Physiology of the Salivary Glands

Mechanisms of Primary Fluid Secretion

Fluid transport in salivary glands is thought to be driven osmotically in response to transepithelial salt gradients. These gradients are generated by ion transport systems localized to the luminal and basolateral membranes of the acinar cell. On the basis of studies in rabbit and rat salivary glands, three mechanisms for primary fluid secretion by the acini have been proposed. These mechanisms ( Fig. 81.2 ) appear to operate concurrently in the same gland and possibly in the same acinar cell. The relative importance of each of these mechanisms varies from species to species, gland type to gland type, and possibly from physiologic status to physiologic status.

Fluid secretion in the acini is the result of the combined action of four membrane transport systems: (1) a Na ⁺ /K ⁺ /2Cl ⁻ cotransporter located in the basolateral membrane of the acinar cell; (2) a calcium (Ca ²⁺ )-activated K ⁺ channel in the basolateral membrane; (3) a calcium-activated Cl ⁻ channel localized to the apical membrane; and (4) an adenosine triphosphatase (ATPase)-driven Na ⁺ /K ⁺ pump in the basolateral membrane. In the resting or unstimulated state, both K ⁺ and Cl ⁻ are concentrated in the acinar cell above the electrochemical equilibrium, the former by the Na ⁺ /K ⁺ -ATPase and the latter via the Na ⁺ /K ⁺ /2Cl ⁻ cotransporter.

In the first mechanism of saliva secretion (see Fig. 81.2A ), stimulation by the autonomic nervous system, leads to a rise in intracellular calcium concentration, which results in the opening of the basolateral Ca ²⁺ -activated K ⁺ channels and the apical calcium-activated Cl ⁻ channels. This increase in K ⁺ and Cl ⁻ conductance allows KCl to flow out of the cell, which results in an accumulation of Cl ⁻ ions and their associated negative electrical charge in the acinar lumen. Sodium in the interstitium then follows Cl ⁻ as a result of electrical attraction, by leaking through the tight junctions between the cells into the acinar lumen. The resulting osmotic gradient for NaCl causes a transepithelial movement of water from the interstitium into the acinar lumen. In the continued presence of the agonist, a net transepithelial chloride flux and a concomitant secretion of fluid are sustained because of Cl ⁻ entry via the Na ⁺ /K ⁺ /2Cl ⁻ cotransporter and exit via the apical Cl ⁻ channel. When the stimulus is removed, the intracellular calcium concentrations fall to resting levels, the K ⁺ and Cl ⁻ channels close, and the cell returns to its resting state. For this model to operate continuously, it must satisfy the constraints of mass and charge balance; in other words, in the steady state, ion transport must be such that neither mass nor charge is continually accumulated in or depleted from the cell. These constraints, along with the known stoichiometries of the Na ⁺ /K ⁺ /2Cl ⁻ cotransporter (1Na ⁺ : K ⁺ : 2Cl ⁻ ) and the Na ⁺ /K ⁺ -ATPase (3Na ⁺ : 2K ⁺ : 1ATP), determine the relative fluxes of ions per cycle: six chloride ions are translocated from the interstitium to the acinar lumen for each ATP molecule hydrolyzed by the Na ⁺ /K+-ATPase.

The second mechanism (see Fig. 81.2B ) is similar to the first mechanism except that in this model, a basolateral exchanger, in parallel with an Na+/H+ exchanger, replaces the Na+/K+/2Cl ⁻ cotransporter. Decreases in intracellular chloride concentrations resulting from secretagogue-induced KCl loss lead to increased Cl ⁻ entry in exchange for via the exchanger. The cytoplasmic acidification that results from this bicarbonate loss is buffered by the Na ⁺ /H ⁺ exchanger, which uses the extracellular-to-intracellular sodium gradient generated by the Na ⁺ /K ⁺ -ATPase to drive protons out of the cell. The net result is the movement of NaCl into the cell in exchange for H ₂ CO ₃ , which in turn is recycled across the basolateral membrane as CO ₂ after hydrolysis by carbonic anhydrase. In this model, three chloride ions are translocated from the interstitium to the acinar lumen for every ATP molecule hydrolyzed. Sodium and water follow the chloride into the acinar lumen from the interstitium.

In contrast to mechanisms 1 and 2, in which chloride is the secreted anion, mechanism 3 (see Fig. 81.2C ) involves apical bicarbonate secretion. In this model, carbon dioxide (CO ₂ ) enters the acinar cell across the basolateral membrane and is converted to plus a proton by carbonic anhydrase. The bicarbonate is lost across the apical membrane via an anion channel, possibly the same channel involved in chloride secretion, and the protein is extruded by the basolateral Na ⁺ /H ⁺ exchanger. In this model, three bicarbonate ions are secreted for every ATP molecule hydrolyzed. Sodium and water follow the secreted bicarbonate ions into the acinar lumen.

