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G cell

G cells, also known as cells, are specialized neuroendocrine cells primarily located in the pyloric of the and the that synthesize and secrete the to regulate production and mucosal integrity. These "open-type" endocrine cells respond to stimuli such as stomach distension, the presence of proteins or , and elevated levels in the gastric , releasing into the systemic circulation to act on parietal cells and enterochromaffin-like (ECL) cells in the gastric fundus. primarily exists in two forms—G-17 in the and G-34 in the intestine—both of which promote (HCl) secretion, enhance gastric motility, and support epithelial while inhibiting in the gastric . The secretion of by G cells is tightly regulated through neural and hormonal mechanisms; vagal efferent neurons and (GRP) stimulate release during the cephalic and gastric , while from D cells inhibits it in response to low or duodenal acidification to prevent excessive production. Although G cells are also present in the and deeper , their primary role in mammals, including humans, centers on maintaining digestive by coordinating secretion with nutrient intake. Dysregulation of G cell function can lead to hypergastrinemia, associated with conditions like Zollinger-Ellison syndrome from gastrinomas or , potentially causing peptic ulcers, (GERD), or increased risk of gastric neoplasms due to gastrin's trophic effects.

Anatomy

Location

G cells, also known as cells, are primarily located in the pyloric of the , where they reside within the pyloric glands. These glands are specialized structures in the antral mucosa that extend from the into the deeper layers of the . Within these glands, G cells are distributed in the portion, neither at the basal nor the apical regions, allowing them to integrate sensory signals from the gastric lumen effectively. A secondary population of G cells is present in the , concentrated in the initial segment adjacent to the . In this region, they are situated particularly within the crypts of Lieberkühn and occasionally in , contributing to local hormonal responses in the upper . G cells occur rarely in the , where their presence is limited and not a primary site of production. Histologically, G cells can be identified under light microscopy in hematoxylin and eosin (H&E)-stained sections by their characteristic fried egg-like appearance, featuring clear or pale surrounding a centrally located, round, dark . This distinguishes them from other enteroendocrine cells in the gastric and duodenal mucosa, though immunohistochemical staining for is often used for confirmation in research and .

Cellular structure

G cells are enteroendocrine cells belonging to the amine precursor uptake and (APUD) system, characterized by their ability to take up amine precursors and decarboxylate them to produce bioactive s and peptides. These cells feature a centrally located, euchromatic surrounded by granular rich in organelles involved in synthesis and storage. The contains abundant rough , a prominent Golgi apparatus, and numerous dense-core secretory granules that serve as the primary site for storage. Electron microscopy reveals the ultrastructural details of these granules, which are round to oval, measure 150-300 nm in diameter, and exhibit an eccentric distribution within the , often concentrated toward the basal region of the . The granules possess a dense core surrounded by a clear , bounded by a unit membrane, reflecting their role in packaging for regulated release. Immunohistochemically, G cells are identified by strong positivity for chromogranin A, a marker of neuroendocrine secretory granules, as well as antibodies specific to , enabling precise localization in sections. Compared to other enteroendocrine cells, G cells display distinct granule morphology.

Physiology

Gastrin secretion

Gastrin is a consisting of 17 or 34 , primarily produced and stored in secretory granules within G cells of the gastric antrum. The two major bioactive forms are -17 (G-17), the predominant amidated form in the antrum comprising 17 , and -34 (G-34), a minor form known as "big gastrin" with 34 . These forms are derived from a larger precursor and exhibit similar biological potency, with activity concentrated in the C-terminal pentapeptide sequence. Gastrin is initially synthesized as preprogastrin (101 ), which is rapidly cleaved to progastrin (80 ) in the . Progastrin undergoes post-translational processing in the trans-Golgi network and secretory granules, where endoproteolytic cleavage occurs at specific dibasic sites by prohormone convertases. Prohormone convertase 1/3 (PC1/3) cleaves at the Arg<sup>36</sup>Arg<sup>37</sup> and Arg<sup>73</sup>Arg<sup>74</sup> sites to facilitate production of G-34 and G-17, while prohormone convertase 2 (PC2) specifically processes the Lys<sup>53</sup>Lys<sup>54</sup> site essential for generating G-17 from G-34 intermediates. Additional modifications, including sulfation at residues and C-terminal α-amidation by peptidylglycine α-amidating monooxygenase, yield the mature, biologically active peptides stored in granules. Upon stimulation, is released from G cells through calcium-dependent , where leads to influx of extracellular calcium via voltage-gated channels, triggering fusion of secretory granules with the plasma membrane. This process is characteristic of neuroendocrine cells and ensures rapid hormone delivery into the circulation. Vagal nerve stimulation can initiate this release via . In healthy individuals, basal circulating levels typically range from 20 to 100 pg/mL, reflecting steady-state . Postprandial concentrations rise modestly, often peaking at 100 to 150 pg/mL and seldom exceeding 200 pg/mL, to support meal-related digestive functions.

