Energy Production: Lipids

Question 1

What are some features of lipids?

Answer 1

They are structurally diverse
Generally insoluble in water (hydrophobic)
Most only contain C,H,O.
They are more reduced than carbohydrates.

Question 2

What lipids contain other elements than C,H, and O? What elements do they contain as well?

Answer 2

Phospholipids contain P and N as well.

Question 3

What are the consequences of lipids being more reduced than carbohydrates?

Answer 3

It means that they release more energy when they are oxidised.
It also means that they require more oxygen.

Question 4

What classes of lipids are there?

Answer 4

Fatty acids
Hydroxy-methyl-glutaric acids also called HMGs
Vitamins

Question 5

What fatty acid derivatives are there? What are their functions?

Answer 5

Fatty acids - fuel molecules
Triacylglycerols also called triglycerides - fuel storage and insulation
Phospholipids
Eicosanoids - local mediators

Question 6

What HMG acids derivatives are there?

Answer 6

Ketone bodies - water soluble fuel molecules
Cholesterol - membranes and steroid hormone synthesis
Cholesterol esters - cholesterol storage
Bile acids and salts - lipid digestion

Question 7

What vitamins are there that are lipids?

Answer 7

Vitamin A, D, E and K.

Question 8

How much energy does a healthy 70kg man need per day?

Answer 8

10-11000 kJ.

Question 9

What is the structure of a triacylglycerol (TAG/triglyceride)?

Answer 9

3 fatty acid side chains and a glycerol back bone.

Question 10

What is the process called that makes triacylglycerol from 3 fatty acids and 1 glycerol?

Answer 10

Esterification

Question 11

What is the process called that breaks up the triacylglycerol into 3 fatty acids and 1 glycerol?

Answer 11

Lipolysis

Question 12

What are some features of triacylglycerols?

Answer 12

They are hydrophobic so they are stored in an anhydrous form.
Utilised in prolonged exercise, in starvation and also in pregancy.

Question 13

Where are triacylglycerols stored?

Answer 13

In adipose tissue

Question 14

What makes triacylglycerols to be stored or released?

Answer 14

Hormones.

Question 15

Very briefly explain triglyceride metabolism.

Answer 15

Broken down in the GI-tract by lipolysis into glycerol and fatty acids.
Glycerols are then taken up in the blood stream and then taken up in the liver.
Fatty acids are hydrophobic and needs to be repackaged into lipoproteins called chylomicrons. They are then taken up in adipose tissue and stored as triglycerides again and made into fatty acids again to reach muscle.

Question 16

Where does stage 1 of triglyceride metabolism take place?

Answer 16

In the GI tract. Lipolysis turns triglyceride into glycerol and 3 fatty acids.

Question 17

What is the enzyme that helps with the lipolysis?

Answer 17

Pancreatic lipases.

Question 18

What are chylomicrons?

Answer 18

Fatty acids are repackaged into chylomicrons which are lipoproteins. This is because fatty acids are hydrophobic and can’t enter the blood stream.

Question 19

What are fatty acids stored as?

Answer 19

Triglycerides

Question 20

How do fatty acids from adipose tissue get to target tissue?

Answer 20

They are carried by a protein called FA-albumin.

Question 21

Briefly explain the triglyceride/fatty acid cycle in adipose tissue.

Answer 21

When there is a high concentration of glucose, glucose is taken up from the blood stream in the adipose tissue.
By glycolysis glucose is converted into glycerol-1-P.
By esterification glycerol-1-P is converted into triglyceride.
Triglyceride can then undergo lipolysis in the adipose tissue to form fatty acids and glycerol. This is in case of starvation for example.
The fatty acids are then carried out to the blood stream with the help of FA-albumin.
Glycerol is transported out of the adipose tissue to the blood stream without any help.

Question 22

What happens if there is a low concentration of glucose in the blood regarding the triglyceride/fatty acid cycle?

Answer 22

Glucose stop being taken up by the adipose tissue and it also promotes lipolysis to form fatty acids and glycerol.

Question 23

Explain the structure of fatty acids and their features.

Answer 23

CH3(CH2)nCOOH which is has a large hydrophobic tail CH3(CH2)n and a smaller hydrophilic group COOH.
It can be either saturated or unsaturated, also polyunsaturated.

Question 24

How do saturated and unsaturated fatty acids differ?

Answer 24

Saturated fatty acids do not have carbon double bonds.

Unsaturated fatty acids have one ore more carbon double bonds.

Question 25

What is stage 2 in fatty acid metabolism? Where does it take place?

Answer 25

In the mitochondria.

It’s when fatty acids are converted into acetyl CoA.

Question 26

Briefly explain stage 2 of fatty acid metabolism.

Answer 26

Fatty acids are activated by linking to coenzyme A outside the mitochondrion.
They are transported across the inner mitochondrial membrane using a carnitine shuttle
Fatty acid cycles are then oxidative where C2 (2 carbons) removed each cycle.

Question 27

Why is activation of fatty acids by coenzyme A needed?

Answer 27

Because fatty acids do not readily cross the inner mitochondrial membrane.

Question 28

Where does activation of fatty acids by coenzyme A take place?

Answer 28

Outside of the mitochondrion in the cytoplasm.

Question 29

How does the carnitine shuttle work?

Answer 29

Acyl-CoA (fatty acid with CoA) reacts with carnitine to form Acyl Carnitine and only Coenzyme A.
Acyl Carnitine can now easily cross the inner mitochondrial membrane.
Acyl carnitine will now react with coenzyme A to then again form Carnitine and Acyl-CoA.
Acyl-CoA can now be found in the matrix.

Question 30

What happens to the Acyl-CoA in the matrix of the mitochondrion now?

Answer 30

It undergoes something called beta-oxidation which removes C2 at every cycle.

