Cell Respiration and Metabolism 121
a greater rate of heat loss and less muscle mass (for shiver-
ing) than do adults. Small mammals such as mice retain large
amounts of brown fat into adulthood, but in adult humans the
brown fat is limited to the supraclavicular area of the ventral
neck. Although its distribution is limited, this brown fat is
believed to contribute to calorie expenditure and heat produc-
tion in adults (chapter 19, section 19.2).
Norepinephrine released by sympathetic nerves (chap-
ter 9) stimulates lipolysis within the brown adipose cell.
Figure 5.14 Beta-oxidation of a fatty acid. After the
attachment of coenzyme A to the carboxyl group ( step 1 ), a pair
of hydrogens is removed from the fatty acid and used to reduce
1 molecule of FAD ( step 2 ). When this electron pair is donated to
the cytochrome chain, 1.5 ATP are produced. The addition of a
hydroxyl group from water ( step 3 ), followed by the oxidation of
the b -carbon ( step 4 ), results in the production of 2.5 ATP from
the electron pair donated by NADH. The bond between the a
and b carbons in the fatty acid is broken ( step 5 ), releasing acetyl
coenzyme A and a fatty acid chain that is 2 carbons shorter than
the original. With the addition of a new coenzyme A to the shorter
fatty acid, the process begins again ( step 2 ). Acetyl CoA enters a
citric acid cycle and generates 1 ATP directly and 9 ATP from the
oxidative phosphorylation of 3 NADH and 1 FADH 2 obtained from
the cycle.
See the Test Your Quantitative Ability section of the Review
Activities at the end of this chapter.
H
C
OH
O
Fatty acid
βα
AMP + PPi
AT P
1.5 ATP
CoA
C
O
CoA
HH
Fatty acid C CC
O
CoA
FAD
FADH 2
Fatty acid C
H 2 O
O
C CoA
HO
H
2.5 ATP
NAD
NADH
Fatty acid C
O
Acetyl CoA
Citric
acid
cycle 10 ATP
CoA
1
2
3
4
5
+ H+
HH
CC
HH
Fatty acid
HH
CC
HH
C
H
H
C
O
C CoA
H
Fatty acid now
two carbons shorter
This releases long-chain fatty acids, which activate a unique
uncoupling protein called UCP1 located in the inner mito-
chondrial membrane. This transport protein uncouples
oxidative phosphorylation: it allows H^1 to move from the
intermembrane space into the matrix, thereby dissipating
the H^1 gradient needed to power the production of ATP by
ATP synthase (see fig. 5.9 ). The lower ATP concentrations
that result exert less inhibition of the electron transport
system, increasing the oxidation of fatty acids to generate
more heat.
Ketone Bodies
Even when a person is not losing weight, the triglycerides
in adipose tissue are continuously being broken down and
resynthesized. New triglycerides are produced while others
are hydrolyzed into glycerol and fatty acids. This turnover
ensures that the blood will normally contain a sufficient level
of fatty acids for aerobic respiration by skeletal muscles, the
liver, and other organs. When the rate of lipolysis exceeds the
rate of fatty acid utilization—as it may in starvation, dieting,
and in diabetes mellitus—the blood concentration of fatty
acids increases.
If the liver cells contain sufficient amounts of ATP so
that further production of ATP is not needed, some of the
acetyl CoA derived from fatty acids is channeled into an
alternate pathway. This pathway involves the conversion of
two molecules of acetyl CoA into four-carbon-long acidic
derivatives, acetoacetic acid and b -hydroxybutyric acid.
Together with acetone, which is a three-carbon-long deriva-
tive of acetoacetic acid, these products are known as ketone
bodies (see chapter 2, fig. 2.21). The three ketone bod-
ies are water-soluble molecules that circulate in the blood
plasma, and their production from fatty acids by the liver
is increased when there is increased lipolysis in the white
adipose tissue.