热区葡萄高光效育种研究与实践

doi:10.3864/j.issn.0578-1752.2025.10.011

摘要/Abstract

摘要：

【目的】葡萄（Vitis vinifera）在热区具有重要的经济价值，但高温气候对其光合效率、果实产量与品质形成了严峻挑战。与此同时，这种高温环境也为培育兼具高光效与耐热特性的葡萄品种提供了天然筛选条件。深入探究热区高温对葡萄光合效率的影响，分析热区高温条件下开展高光效育种的可行性，并利用光合参数早期筛选高光效、耐热且果实品质优良的杂交后代，为热区葡萄高光效育种提供科学依据与实践支撑。【方法】以‘阳光玫瑰’等187份种质资源及5个杂交组合后代的683株葡萄为试验材料，测定净光合速率（P_n）、气孔导度（G_s）、耐热性（F_v/F_m、PI_abs、ET_o/CS_m和W_K）和果实可溶性固形物（Brix）含量，分析杂交后代的光合效率分布特性与耐热表现，筛选具有高光效和耐热性的优良株系。【结果】高温胁迫显著抑制葡萄光合效率，40 ℃时，净光合速率降幅最高可达30.28%。然而，与在较温和环境下形成的第一茬夏果叶片相比，在高温环境下发育形成的第二茬冬果叶片具有更高的光合效率和光合稳定性，表明热区高温气候条件为挖掘高光效潜力提供了独特环境。杂交后代群体的净光合速率等光合效率指标呈正态分布特性，表明葡萄可通过高光效育种逐代选择，提高整体光合水平。筛选出5个高光效优良株系，其中，21A-7-297的净光合速率（24.88 µmol·m^-2·s^-1）较亲本‘阳光玫瑰’高26.42%，果实Brix达22.03，提高15.34%。耐热性分析表明，21A-7-297和21A-7-145在47 ℃高温胁迫下的最大光化学效率（F_v/F_m）分别为0.61和0.62，显著优于亲本‘瑞都红玉’（0.44），表现出更强的高温适应能力。【结论】揭示了热区高温对葡萄光合效率的影响，并利用光合参数及耐热性指标进行早期筛选，在杂交后代群体中快速获得兼具高光效、耐热性与优良品质的株系，证实了热区葡萄高光效育种的可行性和有效性。未来可在深入解析高光效机制的基础上，进一步优化高光效育种策略。

关键词: 热区葡萄, 高温胁迫, 光合效率, 高光效育种, 耐热性

Abstract:

【Objective】 Grapes (Vitis vinifera) hold significant economic importance in hot climate regions. However, high temperatures pose severe challenges to their photosynthetic efficiency, as well as to fruit yield and quality. At the same time, these extreme conditions provide unique natural selection pressures conducive to breeding grape varieties with both high photosynthetic efficiency and heat tolerance. This study aimed to elucidate the impact of high temperatures in hot regions on grape photosynthetic efficiency, assess the feasibility of breeding for high photosynthetic efficiency under such conditions, and employ photosynthetic parameters for the early selection of hybrid progenies exhibiting high efficiency, heat tolerance, and superior fruit quality. The findings are intended to offer scientific foundations and practical support for high-efficiency grape breeding in hot climates. 【Method】 A total of 187 germplasm resources, including Shine Muscat, and 683 progenies from five hybrid crosses were used as experimental materials. We measured the net photosynthetic rate (P_n), stomatal conductance (G_s), heat tolerance indicators (F_v/F_m, PI_abs, ET_o/CS_m and W_K), and soluble solid content (Brix) of the fruits. These data were analyzed to determine the distribution characteristics of photosynthetic efficiency and to evaluate the heat tolerance of the hybrid progenies. Based on these evaluations, we identified elite lines with both high photosynthetic efficiency and heat tolerance. 【Result】 High temperatures significantly inhibited grape photosynthetic efficiency, with the net photosynthetic rate decreasing by up to 30.28% at 40 ℃. However, compared to the first crops of summer fruit leaves formed in a milder environment, the second crops of winter fruit leaves, developed under high-temperature conditions, exhibited higher photosynthetic efficiency and stability, indicating that high-temperature climates in hot regions provide a unique environment for uncovering high-efficiency potential. The net photosynthetic rate and other photosynthetic efficiency indicators in the hybrid progeny population followed a normal distribution, suggesting that photosynthetic efficiency in grapes can be enhanced through generational selection in high-efficiency breeding. Five excellent hybrid lines with high photosynthetic efficiency were selected, among which the line 21A-7-297 had a net photosynthetic rate of 24.88 µmol·m^-2·s^-1, 26.42% higher than the parent Shine Muscat and a fruit Brix of 22.03, 15.34% higher. Heat tolerance analysis showed that 21A-7-297 and 21A-7-145 maintained maximum photochemical efficiency (F_v/F_m) values of 0.61 and 0.62 under 47 ℃ heat stress, significantly higher than the parent Ruiduhongyu (0.44), demonstrating better heat adaptation. 【Conclusion】 This study revealed the impact of high temperatures in hot regions on grape photosynthetic efficiency and used photosynthetic and heat tolerance parameters for early screening. Hybrid lines with high photosynthetic efficiency, heat tolerance, and good fruit quality were rapidly obtained from the hybrid progeny populations, demonstrating the feasibility and effectiveness of high-efficiency breeding for grapes in hot regions. Future work can further optimize high-efficiency breeding strategies based on an in-depth understanding of the underlying mechanisms of high photosynthetic efficiency.

