1 / 57

Energy

Energy. An Introduction to Metabolism. Metabolism. catabolism - breakdown anabolism - synthesize. Metabolic Pathway. Series of enzymatically catalyzed reactions examples Cellular respiration Photosynthesis.

bishop
Download Presentation

Energy

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript

  1. Energy An Introduction to Metabolism

  2. Metabolism • catabolism - breakdown • anabolism - synthesize

  3. Metabolic Pathway • Series of enzymatically catalyzed reactions • examples • Cellular respiration • Photosynthesis http://www.biomedical-engineering-online.com/content/figures/1475-925X-3-15-1-l.jpg

  4. Energy • Capacity to do work, to move matter against opposing force • Kinetic Energy (KE) • energy of motion • Potential Energy (PE) • energy of location or structure

  5. Energy Transformations • KE --------------------> PE sunlight glucose • PE ----------------------> KE glucose breathing

  6. Thermodynamics • The study of energy transformations • Unit of energy = Kcal = 1000 calories • Calorie • Heat required to raise the temperature of 1 g of water 1 °C

  7. Laws of Thermodynamics • Laws that govern energy changes • First Law of Thermodynamics • Second Law of Thermodynamics

  8. First Law of Thermodynamics • Law of Conservation of Energy • Energy cannot be created or destroyed, only transferred and transformed • quantity is constant, not quality • System • collection of matter under study • Closed - system is isolated from its surroundings • Open - energy can be transferred between the system and surroundings

  9. If energy is constant (1st law), why can’t organisms recycle their energy? • Every energy transformation or transfer, some energy becomes unusable (unavailable to do work)

  10. Second Law of Thermodynamics • Entropy (S) increases in the universe • ordered forms of energy are partly converted to heat • Energy transformations are not 100% efficient • it is estimated that in 100 billion years all energy will be converted to heat

  11. Free Energy • energy available to do work ΔG = ΔH - TΔS Δ means "change in" G = ecosystem H = change in total energy in the system T = temperature (°K)→ °C + 273 S = entropy • It informs us if a process can occur spontaneously • free energy is required for spontaneous change

  12. Types of Chemical Reactions • Endergonic reactions • Exergonic reactions

  13. G = free energy • G = G final state - G starting state • G < 0 • releases energy • Exergonic reaction • spontaneous • G > 0 • consumes energy • Endergonic reaction • nonspontaneous • G = 0 • reaction at equilibrium

  14. Exergonic • reactants products ΔG<O example: cellular respiration C6H12O6 + 6O2 6CO2 + 6H2O ΔG = -686 Kcal/mole Exergonic Releases energy (36-38 ATP)

  15. Endergonic • reactants products ΔG>O Example: Photosynthesis ΔG = +686 Kcal/mole Endergonic consumes energy (sun light) 6CO2 + 12H2O C6H12O6 + 6O2 + 6H20

  16. Without ATP Class Activity + GLU = NH3 glutamic acid ammonia glutamine • glutamic acid + ammonia glutamine • ΔG = +3.4 Kcal • Is this exergonic or endergonic? • Does it release or consume energy? • Which has greater free energy? (reactants or products) • How many ATP are needed?

  17. answers • glutamic acid + ammonia glutamine • ΔG = +3.4 Kcal • Is this exergonic or endergonic? Endergonic, the ΔG is positive • Does it release or consume energy? Consumes • Which has greater free energy? Products (reactants or products) • How many ATP are needed? About half (one ATP requires 7.3 Kcal)

  18. Cellular Work • Mechanical work • movement of cell/organelle • Transport work • active transport • Chemical work • synthesis of polymers

  19. ATP • Adenosine Tri Phosphate • Adenosine • Adenine • Ribose • 3 phosphate

  20. ATP Hydrolysis • In lab conditions (standard conditions) • ΔG = -7.3 kcal/mole • exergonic • ATP + H2O ADP + Pi

  21. ATP Synthesis • In lab conditions: • ADP + Pi ATP + H2O • G= +7.3 kcal/mole • endergonic

  22. Activation Energy (EA) • Energy required to break existing bonds before forming new bonds • The difference between free energy of the products and the free energy of the reactants is the ΔG. • reactants absorb E to reach the state allowing bond breakage • new bonds form releasing energy A B A B

  23. Activation Energy (EA) cont.... • Some require a low EA • Thermal energy provided by room temperature is sufficient to reach the transition state • Most require high EA • Gasoline + oxygen, water evaporation • Heat would speed reactions, but it would also denature proteins and kill cells • Enzymes speed reactions by lowering EA • The transition state can then be reached even at moderate temperatures

