H00102--00A, Front mat Genesis

by Charles Baum

  Spiegelman, Sol, 235–236

  RNA-containing vesicles, 158, 242

  Spiral galaxies, 12, 19, 251

  seawater minerals and, 150

  Spontaneous generation, theory of, 83–

  spontaneous, x, xi, 144, 149, 156,

  85, 144–145, 260

  202

  Squalene, 63–64

  into surface life, 142

  Stanford University, 152

  vesicles, 144, 149

  Steele, Andrew, 72–73, 75, 116, 259

  Self-replication

  Sterols, 63–64, 65, 68, 70, 75

  autocatalytic molecules, 29, 193–194

  Stewart, Potter, 25, 252

  biomolecules, 86, 169, 172

  Strecker synthesis, 91

  citric acid cycle, 212

  Strelley Pool Chert, 55–59

  clay life, 162–163, 165

  Sucrose, 135

  competition and, 234–235

  Sugar phosphates, 160, 171, 222

  cross-catalytic systems, 196–197

  Sugars, 96, 131, 135, 136, 156, 167, 176,

  DNA strands, 194–196

  210, 263, 273

  338

  INDEX

  Sulfur, 274. See also Iron–Sulfur World

  Undersea volcanic vents, ecosystems, 1–

  Summons, Roger, 58–59, 65–67

  2. See also Hydrothermal-origins

  Surface origin of life

  hypothesis

  flat life, 28, 191

  ammonia source, 115

  mineral surfaces, 142, 157, 158

  black smokers, 119, 263

  at ocean–atmosphere interface, 86–

  ecosystems, 96–99

  90, 91, 93, 109, 142, 156–157,

  mineral-rich environment, 111, 114,

  274–276

  118, 119, 206, 211, 212, 234

  on rocks, 157

  sulfide pillars, 119

  Sweden

  Uniformitarians, 28, 253

  Museum of Natural History, 60

  Université Louis Pasteur, 259

  State Power Board, 104

  University of Bristol, 90, 257

  Synthetic life, 238–240, 290

  University of California

  Szostak, Jack, 158, 230, 237, 238, 240,

  Davis, 146

  248, 249, 252, 253, 255, 276, 285,

  Los Angeles, 37, 39, 59

  287, 289–291

  San Diego, 22, 92

  Santa Barbara, 256

  Santa Cruz, 149, 232

  T

  University of Chicago, 81, 86–87, 156

  University of Colorado, 30, 59, 216

  Tartaric acid, 170–171

  University of Florida, 261

  Termite colonies, 19

  University of Houston, 91

  Thalidomide, 168

  University of Illinois, 138, 235

  Thermodynamics, laws of, 11, 12, 13

  University of Karlsruhe, 247

  Thin layer hromatographic analysis,

  University of Miami, 200

  177–179, 231

  University of Montana, 73

  Thioester World, 201–203, 269, 281

  University of Newcastle, 268

  Thioesters, 119, 201–202, 269, 281

  University of Regensburg, 207

  Thiols, 119, 269

  University of Washington, 115

  Threose, 221, 290

  Updike, John, 155

  Thymine, 195, 217

  Uracil, 217

  Titan (moon), 31–32, 106

  Urea, 64, 134

  TNA, 221, 287, 290

  Urey, Harold, 81, 86–90, 92, 200, 261

  Toporski, Jan, 73

  U.S. Geological Survey, 116

  Tree of life, 138–141, 264, 273

  Tricarboxylic acid cycle, 274, 283

  V

  U

  van Kranendonk, Martin, 41

  “Ventists,” 109–110, 112, 266. See also Ultracold vacuum experiments, 92,

  Hydrothermal-origins

  122–123, 146, 148–149, 262

  hypothesis

  Ultraviolet radiation, 81, 85, 86, 91, 93,

  Vesicles, 144–145, 146, 149, 150, 189,

  95, 96, 105, 112, 122–123, 127,

  276

  148, 152, 155, 156, 157, 224, 234

  Violarite, 284

  INDEX

  339

  Viruses, 27, 235–236, 238

  Whitehead Institute, 238

  Vitalism, 83, 84–85, 133

  Whitehouse, Martin, 60

  Volcanic eruptions, x, 262–263. See also

  Wills, Christopher, 87, 109–110

  Undersea volcanic vents

  Wilson, E. O., xi, xii

  von Kiedrowski, Guenter, 196

  Woese, Carl, 138–140, 264, 273, 274

  Wöhler, Frederich, 134, 272

  Wolfram, Stephen, 15–16

  W

  Women, in origins research, 187–188

  Wächtershäuser, Günter, 2, 107, 111–

  115, 118–119, 130, 192, 203, 205,

  X

  206–208, 210, 212, 213, 215, 216,

  260, 261, 263, 266–268, 281, 282,

  X-ray spectrometry, 52

