Epigenetic principles of evolution:
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2012
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| Ausgabe: | 1. ed. |
| Schriftenreihe: | Elsevier insights
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| Online-Zugang: | Inhaltsverzeichnis |
| Beschreibung: | XLII, 804 S. Ill., graph. Darst. |
| ISBN: | 9780124158313 |
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| 264 | 1 | |a Amsterdam [u.a.] |b Elsevier |c 2012 | |
| 300 | |a XLII, 804 S. |b Ill., graph. Darst. | ||
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Datensatz im Suchindex
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| adam_text | Epigenetic Principles of
Evolution
Nelson R Cabej
Department of Biology
University of Tirana
Tirana, Albania
AMSTERDAM • BOSTON • HEIDELBERG • LONDON • NEW YORK • OXFORD
ELSEVIER PARIS • SAN DIEGO • SAN FRANCISCO • SINGAPORE • SYDNEY • TOKYO
Contents
Introduction xix
Part I: Epigenetic Basis of Metazoan Heredity 1
1 Control Systems and Determination of Phenotypic Traits in Metazoans 3
The Thermodynamic Enigma of Living Systems 3
On the Meaning of Biological Information 4
Genetic Versus Epigenetic Information 4
Novel Properties of the Biological Information 5
The Control System in Metazoans and the von Neumann s Machine 6
Central Control of Animal Physiology 9
Neural Control of Water Content 9
Neural Control of Glucose and Insulin Biosynthesis 10
Neural Control of Thermoregulation 12
Central Control of Animal Behavior 16
Neural Control of Locomotion 17
Neural Determination of Monogamy in Prairie Voles 17
Central Control of Metazoan Morphology 18
Control of Expression of Nonhousekeeping Genes 20
Chromatin Remodeling in Control of Gene Expression 21
Extracellular Control of Signal Transduction Pathways and
Transcription Factors 22
Hormonal Control of Secreted Proteins and Growth Factors 23
Neural Control of the Endocrine Function 24
Examples of Central Control of Metazoan Morphology 27
Development of the Mammary Gland 27
Central Determination of Body Mass 28
Central Determination of Normal Obesity 29
The Integrated Control System 31
The Hypothesis of the Epigenetic System of Heredity and its Predictions 32
2 Neural Manipulation of Gene Expression 39
Predetermined Versus Manipulative Expression of Genes 39
Processing of External/Internal Stimuli in the CNS Generates
Information for Adaptive Phenotypic Responses 41
Molecular Mechanisms of Manipu lative Expression of Genes in the CNS 49
Contents
Epigenetic Manipulation of Genetic Information in the CNS 51
Selective Elimination of Genetic Information in the CNS 56
Neural Circuits Generate Epigenetic Information 57
Neural Processing of Stimuli Generates Information for Postphylotypic
Development 61
Processing-Dependent Expression of Genes and the Blood-Brain Barrier 66
Generation of Information for Adaptive Camouflage in Xenopus 66
What Do Neural Circuits Do: Sum Up Stimuli or Figure Out Adaptive
Responses? 69
3 Epigenetic Control of Reproduction 81
Epigenetic Control of Reproductive Physiology and Behavior 81
Neuroendocrine Regulation of the Gonadal Function in Insects 81
Local Neural Control of the Reproductive Function in Insects 84
Neuroendocrine Regulation of Reproductive Function in Vertebrates 84
Local Neural Control of the Reproductive Function in Vertebrates 88
Epigenetic Control of Gametogenesis 89
Neural Control of Oogenesis in Insects and Gastropod Molluscs 89
Neural Control of Oogenesis in Vertebrates 93
Neural Control of Spermato-/Spermiogenesis 94
Neural Control of Deposition of Parental Epigenetic Information
in Gametes 96
Neural Control of Deposition of Maternal Factors in Insect Oocytes 97
Neural Control of the Squeezing of Nurse Cell Content into the Oocyte 98
Other Modes of Neural Control of Deposition of Parental Epigenetic
Information in Vertebrate Eggs 106
Role of the Ovarian Innervation in the Ovarian Function 110
