2023-24 Fat as Fuel-WITHOUT ANSWERS PDF

Summary

These lecture notes cover the topic of fat as fuel in the context of Nutrition and Metabolism. They discuss the role of adipose tissue lipase in triglyceride breakdown, fatty acid activation and transport, and the beta-oxidation pathway. The presentation also explores the metabolism of glycerol in starvation, odd-numbered fatty acids, and ketone body formation.

Full Transcript

Faculty of Life Sciences & Medicine

Dr. Lauren 4MBBS101 Nutrition and Metabolism
Albee

Department of Biochemistry
Fat as Fuel
 Fat as Fuel

Dr. Lauren Albee
Biochemistry and Molecular Biology
Chapter 14
Available as an e-textbook at
https://bibliu.com/app/#/signinPage
2
 Learning outcomes
After this lecture you should be able to:
a) Indicate the importance of triglyceride fat for long term fuel storage.
b) Describe the role of adipose tissue lipase in the breakdown of
triglyceride into fatty acids and glycerol.
c) Describe how fatty acids are activated to their CoA esters, and how
they are transported into mitochondria via the carnitine shuttle system.
d) Describe the enzyme reactions of the β-oxidation pathway that yield
acetyl-CoA, NADH and FADH2.
e) Summarise the factors regulating fatty acid oxidation.
f) Explain the term ‘ketone bodies’ and outline the significance of
ketogenesis in starvation.

3
 Biological Functions of Lipids
1. Components of cell
Lipid membranes
bilayer (phospholipids & cholesterol)
(5 nm)

2. Precursors of hormones
Lipid molecule Protein molecule
cholesterol steroid hormones
arachidonic acid
prostaglandins

3. Long term fuels
(triglycerides) 4
Efficiency of Triglycerides as Fuel
Compact storage - triglycerides
stored as large fat droplets in the
Fat droplet fat cells of adipose tissue
Large body stores -
70 kg adult has: 11 kg fat (as
TG)
120 g
glycogen in liver
10 g glucose
Efficiency on weight basis –
Adipose tissue 1 g fat yields 38 kJ
1 g protein 21 kJ 5
 Structure of
Triglyceride fat
(triacylglycerols)
Glycerol component
of triacylglycerol

Glycerol Common fatty
acids:
palmitic acid C
16:0

stearic acid
C 18:0
oleic acid C
18:1 6
 Breakdown of stored
triglyceride fat in
adipose tissue
Lipase Triacylglycerol
activated Triacylglycerol
lipase (active)
by
Fatty acid
adrenaline
&
glucagon Diacylglycerol
DAG lipase Free fatty
acids
Fatty acid
travel in
plasma
Monoacylglycerol bound to
Glycerol MAG lipase albumin
diffuses
in Fatty acid Act as
blood
Glycerol fuels for
muscles, 7
stream
heart &
 Metabolism of glycerol
Glycerol is water soluble & is taken up
by all tissues

most Glycerol
in liver
in starvation
tissues

Enters glycolysis Enters glycolysis
pathway for pathway and is
conversion to converted to
pyruvate, then glucose by
into TCA cycle for gluconeogenesis
oxidation to CO2
 Fatty acid metabolism by -
oxidation pathway
all reactions occur in the mitochondrial
matrix
– (* transport across membrane)
intermediates present as CoA thioesters
biological energy of fatty acid molecule is
conserved as the transfer of 2 H atoms to
the cofactors NAD+ and FAD to form
NADH & FADH2 (no direct ATP synthesis)
series of four enzyme reactions results in
9
removal of two carbon unit as acetyl CoA
Activation of long chain fatty
acids O
CH3 – (CH2)n – CH2 – CH2 – C – O
–H
CoASH ATP
Fatty acyl-CoA
synthetase
(cytosol)
AMP +
PPi
H H O
CH3 – (CH2)n – C – C – C – S-CoA
H H
Fatty acyl-CoA 10
Coenzyme A forms thioester
bonds with carboxylic acids

Blob you don’t need to worry about

CoA-
SH

RCH2 C-O- CoA- RCH2 C-S-
H + O SH CoA O 11
Transport of fatty acyl-CoA into mitochondria: carnitine shuttle
1) Fatty acyl-CoA
5) Carnitine transported
freely diffuses across
back into the
the outer
intermembrane space.
mitochondrial
membrane
4) Carnitine is switched
back for CoA by carnitine
acyltransferase II,
recreating fatty acyl-CoA.

