Black gram (Vigna mungo) is an important short duration grain legume crop. Black gram seeds provide an inexpensive source of dietary protein. Here, we applied the 10X Genomics linked‐read technology to obtain a de novo whole genome assembly of V. mungo cultivated variety Chai Nat 80 (CN80). The preliminary assembly contained 12,228 contigs and had an N50 length of 5.2 Mb. Subsequent scaffolding using the long‐range Chicago and HiC techniques yielded the first high‐quality, chromosome‐level assembly of 499 Mb comprising 11 pseudomolecules. Comparative genomics analyses based on sequence information from single‐copy orthologous genes revealed that black gram and mungbean (Vigna radiata) diverged about 2.7 million years ago . The transversion rate (4DTv) analysis in V. mungo revealed no evidence supporting a recent genome‐wide duplication event observed in the tetraploid créole bean (Vigna reflexo‐pilosa). The proportion of repetitive elements in the black gram genome is slightly lower than the numbers reported for related Vigna species. The majority of long terminal repeat retrotransposons appeared to integrate into the genome within the last five million years. We also examined alternative splicing events in V. mungo using full‐length transcript sequences. While intron retention was the most prevalent mode of alternative splicing in several plant species, alternative 3' acceptor site selection represented the majority of events in black gram. Our high‐quality genome assembly along with the genomic variation information from the germplasm provides valuable resources for accelerating the development of elite varieties through marker‐assisted breeding and for future comparative genomics and phylogenetic studies in legume species.
Mangrove forest ecosystems support a diverse flora and fauna of marine and terrestrial species and have important direct and indirect economic, ecological and social values to mankind. Yellow mangrove (Bruguiera parviflora) belongs to the Rhizophoraceae family and is widely distributed in the intertidal zones along sheltered coastal areas in tropical latitudes. Here, we present a high‐quality, chromosome‐level assembly of the B. parviflora genome. We employed the 10x Genomics linked‐read technology to obtain a preliminary assembly, which was subsequently scaffolded using the long‐range chromatin contact mapping technique (HiC) to obtain a final assembly containing 213,026,782 bases in 10,045 scaffolds with an N50 length of 10,906,948 bases. Our gene prediction recovered 96.5% of the highly conserved orthologues in the Embryophyta lineage based on the Benchmarking Universal Single‐Copy Orthologues (BUSCO) analysis. We analysed the transversion rate at fourfold‐degenerate sites from orthologous gene pairs and discovered evidence supporting a recent whole‐genome duplication event in B. parviflora and other Rhizophoreae members. Comparative studies based on single‐copy orthologous genes indicated that B. parviflora and Bruguiera gymnorrhiza diverged approximately 24.1 million years ago. The population structure analysis revealed that 63 B. parviflora accessions from different geographical regions in Thailand were an admixture of two subpopulations. The examination of alternative splicing events in B. parviflora showed that the most prevalent splicing mechanism was intron retention. This high‐quality genome assembly together with the genetic diversity information obtained from the germplasm provide useful genomic resources for future studies on comparative phylogenetics and evolution of adaptive traits in mangrove species.
Luffa spp. (sponge gourd or ridge gourd) is an economically important vegetable crop widely cultivated in China, India and Southeast Asia. Here, we employed PacBio long‐read single‐molecule real‐time (SMRT) sequencing to perform de novo genome assemblies of two commonly cultivated Luffa species, L. acutangula and L. cylindrica. We obtained preliminary draft genomes of 734.6 Mb and 689.8 Mb with scaffold N50 of 786,130 and 578,616 bases for L. acutangula and L. cylindrica, respectively. We also applied long‐range Chicago and HiC techniques to obtain the first chromosome‐scale whole‐genome assembly of L. acutangula. The final assembly contained 13 pseudomolecules, corresponding to the haploid chromosome number in Luffa spp. (1n = 13, 2n = 26). The sizes of the assembled Luffa genomes are approximately twice as large as the genome assemblies of related Cucurbitaceae. A large proportion of L. acutangula (62.17%; 456.69 Mb) and L. cylindrica (56.78%; 391.65 Mb) genome assemblies contained repetitive elements. Phylogenetic analyses revealed that the substantial accumulation of transposable elements likely contributed to the expansion of the Luffa genomes. We also investigated alternative splicing events in Luffa using full‐length transcript sequences obtained from PacBio Isoform Sequencing (Iso‐seq). While the predominant form of alternative splicing in most plant species examined was intron retention, alternative 3’ acceptor site selection appeared to be a major event observed in Luffa. High‐quality genome assemblies for L. acutangula and L. cylindrica reported here provide valuable resources for Luffa breeding and future genetics and comparative genomics studies in Cucurbitaceae.
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