{"PubmedArticle":{"MedlineCitation":{"@attributes":{"Status":"MEDLINE","Owner":"NLM","IndexingMethod":"Automated"},"PMID":{"@attributes":{"Version":"1"},"@text":"37358764"},"DateCompleted":{"Year":"2023","Month":"07","Day":"31"},"DateRevised":{"Year":"2023","Month":"08","Day":"29"},"Article":{"@attributes":{"PubModel":"Print-Electronic"},"Journal":{"ISSN":{"@attributes":{"IssnType":"Electronic"},"@text":"1573-4978"},"JournalIssue":{"@attributes":{"CitedMedium":"Internet"},"Volume":"50","Issue":"8","PubDate":{"Year":"2023","Month":"Aug"}},"Title":"Molecular biology reports","ISOAbbreviation":"Mol Biol Rep"},"ArticleTitle":"The role of GLUT2 in glucose metabolism in multiple organs and tissues.","Pagination":{"StartPage":"6963","EndPage":"6974","MedlinePgn":"6963-6974"},"ELocationID":[{"@attributes":{"EIdType":"doi","ValidYN":"Y"},"@text":"10.1007\/s11033-023-08535-w"}],"Abstract":{"AbstractText":["The glucose transporter family has an important role in the initial stage of glucose metabolism; Glucose transporters 2 (GLUTs, encoded by the solute carrier family 2, SLC2A genes) is the major glucose transporter in \u03b2-cells of pancreatic islets and hepatocytes but is also expressed in the small intestine, kidneys, and central nervous system; GLUT2 has a relatively low affinity to glucose. Under physiological conditions, GLUT2 transports glucose into cells and allows the glucose concentration to reach balance on the bilateral sides of the cellular membrane; Variation of GLUT2 is associated with various endocrine and metabolic disorders; In this study, we discussed the role of GLUT2 in participating in glucose metabolism and regulation in multiple organs and tissues and its effects on maintaining glucose homeostasis."],"CopyrightInformation":"\u00a9 2023. The Author(s)."},"AuthorList":{"@attributes":{"CompleteYN":"Y"},"Author":[{"@attributes":{"ValidYN":"Y"},"LastName":"Sun","ForeName":"Bo","Initials":"B","AffiliationInfo":[{"Affiliation":"Endorcrine and Metabolism Department, Lanzhou University Second Hospital, Lanzhou, 730000, China."},{"Affiliation":"Department of Infantile Endocrine Genetic Metabolism, Gansu Maternal and child Health Care Hospital, Lanzhou, 730000, China."}]},{"@attributes":{"ValidYN":"Y"},"LastName":"Chen","ForeName":"Hui","Initials":"H","Identifier":[{"@attributes":{"Source":"ORCID"},"@text":"0000-0001-5717-1503"}],"AffiliationInfo":[{"Affiliation":"Endorcrine and Metabolism Department, Lanzhou University Second Hospital, Lanzhou, 730000, China. chenhui@lzu.edu.com."}]},{"@attributes":{"ValidYN":"Y"},"LastName":"Xue","ForeName":"Jisu","Initials":"J","AffiliationInfo":[{"Affiliation":"EndEnorcrine and Metabolism Department, Shenzhen Bao 'an People's Hospital (Group), Shenzhen, 518100, China."}]},{"@attributes":{"ValidYN":"Y"},"LastName":"Li","ForeName":"Peiwu","Initials":"P","AffiliationInfo":[{"Affiliation":"Key Laboratory of Emergency Medicine, Lanzhou University Second Hospital, Lanzhou, 730000, China."}]},{"@attributes":{"ValidYN":"Y"},"LastName":"Fu","ForeName":"Xu","Initials":"X","AffiliationInfo":[{"Affiliation":"Key Laboratory of Emergency Medicine, Lanzhou University Second Hospital, Lanzhou, 730000, China."}]}]},"Language":["eng"],"PublicationTypeList":{"PublicationType":[{"@attributes":{"UI":"D016428"},"@text":"Journal Article"},{"@attributes":{"UI":"D016454"},"@text":"Review"}]},"ArticleDate":[{"@attributes":{"DateType":"Electronic"},"Year":"2023","Month":"06","Day":"26"}]},"MedlineJournalInfo":{"Country":"Netherlands","MedlineTA":"Mol Biol Rep","NlmUniqueID":"0403234","ISSNLinking":"0301-4851"},"ChemicalList":{"Chemical":[{"RegistryNumber":"IY9XDZ35W2","NameOfSubstance":{"@attributes":{"UI":"D005947"},"@text":"Glucose"}},{"RegistryNumber":"0","NameOfSubstance":{"@attributes":{"UI":"D051246"},"@text":"Glucose Transport Proteins, Facilitative"}},{"RegistryNumber":"0","NameOfSubstance":{"@attributes":{"UI":"D051273"},"@text":"Glucose Transporter Type 2"}}]},"CitationSubset":["IM"],"MeshHeadingList":{"MeshHeading":[{"DescriptorName":{"@attributes":{"UI":"D005947","MajorTopicYN":"Y"},"@text":"Glucose"},"QualifierName":[{"@attributes":{"UI":"Q000378","MajorTopicYN":"N"},"@text":"metabolism"}]},{"DescriptorName":{"@attributes":{"UI":"D007515","MajorTopicYN":"Y"},"@text":"Islets of Langerhans"},"QualifierName":[{"@attributes":{"UI":"Q000378","MajorTopicYN":"N"},"@text":"metabolism"}]},{"DescriptorName":{"@attributes":{"UI":"D051246","MajorTopicYN":"N"},"@text":"Glucose Transport Proteins, Facilitative"},"QualifierName":[{"@attributes":{"UI":"Q000235","MajorTopicYN":"N"},"@text":"genetics"},{"@attributes":{"UI":"Q000378","MajorTopicYN":"N"},"@text":"metabolism"}]},{"DescriptorName":{"@attributes":{"UI":"D022781","MajorTopicYN":"N"},"@text":"Hepatocytes"},"QualifierName":[{"@attributes":{"UI":"Q000378","MajorTopicYN":"N"},"@text":"metabolism"}]},{"DescriptorName":{"@attributes":{"UI":"D001692","MajorTopicYN":"N"},"@text":"Biological Transport"}},{"DescriptorName":{"@attributes":{"UI":"D051273","MajorTopicYN":"N"},"@text":"Glucose Transporter Type 2"},"QualifierName":[{"@attributes":{"UI":"Q000235","MajorTopicYN":"N"},"@text":"genetics"},{"@attributes":{"UI":"Q000378","MajorTopicYN":"N"},"@text":"metabolism"}]}]},"KeywordList":[{"@attributes":{"Owner":"NOTNLM"},"Keyword":[{"@attributes":{"MajorTopicYN":"N"},"@text":"Blood glucose homeostasis"},{"@attributes":{"MajorTopicYN":"N"},"@text":"Blood glucose regulation"},{"@attributes":{"MajorTopicYN":"N"},"@text":"GLUT2"},{"@attributes":{"MajorTopicYN":"N"},"@text":"Glucose metabolism"}]}],"CoiStatement":"Bo Sun, Hui Chen, Jisu Xue, Feiwu Li, Xu Fu declare that they have no competing interests."