Scientia Agricultura Sinica ›› 2021, Vol. 54 ›› Issue (14): 3077-3087.doi: 10.3864/j.issn.0578-1752.2021.14.013

• HORTICULTURE • Previous Articles     Next Articles

Effects of Two Microbial Agents on Yield, Quality and Rhizosphere Environment of Autumn Cucumber Cultured in Organic Substrate

WANG JunZheng(),ZHANG Qi,GAO ZiXing,MA XueQiang,QU Feng,HU XiaoHui()   

  1. College of Horticulture, Northwest A&F University/Key Laboratory of Protected Horticultural Engineering in Northwest, Ministry of Agriculture and Rural Affairs, Yangling 712100, Shaanxi
  • Received:2020-08-30 Accepted:2020-11-24 Online:2021-07-16 Published:2021-07-26
  • Contact: XiaoHui HU E-mail:wjz20190915@163.com;hxh1977@163.com

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Abstract:

【Objective】A bag-cultivated experiment was conducted to test the potential of two microbial agents (Bacillus methylotrophicus and Lactobacillus plantarum) on the yield, quality and rhizosphere environment of autumn cucumber using organic substrate as a growth medium. The results of the experiment were helpful to develop the new functional type of microbial agents to guide the high quality and high efficiency production of cucumber. 【Method】Cucumber cultivar ‘Bonai 526’ was sown in a bag of organic substrate. There were a total of six treatments, including CK1 (Irrigation of water and non-application of microbial agents), NT1 (Irrigation of water and application of Bacillus methylotrophicusagents), NT2 (Irrigation of water and application of Lactobacillus plantarumagents), CK2 (Irrigation of nutrient solution and non-application of microbial agents), FT1 (Irrigation of nutrient solution and application ofBacillus methylotrophicusagents), and FT2 (Irrigation of nutrient solution and application of Lactobacillus plantarumagents). The microbial agents (Bacillus methylotrophicus as ‘VL-10’ and Lactobacillus plantarum as ‘LYS-1’) were added to the cucumber rhizosphere at the rate of 2.5×1010 CFU/plant on 20th, 35th and 50th day. 【Result】Compared with CK1 and CK2 treatment,Bacillus methylotrophicus inoculation in both of the nutrient levels increased the dry matter content by 13.51% and 15.02%, and yield by 20.83% and 15.63%, respectively; Lactobacillus plantarum increased the dry matter content by 11.43% and 8.42%, and the yield by 17.42% and 14.96%, respectively. The fruit quality under FT1 treatment was the best; compared with CK2 treatment, its content of free amino acid, organic acid, soluble sugar, reducing sugar and vitamin C were significantly increased by 10.61%, 28.93%, 22.92% and 39.88%, respectively,, followed by FT2 treatment. The accumulation of phosphorus and potassium were significantly higher under both NT1 (7.43% and 10.60%) and NT2 (13.50% and 8.19%) compared with CK1 treatment (P<0.05). Compared with CK2 treatment, the accumulation of nitrogen, and potassium were significantly higher under FT2 (24.18% and 26.25%), while the phosphorus concentration in plants were significantly higher under FT1 (17.16%). Compared with CK2 treatment, the nitrogen, phosphorus and potassium fertilizer utilization rates under FT1 treatment were significantly increased by 82.85%, 483.90% and 75.60% (P<0.05), respectively, which under FT2 treatment was significantly increased by 102.42%, 367.98% and 120.46%, respectively (P<0.05). Compared with CK1 treatment, the treatments NT1 and NT2 improved soil enzymatic activities of sucrase (100.66% and 116.60%), catalase (3.39% and 4.10%) and alkaline phosphatase (6.99% and 95.08%) at the full fruiting stage, among which catalase and alkaline phosphatase activities were still higher at the end of the experiment. Compared with CK2 treatment, the FT1 treatment significantly improved soil enzymatic activities of urease (3.75% and 13.13%), sucrase (68.62% and 31.68%) and alkaline phosphatase (18.00% and 109.64%) in the full fruiting period and the seedling pulling period, while the urease (4.95% and 6.12 %), sucrase (24.93% and 63.35%) and alkaline phosphatase activity (26.99% and 84.01%) under FT2 treatment (P<0.05). The effect ofBacillus methylotrophicagent on the urease and alkaline phosphatase activities were better than that ofLactobacillus plantarumagent. Moreover, the substrate incubated with Bacillus methylotrophic showed significantly higher available nitrogen content (63.33% and 72.70%) (P<0.05) compared with their respective controls at the full fruiting stage, and the increase was 25.48% and 86.46% at the end of the experiment, respectively. 【Conclusion】In conclusion, adding 7.5×1010CFU/plant of Bacillus methylotrophic to the substrate could improve the rhizosphere environment of cucumber and promote the absorption, assimilation and accumulation of essential elements by the plant. Moreover, it could effectively improve the yield and fruit quality of cucumber.

