Varietal Differences in the Root Systems of Rice (Oryza sativa L.) under Drip Irrigation with Plastic Film Mulch

Abstract

With the escalating water scarcity in agriculture, a novel water-saving technique has emerged: drip irrigation with plastic film mulch (DI). Root function is crucial for sustaining rice production, and understanding its response to DI is essential. However, few studies have evaluated root systems in rice varietals and examined which kind of root system contributes to improving rice grain yield and water productivity in DI. If varietal differences of root reactions for water regimes were made clear, it might be more effective to find suitable varieties for DI and to improve grain yield in the DI system. To fill this knowledge gap, we conducted a two-year field experiment comparing two irrigation systems: continuous flooding (CF) and DI. We analyzed their effectiveness with four rice cultivars, including upland, F1 lowland, animal feed lowland, and lowland cultivars. Vertical root distribution, root bleeding rate, photosynthetic-associated parameters, water productivity, and yield performance were analyzed. In our study, the average grain yield of cultivars in the DI system (6.4 t/ha) was equivalent to those in the CF system (6.6 t/ha). The average water productivity under DI (0.34–0.75 kg m⁻³) demonstrated significant water-saving potential, saving approximately 35% of the total water supplied, resulting in higher water productivity compared to CF (0.27–0.51 kg m⁻³). Among the cultivars, the deep root weight of the upland cultivar significantly increased by 51% under DI compared to CF. The deep root ratio was positively correlated with the transpiration rate, grain yield, and water productivity, suggesting its contribution to high transpiration, thus maintaining a high carbon assimilation rate that results in high yield and water productivity. Therefore, deep roots are a notable trait corresponding to high yield under DI, and should be considered for the development of rice growth models for DI and the breeding of aerobic-adapted cultivars.

1. Introduction

With the escalating water scarcity in agriculture, the need to enhance water use efficiency in rice cultivation (Oryza sativa L.) has become paramount. Agriculture accounts for 70% of the world’s freshwater consumption, a figure that has been exacerbated by factors such as population growth, rapid increases in urbanization, and industrial expansion [1,2]. The dwindling availability of water resources due to these challenges accentuates the need for innovative solutions [3]. Addressing the pressing challenge of increasing rice production to meet the demand of a growing population amidst the backdrop of diminishing water resources, a novel water-saving technique has emerged: drip irrigation with plastic film mulch (DI) [4,5]. DI is a novel approach to rice cultivation, wherein an opaque plastic covering is used to mulch the soil surface without standing water throughout the entire rice growth cycle. This water-efficient method is designed to optimize the utilization of water resources for crop production by inhibiting the transfer of water vapor between the soil and the atmosphere, ultimately minimizing the reduction in crop yields associated with conventional rice farming practices.

As an integral component of a plant’s organs, the roots play a pivotal role by providing anchorage for the plant, enhancing nutrient and water uptake, and synthesizing plant hormones, organic acids, and amino acids [6,7]. However, the ability of the roots to effectively carry out their role depends on their type, structure, and modification. This significance extends to water-saving rice production systems, where root growth and structure can be instrumental to the development of the rice plant and grain yield production [8]. Therefore, it is necessary to determine the variation in the root responses of different rice cultivars under DI. Enhancements in root morpho-physiological traits are closely intertwined with heightened shoot biomass accumulation, improved efficiency in the use of nitrogen, increased water productivity, and augmented resistance to plant lodging in various crops [9,10,11]. The alteration of root structure stands out as a strategy to foster the development of a deep root system in rice. This can be accomplished by stimulating deeper elongation, particularly in conditions of low soil moisture, and by encouraging increased root branching to optimize soil water extraction [12,13]. The ability of roots to penetrate the soil to greater depths holds paramount importance in establishing a robust root system, which holds particular significance in gramineous crops with their robust roots [14,15]. While differences among cultivars and the application of breeding practices can influence the formation of deep root systems, the potential to induce such systems through effective cultivation management practices remains a compelling avenue for exploration [16].