Paternal Cytoplasmic Factors in the Sperm Cell 111
Neural Control of Gene Imprinting 112
4 Epigenetic Control of Early Development 127
Epigenetic Control of Formation of Primordial Germ Cells
and Formation of Zygote 127
Epigenetic Control of Migration of PGCs 128
Epigenetic Control of Early Development in Insects 129
Epigenetic Control of Early Development in Vertebrates 130
Epigenetic Control of Early Development in Mammals 132
Epigenetic Control of Formation of Embryonic Germ Layers 136
Maternal Control of Endoderm Formation 136
Maternal Control of Mesoderm Formation 137
Epigenetic Control of Neural Induction and Formation of the CNS 137
5 Neural Control of Postphylotypic Development 147
Neural Control of Metamorphosis 148
Apoptosis in Invertebrates 148
Contents ix
Neural Control of Metamorphosis in Vertebrates 153
Neural Control of Metamorphosis in Amphibians 153
Postphylotypic Development in Vertebrates 154
The Embryonic CNS Controls the Postphylotypic Development in
Vertebrates—Empirical Evidence 154
Development of the Dermomyotome and Sclerotome 156
Neural Control of the Primary Sex Determination 184
Neural Control of Sex Conversion 186
Osteogenesis 187
Neural Control of the Development of the Mammary Gland 193
Neural Control of the Development of Body Mass 194
Neural Control of the Life Span 198
Neural Control of the Onset of Puberty 198
Neural Control of Apoptosis 201
Neural Control of Regeneration 204
6 The Epigenetic System of Inheritance—An Outline 229
The Epigenetic System of Inheritance 229
Gametogenesis and Provision of Maternal Epigenetic
Information to Oocytes 232
Biphasic CNS Control of Reproduction 238
The Parental CNS-Controlled Phase of Reproduction:
Formation of Bauplan and the CNS 238
The Embryonic CNS-Controlled Phase: The Postphylotypic Development 241
The Binary Neural Control of Gene Expression 243
Novel Features of the Epigenetic System of Inheritance 247
Part II: Neural-Developmental Premises of Evolutionary
Adaptation 255
7 Evolution and Stress Responses to Changes in Environment 257
Evolution of Animal Kingdom Is Related to Changes in Environment 257
Neuroendocrine System 259
Stress and Stressors in Vertebrates 262
Neuroendocrine Response to Stress 263
Environmental Stress as a Cue for Adaptive Developmental Plasticity 267
Environmental Stress Induces Evolutionary Changes
Without Changes in Genes 268
8 Behavioral Adaptation to Changed Conditions of Living 275
Adaptation to Changed Conditions of Living 275
Neural Basis of Animal Behavior 275
Neural Basis of Learned Behavior 282
Animal Behavior Is Not Determined by Genes 286
Learned Behaviors Evolve into Innate Behaviors 290
x Contents
Behavioral Atavisms—Activation of Ancestral Behavioral Circuitries 294
Developmental and Evolutionary Relationship Between Behavior and
Morphology 297
9 Ontogeny: The Workshop of Evolutionary Change 307
Ontogeny and the Phylotypic Stage—Why Do All
Developmental Pathways Converge to the Common Bauplan? 309
Ontogeny May Change Without Changes in Genes 312
Generation of Epigenetic Information for Organogenesis
After the Phylotypic Stage 315
Stress-Induced Developmental Instability and Evolution 319
Developmental Constraints and Adaptive Evolutionary Innovations 321
10 Intragenerational Developmental Plasticity 327
Developmental Plasticity: Beyond the Reaction Norm 327
Developmental Plasticity and Possible Evolutionary Implications 331
Adaptive Intragenerational Developmental Plasticity 332
Camouflage (Adaptive Coloration, Cryptic Coloration, and Crypsis) 332
Polyphenisms in Invertebrates 338
Polyphenisms in Vertebrates 350
Predator-Induced Defenses 355
Inborn Developmental Plasticity 357
Developmental Polymorphisms Are Not Genetic Polymorphisms 357
Part III: Epigenetics of Circumevolutionary
Phenomena and the Mechanism of the
Evolutionary Change 367
11 Transgenerational Developmental Plasticity—An
Epitome of Evolutionary Change 369
TDP—Inherited Changes Without Changes in Genes 370
