FA and TAG Metabolism (PDF)

Summary

This document provides an overview of fatty acid (FA) and triacylglycerol (TAG) metabolism, including the processes of synthesis and degradation. It details the roles various enzymes and hormones play in these pathways. This material seems best suited for university-level biochemistry or biology coursework.

Full Transcript

Metabolism of FAs and TAGs
 Making Fatty Acids
Many FAs are obtained preformed in the diet.
XS dietary CHO and protein can be converted to
FAs, which are stored as TAGs
In adult humans, FA synthesis occurs primarily in
the liver, lactating mammary glands and to a
lesser extent the adipose tissue
FA synthesis takes place in the cytosol of the cell
It incorporates Cs from acetyl CoA into the
growing FA chain
It is an anabolic process – needs ATP and NADPH
 1. Production of cytosolic acetyl coenzyme A
2. Carboxylation of acetyl coenzyme A to malonyl coenzyme A
3. Fatty acid synthase

The CoA portion cannot cross the mit
membrane
Condensation reaction between Acetyl
CoA and OAA to generate citrate by
citrate synthase

Q:When would this happen?
Ans: When energy charge is high

When ATP conc is high it inhibits
isocitrate dehydrogenase
Citrate and isocitrate build up
High citrate indicative of high cellular
energy charge
1. Production of cytosolic acetyl coenzyme A

2. Carboxylation of acetyl coenzyme A to
malonyl coenzyme A
3. Fatty acid synthase

The carboxylation of acetyl CoA (2C) to form malonyl CoA (3C) is catalyzed
by acetyl CoA carboxylase (ACC).
This is the rate-limiting and regulated step in FA synthesis
 Short term regulation of ACC

Allosteric Covalent
regulation of regulation of
malonyl CoA acetyl CoA
synthesis by carboxylase by
acetyl CoA AMPK which
carboxylase itself is
regulated both
covalently and
allosterically
 Long-term regulation of ACC
Prolonged consumption of diet with excess calories
(particularly high-CHO) causes an increase in ACC synthesis –
so increased FA synthesis

Synthesis of ACC is upregulated by Insulin via a sterol
regulatory element-binding protein, SREBP-1
 ACC contains a Biotin prosthetic group

Remember: Biotin as a prosthetic group for Pyruvate carboxylase in
gluconeogenesis – both carboxylation reactions
1. Production of cytosolic acetyl coenzyme A
2. Carboxylation of acetyl coenzyme A to malonyl coenzyme A

3. Fatty acid synthase

Fatty acid synthase sequentially adds 2-C units from malonyl-
CoA to the growing fatty acyl chain to form palmitate
After addition of each 2-C unit – the growing chain undergoes
2 reduction reactions that require NADPH (Note: remember PPP)
Fatty acid synthase is a large enzyme
– 2 identical subunits each with 7 catalytic activities
– an acyl carrier protein (ACP segment) which contains a phosphopantetheine
residue (derived from the vit panthothenic acid)
This figure is For clarification of
the process only
You do not need to learn the
details here
No! you do not need to know the names of these enzymes or reactions
Major source of reductant for
FA synthesis
1. PPP major source of supplier of
NADPH
2 NADPH produced for every molecule
of glucose in PPP
2. Cytosolic conversion of malate to
pyruvate
– Malate is oxidized and decarboxylated
by cytosolic malic enzyme (NADP+ –
dependent)
– Note: Malate can also arise from the reduction of
OAA by cytosolic NADH-dependent malate
dehydrogenase
 Further elongation of FA chains
Palmitate (16 carbon) fully saturated LCFA is the
primary end product of fatty acid synthase
activity.
Palmitate elongated by the addition of 2-C units
to the carboxylate end in the smooth ER.
Malonyl CoA is the 2-C donor and NADPH
supplies the electrons
Brain has additional elongation capabilities to
make VLCFAs (>22) which it requires for specific
lipids
 Desaturation of Fatty acid chains
Desaturases in the SER carry out desaturation
of FAs
Require O2, NADH, cytochrome

