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Premium member Presentation Transcript Blood Brain Barrier: Structure, Function and Bypass by Microorganisms: Blood Brain Barrier: Structure, Function and Bypass by Microorganisms Presented by: Syeda Kashfi QadriDiscovery : Discovery 1885: Paul Ehrlich: intravenous dyes in experimental organisms caused staining of all organs except the brain 1913: Edwin Goldmann put forward hypothesis that the cerebral capillaries provide anatomical basis for a physiological barrier between brain and the rest of the body 1950s: Electron microscopy demonstrated that the outermost layers of endothelial cells in brain capillaries are fused togetherWhat is the Blood Brain Barrier?: What is the Blood Brain Barrier? Structural and functional barrier which impedes and regulates the influx of most compounds from blood to brain Formed by brain microvascular endothelial cells (BMEC), astrocyte end feet and pericytes Essential for normal function of CNS Regulates passage of molecules in and out of brain to maintain neural environment. Responsible for metabolic activities such as the metabolism of L-dopa to regulate its concentration in the brain.Structure of Blood Brain Barrier: Structure of Blood Brain Barrier Source: Bock et alDifferences between BMEC and normal endothelial cells: Differences between BMEC and normal endothelial cells Structural differences: Absence of fenestrations More extensive tight junctions (TJ) Functional differences: Impermeable to most substances Sparse pinocytic vesicular transport Increased expression of transport and carrier proteins: receptor mediated endocytosis No gap junctions, only tight junctions Limited paracellular and transcellular transportIntegrity of BBB: Integrity of BBB Tight Junctions Adherens Junctions Pericytes Astrocyte end feetTight Junctions between BMEC: Tight Junctions between BMEC Appear at sites of apparent fusion between outer leaflets of plasma membrane of endothelial cells Continuous Anastomosing Intramenbranous strands or fibrils on P face with complementary groove on E face Protein components: Claudin Occludin Junction Adhesion Molecules Accessory proteins Source: Ballabh et alClaudin: Claudin 22kDa phosphoprotein 4 transmembrane domains localized in TJ strands Source: Ballabh et alOccludin: Occludin 65kDa phosphoprotein, 1 ° structure very different from claudin Regulatory proteins: alters paracellular permeability. Source: Ballabh et alBarrier Function of Occludin and Claudin: Barrier Function of Occludin and Claudin Assemble into heteropolymers and form intramembranous strands which contain channels allowing selective diffusion of ions and hydrophilic molecules. Breakdown of BBB in tissue surrounding brain tumors occurs with concomitant loss of 55kDa occludin expressionJunction Adhesion Molecules:: Junction Adhesion Molecules: 40kDa Integral membrane protein, single transmembrane region Belongs to immunoglobulin superfamily Localizes at tight junctions Involved in cell-to-cell adhesion and monocyte transmigration through BBB Regulates paracellular permeability and leukocyte migration Also found on circulating leukocytes, platelets and lymphoid organs.BMEC intercellular space: BMEC intercellular space Source: Ballabh et alBarrier function of JAM: Barrier function of JAM Homotypic binding between JAM molecules on adjacent endothelial cells acts as a barrier for circulating leukocytes Heterotypic binding of endothelial JAM to leukocyte JAM might guide transmigration of leukocytes across interendothelial junctions So factors that decrease leukocyte migration must either strengthen homotypic interactions or weaken heterotypic interactions.Cytoplasmic accessory proteins: Cytoplasmic accessory proteins (ZO-1, ZO-2, ZO-3, cingulin etc) These link membrane proteins to actin maintenance of structural and functional integrity of endothelium crosslink transmembrane proteins. Membrane associated guanylate kinase-like proteins (MAGUKS) subunits function as protein binding molecules role in organization the plasma membraneAdherens Junction: Adherens Junction Complex between membrane protein cadherin and intermediary proteins called catenins Cadherin-catenin complex joins to actin cytoskeleton