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Plant growth regulators improve root growth of rice seedlings after mechanical transplanting and increase grain yield

Published online by Cambridge University Press:  08 March 2024

Jichao Tang
Affiliation:
Hubei Collaborative Innovation Center for Grain Industry, Agricultural College, Yangtze University, Jingzhou, Hubei, China
Zhimin Zhang
Affiliation:
Hubei Collaborative Innovation Center for Grain Industry, Agricultural College, Yangtze University, Jingzhou, Hubei, China Tianmen Service Center of Modern Agriculture, Tianmen, Hubei, China
Shahbaz Atta Tung
Affiliation:
Department of Agronomy, Pir Mehr Ali Shah-Arid Agriculture University, Rawalpindi, Pakistan
Bilin Lu*
Affiliation:
Hubei Collaborative Innovation Center for Grain Industry, Agricultural College, Yangtze University, Jingzhou, Hubei, China Engineering Research Center of Ecology and Agricultural Use of Wetland, Ministry of Education, Jingzhou, Hubei, China Hubei Provincial Key Laboratory of Waterlogged Disasters and Agricultural Use of Wetland, Jingzhou, Hubei, China
Wenjia Yang*
Affiliation:
Hubei Collaborative Innovation Center for Grain Industry, Agricultural College, Yangtze University, Jingzhou, Hubei, China Engineering Research Center of Ecology and Agricultural Use of Wetland, Ministry of Education, Jingzhou, Hubei, China Hubei Provincial Key Laboratory of Waterlogged Disasters and Agricultural Use of Wetland, Jingzhou, Hubei, China
*
Corresponding authors: Bilin Lu; Email: [email protected], Wenjia Yang; Email: [email protected]
Corresponding authors: Bilin Lu; Email: [email protected], Wenjia Yang; Email: [email protected]
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Summary

Enhancing seedling quality and promoting root growth post-transplantation are crucial for improving mechanically transplanted rice productivity. Here we investigated the impact of various plant growth regulators on hybrid and conventional rice varieties. Treatments, including two-diethylaminoethyl hexanoate (DA-6, 10 mg L−1), a combination of potassium 3-indole-butyrate + potassium 1-naphthylacetate + 6-benzylaminopurine (C3, 50 + 50 + 10 mg L−1), potassium 3-indole-butyrate + potassium 1-naphthylacetate + 1-triacontanol (C4, 50 + 50 + 50 mg L−1), potassium 3-indole-butyrate + potassium 1-naphthylacetate + 1.8% sodium nitrophenolate (C5, 50 + 50 + 1 mg L−1), and a combination of potassium 3-indole-butyrate + potassium 1-naphthylacetate + 1.8% sodium nitrophenolate + DA-6 (C6, 50 + 50 + 1 + 10 mg L−1), were sprayed either 3 or 10 days before transplanting. Seedlings sprayed 10 days before transplanting exhibited a higher number of white roots and total roots at the returning green stage, along with increased grain yield, irrespective of the plant growth regulator used. The C6 combination emerged as the most effective treatment, enhancing the growth of both hybrid and conventional rice seedlings, accelerating the growth rate of white roots and total roots, and increasing the length of the longest white root during the greening period, ultimately resulting in higher grain yield. Our findings demonstrate that pre-transplantation application of a combination of plant growth regulators positively influences rice seedling growth.

Type
Research Article
Copyright
© The Author(s), 2024. Published by Cambridge University Press

Introduction

The surge in large-scale farming has led to the widespread adoption of mechanical transplanting for rice in China, covering over 30% of the total rice planting area (Huang and Zou, Reference Huang and Zou2018). Despite its advantages, this method poses challenges, requiring high-quality rice seedlings (Biswas et al., Reference Biswas, Ladha, Dazzo, Yanni and Rolfe2000) and causing substantial root damage, extending the recovery period (Singh and Singh, Reference Singh and Singh2014; Tang et al., 2020), limiting productivity gains.

