Lecture 16: Secretions of the GI tract and Pancreas

Question 1

What is the function of saliva?

Answer 1

• Initial digestion of Starches and lipids
• Dilution and buffering of ingested food
• Lubrication of ingested food w/ mucus

Question 2

What are Parotid glands?

Answer 2

• Composed of serous cells
• Secrete fluids composed of water, ions, enzymes (rich in amylase)
• Secrete 25% of the daily output of saliva

Question 3

What are submaxillary and Sublingual glands?

Answer 3

• Composed of serous and mucous cells
• Secrete aqueous fluid and mucin glycoprotein for lubrication
• Secrete majority, 75%, of daily output of saliva

Question 4

Describe the structure/function of a salivary gland (acinus, myoepithelial cells, intercalated duct, and striated ducts)

Answer 4

Acinus (blind end) - acinar cells secrete initial saliva

Myoepithelial cells - motile extensions, when stimulated by neural input, contract to eject saliva into the mouth

Intercalated duct - saliva here is similar in ionic composition to plasma

Striated duct - modify the initial saliva to produce the final saliva (hypotonic), alter the concentration of various electrolytes

Question 5

What is saliva composed of?

Answer 5

H2O, electrolytes, α-amylase, lingual lipase, kallikrein, and mucus

Question 6

What are the concentrations of electrolytes that make saliva hypotonic compared to plasma?

Answer 6

Increased K+ & HCO3 concentrations

Decreased Na+ & Cl- concentrations

Question 7

What are the 2 main steps in the formation of saliva and the cells involved?

Answer 7

1) Formation of isotonoc, plasma-like, solution by acinar cells
2) Modification of the isotonic solution by the ductal cells

Question 8

What are the transport mechanism occuring on the lumen/apical side of the salivary ductal cell?

Answer 8

Na+/H+ exchanger

Cl-/HCO3- exchanger

H+/K+ exchanger

Question 9

What are the transport mechanism occurs on the blood/basolateral side of the salivary ductal cell?

Answer 9

• Na+/K+ ATPase
• Cl- channels
• HCO3-/Na+ symporter

Question 10

During salivary secretion what is the combined action of solute movement and what is the net effect; why does it become hypotonic?

Answer 10

• Absorption of Na+ and Cl- (lower compared to plasma)
• Secretion of K+ and HCO3- (higher compared to plasma)
• Net absorbtion of solute (more NaCl is absorbed than KHCO3 secreted), and because ductal cells are impermeable to water the solution can become hypotonic

Question 11

How does saliva become hypotonic as it flows through the ducts?

Answer 11

Ductal cells are impermeable to H2O

Question 12

Discuss the ANS innervations of salivary glands, which is the dominant effect; why is this one of our exceptions?

Answer 12

PNS - presynaptic nerves originate at facial (CN VII) and glossopharyngeal (CN IX) nerves - PNS is DOMINANT effect

SNS - preganglionic nerves originate at the cervical ganglion, whose postganglionic fibers extend to gands in the periarterial space

*BOTH PNS and SNS stimulate salivary secretion - one of the exceptions

Question 13

What stimulants activate and inhibit the PNS for salivary secretion, describe the pathway?

Answer 13

• Conditioning, food, nausea, smell (activators)
• Dehydration, fear, and sleep (inhibitors)
• Presynaptic nerves of CN VII or IX will release ACh that binds to a mAChR –> Increases IP3 and Ca2+ in the acinar or ductal cells, which will increase the secretion of saliva

Question 14

Decribe the SNS innervation pathway for secretion of saliva

Answer 14

• Pre-ganglionic nerves from T1-T3 synapse at cervical ganglion.
• Post-ganglionic sympathetic neurons release NE, which interacts w/ β-adrenergic receptors on acinar and ductal cells.
• Activation of these receptors leads to stimulation of adenyly cyclase and production of cAMP, which leads to increased saliva production

Question 15

Stimulation of salivary cells results in what 3 things?

Answer 15

1. Increased saliva production
2. Increased HCO3 and enzyme secretion
3. Contraction of myoepithelial cells

Question 16

What effects do Vasopressin and aldosterone have on the composition of saliva?