Key words: microbial agents, cucumber, substrate cultivation, yield, fruit quality, rhizosphere environment

Fig. 1

Effects of two microbial agents on cucumber yield cultured in organic substrate ** indicate extremely significant effect, NS indicate no significant effect. Different lowercase letters indicate significant difference (P<0.05), and the letters ‘M’ and ‘F’ represented microbial agents and nutrient solution, respectively. The same as below "

Table 1

Effects of two microbial agents on quality of cucumber cultured in organic substrate"

处理
Treatment 		游离氨基酸
Free amino acids (μg·g-1) 		可溶性蛋白
Soluble protein
(μg·g-1) 		有机酸
Organic acid
(%) 		可溶性糖
Soluble sugar
(%) 		还原糖
Reducing sugar
(%) 		维生素C
Vitamin C
(μg·g-1) 		硝酸盐
Nitrate content
(μg·g-1)
CK1 609.60±6.13f 296.30±5.86c 1.22±0.013d 8.17±0.17d 1.12±0.004c 55.14±0.58d 273.07±4.72d
NT1 700.93±9.03d 349.11±1.08b 1.29±0.017c 9.26±0.34c 1.43±0.068b 55.14±1.01d 338.89±5.16b
NT2 648.57±6.71e 238.72±4.47d 1.42±0.009b 9.12±0.17c 1.37±0.048b 63.88±1.21cd 309.30±5.16c
CK2 745.72±9.07c 373.36±2.81a 1.44±0.013b 9.54±0.23c 1.44±0.080b 73.29±0.58bc 415.58±12.55a
FT1 824.84±7.63a 387.21±4.22a 1.53±0.004a 12.30±0.38a 1.77±0.078a 102.52±5.61a 359.42±5.23b
FT2 800.41±6.48b 302.36±8.98c 1.50±0.015a 10.47±0.41b 1.45±0.033b 79.33±4.62b 360.02±10.16b
方差分析
ANOVA 		营养液 F 489.516** 197.361** 318.604** 61.696** 26.000** 0.244 125.693**
菌剂 M 63.083** 182.428** 33.353** 4.597* 0.153 61.526** 1.797
营养液×菌剂 F×M 1.696 7.256** 44.611** 21.232** 18.003** 25.139** 33.304**

Table 2

Effect of two microbial agents on dry matter accumulation and distribution of cucumber"

处理
Treatment
Root (g/plant)
Stem (g/plant)
Leaf (g/plant)
Fruit (g/plant) 		果实干物质分配系数
Distribution index of fruit (%)
CK1 3.52±0.16b 14.00±0.34d 56.81±2.25b 69.30±0.66e 0.48±0.009c
NT1 4.24±0.08a 16.08±0.14c 57.09±3.78b 85.63±1.24c 0.53±0.013ab
NT2 3.57±0.01b 16.61±0.56bc 58.36±2.27b 81.50±1.26d 0.51±0.013bc
CK2 3.38±0.19b 15.75±0.24c 61.99±0.26b 94.34±0.82b 0.54±0.002ab
FT1 4.41±0.24a 20.43±0.71a 70.95±3.81a 106.03±1.10a 0.53±0.011ab
FT2 3.68±0.10b 17.66±0.39b 62.91±1.57ab 105.99±0.43a 0.56±0.006a
方差分析
ANOVA 		营养液 F 0.151 44.008** 13.372** 874.705** 17.945**
菌剂 M 17.263** 30.714** 1.647 122.633** 2.838
营养液×菌剂 F×M 0.539 7.813** 1.954 3.456 4.494*

Fig. 2

Effects of two microbial agents on the accumulation of nitrogen, phosphorus and potassium of cucumber"

Table 3

Effects of two microbial agents on substrate enzyme activity"