SER (Smooth Endoplasmic Reticulum)
 Routes to Metabolism
Depends on the chain length of the FA
>C20 = very long chain
C12-C20 = long chain
C6-C12 = medium chain
C4 = short chain
Long chain unsaturated – require additional steps-isomerisation and redox
rxns
Water soluble medium chain –do not require carnitine –occurs only in
the liver
Excess FAs – may undergo microsomal ω-oxidation
Very long chain –straight chain and branched chain –metabolised in
peroxisomes
FA degradation
 Release of FAs from
TAG
 Activation of Hormone-
sensitive lipase (HSL)

 Fate of glycerol
 Enters glycolysis in the fed state
 Fasted state it is converted to glucose
 Very important in prolonged fasting

 Fate of FAs
Note:Glycerol cannot be
metabolised in adipose
tissue – no glycerol kinase

-Transported to liver where it
can be phosphorylated.

The resulting glycerol
phosphate can be used to
i) form TAG in the liver,or
ii) can be converted to
DHAP by reversal of the
glycerol phosphate
dehydrogenase reaction –

DHAP can participate in
glycolysis or
gluconeogenesis.
FA oxidation takes place in the
mitochondrial matrix

Mechanisms must be put in
place in order to transport the
LCFA across the membranes
 1st Reaction of the
Carnitine Shuttle
 Catalyzed by a family of isoenzymes present in the
outer mitochondrial membrane
Acyl-CoA synthetases

General reaction
Fatty Acid + CoA + ATP fatty acyl-CoA +AMP+
PPi
LCFA transported from cytosol to mitochondrial matrix – site of
oxidative degradation
Note Malonyl CoA potent inhibitor of CPT-1- why does that make
good economic sense?
 Sources of Carnitine
Can be obtained from

i) the diet, found mainly in meat

ii) Synthesized from aa lysine and methionine
by an enzymatic pathway found in the liver
and kidney but not in skeletal or heart
muscle
 Carnitine Deficiencies
Result in
1. Decreased ability of tissues to use LCFA as a
metabolic fuel

2. Can cause accumulation of toxic amounts of FFAs
and branched-chain acyl groups in cells.
 CPT-1(Carnitine palmitoyl transferase 1) Deficiency
-Genetic CPT-1 deficiency affects the liver, where
an inability to use LCFA for fuel impairs that
tissues ability to synthesize glucose during a
fast

--This can lead to severe hypoglycemia , coma,
and death
 CPT-2 Deficiency
Occurs mainly in skeletal and cardiac muscle

Symptoms range from cardiomyopathy, to
muscle weakness with myoglobinemia
following prolonged exercise
- An example of how the impaired flow of a metabolite from one cell
compartment to another results in pathological presentation
 -Oxidation of Fatty Acids
The major pathway for catabolism of FA
2-C fragments are successfully removed from
the carboxyl end of the fatty acyl CoA
End products – acetyl CoA, NADH and FADH2
-oxidation of Fatty Acids

4 reactions remove each acetyl-CoA
unit from the carboxyl end of a
saturated fatty acyl-CoA
Each step is catalyzed by enzymes with
chain-length specificity
The 4 steps are repeated

NOTE: Acetyl CoA is a +ive allosteric
modulator of pyruvate carboxylase
 Oxidation of
Unsaturated Fatty Acids

Requires 2 additional enzymes
1. An isomerase
2. A reductase
This diagram is for clarification only – you do not need to remember the no
of ATPs made at any stage of this process
 Regulation of FA Oxidation
Fatty acids are a precious fuel

Liver – FAs formed have 2 fates
1……….  oxidation in mitochondria
2………. Conversion to TAGs and PLs

Pathway taken depends on rate of transfer of
LCFatty acyl-CoA into mitochondria
 Regulation
o Controlled by regulating the entry of FAs into the
mitochondria

- Malonyl-CoA (inhibits CPT-1) – prevents futile
cycling

2 of the enzymes of  oxidation are also regulated by
metabolites that signal energy sufficiency

a) When [NADH]/[NAD ] ratio is high, -hydroxyacyl-CoA
+

dehydrogenase is inhibited

b) Thiolase is inhibited by high concentrations of acetyl-CoA
More than 25 enzymes and specific transport
proteins participate in mitochondrial fatty acid
metabolism.

At least 15 of these have been implicated in
inherited diseases in the human.