In previous water-saving rice production studies, the low grain yield of rice under these systems compared with continuous flooding has been commonly ascribed to low soil water availability [17] with little attention given to effective and efficient water absorption by the roots, especially at the deep layer of the soil. However, in our previous studies, we observed comparable grain yield of rice under DI and CF [18,19]. Therefore, we hypothesized that the comparable grain yield largely depends on the root distribution pattern and water uptake capacity of rice roots under DI rather than the reduced quantity of water supplied compared with CF, although this could vary based on varietal differences; hence, there is a need to discover suitable varieties with improved grain yield for the DI system. The objectives of this study were (1) to compare the root characteristics, water productivity, and grain yield performance of rice cultivars under CF and DI, (2) to compare varietal differences in root patterns in response to DI, and (3) to examine which of the root factors contributes to the improvement of rice grain yield and water productivity in DI.

2. Materials and Methods

2.1. Information on Experimental Design, Soil, and Weather

Rice (Oryza sativa L.) crops were cultivated at the Faculty of Environmental Horticulture research farm, Chiba University, Japan (35.78 N, 139.9 E) in the summer seasons of 2020 and 2021. The field experimental design of crop management has been previously reported [19]. The soil at the experimental site was a low-humic Andosol with 39.9% sand, 29.9% silt, and 30.2% clay at 0–20 cm depth. The pH of the soil was 5.2, while the amount of organic matter and total N at 0–20 cm depth were 33.3 g kg⁻¹ and 3.6 g kg⁻¹, respectively. The weather parameters, including the mean temperature, sunshine hours, and rainfall during rice-growing periods, are shown in Figure 1.

The field experiment was arranged in a split-plot design (main plot: irrigation system; subplot: cultivar) with three replicates. The two rice irrigation systems were as follows. (1) CF: continuous flooded system. In this rice production system, each plot had concrete boundaries with an area of 7.5 m². The field was flood-irrigated so that a water layer 4–5 cm above the soil surface was kept until two weeks before harvest. (2) DI: water-saving drip irrigation with plastic film mulch. In this system, raised beds were covered with black polyethylene film. The plots were buried within the rows at a depth of 40 cm to prevent lateral percolation between neighboring plots. Soil moisture content was maintained between 75 and 80% field capacity in both years. The irrigation schedule was monitored using an FDR soil moisture meter (DIK321A, Daiki Rika Kogyo Co., Ltd, Kounosu, Japan). The two irrigation systems were located adjacent to each other, and both were adopted for direct seeding.

Four rice cultivars were examined. (1) Norin24 (upland rice, abbreviated as Norin); (2) Mitsuhikari 2003 (F1 lowland rice, abbreviated as Mitsu); (3) Hokuriku 193 (animal feed lowland rice, abbreviated as Hoku); (4) Koshihikari (lowland rice, abbreviated as Koshi). Viable seeds were directly sown in the field on June 8 and June 1 in 2020 and 2021, respectively. The plant density was 69.6 hills m⁻². Before planting, chemical fertilizers were administered at a rate of 40 kg ha⁻¹ (N:P:K = 20:20:20) on each field, and then top-dressing fertilization was carried out by applying 10 kg ha⁻¹ of nitrogen through foliar spraying at the panicle initiation stage in both years. Other key cultivation management tasks, such as weed control and pesticide spraying, were conducted following local recommendations.

2.2. Sampling and Measurements

Aboveground and root biomass were estimated 4 or 5 times at the panicle initiation, heading, grain-filling, and maturity stages. During each sampling instance, we gathered samples from ten rice hills, which collectively occupied an area of 0.5 m² within each plot. Roots were sampled from each replicate at the panicle initiation stage (DAS50) and heading stage (DAS85), using the dimensions of the monolith soil sampler (150 mm diameter, 30 cm depth) with the aid of five soil-sampling cores. Soil samples were divided into 0–15 cm and 15–30 cm segments and washed carefully in a 0.5 mm stainless steel sieve under running water to separate the roots. The data ignored the roots below 30 cm for both CF and DI. The portion of each root sample was used for the measurement of root length. Roots were arranged on a glass tray, scanned using a scanner (Epson GT-X970, Seiko Epson Corp., Nagano, Japan), and analyzed using ImageJ (Version number: 1.53a), as described by Tajima et al., 2013 [20]. Finally, the remaining roots were oven-dried at 80 °C for 72 h and weighed.