},"PubmedData":{"History":{"PubMedPubDate":[{"@attributes":{"PubStatus":"received"},"Year":"2022","Month":"12","Day":"12"},{"@attributes":{"PubStatus":"accepted"},"Year":"2023","Month":"5","Day":"17"},{"@attributes":{"PubStatus":"medline"},"Year":"2023","Month":"7","Day":"31","Hour":"11","Minute":"42"},{"@attributes":{"PubStatus":"pubmed"},"Year":"2023","Month":"6","Day":"26","Hour":"13","Minute":"7"},{"@attributes":{"PubStatus":"entrez"},"Year":"2023","Month":"6","Day":"26","Hour":"11","Minute":"14"},{"@attributes":{"PubStatus":"pmc-release"},"Year":"2023","Month":"6","Day":"26"}]},"PublicationStatus":"ppublish","ArticleIdList":{"ArticleId":[{"@attributes":{"IdType":"pubmed"},"@text":"37358764"},{"@attributes":{"IdType":"pmc"},"@text":"PMC10374759"},{"@attributes":{"IdType":"doi"},"@text":"10.1007\/s11033-023-08535-w"},{"@attributes":{"IdType":"pii"},"@text":"10.1007\/s11033-023-08535-w"}]},"ReferenceList":[{"Reference":[{"Citation":"Sala-Rabanal M, Hirayama BA, Ghezzi C, Liu J, Huang SC, Kepe V, Koepsell H, Yu A, Powell DR, Thorens B, Wright EM, Barrio JR. Revisiting the physiological roles of SGLTs and GLUTs using positron emission tomography in mice. J Physiol. 2016;594:4425\u20134438. doi: 10.1113\/jp271904.","ArticleIdList":{"ArticleId":[{"@attributes":{"IdType":"doi"},"@text":"10.1113\/jp271904"},{"@attributes":{"IdType":"pmc"},"@text":"PMC4967756"},{"@attributes":{"IdType":"pubmed"},"@text":"27018980"}]}},{"Citation":"Thorens B, Sarkar HK, Kaback HR, Lodish HF. Cloning and functional expression in bacteria of a novel glucose transporter present in liver, intestine, kidney, and beta-pancreatic islet cells. Cell. 1988;55:281\u2013290. doi: 10.1016\/0092-8674(88)90051-7.","ArticleIdList":{"ArticleId":[{"@attributes":{"IdType":"doi"},"@text":"10.1016\/0092-8674(88)90051-7"},{"@attributes":{"IdType":"pubmed"},"@text":"3048704"}]}},{"Citation":"Fagerberg L, Hallstr\u00f6m BM, Oksvold P, Kampf C, Djureinovic D, Odeberg J, Habuka M, Tahmasebpoor S, Danielsson A, Edlund K, Asplund A, Sj\u00f6stedt E, Lundberg E, Szigyarto CA, Skogs M, Takanen JO, Berling H, Tegel H, Mulder J, Nilsson P, Schwenk JM, Lindskog C, Danielsson F, Mardinoglu A, Sivertsson A, von Feilitzen K, Forsberg M, Zwahlen M, Olsson I, Navani S, Huss M, Nielsen J, Ponten F, Uhl\u00e9n M. Analysis of the human tissue-specific expression by genome-wide integration of transcriptomics and antibody-based proteomics. Mol Cell proteomics: MCP. 2014;13:397\u2013406. doi: 10.1074\/mcp.M113.035600.","ArticleIdList":{"ArticleId":[{"@attributes":{"IdType":"doi"},"@text":"10.1074\/mcp.M113.035600"},{"@attributes":{"IdType":"pmc"},"@text":"PMC3916642"},{"@attributes":{"IdType":"pubmed"},"@text":"24309898"}]}},{"Citation":"Mueckler M, Thorens B. The SLC2 (GLUT) family of membrane transporters. Mol Asp Med. 2013;34:121\u2013138. doi: 10.1016\/j.mam.2012.07.001.","ArticleIdList":{"ArticleId":[{"@attributes":{"IdType":"doi"},"@text":"10.1016\/j.mam.2012.07.001"},{"@attributes":{"IdType":"pmc"},"@text":"PMC4104978"},{"@attributes":{"IdType":"pubmed"},"@text":"23506862"}]}},{"Citation":"Uldry M, Ibberson M, Hosokawa M, Thorens B. GLUT2 is a high affinity glucosamine transporter. FEBS Lett. 2002;524:199\u2013203. doi: 10.1016\/s0014-5793(02)03058-2.","ArticleIdList":{"ArticleId":[{"@attributes":{"IdType":"doi"},"@text":"10.1016\/s0014-5793(02)03058-2"},{"@attributes":{"IdType":"pubmed"},"@text":"12135767"}]}},{"Citation":"Bae JS, Kim TH, Kim MY, Park JM, Ahn YH. Transcriptional regulation of glucose sensors in pancreatic \u03b2-cells and liver: an update. Sensors. 2010;10:5031\u20135053. doi: 10.3390\/s100505031.","ArticleIdList":{"ArticleId":[{"@attributes":{"IdType":"doi"},"@text":"10.3390\/s100505031"},{"@attributes":{"IdType":"pmc"},"@text":"PMC3292162"},{"@attributes":{"IdType":"pubmed"},"@text":"22399922"}]}},{"Citation":"Lin CW, Yan F, Shimamura S, Barg S, Shyng SL. Membrane phosphoinositides control insulin secretion through their effects on ATP-sensitive K+ channel activity. Diabetes. 2005;54:2852\u20132858. doi: 10.2337\/diabetes.54.10.2852.","ArticleIdList":{"ArticleId":[{"@attributes":{"IdType":"doi"},"@text":"10.2337\/diabetes.54.10.2852"},{"@attributes":{"IdType":"pmc"},"@text":"PMC1350465"},{"@attributes":{"IdType":"pubmed"},"@text":"16186385"}]}},{"Citation":"Yildirim V, Bertram R. Calcium oscillation frequency-sensitive gene regulation and homeostatic compensation in pancreatic \u03b2-Cells. Bull Math Biol. 2017;79:1295\u20131324. doi: 10.1007\/s11538-017-0286-1.","ArticleIdList":{"ArticleId":[{"@attributes":{"IdType":"doi"},"@text":"10.1007\/s11538-017-0286-1"},{"@attributes":{"IdType":"pubmed"},"@text":"28497293"}]}},{"Citation":"Schmitt CC, Aranias T, Viel T, Chateau D, Le Gall M, Waligora-Dupriet AJ, Melchior C, Rouxel O, Kapel N, Gourcerol G, Tavitian B, Lehuen A, Brot-Laroche E, Leturque A, Serradas P, Grosfeld A. Intestinal invalidation of the glucose transporter GLUT2 delays tissue distribution of glucose and reveals an unexpected role in gut homeostasis. Mol metabolism. 