Dan Yu scite author profile

Tissue barriers that restrict passage of liquids, ions, and larger solutes are essential for the development of multicellular organisms. In simple organisms this allows distinct cell types to interface with the external environment. In more complex species, the diversity of cell types capable of forming barriers increases dramatically. Although the plasma membranes of these barrier-forming cells prevent flux of most hydrophilic solutes, the paracellular, or shunt, pathway between cells must also be sealed. This function is accomplished in vertebrates by the zonula occludens, or tight junction. The tight junction barrier is not absolute but is selectively permeable and is able to discriminate between solutes on the basis of size and charge. Many tight junction components have been identified over the past 20 years, and recent progress has provided new insights into the proteins and interactions that regulate structure and function. This review presents these data in a historical context and proposes an integrated model in which dynamic regulation of tight junction protein interactions determines barrier function.

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Occludin S408 phosphorylation regulates tight junction protein interactions and barrier function

Raleigh

Boe

et al. 2011

218

259

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MLCK-dependent exchange and actin binding region-dependent anchoring of ZO-1 regulate tight junction barrier function

Marchiando

Weber

et al. 2010

Proc. Natl. Acad. Sci. U.S.A.

228

221

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The perijunctional actomyosin ring contributes to myosin light chain kinase (MLCK)-dependent tight junction regulation. However, the specific protein interactions involved in this process are unknown. To test the hypothesis that molecular remodeling contributes to barrier regulation, tight junction protein dynamic behavior was assessed by fluorescence recovery after photobleaching (FRAP). MLCK inhibition increased barrier function and stabilized ZO-1 at the tight junction but did not affect claudin-1, occludin, or actin exchange in vitro. Pharmacologic MLCK inhibition also blocked in vivo ZO-1 exchange in wild-type, but not long MLCK −/− , mice. Conversely, ZO-1 exchange was accelerated in transgenic mice expressing constitutively active MLCK. In vitro, ZO-1 lacking the actin binding region (ABR) was not stabilized by MLCK inhibition, either in the presence or absence of endogenous ZO-1. Moreover, the free ABR interfered with full-length ZO-1 exchange and reduced basal barrier function. The free ABR also prevented increases in barrier function following MLCK inhibition in a manner that required endogenous ZO-1 expression. In silico modeling of the FRAP data suggests that tight junction-associated ZO-1 exists in three pools, two of which exchange with cytosolic ZO-1. Transport of the ABR-anchored exchangeable pool is regulated by MLCK. These data demonstrate a critical role for the ZO-1 ABR in barrier function and suggest that MLCK-dependent ZO-1 exchange is essential to this mechanism of barrier regulation.fluorescence recovery after photobleaching | mathematical models | myosin light chain kinase | paracellular permeability | intestinal epithelium G reat progress has been made toward identifying components of the tight junction. These include transmembrane, peripheral membrane, and regulatory proteins, many of which contain one or more domains that mediate interactions with other tight junction and cytoskeletal proteins (1). These and other observations drove development of models that depicted the tight junction as a static, heavily cross-linked protein complex (2). However, recent data showing rapid and continuous remodeling of the tight junction refuted the previous models and led to the hypothesis that modulation of protein remodeling behavior could be a mechanism of tight junction barrier regulation (3, 4).The perijunctional ring of F-actin and myosin II that supports the tight junction is essential to physiological and pathophysiological barrier regulation (5). For example, activation of perijunctional myosin light chain kinase (MLCK) is sufficient to enhance paracellular permeability (6, 7) and is required for tight junction barrier regulation in response to Na + -nutrient cotransport, inflammatory cytokines, or pathogenic bacteria (8). Thus, modulation of MLCK activity represents a point of convergence for multiple signaling pathways that regulate tight junction barrier function.To assess the role of molecular remodeling in barrier regulation, dynamic behaviors of tight junction proteins were assessed b...

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An improved monomeric infrared fluorescent protein for neuronal and tumour brain imaging

et al. 2014

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Infrared fluorescent proteins (IFPs) are ideal for in vivo imaging and monomeric versions of these proteins can be advantageous as protein tags or for sensor development. In contrast to GFP, which requires only molecular oxygen for chromophore maturation, phytochrome-derived IFPs incorporate biliverdin (BV) as the chromophore. However, BV varies in concentration in different cells and organisms. Here we engineered cells to express the heme oxygenase responsible for BV biosynthesys and a brighter monomeric IFP mutant (IFP2.0). Together, these tools improve the imaging capabilities of IFP2.0 compared to monomeric IFP1.4 and dimeric iRFP. By targeting IFP2.0 to the plasma membrane, we demonstrate robust labeling of neuronal processes in Drosophila larvae. We also show that this strategy improves the sensitivity when imaging brain tumors in whole mice. Our work shows promise in the application of IFPs for protein labeling and in vivo imaging.

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Elucidating the principles of the molecular organization of heteropolymeric tight junction strands

Piontek

Fritzsche

Cording

et al. 2011

Cell. Mol. Life Sci.

119

166

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Paracellular barrier properties of tissues are mainly determined by the composition of claudin hetero-polymers. To analyze the molecular organization of tight junctions (TJ), we investigated the ability of claudins (Cld) to form homo- and heteromers. Cld1, -2, -3, -5, and -12 expressed in cerebral barriers were investigated. TJ-strands were reconstituted by claudin-transfection of HEK293-cells. cis-Interactions and/or spatial proximity were analyzed by fluorescence resonance energy transfer inside and outside of strands and ranked: Cld5/Cld5 > Cld5/Cld1 > Cld3/Cld1 > Cld3/Cld3 > Cld3/Cld5, no Cld3/Cld2. Classic Cld1, -3, and -5 but not non-classic Cld12 showed homophilic trans-interaction. Freeze-fracture electron microscopy revealed that, in contrast to classic claudins, YFP-tagged Cld12 does not form homopolymers. Heterophilic trans-interactions were analyzed in cocultures of differently monotransfected cells. trans-Interaction of Cld3/Cld5 was less pronounced than that of Cld3/Cld1, Cld5/Cld1, Cld5/Cld5 or Cld3/Cld3. The barrier function of reconstituted TJ-strands was demonstrated by a novel imaging assay. A model of the molecular organization of TJ was generated.

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Dan Yu

Tight Junction Pore and Leak Pathways: A Dynamic Duo

Occludin S408 phosphorylation regulates tight junction protein interactions and barrier function

MLCK-dependent exchange and actin binding region-dependent anchoring of ZO-1 regulate tight junction barrier function

An improved monomeric infrared fluorescent protein for neuronal and tumour brain imaging

Elucidating the principles of the molecular organization of heteropolymeric tight junction strands

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