星形胶质细胞可以诱导内皮细胞系紧密连接的形成

为探索星形胶质细胞在血脑屏障内皮细胞紧密连接形成中的重要意义,通过内皮细胞系ECV304与星形胶质细胞体外接触共培养的方法,采用电镜及内皮细胞紧密连接的银染观察星形胶质细胞对内皮细胞系紧密连接的诱导作用。运用Millipore-ERS系统检测紧密连接的功能状况。结果发现,星形胶质细胞可以诱导内皮细胞系形成广泛而连续的紧密连接并产生较高的跨内皮阻抗(transendothelial electrical resistance,TER),于第10d可达321．3Ωcm^2。提示,星形胶质细胞可以诱导ECV304细胞产生紧密连接。同时,ECV304细胞与星形胶质细胞的体外共培养可以作为研究血脑屏障紧密连接结构与功能的一种可靠而简便的体外实验方法。     

A new angle on blood–CNS interfaces: A role for connexins?

Neuronal signaling in the CNS depends on the microenvironment around synapses and axons. To prevent fluctuations in blood composition affecting the interstitial fluid and CSF, two barriers, the blood–brain barrier (BBB) and blood–CSF barrier (BCSFB), are interposed between the blood and the brain/CSF compartment. Brain capillary endothelial cells (ECs) constitute the BBB whereas choroid plexus epithelial (CPE) cells form the BCSFB. The anatomical basis of these barriers is located at the level of an intercellular junctional complex that impedes paracellular diffusion. Tight and adherens junctions are known as the principal constituents of this junctional complex. Transmembrane connexins (Cxs) are the prime building blocks of plasma membrane hemichannels that combine to form intercellular gap junctions (GJ). Although Cxs co-exist within the junctional complex, their influence on tight/adherens junctions and their role in barrier function of BBB ECs and CPE has been mostly ignored. Here, we review current knowledge on the role of Cxs in the BBB, BCSFB and other interfaces that subside within the CNS. We conclude that Cxs are a rather unexplored but promising target for influencing CNS barrier function.     

Constructing ab initio models of ultra-thin Al–AlOx–Al barriers

The microscopic structure of ultra-thin oxide barriers often plays a major role in modern nano-electronic devices. In the case of superconducting electronic circuits, their operation depends on the electrical nonlinearity provided by one or more such oxide layers in the form of ultra-thin tunnel barriers (also known as Josephson junctions). Currently available fabrication techniques manufacture an amorphous oxide barrier, which is attributed as a major noise source within the device. The nature of this noise is currently an open question and requires both experimental and theoretical investigation. Here, we present a methodology for constructing atomic-scale computational models of Josephson junctions using a combination of molecular mechanics, empirical and ab initio methods. These junctions consist of ultra-thin amorphous aluminium-oxide layers sandwiched between crystalline aluminium. The stability and structure of these barriers as a function of density and stoichiometry are investigated, which we compare with experimentally observed parameters.     

日本沼虾生精细胞与支持细胞之间的连接关系

用透射电镜技术研究了日本沼虾精子发生过程中不同细胞之间的连接关系。结果表明,从精原细胞期到次级精母细胞期,在生精细胞之间存在间隙连接与分隔连接与分隔连接,并且两种连接相互邻接,桥粒仅在精原细胞之间发现;从精原细胞期到精细胞期,在生精细胞与支持细胞之间也存在相互邻接的间隙连接与分隔连接,两类细胞之间有大量桥粒,形成血淋巴－精巢屏障,这种屏障可保持生精细管内环境的稳定性;精子发生的不同时期,支持细胞之     

The permeability barrier in the epidermis of the grass snake during the resting stage of the sloughing cycle

Summary Tracer and freeze-fracture replication techniques show that there are two morphologically and topographically distinct permeability barriers in the epidermis of the grass snake. Tight junctions interconnect the apico-lateral plasma membranes of the uppermost living cells, establishing an ionic or osmotic gradient between the stratum germinativum and alpha layer. The second barrier is formed by intercellular lipid sheets in the overlying mesos layer, which are very similar to the barrier found in the stratum corneum of mammals.     

Membrane domain organization of myelinated axons requires βII spectrin

The precise and remarkable subdivision of myelinated axons into molecularly and functionally distinct membrane domains depends on axoglial junctions that function as barriers. However, the molecular basis of these barriers remains poorly understood. Here, we report that genetic ablation and loss of axonal βII spectrin eradicated the paranodal barrier that normally separates juxtaparanodal K⁺ channel protein complexes located beneath the myelin sheath from Na⁺ channels located at nodes of Ranvier. Surprisingly, the K⁺ channels and their associated proteins redistributed into paranodes where they colocalized with intact Caspr-labeled axoglial junctions. Furthermore, electron microscopic analysis of the junctions showed intact paranodal septate-like junctions. Thus, the paranodal spectrin-based submembranous cytoskeleton comprises the paranodal barriers required for myelinated axon domain organization.     