Answer 16

Modify composition by decreasing its [Na+] and increasing its [K+]

Question 17

What are the 2 unusual features in the regulation of salivary secretion?

Answer 17

• Salivary is exclusively under the control of the ANS
• Salivary secretion is increased by BOTH the PNS and SNS (generally these 2 have opposite actions in the GI tract)

Question 18

What are the main components secreted in gastric juice?

Answer 18

• HCL (H+)
• Pepsinogen
• Mucus
• Intrinsic factor
• H2O

Question 19

What is the function of HCL (H+) in gastric juice?

Answer 19

• Together w/ pepsin, it initiates protein digestion
• Necessary for conversion of pepsinogen to pepsin
• Kills a large # of bacteria that enter the stomach

Question 20

Function of the mucus secreted in gastric juice?

Answer 20

• Lines the wall of stomach and protects it from damage
• Lubricant
• Together w/ HCO3, it neutralizes acid and maintains the surface of mucosa at neutral pH

Question 21

Function of Intrinsic Factor (IF) secreted in gastric juice?

Answer 21

Required for the absorption of vitamin B12 in the ileum

Question 22

What are the 2 gland divisions of the gastric mucosa, where is each found, and what is the function of each?

Answer 22

Oxyntic gland - proximal 80% of stomach (body and fundus), secretes acid

Pylroic gland - distal 20% of stomach (antrum), synthesizes and releases gastrin

Question 23

What cells types are found in the oxyntic gland and what does each secrete?

Answer 23

• Mucous neck cell: mucus and pepsinogen
• Parietal cells: HCL and IF
• Enterochromaffin-like cell: Histamine
• D cell: Somatostatin
• Chief cell: Pepsinogen
• Enterochromaffin cell (ANP): Serotonin

Question 24

What cell types are found in the pyloric gland and what does each secrete?

Answer 24

• Mucous neck cell: mucus and pepsinogen
• G cell: gastrin
• D cell: somatostatin

Question 25

What does the # of parietal cells determine?

Answer 25

Maximal secretory rate

Question 26

What is the function of the low gastric pH (1-2) and where is HCL formed?

Answer 26

• Low pH converts pepsinogen to pepsin
• HCL is formed at the villus-like membranes of the canaliculi

Question 27

Atropine blocks what component of the ANS during salivarys secretion?

Answer 27

Blocks ACh binding to mAChR

Question 28

Discuss the cellular mechanism of HCL secretion by gastric parietal cells

Answer 28

• CO2 + H2O inside cells are converted to H2CO3 by carbonic anhydrase, which is then quickly converted to H+ and HCO3-
• On the luminal/apical side: there is a K+/H+ ATPase, which moves H+ into the lumen and Cl- will follow H+ to form HCL
• On the basolateral/blood side: there is an Na+/K+ ATPase moving Na+ out and K+ into the cell. There is also a HCO3/Cl- exchanger that moves Cl- into the cell and HCO3- out.

Question 29

What effect does Omeprazole have on gastric parietal cells; used in the treatment of?

Answer 29

• Inhibits the K+/H+ ATPase so that less H+ is secreted into the lumen which ultimately decreases HCL
• Used in the treatment of ulcers

Question 30

What is the net effect of the cellular mechanism of gastric parietal cells?

Answer 30

Net secretion of HCL and net absorption of HCO3-

Question 31

What is Alkaline tide?

Answer 31

This occurs after a meal where during the production of HCL by parietal cells more HCO3- is entering the blood and raising the pH

Question 32

What are the agents that stimulate H+ secretion by gastric parietal cells?

Answer 32

Vagus n releases ACh to an mAChR –> Gq –> IP3/Ca2+

G cells release gastrin to CCKβ receptor –> Gq –> IP3/Ca2+

ECL cells release Histamin to H2 receptor –> Gs –> cAMP

*These pathways all lead to activation of H+/K+ ATPase and the secretion of H+

Question 33

What are the agents that inhibit H+ secretion by gastric parietal cells?

Answer 33

• Somatostatin and Prostaglandins –> Gi —> inhibit cAMP
• Somatostatin can also inhibit ECL cells and G cells
• Prostaglandins can inhibit ECL cells

Question 34

What effect does Cimetidine have on the secretion of H+ by gastric parietal cells and what is it used to treat?

