夜间低温对白菜型冬油菜光合机构的影响

doi:10.3864/j.issn.0578-1752.2015.04.05

摘要/Abstract

摘要： 【目的】探讨夜间低温对白菜型冬油菜叶片光合机构的影响机理及品种间差异。【方法】采用人工气候室内模拟夜间低温对白菜型冬油菜幼苗叶片气孔形态、叶绿体超微结构、光合特性及产物分配与积累的影响。【结果】昼/夜温度为20℃/10℃时，与弱抗寒品种天油2号相比，超强抗寒品种陇油7号生长点较低，株型匍匐，叶色深，叶绿素含量、胞间CO₂ 浓度（C_i）、叶片净光合速率（P_n）处于同一显著水平。当夜间温度降至5℃处理7 d后，不同抗寒品种气孔导度（G_s）、C_i、P_n下降，叶绿素含量、根/冠升高，表明低夜温下不同品种均有更多光合产物被优先输送到根部；天油2号叶片叶缘、叶尖呈卷曲状或水渍斑状，表现明显冻害症状，陇油7号叶色加深，叶片平展，生长点下陷，未见冻害；夜温降低处理后白菜型冬油菜叶片叶绿素均升高，不同品种叶绿素升高幅度明显不同，天油2号比对照升高6.0%，陇油7号升高9.6%；此时，天油2号大部分气孔关闭或半关闭，其叶片胞间C_i高于陇油7号，G_S、P_n显著低于陇油7号，表明在夜间温度为5℃时，天油2号光合作用受到显著抑制，非气孔限制是引起其光合效率降低的主要原因；而陇油7号在5℃低夜温条件下，叶片气孔大部分仍保持开放，叶片P_n、C_i虽略有下降，但与对照（昼夜温度为20℃/10℃）处于同一显著水平，在5℃低夜温条件下仍保持较高的光合能力。昼/夜温度为20℃/10℃时，白菜型冬油菜叶绿体紧贴细胞内壁整齐排列，基粒片层垛堞整齐紧密，基质片层整齐有序，叶绿体外形呈梭状或单面凹透镜形，内含淀粉颗粒，陇油7号淀粉粒数量和直径均大于天油2号；当昼/夜温度降为20℃/-5℃时，天油2号下部叶片已全部干枯，持绿叶片叶出现水渍状冻害，陇油7号心叶深绿色，下部叶变黄，但叶片平展，叶面呈块状泛红；天油2号相邻叶绿体融合、叶绿体外膜破裂、释放出內溶物，基粒溶解、基质片层断裂，叶绿体膜有序结构完全损坏；陇油7号叶绿体外膜完整清晰，保持部分基粒结构，基质片层结构较完整，其内仍有少量淀粉粒存在；-5℃低夜温处理后冬油菜不同品种C_i升高，叶绿素含量、G_s、P_n下降；但不同品种叶绿素含量、气体交换参数等存在显著差异，天油2号叶绿素含量显著低于陇油7号，其P_n迅速降低到0.210 μmol CO₂·m^-2·s^-1，比对照下降256.2%，陇油7号P_n为0.434 μmolCO₂·m^-2·s^-1，是天油2号的2.06倍，在-5℃低夜温处理后陇油7号仍有较高的光合速率；陇油7号根/冠显著高于天油2号，表明陇油7号更多光合物质被优先输送到根部保存。【结论】低夜温造成白菜型冬油菜叶绿体光合膜结构损伤，引起叶片P_n降低，昼/夜温度为20℃/5℃时，P_n的下降主要与气孔限制相关，而昼/夜温度为20℃/-5℃时，P_n下降主要由非气孔限制引起。

