Crystal Structure of a Claudin Provides Insight into the Architecture of Tight Junctions

Suzuki, Hiroshi; Nishizawa, Takashi; Tani, Kazuhide; Yamazaki, Y.; Tamura, Atsushi; Ishitani, Ryuichiro; Dohmae, Naoshi; Tsukita, Sachiko; Nureki, Osamu; Fujiyoshi, Yoshinori

doi:10.1126/science.1248571

Cited by 325 publications

(476 citation statements)

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“…To verify claudin-21's ion selectivity, we built homology models of claudin-21 based on the crystal structure of claudin-15 (25). We also built structural models of claudin-2 and -10a, as channels with a preference for positively and negatively charged ions, respectively.…”

Section: Resultsmentioning

confidence: 99%

“…Two categories of claudins have been proposed, namely, the paracellular barrier type and the paracellular channel type, based on the transepithelial electrical resistance (TER) or on the cation and/or anion permeability of many epithelial cell lines (5, 7). Among some claudins characterized as channel-type claudins, such as claudin-2, -7, -10, -15, -16, and -17, claudin-2 and -15 have been studied extensively with respect to specific ions and water (9-11, 14, 17, 20, 21, 23, 24).The structure of claudin-15 was recently analyzed; this analysis revealed that two extracellular segments form a unique ␤ sheet domain fixed to a transmembrane four-helix bundle by a W-LW claudin consensus motif (25,26). The high-resolution structure of claudin-15 suggests that a ␤-barrel pore created by eight claudin molecules in the region between two cells can form a paracellular channel, which is regulated by charged residues on the claudins' extracellular domains.…”

mentioning

confidence: 99%

“…The structure of claudin-15 was recently analyzed; this analysis revealed that two extracellular segments form a unique ␤ sheet domain fixed to a transmembrane four-helix bundle by a W-LW claudin consensus motif (25,26). The high-resolution structure of claudin-15 suggests that a ␤-barrel pore created by eight claudin molecules in the region between two cells can form a paracellular channel, which is regulated by charged residues on the claudins' extracellular domains.…”

mentioning

confidence: 99%

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Claudin-21 Has a Paracellular Channel Role at Tight Junctions

Tanaka

Yamamoto

Kashihara

et al. 2016

Molecular and Cellular Biology

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g Claudin protein family members, of which there are at least 27 in humans and mice, polymerize to form tight junctions (TJs) between epithelial cells, in a tissue-and developmental stage-specific manner. Claudins have a paracellular barrier function. In addition, certain claudins function as paracellular channels for small ions and/or solutes by forming selective pores at the TJs, although the specific claudins involved and their functional mechanisms are still in question. Here we show for the first time that claudin-21, which is more highly expressed in the embryonic than the postnatal stages, acts as a paracellular channel for small cations, such as Na ؉ , similar to the typical channel-type claudins claudin-2 and -15. Claudin-21 also allows the paracellular passage of larger solutes. Our findings suggest that claudin-21-based TJs allow the passage of small and larger solutes by both paracellular channel-based and some additional mechanisms. Epithelial cell sheets form and cover every compartment of the body. Homeostasis is specifically maintained for organ and tissue function in each compartment. To create sheets with a barrier function, epithelial cells adhere to each other side by side through well-organized cell-cell adhesion systems (1), such as tight junctions (TJs), which maintain distinct environments by blocking the free exchange of molecules across the cell sheet (2, 3). Accumulating evidence indicates that the molecular strands that form the TJ barriers are composed primarily of polymerized claudins, which are adhesion molecules containing four transmembrane helices (2, 4). The claudins both create the paracellular barrier and determine which ions and/or molecules can selectively cross it (5-7).The claudins comprise a large gene family with at least 27 members, in humans or mice, that have distinct expression patterns and properties (2,3,8). Epithelial cells generally express multiple types of claudins; the particular claudin combination expressed appears to determine the specific properties of each TJbased paracellular permselective barrier (9-22). Two categories of claudins have been proposed, namely, the paracellular barrier type and the paracellular channel type, based on the transepithelial electrical resistance (TER) or on the cation and/or anion permeability of many epithelial cell lines (5, 7). Among some claudins characterized as channel-type claudins, such as claudin-2, -7, -10, -15, -16, and -17, claudin-2 and -15 have been studied extensively with respect to specific ions and water (9-11, 14, 17, 20, 21, 23, 24).The structure of claudin-15 was recently analyzed; this analysis revealed that two extracellular segments form a unique ␤ sheet domain fixed to a transmembrane four-helix bundle by a W-LW claudin consensus motif (25,26). The high-resolution structure of claudin-15 suggests that a ␤-barrel pore created by eight claudin molecules in the region between two cells can form a paracellular channel, which is regulated by charged residues on the claudins' extracellular domains.Although ...

