Neurofibromatosis type 1 (NF1) is a prevalent genetic disorder that affects growth properties of neural-crest-derived cell populations. In addition, approximately one-half of NF1 patients exhibit learning disabilities. To characterize NF1 function both in vitro and in vivo, we circumvent the embryonic lethality of NF1 null mouse embryos by generating a conditional mutation in the NF1 gene using Cre/loxP technology. Introduction of a Synapsin I promoter driven Cre transgenic mouse strain into the conditional NF1 background has ablated NF1 function in most differentiated neuronal populations. These mice have abnormal development of the cerebral cortex, which suggests that NF1 has an indispensable role in this aspect of CNS development. Furthermore, although they are tumor free, these mice display extensive astrogliosis in the absence of conspicuous neurodegeneration or microgliosis. These results indicate that NF1-deficient neurons are capable of inducing reactive astrogliosis via a non-cell autonomous mechanism.
Neurofibromatosis type 1 (NF1) is one of the most prevalent dominantly inherited genetic diseases of the nervous system. NF1 encodes a tumor suppressor whose functional loss results in the development of benign neurofibromas that can progress to malignancy. Neurofibromas are complex tumors composed of axonal processes, Schwann cells, fibroblasts, perineurial cells, and mast cells. Through use of a conditional (cre/lox) allele, we show that loss of NF1 in the Schwann cell lineage is sufficient to generate tumors. In addition, complete NF1-mediated tumorigenicity requires both a loss of NF1 in cells destined to become neoplastic as well as heterozygosity in non-neoplastic cells. The requirement for a permissive haploinsufficient environment to allow tumorigenesis may have therapeutic implications for NF1 and other familial cancers.
Summary
Oxysterols are cholesterol metabolites that serve multiple functions in lipid metabolism, including as liver X receptor (LXR) ligands. 27-hydroxycholesterol (27HC) is an abundant oxysterol metabolized by CYP7B1. How 27HC impacts vascular health is unknown. We show that elevations in 27HC via cyp7b1 deletion promote atherosclerosis in apoe−/− mice without altering lipid status; furthermore, estrogen-related atheroprotection is attenuated. In wild-type mice, leukocyte-endothelial cell adhesion is increased by 27HC via estrogen-receptor (ER)-dependent processes. In monocyte/macrophages 27HC upregulates proinflammatory genes and increases adhesion via ERα. In endothelial cells 27HC is also proadhesive via ERα, and in contrast to estrogen which blunts NF-κB activation, via Erk1,2- and JNK-dependent IκBα degradation 27HC stimulates NF-κB activation. Whereas 27HC administration to apoe−/− mice increases atherosclerosis, apoe−/−;erα−/− are unaffected. Thus, 27HC promotes atherosclerosis via novel proinflammatory processes mediated by ERα, and it attenuates estrogen-related atheroprotection. Strategies to lower 27HC may complement approaches targeting cholesterol to prevent vascular disease.
Neural stem cells have recently been shown to contribute to the cellular remodeling that occurs following traumatic brain injury (TBI). Potential sources for these stem cells from within the brain include the subventricular zone of the lateral ventricles and the subgranular zone of the dentate gyrus. Using intraventricular injections of the fluorescent vital dye DiO in mice, we demonstrate that the subventricular zone population of stem cells can be reliably labeled and followed over time. By following these injections with a contralateral controlled cortical injury we demonstrate that cells from the subventricular zone migrate to the most proximally injured cortical areas. Using doublelabeling immunohistochemistry with anti-nestin, anti-GFAP, and anti-NeuN antibodies we demonstrate that labeled cells from the subventricular zone contribute primarily to the astroglial scar following injury. We do not observe any contribution to deeper areas of injury including the hippocampus. These data demonstrate that the subventricular zone contributes to brain remodeling following TBI, though neural stem cell sources outside the subventricular zone appear to play reparative roles as well.
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