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GLUT2

GLUT2, encoded by the SLC2A2 gene, is a low-affinity facilitative that enables bidirectional diffusion of glucose across plasma membranes, playing an essential role in maintaining glucose throughout the body. It belongs to the major facilitator superfamily of transporters, consisting of approximately 500 organized into 12 transmembrane alpha-helices with a single N-linked site, which facilitates its high-capacity transport without requiring energy input. Expressed prominently in the liver, pancreatic β-cells, basolateral membranes of intestinal and renal epithelial cells, as well as regions of the such as the and , GLUT2 ensures rapid equilibration of glucose levels between blood and these tissues. Its characteristic high for glucose (approximately 17 ) allows it to function efficiently under varying blood glucose concentrations, particularly in postprandial states where glucose fluxes are large. In the liver, GLUT2 mediates the majority (over 97%) of and release, supporting glycolytic and lipogenic processes while sensing glucose to regulate hepatic metabolism. Within pancreatic β-cells, it facilitates glucose entry to trigger insulin secretion via the K+-ATP-dependent pathway, with expression levels of at least 20% being critical for normal glucose-stimulated insulin release. In the kidneys and intestines, GLUT2 works in concert with sodium-glucose cotransporters (SGLT1/2) to reabsorb and absorb glucose, respectively, preventing urinary loss and enabling efficient nutrient uptake. In the , it contributes to glucose sensing in areas like the nucleus tractus solitarius, influencing feeding behavior, , and counter-regulatory responses during . Dysfunction or mutations in SLC2A2 are associated with Fanconi-Bickel syndrome, a rare characterized by hepatorenal glycogen accumulation, , and glucosuria due to impaired glucose transport. Additionally, altered GLUT2 expression has been implicated in the pathophysiology of , where enhanced intestinal absorption or reduced β-cell function may exacerbate , and in immune responses such as CD8+ T-cell activation.

Molecular Biology

Gene Characteristics

The SLC2A2 , which encodes the GLUT2, is located on the long arm of human at cytogenetic band 3q26.2, with genomic coordinates spanning from 170,996,347 to 171,026,720 (GRCh38). This protein-coding gene covers approximately 30.4 kb and consists of 12 exons, with the canonical transcript ENST00000291764.9 producing a 524-amino-acid protein. The SLC2A2 gene exhibits strong evolutionary conservation across mammals, reflecting its essential role in , with orthologs identified in species such as (Slc2a2), (Slc2a2), and (SLC2A2) showing high sequence similarity in coding regions. The promoter region upstream of the contains key regulatory elements, including binding sites for factors (HNF1α and HNF4α) and forkhead box A2 (FOXA2), which mediate tissue-specific . Alternative splicing of SLC2A2 transcripts yields multiple isoforms, with two principal variants reported: the canonical full-length isoform (ISO-1) and a shorter isoform (ISO-2) lacking residues 460-496 due to . Pathogenic mutations in SLC2A2 underlie Fanconi-Bickel syndrome (FBS), a rare autosomal recessive storage disorder characterized by hepatorenal accumulation and glucose intolerance; over 80 variants have been documented, including missense mutations like p.Val423Glu that impair protein trafficking and membrane insertion.

Protein Structure

GLUT2, also known as SLC2A2, belongs to the 2 (SLC2A), a group of facilitated glucose transporters (GLUTs) that mediate passive of hexoses across membranes. The human GLUT2 protein comprises 524 and has a of approximately 58 kDa. The core architecture of GLUT2 consists of 12 transmembrane α-helices arranged in a bundle, forming a central aqueous that accommodates substrate passage, with both the amino (N)- and carboxyl (C)-termini oriented toward the . This is conserved across the GLUT and supports the protein's role as an integral membrane . Notable structural features include a single N-linked site at 63 (Asn-63) located in the first extracellular loop between transmembrane helices 1 and 2, which is critical for proper folding, stability, and retention at the plasma membrane. Additionally, dileucine motifs, such as the sequence in the C-terminal cytoplasmic domain, facilitate endocytic trafficking and recycling of the protein to the cell surface. Although no high-resolution cryo-EM structure of GLUT2 exists, homology models derived from related GLUT isoforms (e.g., and ) depict GLUT2 in alternating conformations during its transport cycle: an outward-open state exposing the substrate-binding site to the , transitioning via an occluded intermediate to an inward-open state that releases the substrate intracellularly, consistent with the rocker-switch mechanism of the major facilitator superfamily.