2017;6:61\u201372. doi: 10.1016\/j.molmet.2016.10.008.","ArticleIdList":{"ArticleId":[{"@attributes":{"IdType":"doi"},"@text":"10.1016\/j.molmet.2016.10.008"},{"@attributes":{"IdType":"pmc"},"@text":"PMC5220280"},{"@attributes":{"IdType":"pubmed"},"@text":"28123938"}]}},{"Citation":"Ghezzi C, Loo DDF, Wright EM. Physiology of renal glucose handling via SGLT1, SGLT2 and GLUT2. Diabetologia. 2018;61:2087\u20132097. doi: 10.1007\/s00125-018-4656-5.","ArticleIdList":{"ArticleId":[{"@attributes":{"IdType":"doi"},"@text":"10.1007\/s00125-018-4656-5"},{"@attributes":{"IdType":"pmc"},"@text":"PMC6133168"},{"@attributes":{"IdType":"pubmed"},"@text":"30132032"}]}},{"Citation":"He Y, Sun L, Yu H, Meng Q. Expression of glucose transporter 2 in liver tissue in patients with hepatogenous diabetes and its significance. J Clin Hepatol. 2017;33:512\u2013515."},{"Citation":"Gremlich S, Roduit R, Thorens B. Dexamethasone induces posttranslational degradation of GLUT2 and inhibition of insulin secretion in isolated pancreatic beta cells. Comparison with the effects of fatty acids. J Biol Chem. 1997;272:3216\u20133222. doi: 10.1074\/jbc.272.6.3216.","ArticleIdList":{"ArticleId":[{"@attributes":{"IdType":"doi"},"@text":"10.1074\/jbc.272.6.3216"},{"@attributes":{"IdType":"pubmed"},"@text":"9013557"}]}},{"Citation":"Burcelin R, Thorens B. Evidence that extrapancreatic GLUT2-dependent glucose sensors control glucagon secretion. Diabetes. 2001;50:1282\u20131289. doi: 10.2337\/diabetes.50.6.1282.","ArticleIdList":{"ArticleId":[{"@attributes":{"IdType":"doi"},"@text":"10.2337\/diabetes.50.6.1282"},{"@attributes":{"IdType":"pubmed"},"@text":"11375328"}]}},{"Citation":"Bady I, Marty N, Dallaporta M, Emery M, Gyger J, Tarussio D, Foretz M, Thorens B. Evidence from glut2-null mice that glucose is a critical physiological regulator of feeding. Diabetes. 2006;55:988\u2013995. doi: 10.2337\/diabetes.55.04.06.db05-1386.","ArticleIdList":{"ArticleId":[{"@attributes":{"IdType":"doi"},"@text":"10.2337\/diabetes.55.04.06.db05-1386"},{"@attributes":{"IdType":"pubmed"},"@text":"16567520"}]}},{"Citation":"Taborsky GJ, Jr, Mundinger TO. Minireview: the role of the autonomic nervous system in mediating the glucagon response to hypoglycemia. Endocrinology. 2012;153:1055\u20131062. doi: 10.1210\/en.2011-2040.","ArticleIdList":{"ArticleId":[{"@attributes":{"IdType":"doi"},"@text":"10.1210\/en.2011-2040"},{"@attributes":{"IdType":"pmc"},"@text":"PMC3384078"},{"@attributes":{"IdType":"pubmed"},"@text":"22315452"}]}},{"Citation":"Guillam MT, H\u00fcmmler E, Schaerer E, Yeh JI, Birnbaum MJ, Beermann F, Schmidt A, D\u00e9riaz N, Thorens B. Early diabetes and abnormal postnatal pancreatic islet development in mice lacking Glut-2. Nat Genet. 1997;17:327\u2013330. doi: 10.1038\/ng1197-327.","ArticleIdList":{"ArticleId":[{"@attributes":{"IdType":"doi"},"@text":"10.1038\/ng1197-327"},{"@attributes":{"IdType":"pubmed"},"@text":"9354799"}]}},{"Citation":"Thorens B, Guillam MT, Beermann F, Burcelin R, Jaquet M. Transgenic reexpression of GLUT1 or GLUT2 in pancreatic beta cells rescues GLUT2-null mice from early death and restores normal glucose-stimulated insulin secretion. J Biol Chem. 2000;275:23751\u201323758. doi: 10.1074\/jbc.M002908200.","ArticleIdList":{"ArticleId":[{"@attributes":{"IdType":"doi"},"@text":"10.1074\/jbc.M002908200"},{"@attributes":{"IdType":"pubmed"},"@text":"10823833"}]}},{"Citation":"Wang X, Gao H, Wu W, Xie E, Yu Y, He X, Li J, Zheng W, Wang X, Cao X, Meng Z, Chen L, Min J, Wang F. The zinc transporter Slc39a5 controls glucose sensing and insulin secretion in pancreatic \u03b2-cells via Sirt1- and Pgc-1\u03b1-mediated regulation of Glut2. Protein Cell. 2019;10:436\u2013449. doi: 10.1007\/s13238-018-0580-1.","ArticleIdList":{"ArticleId":[{"@attributes":{"IdType":"doi"},"@text":"10.1007\/s13238-018-0580-1"},{"@attributes":{"IdType":"pmc"},"@text":"PMC6538592"},{"@attributes":{"IdType":"pubmed"},"@text":"30324491"}]}},{"Citation":"Ohtsubo K, Takamatsu S, Gao C, Korekane H, Kurosawa TM, Taniguchi N. N-Glycosylation modulates the membrane sub-domain distribution and activity of glucose transporter 2 in pancreatic beta cells. Biochem Biophys Res Commun. 2013;434:346\u2013351. doi: 10.1016\/j.bbrc.2013.03.076.","ArticleIdList":{"ArticleId":[{"@attributes":{"IdType":"doi"},"@text":"10.1016\/j.bbrc.2013.03.076"},{"@attributes":{"IdType":"pubmed"},"@text":"23548572"}]}},{"Citation":"Ohtsubo K, Chen MZ, Olefsky JM, Marth JD. Pathway to diabetes through attenuation of pancreatic beta cell glycosylation and glucose transport. Nat Med. 2011;17:1067\u20131075. doi: 10.1038\/nm.2414.","ArticleIdList":{"ArticleId":[{"@attributes":{"IdType":"doi"},"@text":"10.1038\/nm.2414"},{"@attributes":{"IdType":"pmc"},"@text":"PMC3888087"},{"@attributes":{"IdType":"pubmed"},"@text":"21841783"}]}},{"Citation":"Ohtsubo K, Takamatsu S, Minowa MT, Yoshida A, Takeuchi M, Marth JD. Dietary and genetic control of glucose transporter 2 glycosylation promotes insulin secretion in suppressing diabetes. Cell. 2005;123:1307\u20131321. doi: 10.1016\/j.cell.2005.09.041.","ArticleIdList":{"ArticleId":[{"@attributes":{"IdType":"doi"},"@text":"10.1016\/j.cell.2005.09.041"},{"@attributes":{"IdType":"pubmed"},"@text":"16377570"}]}},{"Citation":"Feng L (2018) miR-27a promotes insulin secretion in obesity Induced. Insulin Resistance Via Depressing the Expression of FoxO1. https:\/\/kns.cnki.net\/kcms2\/article\/abstractv=3uoqIhG8C475KOm_zrgu4lQARvep2SAkZIGkvqfmUZglMdu7fCR48zMTNhz_He2RRUyPBnoZMFaE1VDm8jBzEE2RUKNEGVaM&amp;uniplatform=NZKPT&amp;src=copy"},{"Citation":"Ruan Y, Lin N, Ma Q, Chen R, Zhang Z, Wen W, Chen H, Sun J. Circulating LncRNAs analysis in patients with type 2 diabetes reveals novel genes influencing glucose metabolism and islet \u03b2-Cell function. Cell Physiol biochem. 