enteroendocrine cells ͉ gastrointestinal chemosensation ͉ glucose sensor ͉ incretin G lucagon-like peptide-1 (GLP-1) and glucose-dependent insulinotropic polypeptide (GIP) are incretins, peptide hormones secreted from enteroendocrine L and K cells, respectively, that augment insulin secretion after oral intake of glucose (1). How carbohydrates in the gut lumen elicit the release of GLP-1 from L cells and GIP from K cells is unknown (2). Because i.v. glucose administration does not induce secretion of GLP-1 (3) it appears that glucose within the lumen of the gut acts on the luminal surface to stimulate secretion. Thus, we sought to determine what glucose-sensing mechanism in the gut lumen might underlie this L cell response.One mechanism for sensing glucose is by sweet taste receptors in taste receptor cells of the lingual epithelium (4). Sweet compounds bind to and activate specific G protein coupled receptors that couple through the G protein gustducin (5) to specific second messenger cascades (4, 6). Two type 1 taste G protein coupled receptors (T1Rs) heterodimerize to form the T1R2ϩT1R3 sweet taste receptor (7-11). Key elements of the taste transduction pathways are the ␣, , and ␥ subunits of gustducin (␣-gustducin, G 3 , and G␥ 13 ) (5, 12), phospholipase C2 (PLC2) (13), and transient receptor potential channel type M5 (14), a Ca 2ϩ -activated cation channel (15-17). ␣-Gustducin has been detected in brush cells of the stomach, duodenum, and pancreatic ducts in rat (18, 19), T1R2 and T1R3 are present in rodent gut and the enteroendocrine STC-1 cell line (20), and ␣-gustducin and GLP-1 are present in enteroendocrine cells of the human colon (21). However, the functional significance of expression of taste signaling elements in cells of the gastrointestinal (GI) tract had been unclear. Here, we present data that indicate that T1R3 and gustducin have a role in glucosemediated incretin release and may serve as the previously unknown gut lumen glucose sensor. ResultsWe examined L cells of the gut for the presence of taste receptors and elements of taste transduction pathways. In human duodenal biopsy sections ␣-gustducin was detected by immunofluorescence (
The intestinal epithelium forms an essential barrier between a host and its microbiota. Protozoa and helminths are members of the gut microbiota of mammals, including humans, yet the many ways that gut epithelial cells orchestrate responses to these eukaryotes remain unclear. Here we show that tuft cells, which are taste-chemosensory epithelial cells, accumulate during parasite colonization and infection. Disruption of chemosensory signaling through the loss of TRMP5 abrogates the expansion of tuft cells, goblet cells, eosinophils, and type 2 innate lymphoid cells during parasite colonization. Tuft cells are the primary source of the parasite-induced cytokine interleukin-25, which indirectly induces tuft cell expansion by promoting interleukin-13 production by innate lymphoid cells. Our results identify intestinal tuft cells as critical sentinels in the gut epithelium that promote type 2 immunity in response to intestinal parasites.
