Evaluating the Performance of Rice Genotypes for Improving Yield and Adaptability Under Direct Seeded Aerobic Cultivation Conditions

Sandhu, Nitika; Yadaw, Ram Baran; Chaudhary, Bedanand; Prasai, Hari; Iftekharuddaula, Khandakar; Venkateshwarlu, Challa; Annamalai, Anandan; Xangsayasane, Phetmanyseng; Battan, Khushi Ram; Ram, Mangat; Cruz, Ma. Teresa Sta.; Pablico, Paquito; Maturan, Paul Cornelio; Raman, K. Anitha; Catolos, Margaret; Kumar, Arvind

doi:10.3389/fpls.2019.00159

ORIGINAL RESEARCH article

Front. Plant Sci., 15 February 2019

Sec. Plant Breeding

Volume 10 - 2019 | https://doi.org/10.3389/fpls.2019.00159

Evaluating the Performance of Rice Genotypes for Improving Yield and Adaptability Under Direct Seeded Aerobic Cultivation Conditions

$\r\nNitika Sandhu$ Nitika Sandhu¹

Ram Baran Yadaw²

Bedanand Chaudhary²

Hari Prasai³

Khandakar Iftekharuddaula⁴

Challa Venkateshwarlu⁵

Anandan Annamalai⁶

Phetmanyseng Xangsayasane⁷

Khushi Ram Battan⁸

Mangat Ram⁸

Ma. Teresa Sta. Cruz¹

Paquito Pablico¹

Paul Cornelio Maturan¹

K. Anitha Raman¹

Margaret Catolos¹

Arvind Kumar¹^*

¹Rice Breeding Platform, International Rice Research Institute, Los Banos, Philippines
²National Rice Research Program, Hardinath, Nepal
³Regional Agriculture Research Station, Tarahara, Nepal
⁴Plant Breeding Division, Bangladesh Rice Research Institute, Gazipur, Bangladesh
⁵South Asia Breeding Hub, International Rice Research Institute, ICRISAT, Hyderabad, India
⁶Crop Improvement Division, National Rice Research Institute, Cuttack, India
⁷Agriculture Research Center, National Agriculture and Forestry Research Institute, Vientiane, Laos
⁸Rice Research Station, Kaul, India

With the changing climatic conditions and reducing labor-water availability, the potential contribution of aerobic rice varieties and cultivation system to develop a sustainable rice based agri-food system has never been more important than today. Keeping in mind the goal of identifying high-yielding aerobic rice varieties for wider adaptation, a set of aerobic rice breeding lines were developed and evaluated for grain yield, plant height, and days to 50% flowering in 23 experiments conducted across different location in Philippines, India, Bangladesh, Nepal, and Lao-PDR between 2014 and 2017 in both wet and dry seasons. The heritability for grain yield ranged from 0.52 to 0.90. The season-wise two-stage analysis indicated significant genotype x location interaction for yield under aerobic conditions in both wet and dry seasons. The genotype × season × location interaction for yield was non-significant in both seasons indicating that across seasons the genotypes at each location did not show variability in the grain yield performance. Mean grain yield of the studied genotypes across different locations/seasons ranged from 2,085 to 6,433 Kg ha⁻¹. The best-fit model for yield stability with low AIC value (542.6) was AMMI(1) model. The identified stable genotypes; IR 92521-143-2-2-1, IR 97048-10-1-1-3, IR 91326-7-13-1-1, IR 91326-20-2-1-4, and IR 91328-43-6-2-1 may serve as novel breeding material for varietal development under aerobic system of rice cultivation. High yield and stable performance of promising breeding lines may be due to presence of the earlier identified QTLs including grain yield under drought, grain yield under aerobic conditions, nutrient uptake, anaerobic germination, adaptability under direct seeded conditions, and tolerance to biotic stress resistance such as qDTY_2.1, qDTY_3.1, qDTY_12.1, qNR_5.1, AG_9.1, qEVV_9.1, qRHD_1.1, qRHD_5.1, qRHD_8.1 qEMM_1.1, qGY_6.1, BPH3, BPH17, GM4, xa4, Xa21, Pita, and Pita2. The frequency of xa4 gene was highest followed by qAG_9.1, GM4, qDTY_3.1, qDTY_2.1, qGY_6.1, and qDTY_12.1.