2018;46:335\u2013350. doi: 10.1159\/000488434.","ArticleIdList":{"ArticleId":[{"@attributes":{"IdType":"doi"},"@text":"10.1159\/000488434"},{"@attributes":{"IdType":"pubmed"},"@text":"29590649"}]}},{"Citation":"Ding L, Han L, Dube J, Billadeau DD. WASH regulates glucose homeostasis by facilitating Glut2 receptor recycling in pancreatic \u03b2-Cells. Diabetes. 2019;68:377\u2013386. doi: 10.2337\/db18-0189.","ArticleIdList":{"ArticleId":[{"@attributes":{"IdType":"doi"},"@text":"10.2337\/db18-0189"},{"@attributes":{"IdType":"pubmed"},"@text":"30425062"}]}},{"Citation":"Gholami H, Jeddi S, Zadeh-Vakili A, Farrokhfall K, Rouhollah F, Zarkesh M, Ghanbari M, Ghasemi A. Transient congenital hypothyroidism alters gene expression of glucose transporters and impairs glucose sensing apparatus in young and aged offspring rats.\u00a0. Cell physiol biochem. 2017;43:2338\u20132352. doi: 10.1159\/000484386.","ArticleIdList":{"ArticleId":[{"@attributes":{"IdType":"doi"},"@text":"10.1159\/000484386"},{"@attributes":{"IdType":"pubmed"},"@text":"29073628"}]}},{"Citation":"Seyer P, Vallois D, Poitry-Yamate C, Sch\u00fctz F, Metref S, Tarussio D, Maechler P, Staels B, Lanz B, Grueter R, Decaris J, Turner S, da Costa A, Preitner F, Minehira K, Foretz M, Thorens B. Hepatic glucose sensing is required to preserve \u03b2 cell glucose competence. J Clin Investig. 2013;123:1662\u20131676. doi: 10.1172\/jci65538.","ArticleIdList":{"ArticleId":[{"@attributes":{"IdType":"doi"},"@text":"10.1172\/jci65538"},{"@attributes":{"IdType":"pmc"},"@text":"PMC3613916"},{"@attributes":{"IdType":"pubmed"},"@text":"23549084"}]}},{"Citation":"Hosokawa M, Thorens B. Glucose release from GLUT2-null hepatocytes: characterization of a major and a minor pathway. Am J Physiol Endocrinol metabolism. 2002;282:E794\u2013801. doi: 10.1152\/ajpendo.00374.2001.","ArticleIdList":{"ArticleId":[{"@attributes":{"IdType":"doi"},"@text":"10.1152\/ajpendo.00374.2001"},{"@attributes":{"IdType":"pubmed"},"@text":"11882499"}]}},{"Citation":"Dentin R, Denechaud PD, Benhamed F, Girard J, Postic C. Hepatic gene regulation by glucose and polyunsaturated fatty acids: a role for ChREBP. J Nutr. 2006;136:1145\u20131149. doi: 10.1093\/jn\/136.5.1145.","ArticleIdList":{"ArticleId":[{"@attributes":{"IdType":"doi"},"@text":"10.1093\/jn\/136.5.1145"},{"@attributes":{"IdType":"pubmed"},"@text":"16614395"}]}},{"Citation":"Yan Y (2018) The study of Preventative Effects of Estradiol combined with progesterone on streptozotocin-induced diabetes in Ovariectomized. Mice Lan Zhou Da Xue. https:\/\/kns.cnki.net\/kcms2\/article\/abstract?v=3uoqIhG8C475KOm_zrgu4lQARvep2SAkZIGkvqfmUZglMdu7fCR486yZ31DFQgU2hsEhX2AuF4Hi7mybcLjluVmCpxV4q0yX&amp;uniplatform=NZKPT&amp;src=copy","ArticleIdList":{"ArticleId":[{"@attributes":{"IdType":"pmc"},"@text":"PMC6166971"},{"@attributes":{"IdType":"pubmed"},"@text":"30273360"}]}},{"Citation":"Kemp HF, Hundal HS, Taylor PM. Glucose transport correlates with GLUT2 abundance in rat liver during altered thyroid status. Mol Cell Endocrinol. 1997;128:97\u2013102. doi: 10.1016\/s0303-7207(97)04026-4.","ArticleIdList":{"ArticleId":[{"@attributes":{"IdType":"doi"},"@text":"10.1016\/s0303-7207(97)04026-4"},{"@attributes":{"IdType":"pubmed"},"@text":"9140080"}]}},{"Citation":"Kasai D, Adachi T, Deng L, Nagano-Fujii M, Sada K, Ikeda M, Kato N, Ide YH, Shoji I, Hotta H. HCV replication suppresses cellular glucose uptake through down-regulation of cell surface expression of glucose transporters. J Hepatol. 2009;50:883\u2013894. doi: 10.1016\/j.jhep.2008.12.029.","ArticleIdList":{"ArticleId":[{"@attributes":{"IdType":"doi"},"@text":"10.1016\/j.jhep.2008.12.029"},{"@attributes":{"IdType":"pubmed"},"@text":"19303158"}]}},{"Citation":"Pappenheimer JR. On the coupling of membrane digestion with intestinal absorption of sugars and amino acids. Am J Physiol. 1993;265:G409\u2013G417. doi: 10.1152\/ajpgi.1993.265.3.G409.","ArticleIdList":{"ArticleId":[{"@attributes":{"IdType":"doi"},"@text":"10.1152\/ajpgi.1993.265.3.G409"},{"@attributes":{"IdType":"pubmed"},"@text":"8214061"}]}},{"Citation":"Kellett GL, Brot-Laroche E. Apical GLUT2: a major pathway of intestinal sugar absorption. Diabetes. 2005;54:3056\u20133062. doi: 10.2337\/diabetes.54.10.3056.","ArticleIdList":{"ArticleId":[{"@attributes":{"IdType":"doi"},"@text":"10.2337\/diabetes.54.10.3056"},{"@attributes":{"IdType":"pubmed"},"@text":"16186415"}]}},{"Citation":"Kakall ZM, Kavurma MM, Cohen EM, Howe PR, Nedoboy PE, Pilowsky PM. Repetitive hypoglycemia reduces activation of glucose-responsive neurons in C1 and C3 medullary brain regions to subsequent hypoglycemia. Am J Physiol Endocrinol metab. 2019;317:E388\u2013E398. doi: 10.1152\/ajpendo.00051.2019.","ArticleIdList":{"ArticleId":[{"@attributes":{"IdType":"doi"},"@text":"10.1152\/ajpendo.00051.2019"},{"@attributes":{"IdType":"pmc"},"@text":"PMC6732467"},{"@attributes":{"IdType":"pubmed"},"@text":"31013147"}]}},{"Citation":"Mace OJ, Lister N, Morgan E, Shepherd E, Affleck J, Helliwell P, Bronk JR, Kellett GL, Meredith D, Boyd R, Pieri M, Bailey PD, Pettcrew R, Foley D. An energy supply network of nutrient absorption coordinated by calcium and T1R taste receptors in rat small intestine. J Physiol. 