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Evolution of metabolism: CELLULAR RESPIRATION

Evolution of metabolism: CELLULAR RESPIRATION. IMSS BIOLOGY ~ SUMMER 2012. LEARNING TARGETS. To understand the evidence for the evolutionary origin of cellular respiration. To understand the impact of oxygen on the evolution of multicellular life on Earth .

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Evolution of metabolism: CELLULAR RESPIRATION

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  1. Evolution of metabolism: CELLULAR RESPIRATION IMSS BIOLOGY ~SUMMER 2012

  2. LEARNING TARGETS • To understand the evidence for the evolutionary origin of cellular respiration. • To understand the impact of oxygen on the evolution of multicellular life on Earth. • To understand the processes by which cellular respiration harvests chemical energy from food and converts it into ATP that fuels cellular work. • To understand the distinctions between aerobic & anaerobic respiration • To understand the role respiration plays on a cellular, organismal, & ecological scales.

  3. Follow up: Photosynthesis Q’s • All plants and most other photosynthetic organisms contain chlorophyll (primary pigment is chl a), but • At least one group of bacteria (halobacteria) rely solely on bacteriorhodopsin (derived from carotene) for photosynthesis

  4. Theory of endosymbiosis • First proposed by Lynn Margulis in 1960s • Much evidence to support eukaryotic cellular respiration originated via endosymbiosis of aerobic purple bacteria (alpha-proteobacteria) which ultimately became mitochondria. • Note: this drawing shows mitochondria endosymbiosis in BOTH animal and plant cells.

  5. Both figures depict endosymbiotic origin of mitochondria. Which important details are portrayed in the one above that are not below (and vice versa)?

  6. Supporting evidence for endosymbiosis • Mitochondria have own genome (mtDNA) and are self-replicating (divide independently of cell they live in) • Genomes are much reduced from alpha-proteobacteria (purple aerobic bacteria) ancestors • mtDNA, mtRNA, ribosomes, and mechanisms of protein synthesis and oxidative metabolism all similar to that of proteobacteria • Mitochondria have double phospholipid bilayers • Evidence supports mitochondria arose ca. 2 bya in a common ancestor of all extant eukaryotes • mtDNA inherited by one’s mother (maternal lineage)

  7. Human mtDNA contains 37 genes which code for proteins needed for normal mitochondrial function, e.g. 13 genes that code for enzymes involved in oxidative phosphorylation.

  8. Mitochondria functions – beyond oxidative metabolism • Oxidative phosphorylation to make ATP • Greatly increases capacities to make ATP! • Many other cellular activities • Assist in regulation of apoptosis (timed cell death) • Genes code for proteins involved in synthesis of heme and cholesterol • Help keep intracellular levels of Ca+2 low inside neurons – important in cell signaling pathways

  9. Nuclear DNA is inherited from all ancestors. Mitochondrial DNA is inherited from a single maternal lineage.

  10. ACTIVITY The Hunt for mtDNA 15 min.

  11. Atmospheric O2through earth’s history • By 1.5 bya, photosynthesis-derived O2 accumulated to significant levels in atmosphere; this in conjunction with mitochondria  Cambrian Explosion during which metazoan radiation occurred

  12. Life in an oxygenated world • Oxygen is highly reactive and potentially toxic – production of reactive oxygen species (radicals), or ROS causes damage to cell membranes, DNA, RNA, proteins(including enzymes and their cofactors) • Aging = accumulated cellular damage caused by ROS

  13. Evolution of multicellularity – from a metabolic perspective • Chloroplasts & mitochondria meet nrg demands of cell via their electron transport systems which generate ROS  oxidative stress and DNA damage in organelles • In unicellular organisms, DNA repair is only way to maintain pristine chromosomal DNA in organelles, but DNA repair is limited. • Better strategy: avoid DNA damage by having separate germ and somatic cell lines • Germ (reproductive) cells: metabolically quiet early in development  germ line DNA protected from oxidative damage • Somatic cells: must be metabolically active as responsive to rapid change • Bendich, A.J. 2010.http://www.biology-direct.com/content/5/1/42

  14. Energetics of genome complexity • All complex life composed of eukaryotic cells. • Eukaryotic cells arose from prokaryotes just once in 4 billion years. Why haven’t prokaryotes evolved greater complexity? • Lane and Martin (2010) propose that prokaryotic genome constrained by energetics • Endoysymbiosis of mitochondria opened door for 200-fold expansion in number of genes that can be expressed. • 75% of cell’s total nrg budget allocated to protein synthesis. • http://blogs.discovermagazine.com/notrocketscience/2010/10/20/the-origin-of-complex-life-%E2%80%93-it-was-all-about-energy

  15. resources • Big themes in evolution of photosynthesis and respiration http://www.shmoop.com/cell-respiration/evolution.html • Origins of development of eukaryotic organisms – mtDNA and cpDNAhttp://www.biology-direct.com/content/5/1/42 • Evolution 101http://evolution.berkeley.edu/evolibrary/news/071101_genealogy

  16. Introduction to Respiration • Via the circulatory system, O2 is delivered to & CO2 is taken away from tissues • Recall that most metabolic processes of the body depend on ATP • What is the function of O2in cellular respiration?

