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<p>Contributors ix</p> <p><b>1 Antoine: Slave, Creole Gardener, and Expert Grafter of Pecan Trees 1<br /> </b><i>Lenny Wells</i></p> <p>I. Background 2</p> <p>II. Work and Recognition of ‘Centennial’ Pecan 3</p> <p>III. Significance 5</p> <p>Literature Cited 8</p> <p><b>2 Hazelnut Breeding 9<br /> </b><i>Shawn A. Mehlenbacher and Thomas J. Molnar</i></p> <p>I. Introduction 13</p> <p>II. Economic Importance, Producing Countries, and Markets 14</p> <p>III. Taxonomy of the Genus Corylus 15</p> <p>IV. Genetic Resource Collection, Characterization and Preservation 23</p> <p>V. Major Limitations, Needs, and Breeding Objectives 35</p> <p>VI. History of Genetic Improvement 36</p> <p>VII. Breeding Programs Since 1960 46</p> <p>VIII. Floral Biology and Breeding Procedures 54</p> <p>IX. Breeding for Specific Traits 81</p> <p>X. Clonal Selection 110</p> <p>XI. Rootstock Improvement 111</p> <p>XII. Interspecific Hybridization 114</p> <p>XIII. Molecular Markers, Genome Sequences, Transcriptome Sequences and Genetic Engineering 119</p> <p>XIV. Conclusions and Prospects 125</p> <p>Literature Cited 127</p> <p><b>3 Rewiring Network Plasticity to Improve Crops 143<br /> </b><i>Madara Hetti-Arachchilage, Ghana Shyam Challa, and</i><i>Amy Marshall-Colón</i></p> <p>I. Crop Ideotype Design Using Gene Networks 145</p> <p>II. Leveraging Network Plasticity to Improve Crops 149</p> <p>III. Multiscale Modeling to Scale Up Gene Network Predictions 167</p> <p>IV. Concluding Remarks and Future Directions 170</p> <p>Literature Cited 171</p> <p><b>4 Accelerating Crop Domestication in the Era of Gene Editing 185<br /></b><i>Angel Del Valle-Echevarria, Nathan Fumia, Michael A. Gore, and Michael Kantar</i></p> <p>I. Introduction 187</p> <p>II. Molecular Biology in Domesticating and Improving Novel Crops 189</p> <p>III. Bringing in Genes from the Wild into Domesticated Crops 196</p> <p>IV. Going into the Unknown: Can We Redomesticate in a More Specific Way to Create Better Crops? 199</p> <p>V. Do Crop Models Offer Opportunities for Assisting in <i>De Novo </i>Domestication of Wild Species? 200</p> <p>VI. Can We Revive Lost Domesticates and How Would We Breed These? 201</p> <p>VII. Can Machine Learning Be Used to Detect Domestication Loci? 202</p> <p>VIII. Conclusion and Future Directions 203</p> <p>Literature Cited 204</p> <p><b>5 Regional and Global Inter-Connectivity Among Common Bean Breeding Programs 213<br /> </b><i>Matthew W. Blair, Asrat Asfaw, Daniel Ambachew, and</i><i>Paul Kimani</i></p> <p>I. Who Makes Bean Varieties? Breeding at Various Scales 214</p> <p>II. Institutional Context of Bean Breeding 215</p> <p>III. Agenda Setting 235</p> <p>IV. Projects <i>Versus </i>Networks 238</p> <p>V. New Concept of Genotype × Environment × Institution (G × E × I) 241</p> <p>VI. Context-Mechanism-Outcome Framework 245</p> <p>VII. Conclusion and Future Prospects 248</p> <p>Literature Cited 250</p> <p><b>6 The Plant Sciences Symposia Series: A Model for Private Sector Support for Graduate Education 255<br /> </b><i>Jason T. Rauscher and Tabare Abadie</i></p> <p>I. Introduction 256</p> <p>II. Background and History 257</p> <p>III. Objectives and Impact 258</p> <p>IV. Conclusions 270</p> <p>Literature Cited 271</p> <p><b>7 Ideas in Genomic Selection with the Potential to Transform Plant Molecular Breeding: A Review 273<br /> </b><i>Matthew McGowan, Jiabo Wang, Haixiao Dong, Xiaolei Liu, Yi Jia, Xiangfeng Wang, Hiroyoshi Iwata, Yutao Li,</i><i>Alexander E. Lipka, and Zhiwu Zhang</i></p> <p>I. Introduction 276</p> <p>II. Blup Alphabet 277</p> <p>III. Bayesian Alphabet 282</p> <p>IV. Machine Learning 284</p> <p>V. GWAS-Assisted Genomic Selection 288</p> <p>VI. Hybrid Breeding 292</p> <p>VII. Multiple Traits 295</p> <p>VIII. Long-Term Selection 298</p> <p>IX. Assessment of Prediction Accuracy 301</p> <p>X. GS-Transformed Plant Breeding 304</p> <p>XI. Future Prospects 306</p> <p>Funding 307</p> <p>Literature Cited 307</p> <p><b>8 Genetic Revelations of a New Paradigm of Plant Domestication as a Landscape Level Process 321<br /> </b><i>Robin G. Allaby, Chris J. Stevens, Logan Kistler, and Dorian Q. Fuller</i></p> <p>I. Introduction 322</p> <p>II. A Deep Pleistocene Onset of Selection 323</p> <p>III. Modes and Limits of Selection in Domestication 326</p> <p>IV. The Complex Emergence of Domesticates 333</p> <p>V. Landscape Level Origins: A New Paradigm 335</p> <p>Literature Cited 336</p> <p><b>9 Breeding for Acylsugar-Mediated Control of Insects and Insect-Transmitted Virus in Tomato 345<br /> </b><i>Martha A. Mutschler</i></p> <p>I. Introduction 348</p> <p>II. Potential for Plant-Based Pest Resistance 350</p> <p>III. Work Completed Before the Start of the Acylsugar Breeding Program 353</p> <p>IV. Phase 1: Acylsugar Breeding Program and Supporting Work 355</p> <p>V. Phase 2: Acylsugar Breeding Program and Supporting Work 367</p> <p>VI. Phase 3 Acylsugar Breeding Program and Supporting Work 373</p> <p>VII. Ongoing Work: Breeding Lines to Support Creation of Commercial Tomatoes With Insect/Virus Control 394</p> <p>VIII. Future Directions 398</p> <p>Notes 401</p> <p>Literature Cited 401</p> <p>Cumulative Contributor Index 411</p> <p>Cumulative Subject Index 421</p>

<p>Contents</p> <ol><li>Antoine: Slave, Creole Gardener, and Expert Grafter of Pecan Trees 1 </li> <li>Hazelnut Breeding 9</li> <li>Rewiring Network Plasticity to Improve Crops 143</li> <li>Accelerating Crop Domestication in the Era of Gene Editing 185</li> <li>Regional and Global Inter-Connectivity Among Common Bean Breeding Programs 213</li> <li>The Plant Sciences Symposia Series: A Model for Private Sector Support for Graduate Education 255</li> <li>Ideas in Genomic Selection with the Potential to Transform Plant Molecular Breeding: A Review 273</li> <li>Genetic Revelations of a New Paradigm of Plant Domestication as a Landscape Level Process 321</li> <li>Breeding for Acylsugar-Mediated Control of Insects and Insect-Transmitted Virus in Tomato 345</li> </ol>

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