2009;587:195\u2013210. doi: 10.1113\/jphysiol.2008.159616.","ArticleIdList":{"ArticleId":[{"@attributes":{"IdType":"doi"},"@text":"10.1113\/jphysiol.2008.159616"},{"@attributes":{"IdType":"pmc"},"@text":"PMC2670033"},{"@attributes":{"IdType":"pubmed"},"@text":"19001049"}]}},{"Citation":"Thaiss CA, Levy M, Grosheva I, Zheng D, Soffer E, Blacher E, Braverman S, Tengeler AC, Barak O, Elazar M, Ben-Zeev R, Lehavi-Regev D, Katz MN, Pevsner-Fischer M, Gertler A, Halpern Z, Harmelin A, Aamar S, Serradas P, Grosfeld A, Shapiro H, Geiger B, Elinav E. Hyperglycemia drives intestinal barrier dysfunction and risk for enteric infection. Science. 2018;359:1376\u20131383. doi: 10.1126\/science.aar3318.","ArticleIdList":{"ArticleId":[{"@attributes":{"IdType":"doi"},"@text":"10.1126\/science.aar3318"},{"@attributes":{"IdType":"pubmed"},"@text":"29519916"}]}},{"Citation":"Tobin V, Le Gall M, Fioramonti X, Stolarczyk E, Blazquez AG, Klein C, Prigent M, Serradas P, Cuif MH, Magnan C, Leturque A, Brot-Laroche E. Insulin internalizes GLUT2 in the enterocytes of healthy but not insulin-resistant mice. Diabetes. 2008;57:555\u2013562. doi: 10.2337\/db07-0928.","ArticleIdList":{"ArticleId":[{"@attributes":{"IdType":"doi"},"@text":"10.2337\/db07-0928"},{"@attributes":{"IdType":"pubmed"},"@text":"18057092"}]}},{"Citation":"Gouyon F, Caillaud L, Carriere V, Klein C, Dalet V, Citadelle D, Kellett GL, Thorens B, Leturque A, Brot-Laroche E. Simple-sugar meals target GLUT2 at enterocyte apical membranes to improve sugar absorption: a study in GLUT2-null mice. J Physiol. 2003;552:823\u2013832. doi: 10.1113\/jphysiol.2003.049247.","ArticleIdList":{"ArticleId":[{"@attributes":{"IdType":"doi"},"@text":"10.1113\/jphysiol.2003.049247"},{"@attributes":{"IdType":"pmc"},"@text":"PMC2343460"},{"@attributes":{"IdType":"pubmed"},"@text":"12937289"}]}},{"Citation":"Monteiro-Sepulveda M, Touch S, Mendes-S\u00e1 C, Andr\u00e9 S, Poitou C, Allatif O, Cotillard A, Fohrer-Ting H, Hubert EL, Remark R, Genser L, Tordjman J, Garbin K, Osinski C, Saut\u00e8s-Fridman C, Leturque A, Cl\u00e9ment K, Brot-Laroche E. Jejunal T cell inflammation in human obesity correlates with decreased enterocyte insulin signaling. Cell Metabol. 2015;22:113\u2013124. doi: 10.1016\/j.cmet.2015.05.020.","ArticleIdList":{"ArticleId":[{"@attributes":{"IdType":"doi"},"@text":"10.1016\/j.cmet.2015.05.020"},{"@attributes":{"IdType":"pubmed"},"@text":"26094890"}]}},{"Citation":"Troy S, Soty M, Ribeiro L, Laval L, Migrenne S, Fioramonti X, Pillot B, Fauveau V, Aubert R, Viollet B, Foretz M, Leclerc J, Duchampt A, Zitoun C, Thorens B, Magnan C, Mithieux G, Andreelli F. Intestinal gluconeogenesis is a key factor for early metabolic changes after gastric bypass but not after gastric lap-band in mice. Cell Metabol. 2008;8:201\u2013211. doi: 10.1016\/j.cmet.2008.08.008.","ArticleIdList":{"ArticleId":[{"@attributes":{"IdType":"doi"},"@text":"10.1016\/j.cmet.2008.08.008"},{"@attributes":{"IdType":"pubmed"},"@text":"18762021"}]}},{"Citation":"St\u00fcmpel F, Burcelin R, Jungermann K, Thorens B. Normal kinetics of intestinal glucose absorption in the absence of GLUT2: evidence for a transport pathway requiring glucose phosphorylation and transfer into the endoplasmic reticulum. Proc Natl Acad Sci USA. 2001;98:11330\u201311335. doi: 10.1073\/pnas.211357698.","ArticleIdList":{"ArticleId":[{"@attributes":{"IdType":"doi"},"@text":"10.1073\/pnas.211357698"},{"@attributes":{"IdType":"pmc"},"@text":"PMC58729"},{"@attributes":{"IdType":"pubmed"},"@text":"11562503"}]}},{"Citation":"Takata K, Kasahara T, Kasahara M, Ezaki O, Hirano H. Localization of na(+)-dependent active type and erythrocyte\/HepG2-type glucose transporters in rat kidney: immunofluorescence and immunogold study. J Histochem cytochem. 1991;39:287\u2013298. doi: 10.1177\/39.3.1993828.","ArticleIdList":{"ArticleId":[{"@attributes":{"IdType":"doi"},"@text":"10.1177\/39.3.1993828"},{"@attributes":{"IdType":"pubmed"},"@text":"1993828"}]}},{"Citation":"Dominguez JH, Camp K, Maianu L, Garvey WT. Glucose transporters of rat proximal tubule: differential expression and subcellular distribution. Am J Physiol. 1992;262:F807\u2013F812. doi: 10.1152\/ajprenal.1992.262.5.F807.","ArticleIdList":{"ArticleId":[{"@attributes":{"IdType":"doi"},"@text":"10.1152\/ajprenal.1992.262.5.F807"},{"@attributes":{"IdType":"pubmed"},"@text":"1590425"}]}},{"Citation":"Pajor AM, Hirayama BA, Wright EM. Molecular evidence for two renal Na+\/glucose cotransporters. Biochim Biophys Acta. 1992;1106:216\u2013220. doi: 10.1016\/0005-2736(92)90241-d.","ArticleIdList":{"ArticleId":[{"@attributes":{"IdType":"doi"},"@text":"10.1016\/0005-2736(92)90241-d"},{"@attributes":{"IdType":"pubmed"},"@text":"1581333"}]}},{"Citation":"Chin E, Zhou J, Bondy C. Anatomical and developmental patterns of facilitative glucose transporter gene expression in the rat kidney. J Clin Invest. 1993;91:1810\u20131815. doi: 10.1172\/jci116392.","ArticleIdList":{"ArticleId":[{"@attributes":{"IdType":"doi"},"@text":"10.1172\/jci116392"},{"@attributes":{"IdType":"pmc"},"@text":"PMC288162"},{"@attributes":{"IdType":"pubmed"},"@text":"8473519"}]}},{"Citation":"Marks J, Carvou NJ, Debnam ES, Srai SK, Unwin RJ. Diabetes increases facilitative glucose uptake and GLUT2 expression at the rat proximal tubule brush border membrane. J Physiol. 