To determine the differences in root bleeding rate among cultivars grown under CF and DI, 5 hills were marked on each plot at the panicle initiation stage on July 20 and July 24 in 2020 and 2021. The rice stems were trimmed to a height of 10 cm above the soil level at 6:00 PM local time. We then placed 5 g of cotton wool on the upper portion of each cut stem and enclosed it with a polyethylene bag. After 12 h, we retrieved the cotton wool and determined the root bleeding rate by measuring the increase in weight of the cotton wool.

A portable photosynthetic apparatus system of Li-6400 (LI-COR, Lincoln, NE, USA) was used to measure the CO₂ assimilation rate (An), stomatal conductance (g_s), and transpiration rate (E) in the flag leaf of each rice cultivar under the two water regimes at the early grain-filling stage in 2021. The measurements were carried out when photosynthesis was most active (09:00 to 12:00 local time). Throughout the measurement period, the photosynthetic photon flux density level, average leaf temperature, and average vapor pressure deficit were maintained at 1000 μmolm⁻²s⁻¹, 25 °C, and 1.5 kPa, respectively.

Rice plants from a 1 m² area in each plot were collected to determine grain yield at physiological maturity each year. We recorded the count of panicles for each treatment. To determine the rough grain yield, the panicles were threshed and weighed for each rice cultivar. The grain weights were recorded for each cultivar under CF and DI after the grains were dried to a moisture content of 14%. The percentage of grains that had ripened was calculated by dividing the count of filled grains by the total number of grains. Harvest index was defined as grain yield per biomass at maturity. Water productivity was calculated as the ratio of the total quantity of water supplied (irrigation and rainfall) to each cultivar per grain yield.

2.3. Data Analysis

Analysis of variance (ANOVA) was performed using SPSS 20.0 (IBM, New York, NY, USA). The statistical model used included sources of variation due to replication, year (Y), cultivar (C), irrigation regime (IR), and the interaction of Y × C, Y × IR, C × IR, and Y × C × IR. Data from each sampling date were analyzed separately. The means were separated using Duncan’s multiple range test when the effects were significant in each year.

3. Results

3.1. Soil Water Content under DI

The amount of precipitation and irrigation in the CF and DI areas during the growth period are presented in Figure 2 and Table S1. The total irrigation water supplied to the CF was 1085 mm in 2020 and 985 mm in 2021. However, the total irrigation water supplied to the DI was 389 mm in 2020 and further decreased to 311 mm in 2021 due to increased precipitation (822 mm in 2020 and 1022 mm in 2021). The total irrigation water supplied to DI increased by 10% in 2021 compared to 2020. Soil moisture content under DI ranged from 62.3 to 83.4% in 2020 and 67.4 to 87.2% in 2021. Compared with CF, DI saved 35.1 ± 1.5% of the total water supplied in both years.

3.2. Root Growth

3.2.1. Shoot, Root Biomass, and Root-to-Shoot Ratio

Shoot and root biomass were not significantly affected by the irrigation system and year, although significant differences among the cultivars were found (Figure 3, Table S2). Shoot biomass in DI was equivalent to or lower than that in CF in 2021, except for the cultivar Norin, which had a longer growth duration under DI. Varietal differences in shoot biomass were observed from the early tillering stage (DAS65) in DI, earlier than the heading stage (DAS90) in CF. Root biomass was generally higher mid-season (from tillering to early grain filling) than early or late in the season. Root biomass in DI was similar to or lower than that in CF in 2021. The root-to-shoot ratio of all cultivars decreased with growth. The root-to-shoot ratio in DI was lower than that in CF in 2021, except for the cultivar Hoku, which probably competed more for soil nutrients under DI in the early tillering stage. The differences in DI were most obvious in the early growth stage, but were reduced at the heading stage.

3.2.2. Root Distribution Pattern

Root length and weight at the soil depth of 0–30 cm were significantly higher in CF than in DI at the heading stage of rice growth (Figure 4). Root length and weight of all cultivars were significantly lower in DI than in CF in both the surface and subsurface layers at the heading stage, except for Norin. Regarding the varietal difference, Norin developed more subsurface root biomass under DI at the heading stage, followed by Hoku.