Answer 34

• Antagonst of H2 receptors, which block histamines action
• Used to treat duodenal/gastric ulcers, and GERD

Question 35

Why are prostaglandins important within the stomach and what effect does NSAIDs have on them?

Answer 35

• Protect the lining of the GI by decreasing gastric acid production, decreasing blood flow, and producing mucous
• NSAIDs will inhibit the actions of Prostaglandins

Question 36

What is the passive feedback mechanism for regulatng HCL secretion?

Answer 36

As the pH falls, gastrin release is inhibited, which will decrease the amount of HCL secreted

Question 37

Discuss how the role of the vagus nerve on HCL secretion from parietal cells is twofold; how does Atropine play a role here?

Answer 37

• There is a direct and indirect pathway of vagus nerve stimulation
• Direct: release of ACh to parietal cells (Atropine can block ACh)
• Indirect: GRP is released from vagus to G cells, which increases gastrin secretion (Atopine will NOT block the vagal affects on gastrin secretion due to the NT being GRP)

Question 38

How is the rate of HCL secretion potentiated by histamine, ACh, and gastrin?

Answer 38

• Histamine potentiates the action sof ACh and gastrin
• ACh potentiates the actions of histamine and gastrin

*Potentiation is a combined response to 2 stimulants, which exceed the sum of their individual responses

Question 39

What are the pharmological implications due to the potentiation effect produced by histamine, ACh, and gastrin?

Answer 39

• Antagonists of H2 receptors (i.e., Cimetidine) block the direct action of histamine and also block potentiated effects of ACh and gastrin
• Antagonist of mAChRs (i.e., Atropine) blocl the direct effects of ACh and the ACh-potentiated effects of histamine and gastrin

Question 40

What are the 3 phases of gastric HCL secretion?

Answer 40

1. Cephalic phase (30% total HCL secreted): via vagus
2. Gastric phase (60% total HCL secreted): local nervous secretory reflexes, vagal reflexes, and gastrin-histamine stimulation
3. Intestinal phase (10% total HCL secreted) - nervous mechanisms and hormonal mechanisms

Question 41

What are the stimuli and mechanism for the cephalic phase of gasrtic HCL secretion; what is the effect of vagotomy on this phase?

Answer 41

Stimuli: smelling, tasting, chewing, swallowing, and conditioning

• Mechanisms:
• Vagus releases ACh to parietal cell = HCL secretion
• Vagus releases GRP to G cells = gastrin secretion, which is delivered back to the stomach to stimulate HCL secretion from parietal cells

*Vagotomy abolishes this phase*

Question 42

What are the stimuli for the gastric phase of gastric HCL secretions

Answer 42

Stimuli: distention of stomach and presence of broken down proteins, AA’s and small peptides

Question 43

What are the mechanisms involved in the gastric phase of gastric HCL secretion (4 of them)?

Answer 43

Mechanisms: Distention activates mechanoreceptors in the mucosa of oxyntic and pyloric glands

• Vagus nerve releases ACh to parietal cells = stimulates HCL secretion
• Vagus nerve releases GRP to G cells = secretion of gastrin, which travels to parietal cells and stimulates HCL secretion
• Distention of antrum causes local pyloropyloric reflex –> gastrin –> parietal cells
• AA’s and small peptides causes gastrin release to parietal cells

Question 44

What effect does coffee (caffeinated and decaffeinated) have on gastric HCL secretion?

Answer 44

Stimulates gastric HCL secretion

Question 45

What leads to the HCL secretion during the intestinal phase?

Answer 45

• Distention of small intestine stimulates acid secretion
• Digested protein stimulates acid secretion via direct effect on parietal cell: gastrin (intestinal G cells) –> parietal cell

Question 46

What is the non-parietal component of gastric juice composed of?

Answer 46

• Basal alkaline secretion of constant and low volume
• Primarly Na+, Cl+ and K+ at same concentration as plasma
• HCO3 is secreted at a concentration of ~30 mEq/L

Question 47

Waht is the parietal component of gastric juice composed of?