Form adhesive contacts between cells. Assemble via homophilic interactions between extracellular domains of calcium ion dependent cadherins on surface of adjacent cellsPericytes: : Pericytes: Cells of microvessels including capillaries, venules, and arterioles that wrap around endothelial cells. Provide structural support and vasodynamic capacity to microvasculature. Role in structural stability of vessel wall Endothelial cells associated with pericytes are more resistance to apoptosis than isolated endothelial cells Indicates role of PC in structural integrity and genesis of the BBB Phagocytic activityAstrocyte end feet: Astrocyte end feet Star shaped glial cells Provides biochemical support for BMEC Influence of morphogenesis and organization of vessel wall Factors released by astrocytes involved in postnatal maturation of BBB Direct contact between endothelial cells and astrocytes necessary to generate BBB (Rubin et al, 1991) Co-regulate function by the secretion of soluble cytokines such as (LIF, leukemia inhibiting factor), Ca 2+ dependent signals by intracellular IP-3 and gap junction dependent pathways, and second messenger pathways involving extracellular diffusion of purinergic messenger.Regions of brain not enclosed by BBB: Regions of brain not enclosed by BBB Circumventricular organs area postrema, median eminence, neurohypophysis, pineal gland, subfornical organ and lamina terminalis These are regions which need to respond to factors present in systemic circulationCircumventricular organ functions: : Circumventricular organ functions: Pineal gland - secretes melatonin and is associated with circadian rhythms Subfornical organ - regulates body fluids, fluid and electrolyte imbalance Organum vasculosum of the lamina terminalis – detects peptides Choroid Plexus Area Postrema - the “vomiting centre” of the brain Median eminence - regulates the anterior pituitary through the release of neurohormones Neurohypophysis - detects levels of oxytocin and ADH in the bloodNormal BBB transport : Normal BBB transport Diffusion Facilitated transport by carrier systems Receptor mediated endocytosis Paracellular transfer more common than transcellular transferDiffusion: Diffusion Phospholipid bilayer Movement of substances down diffusion gradient Transfer of lipophilic substances alcohol, nicotine, oxygen, carbon dioxideFacilitated transport: Facilitated transport Carrier systems particular essential amino acids, glucose, these are extremely specific transport D-glucose only, large neutral amino acids which act as precursors for neurotransmitters, only which the brain cannot make, glycine: it can block the transmission of nerve signals, hence special carrier which ensures that glycine can be removed from brain Receptor mediated endocytosis Leptin, insulin, overlaps with carrier systemsFactors which cause increase in BBB during pathophysiology: Factors which cause increase in BBB during pathophysiology Factors produced by astrocytes Glutamate, Aspartate Taurine ATP Endothelin-1 NO MIP-2 Tumor necrosis factor alpha TNF-α Interleukin beta IL-β Paracrine signals secreted by endothelium cells or nerve terminals of neurons running close to blood vessels Bradykin 5HT Histamine Thrombin UTP UMP Substance P Qionolonic acid Platelet activating factor Free radicalsE. Coli model: E. Coli model Requirements for BBB translocation and successful infection High degree of bacteremia E Coli invading BMEC Rearrangements of actin cytosleleton Traversal of BBB as live bacteriaThe Consensus: The Consensus The basis for microbial host interactions contributing to bacterial invasion of human BMEC and relevant signaling mechanisms has not been fully elucidatedTransfer of microbes across BBB:: Transfer of microbes across BBB: Physical damage of BBB Ligand receptor interactions followed by host cell actin cytoskeletal rearrangements Transcellular transport while maintaining integrity of BMECPhyscial damage of BBB: Physcial damage of BBB microhemmorage or necrosis of surrounding tissue mechanical obstruction of microvessels by parasitized red blood cells (PRBC), platelets or leukocytes in cerebral malaria, overproduction of cytokines Borrelia bugdorferi : fibrinolytic system linked by