Life's Greatest Secret

Page 49

by Matthew Cobb

as metaphor 112, 147–9, 159, 203, 298, 300

in molecules other than DNA 275

nongenetic transmission 255

philosophers on the nature of 144, 149, 202–3, 297–303

role in biology 30, 73, 82–7, 119, 299–300

role in biology questioned 142, 144, 149

Shannon’s definition of 78, 82, 144, 147

information flow

central dogma concern 262–3, 265, 306

in enzyme induction 307

protein → DNA disallowed 136, 138, 251–2, 265–6

protein → protein 253

in protein synthesis 168–9, 251

‘Information in Contemporary Science’ colloquium 202, 205

information storage potential of DNA 271–2

information theory

influence on molecular genetics 307

Oak Ridge symposium 142–6, 148–9

Royal Society conference 81

Royaumont colloquium 202–3, 205

Information Theory in Biology symposium 84

Information Theory in Health Physics and Radiobiology Symposium 142–9

Informational Macromolecules symposium, 1962 204–5

Ingram, Vernon 125–8, 132, 165

inheritance

of acquired characteristics 138, 260

fundamental question of 1

insects as crustacea 239

intelligence, genetic effects 305

5th International Congress of Biochemistry, Moscow, 1961 183, 185–8, 190–2

International Human Genome Sequencing Consortium 232–3

intraspecific variation 236

introns

and code universality 226

coinage of the term 222

evolution 222–3

human genome project 232, 238

preventing back translation 301

iso-G and iso-C 278

isochores 296

isotopic labelling 67, 163–4

J

Jackson, David 279

Jacob, François

ideas on genetic regulation 168–71, 256–7

meeting with Crick and Brenner 165–6

meeting with Monod 155

meeting with Szilárd 152

on messenger RNA 178

on natural selection 215

on ‘night science’ 171, 218

and Nirenberg 175, 185–6, 189

Nobel Prize 215

operon model 169–71, 243, 306

PaJaMo studies 155–6, 158, 160, 166, 178

report of Crick’s protein synthesis lecture 130

repressor action on DNA 158–9, 257

at the Royaumont colloquium 203

see also Monod

Jeffreys, Alec 230

Joad, Professor Cyril 83

Johannsen, Wilhelm 3

Johns Hopkins University symposium, ‘The Chemical Basis of Heredity,’ 1956 161–3

Jones, Bill 192

Journal of Molecular Biology 160, 167, 185

Joyce, Gerald 275

Joyce, James 268

Jukes, Thomas 201, 226

‘junk DNA’ 247–9, 299

K

Kalmus, Hans 86–7

κ and Π base pairs 278

Kawaoka, Yoshihiro 280

Kay, Lily 88, 180, 181f, 185n

keratin 84, 94–5, 105

Khorana, Gorind 208–9, 212, 214

Kilburn, Tom 74

Kimura, Mitoo 148

King, Martin Luther 272

King’s College, London 89–90, 92–5, 98–9, 101–8, 165

Kolmogoroff, Andrei 77

Koltsov, Nikolai 6–7, 12, 15, 17

L

lactose, and enzyme induction 152–3, 156, 243

Lamarck, Jean-Baptiste 72, 138, 260–1

Landy, Art 187–8

Lane, Nick 287

Large Hadron Collider 272

Lazarsfeld, Paul 29

Leder, Phil 209

Lederberg, Joshua

