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The relatively young and repeated evolutionary origins of dioecy (separate sexes) in flowering plants enable investigation of molecular dynamics occurring at the earliest stages of sex chromosome evolution. With two independently young origins of dioecy in the genus,Asparagusis a model taxon for studying genetic sex-determination and sex chromosome evolution. Dioecy first evolved inAsparagus~3-4 million years ago (Ma) in the ancestor of a now widespread Eurasian clade that includes garden asparagus (Asparagus officinalis), while the second origin occurred in a smaller, geographically restricted, Mediterranean Basin clade includingAsparagus horridus. The XY sex chromosomes and sex-determination genes in garden asparagus have been well characterized, but the genetics underlying dioecy in the Mediterranean Basin clade are unknown. We generated new haplotype-resolved reference genomes for garden asparagus andA. horridus, to elucidate the sex chromosomes ofA. horridusand explore how dioecy evolved between these two closely related lineages. Analysis of theA. horridusgenome revealed an independently evolved XY system derived from different ancestral autosomes (chromosome 3) with different sex-determining genes than documented for garden asparagus (on chromosome 1). We estimate that proto-XY chromosomes evolved around 1-2 Ma in the Mediterranean Basin clade, following an ~2.1-megabase inversion between the ancestral pair. Recombination suppression and LTR retrotransposon accumulation drove the establishment and expansion of the Y-linked sex-determination region (Y-SDR) that now reaches ~9.6-megabases inA. horridus. The new garden asparagus genome revealed a Y-SDR that spans ~1.9-megabases with ten hemizygous genes. Our results evoke hemizygosity as the most probable mechanism responsible for the origin of proto-XY recombination suppression in the Eurasian clade, and that neofunctionalization of one duplicated gene (SOFF) drove the origin of dioecy. These findings support previous inference based on phylogeographic analysis revealing two recent origins of dioecy inAsparagus. Moreover, this work implicates alternative molecular mechanisms for two separate shifts to dioecy in a model taxon important for investigating young sex chromosome evolution. 

Abstract PremiseTarget sequence capture (Hyb‐Seq) is a cost‐effective sequencing strategy that employs RNA probes to enrich for specific genomic sequences. By targeting conserved low‐copy orthologs, Hyb‐Seq enables efficient phylogenomic investigations. Here, we present Asparagaceae1726—a Hyb‐Seq probe set targeting 1726 low‐copy nuclear genes for phylogenomics in the angiosperm family Asparagaceae—which will aid the often‐challenging delineation and resolution of evolutionary relationships within Asparagaceae. MethodsHere we describe and validate the Asparagaceae1726 probe set (https://github.com/bentzpc/Asparagaceae1726) in six of the seven subfamilies of Asparagaceae. We perform phylogenomic analyses with these 1726 loci and evaluate how inclusion of paralogs and bycatch plastome sequences can enhance phylogenomic inference with target‐enriched data sets. ResultsWe recovered at least 82% of target orthologs from all sampled taxa, and phylogenomic analyses resulted in strong support for all subfamilial relationships. Additionally, topology and branch support were congruent between analyses with and without inclusion of target paralogs, suggesting that paralogs had limited effect on phylogenomic inference. DiscussionAsparagaceae1726 is effective across the family and enables the generation of robust data sets for phylogenomics of any Asparagaceae taxon. Asparagaceae1726 establishes a standardized set of loci for phylogenomic analysis in Asparagaceae, which we hope will be widely used for extensible and reproducible investigations of diversification in the family. 

Genomic characterization of Cannabis sativa has accelerated rapidly in the last decade as sequencing costs have decreased and public and private interest in the species has increased. Here, we present seven new chromosome-level haplotype-phased genomes of C. sativa. All of these genotypes were alive at the time of publication, and several have numerous years of associated phenotype data. We performed a k-mer-based pangenome analysis to contextualize these assemblies within over 200 existing assemblies. This allowed us to identify unique haplotypes and genomic diversity among Cannabis sativa genotypes. We leveraged linkage maps constructed from F2 progeny of two of the assembled genotypes to characterize the recombination rate across the genome showing strong periphery-biased recombination. Lastly, we re-aligned a bulk segregant analysis dataset for the major-effect flowering locus Early1 to several of the new assemblies to evaluate the impact of reference bias on the mapping results and narrow the locus to a smaller region of the chromosome. These new assemblies, combined with the continued propagation of the genotypes, will contribute to the growing body of genomic resources for C. sativa to accelerate future research efforts. 

Abstract Cannabis sativais a globally important seed oil, fibre and drug-producing plant species. However, a century of prohibition has severely restricted development of breeding and germplasm resources, leaving potential hemp-based nutritional and fibre applications unrealized. Here we present a cannabis pangenome, constructed with 181 new and 12 previously released genomes from a total of 144 biological samples including both male (XY) and female (XX) plants. We identified widespread regions of the cannabis pangenome that are surprisingly diverse for a single species, with high levels of genetic and structural variation, and propose a novel population structure and hybridization history. Across the ancient heteromorphic X and Y sex chromosomes, we observed a variable boundary at the sex-determining and pseudoautosomal regions as well as genes that exhibit male-biased expression, including genes encoding several key flowering regulators. Conversely, the cannabinoid synthase genes, which are responsible for producing cannabidiol acid and delta-9-tetrahydrocannabinolic acid, contained very low levels of diversity, despite being embedded within a variable region with multiple pseudogenized paralogues, structural variation and distinct transposable element arrangements. Additionally, we identified variants of acyl-lipid thioesterase genes that were associated with fatty acid chain length variation and the production of the rare cannabinoids, tetrahydrocannabivarin and cannabidivarin. We conclude that theC. sativagene pool remains only partially characterized, the existence of wild relatives in Asia is likely and its potential as a crop species remains largely unrealized. 

Abstract PremiseDioecy (separate sexes) has independently evolved numerous times across the angiosperm phylogeny and is recently derived in many lineages. However, our understanding is limited regarding the evolutionary mechanisms that drive the origins of dioecy in plants. The recent and repeated evolution of dioecy across angiosperms offers an opportunity to make strong inferences about the ecological, developmental, and molecular factors influencing the evolution of dioecy, and thus sex chromosomes. The genusAsparagus(Asparagaceae) is an emerging model taxon for studying dioecy and sex chromosome evolution, yet estimates for the age and origin of dioecy in the genus are lacking. MethodsWe use plastome sequences and fossil time calibrations in phylogenetic analyses to investigate the age and origin of dioecy in the genusAsparagus. We also review the diversity of sexual systems present across the genus to address contradicting reports in the literature. ResultsWe estimate that dioecy evolved once or twice approximately 2.78−3.78 million years ago inAsparagus, of which roughly 27% of the species are dioecious and the remaining are hermaphroditic with monoclinous flowers. ConclusionsOur findings support previous work implicating a young age and the possibility of two origins of dioecy inAsparagus, which appear to be associated with rapid radiations and range expansion out of Africa. Lastly, we speculate that paleoclimatic oscillations throughout northern Africa may have helped set the stage for the origin(s) of dioecy inAsparagusapproximately 2.78−3.78 million years ago.