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