  283

  Xylose, 136

  Walters, Malcolm, 55–56, 58

  Washington University, 125, 282

  Water, 85

  Y

  biomolecular assembly in, 3, 110–

  Yale University, 3, 216, 218

  111, 153, 205, 210

  Ycas, Martynas, 113–114, 267

  dielectric constant, 1, 247–248

  Yeast chromosomes, 237

  at extreme pressure-cooker

  Yoder, Hatten S. (Hat), 4, 9, 107, 109,

  conditions, 2, 108, 247–248

  184, 211

  pyruvate experiments, 4–5

  Watson, James, 194, 196

  Werner, Brad, 22

  Z

  Western Australian

  chert, 54

  Zeolites, 160

  shale, 66

  Zinc sulfides, 118

  Whale, evolution, 77–80, 259–260

  Plate 1

  Harold Morowitz, standing next to his simplified metabolic chart. (Courtesy of H. Morowitz)

  George Cody calibrates his gas chromatography mass

  Hatten S. Yoder Jr. with his high-pressure

  spectrometer, or GCMS, prior to an experiment.

  “bomb.” (Carnegie Institution of

  (R. Hazen)

  Washington)

  Plate 2

  Circles of stones form spontaneously in Arctic regions due to the action of freeze-thaw cycles. (Kessler and Werner 2003; © AAAS)

  The disputed 3.45-billion-year-old Apex Chert fossils of J. William Schopf. (Schopf 1993; © AAAS)

  Plate 3

  Bill Schopf (right) peering at Martin Brasier (at the lectern) during their April 2002 debate at the NASA Astrobiology Institute meeting at Moffett Field, California. (O. Green) Chris Hadidiacos at the Geophysical

  Electron microprobe image of cellular structures

  Laboratory’s electron microprobe. (R. Hazen)

  from a 400-million-year-old fossil wood

  (width = 0.3 mm). (R. Hazen)

  Plate 4

  Marilyn Fogel in the isotope lab. (R. Hazen)

  Andrew Steele at the laser Raman spectrometer. Jake Maule in the astrobiology lab. (R. Hazen) (R. Hazen)

  Plate 5

  Stanley Miller and his electric spark apparatus.

  A black smoker with associated fauna.

  (J.E. Strick and S.L. Miller)

  (NOAA)

  Louis Allamandola at the NASA Ames Research Center with his cryo-vacuum chamber.

  (Volker Steger/Science Photo Library)

  Plate 6

  Dave Deamer and Nick Platts in the Santa Cruz lab. (D. Deamer)

  A

  B

&
nbsp; TLC plate of (A) Murchison organics and (B) pyruvate products. Fluorescent patterns on these plates are strikingly similar. (D. Deamer)

  Plate 7

  These fluorescent vesicles form spontaneously from products of pyruvate at high temperature and pressure (width = 0.55 mm). (D. Deamer)

  A

  B

  Weathered feldspar features numerous microscopic pores (A). Microbes can occupy some of these cavities (B). (J. Smith)

  Plate 8

  Glenn Goodfriend (left) and Stephen Jay Gould in Glenn’s lab at George Washington University, March 2002. (R. Hazen)

  Günter Wächtershäuser, who proposed the elaborate

  Iron–Sulfur World hypothesis for life’s origins.

  (A. Neves, Munich)

  Jack Szostak in his Harvard University lab.

  (J. Szostak)

  Document Outline

  FrontMatter

  Contents

  Foreword

  Preface

  Prologue

  Part I Emergence and the Origin of Life 1 The Missing Law

  2 What Is Life?

  3 Looking for Life

  4 Earth’s Smallest Fossils

  5 Idiosyncrasies

  Interlude—God in the Gaps

  Part II The Emergence of Biomolecules 6 Stanley Miller’s Spark of Genius

  7 Heaven or Hell?

  8 Under Pressure

  9 Productive Environments

  Interlude—Mythos Versus Logos

  Part III The Emergence of Macromolecules 10 The Macromolecules of Life

  11 Isolation

  12 Minerals to the Rescue

  13 Left and Right

  Interlude—Where Are the Women?

  Part IV The Emergence of Self-Replicating Systems 14 Wheels Within Wheels

  15 The Iron–Sulfur World

  16 The RNA World

  17 The Pre-RNA World

  18 The Emergence of Competition

  19 Three Scenarios for the Origin of Life

  Epilogue—The Journey Ahead

  Notes

  Bibliography

  Index

  Plates