Intestinal Permeability Defects: Is It Time to Treat?

doi:10.1016/j.cgh.2013.07.001

Clinical Gastroenterology and Hepatology

Volume 11, Issue 9, September 2013, Pages 1075-1083

https://doi.org/10.1016/j.cgh.2013.07.001 Get rights and content

An essential role of the intestinal epithelium is to separate luminal contents from the interstitium, a function primarily determined by the integrity of the epithelium and the tight junction that seals the paracellular space. Intestinal tight junctions are selectively permeable, and intestinal permeability can be increased physiologically in response to luminal nutrients or pathologically by mucosal immune cells and cytokines, the enteric nervous system, and pathogens. Compromised intestinal barrier function is associated with an array of clinical conditions, both intestinal and systemic. Although most available data are correlative, some studies support a model where cycles of increased intestinal permeability, intestinal immune activation, and subsequent immune-mediated barrier loss contribute to disease progression. This model is applicable to intestinal and systemic diseases. However, it has not been proven, and both mechanistic and therapeutic studies are ongoing. Nevertheless, the correlation between increased intestinal permeability and disease has caught the attention of the public, leading to a rise in popularity of the diagnosis of “leaky gut syndrome,” which encompasses a range of systemic disorders. Proponents claim that barrier restoration will cure underlying disease, but this has not been demonstrated in clinical trials. Moreover, human and mouse studies show that intestinal barrier loss alone is insufficient to initiate disease. It is therefore uncertain whether increased permeability in these patients is a cause or effect of the underlying disorder. Although drug targets that may mediate barrier restoration have been proposed, none have been proven effective. As such, current treatments for barrier dysfunction should target the underlying disease.

Section snippets

Definitions

Intestinal permeability is the property that allows solute and fluid exchange between the lumen and tissues. Conversely, intestinal barrier function refers to the ability of the mucosa and extracellular barrier components, eg, mucus, to prevent this exchange. Neither permeability nor barrier function is absolute, and the relative magnitudes of these opposing characteristics vary inversely. However, the term intestinal barrier has become a catch phrase that is being increasingly applied to

Physiological Regulation of Intestinal Barrier Function

The most studied instance of physiological intestinal barrier regulation is that triggered by Na⁺-glucose cotransport. This leads to activation of epithelial MLCK, which drives size-selective, ie, pore pathway, increases in paracellular permeability.15, 31, 32, 33 This enhances paracellular water flux as a result of the osmotic gradient created by transcellular Na⁺ and glucose transport. This combination of paracellular water flow and increased paracellular permeability also allows paracellular

Implications of Animal Model Data for Human Disease

Intestinal barrier loss, ie, permeability increases beyond the normal range, precedes disease onset in mouse models of type I diabetes, GVHD, necrotizing enterocolitis, and IBD. Unfortunately, like human data, most studies that use these models have failed to distinguish between cause and effect. However, there are several exceptions. For example, a zonulin antagonist (larazotide) has been shown to reduce diabetes and IBD in the nonobese diabetic and IL-10 knockout mouse models of these

Implications for Clinical Diagnosis

The data above show that progress is being made in understanding barrier loss in disease, including the means by which such barrier loss contributes to disease. However, they also make it clear that intestinal barrier loss can occur by several mechanisms, only some of which reflect tight junction dysregulation, and that tight junction barrier loss can be divided into distinct pathways that are differentially modulated by disease effectors. Finally, increased intestinal permeability can be

Conclusions

Advances have been made in understanding the cellular mechanisms of intestinal barrier loss in disease. Unfortunately, the only agent purported to restore the barrier failed to do so in clinical trials. More detailed data are available for inflammatory mediators such as TNF and IL-13, as well as some infectious agents. However, this information has not yet led to therapeutic agents suitable for clinical trials. MLCK could be a promising therapeutic target, but the inhibitors presently available