Expression and Distribution

Tissue-Specific Expression

GLUT2, encoded by the SLC2A2 gene, exhibits high expression in tissues critical for systemic glucose regulation. In the liver, particularly in hepatocytes, GLUT2 mRNA and protein levels are markedly elevated, facilitating the bidirectional flux of glucose across the plasma membrane to maintain blood glucose homeostasis. Similarly, the pancreas shows substantial overall GLUT2 expression, with high levels in exocrine cells; in pancreatic beta cells, GLUT2 supports glucose equilibration with blood levels for effective nutrient sensing in rodents, where it is the predominant isoform, but in humans, its expression is relatively low compared to GLUT1 and GLUT3. In the small intestine, GLUT2 is predominantly localized to the basolateral membrane of enterocytes, enabling the release of absorbed glucose into the circulation following apical uptake. The proximal tubules of the kidney also display high GLUT2 abundance on their basolateral surfaces, contributing to the reclamation of filtered glucose from the tubular fluid. Quantitative analyses from large-scale transcriptomic datasets, such as GTEx, reveal tissue-specific disparities in SLC2A2 mRNA expression. Liver tissue exhibits approximately 46-fold higher expression relative to the median across all tissues, underscoring its dominance in hepatic glucose handling, whereas skeletal muscle shows negligible levels, with liver expression exceeding muscle by over 20-fold in comparative studies. Pancreatic expression, while lower than in the liver overall, is consistent with its role in beta-cell function across species, though with noted differences in isoform predominance. Expression of GLUT2 is more limited in other sites, including alveolar epithelial cells of the , retinal pigment epithelium, and select brain regions such as the and , where mRNA and protein levels are detectable but substantially reduced relative to primary metabolic tissues. Developmentally, GLUT2 expression patterns in the liver and are low during fetal stages but increase progressively postnatally, attaining peak levels in adulthood to align with the maturation of glucose metabolic demands.

Regulation of Expression

The expression of GLUT2, encoded by the SLC2A2 gene, is tightly regulated at multiple levels to maintain glucose , particularly in tissues like the liver, , intestine, and . Transcriptional control plays a central role, with glucose-responsive elements in the promoter region responding to availability. Hepatocyte nuclear factor 1α (HNF1α) binds to specific sequences in the SLC2A2 promoter, promoting its expression in hepatocytes, pancreatic β-cells, and intestinal enterocytes, thereby ensuring tissue-appropriate glucose transport capacity. Similarly, carbohydrate response element-binding protein (ChREBP), activated by glucose metabolites such as xylulose-5-phosphate, drives SLC2A2 transcription in the liver, coordinating GLUT2 upregulation with glycolytic flux during high-carbohydrate states. Post-transcriptional regulation further fine-tunes GLUT2 levels, primarily through microRNAs (miRNAs) that target the SLC2A2 mRNA. The miR-29 family negatively regulates GLUT2 by binding to conserved sites in the 3' of SLC2A2, suppressing its translation and contributing to reduced in pathological states like ; this has been observed in pancreatic models and tissues. This mechanism helps balance hepatic glucose handling, as miR-29 overexpression correlates with lower GLUT2 protein in insulin-resistant livers. Hormonal signals integrate metabolic cues to modulate GLUT2 expression, with insulin and exerting opposing effects in the liver. Insulin upregulates SLC2A2 transcription via activation of sterol regulatory element-binding protein-1c (SREBP-1c), enhancing GLUT2 levels to facilitate postprandial and storage. In contrast, downregulates GLUT2 expression during fasting, promoting hepatic glucose output while limiting unnecessary uptake, as observed in studies of isolated hepatocytes where suppresses SLC2A2 mRNA. Beyond expression levels, GLUT2 localization is dynamically regulated by trafficking mechanisms that respond to glucose concentrations. Under high glucose conditions, GLUT2 undergoes from the via caveolae-dependent pathways, reducing surface availability and preventing excessive glucose influx; this process is mediated by dileucine-like motifs in the protein's cytoplasmic domains, which interact with adaptor proteins for - or caveolin-mediated . Such regulation ensures adaptive localization without altering total protein abundance, complementing transcriptional controls in maintaining physiological glucose fluxes.