activation cascade may lead to focal and transient degradation of tight junction proteins.Ligand receptor interactions followed by host cell actin cytoskeletal rearrangements: Ligand receptor interactions followed by host cell actin cytoskeletal rearrangements E.Coli binding to BMEC type I fimbriae, outer membrane protein A, Ibe proteins, cytotoxic necrotizing factor 1 (CNF 1) S. pneumoniae cell wall phosphorylcholine and BMEC platelet activating factor receptorMicrobe-specific interaction with BBB : Microbe-specific interaction with BBB Bacteria bind to BMEC, invade BMEC, induce actin cytoskeletal rearrangement, traverse BBB as live bacteria Mycobacteria unclear, although DNA microarray results show that gene expression profile of M. tuberculosis associated with human BMEC showed at least 33 genes that were 8X or more upregelated and 147 genes that were 8X or more down-regulated. Spirochetes and Fungi largely unknown, poorly understood: they are able to bind, be internalized and traverse human BMEC without obvious change in integrity of BMEC ( Borrelia burgdorferi , C neoformans , C . albicans .Conclusion: Conclusion Knowledge of the morphology and physiology of the blood brain barrier has come a long way, but there are many questions that are still unansweredReferences: References Ballabh P, Braun A, Nedergaard M. The blood-brain barrier: an overview: structure, regulation, and clinical implications. Neurobiol Dis. 2004 Jun;16(1):1-13. Review. Bock U, Haltner E. Porcine cerebral capillary endothelial cells to study blood brain barrier permeability. Across Barriers publication, May 2003, Int J Parasitol. 2006 May 1;36:541-546. Combes V, Coltel N, Faille D, Wassmer SC, Grau GE. Cerebral Malaria: role of microparticles and platelets in alterations of the blood-brain barrier Reichel A. The role of blood-brain barrier studies in the pharmaceutical industry. Curr Drug Metab. 2006 Feb;7(2):183-203. Review. Kim KS. Microbial translocation of the blood-brain barrier. Int J Parasitol. 2006 May 1;36(5):607-14. Epub 2006 Mar 6. Review. You do not have the permission to view this presentation. In order to view it, please contact the author of the presentation.
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Premium member Presentation Transcript Blood Brain Barrier: Structure, Function and Bypass by Microorganisms: Blood Brain Barrier: Structure, Function and Bypass by Microorganisms Presented by: Syeda Kashfi QadriDiscovery : Discovery 1885: Paul Ehrlich: intravenous dyes in experimental organisms caused staining of all organs except the brain 1913: Edwin Goldmann put forward hypothesis that the cerebral capillaries provide anatomical basis for a physiological barrier between brain and the rest of the body 1950s: Electron microscopy demonstrated that the outermost layers of endothelial cells in brain capillaries are fused togetherWhat is the Blood Brain Barrier?: What is the Blood Brain Barrier? Structural and functional barrier which impedes and regulates the influx of most compounds from blood to brain Formed by brain microvascular endothelial cells (BMEC), astrocyte end feet and pericytes Essential for normal function of CNS Regulates passage of molecules in and out of brain to maintain neural environment. Responsible for metabolic activities such as the metabolism of L-dopa to regulate its concentration in the brain.Structure of Blood Brain Barrier: Structure of Blood Brain Barrier Source: Bock et alDifferences between BMEC and normal endothelial cells: Differences between BMEC and normal endothelial cells Structural differences: Absence of fenestrations More extensive tight junctions (TJ) Functional differences: Impermeable to most substances Sparse pinocytic vesicular transport Increased expression of transport and carrier proteins: receptor mediated endocytosis No gap junctions, only tight junctions Limited paracellular and transcellular transportIntegrity of BBB: Integrity of BBB Tight Junctions Adherens Junctions Pericytes Astrocyte end feetTight Junctions between BMEC: Tight Junctions between BMEC Appear at sites of apparent fusion between outer leaflets of plasma membrane of endothelial cells Continuous Anastomosing Intramenbranous strands or fibrils on P face