Question 31

What are the products of beta-oxidation? Use stearic acid (C18) as an example.

Answer 31

From stearic acid (C18):
9 acetyl CoA are formed
8 FADH2, 8 NADH and 8H+ are formed.

Question 32

What happens to the products of beta-oxidation?

Answer 32

The 9 acetyl CoA undergo the TCA cycle (stage 3) to form even more reducing power.
The reducing power FADH2 and NADH + H+ move onto the electron transport chain and oxidative phosphorylation in stage 4.

Question 33

Where does beta-oxidation take place/Where does it not take place? Why does it not take place there?

Answer 33

In most tissues and white blood cells. (In the mitochondria)
It does not take place in the brain and red blood cells.
It doesn’t take place in the brain because fatty acids have a hard time to cross the blood-brain barrier.
It doesn’t take place in red blood cells because they don’t have mitochondria.

Question 34

Is there any ATP synthesis in beta-oxidation?

Answer 34

Not directly in beta-oxidation. But it lays a foundation for ATP synthesis because of the acetyl CoA formation and the formation of NADH and FADH2 as well.

Question 35

Where is glycerol metabolised?

Answer 35

In the liver.

Question 36

Briefly explain glycerol metabolism.

Answer 36

Glycerol uses ATP and glycerol kinase to form glycerol phosphate and ADP. Glycerol phosphate can then take two pathways. It can either go for triacylglycerol synthesis or go into DHAP and then be fed into glycolysis.

Question 37

What are the functions of acetyl CoA?

Answer 37

As it goes into the TCA cycle it can either undergo catabolic pathways or anabolic pathways. It can form fatty acids to then form triglycerides and phospholipids.
It can form HMG as well to then form ketone bodies and cholesterol.

Question 38

What three ketone bodies can be found in the body?

Answer 38

Acetoacetate (liver)
Acetone
beta-hydroxybutyrate (liver)

Question 39

What is the normal plasma ketone body concentration?

Answer 39

Less than 1 mM

Question 40

What is an indication of starvation?

Answer 40

A high plasma concentration of ketone bodies. (2-10 mM) This is called physiological ketosis.

Question 41

What is an indication of untreated type 1 diabetes?

Answer 41

A high plasma concentration of ketone bodies. Higher than 10 mM. This is called pathological ketosis.

Question 42

Where are ketone bodies synthesised?

Answer 42

In the liver by mitochondria.

Question 43

Briefly explain ketone body synthesis.

Answer 43

It is formed by acetyl CoA.
Acetyl-CoA is transported to the liver and then synthase converts Acetyl-CoA into HMG-CoA.
HMG-CoA can then be converted into cholesterol by HMG-CoA reductase or ketone bodies.
The ketone bodies are formed by lyase reacting with HMG-CoA. Acetoacetate is the first step here which can be converted into acetone or beta-hydroxybutyrate.

Question 44

What are regulators of ketone body synthesis?

Answer 44

If TCA is inhibited in some way this can cause acetyl-CoA to go into the ketone body synthesis pathway instead. This means that a high NADH concentration for example causes KB synthesis to increase.

Question 45

Where does the acetyl CoA in the liver for metabolism into ketone bodies come from?

Answer 45

Usually from beta-oxidation of fatty acids into acetyl CoA.

Question 46

Briefly explain metabolism of ketone bodies.

Answer 46

Fatty acids -> Acetyl CoA -> HMG-CoA -> acetoacetate.
Acetoacetate is then either converted into beta-hydroxybutyrate in the liver or released into the blood stream. Beta-hydroxybutyrate is then also released into the blood. Here in the blood acetoacetate can spontaneously be converted into acetone.
Acetoacetate and beta-hydroxybutyrate are then transported into a tissue like muscle.
beta-hydroxybutyrate is converted into acetoacetate.
Acetoacetate then react in the TCA cycle with Succinyl CoA to form Acetoacetyl CoA and then further converted into Acetyl CoA.

Question 47

In short outline metabolism of ketone bodies.

Answer 47

Ketone bodies such as acetoacetate and beta-hydroxybutyrate are converted into acetyl CoA in the muscle.

Question 48

What is ketone body synthesis more regulated by?

Answer 48

Insulin to glucagon ratio. Insulin promotes cholesterol synthesis. Insulin (fed state) means that there is a low production of ketone bodies.
Glucagon (starvation) promotes ketone body production to use ketone bodies for energy.

Question 49

What happens to HMG-CoA when insulin is high?

Answer 49

Cholesterol is formed.

Question 50

What happens to HMG-CoA when glucagon is high?

Answer 50

Ketone bodies are formed.

Question 51

Why are ketone bodies incredibly important in starvation?

Answer 51

Ketone bodies spare glucose in early starvation and in diabetes.

Question 52

Why is sparing glucose important in starvation?

Answer 52

Because RBCs and the brain only use glucose. So ketone bodies being used by muscle instead here makes spare glucose to be able to be used for the brain.

Question 53

What happens in late starvation?

Answer 53

Ketone bodies are used for energy in muscle. Amino acids in the muscle are then transported to the liver where they are converted into pyruvate which then undergo gluconeogenesis to form glucose.
Glycogen also undergo glycogenolysis in order to form glucose.

Question 54

What are some features of ketone bodies?

Answer 54

Water soluble molecules (hydrophilic)

Question 55

What is ketonuria?

Answer 55

When the ketone body concentration is above the renal threshold it is excreted in the urine. It means ketone bodies in the urine.

Question 56

What is ketoacidosis?

Answer 56

When there is a high concentration of acetoacetate and beta-hydroxybutyrate they are acidic and form an acidic environment.

Question 57

How can you detect high acetone concentrations?

Answer 57

By smelling the breath.

This is because volatile acetone may be excreted by the lungs.