Carbohydrates

Question 1

What are the main monosaccharides and why are they called hexoses?

Answer 1

Glucose
Galactose

Made of 6C

Question 2

What are the main disaccharides?

Answer 2

Maltose
Lactose
Sucrose

Question 3

What bond joins together sugar monomers?

Answer 3

Glycosidic

Question 4

What do glycosidic bonds form between?

Answer 4

An OH group of one monomer and the anomeric carbon of another

Question 5

Why are maltose and lactose classed as reducing sugars?

Answer 5

They have a free anomeric carbon 1 which can be oxidised

Question 6

Why is sucrose not a reducing sugar?

Answer 6

Has no free anomeric carbon 1

Question 7

What are the two types of polysaccharides?

Answer 7

Hetero and Homo

Question 8

What is a heteropolysaccharide?

Answer 8

A polysaccharide made from two or more monomer species

Question 9

What is a homopolysaccharide?

Answer 9

Polysaccharide made from one monomer species

Question 10

Example of a polysaccharide?

Answer 10

Starch or Glycogen

Question 11

What makes up starch?

Answer 11

Two glucose polymers - amylose and amyopectin

Question 12

Difference between amylose and amylopectin?

Answer 12

Amylose is not branched and had alpha1–>4 bonds

Amylopectin is branched and has alpha1–>4 and alpha1–>6 bonds.

Question 13

Is glycogen more or less branched than starch?

Answer 13

More

Question 14

Why would we store glucose as glycogen?

Answer 14

Compactness

Glycogen has many reducing ends making it easily utilised to form glucose

Glycogen is not osmotically active yet glucose is - easier to keep glycogen in a cell than it is glucose.

Question 15

Why is glycogen osmotically inactive?

Answer 15

Polymers form hydrated gels

Question 16

Proteins with a carbohydrate attached are called?

Answer 16

Glycoproteins

Question 17

Benefits of a glycoprotein?

Answer 17

Increased solubility

Influences conformation and folding

Protects it from degradation

Acts as a cell to cell communicator

Question 18

Where are the 3 locations of carb digestion?

Answer 18

Mouth
Duodenum
Jujunum

Question 19

What happens in mouth?

Answer 19

Salivary amylase breaks down alpha1–>4 bonds

Question 20

What happens in the duodenum?

Answer 20

Pancreatic amylase acts same as in mouth

Question 21

What happens in the jujunum?

Answer 21

Final digestion by 4 enzymes;

Isomaltase - breaks down alpha1–>6 bonds

Glucoamylase - removes glucose from non reducing ends of carb

Sucrase and Lactase - hydrolyses their sugars

Question 22

What is the end product of carb digestion?

Answer 22

Glucose, Galactose and Fructose

Question 23

How is glucose absorbed after digestion?

Answer 23

It binds to Sodium and enters the cell against its own gradient but along sodiums gradient.

Question 24

How does galactose get absorbed?

Answer 24

Similar to glucose

Question 25

How is fructose absorbed?

Answer 25

Binds to GLUT5 channel protein and moves down its concentration gradient

Question 26

What breaks down cellulose and hemicellulose?

Answer 26

Not us, gut bacteria do releasing CH4 anf H2 gas

Question 27

Example of a disaccharide deficiency?

Answer 27

Lactose intolerance

Question 28

Explain lactose intolerance?

Answer 28

Lactase is deficient Lactose not digested - osmotically active brings water into gut causing diarrhoea Lactose broken down by gut bacteria - gas build up and irritant acids

Question 29

Function of hexokinase and glucokinase ?

Answer 29

To phosphorylate glucose to G-6-P

Question 30

Hexokinase and glucokinase are isoenzymes, what does this mean?

Answer 30

They have the same function, yet different structure, Vmax and Km

Question 31

What is glucokinase for?

Answer 31

Has a high Km and a High Vmax, allowing to to grab lots of glucose fast and trap it quickly, only working when there is a high concentration of glucose due to high Km. Found in hepatocytes

Question 32

What is hexokinase used for?

Answer 32

Used in tissues - has a low Km meaning it can grab glucose more effectivly at low conc. Has a Low Vmax meaning tissues won't over grab and phosphorylate glucose

Question 33

What is G-6-P used for?

Answer 33

Can be turned back to glucose and used, sent to make pentoses or stored as glycogen

Question 34

How is glycogen synthesised?

Answer 34

Glycogenin covalently bonds glucose to UDP forming chains 8 residues long. Glycogen synthase then takes over and extends the glucose chains. Glycogen branching enzyme then breaks the chain and reattaches it as branches via alpha1-->6 bonds.