Agrochemicals, such as plant growth regulators (PGRs), offer potential solutions by enhancing rice seedling root growth (Li et al., Reference Li, Zhong, Li, Li, Ding, Wang, Liu, Tang, Ding and Chen2016). Rice crop growth faces various stresses (Dobermann and Fairhurst, Reference Dobermann and Fairhurst2000; Paul et al., Reference Paul, Choudhary, Suri, Sharma, Kumar and Shobhna2014), and PGRs have been employed to boost stress resistance and increase yields (Pan et al., Reference Pan, Rasul, Li, Tian, Mo, Duan and Tang2013). Various PGRs, including brassinolide (Kaur et al., Reference Kaur, Singh, Deol, Dass and Choudhary2015), gibberellic acid (GA3) (Steffens and Sauter, Reference Steffens and Sauter2006), ethephon (Watanabe et al., Reference Watanabe, Hase and Saigusa2015), triacontanol (Ahmed, Reference Ahmed1990), uniconazole (Kazuo et al., Reference Kazuo, Sachiko, Masatomo, Hiromichi, Akira and Nobutaka1988), multi-effect triazole (Shen and Wu, Reference Shen and Wu1993), abscisic acid (ABA), and benzyladenine (BA) (Gurmani et al., Reference Gurmani, Bano and Salim2006), have shown effects on rice plant growth. Studies indicate that treatments with GA3, ethephon, or their combination effectively enhance seedling growth (Watanabe et al., Reference Watanabe, Hase and Saigusa2015), while soaking seeds in uniconazole increases tiller number but decreases height (Shankun, Reference Shankun1993). Soaking seeds in brassinolide or triacontanol solutions has been shown to increase root length, volume, the number of roots, and both shoot and root dry weight (Ahmed, Reference Ahmed1990; Kaur et al., Reference Kaur, Singh, Deol, Dass and Choudhary2015). Multi-effect triazole at 50 ppm enhances seedling activity, root growth, and early tillering (Shen and Wu, Reference Shen and Wu1993). ABA and BA improve both root system dry weight and aboveground dry matter accumulation (Gurmani et al., Reference Gurmani, Bano and Salim2006). While existing research suggests PGRs can enhance seedling growth, it remains unknown whether they can improve seedling root growth during the recovery period after mechanical transplanting. Broad-spectrum PGRs like 2-diethylaminoethyl hexanoate (DA-6) and sodium nitrophenolate, known for promoting crop growth and stress resistance (Górnik and Grzesik, 2002; Qi et al., 2013), hold promise for addressing slow growth due to mechanical transplanting-induced injuries.

In this study, hybrid and conventional rice varieties received various PGR treatments before transplanting, aiming to investigate the impact of PGRs and application timing on rice seedling growth during the returning green stage and optimize seedling cultivation.

Materials and Methods

Plant material and chemicals

The rice varieties used in this study, Quanliangyou 681 (hybrid) and Fenghuazhan (conventional), were provided by Hubei Quanyin High-tech Seed Industry Co., Ltd. and Hunan Changde Fengyu Seed Co., Ltd., respectively. These varieties were selected for their suitability for local cultivation. Dry hybrid (70 g seeds) and conventional (90 g seeds) rice seedlings were raised in hard plastic seedling trays (58 × 28 cm) on May 4, 2016, and May 6, 2017. Before sowing, the seeds underwent a 12-hour disinfection soak in a strong chlorine solution. The substrate in the seedling trays consisted of a soil and substrate mixture (1:3 vermiculite:peat, v/v) with a ratio of 4:6.

Plant growth regulators (PGRs), including 2-diethylaminoethyl hexanoate (DA-6), potassium 3-indole-butyrate, potassium 1-naphthylacetate (NAA), 1-triacontanol, and 6-benzylaminopurine, were purchased from Shanghai Yuanye Bio-Technology Co., Ltd., and 1.8% sodium nitrophenolate was obtained from Asahi Chemical Industry Co., Ltd. These PGRs were all of analytical grade.

Field site and experimental design

The experiments were conducted from 2016 to 2017 in greenhouse facilities for seedling cultivation and at the Agricultural Science and Technology Industrial Park of Yangtze University, Huazhong Agricultural High−Tech Industrial Development Zone, Jingzhou City, Hubei Province, China (30°22’N, 112°40’E, 34 m a.s.l.). This region, situated in the Jianghan Plain along the middle reaches of the Yangtze River, experiences a subtropical monsoon climate with an average annual sunshine duration of approximately 2000 hours and a total annual solar radiation ranging from 4600 to 4800 MJ m−2. The average annual precipitation varies between 1100 and 1300 mm, with around 70% occurring from April to September.

Plant growth regulators (PGRs) were sprayed onto the leaves of rice seedlings either 10 days (D1) or 3 days (D2) before transplanting. Each treatment with PGRs (Table 1) utilized five seedling trays. Mechanical transplanting of seedlings into a medium-fertility paddy field occurred on May 27, 2016, and May 29, 2017, with harvest dates on September 18, 2016, and September 20, 2017. Fertilization included the application of 650 kg ha−1 compound fertilizer (NPK, 15:15:15) during transplanting, 127.2 kg ha−1 and 84.8 kg ha−1 urea (46% N) at the tillering and panicle initiation stages, respectively, and 24 kg ha−1 potassium chloride (60% K2O) at the panicle initiation stage. A random block experimental design with three replicates per treatment was employed, with rice plants spaced 30 × 16 cm within each 45 m2 plot across all 72 plots. Additional management practices, such as disease and pest control, followed local routine procedures, including the application of 1.5 L ha−1 Pretilachlor 24 hours after rice seeding, 2 kg ha−1 validamycin for rice sheath blight control from June to July, and 0.75 L ha−1 flubendiamide for rice borer (Cnaphalocrocis medinalis) control in August.