  17. Respiration • Involves ALL processes that deliver O2 from environment to the tissues (cells), including • breathing • gas exhange between air & blood and between blood & tissues • transport of respiratory gases by blood • use of O2 in cellular respiration (aka “internal respiration”)

  18. Cellular Respiration - Overview • occurs primarily in mitochondria • harvests nrg stored in organic “fuel” molecules, e.g. glucose (C6H12O6) by enzymatically breaking these molecules down to release their potential nrg • traps and stores this potential nrg in a form that is usable by the cell – ATP! • uses O2 • produces waste products, CO2 & H2O (used in photosynthesis) • Alternative mode: at ocean’s bottom and other anoxic environments, anaerobic organisms synthesize ATP using nitrate or sulfur rather than oxygen

  19. Cellular Respiration - Overview • The cells of aerobic organisms (e.g. plant & animals) perform cellular respiration • Cellular respiration is the primary way chemical nrg is harvested from food and converted into ATP • ATP = adenosine triphosphate • “Currency” of cellular work • To get nrg to do cellular work, cells must break down energy-containing substances to release their potential nrg stored as ATP that can be later used by cell to fuel an endergonic reaction • ATPase is enzyme that hydrolyzes this terminal phosphate bond • http://faculty.ccbcmd.edu/biotutorials/energy/atp.html#atp

  20. Getting the Perspective • A HUGE amount of ATP is needed to fuel all the cellular activities of an organism! • Example • Average human at rest uses ~45 kg (99 lbs.) of ATP per day (but has surplus of < 1 g of ATP at any given moment) • Estimated that each cell generates & consumes ~10 x 106 molecules of ATP per sec! • So, ATP production must be an on-going process in order to remain alive • Evidence of cellular respiration indicates life!!!

  21. ACTIVITY Is it Alive? 30 min.

  22. Oxidation Glucose loses electrons (and hydrogen) • Most common fuel molecule for cell. resp. is glucose (C6H12O6) • Overall redox reaction: glu oxidized (loses electrons) while O2 reduced (gains electrons) C6H12O6  6 6 O2  6 CO2 H2O Glucose Oxygen Carbon dioxide Water Reduction Oxygen gains electrons (and hydrogen)

  23. Role of Oxygen in Cellular Respiration • Cellular respiration can produce up to 38 ATP molecules for each glucose molecule consumed • During cell. resp., hydrogen (H) & its bonding electrons change “partners” • H & electrons go from glu O2, forming H2O (& ATP) • This H transfer is why O2 is so vital to cellular respiration

  24. Critical Redox Reaction • When hydrogen and water bind to form water, a “burst” of nrg is released • This nrg released as electrons of hydrogen “fall” into their new bonds with oxygen • But, the process needs to be stepped down for a cell to capture this nrg and use it for cellular work.

  25. Role of Electron Transfer • Cellular respiration can be considered a controlled fall of electrons that releases nrg in a stepwise way, like walking down a staircase

  26. 1st step: transfer of electrons from glucose to NAD+ (electron acceptor) which reduces it to NADH

  27. Rest of path: electron transport chain • Involves series of redox reactions • Leads to production of lots of ATP

  28. Unpacking Cellular Respiration • The chemical reactions involved in cellular respiration are grouped into three main stages • Glycolysis • Citric acid cycle • Electron transport chain

  29. The Big Picture

  30. Electron transport chain functions like a chemical machine • Uses nrg released by “fall” of electrons (“pulled” by O2) to pump hydrogen ions (H+) across inner mitochondrial membrane  H+ more concentrated on one side of membrane • This H+ can then rush “downhill” thru membrane protein that “spins” the turbine to activate the enzyme, ATP synthase Fig. 6.11

  31. Cyanide is a deadly poison, because it • Binds to a protein complex in the chain and prevents passage of electrons to O2 • Stops ATP synthesis

  32. Summary of ATP yield during cellular respiration

  33. Monomers from food macromolecules serve as fuel for cellular respiration

  34. Anaerobic Respiration • Some cells can actually work for (short) periods without O2, i.e., anaerobically • Sometimes referred to as fermentation • Involves glycolysis lactic acid • Without O2, electrons “dumped” from NADH onto pyruvic acid in order to regenerate NAD+, so lactic acid is formed

  35. Cellular respiration in Yeast • Yeast (the living organisms in soil sample C of the “It’s Alive” activity) are facultative aerobes. • Undergo aerobic respiration when O2 is present – as was the case during the activity – sugar molecules, CO2(what caused the bubbling in the sample), water, and a high yield of ATP C6H12O6+ 6O2 6CO2 + 6H2O + ATP (hi yield) • Undergo alcoholic fermentation when O2 is absent – sugar molecules broken down into ethanol, CO2 and a low yield of ATP C6H12O6 6C2H5OH + 2CO2+ ATP (low yield)

  36. Nrgflow & chemical cycling in ecosystems Fig. 6.2: Nrg flow & chemical cycling in ecosystems

  37. Misconception: • Plants only perform photosynthesis • Plants perform BOTH photosynthesis andcellular respiration • Plants must be able to harvest nrg (synthesize ATP) from fuel molecules (e.g. glu) in order to grow & reproduce just as animals do • Animals perform cellular respiration only

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