碱蓬的染色体级基因组序列揭示了盐生植物的耐盐性。

IF 7.6 Q1 GENETICS & HEREDITY
园艺研究(英文) Pub Date : 2023-08-10 eCollection Date: 2023-09-01 DOI:10.1093/hr/uhad161
Yan Cheng, Jin Sun, Mengwei Jiang, Ziqiang Luo, Yu Wang, Yanhui Liu, Weiming Li, Bing Hu, Chunxing Dong, Kangzhuo Ye, Zixian Li, Fang Deng, Lulu Wang, Ling Cao, Shijiang Cao, Chenglang Pan, Ping Zheng, Sheng Wang, Mohammad Aslam, Hong Wang, Yuan Qin
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引用次数: 1

摘要

土壤盐度是全球作物生产和人类可持续发展日益关注的问题。因此,了解作物的耐盐机制和鉴定耐盐基因对于提高作物对盐胁迫的耐受性至关重要。碱蓬是一种很好地适应海水环境的盐生植物,在其细胞内,特别是在其叶片中,具有吸收和保持高盐浓度的独特能力,这表明存在一种独特的耐盐机制。在这项研究中,我们对绿脓杆菌基因组进行了从头测序。基因组大小为1.02Gb(由两组单倍型组成),包含54 761个注释基因,包括等位基因和重复序列。比较基因组分析显示,S.glauca和Beta vulgaris的基因组具有很强的同源性。在S.glauca基因组中,70.56%包含重复序列,其中逆转录元件最丰富。利用S.glauca基因组的等位基因感知组装,我们研究了分析样本中全基因组等位基因的特异性表达。结果表明,启动子序列的多样性可能有助于等位基因特异性表达的一致性。此外,对ABCE基因家族的系统分析揭示了S.glauca花朵形态的形成,表明a类基因的功能障碍是S.glaucia花瓣缺失的原因。基因家族扩增分析表明,与藜科内的糖生物种相比,在蓝花S.glauca和aralocaspica的共扩增基因家族中,与DNA修复、染色体稳定性、DNA去甲基化、阳离子结合和红光/远红光信号通路相关的基因本体论(GO)术语显著丰富。盐处理下的时程转录组分析揭示了白霜藻对耐盐性的详细反应,以及叶片中与DNA修复和染色体稳定性、脂质生物合成过程和类异戊二烯代谢过程相关的过渡上调基因的富集。此外,转录因子的全基因组分析表明FAR1基因家族显著扩增。然而,还需要进一步的研究来确定FAR1基因家族在S.glauca耐盐性中的确切作用。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

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

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

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

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

Soil salinity is a growing concern for global crop production and the sustainable development of humanity. Therefore, it is crucial to comprehend salt tolerance mechanisms and identify salt-tolerance genes to enhance crop tolerance to salt stress. Suaeda glauca, a halophyte species well adapted to the seawater environment, possesses a unique ability to absorb and retain high salt concentrations within its cells, particularly in its leaves, suggesting the presence of a distinct mechanism for salt tolerance. In this study, we performed de novo sequencing of the S. glauca genome. The genome has a size of 1.02 Gb (consisting of two sets of haplotypes) and contains 54 761 annotated genes, including alleles and repeats. Comparative genomic analysis revealed a strong synteny between the genomes of S. glauca and Beta vulgaris. Of the S. glauca genome, 70.56% comprises repeat sequences, with retroelements being the most abundant. Leveraging the allele-aware assembly of the S. glauca genome, we investigated genome-wide allele-specific expression in the analyzed samples. The results indicated that the diversity in promoter sequences might contribute to consistent allele-specific expression. Moreover, a systematic analysis of the ABCE gene families shed light on the formation of S. glauca's flower morphology, suggesting that dysfunction of A-class genes is responsible for the absence of petals in S. glauca. Gene family expansion analysis demonstrated significant enrichment of Gene Ontology (GO) terms associated with DNA repair, chromosome stability, DNA demethylation, cation binding, and red/far-red light signaling pathways in the co-expanded gene families of S. glauca and S. aralocaspica, in comparison with glycophytic species within the chenopodium family. Time-course transcriptome analysis under salt treatments revealed detailed responses of S. glauca to salt tolerance, and the enrichment of the transition-upregulated genes in the leaves associated with DNA repair and chromosome stability, lipid biosynthetic process, and isoprenoid metabolic process. Additionally, genome-wide analysis of transcription factors indicated a significant expansion of FAR1 gene family. However, further investigation is needed to determine the exact role of the FAR1 gene family in salt tolerance in S. glauca.

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