自然衰老棉花种子的生理变化及ATP合成酶亚基mRNA的完整性

doi:10.3864/j.issn.0578-1752.2023.10.001

摘要/Abstract

摘要：

【目的】种子衰老是一个复杂的生物学过程，以自然衰老的棉花种子为材料，研究种子自然储藏后的生理生化变化及种胚ATP合成酶亚基mRNA的完整性，为进一步揭示种子衰老机理提供依据。【方法】以自然储存3年、5年和新收获的新陆早74号棉花种子为试验材料(以新收获的棉种为对照（CK））；分别采用纸间萌发试验、低温恒温干燥法和TTC染色法测定棉花种子的萌发率、吸水力和种子生活力；利用酸碱滴定法测定棉花种子的酸价和呼吸速率，采用植物ATP合成酶酶联免疫分析试剂盒测定种胚ATP合成酶活性，并利用反转录阻断-双引物扩增法分析棉花种胚ATP合成酶α、β、γ、ε和δ亚基mRNA的完整性。【结果】自然储藏会导致种子活力显著降低。与对照相比，自然储存3年和5年后，棉种萌发率由98.7%分别显著降低至84.0%和58.0%（P<0.05）；种子吸胀初期（4 h内）吸水力分别比对照显著降低了11.0%和26.9%（P<0.05）；TTC染色法检测结果显示种子生活力明显下降，其中，储藏5年的种子仅有胚根部位有少量着色，而子叶等器官未被染色；储藏3年和5年的种子酸价分别较对照显著升高了28.4%和40.0%，表明种子内脂肪类物质发生严重水解；吸胀期间种子呼吸速率和ATP合成酶活性表现出增加趋势（P<0.05），但增幅均显著下降；其中，吸胀24 h后呼吸速率增幅分别较对照降低了33.3%和49.2%，吸胀12 h后ATP合成酶活性增幅则分别较对照降低了17.9%和73.4%；反转录阻断-双引物扩增法分析结果显示，ATP合成酶的α亚基、β亚基、γ亚基和δ亚基mRNA的R值均显著低于对照，而ε亚基mRNA的R值则显著高于对照（P<0.05），说明这5种亚基的mRNA在自然储藏过程中出现不同程度的降解。【结论】延长贮藏时间，将导致棉花种子活力下降；种胚中ATP合成酶亚基mRNA完整性丧失，导致ATP合成酶亚基受损，ATP合成酶活性下降，进而造成ATP合成减少，影响种子萌发能力。这可能是棉花种子衰老的重要原因之一。

关键词: 棉花种子, 种子衰老, 种子活力, ATP合成酶, mRNA完整性

Abstract:

【Objective】Seed aging is a complex biological process, previous studies have been used to elucidate the events. However, the mechanism of seed aging is still unclear. The naturally aged cotton seeds were used as experimental materials, and the physiological and biochemical changes as well as the changes in ATP synthase mRNA integrity that occurred in cotton seed during storage were investigated in order to provide a foundation for further illuminating the aging mechanism of cotton seeds.【Method】In this study, a collection of seeds (cultivar Xinluzao 74) that had been stored for 3 and 5 years served as the experimental materials, the newly harvested seeds were used as the control (CK). The germination percentage, water absorption and viability of cotton seeds were valued by germination test between paper, low constant temperature over method, and TTC staining method, respectively; The acid value and respiratory rate of cotton seeds were determined by the acid-base titration method, and the ATP synthase activity was detected with plant ATP synthase ELISA Kit. The mRNA integrity of ATP synthase subunit α, β, γ, ε, and δ in cotton embryo was analyzed by reverse transcription blocking-double primer amplification method.【Result】Our data suggest that seed vigor dramatically decreased over storage time. After 3 and 5 years of storage, the germination percentage of cotton seeds was significantly decreased from 98.7% to 84.0% and 58.0%, respectively (P<0.05). At the initial stage of seed imbibition (the first 4 h), the water absorption rate of seeds was significantly decreased by 11.0% and 26.9%, respectively. The results of TTC staining showed that only the radicle was slightly stained in seeds preserved 5 years but not the cotyledons and other organs stained; The acid value of seeds was significantly increased by 28.4% and 40.0%, respectively (P<0.05), this indicated that severe hydrolysis of lipid occurred in seeds. Seed respiration rate and ATP synthase activity showed an increasing trend during imbibition, but the increasement was significantly decreased (P<0.05); The respiration rate of seeds was reduced by 33.3% and 49.2% after 24 hours of imbibition, and the activity of ATP synthase was decreased by 17.9% and 73.4% after 12 hours of imbibition, respectively. The results of reverse transcription blocking-double primer amplification showed that the R value of ATP synthase subunits α, β, γ, and δ mRNAs stored in seeds were significantly decreased, but the subunit ε mRNA was significantly increased. These results indicated that the integrity of the ATP synthase subunits mRNA decreased to varying degrees during the natural storage process.【Conclusion】These results showed that a prolonged storage time could reduce seed vigor; The integrity loss of ATP synthase subunit mRNAs stored in seed embryos would cause ATP synthase subunit to be impaired and ATP synthase activity declined, thus lead to a decreased production of ATP and affect seed germination capacity. This might be one of the important reasons for cotton seed aging.

