Gastric Function

The mucosa is composed of surface epithelial cells and glands

The basic structure of the stomach wall is similar to that of other regions of the gastrointestinal (GI) tract (see Fig. 41-2 ); therefore, the wall of the stomach consists of both mucosal and muscle layers. The stomach can be divided, based on its gross anatomy, into three major segments ( Fig. 42-1 ): (1) A specialized portion of the stomach called the cardia is located just distal to the gastroesophageal junction and is devoid of the acid-secreting parietal cells. (2) The body or corpus is the largest portion of the stomach; its most proximal region is called the fundus. (3) The distal portion of the stomach is called the antrum. The surface area of the gastric mucosa is substantially increased by the presence of gastric glands, which consist of a pit, a neck, and a base. These glands contain several cell types, including mucous, parietal, chief, and endocrine cells; endocrine cells also are present in both corpus and antrum. The surface epithelial cells, which have their own distinct structure and function, secrete and mucus.

Marked cellular heterogeneity exists not only within segments (e.g., glands versus surface epithelial cells) but also between segments of the stomach. For instance, as discussed below, the structure and function of the mucosal epithelial cells in the antrum and body are quite distinct. Likewise, although the smooth muscle in the proximal and distal portions of the stomach appear structurally similar, their functions and pharmacological properties differ substantially.

With increasing rates of secretion of gastric juice, the H ⁺ concentration rises and the Na ⁺ concentration falls

The glands of the stomach typically secrete ~2 L/day of a fluid that is approximately isotonic with blood plasma. As a consequence of the heterogeneity of gastric mucosal function, early investigators recognized that gastric secretion consists of two distinct components: parietal-cell and nonparietal-cell secretion. Accordingly, gastric secretion consists of (1) an Na ⁺ -rich basal secretion that originates from nonparietal cells, and (2) a stimulated component that represents a pure parietal-cell secretion that is rich in H ⁺ . This model helps to explain the inverse relationship between the luminal concentrations of H ⁺ and Na ⁺ as a function of the rate of gastric secretion ( Fig. 42-2 ). Thus, at high rates of gastric secretion—for example, when gastrin or histamine stimulates parietal cells—intraluminal [H ⁺ ] is high whereas intraluminal [Na ⁺ ] is relatively low. At low rates of secretion or in clinical situations in which maximal acid secretion is reduced (e.g., pernicious anemia N42-1 ), intraluminal [H ⁺ ] is low but intraluminal [Na ⁺ ] is high.

The proximal portion of the stomach secretes acid, pepsinogens, intrinsic factor, bicarbonate, and mucus, whereas the distal part releases gastrin and somatostatin

The stomach accommodates food, mixes it with gastric secretions, grinds it, and empties the chyme into the duodenum

In addition to its secretory properties, the stomach also has multiple motor functions. These functions are the result of gastric smooth-muscle activity, which is integrated by both neural and hormonal signals. Gastric motor functions include both propulsive and retrograde movement of food and liquid, as well as a nonpropulsive movement that increases intragastric pressure.

Similar to the heterogeneity of gastric epithelial cells, considerable diversity is seen in both the regulation and contractility of gastric smooth muscle. The stomach has at least two distinct areas of motor activity; the proximal and distal portions of the stomach behave as separate, but coordinated, entities. At least four events can be identified in the overall process of gastric filling and emptying: (1) receiving and providing temporary storage of dietary food and liquids; (2) mixing food and water with gastric secretory products, including pepsin and acid; (3) grinding food so that particle size is reduced to enhance digestion and to permit passage through the pylorus; and (4) regulating the exit of retained material from the stomach into the duodenum (i.e., gastric emptying of chyme) in response to various stimuli.

The mechanisms by which the stomach receives and empties liquids and solids are significantly different. Emp­tying of liquids is primarily a function of the smooth muscle of the proximal part of the stomach, whereas emptying of solids is regulated by antral smooth muscle.

The parietal cell has a specialized tubulovesicular structure that increases apical membrane area when the cell is stimulated to secrete acid

In the basal state, the rate of acid secretion is low. Tubulovesicular membranes are present in the apical portion of the resting, nonstimulated parietal cell and contain the H-K pump (or H,K-ATPase) that is responsible for acid secretion. Upon stimulation, cytoskeletal rearrangement causes the tubulovesicular membranes that contain the H-K pump to fuse into the canalicular membrane ( Fig. 42-3 ). The result is a substantial increase (50- to 100-fold) in the surface area of the apical membrane of the parietal cell, as well as the appearance of microvilli. This fusion is accompanied by insertion of the H-K pumps, as well as K ⁺ and Cl ⁻ channels, into the canalicular membrane. The large number of mitochondria in the parietal cell is consistent with the high rate of glucose oxidation and O ₂ consumption that is needed to support acid secretion.

An H-K pump is responsible for gastric acid secretion by parietal cells

The parietal-cell H-K pump is a member of the gene family of P-type ATPases (see pp. 117-118 ) that includes the ubiquitous Na-K pump (Na,K-ATPase), which is present at the basolateral membrane of virtually all mammalian epithelial cells and at the plasma membrane of nonpolarized cells. Similar to other members of this ATPase family, the parietal-cell H-K pump requires both an α subunit and a β subunit for full activity. The catalytic function of the H-K pump resides in the α subunit; however, the β subunit is required for targeting to the apical membrane. N42-3 The two subunits form a heterodimer with close interaction at the extracellular domain.