Dietary sugars are transported from the intestinal lumen into absorptive enterocytes by the sodium-dependent glucose transporter isoform 1 (SGLT1). Regulation of this protein is important for the provision of glucose to the body and avoidance of intestinal malabsorption. Although expression of SGLT1 is regulated by luminal monosaccharides, the luminal glucose sensor mediating this process was unknown. Here, we show that the sweet taste receptor subunit T1R3 and the taste G protein gustducin, expressed in enteroendocrine cells, underlie intestinal sugar sensing and regulation of SGLT1 mRNA and protein. Dietary sugar and artificial sweeteners increased SGLT1 mRNA and protein expression, and glucose absorptive capacity in wild-type mice, but not in knockout mice lacking T1R3 or ␣-gustducin. Artificial sweeteners, acting on sweet taste receptors expressed on enteroendocrine GLUTag cells, stimulated secretion of gut hormones implicated in SGLT1 upregulation. Gut-expressed taste signaling elements involved in regulating SGLT1 expression could provide novel therapeutic targets for modulating the gut's capacity to absorb sugars, with implications for the prevention and/or treatment of malabsorption syndromes and diet-related disorders including diabetes and obesity.carbohydrate absorption ͉ gastrointestinal chemosensation ͉ glucose sensor ͉ glucose uptake T o date, the only identified sugar sensors in the mammalian gastrointestinal tract are those involved in taste transduction (1). Although the gut epithelium senses luminal sugars and modulates its glucose absorptive capacity accordingly, the nature of the sugar-sensing molecule(s) and downstream events remain unknown. Several studies have shown that in many species expression of the intestinal sodium-dependent glucose transporter 1 (SGLT1) is directly regulated by monosaccharides in the lumen of the gut independently of metabolism and appears to involve a G protein-linked second messenger pathway (2-6). Furthermore, the addition of membrane-impermeable glucose analogues to the lumen of the intestine stimulates SGLT1 expression, implying that a glucose sensor on luminal membranes is involved (6).In taste cells, the detection of sugars and sweeteners depends on T1R2ϩT1R3, a heterodimer of type 1 taste receptor subunits (T1Rs) (7,8). The taste receptor cells of the anterior tongue that express T1R2ϩT1R3 typically also express gustducin, a transducin-like heterotrimeric G protein (9). Gustducin's ␣-subunit (G␣ gust ) has been detected in brush cells of the rat stomach, duodenum, and pancreatic ducts (10). G␣ gust and bitter-responsive type 2 taste receptors (T2Rs) are expressed in mouse intestinal endocrine cells and in the murine enteroendocrine cell line STC-1 (11).We reported previously that T1R taste receptors and G␣ gust are expressed in the mouse small intestinal epithelium and proposed that they function as luminal sugar sensors to control SGLT1 expression in response to dietary sugar (12). Here, we provide three lines of evidence in favor of T1R taste receptors an...
Bitter taste receptors (T2Rs) in the human airway detect harmful compounds, including secreted bacterial products. Here, using human primary sinonasal air-liquid interface cultures and tissue explants, we determined that activation of a subset of airway T2Rs expressed in nasal solitary chemosensory cells activates a calcium wave that propagates through gap junctions to the surrounding respiratory epithelial cells. The T2R-dependent calcium wave stimulated robust secretion of antimicrobial peptides into the mucus that was capable of killing a variety of respiratory pathogens. Furthermore, sweet taste receptor (T1R2/3) activation suppressed T2R-mediated antimicrobial peptide secretion, suggesting that T1R2/3-mediated inhibition of T2Rs prevents full antimicrobial peptide release during times of relative health. In contrast, during acute bacterial infection, T1R2/3 is likely deactivated in response to bacterial consumption of airway surface liquid glucose, alleviating T2R inhibition and resulting in antimicrobial peptide secretion. We found that patients with chronic rhinosinusitis have elevated glucose concentrations in their nasal secretions, and other reports have shown that patients with hyperglycemia likewise have elevated nasal glucose levels. These data suggest that increased glucose in respiratory secretions in pathologic states, such as chronic rhinosinusitis or hyperglycemia, promotes tonic activation of T1R2/3 and suppresses T2R-mediated innate defense. Furthermore, targeting T1R2/3-dependent suppression of T2Rs may have therapeutic potential for upper respiratory tract infections.
The tastes of sugars (sweet) and glutamate (umami) are thought to be detected by T1r receptors expressed in taste cells. Molecular genetics and heterologous expression implicate T1r2 plus T1r3 as a sweet-responsive receptor,and T1r1 plus T1r3,as well as a truncated form of the type 4 metabotropic glutamate receptor (taste-mGluR4),as umami-responsive receptors. Here,we show that mice lacking T1r3 showed no preference for artificial sweeteners and had diminished but not abolished behavioral and nerve responses to sugars and umami compounds. These results indicate that T1r3-independent sweet- and umami-responsive receptors and/or pathways exist in taste cells.
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