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<p>Preface, ix</p> <p>About the companion website, xi</p> <p><b>Section 1: Groundwork, 1</b></p> <p><b>1 The excitement of developmental biology, 3</b></p> <p>Where the subject came from, 3</p> <p>Impact of developmental biology, 4</p> <p>Future impact, 5</p> <p><b>2 How development works, 7</b></p> <p>Ultrashort summary, 7</p> <p>Gametogenesis, 10</p> <p>Early development, 13</p> <p>Growth and death, 19</p> <p><b>3 Approaches to development: developmental genetics, 25</b></p> <p>Developmental mutants, 25</p> <p>Sex chromosomes, 27</p> <p>Maternal and zygotic, 27</p> <p>Genetic pathways, 28</p> <p>Genetic mosaics, 30</p> <p>Screening for mutants, 31</p> <p>Cloning of genes, 32</p> <p>Gain-and loss-of-function experiments, 32</p> <p>Transgenesis, 32</p> <p>Other gain-of- function techniques, 34</p> <p>Targeted mutagenesis, 34</p> <p>Other loss-of- function systems, 35</p> <p>Gene duplication, 36</p> <p>Limitations of developmental genetics, 37</p> <p><b>4 Approaches to development: experimental embryology and its molecular basis, 39</b></p> <p>Normal development, 39</p> <p>Developmental commitment, 42</p> <p>Criteria for proof, 48</p> <p>Transcription factors, 48</p> <p>Transcription factor families, 50</p> <p>Other controls of gene activity, 51</p> <p>Signaling systems, 51</p> <p>Genetic regulatory networks, 57</p> <p><b>5 Approaches to development: cell and molecular biology techniques, 61</b></p> <p>Microscopy, 61</p> <p>Optical techniques, 61</p> <p>Confocal, multi-photon, and light sheet microscopes, 63</p> <p>Image capture, 63</p> <p>Anatomical and histological methods, 64</p> <p>Microinjection, 66</p> <p>Study of gene expression by molecular biology methods, 67</p> <p>Study of gene expression by in situ methods, 72</p> <p>Reporter genes, 75</p> <p>Cell-labeling methods, 76</p> <p><b>6 Cells into tissues, 81</b></p> <p>Cells in embryos, 81</p> <p>Cytoskeleton, 82</p> <p>Small GTP-binding proteins, 84</p> <p>Extracellular matrix, 84</p> <p>Cell movement, 85</p> <p>Epithelial organization, 86</p> <p>Morphogenetic processes, 88</p> <p><b>Section 2: Major model organisms, 97</b></p> <p><b>7 Major model organisms, 99</b></p> <p>The big six, 99</p> <p>Access and micromanipulation, 101</p> <p>Genetics and genomes, 101</p> <p>Relevance and tempo, 102</p> <p>Other organisms, 102</p> <p><b>8 Xenopus, 107</b></p> <p>Oogenesis, maturation, and fertilization, 108</p> <p>Normal development, 109</p> <p>Fate maps, 114</p> <p>Experimental methods, 115</p> <p>Processes of regional specification, 119</p> <p><b>9 The zebrafish, 135</b></p> <p>Normal development, 135</p> <p>Fate map, 140</p> <p>Genetics, 141</p> <p>Reverse genetic methods, 144</p> <p>Embryological techniques, 145</p> <p>Regional specification, 145</p> <p>Other roles of the zebrafish, 150</p> <p><b>10 The chick, 153</b></p> <p>Normal development, 154</p> <p>Fate map, 158</p> <p>Regional specification of the early embryo, 159</p> <p>Description of organogenesis in the chick, 164</p> <p><b>11 The mouse, 173</b></p> <p>Mammalian fertilization, 173</p> <p>Normal development of the mouse, 177</p> <p>Fate map, 184</p> <p>Regional specification in the mouse embryo, 185</p> <p>Transgenic mice, 190</p> <p>Embryonic stem cells, 192</p> <p>Knockouts and knock-ins, 192</p> <p>Nuclear transplantation and imprinting, 196</p> <p>X-inactivation, 196</p> <p>Teratocarcinoma, 198</p> <p><b>12 Human early development, 203</b></p> <p>Human reproduction, 203</p> <p>Preimplantation development, 205</p> <p>Human embryonic stem cells, 207</p> <p>Human postimplantation development, 208</p> <p>Postimplantation diagnosis: chorionic villus sampling and amniocentesis, 211</p> <p>Ethics of human development, 211</p> <p><b>13 