The deep root ratio tended to be lower under DI than under CF, even though no significant differences in deep root ratio were observed between the water regimes of either DAS50 or DAS85 (Figure 5). The deep root ratio ranged from 0.1 to 0.19 under CF and ranged from 0.08 to 0.24 under DI, respectively. Generally, varietal differences in deep root ratio in CF were smaller in DAS50 than in DAS85. However, the upland cultivar (Norin) was significantly higher in DI compared to CF in both DAS50 and DAS85. No significant differences in deep root ratio were observed between water regimes of either DAS50 or DAS85.

3.2.3. Root Bleeding Rate

The average root bleeding rate of rice cultivars under CF was significantly higher than that under DI at the panicle initiation stage in both years (Figure 6). In particular, Koshi and Mitsu were significantly higher under CF than DI in 2020 and 2021, respectively. The average root bleeding rate of the 2-year data decreased by 17.5% and 15.3%, respectively, under DI compared with CF. Within the various rice cultivars, Mitsu consistently displayed the highest value under CF conditions, whereas Koshi consistently exhibited the lowest value under DI in both years.

3.3. Photosynthesis-Associated Parameters

An, g_s, and E were not significantly different between CF and DI (

Table 1. Photosynthetic-associated parameters of four rice cultivars at the early grain-filling stage under continuous flooded system (CF) and drip irrigation with plastic film mulch (DI) in 2021.

Cultivar	An (μmolm−2s−1)			gs (mmolm−2s−1)			E (mmolm−2s−1)
	CF	DI		CF	DI		CF	DI
Norin	16.4b	20.0a	*a	315ab	328a	ns	5.4ab	6.0a	*
Mitsu	21.4a	17.4b	*	319a	311b	ns	5.8a	5.3b	ns
Hoku	18.2b	18.2b	ns	301b	307b	ns	5.2b	5.3b	ns
Koshi	16.7b	15.1c	*	268c	255c	*	4.5c	3.8c	*
Mean	18.2	17.7		301	300		5.2	5.1
Cultivar (C)	***			***			***
Irrigation Regime (IR)	ns			ns			ns
C × IR	***			*			***

Note: Data indicate the mean of three replications. Values within a column for each irrigation system followed by different letters are significantly different at p < 0.05 according to Duncan’s multiple range test. ^a indicates the significance within some cultivars under CF and DI by t-test. * and *** are significant differences at p < 0.05 and p < 0.001, respectively; ns means non-significant according to ANOVA. An, g_s, and E indicate CO₂ assimilation rate, stomatal conductance, and transpiration rate, respectively.

). However, the cultivar and the interaction between the water regime and cultivar had a significant effect on the photosynthesis-associated parameters. Mitsu had the highest value in all photosynthetic-associated parameters in CF. An, g_s, and E were significantly higher in Norin under DI than in the other three cultivars. However, they were significantly lower in Koshi under DI compared to CF.

3.4. Yield, Yield Component, Harvest Index, and Water Productivity

Table 2. Water productivity, harvest index, yield, and yield components of four rice cultivars under continuous flooded system (CF) and drip irrigation with plastic film mulch (DI) in 2020 and 2021.

