Project description:Hypoxic-ischemic (HI) injury in the developing brain is a common cause of disability in children, and there are no effective treatments at this time. Erythropoietin (EPO) has recently gained interest as a neuroprotective drug, and EPO and its receptor are expressed within the central nervous system. We have recently shown that pretreatment with EPO markedly reduced brain injury caused by unilateral hypoxic-ischemic insult in 7 day old mice. EPO did not reduce early signs of neuronal injury at 6 hours, but significantly protected the neonatal brain when assessed 24 hours and 7 days after HI. The mechanism of this delayed protection is unclear, but is thought to involve transcription of neuroprotective genes, possibly subsequent to activation of NFkB. By comparing gene expression in EPO- and vehicle- (VEH) treated mice after HI, we should gain insight into the mechanisms underlying the neuroprotective effects of EPO and may identify additional targets for therapeutic interventions. We will compare gene expression patterns in 7-day old mouse forebrain after 1) VEH pretreatment plus sham surgery, 2) VEH pretreatment plus HI, and 3) EPO pretreatment plus HI. We will thus identify genes induced by HI in the developing brain and characterize changes in gene expression caused by EPO pretreatment. We will use the model of neonatal hypoxic-ischemic injury and EPO treatment parameters that were used in our prior studies demonstrating neuroprotection. Based on the time-course of neuroprotection defined in our prior study and the pharmacokinetic profile of EPO, we will examine gene expression 18 hours after HI. We hypothesize that changes in gene expression after EPO pretreatment underlie the neuroprotective effects of this cytokine after neonatal hypoxic ischemic injury. We will examine gene expression in 3 groups: 1) 1) VEH pretreatment + sham surgery, 2) VEH pretreatment + HI, and 3) EPO pretreatment + HI. EPO (5U/g, i.p.) or VEH was injected in 7 day old mice, drawn from 4 litters, with 3 to 4 pups per treatment group in each litter. One hour later, the right common carotid artery was ligated under isoflurane anesthesia, animals were allowed to recover for 90 min and were then placed in hypoxic chambers (10% oxygen, balance nitrogen) for 50 min. The animals subjected to sham surgery received isoflurane anesthesia for a comparable period, incision and dissection to visualize the common carotid artery, but no ligation and no hypoxia. Eighteen hrs later, animals were anesthetized with isoflurane and the right hemisphere was rapidly dissected and placed in RNA Later (Qiagen) at 4C. Total RNA was isolated using an RNeasy lipid tissue mini kit (QIAzol lysis and RNeasy purification, Qiagen). RNA concentrations were determined spectrophotometrically and an aliquot of each sample was examined by gel electrophoresis to screen for degradation. Samples were stored at -80C. After quality control screening, we selected 5 male and 5 female samples per treatment group (extra samples were reserved). We plan to pool 1 male and 1 female for each microarray sample and we plan to run 5 microarrays from each treatment group, for a total of 15 microarrays. We would like to have Agilent Bioanalyzer quality control assays on the individual samples carried out by the consortium before pooling. We will send 10 micrograms of each sample for Agilent QC and subsequent pooling of equimolar amounts. We would like to use Affymetrix mouse gene chips (please advise which specific chips are available; are you using the GeneChip Mouse Expression array 430A or the GeneChip Mouse Genome 430 2.0 Array?).