Physiological Roles

Role in Hepatic Glucose Homeostasis

In the liver, GLUT2 serves as the primary facilitator of bidirectional glucose across the plasma membrane, enabling the organ to act as a central for systemic glucose levels. During the postprandial state, when blood glucose concentrations rise, GLUT2 allows rapid influx of glucose into hepatocytes, supporting its utilization in synthesis and . This transport is characterized by a high and low , with a Km value of approximately 17 , which permits equilibration between extracellular and intracellular glucose without tight by insulin. During fasting or , GLUT2 enables the release of glucose from hepatocytes into the bloodstream, maintaining with plasma glucose levels and preventing intracellular accumulation that could disrupt metabolic balance. This outward transport is essential for hepatic glucose output, derived from and , though studies in GLUT2-deficient models indicate that alternative pathways can partially compensate for its absence in release mechanisms. The transporter's high aligns closely with that of (also ~5-10 mM), the rate-limiting enzyme in hepatic glucose , allowing coordinated, non-insulin-dependent sensing and processing of glucose to fine-tune metabolic fluxes. Beyond direct transport, GLUT2 plays a critical role in hepatoportal glucose sensing, where its expression in portal vein-associated hepatocytes and endothelial cells detects rises in portal glucose post-meal. This sensing triggers neural signals via vagal afferents, modulating insulin and secretion from the as well as peripheral glucose utilization, thereby contributing to overall systemic glucose . In vivo studies using GLUT2-null mice demonstrate that disruption of this pathway impairs the hypoglycemic response to portal glucose infusion, underscoring GLUT2's necessity for integrated liver-mediated regulation.

Role in Pancreatic Glucose Sensing

In pancreatic beta cells, GLUT2 functions as a high-capacity, low-affinity that facilitates the influx of glucose in a manner directly proportional to extracellular concentrations, ensuring that intracellular glucose levels closely mirror those in the without becoming rate-limiting for . This bidirectional property, characterized by a high Km value (approximately 17 mM), allows unrestricted glucose entry across a wide physiological range, from levels around 5 mM to postprandial peaks exceeding 10 mM. By enabling this equilibrative , GLUT2 supports the subsequent glycolytic of glucose, leading to ATP production, closure of ATP-sensitive channels, depolarization, calcium influx, and ultimately of insulin granules. The integration of GLUT2 with forms the core of the beta-cell "glucose " complex, where GLUT2's transport kinetics complement glucokinase's high Km (around 5-10 mM) for glucose . This synergy ensures that the rate of glucose —and thus ATP generation—scales linearly with blood glucose levels, providing a precise metabolic signal for insulin . Disruptions in this complex, such as reduced GLUT2 expression, impair the cell's ability to couple nutrient sensing to release, highlighting its essential role in glucose . Studies using GLUT2 knockout models in rodents demonstrate its critical involvement in glucose-stimulated insulin secretion (GSIS), particularly the rapid first-phase response. In GLUT2-null islets, glucose uptake plateaus at higher concentrations without further increase beyond 6 mM, resulting in absent first-phase insulin secretion and no stimulation of release between 2.8 and 6 mM glucose, though a preserved but delayed second-phase response occurs at supraphysiological levels (>20 mM). Re-expression of GLUT2 in these models restores normal biphasic secretion, confirming its necessity for efficient glucose signaling to insulin and . Notably, the dependence on GLUT2 for beta-cell glucose sensing exhibits species-specific differences. In , where GLUT2 is the predominant (expressed over 10-fold higher than alternatives), its absence severely disrupts GSIS. In contrast, pancreatic beta cells express lower levels of GLUT2, with and predominating (2.7-2.8 times higher expression), allowing partial compensation and maintaining GSIS even under reduced GLUT2 conditions. This interspecies variation underscores the need for caution in extrapolating data to .

Role in Intestinal and Renal Glucose Transport

In the , GLUT2 serves as the primary on the basolateral of enterocytes, enabling the efflux of glucose into the portal circulation following its apical uptake via the sodium-glucose cotransporter SGLT1. This coordinated transport mechanism supports efficient transepithelial absorption of dietary glucose, allowing enterocytes to handle varying luminal concentrations without accumulating intracellular glucose to toxic levels. Under normal physiological conditions, SGLT1 actively transports glucose against its concentration using the sodium , while GLUT2's low-affinity, high-capacity transport (Km ≈ 17 mM) facilitates passive across the basolateral driven by the intracellular-to-extracellular glucose . In the , GLUT2 is expressed on the basolateral membrane of epithelial cells, where it plays a crucial role in the of filtered glucose back into the bloodstream, thereby preventing glucosuria in normoglycemic states. Approximately 90% of filtered glucose is reabsorbed in the early (S1/S2 segments) via the apical sodium-glucose cotransporter SGLT2, with the remaining 10% handled by SGLT1 in the late (S3 segment); GLUT2 then mediates the basolateral exit of this accumulated glucose to maintain renal glucose . This transcellular pathway ensures near-complete recovery of glucose (over 99% under normal filtration rates of 180 g/day), conserving this vital energy substrate while avoiding osmotic diuresis. GLUT2 expression and activity in both intestinal and renal epithelia exhibit adaptive upregulation in response to high-glucose diets, enhancing the capacity for and to match increased dietary or filtered loads. In the small intestine, chronic exposure to high-carbohydrate meals induces GLUT2 transcription and trafficking, increasing basolateral (and potentially apical) protein levels to boost transepithelial flux by up to several-fold during postprandial peaks. Similarly, in the proximal tubule, associated with high-glucose conditions elevates GLUT2 expression, coordinating with upregulated SGLT2 and SGLT1 to augment and mitigate potential urinary glucose loss.

