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Neanderthal Man

Page 31

by Pbo, Svante


  Postscript

  __________________

  Three years later, as I write this, we still do not know what happened to the other part of the finger bone that Anatoly sent to Berkeley. Perhaps one day it can be used for dating so that we will know when the Denisova girl lived.

  Anatoly and his team have continued to unearth amazing bones in Denisova Cave. They have found another huge molar that contains Denisovan DNA. They have also found a toe bone that turned out to come from a Neanderthal.

  David Reich and his postdoc Sriram Sankararaman have used genetic models to date the admixture between Neanderthals and modern humans to sometime between 40,000 and 90,000 years ago.{65} This shows that actual interbreeding between Neanderthals and modern humans has caused the extra similarity between the Neanderthal genome and the genomes of people in Europe and Asia, not the more complicated scenario of ancient substructure in Africa that we also considered in 2010.

  Matthias Meyer, something of a technical wizard in our lab, has developed new and amazingly sensitive methods to extract DNA and make libraries. This has allowed us to use the tiny leftover fragments of the Denisova finger bone to sequence its genome to a total coverage of 30-fold.{66} Recently, we have followed up by sequencing the Neanderthal genome from the toe bone found in Denisova Cave to 50-fold coverage. These ancient genomes are now of higher accuracy than most genomes determined from people living today.

  When we compare the Neanderthal genome to the genome of the Denisovan girl, we see that she carried a component in her genome from a hominin that diverged from the human lineage earlier than Neanderthals and Denisovans. We also see that Denisovans mixed with Neanderthals, and that they contributed small amounts of DNA not only to people in Melanesia but also to people who live on mainland Asia today. These were subtle signals of past mixing that we could not see in 2010, when we worked with genomes of lower quality. The picture that emerges is that there was plenty of mixing among several types of humans in the late Pleistocene, but mostly of small proportions.

  Together with new data from the 1,000 Genomes Project, these two archaic genomes of high quality now allow us to create a near-complete catalog of sites in the genome where all people today are different from Neanderthals and Denisovans as well as from the apes. This catalog contains 31,389 single nucleotide changes and 125 insertions and deletions of a few nucleotides. Of these, 96 change amino acids in proteins, and perhaps 3,000 affect sequences that regulate how genes are turned on and off. There are surely some nucleotide differences, particularly in repetitive parts of the genome, that we have missed, but it is clear that the genetic “recipe” for making a modern human is not very long. The next big challenge is to find out what the consequences of these changes are.

  George Church, a brilliant technical innovator at Harvard University, has suggested that scientists should use our catalog to modify a human cell back to the ancestral state and then use that cell to recreate or “clone” a Neanderthal. In fact, already when we announced that we had completed the Neanderthal genome sequencing at the AAAS meeting in 2009, George was quoted by the New York Times as saying that “a Neanderthal could be brought to life with present technology for about $30 million.” He added that if someone were eager to supply the financing, he “might go along with it.” To his credit, he acknowledged that there are ethical problems with such a project, but suggested that to avoid those, one could use not a human cell but a chimpanzee cell!

  This, as well as later statements to the same effect, I write off as George’s tendency to be provocative. Nevertheless, they point to a dilemma. How do we study traits specific to humans—for example, language or aspects of intelligence—when for both technical and ethical reasons we cannot do what George suggests? The way forward is, on the one hand, the introduction of human and Neanderthal genetic variants into the genomes of human and apes cells that can then be used not to clone individuals but to study their physiology in a plastic dish in the laboratory and, on the other hand, the introduction of such variants into laboratory mice. Our laboratory in Leipzig has already taken the first steps in that direction. In 2002, we found that the protein made from a gene called FOXP2, which Tony Monaco’s group in Oxford, England, had shown to be involved in language ability in humans, differed at two amino-acid positions from the same protein in apes and almost all other mammals.{67} Encouraged by the fact that the mouse FOXP2 protein is very similar to the FOXP2 protein of the chimpanzee, we decided to introduce the two human changes into the mouse genome. It took several years of hard work by a talented student, then postdoc, then group leader in our lab, Wolfgang Enard, until the first mice that made the human version of the FOXP2 protein were born. The results greatly exceeded my expectations. The peeps the pups produced at about two weeks of age when removed from the nest differed subtly but significantly from those of their non-humanized littermates, supporting the idea that these changes have something to do with vocal communication. This finding has led to much more work showing that the two changes affect how neurons extend outgrowths to contact other neurons and how they process signals in parts of the brain that have to do with motor learning.{68} At the moment, we are collaborating with George Church to put these changes into human cells that can be differentiated to neurons in the test tube.