Table 1. Treatments and plant growth regulators used in this study

Note: Spraying about 150 mL of PGR for each seedling tray.

Rice seedling growth

Various plant characteristics were assessed one day prior to transplanting seedlings, including plant height, leaf area per plant, leaf age, the total number of roots per plant, and the 100-plant dry weight for both aboveground and belowground components. The dry weight measurements were conducted after oven-drying at 80 °C until a constant weight was achieved. Each treatment had three replications. Individual leaf area was determined using ImageJ 1.51j8 (NIH, Bethesda MA, USA). Leaf age was quantified based on the number of leaves on the main stem, considering partial leaf extraction from the sheath. The root-shoot ratio was calculated by comparing the dry weights of aboveground and belowground components.

Root growth during the returning green stage

To evaluate root growth during the returning green stage, rice plants were carefully uprooted from the field 3 and 7 days after transplanting, considering the softness of the surface soil. After uprooting, the collected plants were washed with clean water, and various root parameters were recorded, including the number of white roots per plant (roots ≥5 mm in length that were white from base to tip, indicating indefinite roots), the length of the longest white root on each plant, and the total number of roots per plant. Each treatment had ten replications.

Yield and its components

Yield and its components were assessed after the maturation of rice plants, when 90% of the rice husks had turned yellow. In each plot, a 5 m2 area at the central part was chosen. The assessment involved selecting ten rice plants to determine the average effective panicle number. Additionally, five randomly chosen plants were used to assess the number of grains per year, seed setting rate, and 1000-grain weight.

Economic analysis

Economic benefits were quantified by calculating the ratio of total output (in USD per kilogram) to total agricultural input (in USD). Total output comprised the value of grain yield, while total agricultural input encompassed the costs of PGRs, seeds, fertilizers, herbicides, pesticides, and labor. The exchange rate was 6.75 RMB to 1 USD in 2017. The economic benefit associated with the costs of seed, fertilizers, herbicide, pesticide, and labor was consistent across all treatments.

Statistical analysis

The data were analyzed using SPSS 17.0 (SPSS Inc., Chicago IL, USA), and Origin 2019 (OriginLab Corp., Northampton MA, USA) software was employed for plotting. Two-way ANOVA was conducted, and treatment means were compared using the least significant difference (LSD) test at a significance level of p ≤ 0.05. All data are presented as mean ± LSD. The growth rate of rice roots after transplantation was computed following the method described by Islam et al. (Reference Islam, Price and Hallett2021): Increase in white root number per day = [(white root number per plant at 7 days after transplanting) – (white root number per plant at 3 days after transplanting)]/4 days; Increase in total root number per day = [(total root number per plant at 7 days after transplanting) – (total root number per plant at 3 days after transplanting)]/4 days; Increase in the length of the longest white root per day = [(the length of the longest white root at 7 days after transplanting) – (the length of the longest white root at 3 days after transplanting)]/4 days.

Results

The response of rice growth characteristics, yield, and its components to hybrid rice and conventional rice under different PGRs

The comparative performance of hybrid rice and conventional rice under various PGR application methods is summarized in Table S1. In seedlings treated 10 days before transplanting, hybrid rice exhibited significantly increased seedling height, leaf area (D1CK, D1B1), and 100-plant dry weight (D1C6) compared to conventional rice. However, leaf age (D1C5), root number (D1B1, D1C3, D1C4), and root-shoot ratio (D1C4) were reduced in hybrid rice. In seedlings treated 3 days before transplanting, hybrid rice showed improved seedling height, leaf age, 100-plant dry weight, and root–shoot ratio in several PGR methods. Leaf area increased in all treatments, while root number decreased only in D2B1. Table 8 reveals that, compared to conventional rice, hybrid rice exhibited significantly lower effective panicle number (CK, C3) but increased spikelet number per panicle, seed setting rate (several PGR methods), 1000-grain weight, and grain yield (all PGR methods except D1C6 in 1000-grain weight).

Transplanted rice growth as affected by PGRs

For each PGR and considering hybrid rice, seedling height under DA-6 and C3 treatments 10 days before transplanting was significantly higher than plants subjected to the same treatments 3 days before transplanting (Table 2). Additionally, the number of roots per plant sprayed 10 days before transplanting was 11.6–25.6% higher than those sprayed 3 days before transplanting (Table 3). The application of C6 caused the highest 100-plant dry weight in both hybrid and conventional rice seedlings when sprayed 10 days before transplanting and only in conventional seedlings when sprayed 3 days before transplanting (Table 3). The application time of the DA-6, C3, C4, C5, and C6 treatments did not significantly affect the leaf area of hybrid rice seedlings (Table 2). Among all combinations of growth regulators and application times, the C6 treatment 10 days before transplanting had the strongest promoting effect on the number of roots per plant and 100-plant dry weight (Table 3). Additionally, the C6 treatment 3 days before transplanting had a moderate promoting effect on the root–shoot ratio in hybrid rice seedlings.

