Project description:A subset of infants and adults with hemorrhagic stroke and intraventricular hemorrhage (IVH) ultimately develop a life-threatening accumulation of cerebrospinal fluid (CSF), termed post-hemorrhagic hydrocephalus (PHH). An incomplete understanding of this variably progressive condition has hampered the development of new therapies beyond serial neurosurgical interventions. We describe an adeno-associated viral (AAV) gene augmentation approach leveraging the Na-K-Cl cotransporter, NKCC1, to enhance a choroid plexus (ChP) mechanism of CSF surveillance, potassium homeostasis, and water movement to drive decreases in ventricle size in embryonic, neonatal, and adult mouse models of IVH. Intraventricular blood led to increased CSF [K+], triggered cytosolic calcium in ChP epithelial cells, and was followed by NKCC1 activation. ChP-targeted AAV-NKCC1 rapidly reversed blood-induced ventriculomegaly and led to persistently increased CSF clearance capacity, validating the model and treating the most salient clinical features of PHH. NKCC1 is a bi-directional cotransporter, and these data demonstrate that NKCC1 activation triggered a trans-choroidal, NKCC1-dependent CSF ion/water clearance out of the ventricle. Inactive, phosphodeficient AAV-NKCC1-NT51 failed to mitigate ventriculomegaly, indicating that the beneficial effects of NKCC1 augmentation required both elevated CSF [K+] and upstream activation via phosphorylation. Excessive CSF [K+] fluctuations correlated with permanent shunting outcome in humans following hemorrhagic stroke, suggesting potential therapeutic benefits. Collectively, these data highlight a novel role for the ChP in rapid compensation for alterations in CSF homeostasis following IVH and demonstrate the utility of targeted gene therapy to mitigate intracranial fluid accumulation following hemorrhage.

Project description:Intraventricular hemorrhage (IVH) remains a major neurological complication of prematurity that results in cerebral palsy, hydrocephalus, and cognitive deficits. No effective therapy exists to prevent these disorders in infants with IVH. IVH triggers inflammation, cellular infiltration and white matter injury following neurobehavioural deficits.

Project description:Intraventricular hemorrhage (IVH) remains a major neurological complication of prematurity that results in cerebral palsy, hydrocephalus, and cognitive deficits. No effective therapy exists to prevent these disorders in infants with IVH. IVH triggers inflammation, cellular infiltration and white matter injury following neurobehavioural deficits.

Project description:Overexpression of VEGF (vascular endothelial growth factor) in the germinal matrix of the brain causes GMH-IVH-like anomalies (Germinal matrix hemorrhage [GMH]; intraventricular hemorrhage [IVH]). This dataset provides the list of differentially expressed genes in the brain cortices of embryos with transgene directed overexpression of VEGF. Eight samples were analyzed, including four control and four with induced over expression of VEGF. A simple unpaired T-test was used for analysis, with GeneSpring software,

Project description:Overexpression of VEGF (vascular endothelial growth factor) in the germinal matrix of the brain causes GMH-IVH-like anomalies (Germinal matrix hemorrhage [GMH]; intraventricular hemorrhage [IVH]). This dataset provides the list of differentially expressed genes in the brain cortices of embryos with transgene directed overexpression of VEGF.

Project description:Fetal spina bifida can associate with reduced fetal growth. However, little is known about placental development and function in pregnancies with fetal spina bifida, despite that the placenta is a critical regulator of fetal growth. We used data from a case-control study to determine how the placental transcriptome differs in fetuses with isolated spina bifida (cases), compared to fetuses without any congenital anomalies (controls).

Project description:Neural tube closure in vertebrates is achieved through a highly dynamic and coordinated series of morphogenic events involving neural plate, surface ectoderm, and neural plate border. Failure of this process in the caudal region causes spina bifida. Grainyhead-like 3 (GRHL3) is an indispensable transcription factor for neural tube closure as constitutive inactivation of which leads to fully penetrant spina bifida. Here, through single-cell transcriptomics we show that at E8.5, the time-point preceding mouse neural tube closure, the co-expression of Grhl3, Tfap2a, and Tfap2c defines a previously unrecognised progenitor population of surface ectoderm. Specific deletion of Grhl3 expression using Tfap2a-Cre recapitulate the spina bifida observed in Grhl3-null animals. Moreover, conditional inactivation of Tfap2c expression in Grhl3-expressing neural plate border cells also causes mild spina bifida. These findings clearly indicate that Grhl3-expressing neural plate border cells cohort is required for the early-stage neurulation.

Project description:Intraventricular haemorrhage (IVH) is one of the common complications after various acute brain injuries, leading to severe mortality and mobility, with great burdens on economics and society. Recently, a CLEAR III trial (NCT00784134) employing alteplase effectively cleared intraventricular haematoma but did not demonstrate adequate neuro behavioural benefits for patients. Therefore, the present study sought to investigate the pathophysiology of how these haematoma stimulations in ventricles cause neurological dysfunction. An autologous blood stereotactic injection model was employed to establish and mimic secondary IVH in mice, followed by our innovated spatial transcriptome sequencing-based bioinformatic algorithm to investigate the 3D spatial brain regions affected by the primary stimulation of haematoma in the ipsilateral ventricle after IVH, as well as related cell-cell communication strength and pathway analysis. These data illustrate that the three main 3D global pseudospace-time trajectory bundles represent the main neural circuits from the lateral ventricle to the hippocampus and primary cortex induced by experimental intraventricular haematoma stimulation. Further analysis indicated a rapid response in the primary cortex, as well as a direct and integrated effect on the hippocampus after IVH. To the best of our knowledge, this is the first study to interrogate secondary brain injury after IVH by using spatial transcriptome sequencing and bioinformatics analysis. These data could provide more helpful information on the pathophysiological mechanism of IVH in patients after acute brain injury, as well as for the bioinformatics analysis strategies for similar studies in the future.

Project description:Epigenome analysis for spina bifida

Project description:Spina Bifida Aperta in Rats