TDP in Nature 370
Phase Transition in Locusts 374
TDP in Experiments 379
Reconstructing the Chain of Events in Transgenerational Plasticity 383
The Mechanism of Induction of Sexually Reproducing
Generation in D magna 383
Insect Diapause 385
A Neurotransmitter Coding for a Life History Character 386
The Mechanism of Transgenerational Phase Transition in Locusts 387
The Origin of the Information for TDP 393
12 Evolution of Metazoans and Their Control System 405
Principles of Organization of the Multicellular Structure 405
Unicellular Antecedents of Metazoan Life 407
Contents
Unicellular Premises of Coordination of Cell Activity in Metazoans 408
Unicellular Precursors of the Metazoan Epigenetic Informational Structure 411
Impulse Conduction and Sensory-Motor Properties in Protozoans 412
Epigenetic Information in Unicellulars 413
The Origin of Eumetazoan Life 416
Precambrian Metazoans: An Obscure Control System 418
The Diffuse Control System and the Neural Controller:
The Eumetazoan s Eureka 423
Centralization of the Neural Control System 432
Evolution of the Neuroendocrine Control System 435
Neuroendocrine Control System in Invertebrates 435
Evolution of the Neuroendocrine Control in Vertebrates 439
Part IV: Epigenetics of Metazoan Evolution 447
13 Origins of Evolutionary Novelty 449
The Epigenetic Hypothesis of Evolution and its Predictions 449
The Nature of the Evolutionary Change 450
Interactions Organism-Environment in Evolution: The Causal Relationship 452
Behavioral Prelude of Evolutionary Modifications of Animal Morphology 458
Epigenetic Determination of Modifications of Existing Phenotypes 459
Evolution of Body Size in Manduca sexta 461
The Growth Rate 462
Critical Weight 463
PTTH Delay Time 463
Evolution of Wings in Insects 465
Neural Control of Developmental Pathways and Gene
Regulatory Networks of Insect Wings 466
Neo-Darwinian Explanation 470
Epigenetic Explanation 471
Evolution of Caste Developmental Polymorphisms in Insects 472
Neo-Darwinian Explanation of the Caste-Specific Wing
Developmental Polymorphism in P megacephala 479
Epigenetic Explanation of Caste-Specific Wing Developmental
Polymorphism in P megacephala 480
Evolution of the Seasonal Diphenism in the Butterfly Bicyclus anynana 481
Neo-Darwinian Explanation 482
Epigenetic Explanation 482
Evolution of Horns in Beetles 483
Neo-Darwinian Explanation 487
Epigenetic Explanation 488
Evolution of Appendages and Tetrapod Limbs 488
From Fish Fins to Tetrapod Limbs 494
Evolution of Digits 497
Role of the Nervous System in Limb Development 497
Contents
Neo-Darwinian Explanation 502
Epigenetic Explanation 502
Evolution of Wings in Bats 503
Neo-Darwinian Explanation 505
Epigenetic Explanation 505
Evolution of Blood Circulatory System 506
Evolution of Air-Breathing and Surfactant System in Vertebrates 506
Neo-Darwinian Explanation 510
Epigenetic Explanation 510
Evolution of Dentition in Vertebrates 510
Role of the Nervous System in Tooth Development 513
Neo-Darwinian Explanation 516
Epigenetic Explanation 517
Sudden Evolution of Morphology in the Threespine
Stickleback, Gasterosteus aculeatus 518
Evolution of the Auditory System 519
Evolution of Ears and Ultrasonic Echolocation in Insects 520
Evolution of Ears in Vertebrates 522
Neo-Darwinian Explanation 524
Epigenetic Explanation 524
Evolution of Eyes 524
Evolution of Feathers 525
Molecular Mechanism of Feather Development 525
Successive Stages in Evolution of Feathers 528
Neo-Darwinian Explanation 528
Epigenetic Explanation 528
Evolution of Sexual Dichromatism in Birds 529
Neo-Darwinian Explanation 529
Epigenetic Explanation 532
Evolution of Life Histories 535
Evolution of Sexual Reproduction and Alternation of
Asexual and Sexual Modes of Reproduction 535
Neo-Darwinian Explanation 538
Epigenetic Explanation 539
Evolution of Paedomorphosis in a Salamander Species 540
Evolution of Viviparity 542
Neo-Darwinian Explanation 547
Epigenetic Explanation 549