correspondence with von Neumann 146

enthusiasm for nucleic acids 58–9, 63

Nobel Prize 51, 215

Quastler’s symposium and 84

rejects Nirenberg 175

views on terminology 87, 161, 244

Lengyel, Peter 190–1, 203

Leopold, Urs 87

leucine, alternative codons 294–5

Levene, Phoebus, tetranucleotide hypothesis 7, 42–3, 51, 54, 62, 90

life, alien forms 275

life, origins of 286–9

Life Itself by Francis Crick 287

Linschitz, Henry 85

Lipmann, Fritz 189

Lockyer, Becky 255

Lu, Timothy 272

LUCA (Last Universal Common Ancestor) 227, 290, 293

Luria, Salvador 8, 34, 65–6, 97, 215

Luzzati, Vittorio 116

Lwoff, André 59–60, 155, 202, 215

Lysenko, Trofim Denisovich 260–1

lysine, genetic code for 190

lysozyme 125

M

M-9 predictor 24

Maas, Werner 157

MacLeod, Colin 38–41

Macy conference 29

‘ the magic twenty’ 117, 179

The Major Transitions in Evolution (book) 299

mammals

base pair frequencies 295

discovery of ‘split genes’ in 221

genomic imprinting 248

origin of the placenta 245

Manchester 9, 26, 74, 162, 289

Mandelbrot, Benoit 203

Manhattan Project see atomic bomb

Manton, Irene 17

Margulis, Lynn 224

Mars, terraforming 279

Martians 268–9

Martin, Bill 287

Martin, Bob 192

‘maternal effects’ 258

mathematics

approaches to the genetic code 115–16, 143, 174–5, 201, 214–15, 301–2

of next-generation sequencing 235

Patterson function 92, 103, 106

readers’ tolerance of equations 73–4

of Schrödinger’s code-script 14

Mathematical problems in the biological sciences symposium 175

Matthaei, Heinrich

Cold Spring Harbor 1966 Symposium 214

collaboration with Nirenberg 173–5, 177–87

competitors 189–91

Crick’s reaction to 193–6

genetic code success 174, 181–2

not awarded the Nobel Prize 215

Maxwell’s Demon (James Clerk Maxwell) 27, 30, 76

May, Lord (Robert May) 281

Maynard Smith, John 299–300

Mazia, Daniel 61–2

McCarty, Maclyn 41, 43, 46–7, 49, 55, 62, 66, 189n

McClintock, Barbara 245

McCulloch, Warren 24, 82, 86, 149

Mead, Margaret 22, 24

meaning and information flow 78–9, 144

meiosis 12

Mello, Craig 283

Mendel, Gregor 2–3, 128

Meselson, Matthew 163–5, 167, 186–8

messages see communication; information theory

messenger molecule, PaJaMo group 156, 165

messenger RNA (mRNA)

cross-species transfer 271

discovery 166–7, 169

function 317

Nirenberg’s work with 178, 180, 184–5, 208

PaJaMo group and 166, 178

potential manipulation 284

pre-mRNA processing to 222

switch of code investigations to 198

untranslated regions 297

use of possible codons 208, 211

metaphors

information as 112, 147–9, 159, 203, 298, 300

risks associated with 313

methionine/start codon 213

methylation of cytosine 256–8

microsomal particles (ribosomes) 134

Mies
cher, Fritz 14–15

Miller, Stanley 286

Mirsky, Alfred E. 41–3, 55–9, 62, 64, 90–1

MIT (Massachusetts Institute of Technology)

