Feeding-dependent activation of enteric cells and sensory neurons by lymphatic fluid: evidence for a neurolymphocrine system

Poole, Daniel P.; Lee, Mike; Tso, Patrick; Bunnett, Nigel W.; Yo, Sek Jin; Lieu, Tina Marie; Shiu, Amy L.; Wang, Jen-Chywan; Nomura, Daniel K.; Aponte, Gregory W.

doi:10.1152/ajpgi.00433.2013

Cited by 12 publications

(22 citation statements)

References 68 publications

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“…Extrinsic afferent nerves originating in the nodose ganglia densely innervate the antrum and duodenal lamina propria [55] and also in the lumen of lymphatic lacteals [56]. Williams et al recently demonstrated that GLP-1 receptor-expressing nodose neurons were mostly stretch sensors innervating the stomach, whereas the GPR65-expressing population innervated duodenal villi and responded to luminal nutrients [57**].…”

Section: Tuft Cellsmentioning

confidence: 99%

“…Williams et al recently demonstrated that GLP-1 receptor-expressing nodose neurons were mostly stretch sensors innervating the stomach, whereas the GPR65-expressing population innervated duodenal villi and responded to luminal nutrients [57**]. In addition to specific receptors associated with EEC-released hormones such as 5-HT, CCK, and GLP-2, afferent neurons possess nutrient receptors, including LPA5, mGluRs, and FFA3 [56;58;59]. Sensory nerves in the subepithelial space likely receive EEC signals and directly detect absorbed nutrients.…”

Section: Tuft Cellsmentioning

confidence: 99%

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Luminal chemosensing in the gastroduodenal mucosa

Kaji

Kaunitz

2017

Current Opinion in Gastroenterology

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Purpose of review We report recently published knowledge regarding gut chemosensory mechanisms focusing on nutrient-sensing G protein-coupled receptors (GPCRs) expressed on gut enteroendocrine cells (EECs), tuft cells, and in afferent nerves in the gastroduodenal mucosa and submucosa. Recent findings Gene profiling of EECs and tuft cells have revealed expression of a variety of nutrient-sensing GPCRs. The density of EEC and tuft cells is altered by luminal environmental changes that may occur following bypass surgery or in the presence of mucosal inflammation. Some EECs and tuft cells are directly linked to sensory nerves in the subepithelial space. Vagal afferent neurons that innervate the intestinal villi express nutrient receptors, contributing to the regulation of duodenal anion secretion in response to luminal nutrients. Nutrients are also absorbed via specific epithelial transporters. Summary Gastric and duodenal epithelial cells are continually exposed to submolar concentrations of nutrients that activate GPCRs expressed on EECs, tuft cells, and submucosal afferent nerves and are also absorbed through specific transporters, regulating epithelial cell proliferation, gastrointestinal (GI) physiological function, and metabolism. The chemical coding and distribution of EECs and tuft cells are keys to the development of GPCR-targeted therapies.

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Section: Tuft Cellsmentioning

confidence: 99%

Section: Tuft Cellsmentioning

confidence: 99%

Luminal chemosensing in the gastroduodenal mucosa

Kaji

Kaunitz

2017

Current Opinion in Gastroenterology

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“…Interestingly, LPA5 (GPR92) is expressed almost exclusively in microglia [ 379 , 380 ] and is barely detectable in astrocytes [ 381 , 382 ]. LPA5 is also expressed by peripheral neurons and their nerves [ 65 , 383 ] as well as by neurons in the spinal cord [ 65 ]. However, we are aware of no publications regarding LPA5 expression in neurons located in other regions of the CNS.…”

Section: Lysophosphatidic Acid Receptormentioning

confidence: 99%

Pharmacological Tools to Activate Microglia and their Possible use to Study Neural Network Patho-physiology

Peña‐Ortega

2017

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BackgroundMicroglia are the resident immunocompetent cells of the CNS and also constitute a unique cell type that contributes to neural network homeostasis and function. Understanding microglia cell-signaling not only will reveal their diverse functions but also will help to identify pharmacological and non-pharmacological tools to modulate the activity of these cells.MethodsWe undertook a search of bibliographic databases for peer-reviewed research literature to identify microglial activators and their cell-specificity. We also looked for their effects on neural network function and dysfunction.ResultsWe identified several pharmacological targets to modulate microglial function, which are more or less specific (with the proper control experiments). We also identified pharmacological targets that would require the development of new potent and specific modulators. We identified a wealth of evidence about the participation of microglia in neural network function and their alterations in pathological conditions.ConclusionThe identification of specific microglia-activating signals provides experimental tools to modulate the activity of this heterogeneous cell type in order to evaluate its impact on other components of the nervous system, and it also helps to identify therapeutic approaches to ease some pathological conditions related to microglial dysfunction.

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“…Recently, Poole et al [11 •• ] identified LPA5 expression on sensory nerves in the jejunal mucosa, in submucosal and myenteric plexuses, and in primary afferent neurons of dorsal root ganglia of mouse, rat, and human. These authors suggested a novel pathway where molecules, including peptides, in the mesenteric lymphatic fluid (MLF) directly activate LPA5 receptors on sensory nerves.…”

Section: Peptide and Amino Acid Sensingmentioning

confidence: 99%

“…These authors suggested a novel pathway where molecules, including peptides, in the mesenteric lymphatic fluid (MLF) directly activate LPA5 receptors on sensory nerves. MLF may provide signals to comprise a ‘neurolymphocrine’ system in which nerve fibers of the lacteal are part of a visceral sensory system that may function separately from those of the vagus, perhaps through primary spinal afferent nerves [11 •• ]. Irrespective of this, peptone-stimulated GLP-1 release was not reduced in GPR92/93 knockout mice [7 •• ], suggesting that this alternative sensory pathway is less important, than the canonical sensing mechanism, at least in mice.…”

Section: Peptide and Amino Acid Sensingmentioning

confidence: 99%

Duodenal luminal nutrient sensing

Rønnestad

Akiba

Kaji

et al. 2014

Current Opinion in Pharmacology

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The gastrointestinal mucosa is exposed to numerous chemical substances and microorganisms, including macronutrients, micronutrients, bacteria, endogenous ions, and proteins. The regulation of mucosal protection, digestion, absorption and motility is signaled in part by luminal solutes. Therefore, luminal chemosensing is an important mechanism enabling the mucosa to monitor luminal conditions, such as pH, ion concentrations, nutrient quantity, and microflora. The duodenal mucosa shares luminal nutrient receptors with lingual taste receptors in order to detect the five basic tastes, in addition to essential nutrients, and unwanted chemicals. The recent ‘de-orphanization’ of nutrient sensing G protein-coupled receptors provides an essential component of the mechanism by which the mucosa senses luminal nutrients. In this review, we will update the mechanisms of and underlying physiological and pathological roles in luminal nutrient sensing, with a main focus on the duodenal mucosa.

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Feeding-dependent activation of enteric cells and sensory neurons by lymphatic fluid: evidence for a neurolymphocrine system

Cited by 12 publications

References 68 publications

Luminal chemosensing in the gastroduodenal mucosa

Luminal chemosensing in the gastroduodenal mucosa

Pharmacological Tools to Activate Microglia and their Possible use to Study Neural Network Patho-physiology

Duodenal luminal nutrient sensing

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