3. Basic Strategies of Catabolic
Metabolism
• Generate ATP
• Generate reducing power
• Generate building blocks for biosynthesis
4. ATP
• Universal currency of energy
• High phosphoryl-transfer potential
• ATP hydrolysis drives reactions by
changing the equilibrium of coupled
reactions by a factor of 108
• Generated from the oxidation of fuel
molecules
5. Reducing Power
• Oxidation of fuel molecules generates
NADH for mitochondrial ETC
• NADPH is generated for reducing power
for biosynthetic processes
• Pentose phosphate pathway is the major
source of NADPH
6. Biomolecules
• Large number of diverse macromolecules
are synthesized from a small number of
building blocks.
• Carbon skeletons from generated from the
oxidation of macromolecules provide the
building blocks for biosynthetic pathways.
9. Relationships between catabolic and
anabolic processes
• The pathway leading to the biosynthesis of a
compound are distinct from the pathway
leading to its breakdown
• This separation ensure that the processes
are thermodynamically favorable in both
directions
• Allows for reciprocal regulation
10.
11. Themes in Metabolic Regulation
• Allosteric regulation
• Covalent modification
• Control of enzyme levels
• Compartmentalization
• Metabolic specialization of organs
12. Allosteric regulation
• Typically associated with enzymes that
catalyze irreversible reactions
• Allosteric regulators can cause feed back or
feedforward regualtion
• Allosteric regulators are often related to the
energy state of the cell
13. • This type of regulation allows for
immediate response to changes in metabolic
flux (milliseconds to seconds)
• Functions at local level
14. Covalent Modification
• Covalent modification of last step in signal
transduction pathway
• Allows pathway to be rapidly up or down
regulated by small amounts of triggering signal
(HORMONES)
• Last longer than do allosteric regulation
(seconds to minutes)
• Functions at whole body level
15. Enzyme Levels
• Amount of enzyme determines rates of activity
• Regulation occurs at the level of gene
expression
• Transcription, translation
• mRNA turnover, protein turnover
• Can also occur in response to hormones
• Longer term type of regulation
17. Specialization of Organs
• Regulation in higher eukaryotes
• Organs have different metabolic roles
i.e. Liver = gluconeogenesis,
Muscle = glycolysis
• Metabolic specialization is the result of
differential gene expression
