3 types of Enzyme inhibition, inhibitor mode of action Flashcards
Inhibitor
A molecule that acts directly on enzyme to lower the rate of reaction
- Normal cellular inhibitor (product, feed-back)
- Toxins (nerve gas, venom, cyanide etc.)
- Drugs (penicillin etc.)
Normal inhibitor to reduce overproduction of a molecule
Toxins are induced externally which can be fatal
Drugs are taken in externally for treatment
2 groups of inhibitor
Reversible and Non-reversible
3 types of reversible inhibition
- competitive
- non-competitive
- uncompetitive
Reversible inhibition
On/off inhibition
irreversible inhibition
Always on inhibition
How to overcome reversible competitive inhibitor
Overcome it by removing it from the enzyme by 2 methods
Dialysis or dilution
Inhibitor is loosely bound to the enzyme by non-covalent bonds.
Mechanism of competitive inhibitor
Inhibitor and substrate compete for the same active site. Inhibitor have the same shape as substrate. Increasing the S can outnumber the inhibitor.
This is reversible
Mechanism of non-competitive inhibitor
Inhibitor and substrate do not compete for the same active site. Inhibitor have a different shape from substrate. Inhibitor will bind to a allosteric site and change the conformational shape of the enzyme. Non-competitive inhibitor can bind to enzyme before and after reaction.
Increasing S will not overcome its inhibition.
Mechanism of uncompetitive inhibitor
Uncompetitive inhibitor can only bind to the ES complex.
Increasing the S favors its inhibition.
Vmax and Km of competitive inhibitor vs no inhibitors
Vmax is not changed as there is still a substrate concentration where full enzyme activity can be achieved. Inhibitor can be diluted out by the substrate.
Km is increased as at lower substrate concentrations, inhibitor interferes with the binding between enzyme and inhibitor
Vmax and Km of non-competitive inhibitors vs no inhibitors
Vmax is decreased and Km is unchanged.
Km is unchanged as increasing the concentration of the substrate does not reduce this type of inhibition.
Vmax is decreased as fewer functional enzymes leads to fewer available active sites and thus a smaller Vmax.
Draw the Michaelis mentis graph for competitive inhibition
Same asymptote
Higher curve than normal
Draw the Lineweaver burk graph for competitive inhibition
Cut at the same y intercept for competitive inhibitor
Competitive inhibitor cuts at a smaller x intercept
Draw the eadie hofstee graph for competitive inhibition
Slope is much steeper for competitive inhibitor
Vmax, the y intercept cuts as the same point
Draw the Michaelis mentis graph for non-competitive inhibition
Lower asymptote
Same level of Km