Role in digestion

G cells, located primarily in the gastric antrum and , secrete , a key that orchestrates several aspects of gastric . primarily enhances the stomach's ability to process food by promoting acid production, enzyme secretion, and , thereby facilitating protein breakdown and nutrient absorption. Through its actions, ensures coordinated digestive responses across the cephalic, gastric, and intestinal phases, while also supporting the maintenance of gastric mucosal integrity. One primary function of is the stimulation of (HCl) secretion from parietal cells. binds to cholecystokinin-2 (CCK2) receptors on the basolateral of these cells, inducing the expression of the H+/K+-ATPase , which drives acid production into the gastric . This direct effect is complemented by an indirect pathway: activates enterochromaffin-like (ECL) cells to release , which then binds H2 receptors on parietal cells, amplifying HCl output and creating an optimal acidic environment for . Beyond acid , promotes gastric motility by interacting with CCK2 receptors on gastric cells, enhancing antral contractions and mixing of . It also stimulates cells to release pepsinogen, the inactive precursor to , which is essential for initial protein in the acidic milieu. These actions integrate into the broader digestive s: in the cephalic , vagal stimulation triggers initial release; the gastric amplifies via antral distension and protein contact; and the intestinal involves duodenal G cells responding to entry, fine-tuning ongoing gastric activity. Additionally, exerts trophic effects on the , promoting of mucosal cells and inhibiting to maintain and support long-term digestive capacity. This growth-promoting role ensures the regeneration of secretory cells, sustaining efficient over time.

Stimuli

G cells, located in the , are stimulated to release by a variety of neural, luminal, hormonal, and paracrine signals that collectively respond to the presence of and initiate digestive processes. These stimuli ensure a coordinated increase in secretion to promote production during meals. Neural stimulation of G cells primarily occurs through the during the cephalic phase of digestion, where (GRP), also known as bombesin-like peptide, is released from vagal nerve endings and directly activates G cell receptors to trigger secretion. This pathway is activated by the anticipation or sight/smell of food, leading to rapid neural signaling that prepares the for incoming nutrients. Additionally, gastric distention from food intake further enhances vagal GRP release, amplifying the response. Luminal stimuli in the contents play a key role in direct activation of G cells, particularly through the detection of and peptides such as those derived from protein . These nutrients contact the apical surface of G cells, where the calcium-sensing receptor (CaSR) senses aromatic (e.g., ) and calcium ions, leading to intracellular calcium mobilization and subsequent . This mechanism allows G cells to respond precisely to the protein content of a meal, with studies showing that peptone infusion increases serum levels . Hormonal factors, including circulating bombesin, contribute to G cell stimulation by binding to specific receptors on G cells, mimicking neural GRP effects and potentiating release in response to . Bombesin, released from intestinal sources or neural elements, enhances the overall postprandial response without direct dependence on luminal contact. The postprandial response integrates these stimuli, resulting in a rapid rise in levels—often doubling within 5-10 minutes of food intake—driven by the combined neural, luminal, and hormonal inputs from protein-rich meals and gastric distention. This transient surge peaks around 30 minutes and facilitates the gastric phase of acid secretion.

Inhibitors

The secretion of from G cells is tightly regulated by inhibitory mechanisms to prevent excessive production. A primary inhibitor is the low gastric , typically below 2, which directly suppresses release through stimulation of secretion from adjacent D cells in the . This acid-mediated inhibition forms a critical loop: as parietal cells secrete in response to initial stimulation, the resulting drop in luminal activates D cells to release , which in turn binds to type 2 (SST2) on G cells, halting further production. Paracrine signaling via somatostatin provides tonic restraint on G cell activity, independent of luminal pH changes, by diffusing locally from D cells to inhibit and through SST2-mediated pathways. Hormonal factors also contribute to this suppression; , released from duodenal S cells in response to acid, inhibits release from G cells, likely by enhancing somatostatin tone or direct receptor interactions. Similarly, cholecystokinin (CCK), secreted postprandially from duodenal I cells, acts as a physiological inhibitor of by stimulating somatostatin release from D cells or directly modulating G cell responsiveness via CCK receptors. Gastric inhibitory peptide (GIP), produced by K cells in the duodenum, suppresses food-stimulated release, contributing to the postprandial balance of gastric . Pharmacologically, proton pump inhibitors (PPIs) like omeprazole indirectly influence G cell inhibition by elevating gastric , which disrupts the acid-mediated feedback loop and reduces somatostatin-mediated suppression, often leading to compensatory hypergastrinemia during chronic use. This alteration highlights the pH-dependent nature of physiological inhibitors but underscores the need for careful management to avoid dysregulation.

