Lipids and lipid metabolism

Question 1

What are the eight types of dietary fats?

Answer 1

SCFAs; SCFAs (C12-C18); MUFAs; PUFAs (n-6); PUFAs (n-3); cholesterol; phospholipids; trans fats

Question 2

What are sources of SCFAs?

Answer 2

Milk, milk products, butter

Question 3

What are sources of SCFAs (C12-C18)?

Answer 3

Meat, animal foods and fats, coconut and palm oils

Question 4

What are sources of MUFAs?

Answer 4

Olive and rapeseed oils

Question 5

What are sources of PUFAs (n-6)?

Answer 5

Sunflower and soybean oils, meat, eggs, nuts

Question 6

What are sources of PUFAs (n-3)?

Answer 6

Oily fish

Question 7

What are sources of cholesterol?

Answer 7

Eggs, organ meats

Question 8

What are sources of phospholipids?

Answer 8

Animal foods, eggs

Question 9

What are sources of trans-fats?

Answer 9

Ruminant animals, hydrogenated fats in manufactured goods

Question 10

Where are fats stored?

Answer 10

Muscle fibres; within circulation; adipose tissues (subcutaneous and internal fats); adipocytes / lipocytes

Question 11

How much ATP is released per TG?

Answer 11

~400ATP

Question 12

How does fat energy storage compare to carbohydrate energy storage?

Answer 12

Fat accounts for ~80% (50,000-100,000kcal) of energy stored in body; carb energy reserve is just 2% of fat energy reserve (2000kcal)

Question 13

Where is most glycogen stored?

Answer 13

In muscles

Question 14

What is the order of quantity of energy storage?

Answer 14

Fats > proteins > carbs

Question 15

What are the three classes of lipids?

Answer 15

Neutral, compound, and derived lipids

Question 16

What are neutral lipids?

Answer 16

FAs and TGs; comprise of glycerol backbone + 3FAs

Question 17

What are compound lipids?

Answer 17

Plipids; are ampithatic (hydrophobic and philic)

Question 18

What are derived lipids?

Answer 18

Steroids and sterols; cholesterol (6C ring + 5C ring)

Question 19

What is the implication of a longer chain FA?

Answer 19

More solid @RTP

Question 20

What do saturated FAs stimulate?

Answer 20

Stimulates liver to form cholesterol

Question 21

What are trans fats?

Answer 21

Form due to processing (heat, light, hydrogenation); have rigid double bonds; trans fats are trans (H and C on opposite sides @ C=C double bond); trans nature means chain is straight and less likely to be liquid; have structure of unsaturated, with properties of saturated; proposed to be better for health

Question 22

What are examples of

essential FAs?

Answer 22

3-linolenic (n-3) and linoleic (n-6) acid

Question 23

What do 3-linolenic and linoleic acids do?

Answer 23

Play a role in regulation of gene expression; involved in signal transduction; metabolites produce compounds involved in cell function, inflammation, and immune function

Question 24

What are plipids?

Answer 24

Glycerol + 2FAs + Pi; are amphipathic; have hydrophobic tail and hydrophilic head; can be unsaturated or saturated; form plipid bilayer and lipoproteins

Question 25

What do lipoproteins do (general)?

Answer 25

Carry TGs around in blood within them

Question 26

What are four types of lipoproteins?

Answer 26

Chylomicrons, VLDL, LDL, HDL

Question 27

What do chylomicrons do?

Answer 27

Have TGs packaged into them; allow absorption of TGs in small intestines; main transport of FAs to body tissues

Question 28

What do VLDLs do?

Answer 28

Collect lipid droplets; transport FAs to body tissues

Question 29

What do LDLs do?

Answer 29

Transports large amounts of cholesterol

Question 30

What do HDLs do?

Answer 30

Collect excess cholesterol and take back to liver; have more protein and less lipid than LDLs

Question 31

What are three ways that lipids can be mobilised?

Answer 31

Diet –> TGs –> chylomicrons –> lipolysis by lipoprotein lipase –> energy freed from lipids.
Adipose cells/ tissue –> released by hormone sensitive lipase –> form glucagon –> more FFAs and albumin.
Synthesised from liver –> convert excess glucose –> FFAs –> TGs and cholesterol

Question 32

How are lipids metabolised within the post-prandial period?

Answer 32

In mouth, saliva contains lipase; FAs cleaves off TGs; slow process due to watery environment. In stomach, acid-stable lipase further hydrolyses TGs. In small intestine, TGs form past-like substance (lipid droplets) due to hydrophobic nature; gall bladder releases bile salts; bile salts emulsify droplets; pancreatic lipase into duodenum; pancreatic lipase further hydrolyses TGs; LCFA + MGs liberated; MGs and FFAs form micelles; micelles release FFAs and MGs into lining of epithelial cells; FAs and MGs diffuse into villi epithelial cells; FAs + MGs –> TGs due to watery environment; TGs packaged into chylomicrons; chylomicrons diffuse into lymph; lymph deposits chylomicrons in circulatory system within subclavian veins

Question 33

What happens to lipids once in the blood?

Answer 33

Chylomicrons travel to tissues; lipoprotein lipase of extrahepatic tissues release FAs within chlyomicrons; FAs are: taken up by adipose for storage/ taken into muscle for fuel or storage as intramuscular TG/ excess FAs cleaved and trasported back to liver, carried by albumin and recycled in a VLDL –> TG

Question 34

What occurs to lipids in the post-absorptive state/ when fasting?