Table 2. Quality of hybrid (Hyb) and conventional (Conv) rice seedlings as affected by plant growth regulators (PGRs): height (H), leaf area (LA), and leaf age (LAge)

+See Table 1 for details. For each rice type (hybrid or conventional), different letters (a, b, c) indicate significant differences among treatments for a given spraying time based on LSD’s multiple range tests (p < 0.05, n = 3).

Star (*) represents statistical significance between the two spraying times under given PGR treatment based on independent samples t test (p < 0.05, n = 3). The values in table are two-year averages.

Table 3. Quality of hybrid (Hyb) and conventional (Conv) rice seedlings as affected by plant growth regulators (PGRs): number of roots (NR), 100-plant dry weight (PDW), and root-shoot ratio (RSR)

+See Table 1 for details. For each rice type (hybrid or conventional), different letters (a, b, c) indicate significant differences among treatments for a given spraying time based on LSD’s multiple range tests (p < 0.05, n = 3).

Star (*) represents statistical significance between the two spraying times under given PGR treatment based on independent samples t test (p < 0.05, n = 3). The values in table are two-year averages.

Overall and for each regulator solution sprayed, treatments 10 days before transplanting tended to increase the leaf area, leaf age, and root number (per plant) of conventional rice by 31.0–62.9%, 2.7–12.8%, and 1.9–34.6%, respectively, compared with spraying 3 days before transplanting (Tables 2 and 3). Some growth traits of plants treated with C6 both 10 and 3 days before transplanting were higher than those with the other growth regulators and the control treatment. For example, the height, leaf area, and 100-plant dry weight of seedlings treated with C6 at 10 days before transplanting were significantly higher than those of control plants by 29.6%, 64.3%, and 40.0%, respectively. When sprayed 3 days before transplanting, C6 application caused higher height (+17.0%), leaf area (+7.8%), leaf age (+6.4%), and the number of roots (+33.3%) than the control treatment.

Root growth of transplanted rice seedlings as affected by PGRs

Under the same growth regulator solution application, the increases in white root number per plant and total root number per plant sprayed 10 days before transplanting were significantly higher than those sprayed 3 days before transplanting (Fig. 1a). However, the DA-6 and C3 treatments better promoted white root growth when applied 3 days before transplanting than 10 days before transplanting. When considering treatments 10 days before transplanting (D1 time) and the hybrid rice seedlings, the increase (+25.0% to +57.5%) in white root number per plant under DA-6, C3, C4, and C6 was significantly higher than that under the control condition (Fig. 1a). The same was noticed for the total root number per plant when seedlings were sprayed with DA-6, C4, C5, and C6 solutions, with increments between 16.7% and 101.5% compared to the control treatment. The length of the longest white root was also increased under C4 and C6 treatments at 10 days before transplanting. When compared to the control condition, there was an increase in white root number per plant under the C5 and C6 treatments 3 days before transplanting, whereas the total root number per plant was increased by C4 and C6 treatments (Fig. 1a). The growth rate of the longest white root under C3, C4, and C6 treatments was significantly lower than in the control treatment.

Figure 1. Root growth rate of hybrid (a) and conventional (b) rice as affected by PGRs applied 3 (D2) or 10 (D1) days after transplanting. See Table 1 for details about the treatments. Different letters (a, b, c) indicate significant differences among PGR solutions for a given spraying time based on LSD’s multiple range tests (p < 0.05, n = 10). Star (*) represents statistical significance between the two spraying times under a given PGR solution based on independent samples t test (p < 0.05, n = 10). The values in table are two-year averages.

For each growth regulator treatment, and considering conventional rice, plants treated 10 days before transplanting had 7.5% to 93.0% more white roots and 23.3% to 85.7% more total roots than those treated 3 days before transplanting (Fig. 1b). However, the increase in white root length was lower in plants sprayed 10 vs. 3 days before transplanting. The increase in white root number per plant and total root number per plant of seedlings sprayed with growth regulators 10 before transplanting was significantly higher than that of seedlings under the control treatment. The increase in the length of the longest white root under C3 and C5 treatments was significantly lower than that under the control treatment when regulators were sprayed 10 days before transplanting (Fig. 1b). Considering treatments done 3 days before transplanting, plant growth regulators increased the number of white roots by 33.3% to 80.0% compared to the control condition. In relation to the control condition, there were increases in total root number per plant under C5 and C6, and increases in the length of the longest white root under C3, C5, and C6 when solutions were sprayed 3 days before transplanting.