3) Fatty acyl-carnitine
2) Fatty acid group transferred crosses the inner
to carnitine by carnitine mitochondrial membrane
acyltransferase I, creating fatty via a translocase.
acyl-carnitine.
The process is energetically neutral.
Transport of fatty acids into
mitochondria - Stage 1

13
Transport of fatty acids into
mitochondria - Stage 2

14
Overview of β-oxidation pathway

Fatty acyl-CoA with 10
carbons
β-oxidation

+
Fatty acyl-CoA with 8 acetyl-
carbons CoA

Called β-oxidation because the β-carbon undergoes oxidation to produce a
carbonyl group (carbon double-bonded to oxygen).

One round of β-oxidation produces acetyl-CoA and a fatty acyl-CoA that is 2
carbons shorter
Overview of β-oxidation pathway

Remove 2 hydrogens
Cleave bond and add
CoASH

+
Add oxygen (in
water) Remove
2
hydrogens
Reaction 1 - Removal of 2 H
atoms
H H O
CH3 – (CH2)n – C – C – C – S-CoA
H H
Fatty acyl-CoA
FAD
acyl-CoA
1
dehydrogenase
FADH2
H O
CH3 – (CH2)n – C = C – C – S-CoA
17
H
Reaction 2 – Addition of water
H O
CH3 – (CH2)n – C = C – C – S-CoA
H
Enoyl-CoA

2 H2 O
Enoyl-CoA hydratase

H O
CH3 – (CH2)n – C – CH2 – C – S-
CoA OH 18
Hydroxyacyl-CoA
Reaction 3 – Removal of 2
H atoms
H O
CH3 – (CH2)n – C – CH2 – C – S-
CoA OH
Hydroxyacyl-CoA
NAD+
3
Hydroxyacyl-CoA
dehydrogenase
NADH + H+
O O
CH3 – (CH2)n – C – CH2 – C – S-
19
CoA -Ketoacyl-CoA
Reaction 4 - Removal of 2 C units
O O
CH3 – (CH2)n – C – CH2 – C – S-
CoA -Ketoacyl-CoA
4 CoA-SH
-Ketoacyl-CoA thiolase

O O
CH3 – (CH2)n – C – S- + CH3 – C – S-
Fatty acyl-CoA
CoA Acetyl-CoA
CoA
(2 C atoms shorter)
TCA
cycle CO
20
Same reaction pattern seen in the TCA cycle

Remove 2
hydrogens Add oxygen (in Remove 2
water) hydrogens
Shorter fatty acid re enters
reactions 1 - 4
O
CH3 – (CH2)n – C – S-
CoA
Fatty acyl-CoA (2 C atoms shorter)

2C 1 2H
unit 4

3 2
H2 O
2H 22
Summary of -oxidation pathway-
1

Activation stage

C16

mitochondrial
membranes

matrix
23
Summary of -oxidation pathway -
2
Fatty acid with 16 C
atoms 7
will pass through C16
repeats 7
7
of -oxidation pathway
producing NADH C2
& FADH2 C14 2H
Acetyl C12
CoA C10

H2O
2H
24
Summary of -oxidation pathway

C16

Fatty acid with
16 C C2 C14 2H
atoms
8 will give Acetyl C12
rise CoA C10
to
acetyl CoA
which enter the
H2O
TCA cycle 2H
25
Energy yield from fatty acid
oxidation
Fatty acid with 16 C atoms goes
through 7 repeats of
-oxidation producing 7 NADH & 7
FADH2
ATP yield = 7 x 2.5 + 7 x 1.5
= 28

