Lipid Metabolism PDF

Summary

This document covers lipid metabolism, including beta-oxidation, energy yield calculations, ketogenesis, and fatty acid synthesis. It details the process and reactions involved.

Full Transcript

CHAPTER-IV

LIPID METABOLISM

BETA-OXIDATION

Beta-oxidation is the process by which fatty acids, in the form of acyl-CoA molecules, are
broken down in mitochondria and/or peroxisomes to generate acetyl-CoA, the entry molecule for
the citric acid cycle.

The beta oxidation of fatty acids involve three stages:

1. Activation of fatty acids in the cytosol
2. Transport of activated fatty acids into mitochondria (carnitine shuttle)
3. Beta oxidation proper in the mitochondrial matrix

Fatty acids are oxidized by most of the tissues in the body. However, some tissues such as the
adrenal medulla do not use fatty acids for their energy requirements and instead use
carbohydrates.

Energy yield

The ATP yield for every oxidation cycle is 14 ATP (according to the P/O ratio), broken down as
follows:

Source ATP Total
1 FADH2 x 1.5 ATP = 1.5 ATP (some sources say 2 ATP)[citation needed]
1 NADH x 2.5 ATP = 2.5 ATP (some sources say 3 ATP)
1 acetyl CoA x 10 ATP = 10 ATP (some sources say 12 ATP)
TOTAL = 14 ATP
For an even-numbered saturated fat (C2n), n - 1 oxidations are necessary, and the final process
yields an additional acetyl CoA. In addition, two equivalents of ATP are lost during the
activation of the fatty acid. Therefore, the total ATP yield can be stated as:

(n - 1) * 14 + 10 - 2 = total ATP

For instance, the ATP yield of palmitate (C16, n = 8) is:

(8 - 1) * 14 + 10 - 2 = 106 ATP

Represented in table form:

Source ATP Total
7 FADH2 x 1.5 ATP = 10.5 ATP
7 NADH x 2.5 ATP = 17.5 ATP
8 acetyl CoA x 10 ATP = 80 ATP
Activation = -2 ATP
NET = 106 ATP

For sources that use the larger ATP production numbers described above, the total would be 129
ATP ={(8-1)*17+12-2} equivalents per palmitate.

Beta-oxidation of unsaturated fatty acids changes the ATP yield due to the requirement of two
possible additional enzymes.

Ketogenesis

Ketogenesis is the process by which ketone bodies are produced as a result of fatty acid
breakdown.

Types of ketone bodies

The three ketone bodies are:

Acetoacetate, which, if not oxidized to form usable energy, is the source of the two other
ketone bodies below
Acetone, which, unlike free fatty acids, can be used by the brain for energy. Acetone is
generated through the decarboxylation of acetoacetate which may occur spontaneously or
through the enzyme acetoacetate decarboxylase.
β-hydroxybutyrate, which is not, in the technical sense, a ketone according to IUPAC
nomenclature. It is generated through the action of the enzyme D-β-hydroxybutyrate
dehydrogenase on acetoacetate.
Ketogeenesis pathw
way.
Ketolysis

Each of these compo
ounds is syntthesized from
m acetyl-CoA
A moleculess

hesis of Fattty Acids
BioSynth

Fatty aciid synthesiss is the creattion of fatty acids from acetyl-CoA
a and malonyll-CoA precuursors
through action
a of en
nzymes called fatty acid synthases. It I is an impoortant part of
o the lipogeenesis
process, which - togeether with gllycolysis - sttands behindd creating faats from bloood sugar in living
l
organism
ms.

Much likke β-oxidatioon, straight-chain fatty acid
a synthessis occurs viia the six reecurring reacctions
shown beelow, until th
he 16-carbonn palmitic accid is producced.

The diaggrams presen nted show how
h fatty accids are synnthesized in microorganiisms and lisst the
enzymes found in Escherichia
E coli. These reactions area performeed by fatty acid synthaase II
(FASII), which in geeneral contaiin multiple enzymes
e thatt act as one complex. FA
ASII is preseent in
prokaryootes, plants, fungi,
f and paarasites, as well
w as in miitochondria.

In animaals, as well as
a yeast and some fungi,, these samee reactions occur
o on fattty acid synthhase I
(FASI), a large dimeeric protein that
t has all of the enzym matic activitties requiredd to create a fatty
acid. FASI is less eff
fficient than FASII; how
wever, it allowws for the formation
fo off more moleccules,
includingg “medium-cchain” fatty acids via earrly chain term
mination.
Saturateed Straight-Chain Fattyy Acids

Once a 16:0
1 carbon fatty acid has
h been forrmed, it cann undergo a number of modification
m ns, in
particularr by fatty acid synthase III (FAS
SIII), whichh uses 2 caarbon moleccules to elonngate
preformeed fatty acidss.

Regulatiion

CoA is formeed into maloonyl-CoA by acetyl-CoA carboxylaase, at whichh point malonyl-
Acetyl-C
CoA is destined
d to feed
f into thhe fatty acid synthesis pathway.
p Accetyl-CoA caarboxylase is i the
point off regulation in saturated straight-cchain fatty acid syntheesis, and is subject to both
phosphorrylation andd allosteric regulation. Regulation by phosphhorylation occurso mostly in
mammals, while allosteric reguulation occurrs in most organisms. Allosteric controlc occuurs as
feedbackk inhibition by
b palmitoyyl-CoA and activation by b citrate. When
W there are
a high leveels of
palmitoyyl-CoA, the final producct of saturatted fatty acid synthesiss, it allosteriically inactiivates
acetyl-CooA carboxylase to prevvent a buildd-up of fattyy acids in cells.
c Citratee acts to acttivate
acetyl-CoA carboxylase under high levels, because high levels indicate that there is enough
acetyl-CoA to feed into the Krebs cycle and produce energy.

K.ANITA PRIYADHARSHINI

LECTURER

DEPT.OF PHARMACEUTICAL CHEMISTRY

SRM COLLEGE OF PHARMACY