Cultivar	Panicle Number (m−2)			Spikelets (panicle−1)			Ripening Ratio (%)			1000-Grain Weight (g)			Harvest Index (%)			Grain Yield (t ha−1)			Water Productivity (kg m−3)
	CF	DI		CF	DI		CF	DI		CF	DI		CF	DI		CF	DI		CF	DI
2020
Norin	421.6	445.7ab	nsA	67.5b	115.6a	*	84.0b	76.9a	*	20.1b	18.7b	*	0.34	0.35	ns	4.7b	7.4a	*	0.28	0.75a	*
Mitsu	342.1	373.6b	ns	138.4a	116.9a	ns	88.6ab	77.4a	*	21.4a	20.3a	*	0.47	0.39	ns	9.4a	6.9a	*	0.50	0.57a	ns
Hoku	400.5	488.7a	*	83.8ab	129.4a	*	91.2a	59.4b	*	20.5ab	18.8b	*	0.29	0.29	ns	6.4ab	7.1a	ns	0.34	0.59a	*
Koshi	366.0	405.1b	ns	71.8b	67.3b	ns	85.0ab	64.9ab	*	20.1b	19.4ab	ns	0.35	0.35	ns	4.5b	3.4b	*	0.27	0.34b	*
Mean	382.6	428.3		90.4	107.3		87.2	69.7		20.5	19.3		0.36	0.35		6.3	6.2		0.35	0.56
2021
Norin	454.8a	484.8ab	ns	72.3c	105.5a	*	87.2b	80.0a	*	20.5b	18.8bc	*	0.38b	0.40a	ns	5.9c	7.6a	*	0.32c	0.68a	*
Mitsu	350.2b	392.2b	ns	139.3a	115.8a	*	88.7b	80.1a	*	21.3a	20.4a	*	0.43a	0.41a	*	9.2a	7.4a	*	0.51a	0.60b	*
Hoku	440.8a	491.1a	*	91.1b	117.6a	*	93.9a	69.2b	*	20.8ab	18.2c	*	0.33c	0.34b	ns	7.8b	7.3a	ns	0.39b	0.59b	*
Koshi	378.3b	414.3ab	*	69.9c	67.5b	ns	85.7b	74.9ab	*	20.2b	19.5b	*	0.34c	0.34b	ns	4.6d	4.1b	*	0.28d	0.36c	*
Mean	406.0	445.6		93.2	101.6		88.9	76.1		20.7	19.2		0.37	0.37		6.9	6.6		0.38	0.56
Year (Y)	ns			ns			ns			ns			ns			ns			ns
Cultivar (C)	***			***			***			***			**			***			***
Irrigation Regime (IR)	**			*			*			***			ns			ns			***
Y × C	ns			ns			ns			ns			ns			ns			ns
Y × IR	ns			ns			ns			ns			ns			ns			ns
IR × C	ns			***			***			**			ns			*			ns
Y × IR × C	ns			ns			ns			ns			ns			ns			ns

Note: Data indicate the mean of three replications. Values within a column for each irrigation system followed by different letters are significantly different at p < 0.05 according to Duncan’s multiple range test. ^A indicates the significance within some cultivars under CF and DI by t-test. *, **, and *** are significant differences at p < 0.05, p < 0.01, and p < 0.001, respectively; ns means non-significant according to ANOVA.

shows the yield component. The panicle number, number of spikelets per panicle, ripening ratio, and 1000-grain weight were all significantly affected by the irrigation regime. On average, over two years, DI led to an increase in the panicle number and number of spikelets per panicle, but a decrease in the ripening ratio and 1000-grain weight of the cultivars compared to CF. Among the cultivars under DI, the upland cultivar (Norin) significantly increased the number of spikelets per panicle, which contributed to a higher yield than occurred under CF. The F1 lowland and lowland cultivars significantly decreased in ripening ratio and 1000-grain weight; this contributed to the lower yield under DI compared to CF. The ripening ratio and 1000-grain weight of rice cultivars were significantly lower under DI than CF.

4. Discussion

Across both years, the average grain yield of the different rice cultivars showed no significant difference when DI and CF were compared. However, there was a significant impact on yield due to the interaction between the irrigation system and rice cultivar in the year 2021. Among these cultivars, lowland types, such as Mitsu and Koshi, consistently yielded better results under CF conditions compared to DI, while the upland cultivar, Norin, demonstrated higher yields under DI. Furthermore, variations in yields were observed for the animal feed lowland cultivar Hoku under the different irrigation systems. Though not significant, the small deep root ratio trend was found to be stronger under CF than DI, except for Norin, at the panicle initiation stage and heading stage. The irrigation system did not demonstrate a significant effect on the harvest index for the examined cultivars in either of the two years. Nevertheless, there were discernible differences in the harvest indexes of the cultivars between CF and DI in 2021. Notably, among all the cultivars and across both irrigation systems, Mitsu consistently displayed the highest harvest index. DI significantly increased the average water productivity in both years compared with CF. The average water productivity in DI was 0.56 kg grain m⁻³ water, 1.5–1.6 times higher than in CF. All the cultivars achieved higher water productivity under DI in comparison to CF, leading to the more efficient use of irrigation water.