2003;553:137\u2013145. doi: 10.1113\/jphysiol.2003.046268.","ArticleIdList":{"ArticleId":[{"@attributes":{"IdType":"doi"},"@text":"10.1113\/jphysiol.2003.046268"},{"@attributes":{"IdType":"pmc"},"@text":"PMC2343472"},{"@attributes":{"IdType":"pubmed"},"@text":"12963802"}]}},{"Citation":"Powell DR, DaCosta CM, Gay J, Ding ZM, Smith M, Greer J, Doree D, Jeter-Jones S, Mseeh F, Rodriguez LA, Harris A, Buhring L, Platt KA, Vogel P, Brommage R, Shadoan MK, Sands AT, Zambrowicz B. Improved glycemic control in mice lacking Sglt1 and Sglt2. Am J Physiol Endocrinol metabolism. 2013;304:E117\u2013130. doi: 10.1152\/ajpendo.00439.2012.","ArticleIdList":{"ArticleId":[{"@attributes":{"IdType":"doi"},"@text":"10.1152\/ajpendo.00439.2012"},{"@attributes":{"IdType":"pubmed"},"@text":"23149623"}]}},{"Citation":"Santer R, Groth S, Kinner M, Dombrowski A, Berry GT, Brodehl J, Leonard JV, Moses S, Norgren S, Skovby F, Schneppenheim R, Steinmann B, Schaub J. The mutation spectrum of the facilitative glucose transporter gene SLC2A2 (GLUT2) in patients with Fanconi-Bickel syndrome. Hum Genet. 2002;110:21\u201329. doi: 10.1007\/s00439-001-0638-6.","ArticleIdList":{"ArticleId":[{"@attributes":{"IdType":"doi"},"@text":"10.1007\/s00439-001-0638-6"},{"@attributes":{"IdType":"pubmed"},"@text":"11810292"}]}},{"Citation":"Dupuis J, Langenberg C, Prokopenko I, Saxena R, Soranzo N, Jackson AU, Wheeler E, Glazer NL, Bouatia-Naji N, Gloyn AL, Lindgren CM, M\u00e4gi R, Morris AP, Randall J, Johnson T, Elliott P, Rybin D, Thorleifsson G, Steinthorsdottir V, Henneman P, Grallert H, Dehghan A, Hottenga JJ, Franklin CS, Navarro P, Song K, Goel A, Perry JR, Egan JM, Lajunen T, Grarup N, Spars\u00f8 T, Doney A, Voight BF, Stringham HM, Li M, Kanoni S, Shrader P, Cavalcanti-Proen\u00e7a C, Kumari M, Qi L, Timpson NJ, Gieger C, Zabena C, Rocheleau G, Ingelsson E, An P, O'Connell J, Luan J, Elliott A, McCarroll SA, Payne F, Roccasecca RM, Pattou F, Sethupathy P, Ardlie K, Ariyurek Y, Balkau B, Barter P, Beilby JP, Ben-Shlomo Y, Benediktsson R, Bennett AJ, Bergmann S, Bochud M, Boerwinkle E, Bonnefond A, Bonnycastle LL, Borch-Johnsen K, B\u00f6ttcher Y, Brunner E, Bumpstead SJ, Charpentier G, Chen YD, Chines P, Clarke R, Coin LJ, Cooper MN, Cornelis M, Crawford G, Crisponi L, Day IN, de Geus EJ, Delplanque J, Dina C, Erdos MR, Fedson AC, Fischer-Rosinsky A, Forouhi NG, Fox CS, Frants R, Franzosi MG, Galan P, Goodarzi MO, Graessler J, Groves CJ, Grundy S, Gwilliam R, Gyllensten U, Hadjadj S, Hallmans G, Hammond N, Han X, Hartikainen AL, Hassanali N, Hayward C, Heath SC, Hercberg S, Herder C, Hicks AA, Hillman DR, Hingorani AD, Hofman A, Hui J, Hung J, Isomaa B, Johnson PR, J\u00f8rgensen T, Jula A, Kaakinen M, Kaprio J, Kesaniemi YA, Kivimaki M, Knight B, Koskinen S, Kovacs P, Kyvik KO, Lathrop GM, Lawlor DA, Le Bacquer O, Lecoeur C, Li Y, Lyssenko V, Mahley R, Mangino M, Manning AK, Mart\u00ednez-Larrad MT, McAteer JB, McCulloch LJ, McPherson R, Meisinger C, Melzer D, Meyre D, Mitchell BD, Morken MA, Mukherjee S, Naitza S, Narisu N, Neville MJ, Oostra BA, Orr\u00f9 M, Pakyz R, Palmer CN, Paolisso G, Pattaro C, Pearson D, Peden JF, Pedersen NL, Perola M, Pfeiffer AF, Pichler I, Polasek O, Posthuma D, Potter SC, Pouta A, Province MA, Psaty BM, Rathmann W, Rayner NW, Rice K, Ripatti S, Rivadeneira F, Roden M, Rolandsson O, Sandbaek A, Sandhu M, Sanna S, Sayer AA, Scheet P, Scott LJ, Seedorf U, Sharp SJ, Shields B, Sigurethsson G, Sijbrands EJ, Silveira A, Simpson L, Singleton A, Smith NL, Sovio U, Swift A, Syddall H, Syv\u00e4nen AC, Tanaka T, Thorand B, Tichet J, T\u00f6njes A, Tuomi T, Uitterlinden AG, van Dijk KW, van Hoek M, Varma D, Visvikis-Siest S, Vitart V, Vogelzangs N, Waeber G, Wagner PJ, Walley A, Walters GB, Ward KL, Watkins H, Weedon MN, Wild SH, Willemsen G, Witteman JC, Yarnell JW, Zeggini E, Zelenika D, Zethelius B, Zhai G, Zhao JH, Zillikens MC, Borecki IB, Loos RJ, Meneton P, Magnusson PK, Nathan DM, Williams GH, Hattersley AT, Silander K, Salomaa V, Smith GD, Bornstein SR, Schwarz P, Spranger J, Karpe F, Shuldiner AR, Cooper C, Dedoussis GV, Serrano-R\u00edos M, Morris AD, Lind L, Palmer LJ, Hu FB, Franks PW, Ebrahim S, Marmot M, Kao WH, Pankow JS, Sampson MJ, Kuusisto J, Laakso M, Hansen T, Pedersen O, Pramstaller PP, Wichmann HE, Illig T, Rudan I, Wright AF, Stumvoll M, Campbell H, Wilson JF, Bergman RN, Buchanan TA, Collins FS, Mohlke KL, Tuomilehto J, Valle TT, Altshuler D, Rotter JI, Siscovick DS, Penninx BW, Boomsma DI, Deloukas P, Spector TD, Frayling TM, Ferrucci L, Kong A, Thorsteinsdottir U, Stefansson K, van Duijn CM, Aulchenko YS, Cao A, Scuteri A, Schlessinger D, Uda M, Ruokonen A, Jarvelin MR, Waterworth DM, Vollenweider P, Peltonen L, Mooser V, Abecasis GR, Wareham NJ, Sladek R, Froguel P, Watanabe RM, Meigs JB, Groop L, Boehnke M, McCarthy MI, Florez JC, Barroso I. New genetic loci implicated in fasting glucose homeostasis and theirimpact on type 2 diabetes risk. Nature genetics. 2010;42:105\u2013116. doi: 10.1038\/ng.520.","ArticleIdList":{"ArticleId":[{"@attributes":{"IdType":"doi"},"@text":"10.1038\/ng.520"},{"@attributes":{"IdType":"pmc"},"@text":"PMC3018764"},{"@attributes":{"IdType":"pubmed"},"@text":"20081858"}]}},{"Citation":"Roncero I, Alvarez E, Chowen JA, Sanz C, R\u00e1bano A, V\u00e1zquez P, Bl\u00e1zquez E. Expression of glucose transporter isoform GLUT-2 and glucokinase genes in human brain. J Neurochem. 