Khalifa Center for Genetic Engineering and Biotechnology, United Arab Emirates University, Al Ain P.O. Box. 15551, United Arab Emirates.
Mitrix Bio., 400 Farmington Ave., Farmington, CT 06032, USA.
Int J Mol Sci. 2022 Jul 31;23(15):8503. doi: 10.3390/ijms23158503.
The mimosoid legumes are a clade of 40 genera in the Caesalpinioideae subfamily of the Fabaceae that grow in tropical and subtropical regions. Unlike the better studied Papilionoideae, there are few genomic resources within this legume group. The tree is native to the Near East and Indian subcontinent, where it thrives in very hot desert environments. To develop a tool to better understand desert plant adaptation mechanisms, we sequenced the genome to near-chromosomal assembly, with a total sequence length of ~691 Mb. We predicted 77,579 gene models (76,554 CDS, 361 rRNAs and 664 tRNAs) from the assembled genome, among them 55,325 (72%) protein-coding genes that were functionally annotated. This genome was found to consist of over 58% repeat sequences, primarily long terminal repeats (LTR-)-retrotransposons. We find an expansion of terpenoid metabolism genes in and its relative , but not in other legumes. We also observed an amplification of NBS-LRR disease-resistance genes correlated with LTR-associated retrotransposition, and identified 410 retrogenes with an active burst of chimeric retrogene creation that approximately occurred at the same time of divergence of from a common lineage with ~23 Mya. These retrogenes include many biotic defense responses and abiotic stress stimulus responses, as well as the early Nodulin 93 gene. Nodulin 93 gene amplification is consistent with an adaptive response of the species to the low nitrogen in arid desert soil. Consistent with these results, our differentially expressed genes show a tissue specific expression of isoprenoid pathways in shoots, but not in roots, as well as important genes involved in abiotic salt stress in both tissues. Overall, the genome sequence of enriches our understanding of the genomic mechanisms of its disease resistance and abiotic stress tolerance. Thus, it is a very important step in crop and legume improvement.
含羞草类豆科是豆科含羞草亚科中的一个约 40 属的分支,生长在热带和亚热带地区。与研究较多的蝶形花科不同,这个豆科群体中几乎没有基因组资源。该树原产于近东和印度次大陆,在那里它在非常炎热的沙漠环境中茁壮成长。为了开发一种更好地了解沙漠植物适应机制的工具,我们对基因组进行了测序,接近染色体组装,总序列长度约为 691Mb。我们从组装的基因组中预测了 77579 个基因模型(76554 个 CDS、361 个 rRNA 和 664 个 tRNA),其中 55325 个(约 72%)蛋白质编码基因具有功能注释。该基因组由超过 58%的重复序列组成,主要是长末端重复(LTR)-逆转录转座子。我们发现 及其相对 的萜类代谢基因扩张,但在其他豆科植物中没有。我们还观察到与 LTR 相关的逆转座相关的 NBS-LRR 抗病基因的扩增,并鉴定了 410 个具有活跃嵌合逆转录基因创建爆发的返座基因,大约发生在与约 23 Mya 的共同谱系分化的同时。这些返座基因包括许多生物防御反应和非生物胁迫刺激反应,以及早期的 Nodulin 93 基因。Nodulin 93 基因的扩增与该物种对干旱沙漠土壤中低氮的适应性反应一致。与这些结果一致,我们的差异表达基因显示出 shoot 中异戊烯途径的组织特异性表达,但在根中没有,以及两个组织中涉及非生物盐胁迫的重要基因。总的来说, 的基因组序列丰富了我们对其抗病性和非生物胁迫耐受性的基因组机制的理解。因此,这是作物和豆科改良的重要一步。