Prior to this study, little information was available describing varietal differences in rice root morphology and physiology under CF and DI systems. Our results indicate that in DI, root growth at the soil surface is comparable with that under CF during the vegetative phase (Figure 4). Araki et al., 2005 [21], and Luo et al., 2023 [22], revealed that plants first draw water from the surface layer, and subsequently, the area of water extraction gradually shifts downward through the soil profile. When the water content in the shallow layer (0–25 cm depth) was abundant, over 90% of the water uptake occurred in this shallower zone [23,24]. Maintaining paddy soils in a wet but not continuously saturated state during the vegetative phase has the effect of preserving predominantly aerobic soil conditions [25]. These particular soil management practices have significantly facilitated better root growth at the surface layer with the DI approach. The results of our study suggest that current levels of root growth at the surface in CF can be achieved under DI. Our results are consistent with those of Bouman et al., 2006 [26], who showed no significant differences in the root characteristics of rice grown under CF compared with an alternate wetting and drying (AWD) irrigation system. We observed that there were large genotypic differences in root distribution patterns. Regarding the deep root ratio, the lowland cultivars produced comparable biomass to subsurface root growth in DI; however, upland cultivars allocated significantly more root growth at the lower soil horizons in DI compared to CF (Figure 5). This is in line with the conclusion of Kato et al., 2010 [27], who used aerobic cultivation technology. It is known that the soil moisture content, soil nutrient status, and soil physical properties can profoundly influence plant root growth [28].