Broad Institute CRISPR patents 284

David Baltimore at 251

Elias at 147

Farzadfard and Lu at 272

Phillip Sharp at 223

Shannon at 25, 27

Wiener’s group at 21, 24–5

mitochondria

maternal effects 258

and the origin of eukaryotes 239

mitochondrial DNA 224–5

mitosis 12

‘Models in Biology’ symposium 147

models of DNA

Astbury on 54

early attempts 99–100, 103

triple helix models 99–100, 104, 106

Watson and Crick’s final model 106–7, 107f

molecular biology

coinage of the term 21

Ed Tatum on development of 204

funding and coordination 217, 312

Journal of Molecular Biology 160, 167, 185

Molecular Biology of the Gene, by James Watson 140, 251

molecular geneticists 130, 267

molecular genetics

Benzer’s role in creating 162

changes in the practice of 310

colinearity assumption 213

contribution of Jacob and Monod 170

Darwinian framework 220

influence of cybernetics and information theory 148, 298–9, 307–8

reverse transcriptase role 252

universality assumption 250

validity of the word ‘code’ 301

see also central dogma

Monod, Jacques

Chance and Necessity book 306

on cybernetics 407

‘derepression of repression’ 257

on dogma 137

enzymatic adaptation/induction 152–3

Essays in Enzyme Cybernetics project 159

ideas on genetic regulation 168–71, 220, 226, 243

on negative feedback 153–4

PaJaMo studies 155–6, 158, 160, 166, 178

see also Jacob

Morgan, Thomas Hunt 3–6, 9

Moscow, 5th International Congress of Biochemistry, 1961 183, 185–8, 190–2

mRNA see messenger RNA

Mueller, Howard 51

Muller, Hermann

on Avery’s work 50–1, 56

crystal-growth model 7, 15

inducing mutations with X-rays 5

Nobel Prize 33

reaction to What is life? 18

relationship with Morgan 4–5

viruses as models for genes 8

Mullis, Kary 229–30

multicellular organisms

horizontal gene transfer in 271

information storage 299

mutations

bacterial enzyme induction and 155–6

directed/targetted mutations 39, 45, 56, 283

frequency and inheritance of 13

inducing with X-rays 5–6, 10

point mutations and frame-shifts 223

Schrödinger’s views on 12–13, 18–19

single-gene, effects 127–8

T4 phage work on triple coding 192–3

Mycoplasma mycoides 267–8

Myriad Genetics 234

N

Nagasaki 18, 28–9, 89, 151

Naples, Symposium on Submicroscopical Morphology in Protoplasm 96–7

Napp, Abbot of Brno 1–2

Nasuia deltocephalinicola 237

national differences over genetics as information 81–3

National Institutes of Health group 173, 175, 183, 192, 209

natural selection

and the central dogma 262

effect on genetic information 299–300

non-functional DNA as exempt 262

Nature

book reviews 17, 50

Brenner, Jacob and Crick paper 178+

Brenner, Jacob and Meselson paper 167

Crick et al. on the triplet code 193, 197

Gamow letter 114

Gilbert on automation and computers 310

Gilbert on introns 221–2

human genome project 233

Ingram letter 127–8

letter from Ephrussi et al. 87–8

papers by Wilkins et al. 94

on the reversal of the central dogma 250–1

Watson and Crick letters 109, 111–13

Nature Genetics paper with 440

authors 311

Neanderthals 240–2

Neel, James 126

‘negative entropy’ (negentropy) 12, 18, 75–6, 78, 202

negative feedback in biology

in behaviour 23–5

Cold Spring Harbor symposium on 168

in protein synthesis 151–4, 153–5, 157, 168

pyrimidine biosynthesis 154

repression distinguished from 168

systems biology legacy 306

Wiener on 30, 75–6, 79

see also cybernetics

negative feedback in history 76

neo-Darwinian synthesis 138

Neufeld, Fred 37

neural networks 307

neuronal development 223, 239

Neurospora 10

‘night science’ 171, 218

Nirenberg, Marshall

at Cold Spring Harbor 1963 Symposium 207–8

at Cold Spring Harbor 1966 Symposium 214

collaboration with Matthaei 173–5, 177–80

to Crick on press coverage 197

on Crick’s demonstration of a triplet code 194

Crick’s evaluation of 186–7, 192–5

Lily Kay on 185n

Moscow Congress presentations 186–7

Nobel Prize and evaluation of 215–17, 309, 312

rivalry with Ochoa’s group 191–2, 196–7

at the Royaumont colloquium 203

at the Rutgers symposium 204–5

various rejections 175, 183

work with synthetic RNA fragments 209–12

Nobel Prizes

awards for genetic code work 215; limit on numbers sharing 167n; potential recipients 284; potential recipients overlooked 59, 108, 167n, 215

Nobel Prize in Chemistry

Sidney Altman 288; Christian Anfinsen 264; Paul Berg 279; Thomas Cech 288; Wally Gilbert 228, 279; Kary Mullis 229n, 230; Max Perutz 17; Fred Sanger (twice) 120, 228, 279

Nobel Prize in Chemistry (and later Peace)

