of succinylcholine on the expression of Fos protein in mesencephalic periaqueductal gray matter of rats after simulated weightlessness

BACKGROUND： Expression of Fos in neurons of periaqueductal gray （PAG） is used to reflect the excitability. However, changes of expression of Fos in neurons of PAG are caused by injured electrostimulation after simulated weightlessness, and the relationship between pretreatment and injection of succinylcholine has not been determined yet. OBJECTIVE ： To investigate the changes of expression of Fos in PAG induced by injured electrostimulation pretreatment and injection of succinylcholine at 2 weeks after simulated weightlessness.DESIGN： Observational and controlled animal study.SETTING： Department of Physiology, Medical School, Xi＇an Jiaotong University; Key Laboratory of Environment and Genes Related to Diseases, Ministry of Education. MATERIALS： A total of 24 adult female SD rats, of clean grade and weighing 180-220 g, were selected in this study. METHODS： The experiment was completed in the Experimental Animal Center of Xi＇an Jiaotong University.① All rats were randomly divided into 2 groups according to body mass： simulated weightlessness group and control group with 12 in each group. And then, each group was also divided into 3 subgroups： electrostimulation group, succinylcholine-pretreatment group and succinylcholine-injection group with 4 in each subgroup. ②The model of weightlessness was simulated by tail-suspended female rats, which were described and modified by Cheng Jie. Rats in normal control group were given the same interventions as simulated weightlessness group except for tail-suspended. ③ Experimental method： The rats in electrostimulation group were given nociceptive stimulus by a pair of subcutaneous electrodes inserted into 1 and 5 claw of left hindlimb. The stimulus （current： 10 mA; duration： 1 ms; interval： 1 s） lasted for 30 minutes. The rats in succinylcholine-pretreatment group received stimulus after intravenous administration of succinylcholine, rats in succinylcholine-injection group were not given stimulus, just received succinylcholine. ④ All rats were perfused and fixed after 2 hours from the end of stimulation. The brains were removed, and serial frozen sections of midbrain were stained using immunocytochemical method, observed and taken photos under light-microscope. The number and morphological characters of Fos-immunoreactive （Fos-IR） neurons in ventrolateral part of PAG were investigated. MAIN OUTCOME MEASURES： The alterations in number and morphological characters of Fos-IR neurons in ventrolateral PAG of all rats.RESULTS： A total of 24 rats were involved in the final analysis. ① The morphological changes of Fos-IR neurons： The expressions of Fos in ventrolateral part of PAG were observed in both control and simulated weightlessness groups rats after being given nociceptive stimulus. As compared with control group, Fos-IR neurons in simulated weightlessness group were dyed lightly, cellular integrity was impaired, and cellular verge was unclear. ② The numbers of Fos-IR neurons： In control group, the numbers of Fos-IR neurons in ventrolateral part of PAG in simulated weightlessness group were obviously lower than succinylcholine-pretreatment group, but obviously higher than succinylcholine-injection group （46.94±3.38, 71.06±8.96 and 35.04±4.62, respectively, P 〈 0.05）. In 14-day simulated weightlessness group, the numbers of Fos-IR neurons in electrostimulation group were also obviously lower than succinylcholine-pretreatment group, and obviously higher than succinylcholine-injection group （27.77±3.27, 32.91±2.99 and 11.75±1.00, respectively, P 〈 0.05）. The numbers of Fos-IR neurons in all subgroups in control group were obviously higher than those subgroups in simulated weightlessness group. Compared with electrostimulation group, the percentage of expression of Fos in ventrolateral part of PAG responsed to nociceptive stimulus after administration of succinylcholine （SCH） was increased to 51.83% in control group and 18.51% in simulated weightlessness group.CONCLUSION ：① The expression of Fos in neurons in ventrolateral part of PAG were increased by the pretreatment of SCH before nociceptive stimulus.② Nociceptive stimulus could increase the expression of Fos in neurons in ventrolateral part of PAG. ③ The numbers of Fos-IR neurons in ventrolateral part of PAG were decreased obviously after 2-week simulated weightlessness.

Involvement of group Ⅲ metabotropic glutamate receptors in the modulation of spinal nociceptive signals

BACKGROUND： Previous morphological studies have demonstrated that group Ⅲ metabotropic glutamate receptors （mGluRs） are commonly found in nociceptive pathways, particularly in the terminals of primary afferent fibers in the spinal dorsal horn. OBJECTIVE： To investigate the role of group Ⅲ mGluRs in a rat model of spinal nociception by intrathecal administration of a selective agonist, L-Serine-O-phosphate （L-SOP）. DESIGN, TIME AND SETTING： A randomized, controlled, animal experiment. The study was performed at the Department of Physiology and Neurobiology, Shanxi Medical University, between March 2007 and May 2008. MATERIALS： L-SOP of group Ⅲ mGluRs （Tocris Cookson Ltd, UK）, formalin （Sigma, USA）, rabbit anti-c-Fos polyclonal antibody and biotin-labeled goat anti-rabbit IgG （Cell Signaling Technology, USA） were used in this study. METHODS： A total of 26 healthy Wistar rats, aged 1 month and weighing 100-120 g, were subjected to intrathecal catheter implantation. After 5-8 days, 10 rats were selected according to experimental requirements. L-SOP 250 nmol in 10 μL, or the equivalent volume of normal saline, was administered by intrathecal injection into the L3-5 region of the spinal cord in the experimental and control groups, respectively. After 15 minutes, formalin （5%, 50 μL） was subcutaneously injected into the plantar of the left hindpaw of each rat to establish formalin-induced pain models. MAIN OUTCOME MEASURES： Nociceptive behavioral responses and immunohistochemical examination of Fos expression. RESULTS： Intrathecal injection of L-SOP significantly attenuated the second phase nociceptive response compared with the control group （P 〈 0.05）, and Fos expression in the spinal dorsal horn was significantly decreased along with the number of Fos-like immunoreactive neurons （P 〈 0.05）. CONCLUSION： Group Ⅲ mGluRs are involved in the modulation of nociceptive signals, and their activation suppresses the transmission of nociceptive signals.