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