Project description:Hypoxic-ischemic (HI) injury in the developing brain is a common cause of disability in children, and there are no effective treatments at this time. Erythropoietin (EPO) has recently gained interest as a neuroprotective drug, and EPO and its receptor are expressed within the central nervous system. We have recently shown that pretreatment with EPO markedly reduced brain injury caused by unilateral hypoxic-ischemic insult in 7 day old mice. EPO did not reduce early signs of neuronal injury at 6 hours, but significantly protected the neonatal brain when assessed 24 hours and 7 days after HI. The mechanism of this delayed protection is unclear, but is thought to involve transcription of neuroprotective genes, possibly subsequent to activation of NFkB. By comparing gene expression in EPO- and vehicle- (VEH) treated mice after HI, we should gain insight into the mechanisms underlying the neuroprotective effects of EPO and may identify additional targets for therapeutic interventions. We will compare gene expression patterns in 7-day old mouse forebrain after 1) VEH pretreatment plus sham surgery, 2) VEH pretreatment plus HI, and 3) EPO pretreatment plus HI. We will thus identify genes induced by HI in the developing brain and characterize changes in gene expression caused by EPO pretreatment. We will use the model of neonatal hypoxic-ischemic injury and EPO treatment parameters that were used in our prior studies demonstrating neuroprotection. Based on the time-course of neuroprotection defined in our prior study and the pharmacokinetic profile of EPO, we will examine gene expression 18 hours after HI. We hypothesize that changes in gene expression after EPO pretreatment underlie the neuroprotective effects of this cytokine after neonatal hypoxic ischemic injury. We will examine gene expression in 3 groups: 1) 1) VEH pretreatment + sham surgery, 2) VEH pretreatment + HI, and 3) EPO pretreatment + HI. EPO (5U/g, i.p.) or VEH was injected in 7 day old mice, drawn from 4 litters, with 3 to 4 pups per treatment group in each litter. One hour later, the right common carotid artery was ligated under isoflurane anesthesia, animals were allowed to recover for 90 min and were then placed in hypoxic chambers (10% oxygen, balance nitrogen) for 50 min. The animals subjected to sham surgery received isoflurane anesthesia for a comparable period, incision and dissection to visualize the common carotid artery, but no ligation and no hypoxia. Eighteen hrs later, animals were anesthetized with isoflurane and the right hemisphere was rapidly dissected and placed in RNA Later (Qiagen) at 4C. Total RNA was isolated using an RNeasy lipid tissue mini kit (QIAzol lysis and RNeasy purification, Qiagen). RNA concentrations were determined spectrophotometrically and an aliquot of each sample was examined by gel electrophoresis to screen for degradation. Samples were stored at -80C. After quality control screening, we selected 5 male and 5 female samples per treatment group (extra samples were reserved). We plan to pool 1 male and 1 female for each microarray sample and we plan to run 5 microarrays from each treatment group, for a total of 15 microarrays. We would like to have Agilent Bioanalyzer quality control assays on the individual samples carried out by the consortium before pooling. We will send 10 micrograms of each sample for Agilent QC and subsequent pooling of equimolar amounts. We would like to use Affymetrix mouse gene chips (please advise which specific chips are available; are you using the GeneChip Mouse Expression array 430A or the GeneChip Mouse Genome 430 2.0 Array?). Keywords: dose response

Project description:Hypoxic ischemic encephalopathy (HIE) is a primary cause of neonatal death and disabilities resulting from perinatal hypoxia. The progression of HI injury is closely associated with neuroinflammation. Therefore, suppressing inflammatory pathways is a promising therapeutic strategy for treating HIE. Echinatin (Ech) is a principal active component of glycyrrhiza, with anti-inflammatory and anti-oxidative effects, often combined with other herbs to exert effects of clearing heat and detoxifying. This study aimed to investigate the anti-inflammatory and neuroprotective effects of Ech on neonatal rats with hypoxic-ischemic brain damage and on PC12 cells induced by oxygen-glucose deprivation (OGD).

Project description:Background: Neonatal hypoxic-ischemic (HI) brain injury, is one of the leading causes of mortality and long-term neurological morbidity in newborns. Current treatment options for HI brain injury are very limited, but mesenchymal stem cell (MSC) therapy is a promising strategy to boost neuroregeneration after injury. Optimization strategies to further enhance the potential of MSCs are in development. In the current study we aimed to test the potency of hypoxic preconditioning (HP) to enhance the therapeutic efficacy of MSCs in a mouse model for neonatal HI injury. Methods: HI was induced on postnatal day 9 in C57Bl/6 mouse pups. MSCs were cultured at 1% oxygen levels for 24 hours prior to use (HP-MSCs) or under normoxic (21% O2) control conditions (NP-MSCs). At 10 days after induction of HI brain injury, HP-MSCs or NP-MSCs were intranasally administered. Lesion size, sensorimotor outcome, MSC migration and neuroinflammation were assessed by HE staining, cylinder rearing task, gold nanoparticle-labeled MSC tracing and IBA1 staining, respectively. In vitro, the effect of hypoxic preconditioning on MSC migration, potency and proteome profile was studied using assays for transwell-migration, neural stem cell differentiation and neuroinflammation, and LC-MS/MS, respectively. Results: HP-MSCs were superior to NP-MSCs in reducing lesion size and improving sensorimotor outcome after HI. Moreover, hypoxic preconditioning enhanced MSC migration specifically to the HI lesion after intranasal application and in vitro. Additionally, HP-MSCs enhanced neural stem cell (NSC) differentiation into more complex neurons in vitro but did not enhance anti-inflammatory effects compared to NP-MSCs. Lastly, hypoxic preconditioning enriched the expression of pathways mainly related to glucose metabolism and extracellular matrix remodeling in MSCs. Conclusions: Overall, this study showed for the first time that intranasal HP-MSC therapy is a promising optimization strategy to superiorly reduce lesion size and improve neurodevelopmental outcome in a mouse model of neonatal HI brain injury.

