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Transcript 
Chapter 18
Interorgan and Intracellular
Coordination of Energy
Metabolism in Vertebrates
18 - 1
Copyright © 2013 Pearson Canada Inc.
Biochemistry, 4th Edition
Chapter 18 Outline:
• Interdependence of the Major Organs in Vertebrate
Fuel Metabolism
• Hormonal Regulation of Fuel Metabolism
• Responses to Metabolic Stress: Starvation, Diabetes
Copyright © 2013 Pearson Canada Inc.
18 - 2
Biochemistry, 4th Edition
Interdependence of the Major Organs
in Vertebrate Fuel Metabolism
•
Metabolite concentrations represent a significant
intracellular control mechanism.
•
The major fuel depots are triacylglycerols (adipose
tissue), protein (muscle), and glycogen (muscle and
liver).
Copyright © 2013 Pearson Canada Inc.
18 - 3
Biochemistry, 4th Edition
Interdependence of the Major Organs
in Vertebrate Fuel Metabolism
Metabolic interactions among the major fuel-metabolizing organs:
Copyright © 2013 Pearson Canada Inc.
18 - 4
Biochemistry, 4th Edition
Interdependence of the Major Organs
in Vertebrate Fuel Metabolism
Copyright © 2013 Pearson Canada Inc.
18 - 5
Biochemistry, 4th Edition
Hormonal Regulation of Fuel Metabolism
Copyright © 2013 Pearson Canada Inc.
18 - 6
Biochemistry, 4th Edition
Hormonal Regulation of Fuel Metabolism
•
One of the most important roles of liver is to serve as a “glucostat”
monitoring and stabilizing blood glucose levels.
•
Maintenance of blood glucose within narrow limits is critical to brain
function.
•
The key hormones regulating fuel metabolism are insulin, which
promotes glucose use, and glucagon and epinephrine, which
increase blood glucose.
Copyright © 2013 Pearson Canada Inc.
18 - 7
Biochemistry, 4th Edition
Hormonal Regulation of Fuel Metabolism
Actions of glucagon in liver that lead to a rise in blood glucose:
Copyright © 2013 Pearson Canada Inc.
18 - 8
Biochemistry, 4th Edition
Hormonal Regulation of Fuel Metabolism
Copyright © 2013 Pearson Canada Inc.
•
AMPK and mTOR protein kinases play
central roles in orchestrating the
metabolic activity of mammalian cells.
•
AMPK is activated when the energy
charge of the cell is low.
•
Mammalian AMP-activated protein
kinase (AMPK).
18 - 9
Biochemistry, 4th Edition
Hormonal Regulation of Fuel Metabolism
AMPK and mTOR signaling pathways:
Copyright © 2013 Pearson Canada Inc.
18 - 10
Biochemistry, 4th Edition
Hormonal Regulation of Fuel Metabolism
•
mTOR was discovered during biochemical studies with the
bacterial macrolide, rapamycin, a potent
immunosuppressant.
•
Rapamycin binds to a small cellular protein, FKBP12, and
this FKBP12-rapamycin complex allosterically inhibits
mTORC1, but has no effect on mTORC2.
Copyright © 2013 Pearson Canada Inc.
18 - 11
Biochemistry, 4th Edition
Hormonal Regulation of Fuel Metabolism
•
mTOR, in contrast to AMPK, is active under nutrient-rich
conditions, and inactive under nutrient-poor conditions.
•
Sirtuins are a highly conserved family of NAD+-dependent
protein deacetylases.
Copyright © 2013 Pearson Canada Inc.
18 - 12
Biochemistry, 4th Edition
Hormonal Regulation of Fuel Metabolism
•
Sirtuins are named after the founding member of the family, yeast Sir2 (silent
information regulator 2), which deacetylates histones to regulate gene
expression (silencing) of the mating type locus in yeast.
•
Sirtuins are now known to act on many proteins besides histones, and they
are structurally conserved from bacteria to humans.
•
Mammals possess seven sirtuins (SIRT1-7), which differ in their cellular
localization (nucleus, mitochondria, cytoplasm) and protein targets.
•
For most protein targets, deacetylation increases the activity of the target
protein.
•
The deacetylase activity of sirtuins is sensitive to changes in the cellular
levels, being enhanced at high ratios.
•
Thus, sirtuins act as metabolic sensors of the cellular redox state.
Copyright © 2013 Pearson Canada Inc.
18 - 13
Biochemistry, 4th Edition
Hormonal Regulation of Fuel Metabolism
Catalytic core of sirtuins is evolutionarily conserved:
•
X-ray crystal structures of the catalytic cores of
sirtuins from:
a)
b)
c)
d)
e)
•
Copyright © 2013 Pearson Canada Inc.
Yeast
Archaea
eubacterium
Human
yeast Hst2 sirtuin with bound acetylated
peptide substrate and carba-NAD+, a
substrate analog
Show a high degree of structural similarity.
