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Summary Whole‐genome duplications, widely observed in plant lineages, have significant evolutionary and ecological impacts. Yet, our current understanding of the direct implications of ploidy shifts on short‐ and long‐term plant evolution remains fragmentary, necessitating further investigations across multiple ploidy levels.Chlamydomonas reinhardtiiis a valuable model organism with profound potential to study the impact of ploidy increase on the longer term in a laboratory environment. This is partly due to the ability to increase the ploidy level.We developed a strategy to engineer ploidy inC. reinhardtiiusing noninterfering, antibiotic, selectable markers. This approach allows us to induce higher ploidy levels inC. reinhardtiiand is applicable to field isolates, which expands beyond specific auxotroph laboratory strains and broadens the genetic diversity of parental haploid strains that can be crossed. We implement flow cytometry for precise measurement of the genome size of strains of different ploidy.We demonstrate the creation of diploids, triploids, and tetraploids by engineering North American field isolates, broadening the application of synthetic biology principles inC. reinhardtii. However, our newly formed triploids and tetraploids show signs of rapid aneuploidization.Our study greatly facilitates the application ofC. reinhardtiito study polyploidy, in both fundamental and applied settings. 

Summary Genome merging is a common phenomenon causing a wide range of consequences on phenotype, adaptation, and gene expression, yet its broader implications are not well‐understood. Two consequences of genome merging on gene expression remain particularly poorly understood: dosage effects and evolution of expression.We employedChlamydomonas reinhardtiias a model to investigate the effects of asymmetric genome merging by crossing a diploid with a haploid strain to create a novel triploid line. Five independent clonal lineages derived from this triploid line were evolved for 425 asexual generations in a laboratory natural selection experiment.Utilizing fitness assays, flow cytometry, and RNA‐Seq, we assessed the immediate consequences of genome merging and subsequent evolution. Our findings reveal substantial alterations in genome size, gene expression, protein homeostasis, and cytonuclear stoichiometry. Gene expression exhibited expression‐level dominance and transgressivity (i.e. expression level higher or lower than either parent). Ongoing expression‐level dominance and a pattern of ‘functional dominance’ from the haploid parent was observed.Despite major genomic and nucleo‐cytoplasmic disruptions, enhanced fitness was detected in the triploid strain. By comparing gene expression across generations, our results indicate that proteostasis restoration is a critical component of rapid adaptation following genome merging inChlamydomonas reinhardtiiand possibly other systems. 

Allotetraploid cotton (Gossypium) species represents a model system for the study of plant polyploidy, molecular evolution, and domestication. Here, chromosome-scale genome sequences were obtained and assembled for two recently described wild species of tetraploid cotton,Gossypium ekmanianum[(AD)₆,Ge] andGossypium stephensii[(AD)₇,Gs], and one early form of domesticatedGossypium hirsutum, racepunctatum[(AD)₁,Ghp]. Based on phylogenomic analysis, we provide a dated whole-genome level perspective for the evolution of the tetraploidGossypiumclade and resolved the evolutionary relationships ofGs,Ge, and domesticatedG. hirsutum. We describe genomic structural variation that arose duringGossypiumevolution and describe its correlates—including phenotypic differentiation, genetic isolation, and genetic convergence—that contributed to cotton biodiversity and cotton domestication. Presence/absence variation is prominent in causing cotton genomic structural variations. A presence/absence variation-derived gene encoding a phosphopeptide-binding protein is implicated in increasing fiber length during cotton domestication. The relatively unimprovedGhpoffers the potential for gene discovery related to adaptation to environmental challenges. Expanded gene families enoyl-CoA δ isomerase 3 and RAP2-7 may have contributed to abiotic stress tolerance, possibly by targeting plant hormone-associated biochemical pathways. Our results generate a genomic context for a better understanding of cotton evolution and for agriculture. 

Abstract Coffea arabica, an allotetraploid hybrid ofCoffea eugenioidesandCoffea canephora, is the source of approximately 60% of coffee products worldwide, and its cultivated accessions have undergone several population bottlenecks. We present chromosome-level assemblies of a di-haploidC. arabicaaccession and modern representatives of its diploid progenitors,C. eugenioidesandC. canephora. The three species exhibit largely conserved genome structures between diploid parents and descendant subgenomes, with no obvious global subgenome dominance. We find evidence for a founding polyploidy event 350,000–610,000 years ago, followed by several pre-domestication bottlenecks, resulting in narrow genetic variation. A split between wild accessions and cultivar progenitors occurred ~30.5 thousand years ago, followed by a period of migration between the two populations. Analysis of modern varieties, including lines historically introgressed withC. canephora, highlights their breeding histories and loci that may contribute to pathogen resistance, laying the groundwork for future genomics-based breeding ofC. arabica. 

Abstract Cycads represent one of the most ancient lineages of living seed plants. Identifying genomic features uniquely shared by cycads and other extant seed plants, but not non-seed-producing plants, may shed light on the origin of key innovations, as well as the early diversification of seed plants. Here, we report the 10.5-Gb reference genome ofCycas panzhihuaensis, complemented by the transcriptomes of 339 cycad species. Nuclear and plastid phylogenomic analyses strongly suggest that cycads andGinkgoform a clade sister to all other living gymnosperms, in contrast to mitochondrial data, which place cycads alone in this position. We found evidence for an ancient whole-genome duplication in the common ancestor of extant gymnosperms. TheCycasgenome contains four homologues of thefitDgene family that were likely acquired via horizontal gene transfer from fungi, and these genes confer herbivore resistance in cycads. The male-specific region of the Y chromosome ofC. panzhihuaensiscontains a MADS-box transcription factor expressed exclusively in male cones that is similar to a system reported inGinkgo, suggesting that a sex determination mechanism controlled by MADS-box genes may have originated in the common ancestor of cycads andGinkgo. TheC. panzhihuaensisgenome provides an important new resource of broad utility for biologists.