Project description:Fasting is increasingly recognized as a potential therapeutic intervention in the field of neurology and psychiatry. However, its impact upon the blood-brain barrier (BBB), which strictly regulates the cerebral uptake of a wide range of endogenous compounds and drugs, is unknown. In this study we used a combination of in vivo and in vitro experiments to assess the response of the brain endothelium in rats that were fed ad libitum or fasted for one to three days. Fasting did not change the expression of the main drug efflux ATP-binding cassette transporters or P-glycoprotein activity at the BBB but modulated a restrictive set of solute carrier transporters. These included the monocarboxylate transporter Mct1, which is pivotal for the cerebral uptake of ketone bodies and thus for brain adaptation to fasting. Transcriptional profiling of freshly isolated brain endothelial cells showed that Ppar d, a major lipid sensor, was selectively activated in response to fasting. In primary cultured rat brain endothelial cells, pharmacological agonists and free fatty acids selectively activated Ppar d, resulting in the upregulation of Mct1 expression at the transcriptional and protein level. This was confirmed in vivo, by showing that dosing rats with a specific Ppar d antagonist blocked the upregulation of Mct1 expression and activity induced by fasting. Altogether, our study describes for the first time a selective adaptive response of the brain vasculature to fasting and opens new perspectives for the metabolic manipulation of the BBB in the healthy or diseased brain. To further confirm that the Ppar d pathway is active brain endothelial cells, we exposed pc-CECs to GW0742 in the presence or not of GSK0660 for 48 hours and analyzed the cell lysate using non-targeted quantitative proteomics (n=3).

Project description:Fasting upregulates the monocarboxylate transporter Mct1 at the rat blood-brain barrier through Ppar δ activation

Project description:Qosa2014 - Mechanistic modeling that describes Aβ clearance across BBB Qosa2014 - Mechanistic modeling that describes Aβ clearance across BBB. Encoded non-curated model. Issues: - Confusing equation 6 - Missing initial values for spices This model is described in the article: Differences in amyloid-? clearance across mouse and human blood-brain barrier models: kinetic analysis and mechanistic modeling. Qosa H, Abuasal BS, Romero IA, Weksler B, Couraud PO, Keller JN, Kaddoumi A. Neuropharmacology 2014 Apr; 79: 668-678 Abstract: Alzheimer's disease (AD) has a characteristic hallmark of amyloid-? (A?) accumulation in the brain. This accumulation of A? has been related to its faulty cerebral clearance. Indeed, preclinical studies that used mice to investigate A? clearance showed that efflux across blood-brain barrier (BBB) and brain degradation mediate efficient A? clearance. However, the contribution of each process to A? clearance remains unclear. Moreover, it is still uncertain how species differences between mouse and human could affect A? clearance. Here, a modified form of the brain efflux index method was used to estimate the contribution of BBB and brain degradation to A? clearance from the brain of wild type mice. We estimated that 62% of intracerebrally injected (125)I-A?40 is cleared across BBB while 38% is cleared by brain degradation. Furthermore, in vitro and in silico studies were performed to compare A? clearance between mouse and human BBB models. Kinetic studies for A?40 disposition in bEnd3 and hCMEC/D3 cells, representative in vitro mouse and human BBB models, respectively, demonstrated 30-fold higher rate of (125)I-A?40 uptake and 15-fold higher rate of degradation by bEnd3 compared to hCMEC/D3 cells. Expression studies showed both cells to express different levels of P-glycoprotein and RAGE, while LRP1 levels were comparable. Finally, we established a mechanistic model, which could successfully predict cellular levels of (125)I-A?40 and the rate of each process. Established mechanistic model suggested significantly higher rates of A? uptake and degradation in bEnd3 cells as rationale for the observed differences in (125)I-A?40 disposition between mouse and human BBB models. In conclusion, current study demonstrates the important role of BBB in the clearance of A? from the brain. Moreover, it provides insight into the differences between mouse and human BBB with regards to A? clearance and offer, for the first time, a mathematical model that describes A? clearance across BBB. This model is hosted on BioModels Database and identified by: MODEL1409240002. To cite BioModels Database, please use: BioModels Database: An enhanced, curated and annotated resource for published quantitative kinetic models. To the extent possible under law, all copyright and related or neighbouring rights to this encoded model have been dedicated to the public domain worldwide. Please refer to CC0 Public Domain Dedication for more information.

