Scientia Agricultura Sinica ›› 2019, Vol. 52 ›› Issue (22): 4110-4118.doi: 10.3864/j.issn.0578-1752.2019.22.015

• CULTIVATION·PHYSIOLOGY • Previous Articles     Next Articles

Effects of Heterogeneous Salinity Across Rhizosphere on the Growth of Sorghum Seedlings

ZHANG HuaWen1,3,WANG RunFeng1,3,XU MengPing1,3,LIU Bin1,3,CHEN ErYing1,3,HUANG RuiDong2,ZHOU YuFei2,WANG HaiLian1,3()   

  1. 1 Crop Research Institute, Shandong Academy of Agricultural Sciences, Jinan 250100
    2 Agronomy College, Shenyang Agricultural University, Shenyang 110866
    3 Featured Crops Engineering Laboratory of Shandong Province, Jinan 250100
  • Received:2019-06-05 Accepted:2019-08-06 Online:2019-11-16 Published:2019-11-16
  • Contact: HaiLian WANG E-mail:wanghailian11@163.com

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Abstract:

【Objective】Salt content is usually unevenly distributed in saline-alkali lands. Studies on growth and development, and the changes of physiological and biochemical indexes of sorghum seedlings under non-uniform salt stress could provide a theoretical basis for the cultivation of sorghum in saline-alkali land and the efficient exploitation and utilization of saline-alkali lands.【Method】Roots of sorghum were divided into two equal portions by a root-split method and put in uniform and non-uniform NaCl concentration solution, respectively. There were four treatments. No sodium chloride (denoted as 0/0) was the control, 0 and 200 mmol·L -1(denoted as 0/200), 50 mmol·L -1 and 150 mmol·L -1(denoted as 50/150) were non-uniform salinity treatments, and 100 mmol·L -1/100 mmol·L -1 (denoted as 100/100) were uniform salinity treatment. Healthy sorghum seedlings after growing for 14 days in a growth chamber were sampled for the determination of biomass, leaf area, SPAD, root morphology, osmotic regulators content, anti-oxidative enzyme activity, and photosynthetic parameters. 【Result】 Growth of sorghum both in uniform and non-uniform salt stress conditions was severely inhibited, and significant decrease of fresh weight, biomass, leaf area, root morphology, photosynthetic capacity, anti-oxidative enzyme activity and osmotic substance content accumulation was found. Dry weight per plant was increased by 21.19% and 62.71%, fresh weights of seedlings was increased by 35.39% and 86.44%, and leaf area was increased by 13.22% and 88.66%, respectively under 50/150 and 0/200 compared with those under 100/100. Under 50/150 treatment, fresh and dry weights of roots in the 50 mmol·L -1 side were 1.90 and 2.10 times of the 150 mmol·L -1 side. Under 0/200 treatment, fresh and dry weights of roots in 0 mmol·L -1 side were increased by 3.02 and 3.75 times compared with the 200 mmol·L -1 side. Likewise, local root morphology was affected significantly in non-uniform salt treatment. Root length, root volume, root tip number, and root branch number of sorghum seedlings in 50 mmol·L -1 side or 0 mmol·L -1 were significantly increased compared with 150 mmol·L -1 (50/150) or 200 mmol·L -1 (0/200) salt stress side, respectively. Root length, root volume, root tip number, and root branch number of the whole root were significantly increased under 0/200 (P<0.05) compared with the 100/100 treatment. Activities of SOD, CAT, and POD in leaves were significantly higher under non-uniform salt stress (P<0.05). Contents of proline and soluble sugars were significantly increased in leaves with a dramatic reduce in MDA content (P<0.05) under the non-uniform salinity treatments. Compared with seedlings under the 100/100 condition. Photosynthesis of sorghum was significantly enhanced under 0/200 and 50/150 salt stresses, which chiefly was reflected by notably increased photosynthetic rate, stomatal conductance, transpiration rate, and decreased intercellular CO2 concentration (P<0.05). With respect to indexes of fluorescence of photosynthesis, such as ΦPSⅡ, Fv/Fm, and ETR, their values under 50/150 and 0/200 were increased by 5.64% and 19.00%, 9.25% and 18.89%, and 1.93% and 6.89%, respectively. ΦPSⅡ and Fv/Fm under 0/200 were significantly different from those under 100/100 (P<0.05).【Conclusion】Both non-uniform and uniform salt stress treatments caused growth inhibition to sorghum seedlings. However, due to the root compensatory growth of low salt or salt-free side under the non-uniform salt stress condition, whole root morphology, leaf antioxidant enzymes activity, osmotic regulation ability, and photosynthetic capacity were improved in a certain degree. Thus, non-uniform salinity could relieve damages to sorghum seedling initiated by salt stress.