Answer 47

• Slightly hyperosmotic
• Contains 150-160 mEq H+/L and 10-20 mEq K+/L
• Cl- is the only anion present
• As the secretion rate increases, the concentration of electrolytes begins to approach those of pure parietal juices

Question 48

How is the release of gastrin regulated by somatostatin, gastrin, H+ and vagus stimulation?

Answer 48

• Somatostatin acts on G cells to inhibit gastrin release
• Vagal activation stimulates gastrin release through GRP and inhbits the release of somatostatin
• Negative feedback by gastrin causes increased somatostatin
• H+ in gastric lumen stimulates the release of somatostatin

Question 49

What is the most important stimuli for pepsinogen release, where is it released from, and what is the pH requirement?

Answer 49

• Secreted by Chief and Mucus cells in the oxyntic glands
• Requires H+ secretion from parietal cells to lower pH <5
• Vagus is the most important stimulus
• H+ triggers local cholinergic reflexes that stimulate chief cells to secrete pepsinogen

Question 50

What effect does pepsin have on pepsinogen?

Answer 50

Pepsin converts more pepinogen to pepsin

Question 51

What is the function of pepsin and what is its optimal pH, when is it reversibl activated, and irreversibly activated?

Answer 51

• Proteolytic enzyme, splits interior peptide linkages
• Optimal pH: 1.8 -5.5
• Reversibly inactivated: pH >5.0
• Irreversibly inactivated: pH >7-8

Question 52

What is intrinsic factor and why is it so important?

Answer 52

• Mucoprotein secreted by parietal cells
• Binds to and protects B12 for absorption in the Ileum
• ONLY secretion by the stomach that is required (essential)

Question 53

What does failure to secrete IF by parietal cells lead to?

Answer 53

• Pernicious anemia

Question 54

What are common underlying causes of pernicious anemia?

Answer 54

• Atrophic gastritis: chronic inflammation of the stomach mucosa that leads to loss of parietal cells
• Autoimmune metaplastic atrophic gastritis: immune system attacks IF protein or gastric parietal cells

Question 55

How does the gastric mucosal barrier protect the gastric mucosal epithelium against the HCL and pepsin?

Answer 55

• Mucous neck cells secrete mucus
• Gastric epithelial cells secrete HCO3

Question 56

What substances protect the gastric mucosa?

Answer 56

Mucous, HCO3, prostaglandins (i.e., Misoprostol), mucosal blood flow, gastrin, and growth factors

Question 57

What substances damage the gastric mucosa?

Answer 57

Acid, pepsin, NSAIDs, H. pylori, alcohol, smoking, bile, and stress

Question 58

What is Zollinger-Ellison syndrome, causes, and mechanism of the disease?

Answer 58

• Tumor, usually in the pancreas, secretes large quanities of gastrin, which increases H+ secretion by parietal cells and increases parietal cell mass (trophic effect)
• Excessvie H+ arrives to duodenum and overwhelms the buffer capacity of HCO3, creating an ulcer
• Low duodenal pH inactivates pancreatic lipase –> steatorrhea

Question 59

What is the Secretin stimulation test?

Answer 59

• Used in the dx of gastrin-secreting tumors (i.e., Zollinger-Ellison)
• Under normal conditions, secretin administration inhibits gastrin release
• In gastrinomas, injection of secretin causes a paradoxical increase in gastrin release

Question 60

What are the predominate causes of peptic ulcer disease, and what are the two types?

Answer 60

• H. pylori infection and the use of NSAIDs
• Gastric and duodenal ulcers

Question 61

How is H. pylori able to damage the gastric mucosa; what is a common diagnostic test based on?

Answer 61

• Releases cytotoxins that break down the barrier and underlying cells
• Release urease which converts urea –> NH3, which alkalinizes the local enviornment. The NH3 reacts w/ H+ –> NH4+ (ammonium).
• Common diagnostic test based on urease activity

Question 62

Where do gastric ulcers form, major cause, and how do they differ from duodenal ulcers?

Answer 62

• Form on lining of stomach
• Gastric mucosal barrier is defective, as opposed to increased H+ secretion seen in duodenal ulcers
• Major causative agent = H. pylori

Question 63

Where do duodenal ulcers form, major cause, and difference from gastric ulcers?