Key words: cotton seed, seed senescence, seed vigor, ATP synthase, mRNA integrity

宋词, 谷丰序, 邢真真, 张峻铭, 赫文学, 王天波, 王雨露, 陈军营. 自然衰老棉花种子的生理变化及ATP合成酶亚基mRNA的完整性[J]. 中国农业科学, 2023, 56(10): 1827-1837.

SONG Ci, GU FengXu, XING ZhenZhen, ZHANG JunMing, HE WenXue, WANG TianBo, WANG YuLu, CHEN JunYing. Physiological Changes and Integrity of ATP Synthase Subunits mRNA in Naturally Aged Cotton Seeds[J]. Scientia Agricultura Sinica, 2023, 56(10): 1827-1837.

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ATP合成酶亚基 ATP synthase subunits	基因 Gene	正/反向引物序列 Forward/Reverse primes sequence (5′-3′)	引物长度 Primer length (bp)	退火温度 Annealing temperature (℃)	产物大小 Product size (bp)
α	XM_016819324-5	F：GCACTGGATCTATTGTGG	18	58.9	108
	XM_016819324-5	R：GTTCGTGATCGCTTAGAG	18	59.0	108
	XM_016819324-3	F：AACACGAACTCTATCGGA	18	59.1	105
	XM_016819324-3	R：TGTGCCTTTCTATTAAGCC	19	59.0	105
β	XM_016824591-5	F：AAGATCACTGATGAGTTCAC	20	58.9	199
	XM_016824591-5	R：CATCCATAGCAATGGTCC	18	59.0	199
	XM_016824591-3	F：CGAGCTTAGTGAAGATGATAA	21	59.1	128
	XM_016824591-3	R：TCTCCTTCAACTCCACAT	18	58.9	128
γ	XM_016875018-5	F：TGATACACGAACAACAGC	18	59.1	187
	XM_016875018-5	R：ATATAACGAACTCCAATAGGAC	22	59.0	187
	XM_016875018-3	F：TGTTCGGACTTGTTCATG	18	59.0	136
	XM_016875018-3	R：TACCAACTTATGCTGATGTC	20	59.0	136
ε	XM_016862594-5	F：ACAACACAGCCAAAGAAA	18	59.1	97
	XM_016862594-5	R：GCATATGTTCGAGTAGGTTAT	21	59.1	97
	XM_016862594-3	F：ATGATGTTGCACATCCTAAT	20	59.0	91
	XM_016862594-3	R：ACAAGAATACTTGATAACCCAT	22	59.1	91
δ	XM_016861180-5	F：AACATGGACCCTCCTAAA	18	58.9	88
	XM_016861180-5	R：AATTGACAGTAAGCTTGGAA	20	59.1	88
	XM_016861180-3	F：CTTAAGATTCATATGATGGATGC	23	59.1	198
	XM_016861180-3	R：TTGAACTGCAATAAGAACAAC	21	59.1	198
内参 Internal reference	NM_001155179.1(Actin)-5	F：GTATGAGCAAGGAGATCAC	19	58.9	194
内参 Internal reference	NM_001155179.1(Actin)-3	R：TTAGAAGCACTTCATGTGG	19	59.0	194