Introduction

Global climate change, water scarcity, labor shortage, declining water-table level, predicted significant shortfall in rice production, increasing population, expensive labor, and increasing green-house gas emission (GHG; Monaco et al., 2016) are some of the possible reasons focusing the introduction of water-labor-energy efficient direct seeded aerobic rice cultivation system (Nie et al., 2012; Rasul, 2016; USGS, 2016). By 2050, the worldwide water requirement is expected to increase by 55% (Connor, 2015; WWAP, 2016). By 2050, there is a strong necessity to boost the food production by 60% globally and 100% in the developing countries of the world (Alexandratos and Bruinsma, 2012).

In addition to water scarcity, declining agriculture involved labor forces in Asia by 0.1–0.4% (0.2% per year); in Bangladesh, Thailand, and Malaysia by 0.25–0.40%; in Cambodia and Philippines by 0.18% together with the escalating labor wages are important concerns for the sustainability of puddled transplanted rice (PTR) cultivation system (Kumar and Ladha, 2011). Traditional puddled system of rice cultivation requires 114-man days/ha as against 68-man days/ha in direct seeded aerobic cultivation system (Yamano et al., 2013).

Agricultural productivity is a result of combined efforts involving improvement of water use efficiency, land and water management practices, exploitation of water saving technologies, introduction of mechanization, high throughput screening methodologies, better scientific models, and powerful data analysis packages. Several water-saving technologies, for example, alternate wetting and drying (AWD) (Li, 2001; Tabbal et al., 2002), system of rice intensification (SRI) (Stoop et al., 2002), direct seeded aerobic rice (Bouman et al., 2002) have been proposed as suitable substitute to puddled system of rice cultivation (Kumar and Ladha, 2011).

Aerobic system of rice cultivation is growing as an economically feasible, water-labor-energy saving, mechanized, and climate smart agricultural practice to ensure food security. Seven to ten days early maturity of the aerobic rice crop compared to PTR allows timely planting of the succeeding crop in addition to the improvement in nutrient availability and soil conditions (Kumar and Ladha, 2011). Earlier aerobic rice varieties were developed with the aim to replace the low-yielding rice varieties of upland ecosystem (Nie et al., 2012). In the last decade, aerobic rice has not become popular among farmers due to high weed infestation and high cost to control weeds under aerobic situation as compared to PTR. With the availability of appropriate weed control measures, mechanization reducing labor requirements from 11 to 66% compared to PTR (Kumar et al., 2009; Rashid et al., 2009) and improved agronomic management practices; aerobic rice cultivation system is being successfully implemented in rainfed shallow lowland ecosystem.

In recent years, aerobic system of cultivation has gained momentum in irrigated lowlands where rainfall is not sufficient and pumping water from deep well is expensive, delta regions with delayed water supplies and upland system with supplemental irrigation. Aerobic rice needs 30–51% less total water for land preparation depending upon the soil types providing 32–88% higher crop productivity, 50% saving on labor (Wang et al., 2002) and can have 50% reduced GHG emission (Weller et al., 2016) compared to PTR (Bouman et al., 2005). The lack of stable yielding and dry direct seeded adapted varieties for aerobic system is a major limitation in achieving the maximum yield potential under water and resource limited conditions.

Most of the traits needed to improve yield in unfavorable environments are extremely complex in nature. Unraveling key regulators (QTLs/Genes) associated with grain yield and adaptability under aerobic conditions and combining the genes in the genetic background of high yielding mega rice varieties utilizing trait linked markers will ensure food security in the future. Molecular breeding can assist to carry precise breeding introgressing genes for tolerance to abiotic and biotic stresses needed for different regions of India.