Answer 63

• Form on lining of the duodenum
• More common than gastric ulcers and H+ secretion rates are higher than normal
• H. pylori is a major etiologic factor

Question 64

What are the secretory cells of the exocrine pancreas and what does each secrete?

Answer 64

• Acinus: lined by acinar cells that secrete enzymes
• Ducts: lined by ductal epithelial cells; extends to the region in the acinus containing centroacinar cells. Ductal and centroacinar cells secrete the aqueous solution containing HCO3

Question 65

What are the enzymes secreted by acinar cells of the pancreas?

Answer 65

• Amylases and lipases are secreted as active enzymes
• Proteases are secreted in inactive forms and converted to their active forms in the lumen of the duodenum

Question 66

What is produced by pancreatic centroacinar and ductal cells; what happens to the initial secretion?

Answer 66

• Produce initial aqueous solution which is isotonic and contains Na+, K+, Cl-, and HCO3-
• Initial secretion is modified by transport processes in the ductal epithelial cells

Question 67

What are the transport mechanism inside the pancreatic ductal cell, on the luminal/apical side, and on the basolateral/blood side?

Answer 67

• Inside ductal cell CO2 + H2O is converted to H2CO3 by carbonic anhydrase, which quickly dissociates into HCO3 and H+
• Luminal side: HCO3 is sent to lumen in exhchange for Cl-
• Basolateral side: Na+/K+ ATPase brings K+ in and a Na+/H+ exhanger gets H+ out of the cell into the blood

*Na+ is free to travel between pancreatic ductal cells to be used by the Na+/H+ exchanger

Question 68

What is the net result of tranport mechanisms by the pancreatic ductal cells?

Answer 68

Secretion of HCO3 into pancreatic ductal juice and net absorption of H+ into blood

Question 69

How does cystic fibrosis affect the pancreas?

Answer 69

• One of the 1st organs to fail in CF patients
• Mutations in the CFTR, a regulated Cl- channel in the apical surface of the duct cells, leads to a decrease in HCO3 secretion
• Pancreas loses ability to flush active enzymes out of the duct
• May lead to recurrent acute and chronic pancreatitis

Question 70

What is the cephalic phase of pancreatic secretion, stimuli, mediated by, and what does it produce?

Answer 70

Stimuli: smell, taste, and conditioning

Mediated: by Vagus nerve

Produces: mainy an enzymatic secretion

Question 71

What is the gastric phase of pancreatic secretion, stimuli, mediated by, and what does it produce?

Answer 71

Stimuli: distention of stomach

Mediated: by Vagus nerve

Produces: mainly an enzymatic secretion

Question 72

The intestinal phase of pancreatic secreton accounts for what percentage of the pancreatic secretion and what does it produce?

Answer 72

• Accounts for 80% of pancreatic secretion
• Enzymatic and aqueous secretions are stimulated

Question 73

How does the SNS innervate the pancreas and what are its effects?

Answer 73

• Post-ganglionic nerves from celiac and superior mesenteric plexus
• Inhibits secretions

Question 74

How does the PNS innervate the pancreas and what are its effects?

Answer 74

• Pre-ganglionic fibers synapse in the ENS
• Post-ganglionic fibers synapse on the exocrine pancreas
• Stimulates pancreatic secretions

Question 75

Explain why CCK is an important hormonal regulator of pancreatic secretion during the intestinal phase, what stimulates it, where is it released from, and what potentiates its effect?

Answer 75

• Phe, Met, Trp, small peptides, and FA’s stimulate I-cells of the duodenum to release CCK.
• CCK leads to the contraction of the gallbladder and release of the enzymatic secretion from the pancreas into the duodenum
• ACh can potentiate this effect

Question 76

Explain why Secretin is an important hormonal regulator of pancreatic secretions during the intestinal phase, where is it released from, what stimulates it, and what potentiates its effects?

Answer 76

• H+ stimulates S cells of the duodenum to release Secretin, which acts on ductal cell increasing their release of the aqueous secretion containing Na+ and HCO3
• ACh and CCK potentiate the effects of Secretin