Project description:Uptake of circulating succinate by brown adipose tissue (BAT) and beige fat elevates whole-body energy expenditure, counteracts obesity, and antagonizes systemic tissue inflammation in mice. The plasma membrane transporters that facilitate succinate uptake in these adipocytes remain undefined. Here we elucidate a mechanism underlying succinate import into BAT via monocarboxylate transporters (MCTs). We show that succinate transport is strongly dependent on the proportion of it present in the monocarboxylate form. MCTs facilitate monocarboxylate succinate uptake, which is promoted by alkalinization of the cytosol driven by adrenoreceptor stimulation. In brown adipocytes, we show that MCT1 primarily facilitates succinate import. In mice, we show that both acute pharmacological inhibition of MCT1 and congenital depletion of MCT1, decrease succinate uptake into BAT and consequent catabolism. In sum, we define a mechanism of succinate uptake in BAT that underlies its protective activity in mouse models of metabolic disease.

Project description:The blood-brain barrier (BBB) is an evolutionary conserved tissue interface that possesses potent chemical protection properties functioning to strictly modulate the central nervous system (CNS) microenvironment. These same properties, including tight cellular junctions and efflux transporters, also limit access of CNS-active pharmaceuticals. For this reason, understanding the molecular mechanisms that regulate BBB chemical protection is of great biomedical interest. The BBB of Drosophila consists of two surface glia layers that completely surround the brain. This tissue interface contains both “tight” cellular junctions (termed septate junctions) and drug efflux transporters; thus, the Drosophila BBB can potentially serve as a model for understanding complex regulation of BBB physiology. In this study, we show reciprocal compensatory responses following disruption of critical BBB genes: deletion of the septate junction regulator Moody causes increased drug efflux and up-regulation of the P-glycoprotein ortholog Mdr65; conversely, disruption of Mdr65 expression causes increased septate junction tightness and up-regulation of Moody. We reveal these homeostatic interactions with physiologic observations, gene expression data, and anatomical images of the BBB surface. Whole brain microarray data point to responses that are consistent with our physiologic observations and these responses are likely localized to the BBB. To our knowledge, this is the first observation of a reciprocal compensatory interaction at a tissue barrier. Furthermore, this study paves the way for future studies elucidating the direct pathways that link GPCR signaling and drug transporter regulation at the BBB. The main comparisons are between WT_new, C17 (Moody null), and PMdr65 (Mdr65 null). Since WT_new were processed on a different day than C17 and PMdr65, we also included another WT sample (WT_old) to control for genes that change depending on batch effects. Since the mutants are also in a different genetic background than WT, we also included a control that is in a similar background (UAS_control).

Project description:Endothelial cells (ECs) in cerebral vessels are considered the primary targets in acute hemorrhagic brain injuries. EC dysfunction can aggravate neuronal injuries by causing secondary inflammatory responses and blood-brain barrier (BBB) disruption. ECs comprising the BBB are known to have a higher mitochondrial volume compared with peripheral ECs. In previous study, we reported Tek-CRIF1-knockout (KO) mice, with EC-specific deletion of the mitochondrial OxPhos-related gene, Crif1, also known as Gadd45gip1 (encoding GADD45G-interacting protein 1), display profound BBB defects accompanied by reduced expression of junctional proteins in ECs. To identify signaling pathways involved in linking EC-specific mitochondrial dysfunction and BBB disruption, we first performed RNA sequencing using isolated cerebral vessels from Tek-CRIF1 mice. This transcriptome analyses of the Tek-CRIF1-KO mouse revealed significant changes in some signaling, a pathway intimately involved in BBB maintenance.