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SOP can reduce IECs apoptosis through the inhibition of the PI3K/AKT signaling pathway, thereby protecting the intestinal barrier. This study is the first to illustrate how SOP ameliorates colitis and protects the intestinal barrier, suggesting SOP has potential clinical application in treating CD.
High-fat diet-induced obesity causes intestinal Th17/Treg imbalance that impairs the intestinal barrier and aggravates anxiety-like behavior in mice
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The prevalence of autism spectrum disorders (ASD) has been steadily increasing, and growing evidence suggests a link between high-fat diet (HFD), obesity, and ASD; however, the mechanism underlying this association remains elusive. Herein, BTBR T + tf/J (BTBR) inbred mice (a mouse ASD model) and C57Bl/6J (C57) mice were fed an HFD and normal diet (ND) for 8 weeks (groups: C57 + ND, C57 + HFD, BTBR + ND, and BTBR + HFD). Subsequently, mice underwent behavioral assessments, followed by intestinal tissues harvesting to detect expression of intestinal barrier proteins and inflammatory factors and immune cell numbers, and a correlation analysis. HFD-fed BTBR mice developed obesity, elevated blood sugar, significantly aggravated anxiety-like behaviors, impaired intestinal barrier function, intestinal inflammation with elevated CD4⁺IL17⁺ T (Th17) cells and reduced CD4⁺Foxp3⁺ T (Treg) cells, exhibiting reduced expression of proteins related to AMPK regulatory pathway (AMPK, p-AMPK, SIRT1). Correlation analysis revealed that the degree of behavioral anxiety, the degree of intestinal barrier damage, the severity of intestinal inflammation, and the degree of immune cell imbalance positively correlated with each other. Accordingly, HFD-induced obesity may cause intestinal Th17/Treg imbalance via the AMPK-SIRT1 pathway, leading to an inflammatory environment in the intestine, impairing intestinal barrier function, and ultimately aggravating anxiety-like behaviors in mice.
Organ-on-chip models for intestinal permeability studies
2024, Concepts and Models for Drug Permeability Studies: Cell and Tissue based In Vitro Culture Models
Oral administration is the most common and preferable drug administration route. During new drugs development, evaluating the intestinal permeability is essential to replicate intestinal drug absorption and pharmacokinetics in vivo. Common intestinal models are based on Transwell systems, using Caco-2 cells as surrogates of the intestinal epithelium. However, current models fail to replicate the mechanical stimuli associated with the fluid flow and the peristaltic movements present in the human intestine. Organ-on-chip technology holds the potential to fill this gap. In this chapter, an overview of the human intestine and microfluidics technology is provided, followed by a brief description of intestine-on-chip models that can be used to perform intestinal permeability studies. Lastly, some future perspectives for the field are addressed. Intestine-on-chip models promote a faster and more complete differentiation of the intestinal epithelium, increasing the physiological relevance of intestinal in vitro models, thus leading to more reliable drug permeability studies.
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Spontaneous fermentation of Tritordeum flour enhances the nutritional potential of this hybrid cereal. However, the effect of consumption of Tritordeum sourdough bread (SDB) on gut health remains to be elucidated. This study investigated the effect of in vitro digestion and faecal fermentation of SDB compared to that of traditional baker's yeast (BYB) Tritordeum bread. After 24-h anaerobic faecal fermentation, both SDB and BYB (1% w/v) induced an increase in the relative abundances of Bifidobacterium, Megasphaera, Mitsuokella, and Phascolarctobacterium genera compared to baseline, while concentrations of acetate and butyrate were significantly higher at 24 h for SDB compared to those for BYB. Integrity of intestinal epithelium, as assessed through in vitro trans-epithelial electrical resistance (TEER) assay, was slightly increased after incubation with SDB fermentation supernatants, but not after incubation with BYB fermentation supernatants. The SDB stimulated in vitro mucosal immune response by inducing early secretion of inflammatory cytokines, IL-6 and TNF-α, followed by downregulation of the inflammatory trigger through induction of anti-inflammatory IL-10 expression. Overall, our findings suggest that Tritordeum sourdough can modulate gut microbiota fermentation activity and positively impact the gut health.
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: Conflicts of interest The authors disclose no conflicts.

: Funding The authors are supported by the National Institutes of Health (R01DK61931, R01DK68271, T32HD007009), Department of Defense (W81XWH-09-1-0341), the Broad Medical Research Foundation (IBD-022), the Crohn's and Colitis Foundation of America, and the Chicago Biomedical Consortium (with support from The Searle Funds at The Chicago Community Trust).

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Advances in translational scienceIntestinal Permeability Defects: Is It Time to Treat?

Section snippets

Definitions

Physiological Regulation of Intestinal Barrier Function

Implications of Animal Model Data for Human Disease

Implications for Clinical Diagnosis

Conclusions

Gastroenterology

Eur J Cell Biol

Biophys J

Gastroenterology

J Biol Chem

Gastroenterology

Gastroenterology

Lab Invest

Biophys J

Gastroenterology

Lancet

Am J Gastroenterol

Gastroenterology

Gastroenterology

Gastroenterology

Gastroenterology

Gastroenterology

Gastroenterology

Am J Gastroenterol

Am J Gastroenterol

Gastroenterology

Blood

Immunol Today

Gastroenterology

J Invest Dermatol

Lancet

J Gastrointest Surg

Gastroenterology

J Gastrointest Surg

Immunity

Gastroenterology

J Hepatol

Intestinal mucosal barrier function in health and disease

Nat Rev Immunol

The inner of the two Muc2 mucin-dependent mucus layers in colon is devoid of bacteria

Proc Natl Acad Sci U S A

Physiological measurements of luminal stirring in the dog and human small bowel

J Clin Invest

Functional properties of the paracellular pathway in some leaky epithelia

J Exp Biol

Tight junction pore and leak pathways: a dynamic duo

Annu Rev Physiol

Epithelial barriers in homeostasis and disease

Annu Rev Pathol

Epithelial tight junctions in intestinal inflammation

Ann N Y Acad Sci

Physiology and function of the tight junction

Cold Spring Harb Perspect Biol

Claudins and epithelial paracellular transport

Annu Rev Physiol

Increases in guinea pig small intestinal transepithelial resistance induced by osmotic loads are accompanied by rapid alterations in absorptive-cell tight-junction structure

J Cell Biol

Effects of cytochalasin D on occluding junctions of intestinal absorptive cells: further evidence that the cytoskeleton may influence paracellular permeability and junctional charge selectivity

J Cell Biol

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

J Clin Invest

Effect of glucose on passive transport of extracellular probes across the rat small intestinal epithelium in vivo

Gastroenterology

Interferon-gamma selectively increases epithelial permeability to large molecules by activating different populations of paracellular pores

J Cell Sci

Functional modeling of tight junctions in intestinal cell monolayers using polyethylene glycol oligomers

Am J Physiol Cell Physiol

The density of small tight junction pores varies among cell types and is increased by expression of claudin-2

J Cell Sci

Claudin-2 expression induces cation-selective channels in tight junctions of epithelial cells

J Cell Sci

Claudin-2, a component of the tight junction, forms a paracellular water channel

J Cell Sci

Advances in translational science
Intestinal Permeability Defects: Is It Time to Treat?