  Although the two changes in FOXP2 are actually shared with Neanderthals and Denisovans, {69} these experiments nevertheless point to how, in the future, we may sort out which changes are crucial for what makes modern humans special. One can imagine putting such changes into cell lines, and into mice, alone and in different combinations, in order to “humanize” and “neanderthalize” biochemical pathways or intracellular structures, and then to study their effects. One day, we may then be able to understand what set the replacement crowd apart from their archaic contemporaries, and why, of all the primates, modern humans spread to all corners of the world and reshaped, both intentionally and unintentionally, the environment on a global scale. I am convinced that parts of the answers to this question, perhaps the greatest one in human history, lies hidden in the ancient genomes we have sequenced.

  About the Author

  ____________________________

  Svante Pääbo is the director of the Department of Genetics at the Max Planck Institute for Evolutionary Anthropology in Leipzig, Germany. He has been featured in the New York Times, Newsweek, National Geographic, and The Economist, as well as on NPR, PBS, and the BBC. In 2009, Time named him one of the 100 Most Influential People in the World. Pääbo lives in Leipzig.

  Index

  ________________

  Academy of Achievement, 163

  Adenovirus, 24

  Africa

  Denisovan data, 244–245

  gene flow through, 192

  impact of Neanderthal DNA findings, 222–223

  replacement crowd, 198–200

  See also Out-of-Africa hypothesis

  Africans, modern

  exchanges with Europeans, 187–188

  mapping the Neanderthal genome, 155

  MHC gene variability, 224

  mtDNA comparisons with ancient DNA, 12

  Neanderthal nucleotide matches, 183

  San genome, 185–188

  SNPs as indication of interbreeding, 173–177

  AIDS, 36

  Akademgorodok, Siberia, 232–236

  Allelic surfing, 194, 199

  Almas (snow men), 235

  Alu elements, 33–34

  Amber, DNA preservation in, 57–58, 61, 105

  American Association for the Advancement of Science (AAAS), 165–166, 176, 224–225