Drosophila, 217</b></p> <p>Insects, 217</p> <p>Normal development, 219</p> <p>Fate map, 222</p> <p>Pole plasm, 224</p> <p>Drosophila developmental genetics, 224</p> <p>The developmental program, 227</p> <p>The dorsoventral pattern, 228</p> <p>The anteroposterior system, 232</p> <p><b>14 Caenorhabditis elegans, 247</b></p> <p>Adult anatomy, 248</p> <p>Embryonic development, 249</p> <p>Regional specification in the embryo, 251</p> <p>Analysis of postembryonic development, 259</p> <p>The germ line, 262</p> <p>Programmed cell death, 264</p> <p><b>Section 3: Organogenesis, 269</b></p> <p><b>15 Techniques for studying organogenesis and postnatal development, 271</b></p> <p>Genetics, 271</p> <p>Clonal analysis, 275</p> <p>Tissue and organ culture, 278</p> <p>Cell analysis and separation, 279</p> <p><b>16 Development of the nervous system, 283</b></p> <p>Overall structure and cell types, 283</p> <p>Regional specification, 286</p> <p>Neurogenesis and gliogenesis, 292</p> <p>The neural crest, 299</p> <p>Development of neuronal connectivity, 303</p> <p><b>17 Development of mesodermal organs, 315</b></p> <p>Somitogenesis, 315</p> <p>Myogenesis, 322</p> <p>The kidney, 323</p> <p>Germ cell and gonadal development, 326</p> <p>Sex determination, 330</p> <p>Limb development, 330</p> <p>Blood and blood vessels, 340</p> <p>The heart, 343</p> <p><b>18 Development of endodermal organs, 355</b></p> <p>Normal development, 355</p> <p>Organization of the gut tube, 356</p> <p>Fate map of the endoderm, 359</p> <p>Experimental analysis of endoderm development, 359</p> <p>The pancreas, 366</p> <p><b>19 Drosophila imaginal discs, 373</b></p> <p>Metamorphosis, 373</p> <p>Genetic study of larval development, 374</p> <p>Disc development, 378</p> <p>Compartments and selector genes, 378</p> <p>Regional patterning of the wing disc, 381</p> <p>Regeneration and transdetermination, 384</p> <p>Morphogen gradients and polarity, 387</p> <p><b>Section 4: Growth, evolution, regeneration, 391</b></p> <p><b>20 Tissue organization and stem cells, 393</b></p> <p>Types of tissue, 393</p> <p>Tissue renewal, 397</p> <p>Stem cells, 401</p> <p>Intestinal epithelium, 403</p> <p>Epidermis, 408</p> <p>Hair follicles, 410</p> <p>Hematopoietic system, 415</p> <p>Mesenchymal stem cells and “transdifferentiation”, 419</p> <p>Spermatogonia, 419</p> <p><b>21 Growth, aging, and cancer, 425</b></p> <p>Growth: control of size and proportion, 425</p> <p>Biochemical pathways of growth control, 426</p> <p>Growth control in insects, 429</p> <p>Growth control in mammals, 431</p> <p>Liver regeneration, 433</p> <p>Growth in stature, 434</p> <p>Aging, 436</p> <p>Cell autonomous processes, 437</p> <p>The insulin pathway and aging, 438</p> <p>Caloric restriction, 438</p> <p>Cancer, 440</p> <p>Classification of tumors and precursor lesions, 440</p> <p>Molecular biology of cancer, 442</p> <p>Cancer stem cells, 443</p> <p>Cancer progression, 444</p> <p>Cancer therapy, 445</p> <p><b>22 Pluripotent stem cells and their applications, 449</b></p> <p>Human embryonic stem cells, 449</p> <p>Induced pluripotent stem cells, 451</p> <p>Somatic cell nuclear transfer, 453</p> <p>Direct reprogramming, 454</p> <p>Applications of human pluripotent stem cells, 455</p> <p>Cell transplantation therapy, 457</p> <p>Cell transplantation therapies using pluripotent stem cells, 459</p> <p>Transplantation therapy for diabetes, 460</p> <p>Retinal pigment epithelium, 462</p> <p>Spinal repair, 463</p> <p>Cardiomyocytes, 463</p> <p>Parkinson’s disease, 463</p> <p>Introduction of new therapies, 465</p> <p><b>23 Evolution and development, 469</b></p> <p>Macroevolution, 470</p> <p>Molecular taxonomy, 471</p> <p>Phylogeny of animals, 472</p> <p>The fossil record, 473</p> <p>The primordial animal, 474</p> <p>Basal