Cellular Energy: ATP & Enzymes What is it? Where do we get it? How do we use it?
Energy The capacity to perform work; ability to rearrange matter Energy is required to drive reactions 2 forms: –Potential Energy (PE): stored energy, due to position of structure –Kinetic Energy (KE): Energy of motion Heat is KE associated with the movement of molecules/atoms within matter
Energy is just transformed Total amount of Energy in Universe is constant (1 st Law) –Nothing created or destroyed, only transformed One result of ALL energy transfers is the production of heat (2 nd Law) –Heat = disordered, unharnessed KE. This KE is LOST; cannot be used to perform work
Energy is lost during rxns
Chemical Reactions Endergonic (energy input): Store Energy – products have higher energy than reactants; Anabolic Exergonic (energy output): Release Energy – products have lower energy; Catabolic
Endergonic/Anabolic Photosynthesis: –Reactants = CO 2 & H 2 O + light energy –Products = sugar molecules
Exergonic/Catabolic Bonfire –Reactants: Cellulose (glucose), O 2 –Products: light, heat, CO 2, H 2 O Cellular respiration “burns” glucose to harness energy for work
Anabolic and Catabolic Reactions ProteinGlycogen Glucose Amino acids ANABOLIC REACTIONS CATABOLIC REACTIONS Glycerol Uses energy Uses energy Uses energy Yields energy Yields energy Yields energy Yields energy Triglycerides ProteinGlycogenTriglycerides Fatty acidsAmino acids Fatty acids Glycerol Glucose+++
Cellular metabolism The sum of all cellular endergonic and exergonic rxns. Energy coupling (transfer) = use of released energy to run cellular processes ATP provides coupling mechanism
ATP High energy bonds join negatively charged phosphate groups –Energy in bonds + energy of magnetic repulsion (high PE!) Hydrolysis rxn frees trapped energy
ATP Some freed energy is lost as heat The rest is transferred via the phosphate group when it binds to another molecule (phosphorylation)
ATP fuels ALL cellular work
ATP is continually regenerated
Enzymes are also required to drive reactions
Enzymes lower Activation Energy Some energy (E A ) must be applied to begin a rxn –Sometimes the energy barrier is prohibitively large –Enzymes reduce that barrier, allowing rxn to proceed with LESS energy input
Enzyme cycle 1.Available enzyme w/ active site 2.Substrate binds 3.Conversion to products 4.Products released
Enzymes possess: Ideal temperature regimes Ideal pH ranges Cofactors (inorganic molecules & ions) and coenzymes (organic molecules)
What fuels our bodies? 1.Adenosine triphosphate (ATP) 2.Creatine Phosphate (CP) 3.Glucose 4.Fats
What fuels our bodies? Adenosine triphosphate (ATP) – THE energy carrying molecule in the body Muscles store only enough ATP for 1 – 3 seconds of activity –ATP must be generated continuously Usually via carbohydrate metabolism with or without O 2
ATP structure
Alternative Fuels After depleting ATP stores, muscles turn to other sources: –Creatine phosphate (CP) stores energy that is used to make ATP –Creatine phosphate stores enough energy for 3 to 15 seconds of maximal physical effort
CP transfers P to make ATP
Glucose After CP, Glucose is the next source of energy for production of ATP Metabolism of glucose –Anaerobic breakdown of glucose yields 2 ATP molecules (no O 2 ) –Aerobic breakdown of glucose yields 36 – 38 molecules of ATP (with O 2 )
Glucose metabolism In cytoplasm In mitochondria
Fat as fuel Stored triglycerides can be metabolized to generate ATP –For low intensity exercise –For exercise of long duration Ex: 10 hr. car-to-car approach + climb –Abundant energy source. –Provides 2x more energy per gram as carbohydrate
Carbs. or Fats Use BOTH as energy sources for production of ATP –Carbohydrates - high intensity activity –Fats - low intensity exercise Proteins (amino acids) rarely used as a fuel source for exercise
Distribution Short duration, max. int. (0-3 sec) Short duration, high int. ( sec) Short-Mid duration, high int. (4-6 min) Mid duration, moderate int. (32-40 min) Long duration, moderate int. (2.5-3 hr) Extended duration, low-mod int. (5.5-7 hr)