The deep root system in upland rice cultivars enables them to harness water from the deeper soil layers, a resource that remains out of reach for cultivars with shallow root systems. This capability has proven effective in preserving yields, especially under reduced soil moisture conditions [29,30,31,32]. For a more precise assessment of rice’s deep root characteristics under water management, soil samples were taken and measured up to a depth of 60 cm by Kato et al., 2007 [33]. However, due to the presence of concrete boundaries under CF, our study was limited to measurements up to 30 cm below the surface. This discrepancy revealed that the rice cultivars under DI had greater deep root growth potential than under CF. The root bleeding rates conducted during the panicle initiation stage over two consecutive years identified substantial genotypic differences among the rice cultivars (Figure 6). Interestingly, lowland cultivars, such as Mitsu and Koshi, exhibited significantly higher root activity under CF than under DI. This observation aligns with the findings reported by Matsuo et al., 2009 [34], where a decrease in root activity for the lowland cultivar Koshi under water-saving cultivation systems was similarly noted. Furthermore, significant differences in root activity among upland (Norin) and animal feed cultivars (Hoku) under CF and DI were not observed (Figure 6). This could be attributed to the influence of root- and stem-xylem resistance mechanisms. The presence and impact of root- and stem-xylem resistance mechanisms represent essential factors that warrant consideration when assessing disparities in root activity between two irrigation systems [35,36]. These resistance mechanisms can substantially influence the transport of water and sap within the plant, potentially masking or reducing variations in root bleeding rates [37]. The results of this study showed no significant difference among the photosynthetic-associated parameters under CF and DI. However, it was observed that substantial genotypic variation existed among the tested rice cultivars (Table 1). The transpiration rate of Norin showed a significant increase of 11% under DI due to greater deep root development (Figure 7a). Deep roots are instrumental in enhancing a plant’s resilience in drought conditions, ensuring that transpiration can persist even when surface soil dries out. This strategy promotes drought tolerance and improves transpiration efficiency [38,39]. The regulation of deep root functioning and distribution, adjustments in canopy size, and the synthesis of the hormone abscisic acid (ABA) in both roots and leaves collectively play a central role in controlling leaf water potential (LWP) and enhancing leaf transpiration efficiency [40,41,42]. Under severe drought stress conditions, abscisic acid (ABA) typically assumes a more critical and pronounced role in the regulation of plant responses to water stress. However, the significance of ABA in plant responses may not be as pronounced in less severe drought stress conditions. Shi et al., 2015 [43], reported that both upland cultivars (Gaoshan1) and lowland cultivars (Nipponbare) demonstrated the ability to open their stomata for transpiration even under slight-to-moderate drought conditions, which allowed the effective loading of root-generated ABA into the xylem through apoplastic via-pass flow, subsequently reducing ABA exudation. Furthermore, root structural distributions, including deep root ratio and root branching, are likely to be promoted under aerobic conditions [44]. A study by Kato et al., 2013 [45], in northeastern Thailand utilized an irrigation system for aerobic cultivation and obtained similar results, supporting the notion that aerobic conditions can enhance root structure distributions. Plants with the trait of deep roots often exhibit better transpiration efficiency, which means they can achieve higher photosynthesis per unit of water transpired [46]. Our results indicated that the deep roots of the upland cultivar (Norin) could potentially contribute to a high transpiration rate, thus maintaining a high assimilation rate under DI in comparison to CF (Figure 7a and Figure 8). Additionally, while deep roots are one of the factors influencing transpiration, other environmental factors (i.e., temperature, humidity, and light intensity) also contribute to the regulation of transpiration rates [47]. In future research, it will be essential to continue investigating the complex interplay among these factors to gain a more comprehensive understanding of how plants manage water resources and optimize transpiration rates to adapt to various environmental conditions, especially in aerobic and mild water stress conditions. On the other hand, the lowland cultivar (Koshi) significantly decreased gas exchange performance (An, g_s, and E), likely due to the lower plasticity index for lower root bleeding rate (Table 1, Figure 6). Morita et al., 2000, He et al., 2019, Ansari et al., 2004, and Liu et al., 2021 [48,49,50,51], reported that root bleeding is closely linked to the active absorption of water and nutrients, photosynthate transport, and redistribution efficiency in the root system. In a study by Li et al. conducted on winter maize in 2022 [52], they similarly observed a significant effect of water management on various factors, such as root oxidation activity, cytokinin concentrations in both roots and shoots, the rate of photosynthesis in leaves, and the activities of essential enzymes responsible for converting sucrose to starch in grains. The reduction in yield observed in the lowland cultivars under the DI system could be attributed to alterations in root activity, function, and morphology, which may disrupt the effective transport and redistribution of photosynthates within the plants.

In general, the primary goals of water-saving technologies are to achieve higher water use efficiency while maintaining or even increasing crop yields [53]. Our research findings indicate that the average grain yield under DI was equivalent to that under the CF system. Meanwhile, DI demonstrated significant water-saving potential, saving approximately 35% of the total water supplied compared to CF, resulting in water productivity that was on average 53% higher (Table 2). Among the cultivars, DI significantly boosted the grain yield of the upland cultivar (Norin) and the comparable yield of animal feed lowland cultivar (Hoku). The increase in yield can be primarily attributed to the higher number of spikelets per square meter (m²) in these cultivars, despite a trade-off in ripening ratio and individual grain weight. However, lowland rice cultivars (Mitsu and Koshi) produced significantly higher yields under CF. This higher yield can be attributed to their superior ripening ratio and grain weight under CF conditions, offsetting potential trade-offs in other components. On the other hand, a sizeable genotypic variation was observed between root traits and grain yield. The root systems of the upland cultivar (Norin) under DI were characterized by well-developed root growth on the surface, and produced more deep roots compared to the CF sample. Therefore, it can be inferred that those characteristics contributed to a high transpiration rate, thus maintaining a high assimilation rate, resulting in the high yield performance and water productivity of the upland cultivar in production. Furthermore, there was a significant positive relationship between deep root ratio, grain yield (0.745*), and water productivity (0.861*) under DI (Figure 7b,c). The results indicated that vertical root distribution (i.e., the deep root ratio) during the vegetative phase influenced the yield and water productivity. The fact that animal feed lowland rice (Hoku) maintained a comparable yield under DI compared to CF is likely due to the high root-to-shoot ratio during the early growth stage (Figure 3). This high root-to-shoot ratio of Hoku during the early growth stage contributed to the prioritization of root development, which can increase a plant’s capacity to take up essential nutrients, promoting healthy growth and development [54]. These adaptations in the root system facilitated a greater allocation of photosynthetic products to the shoots in particular leaves, ultimately leading to a reduced root-to-shoot ratio and an enhanced yield while conserving water [55,56]. The low yield of lowland cultivars in DI was likely due to the low root vigor and water uptake. The relationship between root bleeding rate and grain yield in DI differed between the lowland cultivars (Mitsu and Koshi) and the other two. There was a significant positive relationship between root bleeding rate and grain yield under CF (Figure 4). This highlights the importance of the root activity of lowland rice in influencing grain yield in CF conditions, where root activity plays a critical role in crop performance.