Functional analysis of tight junctions

Epithelial and endothelial cells are joined to each other via a set of intercellular junctions that differ in their morphological appearance, composition, and function. The tight junction or zonula occludens is the intercellular junction that regulates diffusion between cells and therefore allows endothelia and epithelia to form cellular barriers that separate compartments of different composition. This intercellular gate formed by tight junctions is not only highly regulated but is size- and ion-selective and, hence, represents a semipermeable diffusion barrier. In epithelia, tight junctions form a morphological and functional border between the apical and basolateral cell surface domains. They directly contribute to the maintenance of cell surface polarity by forming a fence that prevents apical/basolateral diffusion of lipids in the outer leaflet of the plasma membrane. Here we describe a set of assays that allow the analysis of tight junctions to determine their integrity and functional state.     

植物根中质外体屏障结构和生理功能研究进展

综述了近10年来植物根中质外体屏障结构和功能的研究进展。质外体屏障指根中内、外皮层初生壁的凯氏带,或次生壁栓质化和木质化,以及植物体表角质层组成的保护组织,能隔绝水、离子和氧气不能自由进出植物体的屏障结构,具有保护植物体的生理功能。根中凯氏带的分子发育机理研究表明根内皮层类似哺乳动物上皮组织的保护作用。植物根中质外体保证内部各种生理代谢在稳定的内部环境中进行,是植物适应各种逆境的重要屏障结构。根中质外体屏障在植物适应干旱、洪涝灾害、离子胁迫和病虫害的侵袭等方面具有重要作用,在探索适应并修复极端生态环境的植物资源中有广阔的应用前景。     

The claudin-like megatrachea is essential in septate junctions for the epithelial barrier function in Drosophila

Vertebrate claudin proteins are integral components of tight junctions, which function as paracellular diffusion barriers in epithelia. We identified Megatrachea (Mega), a Drosophila transmembrane protein homologous to claudins, and show that it acts in septate junctions, the corresponding structure of invertebrates. Our analysis revealed that Mega has transepithelial barrier function similar to the claudins. Also, Mega is necessary for normal tracheal cell morphogenesis but not for apicobasal polarity or epithelial integrity. In addition, we present evidence that Mega is essential for localization of the septate junction protein complex Coracle/Neurexin. The results indicate that claudin-like proteins are functionally conserved between vertebrates and Drosophila.     

The cell junctions of the notochord of Xenopus laevis tadpoles

The cell junctions of the notochord of Xenopus laevis tadpoles were examined with the electron microscope using thin sections, lanthanum tracer experiments, and freeze-fracture replicas. Both the peripheral and vacuolated cells of the notochord are connected by numerous spot desmosomes characterized by an intercellular desmogloea and intermediate filaments on the cytoplasmic sides. The peripheral cells also display numerous hemidesmosomes facing the underlying basal lamina. Staining with rhodamine-phalloidin for F-actin yielded negative results and suggested that adhaerens-type junctions are absent. Tracer experiments with lanthanum and freeze-fracture replicas clearly revealed the presence of gap junctions between both cell types but no indications of tight junctions were found and no intercellular barrier existed for tracer infiltration of the notochord.     

LOCALIZATION OF PERMEABILITY BARRIERS IN THE FROG SKIN EPITHELIUM

Ruthenium red and colloidal lanthanum were used to determine the site of the structural barriers to diffusion within the intercellular spaces of frog skin epithelium. Electron micrographs show that occluding zonules located at the outer border of the stratum corneum and at the outer layer of the stratum granulosum are true tight junctions since they are impermeable to these tracers. Measurement of ¹⁴⁰La uptake by the living skin shows that lanthanum moves across the external surface of the skin readily, into and out of a compartment that has a limited capacity and is bounded on its internal side by a barrier impermeable to lanthanum. Examination of these skins with the electron microscope suggests that the compartment is localized between the external membrane of the cells at the outer layer of the s. granulosum and at the outermost surface of the skin. These observations and other findings described in the literature indicate that the site of the external high resistance barrier of the frog skin is localized at the outer border of the s. granulosum.     

