X-linked adrenoleukodystrophy (ALD) is a devastating neurologic disorder caused by mutations in the ABCD1 gene characterized by the accumulation of very long-chain fatty acids that affects 1:17,000 individuals in the U.S. Approximately 60% of male patients with ALD will convert to a devastating rapidly progressive form of inflammatory demyelination that leads to incapacitation or death within 2-3 years (cerebral ALD). Age of onset and phenotype varies even among individuals with the same mutation but a constant initial event in cerebral ALD is blood brain barrier (BBB) disruption with migration of leukocytes to the brain. The precise molecular and cellular mechanisms controlling BBB function during the course of ALD disease progress remain poorly understood given lack of cellular or animal models that faithfully recapitulate cerebral ALD. To address this critical knowledge gap, Dr. Musolino’s laboratory recently developed an ALD ex-vivo model system using gene-editing strategies and human brain microvascular endothelial cells. Dr. Musolino’s initial studies provide evidence that loss of ABCD1 directly impairs brain endothelial barrier integrity by increasing TGFβ1 levels in a manner correlated with severe transcriptional downregulation of Claudin 5 and increased permeability to small molecules. These alterations precede the accumulation of very-long chain fatty acids suggesting that the BBB dysfunction is not a direct consequence of their accumulation. As with patients, in addition to ABCD1 deficiency in this model, a second event, endothelial activation by inflammatory cytokines or flow sheer stress, is necessary to increase the permeability to leukocytes. Building upon these strong preliminary data Dr. Musolino’s hypothesizes that levels of ABCD1 expression in brain microvascular endothelium controls transcriptional regulation of tight junction proteins via TGFβ1-regulated pathways and determines the permeability to leukocytes during endothelial activation in a dose-dependent manner. To test this hypothesis Dr. Musolino will probe the effect of ABCD1 deficiency upon the BBB by (1) Identifying the molecular mechanisms governing tight junction disruption and increased permeability of ABCD1- deficient brain endothelium (Aim 1), (2) Determining functional consequences of downregulation of tight junction proteins and main regulatory pathways (Aim 2), and (3) Quantifying ABCD1 gene-dose effect on endothelial barrier function (Aim 3). Upon successful completion of these studies Dr. Musolino will have leverage the ability to model the impact of a single-gene mutation to unravel the mechanisms governing the traffic of cells across the BBB in ALD setting forth a strategy to identify the molecular and cell biological mechanisms underlying the conversion to cerebral disease, develop functional assays to test novel therapeutic approaches, and inform the field of neuroinflammation.