Evolution of Behavioral Characters in Insects 550
Evolution of Flight in Insects 550
Evolution of Avoidance Behavior in the Green Tree- and
Red-Bellied Snakes 553
Neo-Darwinian Explanation 554
Epigenetic Explanation 554
Evolution of a New Ovulation Character in House Finches 555
Contents xiii
Evolution of the Circadian System in Blind Moles 555
Neural Mechanisms of Metazoan Migration 556
Light-Dependent Magnetic Orientation 556
Trigeminal System of Geomagnetic Orientation 558
Experimental Induction and Evolution of New Characters 560
Rapid Evolution of Physiological Characters in Drosophila 560
Neo-Darwinian Explanation 560
Epigenetic Explanation 560
Evolution of Life History Characters in D melanogaster 561
14 Evolution by Loss 579
Vestigialization of Metazoan Structures 579
Vestigialization of Limbs in Squamates 580
Simplification of the Brain and Morphology in Plethodontid
Salamanders 581
Loss of Animal Structures in Nature 581
Loss of Wings in Insects 582
Loss of Wings in Phasmids 582
Loss of the Gasbladder in Fish 583
Loss of Teeth in Birds 583
Loss of Tetrapod Limbs 585
Loss of Limbs in Amphibians and Reptiles 585
Loss/Reduction of Limbs in Aquatic Mammals 588
Loss of Lungs in Salamanders 595
Loss of Eyes in the Mole Rat Spalax ehrenbergi 596
Loss of Characters in Cave-Dwelling Animals 596
Loss of Eyes in Astyanax fasciatus (mexicanus): Epigenetics of an
Evolutionary Event 598
Loss of Pigmentation in the Cavefish A mexicanus 607
Loss of the Male Conspicuous Coloration in Lizards 609
Loss of Sexual Dichromatism in Birds 609
Loss of Stages in Complex Life Cycles in Insects 610
Loss of Adult Stage of Development—Paedomorphosis in Insects 610
Loss of Terrestrial Mature Stage in Amphibians—Paedomorphosis 611
Neo-Darwinian Explanation 614
Epigenetic Explanation 614
Loss of Physiological Characters in Drosophila melanogaster 615
Loss of Resistance to Environmental Stressors in D melanogaster 615
Loss of Behaviors 615
Loss of the Acoustic Startle Response in Moths
Endemic to Bat-Free Habitats 615
15 Evolution by Reverting to Ancestral Characters 623
Evolutionary Reversions: The Course of Evolution Is Not Unidirectional 623
Atavisms: Ancestral Developmental Pathways May Be Conserved and
Reactivated 627
xiv Contents
Neo-Darwinian Explanation of Atavisms 629
Epigenetic Explanation of Atavisms 629
Evolutionary Reversions in Nature 629
Reversion of Shell Coiling in Gastropods 629
Reversion of Cartilaginous Skeleton in Fish 630
Reversion of the Hydrodynamic Body Shape in Marine Mammals 631
Reversion of Wings in Stick Insects 632
Reversion of Mandible in a Collembolan Insect 633
Reversion of Eyes in Ostracods 633
Reversion of Limbs in Snakes 633
Reappearance of Musculus IFE in the Bowerbird Loria loriae
and the New Zealand Thrush, Turnagra capensis 633
Reversion of an Ancestral Digit in Guinea Pigs 634
Evolutionary Reversion of Life Histories 634
Evolutionary Reversions in Experiments 634
Experimental Reversion of Teeth in Birds 634
Neo-Darwinian Explanation 636
Epigenetic Explanation 636
Reversion of Ancestral Genetic Systems in Insects 636
Reversion of Life History Characters 637
Reversion of Ancestral Modes of Development in Gastropods 637
Reversion of Direct and Biphasic Development in
Plethodontid Salamanders 637
Neo-Darwinian Explanation 638
Epigenetic Explanation 638
Reversion of Ancestral Reproductive Modes in Vertebrates 638
Reversion to Ancestral Oviparity in Sharks and Rays 640
Reversion of Viviparity in Reptiles 640
Re-Evolution of Oviparity in Bovides 641
Reversion of Arboreal Carabides to the Ground-Dwelling Habitat 641
Experimental Reversion of Ancestral Characters 642
Experimental Reversion of Ancestral Characters in Drosophila 642
Neo-Darwinian Explanation 642
Epigenetic Explanation 643
Experimental Reversion of Hip Glands in Voles 644
Neo-Darwinian Explanation 645
Epigenetic Explanation 645
Reversion of Sexuality in Parthenogenetic Lizards 645
Modified Ancestral Structures Reappear Stepwise 646
