Chromosome-scale genome sequence of <i>Suaeda glauca</i> sheds light on salt stress tolerance in halophytes

Cheng, Yan; Sun, Jin; Jiang, Mengwei; Luo, Zhihua; Wang, Yu; Liu, Qing; Li, Weiming; Hu, Bing; Dong, Chunxing; Ye, Kangzhuo; Li, Zixian; Deng, Fang; Wang, Lulu; Cao, Ling; Cao, Shijiang; Pan, Chenglang; Zheng, Ping; Wang, Sheng; Aslam, Mohammad; Wang, Yuzhuo; Qin, Yuan

doi:10.1093/hr/uhad161

Cited by 7 publications

(1 citation statement)

References 71 publications

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“…The higher gene counts in C. quinoa and A. palmeri compared to other amaranth species may indicate specific adaptations or complexities in their genetic makeup, possibly contributing to unique physiological traits or environmental adaptations. The high percentage of functionally annotated genes (ranging from 88.05% to 95.28%), which is consistent with earlier studies such as S. aralocaspica (97.2%) [25] and S. glauca (91.80%) [35], is indicative of a comprehensive understanding of the biological roles of these genes. The use of various databases for annotation, such as NCBI-NR, TrEMBL, InterProScan, Swiss-Prot, COG, KEGG, and GO, enhances the robust-ness of the functional annotations, providing a multi-faceted view of the gene functions.…”

Section: Discussionsupporting

confidence: 90%

Genome-Wide Comparative Analysis of Five Amaranthaceae Species Reveals a Large Amount of Repeat Content

Singh,

Maurya,

Rajkumar

et al. 2024

Plants

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Amaranthus is a genus of C4 dicotyledonous herbaceous plant species that are widely distributed in Asia, Africa, Australia, and Europe and are used as grain, vegetables, forages, and ornamental plants. Amaranth species have gained significant attention nowadays as potential sources of nutritious food and industrial products. In this study, we performed a comparative genome analysis of five amaranth species, namely, Amaranthus hypochondriacus, Amaranthus tuberculatus, Amaranthus hybridus, Amaranthus palmeri, and Amaranthus cruentus. The estimated repeat content ranged from 54.49% to 63.26% and was not correlated with the genome sizes. Out of the predicted repeat classes, the majority of repetitive sequences were Long Terminal Repeat (LTR) elements, which account for about 13.91% to 24.89% of all amaranth genomes. Phylogenetic analysis based on 406 single-copy orthologous genes revealed that A. hypochondriacus is most closely linked to A. hybridus and distantly related to A. cruentus. However, dioecious amaranth species, such as A. tuberculatus and A. palmeri, which belong to the subgenera Amaranthus Acnida, have formed their distinct clade. The comparative analysis of genomic data of amaranth species will be useful to identify and characterize agronomically important genes and their mechanisms of action. This will facilitate genomics-based, evolutionary studies, and breeding strategies to design faster, more precise, and predictable crop improvement programs.

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Section: Discussionsupporting

confidence: 90%

Genome-Wide Comparative Analysis of Five Amaranthaceae Species Reveals a Large Amount of Repeat Content

Singh,

Maurya,

Rajkumar

et al. 2024

Plants

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Understanding the salinity resilience and productivity of halophytes in saline environments

Chen,

Wang

2024

Plant Science

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Exploring salt tolerance mechanisms using machine learning for transcriptomic insights: case study in Spartina alterniflora

Huang,

Chen,

et al. 2024

Horticulture Research

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Salt stress poses a significant threat to global cereal crop production, emphasizing the need for a comprehensive understanding of salt tolerance mechanisms. Accurate functional annotations of differentially expressed genes are crucial for gaining insights into the salt tolerance mechanism. The challenge of predicting gene functions in under-studied species, especially when excluding infrequent GO terms, persists. Therefore, we proposed the use of NetGO 3.0, a machine learning-based annotation method that does not rely on homology information between species, to predict the functions of differentially expressed genes under salt stress. Spartina alterniflora, a halophyte with salt glands, exhibits remarkable salt tolerance, making it an excellent candidate for in-depth transcriptomic analysis. However, current research on the S. alterniflora transcriptome under salt stress is limited. In this study, we used S. alterniflora as an example to investigate its transcriptional responses to various salt concentrations, with a focus on understanding its salt tolerance mechanisms. Transcriptomic analysis revealed substantial changes impacting key pathways such as gene transcription, ion transport, and ROS metabolism. Notably, we identified a member of the SWEET gene family in S. alterniflora, SA_12G129900.m1, showing convergent selection with the rice ortholog SWEET15. Additionally, our genome-wide analyses explored alternative splicing responses to salt stress, providing insights into the parallel functions of alternative splicing and transcriptional regulation in enhancing salt tolerance in S. alterniflora. Surprisingly, there was minimal overlap between differentially expressed and differentially spliced genes following salt exposure. This innovative approach, combining transcriptomic analysis with machine learning-based annotation, avoids the reliance on homology information and facilitates the discovery of unknown gene functions, and is applicable across all sequenced species.

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Chromosome-scale genome sequence of Suaeda glauca sheds light on salt stress tolerance in halophytes

Cited by 7 publications

References 71 publications

Genome-Wide Comparative Analysis of Five Amaranthaceae Species Reveals a Large Amount of Repeat Content

Genome-Wide Comparative Analysis of Five Amaranthaceae Species Reveals a Large Amount of Repeat Content

Understanding the salinity resilience and productivity of halophytes in saline environments

Exploring salt tolerance mechanisms using machine learning for transcriptomic insights: case study in Spartina alterniflora

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