Lipids 4: Fatty Acid Metabolism I

Question 1

What does fat metabolism depend on?

Answer 1

glucose status

Question 2

What is the general change in plasma levels of fuels after consumption of a meal?

Answer 2

• TG: goes up slowly, more work for TG to get from diet into circulation, also does not go up much
• FFA: go down when we eat, controlled more so by what is coming out of the adipose tissue so more used in fasting
• ketone bodies: nothing really happens, usual only applicable in longer fasting

Question 3

What are the tissue specific metabolism of the brain?
* fuels used
* fuels released

Know this!

Answer 3

• fuels used: glucose, ketone bodies, lactate (when [plasma] elevated)
• fuels released: lactate

Question 4

What are the tissue specific metabolism of the skeletal muscle?
* fuels used
* fuels released

Know this!

Answer 4

Power house of the body so it gets fuel from a bunch of different sources
* fuels used: glucose, FFAs, TGs, branched chain AA, lactate
* fuels released: lactate, alanine glutamine

Question 5

What are the tissue specific metabolism of the heart?
* fuels used
* fuels released

Know this!

Answer 5

• fuels used: FFAs, TGs, ketone bodies, glucose, lactate
• fuels released: NA

Question 6

What are the tissue specific metabolism of the liver?
* fuels used
* fuels released

Know this!

Answer 6

Uses everything especially since it is a controller
* fuels used: AAs (partial oxidation), FFAs, lactate, glycerol, glucose, alcohol
* fuels released: glucose, ketone bodies, lactate (during absorptive phase), TGs

Also site of galactose and fructose metabolism

Question 7

What are the tissue specific metabolism of the intestine?
* fuels used
* fuels released

Know this!

Answer 7

• fuels used: glucose, glutamine
• fuels released: lactate, alanine

Also releases dietary glucose, galactose, fructose, AAs & lipids

Question 8

What are the tissue specific metabolism of the RBCs?
* fuels used
* fuels released

Know this!

Answer 8

• fuels used: glucose
• fuels released: lactate

Question 9

What are the tissue specific metabolism of the kidney?
* fuels used
* fuels released

Know this!

Answer 9

• fuels used: glucose, FFAs, ketone bodies, lactate, glutamine
• fuels released: glucose (renal gluconeogenesis important in prolonged starvation)

Question 10

What are the tissue specific metabolism of the adipose tissue?
* fuels used
* fuels released

Know this!

Answer 10

• fuels used: glucose, TGs
• fuels released: glycerol, FFAs, lactate

Question 11

What determines the fate of Acetyl-CoA?

Answer 11

An individuals energy state

Question 12

What is the overall route of glucose in the fed state regarding FA & lipid metabolism?

Answer 12

Net flux of orange outline
* Glucose comes into the liver and makes pyruvate in the cytosol which pyruvate enters mito and becomes AcetylCoA. AcetylCoA can go into a few different places but when the liver does not need all this energy in the fed state the AcetylCoA will be converted to fatty acids.

Question 13

How does synthesis of long chain fatty acids occur?

Answer 13

• de novo lipogenesis (DNL)
• modifications of exogenous FAs

Question 14

What determines the rate of DNL?

Answer 14

Regulated a lot by insulin
* genetics, obesity, diet, fed/fasting state, energy state of individual
* DNL is increased in insulin resistance, fatty liver disease, CHO induced hypertryglyceredemia (HTG), and fed state

Question 15

How much can the rate of DNL differ between people?

Answer 15

<5%-35%
* Most healthy individuals have a low rate of DNL where <5% of FAs transported from the liver are de novo, but can be up to 35% in some individuals

Question 16

What is the site of fatty acid synthesis?

Answer 16

• major site is in the liver hepatocytes cytosol
• also occurs in adipose

Question 17

What is AcetylCoA converted to in FA synthesis?

Answer 17

Acetyl-CoA → Palmitate

Question 18

What is the first committed step and enzyme of FA synthesis? what regulates the enzyme?

Answer 18

The conversion of Acetyl CoA → Malonyl CoA which is determined by the RLS enzyme Acetyl CoA Carboxylase (ACC)
* activated by insulin (insulin-dependant dephosphorylation)
* activated by citrate build up
* inhibited by palmitate build up
* inhibited by cAMP-dependant phosphorylation

Question 19

Where in the cell can Acetyl-CoA be generated?

Answer 19

• mito matrix
• cell cytosol

Question 20

Where does Acetyl-CoA in the mito come from? In which state will the sources be more active?

Answer 20

2 sources:
* PDH complex during fed state
* FA oxidation during fasting state

Question 21

Where does Acetyl-CoA in the cytosol come from?
In which state does Acetyl-CoA show up in the cytosol?

Answer 21

Glucose goes into the cytosol and is converted to pyruvate which goes into the mito and becomes Acetyl-CoA via PDH. Acetyl-CoA is converted to citrate in the mito which builds up and then leaves the mito into the cytosol where it continues to build up. Citrate built up in the cytosol is converted to Acetyl-CoA (cytosilic) which then goes into FA synthesis.
* More active during fed state

Question 22

How does FA synthesis regulate fatty acid oxidation?

Answer 22

Oxidation is reciprocally regulated
* The Malonyl CoA produced during FA synthesis inhibits the enzyme carnitine palmitoyltransferase (CPT1) which breaks down fats

Question 23

How do insulin and glucagon regulate FA synthesis?

