Warwate Sunil Indrajit, Awana Monika, Thakare Swapnil S, Krishnan Veda, Kumar Suresh, Bollinedi Haritha, Arora Ajay, Sevanthi Amitha Mithra, Ray Mrinmoy, Praveen Shelly, Singh Archana
Division of Biochemistry, ICAR-Indian Agricultural Research Institute, New Delhi, India.
Division of Genetics, ICAR-Indian Agricultural Research Institute, New Delhi, India.
Front Nutr. 2024 Oct 23;11:1448450. doi: 10.3389/fnut.2024.1448450. eCollection 2024.
Rice is a primary food source almost for more than 50% of the total world's population. Glycemic index (GI) is high in most of the rice varieties, limiting their consumption by diabetic and obese people. As a result, developing new rice varieties with low GI necessitates a thorough understanding of starch biogenesis gene expression and its interrelationship.
A total 200 rice genotypes were analyzed for total starch content (TSC), amylopectin content (APC), and amylose content (AC). The clustering of these rice genotypes was done based on their AC. Further, these genotypes were categorized into three groups up to 10% amylose-low, 10-26% amylose-medium, and more than 26% amylose-high. Among them, six genotypes 1 from low AC (NJ-72), 2 from medium AC (UPRI-2003-18, PRR-126), and 3 from high AC (RNRM-7, Urvashi and Ananga) were selected. The genotypes selected from the medium and high AC groups were having 2% amylose variation among themselves respectively and they were further used to study the level of RS, protein content (PC), fatty acid (FA) profiles, and granule morphology along with low group sample.
Resistant starch (RS) content ranged from 0.33-2.75%, and fatty acid profiling revealed high levels of palmitic, linoleic, and oleic acids. The degree of crystallinity and APC% were found to be positively correlated. Ananga, the genotype with the highest RS, displayed compact starch granules. Further, NJ-72 showing low RS and Ananga with high RS were selected for investigation of enzymatic activities of starch biosynthesis, metabolites accumulation, and expressions of 20 starch biogenesis genes in developing endosperm. Starch branching enzymes (SBE) and starch synthase (SS) activities peaked at 13 days after anthesis (DAA), while starch debranching enzymes (DBE) were most active at 18 DAA. In Ananga, TSC, AC, APC, and RS levels progressively increased from 3 to 23 DAA. Ananga showed 1.25-fold upregulation of at 18DAA. Higher expressions of and were observed in NJ-72 at 13DAA. was predominantly expressed followed by . GBSSI was positively correlated with both AC and RS while , and were positively related to APC.
This research could lead to the development of rice varieties with improved nutritional qualities, such as higher RS content, which is beneficial for human health due to its role in lowering glycemic response and promoting gut health. Additionally, the study provides insights into how the modulation of key genes and enzymes can affect starch composition, offering strategies to breed rice varieties tailored for specific dietary needs or industrial applications.
大米几乎是全球超过50%人口的主要食物来源。大多数水稻品种的血糖生成指数(GI)较高,这限制了糖尿病患者和肥胖人群对其的食用。因此,培育低GI的新型水稻品种需要深入了解淀粉生物合成基因的表达及其相互关系。
对总共200个水稻基因型进行了总淀粉含量(TSC)、支链淀粉含量(APC)和直链淀粉含量(AC)的分析。这些水稻基因型根据其AC进行聚类。此外,这些基因型被分为三组,直链淀粉含量低于10%为低直链淀粉组,10%-26%为中直链淀粉组,高于26%为高直链淀粉组。其中,从低AC组中选择了6个基因型中的1个(NJ-72),从中AC组中选择了2个(UPRI-2003-18、PRR-126),从高AC组中选择了3个(RNRM-7、Urvashi和Ananga)。从中AC组和高AC组中选择的基因型彼此之间直链淀粉含量分别有2%的差异,它们与低AC组样本一起进一步用于研究抗性淀粉(RS)水平、蛋白质含量(PC)、脂肪酸(FA)谱以及颗粒形态。
抗性淀粉(RS)含量在0.33%-2.75%之间,脂肪酸谱分析显示棕榈酸、亚油酸和油酸含量较高。发现结晶度和APC%呈正相关。RS含量最高的基因型Ananga显示出紧密的淀粉颗粒。此外,选择RS含量低的NJ-72和RS含量高的Ananga来研究发育中的胚乳中淀粉生物合成的酶活性、代谢物积累以及20个淀粉生物合成基因的表达。淀粉分支酶(SBE)和淀粉合酶(SS)活性在开花后13天(DAA)达到峰值,而淀粉脱支酶(DBE)在18 DAA时活性最高。在Ananga中,TSC、AC、APC和RS水平从3 DAA到23 DAA逐渐增加。Ananga在18 DAA时显示出[具体基因]上调1.25倍。在13 DAA时,NJ-72中观察到[具体基因]和[具体基因]的表达较高。[具体基因]表达占主导,其次是[具体基因]。颗粒结合型淀粉合酶I(GBSSI)与AC和RS均呈正相关,而[具体基因]、[具体基因]和[具体基因]与APC呈正相关。
本研究有助于培育营养品质得到改善的水稻品种,如具有较高RS含量的品种,由于其在降低血糖反应和促进肠道健康方面的作用,对人类健康有益。此外,该研究深入了解了关键基因和酶的调控如何影响淀粉组成,为培育适合特定饮食需求或工业应用的水稻品种提供了策略。
