Randall J. Mrsny

Physiological regulation of epithelial tight junctions is associated with myosin light-chain phosphorylation

Tight junctions serve as the rate-limiting barrier to passive movement of hydrophilic solutes across intestinal epithelia. After activation of Na+-glucose cotransport, the permeability of intestinal tight junctions is increased. Because previous analyses of this physiological tight junction regulation have been restricted to intact mucosae, dissection of the mechanisms underlying this process has been limited. To characterize this process, we have developed a reductionist model consisting of Caco-2 intestinal epithelial cells transfected with the intestinal Na+-glucose cotransporter, SGLT1. Monolayers of SGLT1 transfectants demonstrate physiological Na+-glucose cotransport. Activation of SGLT1 results in a 22 +/- 5% fall in transepithelial resistance (TER) (P < 0.001). Similarly, inactivation of SGLT1 by addition of phloridzin increases TER by 24 +/- 2% (P < 0.001). The increased tight junction permeability is size selective, with increased flux of small nutrient-sized molecules, e.g., mannitol, but not of larger molecules, e.g., inulin. SGLT1-dependent increases in tight junction permeability are inhibited by myosin light-chain kinase inhibitors (20 microM ML-7 or 40 microM ML-9), suggesting that myosin regulatory light-chain (MLC) phosphorylation is involved in tight junction regulation. Analysis of MLC phosphorylation showed a 2.08-fold increase after activation of SGLT1 (P < 0.01), which was inhibited by ML-9 (P < 0.01). Thus monolayers incubated with glucose and myosin light-chain kinase inhibitors are comparable to monolayers incubated with phloridzin. ML-9 also inhibits SGLT1-mediated tight junction regulation in small intestinal mucosa (P < 0.01). These data demonstrate that epithelial cells are the mediators of physiological tight junction regulation subsequent to SGLT1 activation. The intimate relationship between tight junction regulation and MLC phosphorylation suggests that a critical step in regulation of epithelial tight junction permeability may be myosin ATPase-mediated contraction of the perijunctional actomyosin ring and subsequent physical tension on the tight junction.

Epithelial myosin light chain kinase–dependent barrier dysfunction mediates T cell activation–induced diarrhea in vivo

Disruption of the intestinal epithelial barrier occurs in many intestinal diseases, but neither the mechanisms nor the contribution of barrier dysfunction to disease pathogenesis have been defined. We utilized a murine model of T cell-mediated acute diarrhea to investigate the role of the epithelial barrier in diarrheal disease. We show that epithelial barrier dysfunction is required for the development of diarrhea. This diarrhea is characterized by reversal of net water flux, from absorption to secretion; increased leak of serum protein into the intestinal lumen; and altered tight junction structure. Phosphorylation of epithelial myosin II regulatory light chain (MLC), which has been correlated with tight junction regulation in vitro, increased abruptly after T cell activation and coincided with the development of diarrhea. Genetic knockout of long myosin light chain kinase (MLCK) or treatment of wild-type mice with a highly specific peptide MLCK inhibitor prevented epithelial MLC phosphorylation, tight junction disruption, protein leak, and diarrhea following T cell activation. These data show that epithelial MLCK is essential for intestinal barrier dysfunction and that this barrier dysfunction is critical to pathogenesis of diarrheal disease. The data also indicate that inhibition of epithelial MLCK may be an effective non-immunosuppressive therapy for treatment of immune-mediated intestinal disease.

In vitro evaluation of microparticles and polymer gels for use as nasal platforms for protein delivery

AbstractPurpose. Nasal delivery of protein therapeutics can be compromised by the brief residence time at this mucosal surface. Some bioadhesive polymers have been suggested to extend residence time and improve protein uptake across the nasal mucosa. We examined several potential polymer platforms for their in vitro protein release, relative bioadhesive properties and induction of cytokine release from respiratory epithelium. Methods. Starch, alginate, chitosan or Carbopol® microparticles, containing the test protein bovine serum albumin (BSA), were prepared by spray-drying and characterized by laser diffraction and scanning electron microscopy. An open-membrane system was used to determine protein release profiles and confluent, polarized Calu-3 cell sheets were used to evaluate relative bioadhesion, enhancement of protein transport and induction of cytokine release in vitro. Results. All spray-dried microparticles averaged 2−4 μm in diameter. Loaded BSA was not covalently aggregated or degraded. Starch and alginate microparticles released protein more rapidly but were less adhesive to polarized Calu-3 cells than chitosan and Carbopol® microparticles. Protein transport across polarized Calu-3 cells was enhanced from Carbopol® gels and chitosan microparticles. A mixture of chitosan microparticles with lysophosphatidylcholine increased protein transport further. Microparticles prepared from either chitosan or starch microparticles, applied apically, induced the basolateral release of IL-6 and IL-8 from polarized Calu-3 cells. Release of other cytokines, such as IL-lβ, TNF-α, GM-CSF and TGF-β, were not affected by an apical exposure to polymer formulations. Conclusions. We have described two systems for the in vitro assessment of potential nasal platforms for protein delivery. Based upon these assessments, Carbopol® gels and chitosan microparticles provided the most desirable characteristics for protein therapeutic and protein antigen delivery, respectively, of the formulations examined.

Transcellular uptake mechanisms of the intestinal epithelial barrier Part one

Part one of this two-part review addresses the transport of therapeutics across the intestinal barrier, and focuses on transcellular transport through the intestinal epithelia. The anatomical, biochemical and physiological parameters impacting transcellular uptake of orally administered drugs are described, and methods for overcoming obstacles limiting successful transcellular oral drug delivery are discussed. Part two will cover paracellular transport.

