The neurodegeneration in colchicine induced AD rats (cAD) is mediated by cox-2 linked neuroinflammation. The importance of ROS in the inflammatory process in cAD has not been identified, which may be deciphered by blocking oxidative stress in this model by a well-known anti-oxidant vitamin C. Therefore, the present study was designed to investigate the role of vitamin C on colchicine induced oxidative stress linked neuroinflammation mediated neurodegeneration and memory impairments along with peripheral immune responses in cAD. The impairments of working and reference memory were associated with neuroinflammation and neurodegeneration in the hippocampus of cAD. Administration of vitamin C (200 and 400 mg/kg BW) in cAD resulted in recovery of memory impairments, with prevention of neurodegeneration and neuroinflammation in the hippocampus. The neuroinflammation in the hippocampus also influenced the peripheral immune responses and inflammation in the serum of cAD and all of these parameters were also recovered at 200 and 400 mg dose of vitamin C. However, cAD treated with 600 mg dose did not recover but resulted in increase of memory impairments, neurodegeneration and neuroinflammation in hippocampus along with alteration of peripheral immune responses in comparison to cAD of the present study. Therefore, the present study showed that ROS played an important role in the colchicine induced neuroinflammation linked neurodegeneration and memory impairments along with alteration of peripheral immune responses. It also appears from the results that vitamin C at lower doses showed anti-oxidant effect and at higher dose resulted in pro-oxidant effects in cAD.
Insulin-resistant brain state is proposed to be the early sign of Alzheimer's disease(AD), which can be studied in intracerebroventricular streptozotocin (ICV-STZ) rodent model. ICV-STZ is reported to induce sporadic AD with the majority of the disease hallmarks as phenotype. On the other hand, Available experimental evidence has used varying doses of STZ (<1 to 3mg/kg) and studied its effect for different study durations, ranging from 14-270 days. Though these studies suggest 3mg/kg of ICV-STZ to be the optimum dose for progressive pathogenesis, the reason for such is elusive.Here we sought to investigate the mechanism of action of 3mg/kg ICV-STZ on cognitive and non-cognitive aspects at a follow-up interval of two weeks for two months. On 60th day, we examined layer thickness, cell density, ventricular volume, spine density, protein expression related to brain metabolism and mitochondrial function by histological examination. Findings suggest progressive loss of spatial, episodic, avoidance memory with increase in anxiety in a span of two month. Furthermore, hippocampal neurodegeneration, ventricular enlargement, diffused amyloid plaque deposition, loss of spine in dentate gyrus and imbalance in energy homeostasis was found on 60th day post injection. Interestingly, AD rats showed a uniform fraction of time spent in four quadrants of water maze with change in strategy when they were exposed to height. Our findings reveal that ICV-STZ injection at a dose of 3mg/kg can cause cognitive and neuropsychiatric abnormalities due to structural loss both at neuronal as well as synaptic level, which is tightly associated with change in neuronal metabolism.
Sleep is important for cognitive and physical performance. Sleep deprivation not only affects neural functions but also results in muscular fatigue. A good night's sleep reverses these functional derangements caused by sleep deprivation. The role of sleep in brain function has been extensively studied. However, its role in neuromuscular junction or skeletal muscle morphology is sparsely addressed although skeletal muscle atonia and suspended thermoregulation during rapid eye movement sleep possibly provide a conducive environment for the muscle to rest and repair; somewhat similar to slow-wave sleep for synaptic downscaling. In the present study, we have investigated the effect of 24 h sleep deprivation on the neuromuscular junction morphology and neurochemistry using electron microscopy and immunohistochemistry in the rat soleus muscle. Acute sleep deprivation altered synaptic ultra-structure viz. mitochondria, synaptic vesicle, synaptic proteins, basal lamina, and junctional folds needed for neuromuscular transmission. Further acute sleep deprivation showed the depletion of the neurotransmitter acetylcholine and the overactivity of its degrading enzyme acetylcholine esterase at the neuromuscular junction. The impact of sleep deprivation on synaptic homeostasis in the brain has been extensively reported recently. The present evidence from our studies shows new information on the role of sleep on neuromuscular junction homeostasis and its functioning.