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Section: Resultsmentioning

confidence: 99%

mentioning

confidence: 99%

mentioning

confidence: 99%

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Claudin-21 Has a Paracellular Channel Role at Tight Junctions

Tanaka

Yamamoto

Kashihara

et al. 2016

Molecular and Cellular Biology

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“…Claudin-2 pores also permit the flux of water through a common pore (Muto et al, 2010;Rosenthal et al, 2016Rosenthal et al, , 2010. The specificity for Na + is governed by the first of two extracellular loops of claudin-2 that are adjoined to four transmembrane domains with intracellular N-and C-termini Li et al, 2014;Suzuki et al, 2014;Yu et al, 2009). Pore-forming claudins define the charge and size selectivity of the high-capacity pore pathway Colegio et al, 2002;Shen et al, 2011;Turner, 2009;Van Itallie et al, 2008;Weber et al, 2010).…”

Section: Claudin Proteins Define the Selectivity Of Paracellular Permmentioning

confidence: 99%

The mucosal barrier at a glance

Turner

2017

Journal of Cell Science

214

183

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Mucosal barriers separate self from non-self and are essential for life. These barriers, which are the first line of defense against external pathogens, are formed by epithelial cells and the substances they secrete. Rather than an absolute barrier, epithelia at mucosal surfaces must allow selective paracellular flux that discriminates between solutes and water while preventing the passage of bacteria and toxins. In vertebrates, tight junctions seal the paracellular space; flux across the tight junction can occur through two distinct routes that differ in selectivity, capacity, molecular composition and regulation. Dysregulation of either pathway can accompany disease. A third, tight-junction-independent route that reflects epithelial damage can also contribute to barrier loss during disease. In this Cell Science at a Glance article and accompanying poster, we present current knowledge on the molecular components and pathways that establish this selectively permeable barrier and the interactions that lead to barrier dysfunction during disease.

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“…Crystal structures of Claudins, proteins with close homology to TARPs, enabled a more refined view, defining a folded extracellular 'cap' (Suzuki et al, 2014;Saitoh et al, 2015;Shinoda et al, 2016) that substantially limits the sections of the extracellular portion of TARPs that are able to interact with the AMPA receptor, and therefore the likely range of these interactions. More recently, cryo-EM/single particle analysis of GluA2-TARP complexes allowed unambiguous positioning of TARPs at the periphery of the GluA2 pore, and partially resolved the extracellular domains of TARPs (Twomey et al, 2016;Zhao et al, 2016).…”

Section: A Model Of Auxiliary Protein Interactionsmentioning

confidence: 99%

Control of AMPA Receptor Activity by the Extracellular Loops of Auxiliary Proteins

Eibl

Riva

Volkmer

et al. 2018

Biophysical Journal

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At synapses throughout the mammalian brain, AMPA receptors form complexes with auxiliary proteins, including TARPs. However, how TARPs modulate AMPA receptor gating remains poorly understood. We built structural models of TARP-AMPA receptor complexes for TARPs g2 and g8, combining recent structural studies and de novo structure predictions. These models, combined with peptide binding assays, provide evidence for multiple interactions between GluA2 and variable extracellular loops of TARPs. Substitutions and deletions of these loops had surprisingly rich effects on the kinetics of glutamate-activated currents, without any effect on assembly. Critically, by altering the two interacting loops of g2 and g8, we could entirely remove all allosteric modulation of GluA2, without affecting formation of AMPA receptor-TARP complexes. Likewise, substitutions in the linker domains of GluA2 completely removed any effect of g2 on receptor kinetics, indicating a dominant role for this previously overlooked site proximal to the AMPA receptor channel gate.

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Crystal Structure of a Claudin Provides Insight into the Architecture of Tight Junctions

Cited by 325 publications

References 45 publications

Claudin-21 Has a Paracellular Channel Role at Tight Junctions

Claudin-21 Has a Paracellular Channel Role at Tight Junctions

The mucosal barrier at a glance

Control of AMPA Receptor Activity by the Extracellular Loops of Auxiliary Proteins

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