A Key Claudin Extracellular Loop Domain is Critical for Epithelial Barrier Integrity

Intercellular tight junctions (TJs) regulate epithelial barrier properties. Claudins are major structural constituents of TJs and belong to a large family of tetra-spanning membrane proteins that have two predicted extracellular loops (ELs). Given that claudin-1 is widely expressed in epithelia, we further defined the role of its EL domains in determining TJ function. The effects of several claudin-1 EL mimetic peptides on epithelial barrier structure and function were examined. Incubation of model human intestinal epithelial cells with a 27-amino acid peptide corresponding to a portion of the first EL domain (Cldn-1(53-80)) reversibly interfered with epithelial barrier function by inducing the rearrangement of key TJ proteins: occludin, claudin-1, junctional adhesion molecule-A, and zonula occludens-1. Cldn-1(53-80) associated with both claudin-1 and occludin, suggesting both the direct interference with the ability of these proteins to assemble into functional TJs and their close interaction under physiological conditions. These effects were specific for Cldn-1(53-80), because peptides corresponding to other claudin-1 EL domains failed to influence TJ function. Furthermore, the oral administration of Cldn-1(53-80) to rats increased paracellular gastric permeability. Thus, the identification of a critical claudin-1 EL motif, Cldn-1(53-80), capable of regulating TJ structure and function, offers a useful adjunct to treatments that require drug delivery across an epithelial barrier.

Intrachromosomal Looping Is Required for Activation of Endogenous Pluripotency Genes during Reprogramming

Generation of induced pluripotent stem cells (iPSCs) by defined factors is an extremely inefficient process, because there is a strong epigenetic block preventing cells from achieving pluripotency. Here we report that virally expressed factors bound to the promoters of their target genes to the same extent in both iPSCs and unreprogrammed cells (URCs). However, expression of endogenous pluripotentcy genes was observed only in iPSCs. Comparison of local chromatin structure of the OCT4 locus revealed that there was a cohesin-complex-mediated intrachromosomal loop that juxtaposes a downstream enhancer to the genes promoter, enabling activation of endogenous stemness genes. None of these long-range interactions were observed in URCs. Knockdown of the cohesin-complex gene SMC1 by RNAi abolished the intrachromosomal interaction and affected pluripotency. These findings highlight the importance of the SMC1-orchestrated intrachromosomal loop as a critical epigenetic barrier to the induction of pluripotency.

The colon as a site for drug delivery

Abstract Colonic drug absorption, as an alternative to parenteral drug delivery, is evaluated for its potential advantages and limitations. Methodologies for studying and enhancing colonic drug absorption are discussed with emphasis on the biological and chemical nature of absorption barriers. Recent efforts at identifying factors that control colonie drug absorption and which might be exploited in a delivery scheme are described.

The second loop of occludin is required for suppression of Raf1-induced tumor growth

Tight junctions (TJs) regulate epithelial cell polarity and paracellular permeability. Loss of functional TJs is commonly associated with epithelial cell-derived cancers. Raf1-mediated transformation of rat salivary gland epithelial cells (Pa4-Raf1) induces transcriptional downregulation of the TJ protein occludin and forced re-expression of occludin rescues polarized phenotype of epithelial cells. In the present study, we used this model to examine how specific structural modifications in the occludin protein affect its function in vitro and influence tumor growth in vivo. Our results revealed that neither the C-terminal nor the N-terminal half of occludin alone were sufficient to rescue cells from transformation by Raf1. However, forced expression of an occludin mutant lacking the first extracellular loop was sufficient to rescue cells from Raf1-mediated transformation. Interestingly, forced expression of an occludin mutant lacking the second extracellular loop did not rescue the epithelial phenotype in vitro nor did it prevent tumor growth in vivo. These results demonstrate that the TJ protein occludin has a potent inhibitory effect on the Raf1-mediated tumorigenesis, and the second extracellular loop of occludin appears to be critical for this function.

Regulation of the intestinal epithelial paracellular barrier.

Paracellular transport of orally-administered drugs, the passage of molecules between adjacent intestinal epithelial cells, is impeded by a range of structural and functional features found in the intestine. An increased knowledge of the mechanisms that govern the paracellular barrier will enable the pharmaceutical scientist to design novel and rational formulations and delivery platforms that will improve the oral bioavailability of therapeutic molecules, particularly proteins and peptides, which would be taken-up by the paracellular pathway.

Raf 1 represses expression of the tight junction protein occludin via activation of the zinc-finger transcription factor slug

Although dysregulation of tight junction (TJ) proteins is observed in epithelial malignancy, their participation in epithelial transformation is poorly understood. Recently we demonstrated that expression of oncogenic Raf 1 in Pa4 epithelial cells disrupts TJs and induces an oncogenic phenotype by downregulating expression of the TJ protein, occludin. Here we report the mechanism by which Raf 1 regulates occludin expression. Raf 1 inhibited occludin transcription by repressing a minimal segment of the occludin promoter in concert with upregulation of the transcriptional repressor, Slug without influencing the well-documented transcriptional repressor, Snail. Overexpression of Slug in Pa4 cells recapitulated the effect of Raf 1 on occludin expression, and depletion of Slug by small interfering RNA abrogated the effect of Raf 1 on occludin. Finally, chromatin immunoprecipitation assays and site-directed mutagenesis demonstrated a direct interaction between Slug and an E-box within the minimal Raf 1-responsive segment of the occludin promoter. These findings support a role of Slug in mediating Raf 1-induced transcriptional repression of occludin and subsequent epithelial to mesenchymal transition.