16 Neural Crest-Determined Evolutionary Novelties 651
Neural Crest-Determined Evolution in Vertebrates 651
Origin of the Neural Crest 652
Development of the Neural Crest 654
Migration of Neural Crest Cells to Target Sites 656
Contents xv
The Source of Epigenetic Information of Neural Crest Cells 657
Neural Crest and Vertebrate Morphogenesis 658
Neural Crest-Determined Evolutionary Novelties in Vertebrates 662
The Vertebrate Head 662
Evolution of the Vertebrate Jaw 664
Paleontological Evidence of the Evolution of the Middle Ear Ossicles 666
Ontogeny of the Middle Ear Ossicles 667
Neural Crest in Evolution of Dentition in Vertebrates 670
An Evolutionary Event in Darwin s Finches 670
The Role of the Neural Crest in Beak Development 671
Evolution of the Adult Pigment Patterns in Danio Fish 679
Evolution of the Cardiac Tract Outflow 680
Evolution of the Forebrain Vasculature 681
Neural Crest-Determined Development of Feathers in Bird s Head 681
17 Evolutionary Convergences: The Trend Toward
Sameness in Metazoan Evolution 687
Predictability in Metazoan Evolution: Evolutionary Sameness 687
Evolutionary Convergences in the Animal Kingdom 688
Convergent Evolution of Eyes 689
Convergence of Electrical Organs and Electroreception in Fish 689
Evolutionary Convergences of the Nervous System 691
Convergence of Cerebellum-Like Structures 693
Convergence of Ear Asymmetry in Owls 693
Convergence of the Ballistic Tongue 693
Convergence of Plumage Patterns in Orioles 696
Convergence of the Tribosphenic Molar Teeth 697
Multifaceted Convergence in Tunas and Lamnid Sharks 698
Convergence to a Common Mode of Reproduction in Frogs 698
Convergence of Overall Body Form in Aquatic
Mammals and the Reptilian Ichthyosaurus 698
Convergence of Placental Mammals and Australian Marsupials 701
Paleontological Evidence for Convergence 701
Neo-Darwinian Explanation of Convergent Evolution 703
Epigenetic Explanation of Evolutionary Convergences 703
18 Species and Allopatric Speciation 707
The Concept of Species 707
The Neo-Darwinian Theory and the Problem of Speciation 709
Speciation Modes According to the Spatial Occurrence 712
Allopatric Speciation 712
Verification of Allopatric Models of Speciation 714
The Basic Allopatric Model 714
The Reinforcement Model 716
Divergence-with-Gene-Flow Model 718
xvi Contents
Peripatric Speciation 718
The Founder Effect Model 719
The Bottleneck Model 720
Ecological Speciation 720
19 Epigenetics of Sympatric Speciation—Speciation as a
Mechanism of Evolution 725
Recognition of the Reality of Sympatric Speciation 725
Sympatric Speciation: No Changes in Genes Are Involved 726
Natural Selection and Sexual Selection in Sympatric Speciation 729
Neurocognitive Populational Breakup 731
Reproductive Isolation via Mate Choice 732
Evolution of Mating Preferences 733
Fisher s Runaway Hypothesis 734
The Good Gene Hypothesis 734
Sensory Exploitation Hypothesis 736
Neurocognitive Mechanisms of Sympatric Reproductive Isolation 737
Evolution of Receiver Biases 737
Evolution of Sender s Signaling 742
Mate Recognition System 745
Neurocognitive Mechanism of Reproductive Isolation 751
Visual-Cognitive Mechanism of Reproductive Isolation 751
Neural Reception of Visual Signaling 751
Neural Reception and Processing of Bioluminescent Signals 752
Olfactory-Cognitive Mechanism of Reproductive Isolation 755
Neural Reception and Processing of Olfactory Signals 755
Olfactorily Determined Reproductive Isolation in Sympatry 757
Auditory-Cognitive Reproductive Isolation 759
Neural Reception and Processing of Acoustic Signals 759
The Song Circuit in the Brain of Birds 761
Acoustically Determined Reproductive Isolation in Sympatry 762
Electrocognitive Mechanism of Reproductive Isolation 766
Electrogenesis in Fish 766
The Structure of the System of Electroreception in Fish 767
Electrosensory Communication in Social and Reproductive Behavior 769
Evolution of Electrosignals, Electrocognitive Isolation of