  American Museum of Natural

  History, 57–58

  Amino group loss, 5–8, 113

  Amino-acid preservation, 78

  Amplification of DNA

  limitations of ancient samples, 46

  Native American remains, 71

  Oetzi, the Ice Man, 69–70

  PCR process, 8–12

  PCR process on mummy a
nd

  thylacine samples, 39–40

  Anasazi, 131

  Ancestors. See Common ancestors

  Ancestral allele, 156–158, 181, 243

  Ancestry testing, 202–203

  Animal droppings, DNA in, 56, 105–107

  Antediluvian DNA, 58–59

  Apes, 89–90

  cognitive development, 85–86, 205–207

  comparing Neanderthal, modern human and ape genomes, 182

  genome analysis of modern humans and, 219

  nuclear DNA variation, 92

  See also Chimpanzees; Gorillas

  Asia

  ancient Native American DNA sequences, 44

  Middle East origins scenario, 189

  replacement crowd, 199

  Asians, modern

  comparing, Neanderthal, African, and Chinese genomes, 177

  Denisovans’ contribution to the Asian genome, 245, 247, 251–252

  mapping Neanderthal gene flow, 194–195

  MHC gene variability, 224

  mtDNA comparisons with ancient DNA, 12

  multiregional model of human origins, 20–21

  reaction to Neanderthal DNA findings, 222–223

  Aurignacian culture, 198

  Autrum, Hansjochem, 50

  Bacteria, mtDNA in, 59

  Bacterial cloning, 25, 109–111, 114–115, 121–122, 128

  Bacterial DNA, 57, 146–151, 153

  Behaviors and rituals, 3

  Bentley, David, 161–162

  Bergström, Sune, 184

  Berlin-Brandenburg Academy of

  Sciences and Humanities, 134–135, 138

  Blank extract, 51, 54

  Bodmer, Walter, 82

  Boesch, Christophe, 83–84, 89–90

  Bonobos, 94, 212

  Bougainville, 245–247

  Brajković, Dejana, 130, 132

  Brain size, 219

  Briggs, Adrian, 147(fig.), 171, 228, 239–242

  AAAS conference, 166

  background, 114–115

  comparing Denisova and modern genomes, 246

  454 process, 117, 119

  increasing Neanderthal DNA proportions, 148

  increasing sequencing efficiency, 122

  Brigham Young University, Utah, 58–60

  Broad Institute, 164–165, 171

  Bronze Age humans, 52, 76

  Burbano, Hernan, 147(fig.)

  Bustamante, Carlos, 249

  California Polytechnic State

  University, 58

  Cannibalism, 131–132

  Cano, Raul, 58

  Carmel mountains, Israel, 197

  Cartilage, DNA remains in, 30, 30(fig.), 54–55

  Cavalli-Sforza, Luca, 93

  Cave-bear bones, 76–78, 97, 99–101, 103–104, 109–113

  Cell journal, 18–21, 79, 165

  Cetus Corporation, 40–41

  Chimpanzees, 89–90, 183

  ancestral and derived alleles, 176

  cognitive development, 207

  common ancestor of humans and, 93(fig.), 169

  comparing human genome and chimpanzee genome, 4

  comparing Neanderthal, modern human and ape genomes, 182

  competition for reproduction,

  212

  genetic variation, 79, 93–94

  reconstructing the ancestral

  genome, 169

  reference for Neanderthal genome mapping, 155–156

  See also Apes; Gorillas

  Chinese genome

  comparing, Neanderthal, African, and Chinese genomes, 177

  Denisovan SNPs, 244

  mapping gene flow, 194–195

  Neanderthal nucleotide matches, 183

  sequencing modern genomes, 185–186, 189

  Chromosome 17 inversion, 166–167

  Church, George, 252–253

  Clean room procedures, 52–57, 87–88, 87(fig.)

  Clegg, J.B., 55

  Cloning

  bacterial cloning, 25, 109–111, 114–115, 121–122, 128

  bringing a Neanderthal to life, 252

  Cetus Corporation processes, 40

  Croatian Neanderthal samples, 78–79

  independent verification, 14–18

  mammoth remains, 101–103

  mummy DNA, 32–35

  Native American remains, 71

  Oetzi, the Ice Man, 69–70

  PCR process, 8–12

  quagga DNA, 34, 40–41

  reconstruction of Neanderthal mtDNA, 11(fig.)

  thylacine data, 44–45

  transplantation antigens, 24

  See also Polymerase chain reaction

  Cognitive development, 205–207

  Cold Spring Harbor Laboratory, 37–38, 43–44, 116, 120, 219

  Common ancestors

  Denisova mtDNA data, 229

  Denisovans and Neanderthals, 243–244, 247–248

  fossil data, 95

  humans and chimpanzees, 169–171, 182

  humans and great apes, 93(fig.),

  94

  Mitochondrial Eve, 13(fig.), 14–15, 88

  modern humans and Neanderthals, 72–73, 78, 91

  separation of humans and chimpanzees, 169–171

  sloths, 66–67

  using the chimpanzee as reference for Neanderthal genome mapping, 155–156

  Wilson’s research, 41

  Comrie, Bernard, 83–84

  Consensus nucleotide, 10

  Conservation genetics, 56

  Contamination

  as obstacle to Neanderthal genome mapping, 155–156

  bacterial cloning versus 454 process, 150–151

  clean room procedures, 52–57, 87–88, 87(fig.)