2004;88:1203\u20131210. doi: 10.1046\/j.1471-4159.2003.02269.x.","ArticleIdList":{"ArticleId":[{"@attributes":{"IdType":"doi"},"@text":"10.1046\/j.1471-4159.2003.02269.x"},{"@attributes":{"IdType":"pubmed"},"@text":"15009676"}]}},{"Citation":"Liu Y, Liu F, Grundke-Iqbal I, Iqbal K, Gong CX. Brain glucose transporters, O-GlcNAcylation and phosphorylation of tau in diabetes and Alzheimer\u2019s disease. J Neurochem. 2009;111:242\u2013249. doi: 10.1111\/j.1471-4159.2009.06320.x.","ArticleIdList":{"ArticleId":[{"@attributes":{"IdType":"doi"},"@text":"10.1111\/j.1471-4159.2009.06320.x"},{"@attributes":{"IdType":"pmc"},"@text":"PMC2760012"},{"@attributes":{"IdType":"pubmed"},"@text":"19659459"}]}},{"Citation":"Arluison M, Quignon M, Thorens B, Leloup C, Penicaud L. Immunocytochemical localization of the glucose transporter 2 (GLUT2) in the adult rat brain. II. Electron microscopic study. J Chem Neuroanat. 2004;28:137\u2013146. doi: 10.1016\/j.jchemneu.2004.06.002.","ArticleIdList":{"ArticleId":[{"@attributes":{"IdType":"doi"},"@text":"10.1016\/j.jchemneu.2004.06.002"},{"@attributes":{"IdType":"pubmed"},"@text":"15482900"}]}},{"Citation":"Garc\u00eda M, Mill\u00e1n C, Balmaceda-Aguilera C, Castro T, Pastor P, Montecinos H, Reinicke K, Z\u00fa\u00f1iga F, Vera JC, O\u00f1ate SA, Nualart F. Hypothalamic ependymal-glial cells express the glucose transporter GLUT2, a protein involved in glucose sensing. J Neurochem. 2003;86:709\u2013724. doi: 10.1046\/j.1471-4159.2003.01892.x.","ArticleIdList":{"ArticleId":[{"@attributes":{"IdType":"doi"},"@text":"10.1046\/j.1471-4159.2003.01892.x"},{"@attributes":{"IdType":"pubmed"},"@text":"12859684"}]}},{"Citation":"Mar\u00edn-Juez R, Rovira M, Crespo D, van der Vaart M, Spaink HP, Planas JV. GLUT2-mediated glucose uptake and availability are required for embryonic brain development in zebrafish. J Cereb blood flow metabol: official J Int Soc Cereb Blood Flow Metab. 2015;35:74\u201385. doi: 10.1038\/jcbfm.2014.171.","ArticleIdList":{"ArticleId":[{"@attributes":{"IdType":"doi"},"@text":"10.1038\/jcbfm.2014.171"},{"@attributes":{"IdType":"pmc"},"@text":"PMC4294397"},{"@attributes":{"IdType":"pubmed"},"@text":"25294126"}]}},{"Citation":"Tarussio D, Metref S, Seyer P, Mounien L, Vallois D, Magnan C, Foretz M, Thorens B. Nervous glucose sensing regulates postnatal \u03b2 cell proliferation and glucose homeostasis. J Clin Investig. 2014;124:413\u2013424. doi: 10.1172\/jci69154.","ArticleIdList":{"ArticleId":[{"@attributes":{"IdType":"doi"},"@text":"10.1172\/jci69154"},{"@attributes":{"IdType":"pmc"},"@text":"PMC3871223"},{"@attributes":{"IdType":"pubmed"},"@text":"24334455"}]}},{"Citation":"Wan HZ, Hulsey MG, Martin RJ. Intracerebroventricular administration of antisense oligodeoxynucleotide against GLUT2 glucose transporter mRNA reduces food intake, body weight change and glucoprivic feeding response in rats. J Nutr. 1998;128:287\u2013291. doi: 10.1093\/jn\/128.2.287.","ArticleIdList":{"ArticleId":[{"@attributes":{"IdType":"doi"},"@text":"10.1093\/jn\/128.2.287"},{"@attributes":{"IdType":"pubmed"},"@text":"9446857"}]}},{"Citation":"Mounien L, Marty N, Tarussio D, Metref S, Genoux D, Preitner F, Foretz M, Thorens B. Glut2-dependent glucose-sensing controls thermoregulation by enhancing the leptin sensitivity of NPY and POMC neurons.\u00a0. FASEB j: off publ Fed Am Soc Exp Biol. 2010;24:1747\u20131758. doi: 10.1096\/fj.09-144923.","ArticleIdList":{"ArticleId":[{"@attributes":{"IdType":"doi"},"@text":"10.1096\/fj.09-144923"},{"@attributes":{"IdType":"pubmed"},"@text":"20097878"}]}},{"Citation":"Lamy CM, Sanno H, Labou\u00e8be G, Picard A, Magnan C, Chatton JY, Thorens B. Hypoglycemia-activated GLUT2 neurons of the nucleus tractus solitarius stimulate vagal activity and glucagon secretion. Cell Metabol. 2014;19:527\u2013538. doi: 10.1016\/j.cmet.2014.02.003.","ArticleIdList":{"ArticleId":[{"@attributes":{"IdType":"doi"},"@text":"10.1016\/j.cmet.2014.02.003"},{"@attributes":{"IdType":"pubmed"},"@text":"24606905"}]}},{"Citation":"Madisen L, Mao T, Koch H, Zhuo JM, Berenyi A, Fujisawa S, Hsu YW, Garcia AJ, 3rd, Gu X, Zanella S, Kidney J, Gu H, Mao Y, Hooks BM, Boyden ES, Buzs\u00e1ki G, Ramirez JM, Jones AR, Svoboda K, Han X, Turner EE, Zeng H. A toolbox of cre-dependent optogenetic transgenic mice for light-induced activation and silencing. Nat Neurosci. 2012;15:793\u2013802. doi: 10.1038\/nn.3078.","ArticleIdList":{"ArticleId":[{"@attributes":{"IdType":"doi"},"@text":"10.1038\/nn.3078"},{"@attributes":{"IdType":"pmc"},"@text":"PMC3337962"},{"@attributes":{"IdType":"pubmed"},"@text":"22446880"}]}},{"Citation":"Finegood DT, Scaglia L, Bonner-Weir S. Dynamics of beta-cell mass in the growing rat pancreas. Estimation with a simple mathematical model. Diabetes. 1995;44:249\u2013256. doi: 10.2337\/diab.44.3.249.","ArticleIdList":{"ArticleId":[{"@attributes":{"IdType":"doi"},"@text":"10.2337\/diab.44.3.249"},{"@attributes":{"IdType":"pubmed"},"@text":"7883109"}]}},{"Citation":"Girard J, Ferr\u00e9 P, P\u00e9gorier JP, Du\u00e9e PH. Adaptations of glucose and fatty acid metabolism during perinatal period and suckling-weaning transition. Physiol Rev. 1992;72:507\u2013562. doi: 10.1152\/physrev.1992.72.2.507.","ArticleIdList":{"ArticleId":[{"@attributes":{"IdType":"doi"},"@text":"10.1152\/physrev.1992.72.2.507"},{"@attributes":{"IdType":"pubmed"},"@text":"1557431"}]}},{"Citation":"Berthoud HR, Neuhuber WL. Functional and chemical anatomy of the afferent vagal system. Auton neuroscience: basic Clin. 2000;85:1\u201317. doi: 10.1016\/s1566-0702(00)00215-0.","ArticleIdList":{"ArticleId":[{"@attributes":{"IdType":"doi"},"@text":"10.1016\/s1566-0702(00)00215-0"},{"@attributes":{"IdType":"pubmed"},"@text":"11189015"}]}},{"Citation":"Preitner F, Ibberson M, Franklin I, Binnert C, Pende M, Gjinovci A, Hansotia T, Drucker DJ, Wollheim C, Burcelin R, Thorens B. Gluco-incretins control insulin secretion at multiple levels as revealed in mice lacking GLP-1 and GIP receptors. J Clin Investig. 