Populations, and Sympatric Speciation in Fish 774
Neo-Darwinian Explanation of Sympatric Reproductive Isolation and
Speciation of Brienomyrus spp 776
Epigenetic Explanation of Sympatric Reproductive
Isolation and Speciation of Brienomyrus spp 776
Brain, Behavior, and Evolution 777
Behavioral Drive or Brain Size-Environmental Change Hypothesis 778
Neo-Darwinian Explanation of the Correlation Between the
Brain Size and Evolutionary Rates 779
Contents
Epigenetic Explanation of the Correlation Between the
Brain Size and Evolutionary Rates 780
Neurocognitive Sympatric Speciation 781
Neurocognitive Basis of Sympatric Speciation 782
Neurocognitive Sympatric Speciation in Nature 783
Neurocognitive Sympatric Speciation in Insects 783
Neo-Darwinian Explanation of Sympatric Speciation by
Host Plant Shifting 787
Epigenetic Explanation of Sympatric Speciation by Host
Plant Shifting 788
Neurocognitive Sympatric Speciation in Fish 790
Neurocognitive Sympatric Speciation in Salamanders 792
Neurocognitive Sympatric Speciation in Birds 793
Despeciation or Fusion of Species 793
|
| any_adam_object | 1 |
| author | Çabej, Nelson R. ca. 20./21. Jh |
| author_GND | (DE-588)1023628295 |
| author_facet | Çabej, Nelson R. ca. 20./21. Jh |
| author_role | aut |
| author_sort | Çabej, Nelson R. ca. 20./21. Jh |
| author_variant | n r ç nr nrç |
| building | Verbundindex |
| bvnumber | BV039628280 |
| classification_rvk | WG 1900 WH 2600 |
| classification_tum | BIO 180f |
| ctrlnum | (OCoLC)760126575 (DE-599)BVBBV039628280 |
| discipline | Biologie |
| edition | 1. ed. |
| format | Book |
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| id | DE-604.BV039628280 |
| illustrated | Illustrated |
| indexdate | 2024-07-10T00:07:46Z |
| institution | BVB |
| isbn | 9780124158313 |
| language | English |
| oai_aleph_id | oai:aleph.bib-bvb.de:BVB01-024478492 |
| oclc_num | 760126575 |
| open_access_boolean | |
| owner | DE-355 DE-BY-UBR DE-M49 DE-BY-TUM DE-11 DE-19 DE-BY-UBM |
| owner_facet | DE-355 DE-BY-UBR DE-M49 DE-BY-TUM DE-11 DE-19 DE-BY-UBM |
| physical | XLII, 804 S. Ill., graph. Darst. |
| publishDate | 2012 |
| publishDateSearch | 2012 |
| publishDateSort | 2012 |
| publisher | Elsevier |
| record_format | marc |
| series2 | Elsevier insights |
| spelling | Çabej, Nelson R. ca. 20./21. Jh. Verfasser (DE-588)1023628295 aut Epigenetic principles of evolution Nelson R. Cabej 1. ed. Amsterdam [u.a.] Elsevier 2012 XLII, 804 S. Ill., graph. Darst. txt rdacontent n rdamedia nc rdacarrier Elsevier insights Evolution (DE-588)4071050-6 gnd rswk-swf Epigenetik (DE-588)7566079-9 gnd rswk-swf Evolution (DE-588)4071050-6 s Epigenetik (DE-588)7566079-9 s b DE-604 HEBIS Datenaustausch application/pdf http://bvbr.bib-bvb.de:8991/F?func=service&doc_library=BVB01&local_base=BVB01&doc_number=024478492&sequence=000002&line_number=0001&func_code=DB_RECORDS&service_type=MEDIA Inhaltsverzeichnis |
| spellingShingle | Çabej, Nelson R. ca. 20./21. Jh Epigenetic principles of evolution Evolution (DE-588)4071050-6 gnd Epigenetik (DE-588)7566079-9 gnd |
| subject_GND | (DE-588)4071050-6 (DE-588)7566079-9 |
| title | Epigenetic principles of evolution |
| title_auth | Epigenetic principles of evolution |
| title_exact_search | Epigenetic principles of evolution |
| title_full | Epigenetic principles of evolution Nelson R. Cabej |
| title_fullStr | Epigenetic principles of evolution Nelson R. Cabej |
| title_full_unstemmed | Epigenetic principles of evolution Nelson R. Cabej |
| title_short | Epigenetic principles of evolution |
| title_sort | epigenetic principles of evolution |
| topic | Evolution (DE-588)4071050-6 gnd Epigenetik (DE-588)7566079-9 gnd |
| topic_facet | Evolution Epigenetik |
| url | http://bvbr.bib-bvb.de:8991/F?func=service&doc_library=BVB01&local_base=BVB01&doc_number=024478492&sequence=000002&line_number=0001&func_code=DB_RECORDS&service_type=MEDIA |
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