8.1 Metabolism Flashcards
Enzymes
Substrate binds to active site to be split or binded
Lower activation energy required
Enzyme inhibitors
Competative vs non-competative
Competative blocks active site
Non-competative binds to allosteric side to change the shape of the active site
End product inhibitation
A negative feedback used to regulate the production of a given molecule.
End product combines with with first enzyme
Metabolism
describes the sum total of all reactions that occur within an organism in order to maintain life
activation energy
Enzymes speed up the rate of a biochemical reaction by lowering the activation energy
The certain amount of energy in order to proceed in a reaction.
exergonic = energy released into system
endergonic = lost to the system
End-product inhibition of the pathway that converts threonine to isoleucine
Isoleucine is an essential amino acid, meaning it is not synthesised by the body in humans
In plants and bacteria, isoleucine may be synthesised from threonine in a five-step reaction pathway
- In the first step of this process, threonine is converted into an intermediate compound by an enzyme (threonine deaminase)
- Isoleucine can bind to an allosteric site on this enzyme and function as a non-competitive inhibitor
- This feedback inhibition ensures that isoleucine production does not cannibalise available stocks of threonine
Factors Affecting Enzyme Activity
The Effect of Inhibition on Enzyme Kinetics
Competitive and non-competitive inhibitors effect the kinetics of an enzyme-catalysed reaction in different ways:
Both reduce the rate of reaction by limiting the amount of uninhibited enzyme available for reaction
Metabolic pathways
typically organised into chains or cycles of enzyme-catalysed reactions
Examples of chains: Glycolysis
Examples of cycles: Krebs cycle
