Competitive inhibitors Spontaneous Feedback inhibition Lowering activation energy Gibb’s free energy Exergonic Enzyme 2nd Law of Thermodynamics Chemical energy Thermo- dynamics 7.3 kcal/mol Substrates Metabolic pathway Chemical, transport, mechanical Coenzymes Heat Endergonic Transition state Anabolic 1st Law of Thermodynamics Catabolic ATP Noncompetitive inhibitors Enzyme inhibitors - ΔG Thermal energy Negative Allosteric regulation Cofactors Temperature and acidity Energy coupling Quick, specific, re- useable Cooperativity Potential energy Contorted to unstable state Equilibrium Kinetic energy Metabolism Activation energy + ΔG Competitive inhibitors Spontaneous Feedback inhibition Lowering activation energy Gibb’s free energy Exergonic Enzyme 2nd Law of Thermodynamics Chemical energy Thermo- dynamics 7.3 kcal/mol Substrates Metabolic pathway Chemical, transport, mechanical Coenzymes Heat Endergonic Transition state Anabolic 1st Law of Thermodynamics Catabolic ATP Noncompetitive inhibitors Enzyme inhibitors - ΔG Thermal energy Negative Allosteric regulation Cofactors Temperature and acidity Energy coupling Quick, specific, re- useable Cooperativity Potential energy Contorted to unstable state Equilibrium Kinetic energy Metabolism Activation energy + ΔG
(Print)
Competitive inhibitors
Spontaneous
Feedback inhibition
Lowering activation energy
Gibb’s free energy
Exergonic
Enzyme
2nd Law of Thermodynamics
Chemical energy
Thermo-dynamics
7.3 kcal/mol
Substrates
Metabolic pathway
Chemical, transport, mechanical
Coenzymes
Heat
Endergonic
Transition state
Anabolic
1st Law of Thermodynamics
Catabolic
ATP
Noncompetitive inhibitors
Enzyme inhibitors
- ΔG
Thermal energy
Negative
Allosteric regulation
Cofactors
Temperature and acidity
Energy coupling
Quick, specific, re-useable
Cooperativity
Potential energy
Contorted to unstable state
Equilibrium
Kinetic energy
Metabolism
Activation energy
+ ΔG