Answer 23

• high blood glucose will increase insulin release (decrease glucagon). Insulin stimulates phosphatase which dephosphorylates ACC activating it to convert Acetyl-CoA to Malonyl-CoA
• low blood glucose will increase glucagon release (decrease insulin). glucagon stimulates PKA which phosphorylates ACC inhibiting it and preventing FA synthesis.

Question 24

How does citrate and palmitate regulate FA synthesis?

Answer 24

Citrate is a ‘feed-forward’ activator for ACC and thus FA synthesis
* fed state: ↑ citrate in mito + ↓ cytosilic long-chain acyl CoA → ↑FA synthesis
* fasting state: opposite so negative feedback regulation whereby build up of palmitoyal CoA will inhibit ACC and thus FA synthesis

Question 25

What are the main FAs that get made from FA synthesis?

Answer 25

• palmitate 16:0 (major)
• stearate 18:0
• palmitoleate 16:1(n-7)
• oleate 18:1

Question 26

What is the second and final committed step of of FA synthesis?

Answer 26

Chain elongation in the smooth ER by 2 C’s so the growing chain produced even # FAs via the FAS enzyme, fatty acid synthase

Question 27

What happens in one cycle of elongation during FA synthesis?

Answer 27

The addition of 2 Cs are reduced, dehydrated, reduced again allowing the next 2 Cs to be added via FAS

Question 28

Regulation of FAS enzyme

Answer 28

regulated mostly at level of protein/gene (not allosteric or phosphorylation) - transcriptional & translational SREBP-1c
* Fed state ↑ FAS expression
* fasted state ↓ FAS expression
* CHO feeding ↑ FAS via upregulation of SREBP-1c & ChREBP
* PUFAs ↓ FAS expression

Question 29

FAS to make SFAs, MUFAs, MUFAs

Answer 29

• SFAs: Greater elongation of 16:0 occurs (18:0…), but not well understood and happens differently in various organs & cells but enzyme activity similar to FAS
• MUFAs: delta-9 desaturase initiates desaturation reaction (14:1. 16:1, 18:1…)
• PUFAs: multiple desaturation & elongation steps but double bonds cannot be introduced after delta-9 position (n ω-3 or ω-6 bonds can be added)

Question 30

Why is FA composition important?

Answer 30

The chain length and degree of saturation influences membrane functions, cell signaling, and has health implications

Question 31

FA composition of adipose tissue

Answer 31

shows ~1⁄2 is oleate (18:1) & 1⁄4 is palmitate (16:0) and is a combination of 3 sources of FAs:
1. dietary source (exogenous),
2. dietary FAs that have been elongated &/or desaturated
3. de novo synthesized fatty acids (endogenous)

Question 32

How do we store FFAs?

Answer 32

TG is the storage form because FFAs can act as a detergent
* form micelles in solution and acts as detergents in the presence of lipid membranes.

Question 33

Where must the cell obtain FAs to make TGs?

Answer 33

• De novo synthesis
• FAs taken up from circulation as FFAs (from lypolysis or lipoproteins)

Question 34

How are FFAs present in circulation to be taken up cells?

Answer 34

• Released by lipolysis of adipose tissue & associated with plasma albumin during fasting
• Generated locally from circulating lipoproteins, by the action of lipoprotein lipases localized on the endothelium of the capillaries within the tissue

Question 35

What makes up a TG?

Answer 35

3 Fatty acyl-CoAs + Glycerol 3-P

Question 36

Basic steps of FAs being converted to TG?

Answer 36

1. FAs taken up by cell by passive difussion or FA transporters
2. FAs transported within the cell bound to FA binding proteins (FABPs)
3. Re-esterification of FAs into TGs via acyltransferase which happens on surface of ER and gain access to ER once reformed

Question 37

What are the transporters on cells that take up FAs for TG synthesis?

Answer 37

• Fatty acid translocase (FAT/CD36)
• Fatty acid transport proteins (FATPs)
• Plasma membrane fatty acid binding protein (FABPpm)

Question 38

What are the 2 pathways for TG biosynthesis?

Answer 38

• Monoacylglycerol pathway (major in enterocytes)
• Glycerol 3-phosphate pathway (enterocytes & other tissues)

Question 39

Monoacylglycerol pathway for TG biosynthesis

Answer 39

Question 40

Glycerol 3-phosphate pathway for TG biosynthesis

Answer 40

Question 41

Where does TG synthesis occur?

Answer 41

All tissues that store TG

Question 42

Where does TG synthesis occur?

Answer 42

All tissues that store TG

Question 43

Why is fructose lipogenic?

Answer 43

Hepatic fructose metabolism begins with phosphorylation by fructokinase . Fructose carbon enters the glycolytic pathway at the triose phosphate level (dihydroxyacetone phosphate & glyceraldehyde-3- phosphate). Thus, fructose bypasses the major control point by which glucose carbon enters glycolysis (phosphofructokinase), where glucose metabolism is limited by feedback inhibition by citrate & ATP. This allows fructose to serve as an unregulated source of both glycerol- 3-phosphate & acetyl- CoA for hepatic lipogenesis.
P, phosphate.

Question 44

Sources of fatty acids

Answer 44