Project description:Blood-brain barrier (BBB) critically regulate the homeostasis of central nervous system (CNS). This barrier property allows cerebral vessels to meet the extremely high metabolic demand of neural activities and meanwhile protect sensitive neurons from toxic plasma components, blood immune cells and xenobiotics. Therefore, a comprehensive inventory of the molecular determinants of BBB would substantially facilitate understanding of the pathogenesis of neurological disorders involving BBB dysfunction and promote development of novel CNS drug delivery strategies. Here, we established the proteome activity landscapes of adult mouse brain, lung and liver ECs. In this study, we produced a comprehensive molecular atlas of adult mouse BBB and revealed novel insights into adult BBB in health and Alzheimer’s disease.

Project description:The blood-brain barrier (BBB) is an evolutionary conserved tissue interface that possesses potent chemical protection properties functioning to strictly modulate the central nervous system (CNS) microenvironment. These same properties, including tight cellular junctions and efflux transporters, also limit access of CNS-active pharmaceuticals. For this reason, understanding the molecular mechanisms that regulate BBB chemical protection is of great biomedical interest. The BBB of Drosophila consists of two surface glia layers that completely surround the brain. This tissue interface contains both “tight” cellular junctions (termed septate junctions) and drug efflux transporters; thus, the Drosophila BBB can potentially serve as a model for understanding complex regulation of BBB physiology. In this study, we show reciprocal compensatory responses following disruption of critical BBB genes: deletion of the septate junction regulator Moody causes increased drug efflux and up-regulation of the P-glycoprotein ortholog Mdr65; conversely, disruption of Mdr65 expression causes increased septate junction tightness and up-regulation of Moody. We reveal these homeostatic interactions with physiologic observations, gene expression data, and anatomical images of the BBB surface. Whole brain microarray data point to responses that are consistent with our physiologic observations and these responses are likely localized to the BBB. To our knowledge, this is the first observation of a reciprocal compensatory interaction at a tissue barrier. Furthermore, this study paves the way for future studies elucidating the direct pathways that link GPCR signaling and drug transporter regulation at the BBB.

Project description:The blood-brain barrier (BBB) represents a major challenge when developing central nervous system (CNS)-active therapeutics. The non-human primate (NHP)-brain endothelium constitutes an essential alternative to human in the prediction of molecule trafficking across the BBB and in the search of new brain-specific transport mechanisms. This study presents a comparison between the NHP transcriptome of freshly isolated brain microcapillaries and in vitro-selected brain endothelial cells (BECs), focusing on important BBB features – tight junctions, receptors mediating transcytosis (RMT), ABC and SLC transporters. In vitro BECs conserved most of the BBB key elements for barrier integrity and control of molecular trafficking. We also assessed the function of RMT via the Transferrin Receptor (TFRC) in the characterized NHP-BBB model, where both human transferrin and anti-hTFRC antibody showed increased apical-to-basolateral passage in comparison to control molecules. In parallel, we investigated eventual BBB-related regional differences in 7-day in vitro-selected BECs from 5 brain structures: brainstem, cerebellum, cortex, hippocampus and striatum. Our analysis retrieved very few differences in the brain endothelium from these 5 brain regions, suggesting a rather homogeneous BBB role and function across the brain parenchyma. In conclusion, the presently established NHP-derived BBB model closely mimics the physiological BBB, therefore representing a ready-to-use tool for assessment of the penetration of biotherapeutics into the human CNS.

Project description:The blood-brain barrier (BBB) is critical for neural function as it restricts effects of peripheral molecules on the brain. We report here circadian regulation of the BBB in mammals. Efflux of xenobiotics by the BBB oscillates in mice, with highest levels during the active phase and lowest during the resting phase. This oscillation is abrogated in circadian clock mutants. To elucidate the mechanisms of circadian regulation, we profiled the transcriptome of brain endothelial cells; interestingly, we detected limited circadian regulation of transcription, with no evident oscillations in efflux transporters. We recapitulated the cycling of xenobiotic efflux using a human microvascular endothelial cell line to find that the molecular clock drives the cycling of intracellular magnesium through transcriptional regulation of TRPM7, thereby accounting for the rhythm in efflux. As many drugs are substrates of efflux transporters, these findings highlight the importance of considering circadian regulation when targeting therapeutics to the CNS.