Rice yield and its components as affected by PGRs

For each growth regulator applied, the yield of the treatments sprayed 10 days before transplanting was 1.4% to 9.2% higher than those sprayed 3 days before transplanting (Table 4). The yield in C4 and C6 treatments applied 10 days before transplanting was significantly higher than that of the control treatment by 8.0% and 11.2%, respectively. When considering treatments done 3 days before transplanting, the yield in C6 was significantly higher than that of the other treatments. As shown in Table 4, the grain yield of hybrid rice treated 10 days before transplanting outperformed that of plants treated 3 days before transplanting, mainly owing to increases in effective panicle number (+1.2% to +10.3%) and the number of grains per panicle (+1.1% to +10.2%). For the two spraying times, the effective panicle number under the C6 treatment was the highest (Table 4).

Table 4. Yield and yield components of hybrid (Hyb) and conventional (Conv) rice as affected by plant growth regulators (PGRs): effective panicle number (EPN), spikelet number per panicle (SNP), seed setting rate (SS), 1000-grain weight (TGW), and grain yield (GY)

#Days after transplanting;

+See Table 1 for details. For each rice type (hybrid or conventional), different letters (a, b, c) indicate significant differences among treatments for a given spraying time based on LSD’s multiple range tests (p < 0.05, n = 3).

Star (*) represents statistical significance between the two spraying times under given PGR treatment based on independent samples t test (p < 0.05, n = 3). The values in table are two-year averages.

The grain yield of conventional rice was 1.7% to 11.0% higher when plants were sprayed 10 days before transplanting compared to those sprayed 3 days before transplanting (Table 4). The yield in C4 and C6 treatments was significantly higher than that in the control treatment when plants were treated 10 days before transplanting. The yield in the C6 treatment sprayed 3 days before transplanting was significantly higher than that of the control treatment (+6.0%). When comparing spraying times, the yield increase of conventional rice due to growth regulators noticed in plants sprayed 10 days before transplanting was caused by increases in effective panicle number (+0.3% to +12.9%). For both spraying times, the effective panicle number under the C6 treatment was the highest.

Economic benefit as affected by PGRs

Overall, the net economic benefit (NEB) of the PGR treatments sprayed 10 days before transplanting was higher (+1.4% to +9.3%) than those sprayed 3 days before transplanting (Table 5). When considering only treatments done 10 days before transplanting, NEB in C4 and C6 treatments was significantly higher than in the control treatment. The NEB in the C6 treatment was the highest when compared to the other treatments sprayed 3 days before transplanting (Table 5).

Table 5. Economic benefit of rice as affected by plant growth regulators (PGRs): economic benefit of cost of PGRs (EBPGR cost); economic benefit of rice yield (EByield); and net economic benefit (NEB = EByield – EBPGR cost)

+See Table 1 for details. The currency USD/RMB was 6.75/1 in 2017. The prices of 2-diethylaminoethyl hexanoate, potassium 3-indole-butyrate, potassium 1-naphthylacetate, 1-triacontanol, 6-benzylaminopurine, and 1.8% sodium nitrophenolate were 0.62, 0.53, 0.19, 0.69, and 0.71 USD g−1, respectively. Rice grain price was 0.41 USD kg−1. Different letters (a, b, c) indicate significant differences among different PGR solutions for a given spraying time based on LSD’s multiple range tests (p < 0.05, n = 3).

Star (*) represents statistical significance between the two spraying times under a given PGR solution based on independent samples t test (p < 0.05, n = 3). The values in table are two-year averages.

Discussion

Our study reveals that seedlings sprayed 10 days before transplanting exhibited a higher number of white roots and total roots at the returning green stage, resulting in a higher grain yield compared to those sprayed 3 days before transplanting. Furthermore, a solution composed of potassium 3-indole-butyrate (50 mg L−1), potassium 1-naphthylacetate (50 mg L−1), 2-diethylaminoethyl hexanoate (10 mg L−1), and 1.8% sodium nitrophenolate (1 mg L−1) significantly increased the growth rate of white roots, total roots, and the length of the longest white root during the greening period. This enhancement led to an increased grain yield and net economic benefit in both hybrid and conventional rice. The results highlight that the growth of rice seedlings raised in substrate trays can be substantially improved after transplanting by using a combination of plant growth regulators.

Plant growth regulators (PGRs) exhibit diverse effects on plant growth due to their mechanisms of action, and the growth regulators used in this study were predominantly growth-promoting and broad-spectrum. For example, potassium 3-indole-butyrate promotes cell division and induces the formation of adventitious roots in plants, while potassium 1-naphthylacetate, a broad-spectrum PGR, stimulates cell division, expansion, and the formation of adventitious roots. DA-6 enhances protein, chlorophyll, nucleic acid content, and photosynthetic rate, promoting root growth and improving stress resistance. Sodium nitrophenolate acts as a potent cell activator, quickly absorbed by cells to enhance viability and promote rooting. 6-benzylaminopurine, when absorbed by leaves, inhibits chlorophyll, nucleic acid, and protein degradation, delays plant senescence, and improves nutrient transport. 1-Triacontanol, another broad-spectrum PGR, promotes cell division, increases plant weight, enhances enzyme activity, and has root growth-promoting abilities.