Linus Pauling 17

Nobel Prize in Physics

Louis de Broglie 82; Dick Feynman 117

Nobel Prize in Physiology or Medicine

David Baltimore 252; George Beadle 215; Sydney Brenner 215; Macfarlane Burnet 34, 140; Francis Crick 18, 108, 207, 215; Max Delbrück 215; Renato Delbucco 252; Andrew Fire 283; Al Hershey 215; Robert Holley 215; François Jacob 215; Gorind Khorana 215; Joshua Lederberg 51, 215; Fritz Lipmann 189; Salvador Luria 215; André Lwoff 215; Barbara McClintock 245–6; Craig Mello 283; Jacques Monod 157, 215; Thomas Hunt Morgan 5; Hermann Muller 33; Marshall Nirenberg 215; Severo Ochoa 176, 215; Stanley Prusiner 254; Richard Roberts 223; Phillip Sharp 223; Wendell Stanley 64; Ed Tatum 215; Howard Temin 252; Harold Varmus 188; James Watson 18, 108, 207, 215; Maurice Wilkins 18, 108, 207, 215

non-coding DNA 141, 222, 232

non-repetitive code-scripts 15

non-ribosomal peptides 264

nongenetic transmission of information 255

Northrop, John 46, 66

Novick, Aaron 153–4, 168

NRDC (National Research Defense Committee) 20–1, 27

nucleic acids

genes as 47, 52, 91

identification of the transforming principle as 38, 40

possible information transfers with proteins 136

publishing and conferences on 53

supposed uniformity 42

virus use of DNA or
RNA 289

see also DNA; RNA

nucleic acids, synthetic see oligonucleotides; polynucleotides; XNA

nucleic acid bases see bases

nuclein (now DNA) 7, 15

nucleoproteins

defined 317

as imagined material of genes 42–3, 60, 94, 97, 200n

nucleotides

defined 317

sequence variation and specificity 57–8

see also bases

Nyquist, Harry 27

O

Oak Ridge National Laboratory 62, 122, 142, 144, 148–9

Ochoa, Severo

discovery of polynucleotide phosphorylase 176

Informational Macromolecules symposium, 1962 204–5

on mRNA reading direction 212

Nobel Prize 215

openness to a doublet code 201, 205

polynucleotide investigations 190–2, 196–9

rivalry with Nirenberg and Matthaei 189–92, 209

at Royaumont 203–5

at the Rutgers symposium 204–5

Ohno, Susumu 247

olfactory receptor genes 245

oligonucleotides 208–9

On the Human Use of Human Beings, by Norbert Wiener 83, 268

On the nature of gene mutation and gene structure (‘Three-Man Paper’) 6, 13, 17–19

‘one gene, one enzyme hypothesis’ 10–11, 160, 204, 244

‘onion test’ 246–7

operons 169–71, 243, 306, 317

organic sensors 273

Orgel, Leslie 178, 287, 292

origins of life 286–9

Osawa, Syozo 226

Oxford Nanopore Technologies 236

P

Pääbo, Svante 240–1

PaJaMo (Pardee, Jacob and Monod) studies 155–6, 158, 160, 166, 178

palaeogenomics 240–1

pandas, giant 235

panspermia, directed 287

Paramecium 225

Pardee, Arthur 154–6, 168

see also PaJaMo studies

Paris, ‘Biological units endowed with genetic continuity’ meeting 53, 59–61

‘parity thesis’ 303

patenting issues 232, 234, 284

Patterson function 92, 103, 106

Pauling, Linus

at Cerebral Mechanisms in Behavior symposium 80

molecular structure of DNA 104–5, 108

molecular structure of proteins 84–5, 94–5, 97, 100, 105

reaction to Ronwin’s structure 103

reaction to What is life? 17

on sickle-cell anaemia 126

PCR (polymerase chain reaction) 229–30, 276, 317

PCSK9 gene 237

pea aphids 270–1

peas, Mendel’s experiments 2–3

peptides

assembled without DNA involvement 264

as possible early replicating systems 288

personalised medicine 236–7

Perutz, Max

haemoglobin studies 126

hands Watson and Crick MRC report containing Franklin’s data 105, 122

human genome project and 233

joined by Watson 97

‹ Prev Next ›