18 - 14
Biochemistry, 4th Edition
Hormonal Regulation of Fuel Metabolism
PGC-1 and SIRT1 control the
reprogramming of fuel utilization
pathways in response to fasting:
Copyright © 2013 Pearson Canada Inc.
•
A high NAD/NADH ratio, in response to
low nutrients (fasting), activates SIRT1
to deacetylate PGC-1 upregulating its
transcriptional coactivator function.
•
Tissue-specific transcriptional activation
programs result in increased
gluconeogenesis (liver) and increased
fatty acid oxidation (skeletal and heart
muscle).
18 - 15
Biochemistry, 4th Edition
Hormonal Regulation of Fuel Metabolism
Copyright © 2013 Pearson Canada Inc.
18 - 16
Biochemistry, 4th Edition
Hormonal Regulation of Fuel Metabolism
•
Calorie restriction (CR) extends lifespan in organisms ranging
from yeast to primates.
•
The mechanisms are not fully understood, but sirtuins are
important mediators of this response.
•
Although resveratrol and newer classes of SIRT1 activators
do indeed confer many phenotypes of CR on fed animals, they
are not likely to represent a simple “fountain of youth.”
•
Nonetheless, pharmacological manipulation of sirtuin function
holds great promise for treatment of aging-related diseases.
Copyright © 2013 Pearson Canada Inc.
18 - 17
Biochemistry, 4th Edition
Hormonal Regulation of Fuel Metabolism
Copyright © 2013 Pearson Canada Inc.
•
Proliferating and nonproliferating cells use different
metabolic strategies to generate energy.
•
Proliferative metabolism, in both unicellular and
multicellular organisms, relies on glycolysis, a rapid
but relatively inefficient process for generating ATP.
•
This “fermentative” metabolism requires abundant
nutrients.
•
When nutrients are scarce, unicellular organisms
adapt to a starvation metabolism, characterized by the
slower, but more efficient, oxidative metabolism.
•
This same efficient oxidative metabolism is used by
nondividing, differentiated mammalian cells.
•
Nutrient abundance is rarely an issue in multicellular
organisms so that the switch between proliferative
and quiescent metabolism is determined by the
presence or absence of appropriate growth factors,
rather than by nutrient availability.
18 - 18
Biochemistry, 4th Edition
Hormonal Regulation of Fuel Metabolism
Fuel and hormonal control of food intake in the arcuate nucleus of
the hypothalamus:
•
Activation of AMPK promotes food intake; inhibition suppresses food intake.
•
Insulin acts through the phosphoinositide 3-kinase (PI3K) cascade to inhibit
food intake.
•
Leptin has both direct and indirect effects (through PI3K and AMPK) on
mTOR.
•
Adiponectin and ghrelin stimulate food intake by activating AMPK.
Copyright © 2013 Pearson Canada Inc.
18 - 19
Biochemistry, 4th Edition
Hormonal Regulation of Fuel Metabolism
Endocrine regulation of food
intake and energy
homeostasis in mammals:
•
Copyright © 2013 Pearson Canada Inc.
The effects of the major
endocrine regulators on AMPK
signaling in brain, adipose
tissue, liver, and skeletal muscle.
18 - 20
Biochemistry, 4th Edition
Responses to Metabolic Stress:
Starvation, Diabetes
Major events in the storage, retrieval, and use of fuels in the fed
and unfed states and in early starvation:
Copyright © 2013 Pearson Canada Inc.
18 - 21
Biochemistry, 4th Edition
•
Responses to Metabolic Stress:
Starvation, Diabetes
•
Copyright © 2013 Pearson Canada Inc.
Metabolic adaptations promote
alternative fuel use during starvation so
that glucose homeostasis is maintained
for several weeks.
18 - 22
Biochemistry, 4th Edition
Responses to Metabolic Stress:
Starvation, Diabetes
•
Diabetes results either from insulin deficiency or from defects in
the insulin response mechanism.
•
Two related mechanisms have been proposed as causes of type
2 diabetes: the lipid overload hypothesis and the inflammation
hypothesis.
•
Diabetes can be thought of as "starvation in the midst of plenty"
because cells are unable to utilize the glucose that accumulates
in the blood.
Copyright © 2013 Pearson Canada Inc.
18 - 23
Biochemistry, 4th Edition
Responses to Metabolic Stress:
Starvation, Diabetes
The metabolic abnormalities in diabetes:
•
The insulin deficiency blocks the uptake of glucose into muscle and adipose
tissue and reduces glucose catabolism in all tissues.
•
Proteolysis in muscle and lipolysis in adipose tissue are enhanced.
•
In the liver, gluconeogenesis from amino acids and citric acid cycle
intermediates is stimulated as the cells attempt to remedy the perceived lack
of usable glucose, and fatty acid oxidation and ketogenesis are also
increased.
Copyright © 2013 Pearson Canada Inc.
18 - 24
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