Gliotactin,a novel marker of tricellular junctions,is necessary for septate junction development in Drosophila

Septate junctions (SJs), similar to tight junctions, function as transepithelial permeability barriers. Gliotactin (Gli) is a cholinesterase-like molecule that is necessary for blood-nerve barrier integrity, and may, therefore, contribute to SJ development or function. To address this hypothesis, we analyzed Gli expression and the Gli mutant phenotype in Drosophila epithelia. In Gli mutants, localization of SJ markers neurexin-IV, discs large, and coracle are disrupted. Furthermore, SJ barrier function is lost as determined by dye permeability assays. These data suggest that Gli is necessary for SJ formation. Surprisingly, Gli distribution only colocalizes with other SJ markers at tricellular junctions, suggesting that Gli has a unique function in SJ development. Ultrastructural analysis of Gli mutants supports this notion. In contrast to other SJ mutants in which septa are missing, septa are present in Gli mutants, but the junction has an immature morphology. We propose a model, whereby Gli acts at tricellular junctions to bind, anchor, or compact SJ strands apically during SJ development.     

Potential use of tight junction modulators to reversibly open membranous barriers and improve drug delivery

The epithelial and endothelial barriers of the human body are major obstacles for drug delivery to the systemic circulation and to organs with unique environment and homeostasis, like the central nervous system. Several transport routes exist in these barriers, which potentially can be exploited for enhancing drug permeability. Beside the transcellular pathways via transporters, adsorptive and receptor-mediated transcytosis, the paracellular flux for cells and molecules is very limited. While lipophilic molecules can diffuse across the cellular plasma membranes, the junctional complexes restrict or completely block the free passage of hydrophilic molecules through the paracellular clefts. Absorption or permeability enhancers developed in the last 40 years for modifying intercellular junctions and paracellular permeability have unspecific mode of action and the effective and toxic doses are very close. Recent advances in barrier research led to the discovery of an increasing number of integral membrane, adaptor, regulator and signalling proteins in tight and adherens junctions. New tight junction modulators are under development, which can directly target tight or adherens junction proteins, the signalling pathways regulating junctional function, or tight junction associated lipid raft microdomains. Modulators acting directly on tight junctions include peptides derived from zonula occludens toxin, or Clostridium perfringens enterotoxin, peptides selected by phage display that bind to integral membrane tight junction proteins, and lipid modulators. They can reversibly increase paracellular transport and drug delivery with less toxicity than previous absorption enhancers, and have a potential to be used as pharmaceutical excipients to improve drug delivery across epithelial barriers and the blood-brain barrier.     

A blood-brain barrier without tight junctions in the fly central nervous system in the early postembryonic stage

Summary The anatomical basis of the vertebrate blood-brain barrier is a series of tight junctions between endothelial cells of capillaries in the central nervous system. Over two decades ago, tight junctions were also proposed as the basis of the blood-brain barrier in insects. Currently there is a growing understanding that septate junctions might possess barrier properties in various invertebrate epithelial cells. We now examine these two views by studying the blood-brain barrier properties of the early postembryonic larva of a dipteran fly (Delia platura) by transmission electron microscopy. Newly hatched larvae possess a functioning blood-brain barrier that excludes the extracellular tracer, ionic lanthanum. This barrier is intact throughout the second instar stage as well. The ultrastructural correlate of this barrier is a series of extensive septate junctions that pervade the intercellular space between adjacent perineurial cells. No tight junctions were located in either nerve, glial or perineurial cell layers. We suggest that the overall barrier might involve septate junctions within extensive, meandering intercellular clefts.     

Tricellulin constitutes a novel barrier at tricellular contacts of epithelial cells

For epithelia to function as barriers, the intercellular space must be sealed. Sealing two adjacent cells at bicellular tight junctions (bTJs) is well described with the discovery of the claudins. Yet, there are still barrier weak points at tricellular contacts, where three cells join together. In this study, we identify tricellulin, the first integral membrane protein that is concentrated at the vertically oriented TJ strands of tricellular contacts. When tricellulin expression was suppressed with RNA interference, the epithelial barrier was compromised, and tricellular contacts and bTJs were disorganized. These findings indicate the critical function of tricellulin for formation of the epithelial barrier.     

Erythropoietin protects intestinal epithelial barrier function and lowers the incidence of experimental neonatal necrotizing enterocolitis

The impermeant nature of the intestinal barrier is maintained by tight junctions (TJs) formed between adjacent intestinal epithelial cells. Disruption of TJs and loss of barrier function are associated with a number of gastrointestinal diseases, including neonatal necrotizing enterocolitis (NEC), the leading cause of death from gastrointestinal diseases in preterm infants. Human milk is protective against NEC, and the human milk factor erythropoietin (Epo) has been shown to protect endothelial cell-cell and blood-brain barriers. We hypothesized that Epo may also protect intestinal epithelial barriers, thereby lowering the incidence of NEC. Our data demonstrate that Epo protects enterocyte barrier function by supporting expression of the TJ protein ZO-1. As immaturity is a key factor in NEC, Epo regulation of ZO-1 in the human fetal immature H4 intestinal epithelial cell line was examined and demonstrated Epo-stimulated ZO-1 expression in a dose-dependent manner through the PI3K/Akt pathway. In a rat NEC model, oral administration of Epo lowered the incidence of NEC from 45 to 23% with statistical significance. In addition, Epo treatment protected intestinal barrier function and prevented loss of ZO-1 at the TJs in vivo. These effects were associated with elevated Akt phosphorylation in the intestine. This study reveals a novel role of Epo in the regulation of intestinal epithelial TJs and barrier function and suggests the possible use of enteral Epo as a therapeutic agent for gut diseases.     

