世界芝麻产业的生产和成就:过去和现状

Q3 Agricultural and Biological Sciences
Gazali B.T.A. Sanni , Vincent Ezin , Ifagbémi Bienvenue Chabi , Antoine Abel Missihoun , Quenum Florent , Zangui Hamissou , Mareme Niang , Adam Ahanchede
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引用次数: 0

摘要

芝麻生产在农业、食品工业和作物多样性方面具有重要意义,因为它营养丰富,有益健康。尽管芝麻具有重要价值,但它仍然是一种 "孤儿作物",很少受到科学界的关注,因此与其他主要油籽作物相比,芝麻产量较低。本综述全面概述了全球范围内芝麻的生产、知识和研究进展现状。本综述广泛使用了粮农组织统计数据库(FAOSTAT)来研究 1961 年至 2021 年的全球趋势。过去 60 年间,全球芝麻产量大幅增长,亚洲和非洲是主要生产国。omics 技术与生物技术干预相结合,彻底改变了我们对芝麻遗传基础的认识,提高了产量,增强了抗逆性,改善了种子质量。高通量测序方法,如 RNA-seq、RAD-seq、SLAF-seq 和 GBS 技术,被用于各种研究、连锁图谱绘制和性状相关标记的鉴定。在芝麻研究中,精细连接图谱以及基因组学、蛋白质组学、转录物组学和代谢组学等多组学研究已被用于基因和 QTL 图谱绘制。报告了与含油量、产量和抗逆性有关的蛋白质和代谢途径。发现了与产量及其成分、干旱、盐分和渗透胁迫耐受性有关的基因和 QTLs。最近还发现了与蒴果破碎和种子破碎有关的候选基因。要想在芝麻方面取得更大成就,必须通过机械化、先进的农业实践和向农民传播知识来提高芝麻生产效率。应特别加强 MAS 和多组学整合。芝麻生产的进步为农民、政府和农业部门的利益相关者提供了一个重要而有前景的机会。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Production and achievements of Sesamum indicum industry in the world: Past and current state

Sesame production is important in agriculture, food industry, and the crop diversity due to its rich nutritional profile and health benefits. Despite its significant value, sesame is still an orphan crop that has received little scientific attention, resulting in low yield compared to other major oilseed crops. This review offers a comprehensive overview of the present state of production, knowledge, and research advancements concerning Sesamum indicum on a global scale. The FAOSTAT database was extensively used to examine the global trends from 1961 to 2021. In the past 60 years, global sesame production has substantially increased, with Asia and Africa being the primary producers. The integration of omics technologies and biotechnological interventions has revolutionized our understanding of the genetic basis of sesame, enhanced productivity, invigorated stress resilience, and improved seed quality. High-throughput sequencing methods such as RNA-seq, RAD-seq, SLAF-seq, and GBS technology are used in various studies, linkage mapping, and identification of trait-associated markers. Fine linkage maps, and multi-omics studies such as genomics, proteomics, transcriptomics, and metabolomics have been employed in sesame research for gene and QTL mapping. Proteins and metabolic pathways related to oil content, yield, and stress tolerance were reported. Genes and QTLs related to yield and its components, drought, salt, and osmotic stress tolerance were discovered. Candidate genes associated with capsule shattering and seed shattering were recently revealed. For more achievement in sesame, it is important to enhance sesame production efficiency through mechanization, advanced agricultural practices, and knowledge dissemination to farmers. MAS and multi-omics integration should be particularly reinforced. The advancements in sesame production present a significant and promising opportunity for farmers, governments, and stakeholders in the agricultural sector.

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来源期刊
Oil Crop Science
Oil Crop Science Food Science, Plant Science, Agronomy and Crop Science
CiteScore
3.40
自引率
0.00%
发文量
20
审稿时长
74 days
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