Biochemical Properties

Transport Kinetics

GLUT2 functions as a facilitative , employing an alternating access mechanism characteristic of the major facilitator superfamily, wherein the protein alternates between outward-open and inward-open conformations to enable passive, bidirectional of glucose across the without direct energy expenditure. This model ensures efficient equilibration of glucose concentrations between the and , particularly in tissues exposed to fluctuating glucose levels. The of GLUT2-mediated glucose reflect its low-affinity, high-capacity profile, with a Michaelis constant (Km) of approximately 17 mM, allowing the transporter to operate near linearly at physiological and postprandial glucose concentrations without becoming saturated. In hepatocytes, the maximum velocity (Vmax) ranges from 35 to 106 nmol/min/mg protein, supporting rapid glucose flux during metabolic shifts such as or . These parameters underscore GLUT2's role in high-throughput rather than precise regulation at low glucose levels. Transport activity is optimized at physiological temperature (37°C), consistent with mammalian cellular conditions. Regarding directionality, GLUT2 displays symmetric kinetics in many contexts, facilitating comparable rates of influx and efflux to maintain .

Substrate Interactions

GLUT2 primarily facilitates the transport of D-glucose across membranes, exhibiting a low with a of approximately 17 . It also transports glucose analogs such as with comparable , around 11 , allowing for its use in experimental studies of . In addition to D-glucose, GLUT2 accommodates other hexoses including D-fructose ( ~66-76 ) and D-galactose ( ~92 ), though with lower efficiency due to their reduced compared to glucose. As a facilitative transporter, GLUT2 enables bidirectional of these substrates down their concentration gradients without expenditure, supporting equilibrium across membranes in tissues like the liver and . This passive mechanism ensures rapid equilibration of glucose levels between and cells, particularly under varying conditions. A recent discovery in 2025 revealed that GLUT2 also serves as a bi-directional urate transporter, with a Km of approximately 4.6 mM, reflecting its characteristically low substrate affinity. This urate occurs independently of glucose, as 10 mM glucose does not affect urate uptake, and operates robustly with a Vmax of about 2,257 pmol/min/mg protein, contributing to renal urate handling. GLUT2's substrate interactions are modulated by inhibitors such as , which binds asymmetrically to the outward-facing conformation of the transporter, and cytochalasin B, an endofacial that targets the inward-facing involving transmembrane helices 10 and 11. These compounds demonstrate distinct binding preferences, with cytochalasin B showing weaker inhibition of GLUT2 ( ~2.1 μM) compared to other GLUT isoforms.

Clinical and Pathological Significance

Associated Genetic Disorders

Fanconi-Bickel syndrome (FBS) is a rare autosomal recessive monogenic disorder caused by biallelic loss-of-function mutations in the SLC2A2 gene, which encodes the GLUT2 glucose transporter. Clinically, FBS manifests in infancy or early childhood with hepatorenal glycogen accumulation leading to hepatomegaly and renal enlargement, proximal renal tubulopathy resulting in glucosuria, phosphaturia, aminoaciduria, and bicarbonate wasting, as well as rickets due to hypophosphatemia and vitamin D resistance. Additional features include failure to thrive, short stature, fasting hypoglycemia, postprandial hyperglycemia, and galactose intolerance, reflecting impaired glucose and galactose transport in the liver, kidney, intestine, and pancreas. Less than 200 cases of FBS have been reported worldwide as of 2025, with approximately 70 distinct pathogenic SLC2A2 variants identified, including missense, nonsense, frameshift, and splice-site mutations predominantly affecting protein trafficking, stability, or transport activity. A rarer association involves transient neonatal diabetes mellitus (TNDM), also caused by biallelic SLC2A2 mutations, typically in consanguineous families. This condition presents with and hypoinsulinemia in the neonatal period, often resolving spontaneously within months to years post-infancy, though some patients may develop later glucose intolerance or features overlapping with FBS. Fewer than 10 cases have been documented, highlighting its extreme rarity compared to other genetic causes of TNDM. Diagnosis of these disorders relies on clinical suspicion based on the characteristic , followed by confirmatory genetic sequencing of SLC2A2 to identify homozygous or compound heterozygous loss-of-function variants, such as those disrupting GLUT2 membrane localization or substrate binding. Functional studies, including assays in systems, can further validate pathogenicity for novel variants. Animal models provide insights into the ; global Slc2a2 mice exhibit hypoinsulinemia due to impaired glucose-stimulated insulin in pancreatic β-cells, along with postnatal growth defects, , and reduced lifespan, recapitulating key aspects of human FBS and TNDM. These mice demonstrate hepatorenal storage and glucosuria, underscoring GLUT2's essential role in transcellular glucose flux across multiple tissues.