animals, 479</p> <p>What really happened in evolution?, 481</p> <p>Segmented body plans and Hox genes, 482</p> <p>Insect wings and legs, 483</p> <p>Atavisms, 483</p> <p>Vertebrate limbs, 485</p> <p><b>24 Regeneration of missing parts, 491</b></p> <p>Types of regeneration, 491</p> <p>Distribution of regenerative capacity, 491</p> <p>Planarian regeneration, 492</p> <p>Insect limb regeneration, 497</p> <p>Vertebrate limb regeneration, 499</p> <p>The process of limb regeneration, 499</p> <p>The source of cells for regeneration, 501</p> <p>Regeneration of regional pattern, 502</p> <p>Regeneration: ancestral or adaptive property?, 508</p> <p>General properties of regeneration, 509</p> <p>Glossary, 513</p> <p>Index, 527</p>

<p><b>Professor Jonathan M.W. Slack </b>is an emeritus professor of the University of Bath, UK, where he was Head of the Department of Biology and Biochemistry; and the University of Minnesota, USA, where he was director of the Stem Cell Institute. He is a member of the European Molecular Biology Organization and a ??Fellow of the Academy of Medical Sciences. He has published numerous research papers on developmental biology as well as five other books, including <i>The Science of Stem Cells</i> (Wiley-Blackwell 2018).</p> <p><b>Professor Leslie Dale </b>is Professor of Developmental Biology at University College London, UK, where he was Head of Teaching for the Department of Cell and Developmental Biology. He teaches developmental biology to both undergarduate and medical students. For his PhD he studied regeneration in Drosophila imaginal discs and subsequently the development of <i>Xenopus</i> embryos.

<p><b>Discover the foundations of developmental biology with this up to date and focused resource from two leading experts</b></p> <p>The newly revised Fourth Edition of <i>Essential Developmental Biology</i> delivers the fundamentals of the developmental biology of animals. Designed as a core text for undergraduate students in their first to fourth years, as well as graduate students in their first year, the book is suited to both biologically based and medically oriented courses. The distinguished authors presume no prior knowledge of development, animal structure, or histology. <p>The new edition incorporates modern single cell transcriptome sequencing and CRISPR/Cas9, as well as other methods for targeted genetic manipulation. The existing material has also been reorganized to provide for easier reading and learning for students. The book avoids discussions of history and experimental priority and emphasizes instead the modern advances in developmental biology. The authors have kept the text short and focused on the areas truly central to developmental biology. Readers will benefit from the inclusion of such topics as: <li>A thorough discussion of the groundwork of developmental biology, including developmental genetics, cell signaling and commitment, and cell and molecular biology techniques</li> <li>An exploration of major model organisms, including Xenopus, the zebrafish, the chick, the mouse, the human, Drosophila, and Caenorhabditis elegans</li> <li>A treatment of organogenesis, including postnatal development, and the development of the nervous system, mesodermal organs, endodermal organs, and imaginal discs in drosophila</li> <li>A final section on growth, stem cell biology, evolution, and regeneration</li></ul> <p>Perfect for undergraduate students, especially those preparing to enter teaching or graduate studies in developmental biology, <i>Essential Developmental Biology</i> will also earn a place in the libraries of those in the pharmaceutical industry expected to be able to evaluate assays based on developmental systems.

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