关键词: 白菜型冬油菜, 低温, 光合特性, 超微结构

Abstract: 【Objective】 The objective of this paper is to investigate the effects of low nocturnal temperature on photosynthetic apparatus of winter rapeseed (Brassica campestris L.) and the associated differences between different cultivars. 【Method】 An artificial climate chamber was used to simulate the effects of low nocturnal temperature on stomatal morphologies, chloroplast ultrastructure, photosynthetic parameters, and dry matter distribution and accumulation in seedling leaves of two winter rapeseed cultivars, Longyou-7 with ultra cold resistance and Tianyou-2 with weak cold resistance. 【Result】 At diurnal/nocturnal temperatures of 20/10℃ (control), the leaves of Louyou-7 had lower growing point than those of Tianyou-2, both showed a creep plant type, a deep green leaf color, and similar levels of leaf chlorophyll content, stomatal conductance (G_s), intercellular CO₂ concentration (C_i), and photosynthetic rate (P_n). After nocturnal temperature drops to 5°C for 7 days, both cultivars had decreased G_s, C_i, and P_n but increased leaf chlorophyll content and root/shoot ratio, indicating that more photosynthetic products were transported with priority to the roots. Tianyou-2 had curved leaf margin and tip with spotty water stains, showed obvious symptoms of cold damage, whereas Longyou-7 had a depended leaf color, a flat leaf shape, and a subsided growing point with no symptoms of cold damage. After treatment at low nocturnal temperature, both cultivars had increased leaf chlorophyll content but the extent of increase differed between Tianyou-2 and Longyou-7 (6.0% vs. 9.6%). During this period, the majority of stomata were closed or semi-closed in Tianyou-2, with higher C_i but lower G_s and P_n than Longyou-7. These observations suggested that at low nocturnal temperature of 5℃, photosynthesis was significantly inhibited in Tianyou-2, mainly because of non-stomatal limitation. On the contrary, most stomata remained open in Longyou-7 at low nocturnal temperature of 5℃, associated with minor decreases in C_i and P_n but no significant differences from data of the control (diurnal/nocturnal temperatures of 20/10℃). These results demonstrated that Longyou-7 maintained relatively high photosynthetic rate at low nocturnal temperature. Regarding chloroplast ultrastructure, the leaves of control plants at diurnal/nocturnal temperatures of 20/10℃ had orderly arranged chloroplasts close to the inner wall of cells, with neat and dense stacks of grana lamellae in an orderly arrangement; the chloroplasts displayed a spindle or single-sided concave shape, containing starch granules which were more and bigger in Longyou-7 than in Tianyou-2. When the diurnal/nocturnal temperatures dropped to 20/-5℃, leaves of Tianyou-2 had the lower part completely dried up and the green-holding leaves with water stains as the symptoms of cold damage, whereas Longyou-7 had interior leaves in a deep green color and the lower part of leaves in a flat shape, with massive red color at the blade surface. With respect to chloroplast ultrastructure, Tianyou-2 had adjacent chloroplasts fused together, with ruptured chloroplast membrane, released inclusions, dissolved grana, and broken stromal lamellae, indicating complete damage of the ordered structure of chloroplast membrane. In contrast, Longyou-7 had chloroplasts retaining complete and clear outer membrane and partial structure of grana, with complete structure of stromal lamellae containing a small amount of starch granules. After treatment at low nocturnal temperature of -5℃, both cultivars had increased C_i and decreased chlorophyll content, G_s and P_n. However, Tianyou-2 had significantly lower chlorophyll content than Longyou-7 and the P_n rapidly declined to 0.210 μmol CO₂·m^-2·s^-1, with 255.2% decrease compared to the control. Longyou-7 had the P_n of 0.434 μmol CO₂·m^-2·s^-1, which was 2.06-fold that of Tianyou-2. These results indicated that Longyou-7 maintained relatively high photosynthetic rate after treatment at low nocturnal temperature. The root/shoot ratio was significantly higher in Longyou-7 than in Tianyou-2, reflecting that the former transported more photosynthetic products with priority to the roots for storage. 【Conclusion】 Low nocturnal temperature caused damage to the structure of photosynthetic membrane of chloroplasts and reduction of P_n in leaves of winter rapeseed, thus influencing photosynthetic processes in this crop. The reduction of P_n was mainly related to stomatal limitation at diurnal/nocturnal temperatures of 20/5℃ and non-stomatal limitation at diurnal/nocturnal temperatures of 20/-5℃.

Key words: winter rapeseed, low temperature, photosynthetic characteristics, chloroplast ultrastructure

刘自刚，孙万仓，方彦，李学才，杨宁宁，武军艳，曾秀存，王月. 夜间低温对白菜型冬油菜光合机构的影响[J]. 中国农业科学, 2015, 48(4): 672-682.

LIU Zi-gang, SUN Wan-cang, FANG Yan, LI Xue-cai, YANG Ning-ning, WU Jun-yan, ZENG Xiu-cun, WANG Yue. Effects of Low Nocturnal Temperature on Photosynthetic Apparatus of Winter Rapeseed (Brassica campestris L.)[J]. Scientia Agricultura Sinica, 2015, 48(4): 672-682.

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