Implications in Diabetes and Metabolic Diseases

GLUT2 polymorphisms, particularly the rs5400 variant (Thr110Ile), have been associated with increased risk of in various populations. In the Finnish Diabetes Prevention Study, SNPs including rs5400 predicted conversion from impaired glucose tolerance to , with the minor allele conferring higher susceptibility. Genome-wide association studies further link GLUT2 variants to elevated hyperglycemia and progression to , highlighting polygenic contributions to impaired glucose sensing. Reduced GLUT2 expression in pancreatic beta cells is implicated in the of by contributing to defective glucose-stimulated insulin secretion. In diabetic models such as db/db mice, glucose-unresponsive beta cells exhibit downregulated GLUT2, leading to diminished and impaired insulin release, a change that is reversible upon glycemic control. Human studies corroborate this, showing that decreased GLUT2 levels in beta cells correlate with loss of first-phase insulin secretion in progression. In diabetic nephropathy, altered renal GLUT2 expression exacerbates hyperglycemia-induced tubular damage. Hyperglycemia upregulates GLUT2 in cells, enhancing basolateral glucose efflux and contributing to , , and in . Experimental from streptozotocin-induced diabetic models demonstrates that increased GLUT2 facilitates excessive glucose , promoting renal injury and progression to nephropathy. GLUT2 serves as an indirect therapeutic target in through modulation by SGLT2 inhibitors, which disrupt renal glucose reabsorption. By blocking apical SGLT2 uptake, these agents reduce intracellular glucose availability for basolateral efflux via GLUT2, promoting glucosuria and alleviating without directly inhibiting GLUT2. This mechanism underlies the renoprotective effects of SGLT2 inhibitors, as observed in clinical trials where they mitigate by lowering glomerular hyperfiltration and tubular glucose overload.

Emerging Roles in Other Conditions

Recent studies have demonstrated that GLUT2 functions as a bidirectional urate transporter in renal cells, facilitating both urate and depending on physiological conditions. This dual role influences serum urate homeostasis, with genetic variants or dysregulation of GLUT2 contributing to elevated urate levels in and increasing the risk of flares. Post-2020 investigations, including functional assays in systems, confirm that GLUT2's urate transport capacity is comparable to established urate handlers like GLUT9, highlighting its therapeutic potential in modulating urate excretion for management. In (HCC), GLUT2 is frequently overexpressed, enhancing glucose influx into tumor cells and sustaining the Warburg effect, where aerobic predominates to support rapid proliferation and biomass production. This upregulation correlates with poorer , as GLUT2 facilitates metabolic reprogramming that favors production over , even in oxygenated environments. A 2021 in silico screening study identified several GLUT2-selective inhibitors with values ranging from 0.61 to 19.3 μM, to the transporter's central cavity and offering promise for targeted therapies to disrupt HCC glucose metabolism without broadly affecting normal tissues. Associations between GLUT2 and neurodegenerative diseases, particularly (AD), involve altered expression levels that impact brain glucose uptake and neuronal energy supply. In AD patient brains and rodent models, GLUT2 expression is elevated compared to controls, potentially as a compensatory mechanism amid overall hypometabolism, though it may disrupt astrocyte-neuron glucose shuttling. This dysregulation contributes to impaired cognitive function by exacerbating energy deficits in vulnerable regions like the , where glucose transport alterations precede amyloid-beta accumulation. Post-2020 research has linked GLUT2 to severity through metabolic dysregulation, especially in where infection alters the distribution of GLUT2, enriching its expression in islets alongside changes in other glucose-sensing proteins, impairing insulin secretion and promoting . In infected patients, this leads to bidirectional disruptions in glucose , amplifying and multi-organ damage that correlates with worse clinical outcomes. In obesity, GLUT2 undergoes adaptive changes, such as increased apical insertion in enterocytes to boost postprandial glucose , which sustains and fat accumulation. Renal GLUT2 adaptations in obese models further alter tubular glucose reabsorption, contributing to glomerular hyperfiltration and long-term metabolic strain, as evidenced by reversal of obesity phenotypes upon targeted GLUT2 knockdown.