In this study, the use of drip irrigation with plastic film mulch enhanced the development of shallow roots and facilitated the elongation of deeper roots, thereby significantly contributing to plant growth and yield. However, understanding this process requires an in-depth exploration of the complex relationship between root morphology and soil moisture content. Therefore, further research is crucial to improve the adaptive responses of rice roots to the DI system. Additionally, adequate soil aeration is vital for root elongation and activity, positively influencing plant development, water productivity, and yield. Yamaguchi et al., 2017 [57] reported that the alternate wetting and drying system of rice could improve reductive conditions due to soil aeration, which might lead to promoting root spread and decreasing culm lodging. Proper aeration increases the oxygen concentration in the root zone, indirectly benefiting root and photosynthetic system responses [58]. Conversely, poor soil aeration leads to hypoxia, reducing transpiration, nutrient uptake, and overall plant growth. Effective soil aeration enhances redoxase enzyme activity and root metabolism, improving nutrient absorption and accelerating plant growth and yield [59]. In drip irrigation with plastic film mulch without soil submergence, variations in soil aeration due to irrigation and mulching practices influence nutrient availability due to aerobic microorganisms and nitrogen use efficiency, resulting in overall plant growth and yield. Comprehensive studies considering these factors are essential for rice production under the DI system.

The development and identification of suitable genotypes and crop management options are underway worldwide to make agriculture more resource efficient and productive under drip irrigation with plastic film mulch [60]. As a first for future studies, exploring varietal differences under drip irrigation is an essential avenue for future research in agriculture. To further investigate and select adaptable crop cultivars, developing guidelines for selecting rice cultivars optimized for drip irrigation with plastic film mulch is crucial, considering annual variability due to climatic and environmental factors, soil conditions, plant density, and fertilizer management. Secondly, the alterations in the root structures of deep root systems result from increased root branches [14]. Further research is needed to improve the development of the rice root system in drip irrigation systems, including the study of adaptive responses, such as adventitious root emergence, lateral root branching, and water uptake. Thirdly, because of the limited extent of the research on root morphology and physiological characteristics in DI systems, additional studies are essential to elucidate the specific traits that contribute to optimal crop performance under DI conditions.

5. Conclusions

In our study, the average grain yield under DI was equivalent to that under the CF systems. Meanwhile, DI demonstrated significant water-saving potential, saving approximately 35% of the total water supplied compared to CF, resulting in higher water productivity. Also, using DI for rice cultivation increased shallow root traits and significantly increased the deep root weight of upland cultivars by 51% compared with under CF. The positive correlation between deep root ratio, transpiration rate, grain yield, and water productivity suggests the crucial role of deep roots in maintaining a high CO2 assimilation rate, and ultimately resulting in a higher yield and water productivity under drip irrigation with plastic film mulch. Notably, the variation in the root morpho-physiological traits of rice cultivars under DI is attributable to the differences in their root-to-shoot ratio and root bleeding rates. Therefore, further research is required to improve rice root traits, especially the deep root weight, to ensure their adaptability to the DI system in order to produce desirable high yields while saving a substantial amount of water. The well-developed shallow root systems and deeper root elongation of rice were considered to be the ideal root characteristics for the DI system, resulting in higher grain yield and water productivity. These attributes should be considered for the development of rice growth models for DI and the breeding of aerobic-adapted cultivars.