Project description:Novel Neuroprotective Treatment Option for Neonatal Hypoxic Ischemic Brain Injury

Project description:Hypoxic-ischemic (HI) injury in the developing brain is a common cause of disability in children, and there are no effective treatments at this time. Exposure to sublethal hypoxic conditions (hypoxic preconditioning) 24 hours prior to hypoxic-ischemic insult is protective in the developing rat model. We have observed protective effects on brain histopathology and on long-term sensory-motor behavioral tasks. Changes in gene expression are thought to underlie this protective effect. By comparing gene expression in rats subjected to hypoxic preconditioning or sham conditioning at several time points from 0 to 24 hrs after preconditioning, we should gain insight into the mechanisms underlying these neuroprotective effects and may identify targets for therapeutic intervention. The aim of this study is to determine the effect of hypoxic preconditioning on global gene expression, and, in littermates, to examine the effect of hypoxic preconditioning 24 h prior to hypoxic-ischemic insult on brain histopathology. We hypothesize that changes in gene expression underlie the protective effect of hypoxic preconditioning against subsequent hypoxic-ischemic insult. Gene expression will be examined in two groups, 1) preconditioned and 2) sham controls, at 4 time points. On postnatal day 6, preconditioned animals are exposed to normothermic hypoxia for 3 hrs (8.0% oxygen, 36 degrees C), and sham animals are simultaneouosly exposed to normoxia at 36 degrees C. Animals are then returned to their dams until euthanized at 4 time points (0h, 2h, 8h, and 24h later). Five brains/group/timepoint will be used, with an equal number of males and females in each group. Brains are removed and dissected on ice. Cerebral cortex is dissected from both hemispheres and rapidly frozen on dry ice. Total RNA is isolated using the QIAGEN RNeasy Protect Maxi Kit. Littermates of these animals will be exposed to hypoxic preconditioning or sham preconditioning and subjected to hypoxic-ischemic injury 24 h later. These animals are euthanized at postnatal day 14 for histopathologic evaluation of injury.

Project description:Integrating stem cell therapies into clinical settings faces several challenges, particularly in achieving the high cell yields necessary for attaining therapeutic doses. Preconditioning with hypoxic conditions has shown promise in enhancing the mesenchymal stem cells (MSCs)’ reparative capabilities of the central nervous system. Recent evidence suggests that oxygen concentration and exposure duration can shape MSCs’ phenotypes, supporting the need for further optimization of this strategy in a way to achieve maximal repair. Methods: Wistar Han rat pups from both sexes underwent hypoxic-ischemic (HIE) brain injury at postnatal day 10 using the Rice-Vannucci model and were treated with umbilical cord derived-MSCs (UC-MSCs) preconditioned with prolonged mild hypoxia (MH; 5% oxygen for 48 hours) or short severe hypoxia (SSH; 0.1% oxygen for 24 hours) two days later. Results: Our results show that UC-MSCs’ were able to alleviate motor and cognitive deficits caused by the HI brain lesion. To investigate the molecular effects of hypoxia-preconditioned MSCs in the neonatal brain post-HIE, we employed untargeted proteomics on ipsilesional brain samples from control, HIE, HIE treated with naïve UC-MSCs, and HIE treated with SSH-preconditioned UC-MSCs groups, 30 days after lesion induction. This approach identified protein signatures related to injury and therapeutic intervention. Pathway enrichment analysis further revealed that administration of UC-MSCs preconditioned with short severe hypoxia significantly impacted neural signaling, protein synthesis, and energy metabolism pathways, pointing to long-term mechanisms that may support neuronal repair. Conclusion: These findings enhance our understanding of hypoxia-preconditioning in MSCs therapy in driving a positive therapeutic response, supporting the development of more effective and feasible treatments for neonatal hypoxic-ischemic brain injury.

