Carbohydrates 2

Question 1

What are some carbohydrates in the diet?

Answer 1

Starch (cereals, potatoes)

Glycogen (meat)

Cellulose and hemicellulose (plant cell walls)

Oligosaccharides containing a1-6 linked galactose (peas, beans)

Lactose, succrose, maltose (milk, sugar, beer)

Glucose, fructose (fruit, honey)

Question 2

Where are 3 places that carbohydrates are digested?

Answer 2

Mouth

Duodenum

Jejanum

Question 3

How are carbohydrates digested in the mouth?

Answer 3

Salivary amylase hydrolyses a1-4 bonds of starch

Question 4

How are carbohydrates digested in the duodenum?

Answer 4

Pancreatic amylase works as in the mouth (hydrolyses a1-4- bonds)

Question 5

How are carbohydrates digested in the jejunum?

Answer 5

Final digestion by mucosal cell surface enzymes

Question 6

What are enzymes that digest carbohydrates in the jejunum and what do they do?

Answer 6

Isomaltase (hydrolysis a1-6 bonds)

Glucoamylase (removes glucose from non reducing end)

Sucrase (hydrolysis sucrose)

Lactase (hydrolysis lactose)

Question 7

What is the deudenum and jejunum part of?

Answer 7

Small intestine

Question 8

Are any carbohydrates digested in the stomach?

Answer 8

No

Question 9

Where are glucose transporters found?

Answer 9

In the microvilli of epithelial cells facing the lumen of the intestine

Question 10

What does our high intake os salt cause?

Answer 10

High Na concentration outside of cells

Question 11

What is the glucose transporter driven by?

Answer 11

Na, it takes in 2 Na and 1 glucose

Question 12

What maintains the concentration gradient of Na that can drive glucose into the cells?

Answer 12

Na⁺/K⁺ pumps

Question 13

How is glucose then pumped from within the cell into the blood?

Answer 13

Pump on the basal surface of the cell move glucose to blood, only transporting glucose due to the high concentration gradient

Question 14

What the exact process for the absorption of glucose?

Answer 14

1. High [Na⁺] out of the cell due to high salt intake
2. Na⁺/K⁺ pump maintains the concentration gradient
3. Transporters on microvilli bring in 2 Na⁺ and 1 glucose
4. Transporter on basal surface lets 1 glucose leave into blood due to concentration gradient

Question 15

Why can the absorption of glucose be described as an indirect ATP process?

Answer 15

Because of the use of the Na⁺ pump

Question 16

Why will glucose be pumped in the cell even if its up its concentration gradient?

Answer 16

Because of the Na⁺ concentration which drives the pump

Question 17

How is galactose absorbed?

Answer 17

Similarly to glucose utilising gradients

Question 18

How is fructose absorbed?

Answer 18

1. Binds to channel protein GLUT5
2. Simply moves down its concentration gradient

Question 19

What happens to cellulose and hemicellulose?

Answer 19

Cannot be digested by the gut, are broken down into methane and hydrogen by gut bacteria

Question 20

What do cellulose and hemicellulose do?

Answer 20

Increase facial bulk and decrease transit time

Cause smelly farts (broken down into methane)

Question 21

What be disaccaride deficiencies be caused by?

Answer 21

Genetic

Severe intestinal infection

Inflammation of the gut lining

Drugs injuring the gut wall

Surgical removal of part of the intestine

Question 22

What does diagnosis of disaccaride defficiencies require?

Answer 22

Enzyme tests of intestinal secretions for lactose, maltose or sucrose activity

Question 23

What is the most common disaccharide deficiency?

Answer 23

Lactose intolerence

Question 24

What causes the symptoms of lactose intolerence?

Answer 24

Undigested lactose broken down by gut bacteria causing gas build up and acid

Lactose is osmotically active, drawing water into the lumen from the gut causing diarrhoea

Question 25

What is the fate of absorbed glucose?

Answer 25

1. Diffuses through intestinal epithelium cells into blood and then the liver
2. Immedietely phosphorylated into glucose-6-phosphate by the hepatocytes

Question 26

Why is glucose converted into glucose-6-phosphate?

Answer 26

Because glucose-6-phosphate cannot escape the cell as GLUT transporters don’t recognise it

Question 27

What enzymes control the reaction of glucose to glucose-6-phophate?

Answer 27

Glucokinase (liver)

Hexokinase (skeletal muscle)

Question 28

Where is glucokinase found?

Answer 28

In the liver

Question 29

Where is hexokinase found?

Answer 29

In skeletal muscle

Question 30

What are the kenetic properties of glucokinase and hexokinase?

Answer 30

Glucokinase has high K_M and high v_max

Hexokinase has low K_M and low v_max

Question 31

What happens when the concetration of blood glucose is low, in terms of glucokinase and hexokinase?

Answer 31

Liver doesn’t grab all of it (due to high K_M of glucokinase) so other tissues can use it

Question 32

What happens when glucose concentration is high, in terms of glucokinase and hexokinase?

Answer 32

The liver grabs a lot more of it

Question 33

Why would glucose-6-phosphate be converted back to glucose in the liver?

Answer 33

To enter the blood stream and travel to where it is needed

Question 34

What is substrate level phosphorylation?

Answer 34

Formation of ATP by direct transfer of a phosphoryl group (PO₃) to ADP from another phosphorylated compound

Question 35

What is oxidative phosphorylation?

Answer 35

ATP is formed from the transfer of electrons from NADH or FADH₂ to O₂ by a series of electron carriers

Question 36

What does the pathway of glycogen in the liver to glucose in the blood look like?

Question 37

What does the fate of glycogen in skeletal muscle look like?

Question 38

Where is the enzyme glucose-6-phosphotase found?

Answer 38

In the liver, not the skeletal muscle as the genes that code for it are not active

Question 39

What does glucose-6-phosphatase do?

Answer 39

Breaks down glucose-6-phosphate into glucose

Question 40

What is the exact process of the synthesis of glycogen?

Answer 40

1. Glycogenin begins process by covalently binding glucose from uracil diphosphate (UDP) glucose to form a chain of about 8 monomers
2. Glycogen synthase takes over and extends the glucose chain
3. Chains formed are broken by glycogen branching enzymes and reattacthed via a1-6- bonds to give branching points
4. Glycogen synthase extends the chain and repeat

Question 41

How does glycogenin catalyse the synthesis of glycogen?

Answer 41

Producing a tiny amount of glucose to start the chain

Question 42

What is uracil diphospahte (UDP)?

Answer 42

A carrier molecule that allows the cell to defferentiate what glucose is to be used for the synthesis of glycogen

Question 43

What is the exact process of the degradation of glycogen?

Answer 43

1. Glucose monomers are removed one at a time from the non reducing end by glycogen phophorylase to produce G-1-P
2. Branch is removed by debranching enzyme
3. Transferase removes 3 glucose monomers and attatches them to nearest non reducing end via a1-4 bonds)
4. Glucosidase removes final glucose monomer by breaking a1-6 bond and releases a free glucose
5. Process repeats

Question 44

What is G-1-P readily converted to and what does this look like?

Answer 44

G-6-P

Question 45

What are some common diseases associated with glycogen storage?

Answer 45

van Gierke’s disease

McArdle’s disease

Question 46

What is van Gierke’s disease caused by?

Answer 46

A G-6-P defficiency in the liver, kidney and intestine

Question 47

What are the symptoms of van Gierke’s disease?

Answer 47

High [liver glycogen]

Low [blood glucose]

High [blood lactate]

Question 48

What is the treatment of van Gierke’s disease?

Answer 48

Regular carbohydrate feeding