处理
Treatment 		脲酶
Urease activity
(mg·g-1·d-1) 		蔗糖酶
Sucrase activity
(mg·g-1·d-1) 		过氧化氢酶
Catalase activity
(mL·g-1·d-1) 		碱性磷酸酶
Alkaline phosphatase activity (mg·g-1·d-1)
盛果期
Full fruiting stage 		拉秧期
Seedling pulling stage 		盛果期
Full fruiting stage 		拉秧期
Seedling pulling stage 		盛果期
Full fruiting stage 		拉秧期
Seedling pulling stage 		盛果期
Full fruiting stage 		拉秧期
Seedling pulling stage
CK1 6.53±0.02b 6.78±0.09c 136.86±9.37e 103.36±1.90c 1.93±0.139d 2.36±0.012bc 5.46±0.31c 3.86±0.71b
NT1 5.81±0.04c 6.36±0.02d 274.62±9.00b 83.81±5.17d 2.34±0.003b 2.44±0.009ab 6.59±0.30b 7.53±0.44a
NT2 5.85±0.01c 6.66±0.03c 296.44±1.22a 63.53±8.88e 2.48±0.021b 2.54±0.039a 5.83±0.12c 4.13±0.45b
CK2 6.67±0.03b 6.70±0.03c 160.30±0.37d 96.57±0.80cd 2.03±0.168cd 2.23±0.015d 5.89±0.03c 3.94±0.37b
FT1 6.92±0.11a 7.58±0.09a 270.29±5.32b 127.16±8.72b 2.85±0.018a 2.31±0.033cd 6.95±0.28ab 8.62±0.43a
FT2 7.00±0.10a 7.11±0.05b 200.27±9.24c 157.75±1.71a 2.26±0.006bc 2.46±0.059ab 7.48±0.09a 7.25±0.11a
方差分析
ANOVA 		营养液 F 234.482** 127.569** 20.907** 90.592** 0.827 17.273** 2.55 4.972*
菌剂 M 7.104** 8.047** 182.185** 1.811 23.677** 19.534** 16.378** 1.783
营养液×菌剂 F×M 39.428** 63.632** 41.375** 40.529** 9.634** 0.466 13.287** 51.432**

Table 4

Effects of two microbial agents on the content of available nitrogen in substrate"

处理
Treatment 		NH4+-N
(mg·kg-1) 		NO3--N
(mg·kg-1) 		有效态N总量
Total available nitrogen (mg·kg-1)
盛果期 Full fruiting stage 拉秧期Seedling pulling stage 盛果期 Full fruiting stage 拉秧期 Seedling pulling stage 盛果期 Full fruiting stage 拉秧期 Seedling pulling stage
CK1 21.81±0.67d 24.16±0.72b 405.44±5.17e 271.84±2.54f 427.25±5.45e 296.00±3.16f
NT1 75.63±0.69a 20.37±0.23bc 622.19±3.82c 341.12±2.08d 697.81±3.98c 371.41±2.13d
NT2 62.03±2.47b 30.61±2.64a 612.64±18.31c 283.15±4.38e 674.67±20.77c 313.76±5.91e
CK2 15.47±0.51e 30.29±0.37a 514.72±1.64d 389.23±5.04c 530.19±2.14d 409.60±4.94c
FT1 77.39±0.68a 18.67±0.74c 838.24±8.52a 745.07±1.12a 915.63±9.18a 763.73±0.44a
FT2 41.92±0.65c 22.56±0.67b 704.16±7.09b 437.76±3.15b 746.08±7.28b 460.32±3.75b
方差分析
ANOVA 		营养液 F 244.174** 1.517 346.006** 5046.852** 223.717** 3769.324**
菌剂 M 1243.315** 25.307** 467.776** 3411.182** 542.801** 2423.188**
营养液×菌剂 F×M 180.810** 17.469** 27.105** 975.240** 35.165** 714.535**

Fig. 3

Effects of two microbial agents on fertilizer utilization of cucumber"

Table 5

Correlation analysis of rhizosphere environment and fruit quality in fruiting period"

因子
Factor 		游离氨基酸
Free amino acids 		可溶性蛋白
Soluble protein 		有机酸
Organic acid 		可溶性糖
Soluble sugar 		还原糖
Reducing sugar 		维生素C
Vitamin C 		硝酸盐
Nitrate content
脲酶 Urease 0.651** 0.410 0.532* 0.540* 0.312 0.686** 0.408
蔗糖酶 Sucrase 0.166 -0.106 0.296 0.349 0.501* 0.192 -0.053
过氧化氢酶 Catalase 0.426 0.128 0.435 0.652** 0.689** 0.563* -0.003
碱性磷酸酶
Alkaline phosphatase 		0.762** 0.256 0.547* 0.637** 0.467 0.501* 0.320
铵态氮 Ammonium 0.123 0.127 0.094 0.382 0.501* 0.190 -0.150
硝态氮 Nitrate 0.798** 0.315 0.764** 0.879** 0.844** 0.771** 0.340
有效态氮总量
Total available nitrogen 		0.728** 0.301 0.693** 0.845** 0.834** 0.716** 0.276
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