  24. Catalyst • Chemical agent that accelerates a reaction by reducing the amount of activation energy required • They don’t change the ΔG

  25. Enzymes • Class of proteins serving as catalysts • specific • suffix -ase • Catechol oxidase • Sucrase • ATP synthase • Carbonic anhydrase

  26. Enzymes (cont.) • CO2 + H2O H2CO3 • without enzyme: 200 = 2 x 102 per hour • with enzyme: 2,000,000,000 = 2 x 109 per hr (carbonic anhydrase)

  27. Enzymes are Substrate Specific • Substrate • Active site of enzyme • Induced fit • enzyme-substrate complex

  28. Enzymes • A single enzyme molecule can catalyze thousands or more reactions a second • Enzymes are unaffected by the reaction and are reusable • Most metabolic enzymes can catalyze a reaction in both the forward and reverse direction

  29. Some Factors that Affect Enzyme Activity • temperature • pH • specificity • cofactor necessity • ionic concentration • substrate concentration

  30. 1. Temperature • As T° increases, activity increases BUT • at some point thermal agitation begins to disrupt the weak bonds that stabilize the protein’s active conformation and the protein denatures • each enzyme has an optimal temperature

  31. 2. pH • pH also influences shape • each enzyme has an optimal pH • Most enzymes fall between pH 6 - 8

  32. 3. Specificity • How discriminating the enzyme is in catalyzing different potential substrates

  33. 4. Cofactor Necessity • Some enzymes require a cofactor (nonprotein portion) • they bind to the enzyme permanently or reversibly • Inorganic (cofactor)→ minerals • Organic cofactors (coenzymes) → vitamins, NAD, FAD • The way in which cofactors assist catalysis are diverse

  34. 5. Ionic Concentration • Ions interfere with the enzymes ionic bonds • Can disrupt the tertiary level

  35. 6. Substrate Concentration • Substrate concentration is directly proportional to the rate until saturation of enzyme is reached

  36. ACTIVITY • You are designing an experiment with an enzyme (amylase) that breaks down starch and is present in your small intestine. • What temperature will be the best? • What pH will be the best? • What substrate is the best? • What other factors should you consider?

  37. answers • You are designing an experiment with an enzyme (amylase) that breaks down starch and is present in your small intestine. • Temperature: 37°C • pH: 8 • Substrate: Starch • Other factors to consider: cofactors

  38. Effectors • Chemicals that regulate enzyme activity • Inhibitors • Activators

  39. Inhibitors • Turn enzymes "off" • end product • competitive inhibitor • binds to active site • reversible or permanent • noncompetitive inhibitor • binds to allosteric site • reversible

  40. Applications • Pesticides are toxic to insects; Nerve gas toxic to humans inhibit key enzymes in the nervous system • DDT, malathion and parathion inhibit acetylcholinesterase Nerve cells cannot transmit signals, death occurs • Cyanide inhibits enzyme from making ATP • Many antibiotics inhibit enzymes in bacteria Penicillin inhibits an enzyme used in making cell walls • Cancer drugs inhibit enzymes that promote cell division

  41. Allosteric Enzymes • Enzymes that exist in active or inactive form • There are 3 forms of regulation • Allosteric activator • Allosteric inhibitor • Cooperativity Active form

  42. Allosteric Activator • Binds to allosteric site • stabilize the conformation that has a functional active site • Increases enzyme activity

  43. Allosteric Inhibitor (noncompetitive) • Binds to allosteric site • stabilize the conformation that lacks an active site. • Reduces enzyme activity

  44. Cooperativity • enzyme w/multiple subunits • Binding of one substrate to active site causes all subunits to assume their active conformation

  45. ACTIVITY X A B C Which of these (A, B, C) has a non-competitive inhibitor? What is "X"? What is “Z"? What is “Y”? Z Y

  46. answers • C • Substrate • Competitive inhibitor • Enzyme

  47. ACTIVITY C B A What type of enzyme is this? What is represented by A? What is the effect of C on the enzyme in this case? Is B an example of stable or inactive?

  48. answers • Allosteric • Inactive subunit • Activates the enzyme • Stable

  49. Enzyme structure (some) • Types of enzymes • Enzyme: cofactor independent • Holoenzyme: has a permanently bound cofactor • Enzyme + cofactor • Apoenzyme: has a temporary cofactor • Enzyme portion

More Related