Project description:This SuperSeries is composed of the following subset Series:; GSE1831: Temporal analysis of P15 hippocampus in kainate-induced seizures. Koh-2K08NS002068-04; GSE1834: Temporal analysis of hippocampus in kainate-induced seizures. Koh-7K08NS002068-05-3 Experiment Overall Design: Refer to individual Series

Project description:Temporal analysis of hippocampus in kainate-induced seizures. Koh-7K08NS002068-05-3

Project description:Neuron susceptibility to seizure-induced injury. Dingledine-5R01NS031373-10-2

Project description:Neuropsychiatric consequences of poorly controlled seizures that begin in childhood can be devastating. School failure or behavioral difficulty in a child with epilepsy is common and can become the focus of concern for families. Current antiepileptic drugs compound problems with their CNS side effects; effective therapy is currently limited as little is known about the cellular and molecular changes caused by seizures in the developing brain. This study will investigate transcriptional regulation induced by early-life seizures and explore alternative nonpharmacological therapeutic strategies in reversing damages of early-life seizures. We will study the therapeutic efficacy of environmental enrichment in reducing seizure-induced neuronal injury and in modifying gene expression alterations. We will explore molecular mechanisms underlying the beneficial effects of enriched environment and examine how different genes act in concert to influence the outcome of seizure-induced damage. To test the effect of environmental enrichment in modifying KA seizure-induced alterations in gene expression. We hypothesize that environmental enrichment enhances plastic, homeostatic response of immature brain to excessive, dysregulating seizure activity and protect against maladaptive response of developing animals to seizures. After inducing seizures by systemic injection of KA (8 mg/kg) or PBS injections (control) at P20, we will randomly assign P21 male Long Evans rats to 4 groups: enrichment housing (control-enriched; SE-enriched) or to standard vivarium cages (control; SE). Sixteen animals (8 control-enriched; 8 SE-enriched) will be housed as a group in a plastic rectangular cage measuring 115cm x 80 cm containing a running wheel, tunnels, rubber balls, a maze, a mirror, and a clock with a cyclist pendulum. Control and KA will be housed individually in a standard cage. Four litters will be used for each run of experiment and the experiment will be repeated once to obtain 16 animals per group. At P30, 240 h after KA or PBS, animals will be deeply anesthetized with isoflurane, decapitated for total RNA preparation (half brain for each, n = 12 per group). Total RNA will be isolated from each hippocampus individually, and equal amounts of RNA from 4 hippocampi will be pooled for each Genechip. Three independent hybridizations will be performed per condition (total of 12 Genechip Rat Expression Set 230).

Project description:Signaling to Transcription Networks in the Neuronal Retrograde Injury Response

Project description:Summary: Spinal cord injury (SCI) is a damage to the spinal cord induced by trauma or disease resulting in a loss of mobility or feeling. SCI is characterized by a primary mechanical injury followed by a secondary injury in which several molecular events are altered in the spinal cord often resulting in loss of neuronal function. Analysis of the areas directly (spinal cord) and indirectly (raphe and sensorimotor cortex) affected by injury will help understanding mechanisms of SCI. Hypothesis: Areas of the brain primarily affected by spinal cord injury are the Raphe and the Sensorimotor cortex thus gene expression profiling these two areas might contribute understanding the mechanisms of spinal cord injury. Specific Aim: The project aims at finding significantly altered genes in the Raphe and Sensorimotor cortex following an induced moderate spinal cord injury in T9.

Project description:Evidence for a rheostat that determines neuronal survival after traumatic brain injury

Project description:Few studies have assessed the patterns of parasite populations of rodents over a longitudinal gradient in Chile. In this work, the gastrointestinal helminthic fauna of invasive rodents in Chile was examined to assess the association between their presence/absence and abundance with latitude, host sex, and host body condition, and to assess the coexistence and correlation of the abundance between parasite species. Rodents were obtained from 20 localities between 33 and 43°S. Helminths were extracted from the gastrointestinal tract and identified morphologically. Overall, 13 helminth taxa were obtained. The most frequently identified parasite species was Heterakis spumosa, and the most abundant was Syphacia muris, while Physaloptera sp. was the most widely distributed. No locality presented with a coexistence that was different from that expected by chance, while the abundance of five helminthic species correlated with the abundance of another in at least one locality, most likely due to co-infection rather than interaction. Host sex was associated with parasite presence or abundance, and female sex-biased parasitism was notably observed in all cases. Body condition and latitude presented either a positive or negative association with the presence or abundance of parasites depending on the species. It is notable that the likely native Physaloptera sp. is widely distributed among invasive rodents. Further, gravid females were found, suggesting spillback of this species to the native fauna. The low frequency and abundance of highly zoonotic hymenolepid species suggest that rodents are of low concern regarding gastrointestinal zoonotic helminths.

Project description:Transcriptomics of environmental enrichment and cocaine using quantitative next generation sequencing

Project description:Neuropsychiatric consequences of poorly controlled seizures that begin in childhood can be devastating. School failure or behavioral difficulty in a child with epilepsy is common and can become the focus of concern for families. Current antiepileptic drugs compound problems with their CNS side effects; effective therapy is currently limited as little is known about the cellular and molecular changes caused by seizures in the developing brain. This study will investigate transcriptional regulation induced by early-life seizures and explore alternative nonpharmacological therapeutic strategies in reversing damages of early-life seizures. We will study the therapeutic efficacy of environmental enrichment in reducing seizure-induced neuronal injury and in modifying gene expression alterations. We will explore molecular mechanisms underlying the beneficial effects of enriched environment and examine how different genes act in concert to influence the outcome of seizure-induced damage. To test the effect of environmental enrichment in modifying KA seizure-induced alterations in gene expression. We hypothesize that environmental enrichment enhances plastic, homeostatic response of immature brain to excessive, dysregulating seizure activity and protect against maladaptive response of developing animals to seizures. After inducing seizures by systemic injection of KA (8 mg/kg) or PBS injections (control) at P20, we will randomly assign P21 male Long Evans rats to 4 groups: enrichment housing (control-enriched; SE-enriched) or to standard vivarium cages (control; SE). Sixteen animals (8 control-enriched; 8 SE-enriched) will be housed as a group in a plastic rectangular cage measuring 115cm x 80 cm containing a running wheel, tunnels, rubber balls, a maze, a mirror, and a clock with a cyclist pendulum. Control and KA will be housed individually in a standard cage. Four litters will be used for each run of experiment and the experiment will be repeated once to obtain 16 animals per group. At P30, 240 h after KA or PBS, animals will be deeply anesthetized with isoflurane, decapitated for total RNA preparation (half brain for each, n = 12 per group). Total RNA will be isolated from each hippocampus individually, and equal amounts of RNA from 4 hippocampi will be pooled for each Genechip. Three independent hybridizations will be performed per condition (total of 12 Genechip Rat Expression Set 230). Keywords: dose response