Question 35

How is glycogen degraded?

Answer 35

1. Glucose monomers are removed one at a time as G-1-P from non reducing ends. Phosphorylated by glycogen phosphorylase. 2. Remaining glycogen moecules is debrached by the transferase activity of a de-branchin enzyme which removes 3 of the last 4 glucose residues on a branch and reattaches it to the nearest non-reducing of main chain via alpha1--> 4 bonds. 3. Last branched glucose is removed by glucosiadase leaving behind an unbranched glycogen chain which glycogen phosphorylase can act upon as needed.

Question 36

What is glycolysis?

Answer 36

A catbolic pathway that forms ATP and pyruvate from glucose anerobically via substrate-level phosphorylation. Occurs in cytosol so no complex organelles needed.

Question 37

How many phases does glycolysis have?

Answer 37

2 - preparatory and payoff phases each with 5 steps.

Question 38

How many ATP are used and made in glycolysis?

Answer 38

Per glucose; 2 ATP needed for preparatory phase 4 made in payoff phase

Question 39

Why is glycolysis not reversible?

Answer 39

It has overall -ve change in gibbs free energy making it spontaneous. It has 3 very spontanous steps which make this irreversible

Question 40

What happens at the end of the prep phase?

Answer 40

Glucose makes G-3-P Step 3 of this phase is irreversable and first commited phase.

Question 41

What happens end of payoff phase?

Answer 41

2 G-3-P molecules end up as 2 ATP and 2 NADH

Question 42

Why does NAD+ need to be regenerated?

Answer 42

For use in metabolic pathways to reduce various intermediate metabolites

Question 43

Example of NAD+ regeneration?

Answer 43

During anerboic respiration, Pyruvate changed to lactate using NADH-->NAD+ which can go off and be used as needed.

Question 44

What is the use and regeneration of NAD+ termed as?

Answer 44

Redox balance

Question 45

How is pyruvate converted to lactate?

Answer 45

Via fermentation - is reduced to lactate using lactate dehydrogenase and is driven by oxidation of NADH to NAD+ - redox balance.

Question 46

How is lactase later changed to glucose?

Answer 46

In the liver via gluconeogenisis.

Question 47

What is the cori cycle?

Answer 47

Interaction between the liver and muscles

Question 48

How is pyruvate converted to acetyl CoA?

Answer 48

Aerobic respiration - pyruvate is moved to the mitochondria and enzyme pyruvate dehydrogenase turns it to Acetyl-CoA and CO2. This also involves the reduction of NAD+ to NADH

Question 49

What is gluconeogenisis?

Answer 49

Process of making glucose from non carb molecules when body is starving/fasting

Question 50

Since glycolysis is irreversible, how does gluconeogenisis occur?

Answer 50

Uses bypass reactions to get passed the 3 irreversible steps

Question 51

What are bypass reactions A and B?

Answer 51

Occur in mitochondria - Lactate to pyruvtae via lactatse dehydrogenase and NADH to NAD+. Pyruvate undergoes reaction A - pyruvate to oxaloacetate. Reaction B - oxaloactetae to PEP.

Question 52

Reaction C?

Answer 52

F-1,6-bisP to F-6-P

Question 53

Reaction D?

Answer 53

Final step in gluconeogenisis G-6-P to Glucose

Question 54

What is the fate of fructose?

Answer 54

Joins glycolysis using ATP to form F-1-P and then glyceraldehyde and using 1 more ATP forming glyceraldehyde-3-phosphate.

Question 55

Fate of galactose?

Answer 55

Joins glycolysis through conversion of glucose-1-phosphate by UDP.

Question 56

What does the pentose phosphate pathway do?

Answer 56

Produces NADPH and pentose sugars Also metabolises pentose sugars in diet

Question 57

What are pentose sugars needed for?

Answer 57

Nucleic acid synthsis

Question 58

2 phases of pentose phosphate cycle?

Answer 58

Oxidative irreversible - G-P-6 to pentose phosphate AND Makes NADPH Non oxidative reversible - Interconverts G-P-6 and pentose phosphate to form lots of 3 to 7 carbon sugars

Question 59

Difference between NAD+ and NADP+?

Answer 59

NAD+ - used in metabolism | NADP+ - used in anabolism

Question 60

What does alcohol inhibit in liver which slows gluconeogenisis?

Answer 60

NAD+ is used to break ethanol down, not enough for gluconeogenisis.