Answer 34

Are no chlyomicrons; liver produces VLDLs; VLDLs carry TG; drop in glucose = drop in insulin, increase in glucagon; glucagon stimulates (via hormone sensitive lipase) adipose cells to release FAs into blood; albumin is released by liver; FAs bind to albumin; liver takes up FAs which are picked up by LDL and HDL; liver breaks down fats for gluconeogenesis

Question 35

How is FA utilisation regulated?

Answer 35

Transport of acyl-CoA esters into mitochondria; availability of FAD and NAD for beta-oxidation; lipolysis of TG –> FFAs (analogous to mobilisation of glycogen); resterification of FAs; mobilisation from adipose tissue

Question 36

What is beta oxidation?

Answer 36

The separation of C chain at the 2nd (beta) carbon

Question 37

How are FAs transported to target cells?

Answer 37

Adipose stores TGs; lipase breaks down TGs –> MG + FAs; FAs enter blood; FA enters cell via transporter; FA enters mitochondrion

Question 38

What cells cannot metabolise FAs?

Answer 38

Brain cell or RBCs

Question 39

How do FAs enter the mitochondrial matrix of the target cell?

Answer 39

Acyl-CoA synthase catalyses FFA –> acyl-CoA; acyl-CoA through porins of outer membrane; acyl-CoA into intermembrane space; carnitine palmitoyl transferase 1 on outer membrane attaches carnitine + acyl-CoA –> acyl carnitine (carnitine shuttle); CoA back into cytoplasm; acyl carnitine through carnitine acylcarnitine translocase on inner membrane into matrix; carnitine palmitoyl transferase 2 attaches CoA + acyl –> acyl-CoA; carnitine regenerated and back to intermembrane space

Question 40

What regulates rate of FAO at CAPT1?

Answer 40

Glycolytic flux

Question 41

How does beta oxidation occur?

Answer 41

Fatty acyl CoA has two C atoms removed from FA –> acetyl CoA + remaining FA: involves dehydrogenation (simultaneously reducing FAD); hydration; dehydrogenation (simultaneously reducing NAD); thiolysis (cleavage reaction catalysed by thiolase). Remaining FA re-enters pathway

Question 42

Why is the actual energy yield from FAs not as much as the theorised?

Answer 42

Due to activation of FAs and processes in Krebs and ETC

Question 43

Roughly how many ATP are produced from each acetyl-CoA, NADH, and FADH2?

Answer 43

Acetyl-CoA ~10ATP (perfect would be 12).
NADH ~2.5 (perfect would be 3).
FADH2 ~1.5 (perfect would be 2)

Question 44

How many ATP are used in FA activation?

Answer 44

2

Question 45

How nutrients interconverted?

Answer 45

Gluconeogenesis at the liver: glycerol, lactate and certain amino acids –> glucose; Lipogenesis at the liver and adipose cells: glucose and amino acids –> lipids

Question 46

How is lactate converted to glucose?

Answer 46

Cori cycle: 2 lactate –> 2 pyruvate + glucose

Question 47

How does carb oxidation change during prolonged exercise?

Answer 47

Significantly reduces over a three hour time span

Question 48

How does fat oxidation change during prolonged exercise?

Answer 48

Significantly increases from onset of exercise

Question 49

What substrate is responsible to largest energy expenditure?

Answer 49

Muscle glycogen - is used until it runs out

Question 50

What is maximal fat oxidation?

Answer 50

Fat max: consume most fat @65% VO2max

Question 51

Where does the range of fat max lie in regards to HR?

Answer 51

~60-80% HRmax

Question 52

How does training status affect fat max?

Answer 52

%VO2max where fat max lies remains the same; fat max rate is increased in higher trained individuals

Question 53

How does training affect substrate utilisation?

Answer 53

Endurance training increases use of intramuscular fat stores; less carbs are used

Question 54

How does gender affect fat max?

Answer 54

Females’ fat max occurs at higher %HRmax; females’ fat max rate is higher

Question 55

How does carb intake affect fat oxidation?

Answer 55

Consumption of carbs pre-exercise significantly reduces fat oxidation, particularly on intramuscular TGs

Question 56

How does cycling affect fat max compared to running on a treadmill?

Answer 56

Oxidise much lower fats; fat max similar both when on treadmill and bike

Question 57

How does exercise affect glycogenolysis?

Answer 57

Increased exercise intensity increases glycogenolysis in almost a linear relationship

Question 58

Why is fat oxidation not sufficient at high intensity?

Answer 58

70-90% VO2max needs ~1mol ATP/min, but maximal rate of rate oxidation is only ~0.4 mol ATP/min

Question 59

How does carb oxidation reduce fat oxidation at increased exercise intensity?

Answer 59

Increased plasma FAs does not increase fat oxidation during high intensity + main effect is on IMTG = limitation within muscle cell. Only oxidation of LCFAs is impaired = carnitine shuttle and beta oxidation are limiting = CoA, NAD, carnitine all needed for processes. CoA, NAD, carnitine reduced during high intensity exercise with increase in carb oxidation = source of reduced fat oxidation