The important key component of success in aerobic rice system is selection of widely adapted suitable aerobic rice cultivars (Wang et al., 2002). The present study was undertaken to identify the suitable aerobic adapted breeding lines suited to rainfed shallow lowland ecosystems of different countries of Asia; to study G (genotype) × E (environment) [genotype × location, genotype × season × location) interactions to identify genotypes that perform well over a broad range of growing conditions.

Materials and Methods

Plant Material and Experimental Sites

The plant material comprised of conventionally developed advanced breeding lines (genotypes) from the rainfed breeding program of IRRI which was developed through bi-parental (142 crosses) and complex cross (12 crosses). The advanced breeding lines were developed involving popular lowland rice varieties grown in different countries crossed with released/pre-breeding drought tolerant aerobic as well as shallow lowland suited lines developed at IRRI between 2009 and 2013 (Table 1). The generations were advanced by selfing and a total of 401 and 441 F₅/F₆ breeding lines were tested during wet season and dry season, respectively.

TABLE 1

Table 1. Detailed description on number of crosses developed per seasons/years and parentage to develop advanced breeding lines used in the present study.

A series of 23 experiments were conducted under aerobic conditions at the International Rice Research Institute (IRRI, Los Baños), Philippines; Bangladesh Rice Research Institute (BRRI, Gazipur), Bangladesh; Regional Agriculture Research Station (RARS, Tarahara), Nepal; National Rice Research Program (NRRP, Hardinath), Nepal; and National Rice Research Institute (NRRI, Cuttack), India IRRI-South Asia Breeding Hub (SA), ICRISAT (Hyderabad), India; Rice Research Station (RRS), Kaul, Haryana (India) and National Agriculture and Forestry Research Institute (NAFRI), Lao PDR. The detailed description on experimental design, number of advanced breeding lines screened in each season per location and the management practices followed in each experiment and location is presented in Table 2.

TABLE 2

Table 2. Details of the experiments conducted in 2014–17 across different ecosystems, seasons and years.

Agronomic Management Practices

Pedoclimatic Conditions

The Philippines is located at 14°10′11.81^′′ N, 121°15′39.22^′′ E, and the soil characteristics included pH 7.7 (0.01 M CaCl₂), 39% clay, 21% sand, 36% silt, 16.0 meq 100 g⁻¹ Ca, 7.8 meq 100 g⁻¹ Mg, 1.09 meq 100 g⁻¹ K, 20 mg kg⁻¹ P, and 0.101% KjN. BRRI, Bangladesh is located at latitude 23°45′ N, longitude 90° 22′ E, elevation 8.4 m above sea level. The sand, silt and clay of the experimental site varied from 17 to 19, 59 to 63, and 21 to 22, respectively, soil porosity 41 to 50% and organic matter content varied from 0.58 to 2.13%. The NRRP, Hardinath is located at 26°47′46.5 ″N and 85°57′49.35″ E. The sand, silt, and clay content of the experimental site was 37, 42, and 20%, respectively. The pH value of the soil was near to neutral; pH = 6.59) and very low in available sulfur (0.79 ± 0.06 ppm) and available boron (0.37 ± 0.05 ppm). The organic matter (1.02 ± 0.007%), total nitrogen (0.07 ± 0.002 %), extractable potassium (42.49 ± 2.52 ppm), available zinc (0.83 ± 0.21 ppm), and available manganese (6.75 ± 0.64 ppm) status was also low. RARS, Tarahara is located at 26°42′16.85″ North latitude and 87°16′38.43″ East longitude, and at 136 meters above sea level. The climate is subtropical, the soil texture is dominated by clay loam, and soil pH ranges from 6.5 to 7.0. The texture of the soil was clay loam with 3.42% organic matter, 0.04%total nitrogen, 108 kg/ha available phosphorus and 133 kg/ha K. The soil of the experimental site at NRRI, cuttack was basically clay loam texture with 32% clay, 38% silt, and 33% sand with medium bulk density of 1.45 g/cm³. Nutritional analyses of the soil showed medium status with 0.53% organic carbon, 214.03 kg/ha available nitrogen, 36.15 kg/ha available phosphorus (P₂O₅), and 164.05 kg/ha available potassium (K₂O). 85°55′48″ E to 85°56′48″ E longitudes and 20°26′35″ N to 20° 27′ 20″ N latitudes with the general elevation of the farm being 24 m above the sea level. The soil of the RRS, Kaul experimental site was basically clay loam, having 25% clay, 30% silt, and 45% sand with bulk density of 1.55 g/cm³. The soil was alkaline in reaction (pH 8.1), low in organic carbon (0.40%) and available nitrogen (190 kg/ha), medium in available phosphorus (36.6 kg/ha P₂O₅), and high in available potassium (371 kg/ha K₂O). The Hyderabad is located at 17° 22′ 31″ N and 78° 28′ 27″ E and the soil at experimental site consists of 21% clay, >9% silt, and 72% sand with organic content 0.5 ± 1%. Lao PDR is located at 17.9757° N, 102.6331° E and the soil pH varied from 5 to 7.5.