The proper development of seedlings and roots serves as the cornerstone for achieving higher yields in any crop. In previous studies, PGRs, including DA-6, potassium 3-indole-butyrate, potassium 1-naphthylacetate, sodium nitrophenolate, triacontanol, and 6-benzylaminopurine, have been reported to improve the quality of rice seedlings and increase yield. In this study, some growth regulators did not consistently promote rice growth in certain conditions (Tables 2 and 3). Height, leaf area, leaf age, and root number per plant after a single application of DA-6 tended to be higher than those in the control treatment in both hybrid and conventional rice. At the returning green stage, application of DA-6 at 10 days before transplanting increased the growth of white root and total root number per plant in both hybrid and conventional rice, a positive effect not observed in grain yield (Fig. 1, Table 4). Additionally, spraying growth regulators (C3 to C6) 10 days before transplanting proved more conducive to rice growth compared to control and DA-6 treatments, with the C6 treatment providing the greatest benefit for increasing yield. This result aligns with previous reports that mixed PGR solutions exert a greater growth-promoting effect than single PGRs (Watanabe et al., Reference Watanabe, Hase and Saigusa2015; Xiao et al., Reference Xiao, Mao, Lu, Zeng, He, Wang and Yao2008). This may be attributed to the synergistic effects of multiple growth regulators, enhancing various underlying processes linked to plant growth. Moreover, yield components were balanced, and the ultimate grain yield of plants treated with C6 was the highest among all treatments.

PGRs can be applied throughout most of the rice growth period, yet limited studies have explored the influence of PGR spraying time on rice growth (Pal et al., Reference Pal, Mallick, Ghosh, Pal, Tzudir and Barui2009; Rezaeieh et al., 2014; Watanabe et al., 2015). Our current study contributes evidence demonstrating that the timing of growth regulator application significantly affects rice growth, influencing the root number per plant in hybrid rice seedlings, as well as both leaf area and root number per plant in conventional rice seedlings (Fig. 1, Table 2). The 7-day period post-transplanting emerges as a crucial phase for the resumption of normal rice root growth. Notably, white roots, indicative of newly grown roots, exhibit heightened vigor and play a pivotal role in nutrient absorption (Jiang et al., Reference Jiang, Zhang, Bai, Sun, Wang, Ding, Jiang and Zhang2014). Compared to spraying 3 days before transplanting, applying PGRs 10 days before transplanting provides an additional week to stimulate root development. When comparing the two spraying times, PGR application 10 days before transplanting led to an increase in the number of white roots and total roots in both hybrid and conventional rice seedlings after transplanting. However, there was no significant difference in the growth rate of white roots between the two spraying times (Fig. 1). Additionally, the spraying time exerted a more pronounced impact on the yield of conventional rice than on hybrid rice (Table 4). Such disparity may be caused by the differences in growth characteristics.

This study observed a differential response between hybrid rice and conventional rice to PGRs (Supplementary Material Table S1). In plants treated 10 days before transplanting, the leaf area in all treatments was higher in hybrid rice than in conventional rice (Table 2). Regardless of the spraying time and treatment, the 1000-grain weight and grain yield of hybrid rice were higher than those of conventional rice, with the exception of the C6 treatment at 10 days before transplanting (Table 4). The strong heterosis in biomass production and the high yield potential of hybrid crops have been widely recognized (Cheng et al., Reference Cheng, Zhuang, Fan, Du and Cao2007; Yuan, Reference Yuan1997). Numerous studies have indicated that hybrid rice exhibits higher total N, P, and K accumulation, a ‘darker’ leaf color (higher leaf N content), and a longer leaf greenness than conventional rice. As a consequence, hybrid rice demonstrates an increased seedling index, leaf area, chlorophyll level, high activity of protective enzymes in leaves, as well as high root/shoot biomass (Chen et al., Reference Chen, Zheng, Feng, Zhou, Mu, Liu, Zhao, Shen, Rao and Li2021; Mahajan et al., Reference Mahajana, Pandeya, Kumar, Dattaa, Sahoo and Parsad2014; Wei et al., Reference Wei, Meng, Li, Xu, Huo, Wei, Guo, Zhang and Dai2017).

Conclusions

When compared to non-sprayed plants and other treatments with plant growth regulators sprayed alone or in combination, the solution composed of potassium 3-indole-butyrate (50 mg L−1), potassium 1-naphthylacetate (50 mg L−1), 2-diethylaminoethyl hexanoate (10 mg L−1), and 1.8% sodium nitrophenolate (1 mg L−1) applied 10 days before transplanting resulted in the highest grain yield and net economic benefit in both hybrid and conventional rice, while also improving root growth at the returning green stage.