Project description:We report the miRNA-Seq and Nanostring mRNA data from regional brain samples after neonatal hypoxic-ischemic brain injury (induced by unilateral carotid artery ligation and 30 minutes at 8% oxygen in CD1 mice at postnatal day 9). Analyses are perfomed in the cerebellum, striatum/thalamus, and whole cortex. Examination of regional small RNA expression between four postnatal day 9 mouse pups after hypoxic-ischemic brain injury versus four sham surgery controls

Project description:Hypoxic-ischemic (HI) injury in the developing brain is a common cause of disability in children, and there are no effective treatments at this time. Exposure to sublethal hypoxic conditions (hypoxic preconditioning) 24 hours prior to hypoxic-ischemic insult is protective in the developing rat model. We have observed protective effects on brain histopathology and on long-term sensory-motor behavioral tasks. Changes in gene expression are thought to underlie this protective effect. By comparing gene expression in rats subjected to hypoxic preconditioning or sham conditioning at several time points from 0 to 24 hrs after preconditioning, we should gain insight into the mechanisms underlying these neuroprotective effects and may identify targets for therapeutic intervention. The aim of this study is to determine the effect of hypoxic preconditioning on global gene expression, and, in littermates, to examine the effect of hypoxic preconditioning 24 h prior to hypoxic-ischemic insult on brain histopathology. We hypothesize that changes in gene expression underlie the protective effect of hypoxic preconditioning against subsequent hypoxic-ischemic insult. Gene expression will be examined in two groups, 1) preconditioned and 2) sham controls, at 4 time points. On postnatal day 6, preconditioned animals are exposed to normothermic hypoxia for 3 hrs (8.0% oxygen, 36 degrees C), and sham animals are simultaneouosly exposed to normoxia at 36 degrees C. Animals are then returned to their dams until euthanized at 4 time points (0h, 2h, 8h, and 24h later). Five brains/group/timepoint will be used, with an equal number of males and females in each group. Brains are removed and dissected on ice. Cerebral cortex is dissected from both hemispheres and rapidly frozen on dry ice. Total RNA is isolated using the QIAGEN RNeasy Protect Maxi Kit. Littermates of these animals will be exposed to hypoxic preconditioning or sham preconditioning and subjected to hypoxic-ischemic injury 24 h later. These animals are euthanized at postnatal day 14 for histopathologic evaluation of injury. Keywords: time-course

Project description:Neonatal hypoxic-ischemic (HI) encephalopathy can lead to severe brain damage and is a common cause of neurological handicaps in adulthood. To elucidate the molecular events occurring in cerebral cortices of mature rats (8 weeks old) after neonatal HI brain insult, we performed comprehensive gene expression and gene network analyses using a DNA microarray system (Agilent 4x44K). A rat model of neonatal HI encephalopathy (Rice model) was obtained by unilateral ligation of the common carotid artery of 7-day-old rats with hypoxia (exposure to 8% oxygen). Due to the HI insult-related breakdown of the ipsilateral hemisphere in the brain, RNAs were prepared from the contralateral cerebral cortices of 8-week-old rats and analyzed by DNA microarray. Biofunctional analysis of differentially regulated genes revealed that many upregulated genes were related to cell death signaling, such as the arachidonic acid cascade. In contrast, many downregulated genes were related to gene expression, reflecting progressive damage by the HI insult, even within the contralateral cerebral hemisphere. Seven-day-old Wistar rats were assigned to two groups: the control group and the Rice group (four pups in each group). HI brain insult was not induced in the control group rats. The Rice group rats were subjected to a modified LevineM-bM-^@M-^Ys procedure to induce HI brain injury. The Rice group rats were anesthetized with ether, and the left carotid artery was sectioned between double ligatures with 4-0 surgical silk. The rats were allowed to recover for 1M-bM-^@M-^S2 h and then exposed to 1 h of hypoxia in a plastic chamber that was perfused with a mixture of humidified 8% oxygen balanced with nitrogen. The temperature inside the chamber was maintained at 33 M-BM-0C, the usual temperature generated when pups huddle with the mother. The cerebral cortexes contralateral to the HI brain insult and those of the same side of the control animals were used for the experiment.