Key words: grapes in hot climate region, high-temperature stress, photosynthetic efficiency, high photosynthetic efficiency breeding, heat tolerance

曹雄军, 王博, 韩佳宇, 廖永峰, 谢蜀豫, 白扬, 黄小云, 陆丽, 黄秋秘, 江春分, 盘丰平, 白先进. 热区葡萄高光效育种研究与实践[J]. 中国农业科学, 2025, 58(10): 1994-2007.

CAO XiongJun, WANG Bo, HAN JiaYu, LIAO YongFeng, XIE ShuYu, BAI Yang, HUANG XiaoYun, LU Li, HUANG QiuMi, JIANG ChunFen, PAN FengPing, BAI XianJin. Research and Practice on High Photosynthetic Efficiency Breeding of Grapes in Hot Climate Regions[J]. Scientia Agricultura Sinica, 2025, 58(10): 1994-2007.

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序号 No.	亲本组合 Parent combination	杂交后代数量（株） Number of hybrid offspring (plants)	杂交后代编号 Hybrid offspring code
1	阳光玫瑰×瑞都红玉 Shine Muscat×Ruiduhongyu	158	21A-7-n
2	阳光玫瑰×克瑞森 Shine Muscat×Crimson seedless	268	21A-3-n
3	阳光玫瑰×玉波2号 Shine Muscat×Yubo2	81	21A-5-n
4	阳光玫瑰×优系T Shine Muscat× Elite plant T	109	21A-1-n
5	瑞都红玉×克瑞森 Ruiduhongyu×Crimson seedless	67	21A-87-n

品种 Variety	生产季节 Growing season	P_nmax(µmol·m^-2·s^-1)	T_opt (℃)	T_P_n₉₀ (℃)	Δ_{35 ℃}(%)	Δ_{40 ℃}(%)
阳光玫瑰 Shine Muscat	夏果 Summer fruit	19.24±1.21b	26.11±0.48c	16.06-36.24	7.50±0.83b	18.84±0.78b
阳光玫瑰 Shine Muscat	冬果 Winter fruit	26.20±0.95a	27.81±0.51b	20.58-37.54	5.90±0.53c	14.84±1.68b
巨峰 Kyoho	夏果 Summer fruit	12.94±2.25c	27.97±0.68b	20.38-35.10	9.68±0.47a	30.28±4.11a
巨峰 Kyoho	冬果 Winter fruit	19.85±1.86b	29.78±1.15a	19.94-37.76	3.99±1.26d	17.53±2.20b