Supplementary material

The supplementary material for this article can be found at https://doi.org/10.1017/S0014479724000048

Acknowledgements

This work was funded by the National Key Research and Development Program of China (No. 2017YFD030140404).

Competing interests

The authors declare no conflicts of interest.

Footnotes

Jichao Tang and Zhimin Zhang contribute equally to this work.

References

Ahmed, J. (1990). Effects of a growth regulator on rice seedling growth. International Rice Research Newsletter 15, 23.Google Scholar
Biswas, J.C., Ladha, J.K., Dazzo, F.B., Yanni, Y.G. and Rolfe, B.G. (2000). Rhizobial inoculation influences seedling Vigor and yield of rice. Agronomy Journal 92, 880886.CrossRefGoogle Scholar
Chen, G.J., Zheng, D.F., Feng, N.J., Zhou, H., Mu, D.W., Liu, L., Zhao, L.M., Shen, X.F., Rao, G.S. and Li, T.Z. (2021). Effects of exogenous salicylic acid and abscisic acid on growth, photosynthesis and antioxidant system of rice. Chilean Journal of Agricultural Research 82, 2132.CrossRefGoogle Scholar
Cheng, S.H., Zhuang, J.Y., Fan, Y.Y., Du, J.H. and Cao, L.Y. (2007). Progress in research and development on hybrid rice: a super-domesticate in China. Annals of Botany 100, 959966.CrossRefGoogle Scholar
Dobermann, A. and Fairhurst, T. (2000). Rice: nutrient disorders & nutrient management. Handbook Series (p. 191). Available at http://books.google.com/books?id=V-kJxfFhkaUC&pgis=1.Google Scholar
Górnik, K. and Grzesik, M. (2002). Effect of Asahi SL on China aster ‘Aleksandra’ seed yield, germination and some metabolic events. Acta Physiologiae Plantarum 24, 379383.CrossRefGoogle Scholar
Gurmani, A.R., Bano, A. and Salim, M. (2006). Effect of growth regulators on growth, yield and ions accumulation of rice (Oryza sativa L.) under salt stress. Pakistan Journal of Botany 38, 14151424.Google Scholar
Huang, M. and Zou, Y. (2018). Integrating mechanization with agronomy and breeding to ensure food security in China. Field Crops Research 224, 2227.CrossRefGoogle Scholar
Islam, M.D.D., Price, A.H. and Hallett, P.D. (2021). Contrasting ability of deep and shallow rooting rice genotypes to grow through plough pans containing simulated biopores and cracks. Plant and Soil 467, 515530.CrossRefGoogle Scholar
Jiang, S.K., Zhang, F.M., Bai, L.M., Sun, S.C., Wang, T.T., Ding, G.H., Jiang, H. and Zhang, X.J. (2014). QTL analysis on new root traits after rice transplanting. Chinese Journal of Rice Science 28, 598604. (in Chinese)Google Scholar
Kaur, R., Singh, K., Deol, J.S., Dass, A. and Choudhary, A.K. (2015). Possibilities of improving performance of direct seeded rice using plant growth regulators: a review. Proceedings of the National Academy of Sciences India 85, 909922.Google Scholar
Kazuo, I., Sachiko, N., Masatomo, K., Hiromichi, O., Akira, S. and Nobutaka, T. (1988). Levels of IAA, cytokinins, ABA and ethylene in rice plants as affected by a gibberellin biosynthesis inhibitor, uniconazole-P. Plant & Cell Physiology 29, 97104.Google Scholar
Li, X., Zhong, Q., Li, Y., Li, G., Ding, Y., Wang, S., Liu, Z., Tang, S., Ding, C. and Chen, L. (2016). Triacontanol reduces transplanting shock in machine-transplanted rice by improving the growth and antioxidant systems. Frontiers in Plant Science 7, 872.Google ScholarPubMed
Mahajana, G.R., Pandeya, R.N., Kumar, D., Dattaa, S.C., Sahoo, R.N. and Parsad, R. (2014). Development of critical values for the leaf color chart, SPAD and fieldscout CM 1000 for fixed time adjustable nitrogen management in aromatic hybrid rice (Oryza sativa L.). Communications in Soil Science and Plant Analysis 45, 18771893.CrossRefGoogle Scholar
Pal, D., Mallick, S., Ghosh, R.K., Pal, P., Tzudir, L. and Barui, K. (2009). Efficacy of Triacontanol on the growth and yield of rice crop in inceptisol of West Bengal. Journal of Crop & Weed 5, 128130.Google Scholar
Pan, S., Rasul, F., Li, W., Tian, H., Mo, Z., Duan, M. and Tang, X. (2013). Roles of plant growth regulators on yield, grain qualities and antioxidant enzyme activities in super hybrid rice (Oryza sativaL.). Rice 6, 9.CrossRefGoogle Scholar
Paul, J., Choudhary, A.K., Suri, V.K., Sharma, A.K., Kumar, V. and Shobhna, V. (2014). Bioresource nutrient recycling and its relationship with biofertility indicators of soil health and nutrient dynamics in rice–wheat cropping system. Communications in Soil Science & Plant Analysis 45, 912924.CrossRefGoogle Scholar
Qi, R., Gu, W., Zhang, J., Hao, L. and Li, Z. (2013). Exogenous diethyl aminoethyl hexanoate enhanced growth of corn and soybean seedlings through altered photosynthesis and phytohormone. Australian Journal of Crop Science 7, 20212028.Google Scholar
Rezaeieh, A.D., Aminpanah, H. and Sadeghi, S.M. (2014). Effect of methanol foliar application on rice (Oryza sativa L.) growth and grain yield. International Journal of Biosciences 5, 119125.Google Scholar
Shankun, C. (1993). Studies on the effects of soaking seeds with s-3307 solution on reducing plant height and increasing tillers of rice seedlings. Acta Agriculturae Universitatis Jiangxiensis 15, 194197. (in Chinese)Google Scholar
Shen, Y. and Wu, Y. (1993). Physiologic effect of treating seeds with multieffect triazole (met) in rice seedling raising with plastic sheet mulching. Acta Agriculturae Shanghai 9, 5861. (in Chinese)Google Scholar
Singh, K.N. and Singh, H. (2014). Transplanting shock in temperate rice and its influence on rooting characteristics and grain yield. Indian Journal of Agricultural Research 48, 389393.CrossRefGoogle Scholar
Steffens, B. and Sauter, W.M. (2006). Interactions between ethylene, gibberellin and abscisic acid regulate emergence and growth rate of adventitious roots in deepwater rice. Planta 223, 604612.CrossRefGoogle ScholarPubMed
Watanabe, H., Hase, S. and Saigusa, M. (2015). Effects of the combined application of Ethephon and Gibberellin on growth of rice (Oryza sativa L.) seedlings. Plant Production Science 10, 468472.CrossRefGoogle Scholar
Wei, H.H., Meng, T.Y., Li, C., Xu, K., Huo, Z.Y., Wei, H.Y., Guo, B.W., Zhang, H.C. and Dai, Q.G. (2017). Comparisons of grain yield and nutrient accumulation and translocation in high-yielding japonica/indica hybrids, indica hybrids, and japonica conventional varieties. Field Crops Research 204, 101109.CrossRefGoogle Scholar
Tang, X., Shao, C., Yu, N., Wang, H., Long, Q., Huang, Y., Lu, M., Xie, J. and Wan, J. (2014). Proteomics analysis of 6-BA on rice seedlings roots growth under nutrient stress condition. Chinese Agricultural Science Bulletin 30, 202207. (in Chinese)Google Scholar
Xiao, L., Mao, J.H., Lu, D.H., Zeng, H.L., He, L., Wang, S.Y. and Yao, L. (2008). Application of the mixture of abscisic acid and 3-indole butyric acid on rice. Southwest China Journal of Agricultural Sciences 21, 597601. (in Chinese)Google Scholar
Yuan, L.P. (1997). Hybrid rice breeding for super high yield. Hybrid Rice 12, 16. (in Chinese)Google Scholar
Figure 0