with complementary groove on E face Protein components: Claudin Occludin Junction Adhesion Molecules Accessory proteins Source: Ballabh et alClaudin: Claudin 22kDa phosphoprotein 4 transmembrane domains localized in TJ strands Source: Ballabh et alOccludin: Occludin 65kDa phosphoprotein, 1 ° structure very different from claudin Regulatory proteins: alters paracellular permeability. Source: Ballabh et alBarrier Function of Occludin and Claudin: Barrier Function of Occludin and Claudin Assemble into heteropolymers and form intramembranous strands which contain channels allowing selective diffusion of ions and hydrophilic molecules. Breakdown of BBB in tissue surrounding brain tumors occurs with concomitant loss of 55kDa occludin expressionJunction Adhesion Molecules:: Junction Adhesion Molecules: 40kDa Integral membrane protein, single transmembrane region Belongs to immunoglobulin superfamily Localizes at tight junctions Involved in cell-to-cell adhesion and monocyte transmigration through BBB Regulates paracellular permeability and leukocyte migration Also found on circulating leukocytes, platelets and lymphoid organs.BMEC intercellular space: BMEC intercellular space Source: Ballabh et alBarrier function of JAM: Barrier function of JAM Homotypic binding between JAM molecules on adjacent endothelial cells acts as a barrier for circulating leukocytes Heterotypic binding of endothelial JAM to leukocyte JAM might guide transmigration of leukocytes across interendothelial junctions So factors that decrease leukocyte migration must either strengthen homotypic interactions or weaken heterotypic interactions.Cytoplasmic accessory proteins: Cytoplasmic accessory proteins (ZO-1, ZO-2, ZO-3, cingulin etc) These link membrane proteins to actin maintenance of structural and functional integrity of endothelium crosslink transmembrane proteins. Membrane associated guanylate kinase-like proteins (MAGUKS) subunits function as protein binding molecules role in organization the plasma membraneAdherens Junction: Adherens Junction Complex between membrane protein cadherin and intermediary proteins called catenins Cadherin-catenin complex joins to actin cytoskeleton Form adhesive contacts between cells. Assemble via homophilic interactions between extracellular domains of calcium ion dependent cadherins on surface of adjacent cellsPericytes: : Pericytes: Cells of microvessels including capillaries, venules, and arterioles that wrap around endothelial cells. Provide structural support and vasodynamic capacity to microvasculature. Role in structural stability of vessel wall Endothelial cells associated with pericytes are more resistance to apoptosis than isolated endothelial cells Indicates role of PC in structural integrity and genesis of the BBB Phagocytic activityAstrocyte end feet: Astrocyte end feet Star shaped glial cells Provides biochemical support for BMEC Influence of morphogenesis and organization of vessel wall Factors released by astrocytes involved in postnatal maturation of BBB Direct contact between endothelial cells and astrocytes necessary to generate BBB (Rubin et al, 1991) Co-regulate function by the secretion of soluble cytokines such as (LIF, leukemia inhibiting factor), Ca 2+ dependent signals by intracellular IP-3 and gap junction dependent pathways, and second messenger pathways involving extracellular diffusion of purinergic messenger.Regions of brain not enclosed by BBB: Regions of brain not enclosed by BBB Circumventricular organs area postrema, median eminence, neurohypophysis, pineal gland, subfornical organ and lamina terminalis These are regions which need to respond to factors present in systemic circulationCircumventricular organ functions: : Circumventricular organ functions: Pineal gland - secretes melatonin and is associated with circadian rhythms Subfornical organ - regulates body fluids, fluid and electrolyte imbalance Organum vasculosum of the lamina terminalis – detects peptides Choroid Plexus Area Postrema - the “vomiting centre” of the brain Median eminence - regulates the anterior pituitary through the release of neurohormones Neurohypophysis - detects levels of oxytocin and ADH in the bloodNormal BBB transport : Normal BBB transport