Comparative genomic analysis of underutilized legumes: insights into evolutionary relationships, genome evolution and stress tolerance

Q1 Immunology and Microbiology

Biotechnology Reports Pub Date : 2025-08-21 DOI:10.1016/j.btre.2025.e00918

Omena Bernard Ojuederie , Ufuoma Lydia Akpojotor , Adetomiwa Ayodele Adeniji , Tina Chukwuyem Ojuederie , Jacob Olagbenro Popoola , Olubukola Oluranti Babalola

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引用次数: 0

Abstract

African yam bean, Mung bean, and Winged bean, which are rich sources of nutrients and bioactive compounds, offer significant potential for food and nutrition security, yet they are underutilized. A comparative genomic analysis of these legumes with cowpea was conducted to unearth their molecular architecture and uncover their rich genomic profile. Protein and genomic fasta sequences were retrieved from the GenBank of the NCBI, and orthologous genes investigated, and secondary metabolites determined using OrthoVenn3 and PlantiSMASH programs. A total of 7761 single-copy and 20,250 unique genes were identified, which revealed their genetic diversity and conservation. Phylogenetic analysis showed the closest relationship between Cowpea and Mung bean, with Winged bean diverging significantly. Cowpea and Mung bean had significant gene expansions (+1051), while African yam bean (-864) and Winged bean (-643) had substantial gene losses. GO enrichment revealed the contributions to adaptations in the different legume species to biotic and abiotic stresses, highlighting their potential as climate-resilient crops. The highest protein gene (enzyme) count for saccharide (68) and terpene (18) biosynthesis was obtained in AYB. At the same time, mung bean had the highest gene clusters for alkaloids (10) and polyketides (5), and the highest enzyme count for the biosynthesis of alkaloids (32) and polyketides (17). Underutilized legumes exhibited higher essential amino acid levels compared to cowpea. These findings provide valuable insights for breeding programs and biotechnological interventions to improve the nutritional value and acceptance of these underutilized legumes, ultimately contributing to food and nutrition security.

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未充分利用的豆科植物的比较基因组分析：对进化关系，基因组进化和胁迫耐受性的见解

非洲山药豆、绿豆和翼豆是营养物质和生物活性化合物的丰富来源，为粮食和营养安全提供了巨大潜力，但尚未得到充分利用。对这些豆科植物与豇豆进行了基因组比较分析，揭示了它们的分子结构，揭示了它们丰富的基因组图谱。从NCBI的GenBank中检索蛋白质和基因组fasta序列，研究同源基因，并使用OrthoVenn3和PlantiSMASH程序测定次级代谢物。共鉴定出7761个单拷贝基因和20250个独特基因，揭示了它们的遗传多样性和保守性。系统发育分析表明，豇豆与绿豆亲缘关系最密切，有翼豆有明显的分化。豇豆和绿豆基因扩增显著（+1051），而非洲山药豆（-864）和翼豆（-643）基因缺失显著。氧化石墨烯的富集揭示了不同豆科植物对生物和非生物胁迫的适应性，突出了它们作为气候适应型作物的潜力。糖（68个）和萜烯（18个）生物合成蛋白基因（酶）计数最高。同时，绿豆中生物碱（10个）和聚酮（5个）基因簇数最多，生物碱（32个）和聚酮（17个）生物合成酶数最多。与豇豆相比，未充分利用的豆类显示出更高的必需氨基酸水平。这些发现为育种计划和生物技术干预提供了有价值的见解，以提高这些未充分利用的豆类的营养价值和接受度，最终促进粮食和营养安全。

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来源期刊

Biotechnology Reports Immunology and Microbiology-Applied Microbiology and Biotechnology

CiteScore

15.80

自引率

0.00%

发文量

审稿时长

55 days

期刊介绍： Biotechnology Reports covers all aspects of Biotechnology particularly those reports that are useful and informative and that will be of value to other researchers in related fields. Biotechnology Reports loves ground breaking science, but will also accept good science that can be of use to the biotechnology community. The journal maintains a high quality peer review where submissions are considered on the basis of scientific validity and technical quality. Acceptable paper types are research articles (short or full communications), methods, mini-reviews, and commentaries in the following areas: Healthcare and pharmaceutical biotechnology Agricultural and food biotechnology Environmental biotechnology Molecular biology, cell and tissue engineering and synthetic biology Industrial biotechnology, biofuels and bioenergy Nanobiotechnology Bioinformatics & systems biology New processes and products in biotechnology, bioprocess engineering.