Key words: sorghum bicolor, split root, non-uniform salinity, photosynthesis, fluorescence

Table 1

Effects of split-root salt stress treatments on agronomic traits of sorghum seedlings"

处理Treatment 地上部 Shoot 根部 Root 整株 Whole plant
鲜重
Fresh
weight (g/plant)		 干重
Dry weight (g/plant)		 叶面积
Leaf area (cm2)		 单侧鲜重
Fresh weight of each side (g/plant)		 总鲜重
Total fresh
Weight (g/plant)		 单侧干重
Dry weight of each side(g/plant)		 总干重
Total dry weight (g/plant)		 鲜重
Fresh
weight (g/plant)		 干重
Dry weight (g/plant)
0/0 14.93±0.57a 1.74±0.08a 171.21±6.26a 2.79±0.04b 5.57±0.08a 0.20±0.01b 0.40±0.01a 20.51±0.50a 2.14±0.09a
100/100 6.36±0.20d 0.92±0.03b 67.28±2.59c 1.35±0.06c 2.71±0.13d 0.13±0.01c 0.27±0.01b 9.07±0.32d 1.18±0.02d
50/150-50 7.86±0.03c 1.12±0.09b 76.17±0.59c 2.86±0.02b 4.06±0.11c 0.21±0.01b 0.31±0.02b 12.28±0.06c 1.43±0.09c
50/150-150 1.20±0.03d 0.10±0.01d
0/200-0 12.86±0.23b 1.54±0.02a 126.93±4.55b 3.32±0.07a 4.42±0.08b 0.30±0.01a 0.38±0.02a 16.91±0.34b 1.92±0.03b
0/200-200 1.10±0.02d 0.08±0.00d

Table 2

Effects of split-root salt stress treatments on root growth of sorghum"

处理
Treatment		 根系长度
Root length (mm)		 根系体积
Root volume(mm3)		 根尖数
Tips of root		 分支数
Forks of root
单侧根系
Root of each side		 整根
Whole root		 单侧根系
Root of each side		 整根
Whole root		 单侧根系
Root of each side		 整根
Whole root		 单侧根系
Root of each side		 整根
Whole root
0/0 201.86±4.06bc 403.71±8.11a 1.54±0.06b 3.07±0.12a 6387±122b 12773±244a 34137±1617a 68274±3235a
100/100 173.83±1.75c 347.67±3.50b 0.76±0.05d 1.39±0.19b 4856±70c 9713±140c 12604±1036c 25208±2071c
50/150-50 221.60±15.70b 354.65±3.62b 1.09±0.05c 1.81±0.02b 6093±179b 10238±170c 19179±416b 30098±1052c
50/150-150 133.00±16.80d 0.72±0.03d 4145±197cd 10919±134cd
0/200-0 300.76±5.57a 414.63±2.80a 2.14±0.09a 2.81±0.19a 8811±547a 12005±232b 35453±1860a 44400±1952b
0/200-200 113.87±2.79d 0.67±0.04d 3861±150d 8947±476d

Fig. 1

Effects of split-root salt stress treatments on leaf SPAD values of sorghum Different letters represent significant difference between different treatments at 0.05 level"

Table 3

Effects of split-root salt stress treatments on photosynthetic and chlorophyll fluorescence parameters of sorghum"

处理
Treatment		 净光合速率
Pn (μmol CO2·m-2·s-1)		 气孔导度
Gs (mol·m-2·s-1)		 细胞间隙CO2浓度
Ci (μmol·mol-1)		 蒸腾速率
Tr (mmol·m-2·s-1)		 实际光化学效
ΦPSII		 最大光化学效率
Fv/Fm		 电子传递效率
ETR
0/0 7.83±0.25a 0.046±0.003a 116.40±16.10b 2.05±0.214a 0.780±0.032a 0.820±0.020a 3.225±0.083a
100/100 1.68±0.12d 0.016±0.003c 223.60±28.90a 0.77±0.125c 0.621±0.014b 0.726±0.010c 2.605±0.301b
50/150 4.30±0.16c 0.025±0.001b 122.33±4.74b 1.21±0.023b 0.656±0.012b 0.740±0.003bc 2.846±0.048ab
0/200 5.80±0.03b 0.030±0.001b 84.90±11.90b 1.43±0.071b 0.739±0.007a 0.776±0.004b 3.097±0.044ab

Table 4

Effects of split-root salt stress treatments on anti-oxidative enzyme activities and osmotic regulators of sorghum"

处理
Treatment		 超氧化物歧化酶活性
SOD activity
(U·g-1 FW)		 过氧化物酶活性
POD activity
(U·g-1 FW)		 过氧化氢酶活性
CAT activity
(nmol·min-1·g-1 FW)		 丙二醛含量
MDA contents
(nmol·g-1 FW)		 脯氨酸含量
PRO contents
(μg·g-1 FW)		 可溶性糖含量
SS contents
(mg·g-1 FW)
0/0 147.13±7.23d 2626.7±29.1c 88.58±0.391d 166.09±4.69c 56.72±1.44c 4.23±0.24d
100/100 255.35±9.05c 2804.0±78.4bc 108.48±3.91c 228.60±10.20a 66.34±1.10bc 5.51±0.24c
50/150 327.28±6.00b 2982.7±44.4b 183.06±3.91b 187.83±3.76b 82.88±4.55b 8.04±0.18b
0/200 440.30±12.50a 3460.0±87.2a 266.68±3.12a 174.00±2.56bc 205.40±11.20a 10.62±0.19a
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