  collecting El Sidrón bones, 137

  Denisova Cave remains, 230–231, 239

  importance of eliminating, 15–17, 50–51

  inconsistencies with human reference genome, 124–127

  isolating experiments and samples, 52–56

  isolating nuclear DNA in cave bears and mammoths, 112–113

  mapping the Neanderthal genome, 156–158

  mechanisms of, 64–65

  multiregional theory, 95–97

  mummy samples, 51–52

  Contamination (continued)

  Native American remains, 44, 67–68

  nuclear DNA extraction from mammoths, 101

  nuclear genome of the Neanderthal, 160

  Oetzi, the Ice Man, 69–71

  PCR process, 8–12

  putative dinosaur DNA, 59–60

  sex chromosome data, 179–181

  Convergent evolution, 45, 64–66

  Coop, Graham, 124, 155

  Copper Age remains, 68–71

  Coprolites. See Animal droppings, DNA in

  Creationism, 221

  Criteria of authenticity, 51–52

  Croatian Academy of Sciences and Arts, 77, 130, 132–135, 138, 139(fig.), 179

  Dabney, Jesse, 147(fig.)

  Darwin, Charles, 63

  Das Altertum journal, 32

  David, Charles, 47, 50

  Deamination (of nucleotides), 7,

  154

  Denisova Cave remains

  comparing Denisova and modern genomes, 244–245

  comparing Denisova and Neanderthal genomes, 233, 243–244

  comparing Neanderthal mtDNA sequences with Denisova sequences, 228–231

  publishing the findings, 235–236, 245–249

  sequencing the nuclear genome, 238–242

  tooth, 235, 236(fig.)

  Derevianko, Anatoly, 227–228, 228(fig.), 231–233, 235, 238–239, 242(fig.), 244, 250

  Derived allele, 156–158, 176, 181,

  243

  Diamond, Jared, 43

  Dinosaur, DNA extraction from, 58–60, 111

  DNA amplification. See Amplification of DNA

  DNA extraction

  cannibalized remains, 132

  Denisovan girl, 251

  Egyptian mummies, 27–32

>   improving efficiency, 143–151

  initial studies of ancient materials, 26–27

  silica extraction method, 55

  Solexa technique, 161

  Vindija bone samples, 139–141

  See also Polymerase chain reaction

  DNA sequencing

  chimpanzee genome, 4

  Denisova Cave remains, 236–237

  determining human origins, 41–43

  humans and apes, 94

  information derived from, 25

  initial results, 1

  kangaroo rats, 42–43

  mapping convergent evolution, 66

  Neanderthal genome mapping project, 118, 122–123

  preserved Native American skeletons, 43–44

  pyrosequencing, 107–108, 111–115

  Sanger method, 107–108, 110

  technical intricacies of DNA retrieval, 45–46

  Egg cells, 19–20

  Egholm, Michael, 111, 114, 118–119, 122–124, 146, 149, 160–161, 163

  Egyptology, 23–25

  El Sidrón, Spain, 136–137

  Elephants, nuclear DNA extraction from, 101–103

  Enard, Wolfgang, 253

  Endangered species, 56

  Enhancers, 38

  Errors in mapping, 154

  Eskimo remains, 215

  Ethical concerns, 252–253

  European Bioinformatics Institute, Cambridge, England, 218

  European Molecular Biology Organization, 135

  Europeans, modern

  Africans’ exchanges with, 187–188

  comparing Neanderthal data with modern genome, 181

  determining Neanderthals’ contribution to the modern genome, 171–173

  genetic variation, 92–93

  human reference genome and present-day human genome, 185–188

  mapping gene flow, 192–195

  mapping modern genomes, 188

  mapping the Neanderthal genome, 155

  MHC gene variability, 224

  mtDNA comparisons with ancient DNA, 12

  multiregional model of human origins, 20–21

  Neanderthal mtDNA in, 96–97

  out-of-Africa model of human origins, 19

  reaction to Neanderthal DNA findings, 222–223

  replacement crowd, 199

  SNPs as indication of interbreeding, 173–177

  studying modern and ancient Egyptians, 25–26

  See also Africans, modern; Asians, modern; Modern humans

  Evans, Tom, 148

  Evolutionary anthropology, 83–84

 

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