1 / 49

Origins and Early Evolution of Life

Origins and Early Evolution of Life. Richard Vann CBI 206/ANESTH 445 Physiology and Medicine of Extreme Environments Spring 2013. Origin of Life Topics. Who, when, what, where, how, why Discussion. Panspermia & Spontaneous Generation. Anaximander 611-547 BC. Anaxagoras 500?-428 BC.

isanne
Download Presentation

Origins and Early Evolution of Life

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. Origins and Early Evolutionof Life Richard Vann CBI 206/ANESTH 445 Physiology and Medicine of Extreme Environments Spring 2013

  2. Origin of Life Topics • Who, when, what, where, how, why • Discussion

  3. Panspermia & Spontaneous Generation Anaximander 611-547 BC Anaxagoras 500?-428 BC Aristotle 384-322 BC • Panspermia: life exists throughout the universe • Spontaneous generation: life forms by the action of the sun on the primordial terrestrial slime

  4. Recipe for Mice:Jan Baptista van Helmont (1580-1644) • Put a soiled shirt and grains of wheat in a jar and let them ferment • Mice form after 21 days • No experimental evidence provided

  5. Friedrich Wöhler & Urea (1828) • Organic and non-living compounds are different (“élan vital, life force, will-to-live”) • Wöhler made urea by heating ammonium cyanate • "I can no longer, so to speak, hold my chemical water and must tell you that I can make urea without needing a kidney, whether of man or dog." • A founder of organic chemistry

  6. Death of Spontaneous Generation:Louis Pasteur (1859) • Living systems arise biotically from other living systems

  7. Charles Darwin (1871) “But if (& oh what a big if) we could conceive in some warm little pond with all sorts of ammonia & phosphoric salts, - light, heat, electricity, etc. present, that a protein compound was chemically formed, ready to undergo still more complex changes …” - letter to Joseph Hooker

  8. Aleksandr Oparin (1924) • Early atmosphere was strongly reducing • CH4, NH3, H2O , H2 (no O2) • Sunlight reacted with non-living chemicals in the “primeval soup” • Unique, abiogenic, spontaneous generation of life • No difference between a living organism and lifeless matter

  9. J.B.S. Haldane (1929) “When ultra-violet light acts on a mixture of water, carbon dioxide and ammonia, a vast variety of organic substances are made, including sugars and apparently some of the materials from which proteins are built up … [B]efore the origin of life they must have accumulated till the primitive oceans reached the consistency of hot dilute soup.”

  10. Harold Urey1893-1981 Stanley Miller1930-2007

  11. Miller-Urey Ocean-Atmosphere (1953)

  12. Miller (1953). Production of amino acids under possible primitive Earth conditions. Science 117: 528.

  13. Space • Radio astronomy found evidence of organic molecules on space dust • Laboratory simulations of deep space created organic molecules • Collisions of comets with primitive Earth • Murchison meteorite in Australia 1969 contained organic molecules

  14. Exogenesis and Mars • Mars may have been habitable a billion years before Earth • A meteorite from Mars recovered in 1984 was claimed to contain fossil life but this is disputed • The question of exogenesis from Mars to Earth is unresolved

  15. Hydrothermal Volcanic Vents Giant Clams DSV Alvin (1977) Tube Worms Hydrothermal vents

  16. Corliss, Baross & Hoffman. 1981. An hypothesis concerning the relationship between submarine hot springs and the origin of life on Earth. OceanolgicaActa 4 (Suppl): 59-69.

  17. Deep, Hot Biosphere Rock-Eating Bacteria Yellowstone (1966) Thermophiles • Laboratory Simulations • Reactants: N2, CO2, S, Fe • Minerals: Fe-S, Ni-S • Products: NH3, amino acids, peptide bonds, C-fixation Fe-complexes

  18. Origin of Primordial Molecules - Deamer (2002)

  19. Timeline ~13.7 bya “Big Bang” (atomic evolution) ~11.5 Supernovae & heavy elements ~4.6 Sun, solar system & Earth ~4.4 Oceans formed ~4.4-3.9 Chemical evolution ~4.2-4.0 Earliest life at hydrothermal vents? 4.0-3.7 Earliest life at sea level? ~3.5 Earliest fossils (Apex chert, WestAus) ~0.5 Organic evolution (‘naked genes’) ~1 mya Social evolution (humans)

  20. When was Earth Ready for Life? - Schopf (2002) Oldest Fossils: Stromatolites Sterilizing Meteor Storms Origin of Sustained Life Success of Life 3.5 3.0 3.9 4.5 4.0 Planetary Birth Billions of Years Ago (bya)

  21. Life and the Atmosphere OXYGEN CATASTROPHE SUSTAINED LIFE STERILIZING METEOR STORMS OLDEST FOSSILS: STROMATOLITES EUKARYOTES CHEMICAL EVOLUTION O2 metab BIF

  22. 3.9 – 3.5 bya Time Many early life forms (temperature, anaerobic, radiation, arsenic, salt) Present Biochemistry (ATP, Krebs cycle, RNA, DNA) O2 Catastrophe LUCA

  23. NASA Definition of Life • “A self-sustaining chemical system capable of Darwinian evolution” • Self-sustaining (energy production) • Chemical system (cell membranes) • Darwinian evolution (replication) • What’s the driving force that makes this system run?