Sleep is important for cognitive and physical performance. Sleep deprivation not only affects neural functions but also results in muscular fatigue. A good night's sleep reverses these functional derangements caused by sleep deprivation. The role of sleep in brain function has been extensively studied. However, its role in neuromuscular junction or skeletal muscle morphology is sparsely addressed although skeletal muscle atonia and suspended thermoregulation during rapid eye movement sleep possibly provides a conducive environment for the muscle to rest and repair; somewhat similar to slow-wave sleep for synaptic downscaling. In the present study, we have investigated the effect of 24 h sleep deprivation on the neuromuscular junction morphology and neurochemistry using electron microscopy and immunohistochemistry in the rat soleus muscle. Acute sleep deprivation altered synaptic ultra-structure viz. mitochondria, synaptic vesicle, synaptic proteins, basal lamina, and junctional folds needed for neuromuscular transmission. Further acute sleep deprivation showed the depletion of the neurotransmitter acetylcholine and the overactivity of its degrading enzyme acetylcholine esterase at the neuromuscular junction. The impact of sleep deprivation on synaptic homeostasis in the brain has been extensively reported recently. The present evidence from our studies shows new information on the role of sleep on neuromuscular junction homeostasis and its functioning.
Gliosis and dendritic loss is reported to be secondary to the amyloid beta (Aß) and hyperphosphorylated tau (hp‐tau) production in Alzheimer’s disease(AD) brain. STZ administration is reported to induce sporadic AD. Previous clinical or preclinical studies on effect of rTMS treatment in AD patients or APP23 mice showed cognitive improvement alone or as adjuvant therapy along‐with amelioration of the glial aggravation in the hippocampus. However, studies on the effect of magnetic field stimulation on the gliosis related dendritic trimming in animal models of sporadic AD is elusive. Therefore, in the present study we have looked in to the effect of extremely low frequency magnetic field stimulation (ELF‐MF; 17.96µT, 50Hz, 2hr/day) for one month post‐injection of STZ (bilateral, 3mg/kg). Total 45 animals were (ethical no. 937/IAEC/2016) randomly divided into five groups: Control, Sham, AD, Sham+MF and AD+MF. After assessing retention of spatial and avoidance memory using Morris water maze and passive avoidance step down test on 30th day, animals were sacrificed and tissues processed for oxidative stress and immunofluorescence, Golgi‐Cox staining. Behavioural analysis revealed spatial memory improvement with no effect on the avoidance memory loss in AD+MF group as compared to AD group. We also found significant decrease in superoxide dismutase, catalase, GSH and increase in malon‐di‐aldehyde (MDA) in AD group. ELF‐MF treatment only reduced MDA level in hippocampus and frontal cortex. GFAP, IBA‐1 and hp‐tau (ser356) positive cells were found to be reduced in AD+MF group, as compared to all groups except Control. Sholl analysis revealed partial improvement of reduction in the number of intersection, bifurcation and length in basal and apical dendrite in the AD group after ELF‐MF treatment in CA3 layer. These findings suggests dual role of ELF‐MF exposure on STZ model of AD showing improvement of spatial memory by reducing the gliosis induced dendritic loss. However, inability to manage oxidative stress due to STZ, which may lead to avoidance memory deficit even after exposure period of one month.
Violent behavior is an aberrant form of aggression that has detrimental impact on health and society. Early life trauma triggers adulthood violence and criminality, though molecular mechanisms remain elusive. Here, we provide brain region specific transcriptome profiles of peripubertal stress (PPS) exposed adult violent male and resilient female mice. We identify transthyretin (TTR) as a key regulator of PPS induced violent behavior and its intergenerational inheritance. TTR mediated long-term perturbation in hypothalamic thyroid hormone (TH) availability contributed to male violent behavior without affecting circulating hormone. Ttr gene ablation in hypothalamus impaired local TH signaling including levels of TH transporters (Mct8, Oatp1c1), deiodinase 2 (DIO2) and TH responsive genes (Nrgn, Trh and Hr). Violent behavior and impaired TTR-TH signaling was also inherited in F1 male progenies. Further, we deciphered Ttr promoter hyper methylation in hypothalamus of violent males across generations. Our findings reveal that trauma during puberty trigger lasting violent behavior by epigenetic programming of TTR and consequent impaired local thyroid availability in brain. TTR-TH signaling in hypothalamus can serve as potential target in reversal of violent behavior.
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