The activity of these P-type ATPases, including the gastric H-K pump, is affected by inhibitors that are clinically important in the control of gastric acid secretion. The two types of gastric H-K pump inhibitors are (1) substituted benzimidazoles (e.g., omeprazole), which act by binding covalently to cysteines on the extracytoplasmic surface; and (2) substances that act as competitive inhibitors of the K ⁺ -binding site (e.g., the experimental drug Schering 28080). Omeprazole is a potent inhibitor of parietal-cell H-K pump activity and is an extremely effective drug in the control of gastric acid secretion in both normal subjects and patients with hypersecretory states ( Box 42-1 ). In addition, H-K pump inhibitors have been useful in furthering understanding of the function of these pumps. Thus, ouabain, a potent inhibitor of the Na-K pump, does not inhibit the gastric H-K pump, whereas omeprazole does not inhibit the Na-K pump. The colonic H-K pump, whose α subunit has an amino-acid sequence that is similar but not identical to that of both the Na-K pump and the parietal-cell H-K pump, is partially inhibited by ouabain but not by omeprazole.

The key step in gastric acid secretion is extrusion of H ⁺ into the lumen of the gastric gland in exchange for K ⁺ ( Fig. 42-4 ). The K ⁺ taken up into the parietal cells is recycled to the lumen through K ⁺ channels. The final component of the process is passive movement of Cl ⁻ into the gland lumen. The net result is the secretion of HCl. Secretion of acid across the apical membrane by the H-K pump results in a rise in parietal-cell pH. The adaptive response to this rise in pH includes passive uptake of CO ₂ and H ₂ O, which the enzyme carbonic anhydrase (see p. 630 ) converts to and H ⁺ . The H ⁺ is the substrate of the H-K pump. The exits across the basolateral membrane via a Cl-HCO ₃ exchanger (AE2 or SLC4A2), which also provides some of the Cl ⁻ required for net HCl movement across the apical/canalicular membrane. The basolateral Na-H exchanger may participate in intracellular pH regulation, especially in the basal state.

Three secretagogues (acetylcholine, gastrin, and histamine) directly and indirectly induce acid secretion by parietal cells

The action of secretagogues on gastric acid secretion occurs via at least two parallel and perhaps redundant mechanisms ( Fig. 42-5 ). In the first, acetylcholine (ACh), gastrin, and histamine bind directly to their respective receptors on the parietal-cell membrane and synergistically stimulate acid secretion. ACh (see Fig. 14-8 ) is released from endings of the vagus nerve (cranial nerve X), and as we will see below, gastrin is released from G cells. Histamine is synthesized from histidine in ECL cells of the lamina propria (see Fig. 13-8 B ). In the second mechanism, ACh and gastrin indirectly induce acid secretion as a result of their stimulation of histamine release from ECL cells.

The three acid secretagogues act through either Ca ²⁺ /diacylglycerol or cAMP

Stimulation of acid secretion by ACh, gastrin, and histamine is mediated by a series of intracellular signal-transduction processes similar to those responsible for the action of other agonists in other cell systems. All three secretagogues bind to specific G protein–coupled receptors on the parietal-cell membrane ( Fig. 42-6 ).

ACh binds to an M ₃ muscarinic receptor (see pp. 341–342 ) on the parietal-cell basolateral membrane. This ACh receptor couples to a GTP-binding protein (Gα _q ) and activates phospholipase C (PLC), which converts phosphatidylinositol 4,5-bisphosphate (PIP ₂ ) to inositol 1,4,5-trisphosphate (IP ₃ ) and diacylglycerol (DAG; see p. 58 ). IP ₃ causes internal stores to release Ca ²⁺ , which then probably acts via calmodulin-dependent protein kinase (see p. 60 ). DAG activates protein kinase C (PKC). The M ₃ receptor also activates a Ca ²⁺ channel.

Gastrin binds to a specific parietal-cell receptor that has been identified as the gastrin-cholecystokinin type 2 (CCK ₂ ) receptor. Two related CCK receptors have been identified, CCK ₁ and CCK ₂ . Their amino-acid sequences are ~50% identical, and both are G protein coupled. The CCK ₂ receptor has equal affinity for both gastrin and CCK. In contrast, the CCK ₁ receptor's affinity for CCK is three orders of magnitude higher than its affinity for gastrin. These observations and the availability of receptor antagonists are beginning to clarify the parallel, but at times opposite, effects of gastrin and CCK on various aspects of GI function. The CCK ₂ receptor couples to Gα _q and activates the same PLC pathway as does ACh; this process leads to both an increase in [Ca ²⁺ ] _i and activation of PKC.

The histamine receptor on the parietal cell is an H ₂ receptor that is coupled to the Gα _s GTP-binding protein. Histamine activation of the receptor complex stimulates the enzyme adenylyl cyclase, which, in turn, generates cAMP. The resulting activation of protein kinase A leads to the phosphorylation of certain parietal-cell proteins, including the H-K pump.