Clinical significance

Disorders involving G cells

G cell hyperplasia refers to an increase in the number of G cells in the gastric antrum and , often resulting in hypergastrinemia due to elevated secretion. This condition is commonly secondary to hypochlorhydria or , where reduced acid feedback inhibition stimulates G cell proliferation; common triggers include long-term (PPI) therapy or conditions impairing acid production. In such cases, serum levels may rise significantly, sometimes exceeding 1000 pg/mL, promoting enterochromaffin-like (ECL) cell and increasing the risk of gastric neuroendocrine tumors. Zollinger-Ellison syndrome (ZES) arises from , which are neuroendocrine tumors originating from G-like cells that autonomously secrete excessive , independent of normal regulatory mechanisms. These tumors, typically located in the or within the "gastrinoma triangle," lead to profound hypersecretion, causing refractory peptic ulcers, severe , and from inactivated pancreatic enzymes. Approximately 20-30% of cases are associated with (MEN1), and approximately 25–30% present with metastases at diagnosis. In , G cell populations can be altered depending on the etiology and gastric region affected, often contributing to disrupted homeostasis and hypochlorhydria from concurrent loss. Autoimmune , targeting the gastric body and fundus, spares the and typically induces G cell due to achlorhydria-driven loss of acid inhibition, resulting in marked hypergastrinemia. In contrast, pylori-associated multifocal involving the leads to G cell atrophy and reduced density, causing hypochlorhydria alongside low serum levels and impaired digestive function. Histological alterations in G cell density are prominent in gastric and , reflecting premalignant changes in the mucosa. In , antral glands undergo transformation where gastrin-producing G cells are notably absent, replaced by intestinal-type epithelium lacking this cell population, which disrupts local signaling and contributes to ongoing . During progression to , G cell scarcity persists in metaplastic foci, with studies showing reduced G cell markers in dysplastic lesions compared to normal antral mucosa, potentially exacerbating acid dysregulation and cancer risk. Diagnostic evaluation of G cell-related disorders relies on key markers, particularly elevated fasting serum gastrin levels exceeding 1000 pg/mL. In the context of low gastric (≤2), this strongly suggests ZES due to inappropriate hypergastrinemia with hyperchlorhydria, whereas high gastrin with ( >6) indicates conditions such as G cell hyperplasia or autoimmune . The stimulation test is crucial for confirmation, especially in equivocal cases (gastrin 200-1000 pg/mL); administration of provokes a paradoxical rise in serum gastrin by ≥120 pg/mL in gastrinomas, distinguishing ZES from other causes of hypergastrinemia with high sensitivity (>90%).

Therapeutic implications

Proton pump inhibitors (PPIs), such as omeprazole, are widely used to treat acid-related disorders by irreversibly inhibiting the pump in parietal cells, thereby reducing secretion. This acid suppression disrupts the normal negative feedback on release, leading to sustained hypergastrinemia that stimulates antral G cells and can result in compensatory G cell hyperplasia over prolonged use. Despite this, PPIs effectively control symptoms like and pain in conditions such as (GERD) and peptic ulcers, with the hypergastrinemia generally reversible upon discontinuation. Gastrin receptor antagonists, particularly cholecystokinin-2 (CCK2) receptor blockers like netazepide, represent an experimental therapeutic approach for managing excessive gastrin signaling in Zollinger-Ellison syndrome (ZES), a condition characterized by gastrinomas causing severe acid hypersecretion. These antagonists competitively inhibit the CCK2 receptor on parietal cells and enterochromaffin-like (ECL) cells, suppressing acid production and mitigating the trophic effects of hypergastrinemia without the broad acid suppression of PPIs. Clinical studies have demonstrated their potential to reduce gastric acid output and tumor biomarkers in ZES patients, though they remain investigational pending larger trials. Somatostatin analogs, such as octreotide, offer targeted inhibition of excessive gastrin secretion in gastrinomas associated with ZES by binding to somatostatin receptors on tumor cells, thereby reducing hormone release and alleviating symptoms like refractory ulcers. Long-term administration of octreotide has shown efficacy in suppressing elevated gastrin levels, providing symptomatic relief, and exhibiting antitumor effects in progressive malignant gastrinomas, with response rates around 50% in metastatic cases. These agents are particularly valuable when surgery is not feasible, often used adjunctively with PPIs to control acid hypersecretion. Eradication therapy for infection, typically involving a combination of antibiotics (e.g., and amoxicillin) and a , restores normal G function by eliminating the bacterium's interference with antral regulatory mechanisms. H. pylori infection induces G cell hyper and hypergastrinemia through and inhibition of D cells, but successful eradication normalizes stimulated , reduces G cell , and enhances D cell populations within months. This intervention not only prevents progression to but also mitigates associated hypergastrinemia, improving overall gastric physiology. Gastrin serves as a valuable for detecting and monitoring gastric neuroendocrine tumors (GNETs), particularly type 1 tumors arising in autoimmune metaplastic , where elevated levels correlate with tumor prevalence and progression. In these contexts, hypergastrinemia drives ECL cell and neoplastic transformation, making serial measurements essential for early identification and surveillance post-treatment. Emerging therapies, such as CCK2 antagonists, leverage this biomarker by normalizing levels and inducing tumor regression in preclinical and early clinical settings.