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