Diffusion Facilitated transport by carrier systems Receptor mediated endocytosis Paracellular transfer more common than transcellular transferDiffusion: Diffusion Phospholipid bilayer Movement of substances down diffusion gradient Transfer of lipophilic substances alcohol, nicotine, oxygen, carbon dioxideFacilitated transport: Facilitated transport Carrier systems particular essential amino acids, glucose, these are extremely specific transport D-glucose only, large neutral amino acids which act as precursors for neurotransmitters, only which the brain cannot make, glycine: it can block the transmission of nerve signals, hence special carrier which ensures that glycine can be removed from brain Receptor mediated endocytosis Leptin, insulin, overlaps with carrier systemsFactors which cause increase in BBB during pathophysiology: Factors which cause increase in BBB during pathophysiology Factors produced by astrocytes Glutamate, Aspartate Taurine ATP Endothelin-1 NO MIP-2 Tumor necrosis factor alpha TNF-α Interleukin beta IL-β Paracrine signals secreted by endothelium cells or nerve terminals of neurons running close to blood vessels Bradykin 5HT Histamine Thrombin UTP UMP Substance P Qionolonic acid Platelet activating factor Free radicalsE. Coli model: E. Coli model Requirements for BBB translocation and successful infection High degree of bacteremia E Coli invading BMEC Rearrangements of actin cytosleleton Traversal of BBB as live bacteriaThe Consensus: The Consensus The basis for microbial host interactions contributing to bacterial invasion of human BMEC and relevant signaling mechanisms has not been fully elucidatedTransfer of microbes across BBB:: Transfer of microbes across BBB: Physical damage of BBB Ligand receptor interactions followed by host cell actin cytoskeletal rearrangements Transcellular transport while maintaining integrity of BMECPhyscial damage of BBB: Physcial damage of BBB microhemmorage or necrosis of surrounding tissue mechanical obstruction of microvessels by parasitized red blood cells (PRBC), platelets or leukocytes in cerebral malaria, overproduction of cytokines Borrelia bugdorferi : fibrinolytic system linked by activation cascade may lead to focal and transient degradation of tight junction proteins.Ligand receptor interactions followed by host cell actin cytoskeletal rearrangements: Ligand receptor interactions followed by host cell actin cytoskeletal rearrangements E.Coli binding to BMEC type I fimbriae, outer membrane protein A, Ibe proteins, cytotoxic necrotizing factor 1 (CNF 1) S. pneumoniae cell wall phosphorylcholine and BMEC platelet activating factor receptorMicrobe-specific interaction with BBB : Microbe-specific interaction with BBB Bacteria bind to BMEC, invade BMEC, induce actin cytoskeletal rearrangement, traverse BBB as live bacteria Mycobacteria unclear, although DNA microarray results show that gene expression profile of M. tuberculosis associated with human BMEC showed at least 33 genes that were 8X or more upregelated and 147 genes that were 8X or more down-regulated. Spirochetes and Fungi largely unknown, poorly understood: they are able to bind, be internalized and traverse human BMEC without obvious change in integrity of BMEC ( Borrelia burgdorferi , C neoformans , C . albicans .Conclusion: Conclusion Knowledge of the morphology and physiology of the blood brain barrier has come a long way, but there are many questions that are still unansweredReferences: References Ballabh P, Braun A, Nedergaard M. The blood-brain barrier: an overview: structure, regulation, and clinical implications. Neurobiol Dis. 2004 Jun;16(1):1-13. Review. Bock U, Haltner E. Porcine cerebral capillary endothelial cells to study blood brain barrier permeability. Across Barriers publication, May 2003, Int J Parasitol. 2006 May 1;36:541-546. Combes V, Coltel N, Faille D, Wassmer SC, Grau GE. Cerebral Malaria: role of microparticles and platelets in alterations of the blood-brain barrier Reichel A. The role of blood-brain barrier studies in the pharmaceutical industry. Curr Drug Metab. 2006 Feb;7(2):183-203. Review. Kim KS. Microbial translocation of the blood-brain barrier. Int J Parasitol. 2006 May 1;36(5):607-14. Epub 2006 Mar 6. Review.