  24. Energy and Complexity - Chaisson (2001) Stars 2 erg/g/sec Planets 75 Large animals 20,000 Human brain 74,000 Society 500,000

  25. Sagaminopteron Ornatum

  26. Thermodynamics • 1st Law: energy is conserved, not created or destroyed • all forms of energy are inter-convertible • 2nd Law: heat flows from higher to lower temp • Energy conversions are never complete • Some energy is always lost to the environment as wasted heat (ΔQ) • Entropy (S) = wasted heat divided by the environmental temperature (ΔS=ΔQ/T) • Entropy is generated with each energy conversion • The entropy of a closed system always increases • Entropy is “time’s arrow”

  27. Entropy Generation Rate - Silva (2008)

  28. Entropy (S) and “Heat-Death” Universe • Life is maintained by energy input from the universe & entropy export to the universe • Does time stop when dS/dt=0? dS/dt > 0 ∆Suniverse > 0 Energy Life ∆Slife = 0

  29. How Did Early Life Get Energy? • Heterotroph – the ‘premordial soup’ provided high energy complex molecules that had been abiotically synthesized (Oparin & Haldane). • Modern heterotrophs eat other organisms. • Autotroph – energy derived from oxidation of ammonia to nitrous & nitric acid, sulfur to sulfurate, iron to iron oxide, and methane to carbon dioxide & hydrogen.

  30. Reverse TCA Cycle no catalyst: very slow 2 CO2 + 4 H2 2 H2O + C2O2 (acetate)

  31. Iron-Sulfur World - Günter Wächtershäuser • Life originated on mineral surfaces near deep hydrothermal vents (“primordial sandwich”) • 1st cells were lipid bubbles on mineral surfaces • Metabolism predated genetics with iron sulfides as energy source (chemoautotrophs) • Photoautotrophs evolved as chemical energy was deleted • Autocatalytic & self-replicating metabolism

  32. Thioester World - de Duve • Thioester bonds are high energy & played the role of ATP in early life • Thioesters are intermediates in the ancient processes leading to ATP • Thioesters evolved into ATP

  33. Driving Force: Entropy & Probability • Heat is molecular motion • Most probable configuration has greatest entropy S1 < S2 Less probable (S1) More probable (S2) • Attractive & repulsive intermolecular forces determine the most probable configuration More probable (S4) Less probable (S3) S3 < S4

  34. Simulation of Self-Assembly http://complex.upf.es/~harold/lipid_world/index.html Before self-assembly (low S) After self-assembly (high S)

  35. Self-Assembly of Liposomes - Bangham (1961); Deamer (1997, 2002) Murchinson Meteorite extract Murchinson Liposomes

  36. Biological Self-Assembly • Lipid bi-layer membranes • Structure guided by attractive & repulsive forces (“lock-and-key”) • Antibody & antigen • Substrate & enzyme

  37. Lipid World - Serge, Ben-Eli, Deamer, Lancet (2000) • Coacervates. 1-100 μ “proto-cells” (Oparin 1932) • Microspheres formed by heat-polymerized amino acids (Fox 1957) • Murchison carbonaceous meteorite (Deamer 1997). Catalytic activity, replication, etc. also proposed.

  38. Tobacco Mosaic Virus (TMV) • TMV self-assembly from separated protein & RNA

  39. Darwinian Evolution - Darwin (1959) • Modified progeny of ‘A’ are better adapted to the environment & survive • Subsequent generations of ‘B’ – ‘F’ are unmodified & become extinct • Track ‘A’s genealogy into deep time to find LUCA • Fossil record too limited

  40. Systematics or Phylogenetics - Haeckel (1866) • Commonality of traits • Animals – consumers • Plants – producers • Protists – reducers • Eucaryote* – nucleus, etc. • Prokaryote* – no nucleus * Stanier (1961) [common biochemistry] • LUCA • Fossils–no! Genetic code? Evolutionary time

  41. DNA Code Cytosine Guanine Adenine Thymine

  42. RNA World • RNA-based life predated DNA life • RNA can act as its own catalyst (‘ribozyme’) so proteins were unnecessary • RNA evolved into DNA which is more stable • Ribosomal RNA (rRNA) is a remnant of the RNA World • Problems: RNA chemically fragile, difficult to synthesize abiotically, limited catalysis

  43. Pre-RNA Worlds • Alternative nucleic acids • RNA precursors: threose nucleic acid (TNA), PNA (peptose), GNA (glycol) • PAH (Polycyclic Aromatic Hydrocarbon) World • PAHs are amphiphilic and might self-organize in stacks as a nucleic acid backbone

  44. Clay World - Cairns-Smith (1985) • Proto-life was inorganic and existed on solid surfaces such as clays • Clays catalyzed formation of complex organic molecules • Clays acted as template for RNA self-assembly and evolved into RNA • Natural selection enhanced their replication potential

  45. Ribosome - Woese (1981) • Site of protein synthesis in all cells • Functionally constant over time • Ribosomal RNA 16S • RNA “dictionaries” → phylogenetic trees • Genotype → phenotype (cell membranes)

  46. Phylogenetic Tree of Life (16S rRNA) - Woese (1990) ‘progenotes’

  47. Horizontal Gene Transfer (HGT) • ‘Infective heredity’ • Endosymbiosis • Mitochondria (1.7-2 bya) • Plastids (1.5 bya) • Antibiotic resistance • Plasmids • Viruses

  48. Artificial HGT (Social Evolution) - Craig Venter • Sequence yeast cell genome (Myoplasma mycoides) • SynthesizeM. mycoides genome from lab chemicals • Transplant synthetic genome into recipient cell (M. capricolum) • Test viability of synthetic cell • Next find minimal viable synthetic genome • Applications – bio-fuels, vaccines, drugs, etc.

  49. What are the limitations of the field? • What came first: metabolism or replication? • What would be the result if you could re-run evolution again beginning from the Big Bang? • What would be the result if you re-ran evolution from the Big Bang 1,000 times? • Is laboratory investigation of the creation of some form of life valuable? • If you were in charge of an origin of life lab, where might you focus your efforts?

More Related