Fatty acid with 16 C atoms produces
8 acetyl CoA
ATP yield from complete oxidation of
acetyl CoA 26
Regulation of fat metabolism
Release of fatty acids from adipose
tissue
adrenaline & glucagon activate lipase
enzyme

Rate of entry into mitochondria via
carnitine shuttle

Rate of reoxidation of cofactors NADH
27
& FADH by Electron Transport Chain
Metabolism of odd numbered
fatty acids

-oxidation will result in the
following:
C15 C13 C11 C9 C7
C5 C3

28
 Metabolism of odd numbered
fatty acids – dealing with the last
3 carbons
CH3 CH2 – C – S-CoA ATP

O CO2 ADP +Pi
Propionyl-CoA-carboxylase
OOC – CH – C – S-CoA
-

CH3 OMethylmalonyl-CoA mutase

OOC – CH2 – CH2 – C – S-CoA
-

O
Succinyl-CoA TCA cycle
 Ketone body formation
‘Ketogenesis’ occurs when fat
metabolism is the main source of
energy:
– in starvation
– in Type I diabetes No need to
learn these
structures
Fatty acid oxidation in hepatocytes
leads to high concentrations of Acetyl
Co A - exceeds capacity of the TCA
cycle.

Excess Acetyl CoA is converted into
‘ketone bodies’ in liver

acetoacetate and β
 Ketone bodies can be utilised for
energy by most
(but not all) tissues
acetoacetate and β hydroxybutyrate are released into the
bloodstream.
In most cell types they can be converted back into TCA
cycle intermediates (acetyl CoA and succinate).

Most tissues oxidise a mixture of fatty acids and ketone
bodies
Liver cannot utilise ketone bodies – WHY?

Brain cannot utilise fatty acids – WHY?
– uses glucose and small amount of ketone bodies
(‘emergency fuel’)
Summary of mitochondrial events
 MCQ 1
1. How are free fatty acids transported in the
blood? They are:

A. carried by albumin.
B. carried by carnitine.
C. carried by chylomicrons.
D. carried by low- and high-density lipoproteins
(LDLs and HDLs)
E. freely soluble and do not require a carrier. 33
 MCQ 2
2. What are the three main biological function
of lipids?
A. Components of ribosomes, precursor for steroid
hormones, and long-term fuel storage.
B. Components of membranes, precursor for steroid
hormones, and short-term fuel storage.
C. Components of membranes, precursor for steroid
hormones, and long-term fuel storage.
D. Components of the nucleic acids, precursor for
peptide hormones, and long-term fuel storage.
E. Components of membranes, precursor for peptide 34
 MCQ 3
3. Fatty acids with an odd number of carbons
undergo β-oxidation until three carbons of the
fatty acid remain. This three-carbon unit
(propionyl-CoA) is then converted to:
A.succinyl-CoA.
B.acetyl-CoA.
C.enoyl-CoA.
D.pyruvate.
E.glycerol.
35
 MCQ 4
4. A reaction sequence that takes place in
mitochondria when fatty acids are broken down
for energy can be described as:

A.an oxidation followed by a hydration followed by a
reduction.
B.an oxidation followed by an oxidation followed by a
decarboxylation.
C.an oxidation followed by an oxidation followed by a
hydrolysis.
36
D.an oxidation followed by a reduction followed by a
 MCQ 5
5. A deficiency that prevents someone from
synthesising carnitine could cause:

A.Accumulation of lipid droplets in the mitochondrial
matrix of liver cells
B.Accumulation of lipid droplets in the cytosol of liver
cells
C.A decrease in free long chain fatty acids circulating in
the blood.
D.Increased beta -oxidation and reduced storage of long
chain fatty acids in liver cells 37