Mechanisms of Primary Macromolecule Secretion

The protein subcomponent of saliva is derived primarily from secretory granules of the acinar and ductal cells. Secretory proteins are discharged into the lumen of the secretory unit by a process of exocytosis, wherein fusion of secretory granules with a delimited portion of the plasmalemma of the apical membrane occurs. The membrane fusion is the last of a series of steps required for the transfer of export proteins from their synthesis in the rough endoplasmic reticulum (RER) to the extracellular environment. According to the model offered by Palade, the secretory process can be divided into six steps: (1) synthesis, (2) segregation, (3) intracellular transport, (4) concentration, (5) intracellular storage, and (6) discharge.

The synthesis of secretory proteins requires the uptake of amino acids by the cell, which is accomplished via an active transport mechanism in the basolateral surface of the cell. Transfer ribonucleic acids then deliver the amino acids to the ribosomes of the RER, where messenger ribonucleic acids are translated into polypeptides. Before transport of these polypeptides from the RER to the Golgi apparatus, they undergo some posttranslational modifications and are segregated in the cisternal space of the RER. Segregation is regarded as an irreversible step. From the RER, polypeptides are transported to the Golgi apparatus via an ATP-dependent mechanism. In this apparatus, polypeptides undergo further posttranslational modifications, such as terminal glycosylation, and are concentrated. At this step the polypeptides are transferred from a high-permeability membrane to a membrane with characteristics similar to those of the plasmalemma, forming secretory granules. On appropriate stimulation from the autonomic nervous system, the secretory granules discharge their contents into the glandular lumen by the process of exocytosis. The membrane of the secretory granule fuses with the plasmalemma, bringing into continuity the contents of the secretory granule and the extracellular lumen and at the same time maintaining a diffusion barrier between the interior of the cell and the extracellular medium. The mechanism by which the cell recycles the apical membrane is not completely understood but likely involves the process of endocytosis and the selective degradation of endocytic vesicles.

Mechanisms of Ductal Secretion

Ductal secretion is not constant, and the underlying mechanisms are only partially understood. Microperfusion studies of excretory ducts have confirmed the ability of ductal cells to modify saliva by reabsorbing sodium and chloride and secreting potassium and bicarbonate to produce the final hypotonic solution. In addition, ductal cells have the ability to secrete some protein into the ductal lumen. In general, when the salivary flow rate is slow, more time is available in which ion transfer can occur across the tubular cells, which results in greater modification of the secretory fluid. When the flow rate is high, however, the contact period is shortened, and this diminishes the influence of the tubular cells on solute concentration. The exception to this rule is that conditions stimulating increased flow rates also stimulate increased bicarbonate secretion.

Neuronal Control of Secretion

In general, significant secretion from the human salivary glands occurs only in response to stimulation by the autonomic nervous system or the action of substances that can mimic the effects of such stimulation. Both sympathetic and parasympathetic nerves innervate the salivary glands, although the effects of the parasympathetic nerves predominate. Nevertheless, it is likely that the two components of the autonomic nervous system have a synergistic effect on salivary gland function. Parasympathetic stimulation is the principal impetus for salivary gland fluid secretion. In addition, parasympathetic stimulation leads to some exocytosis and protein secretion, myoepithelial contraction, and vasodilation. Sympathetic stimulation is a weak mobilizer of salivary fluid, although its effect may be additive to that of the parasympathetic system. On the other hand, sympathetic stimulation causes high levels of protein secretion, myoepithelial contraction, and maintenance of vascular tone. In general, parasympathetic stimulation leads to the output of saliva that has a large volume and low protein content, whereas sympathetic stimulation leads to the secretion of low volumes of saliva with high protein content.

The innervation patterns of the major salivary glands differ considerably among species, subjects, and cell types. The parasympathetic supply to the parotid gland originates in the inferior salivatory nucleus and travels with the glossopharyngeal nerve and then with the Jacobson nerve to the otic ganglion, where it synapses. The postganglionic fibers are carried by the auriculotemporal branch of the trigeminal nerve to the parotid gland. The parasympathetic supply to the submandibular gland originates in the superior salivatory nucleus and travels via the nervus intermedius and chorda tympani to the submandibular ganglion. Some of these fibers synapse in the ganglion, whereas others synapse in the gland itself. The sympathetic supply to the parotid and submandibular glands originates from the superior cervical ganglion and follows major arterial blood vessels to reach the various salivary glands. Nerve fibers of the parasympathetic and sympathetic nervous systems are distributed in a similar fashion around the acini and intercalated ducts and are striated, although the parasympathetic fibers predominate. Myoepithelial cells are similarly liberally innervated, whereas the collecting ducts are sparsely innervated. In contrast to other organ systems such as skeletal muscles, which contain a well-defined neuronal synapse at the axon–effector organ interface, secretory cells have unmyelinated fibers of the parasympathetic and sympathetic systems that lie in close proximity to the effector cell. These axonal fibers can lie either outside (epilemmal fibers) or inside (hypolemmal fibers) the basement membrane of the effector cell. Neurotransmitters released from the axon presumably reach the secretory cell by diffusion. These neurotransmitters, as well as other hormones and regulatory molecules, affect the function of salivary cells in a complex manner that is poorly understood.