Activation of TLR2 enhances tight junction barrier in epidermal keratinocytes

The epidermis has developed physical and immunological barriers that prevent infiltration of deleterious chemicals and pathogens. As a first step to understanding the relationship between these barriers, we investigated whether TLR2 activation functionally alters tight junctions (TJs) in cultured human keratinocytes. Stimulation with peptidoglycan, a ligand for TLR2, elevated the TJ-associated barrier in the space of 3 h. The increase in TJ-associated barrier function due to peptidoglycan stimulation was suppressed by the knockdown of TLR adaptor MyD88 or the pretreatment with TLR2-neutralizing Ab, indicating that TLR2 activation enhanced TJ-associated barrier. One and 3 h after peptidoglycan stimulation, expression levels of the TJ proteins occludin, claudin-1, claudin-4, and ZO-1 were unchanged. However, immunoprecipitation studies demonstrated that the association of phospho-atypical protein kinase Cζ/ι, crucial for TJ biogenesis, with occludin was increased. Significantly, inhibition of atypical protein kinase Cζ/ι activity completely blocked the immediate elevation of the TJ-associated barrier. Finally, peptidoglycan was applied to the stratum corneum surface of a human skin equivalent, and the TJ barrier was evaluated. In the space of 3 h after the stimulation, the amount of intercellular tracer in the stratum corneum incubated from the dermal side was reduced, indicating that the TJ barrier is strengthened via TLR2 activation. Taken together, our findings indicated that infiltration of pathogens into the epidermis immediately enhanced TJ function via TLR2 signaling. Furthermore, the dynamically controlled TJs in skin are considered fundamental in preventing further invasion of pathogens and maintaining cutaneous barrier homeostasis.     

A seamless trespass: germ cell migration across the seminiferous epithelium during spermatogenesis

During spermatogenesis, preleptotene spermatocytes traverse the blood-testis barrier (BTB) in the seminiferous epithelium, which is reminiscent of viral pathogens breaking through the tight junctions of host epithelial cells. The process also closely resembles the migration of leukocytes across endothelial tight junctions to reach inflammation sites. Cell adhesion molecules of the immunoglobulin superfamily (e.g., JAM/CAR/nectin) participate in germ cell migration by conferring transient adhesion between Sertoli and germ cells through homophilic and heterophilic interactions. The same molecules also comprise the junctional complexes at the BTB. Interestingly, JAM/CAR/nectin molecules mediate virus uptake and leukocyte transmigration in strikingly similar manners. It is likely that the strategy used by viruses and leukocytes to break through junctional barriers is used by germ cells to open up the inter-Sertoli cell junctions. In associating these diverse cellular events, we highlight the "guiding" role of JAM/CAR/nectin molecules for germ cell passage. Knowledge on viral invasion and leukocyte transmigration has also shed insights into germ cell movement during spermatogenesis.     

Cellular Elements of the Blood-Brain Barrier

The Blood-brain-barrier (BBB) provides both anatomical and physiological protection for the central nervous system (CNS), shielding the brain for toxic substances in the blood, supplying brain tissues with nutrients and filtering harmful compounds from the brain back to the bloodstream. The BBB is composed of four main cellular elements: endothelial cells (ECs), astrocyte end-feet, microglial cells, and perycites. Transport across the BBB is limited by both physical and metabolic barriers (enzymes, and different transport systems). Tight junctions (TJs) present between ECs form an important barrier against diffusion, excluding most blood-borne substances for entering the brain.     

Channels in epithelial cell membranes and junctions.

Epithelia may be classified as "tight" or "leaky," depending on whether there is a significant pathway for transepithelial ion permeation via the junctions and bypassing the cells. The resistance of this paracellular channel may depend partly on structures visible in the electron microscope, partly on wall charge. Permeability determinations in the leaky junctions of gallbladder epithelium, using many different organic cations, suggest that the critical barriers barriers to ion permeation are 5--8 A in radius and bind cations by up to four strongly proton-accepting oxygens. The apical cell membrane of tight epithelia contains a Na+-selective channel that is blocked by amiloride and Ca2+, subject to negative feedback control by the Na+ pump in the basolateral membrane, and somehow promoted by aldosterone. To determine the permeabilities of these two channels (the junctional channel of leaky epithelia, and the Na+ channel of tight epithelia) to water and nonelectrolytes remains a major unsolved problem.