2004;113:635\u2013645. doi: 10.1172\/jci20518.","ArticleIdList":{"ArticleId":[{"@attributes":{"IdType":"doi"},"@text":"10.1172\/jci20518"},{"@attributes":{"IdType":"pmc"},"@text":"PMC338268"},{"@attributes":{"IdType":"pubmed"},"@text":"14966573"}]}},{"Citation":"Burcelin R, del Carmen Mu\u00f1oz M, Guillam MT, Thorens B. Liver hyperplasia and paradoxical regulation of glycogen metabolism and glucose-sensitive gene expression in GLUT2-null hepatocytes. Further evidence for the existence of a membrane-based glucose release pathway. J Biol Chem. 2000;275:10930\u201310936. doi: 10.1074\/jbc.275.15.10930.","ArticleIdList":{"ArticleId":[{"@attributes":{"IdType":"doi"},"@text":"10.1074\/jbc.275.15.10930"},{"@attributes":{"IdType":"pubmed"},"@text":"10753892"}]}},{"Citation":"D\u00fcfer M, H\u00f6rth K, Wagner R, Schittenhelm B, Prowald S, Wagner TF, Oberwinkler J, Lukowski R, Gonzalez FJ, Krippeit-Drews P, Drews G. Bile acids acutely stimulate insulin secretion of mouse \u03b2-cells via farnesoid X receptor activation and K(ATP) channel inhibition. Diabetes. 2012;61:1479\u20131489. doi: 10.2337\/db11-0815.","ArticleIdList":{"ArticleId":[{"@attributes":{"IdType":"doi"},"@text":"10.2337\/db11-0815"},{"@attributes":{"IdType":"pmc"},"@text":"PMC3357280"},{"@attributes":{"IdType":"pubmed"},"@text":"22492528"}]}},{"Citation":"Barker A, Sharp SJ, Timpson NJ, Bouatia-Naji N, Warrington NM, Kanoni S, Beilin LJ, Brage S, Deloukas P, Evans DM, Grontved A, Hassanali N, Lawlor DA, Lecoeur C, Loos RJ, Lye SJ, McCarthy MI, Mori TA, Ndiaye NC, Newnham JP, Ntalla I, Pennell CE, St Pourcain B, Prokopenko I, Ring SM, Sattar N, Visvikis-Siest S, Dedoussis GV, Palmer LJ, Froguel P, Smith GD, Ekelund U, Wareham NJ, Langenberg C. Association of genetic loci with glucose levels in childhood and adolescence: a meta-analysis of over 6,000 children. Diabetes. 2011;60:1805\u20131812. doi: 10.2337\/db10-1575.","ArticleIdList":{"ArticleId":[{"@attributes":{"IdType":"doi"},"@text":"10.2337\/db10-1575"},{"@attributes":{"IdType":"pmc"},"@text":"PMC3114379"},{"@attributes":{"IdType":"pubmed"},"@text":"21515849"}]}},{"Citation":"Gaulton KJ, Willer CJ, Li Y, Scott LJ, Conneely KN, Jackson AU, Duren WL, Chines PS, Narisu N, Bonnycastle LL, Luo J, Tong M, Sprau AG, Pugh EW, Doheny KF, Valle TT, Abecasis GR, Tuomilehto J, Bergman RN, Collins FS, Boehnke M, Mohlke KL. Comprehensive association study of type 2 diabetes and related quantitative traits with 222 candidate genes. Diabetes. 2008;57:3136\u20133144. doi: 10.2337\/db07-1731.","ArticleIdList":{"ArticleId":[{"@attributes":{"IdType":"doi"},"@text":"10.2337\/db07-1731"},{"@attributes":{"IdType":"pmc"},"@text":"PMC2570412"},{"@attributes":{"IdType":"pubmed"},"@text":"18678618"}]}},{"Citation":"Laukkanen O, Lindstr\u00f6m J, Eriksson J, Valle TT, H\u00e4m\u00e4l\u00e4inen H, Ilanne-Parikka P, Kein\u00e4nen-Kiukaanniemi S, Tuomilehto J, Uusitupa M, Laakso M. Polymorphisms in the SLC2A2 (GLUT2) gene are associated with the conversion from impaired glucose tolerance to type 2 diabetes: the finnish diabetes Prevention Study. Diabetes. 2005;54:2256\u20132260. doi: 10.2337\/diabetes.54.7.2256.","ArticleIdList":{"ArticleId":[{"@attributes":{"IdType":"doi"},"@text":"10.2337\/diabetes.54.7.2256"},{"@attributes":{"IdType":"pubmed"},"@text":"15983230"}]}},{"Citation":"Igl W, Johansson A, Wilson JF, Wild SH, Polasek O, Hayward C, Vitart V, Hastie N, Rudan P, Gnewuch C, Schmitz G, Meitinger T, Pramstaller PP, Hicks AA, Oostra BA, van Duijn CM, Rudan I, Wright A, Campbell H, Gyllensten U. Modeling of environmental effects in genome-wide association studies identifies SLC2A2 and HP as novel loci influencing serum cholesterol levels. PLoS Genet. 2010;6:e1000798. doi: 10.1371\/journal.pgen.1000798.","ArticleIdList":{"ArticleId":[{"@attributes":{"IdType":"doi"},"@text":"10.1371\/journal.pgen.1000798"},{"@attributes":{"IdType":"pmc"},"@text":"PMC2792712"},{"@attributes":{"IdType":"pubmed"},"@text":"20066028"}]}},{"Citation":"Borglykke A, Grarup N, Spars\u00f8 T, Linneberg A, Fenger M, Jeppesen J, Hansen T, Pedersen O, J\u00f8rgensen T. Genetic variant SLC2A2 [corrected] is associated with risk of cardiovascular disease\u2013assessing the individual and cumulative effect of 46 type 2 diabetes related genetic variants. PLoS ONE. 2012;7:e50418. doi: 10.1371\/journal.pone.0050418.","ArticleIdList":{"ArticleId":[{"@attributes":{"IdType":"doi"},"@text":"10.1371\/journal.pone.0050418"},{"@attributes":{"IdType":"pmc"},"@text":"PMC3503928"},{"@attributes":{"IdType":"pubmed"},"@text":"23185617"}]}},{"Citation":"Eny KM, Wolever TM, Fontaine-Bisson B, El-Sohemy A. Genetic variant in the glucose transporter type 2 is associated with higher intakes of sugars in two distinct populations. Physiol Genom. 2008;33:355\u2013360. doi: 10.1152\/physiolgenomics.00148.2007.","ArticleIdList":{"ArticleId":[{"@attributes":{"IdType":"doi"},"@text":"10.1152\/physiolgenomics.00148.2007"},{"@attributes":{"IdType":"pubmed"},"@text":"18349384"}]}}]}]}}}