Table 1. Treatments and plant growth regulators used in this study

Figure 1

Table 2. Quality of hybrid (Hyb) and conventional (Conv) rice seedlings as affected by plant growth regulators (PGRs): height (H), leaf area (LA), and leaf age (LAge)

Figure 2

Table 3. Quality of hybrid (Hyb) and conventional (Conv) rice seedlings as affected by plant growth regulators (PGRs): number of roots (NR), 100-plant dry weight (PDW), and root-shoot ratio (RSR)

Figure 3

Figure 1. Root growth rate of hybrid (a) and conventional (b) rice as affected by PGRs applied 3 (D2) or 10 (D1) days after transplanting. See Table 1 for details about the treatments. Different letters (a, b, c) indicate significant differences among PGR solutions for a given spraying time based on LSD’s multiple range tests (p < 0.05, n = 10). Star (*) represents statistical significance between the two spraying times under a given PGR solution based on independent samples t test (p < 0.05, n = 10). The values in table are two-year averages.

Figure 4

Table 4. Yield and yield components of hybrid (Hyb) and conventional (Conv) rice as affected by plant growth regulators (PGRs): effective panicle number (EPN), spikelet number per panicle (SNP), seed setting rate (SS), 1000-grain weight (TGW), and grain yield (GY)

Figure 5

Table 5. Economic benefit of rice as affected by plant growth regulators (PGRs): economic benefit of cost of PGRs (EBPGR cost); economic benefit of rice yield (EByield); and net economic benefit (NEB = EByield – EBPGR cost)

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