Land Preparation

Land preparations under aerobic conditions involved plowing using terra disc plow (IRRI and BRRI), mold board plow (NRRP, RARS, and NRRI), disc plow (IRRI-SA), and harrow (NAFRI and RRS). The plowing was followed by 3 rotorvations at weekly intervals (IRRI and BRRI); 3 tilling with nine tine cultivator (NRRI, RARS); 2 tillering with cultivator, light irrigation, and single rotorvation after 3–4 days (NRRI); 3 rotorvations at alternate days (IRRI-SA); and planking (NAFRI and RRS) followed by field leveling. At IRRI and NRRI, the field was laser leveled and allowed for the first flush of weeds to emerge and grow for 3 weeks, then controlled with the application of glyphosate (1.0 Kg ai/ha).

Seed Rate

The seed rate varied from 20 to 30 Kg ha⁻¹ (IRRI, BRRI, NRRI and RARS), 50 Kg ha⁻¹ (NRRI), 30 to 40 Kg ha⁻¹ (NAFRI), and 20 to 25 Kg ha⁻¹ (RRS). Sowing was practiced using Wintersteiger plot seeder (IRRI), dibbling 2 to 3 seeds/hill (IRRI-SA and RRS Kaul), line sowing (NRRI) and seed drill (NRRI and RARS).

Insect/Pest/Weed Management

At IRRI, combination of pre-emergence [oxadiazon at 0.5 Kg ai ha⁻¹ at 6 days after seeding (DAS)], early post emergence [bispyribac sodium 0.03 Kg ai ha⁻¹ (9.7%, nominee) at 11 and 22 DAS] and spot weeding at 35 and 55 DAS was used to control weeds. Integrated pest management practices involving rat baiting using ditrac (0.05 g kg⁻¹ = 0.005% brodifacoum) bait to control rats, pre-seeding application of fipronil (0.075 Kg ai ha⁻¹) along the bunds and at 7 DAS along the plot edges was followed. At BRRI, pre-emergence herbicide (petilachlor 500 EC @ 1.0 Kg ai ha⁻¹ at 6 days after seeding (DAS) was applied followed by hand weeding when needed. At NRRP, RARS, and NAFRI, application of pendimethaline @ 8 ml liter⁻¹, nominee gold (bispyribac sodium) as post emergence @ 0.4 ml liter⁻¹ plus one manual weeding was practiced to control weeds. At NRRI, combination of pre-emergence (oxadiazon @ 0.5 Kg ai ha⁻¹ at 6 days after seeding (DAS), early post emergence [bispyribac sodium @ 0.03 Kg ai ha⁻¹ (9.7%, nominee) between 15 and 20 DAS] and spot weeding at 35 DAS was used to control weeds. At IRRI-SA, combination of pre-emergence (pendimethalin @ 1.0 Kg ai ha⁻¹ at 6 days after seeding (DAS), early post emergence [bispyribac sodium @ 0.03 Kg ai ha⁻¹ (9.7%, nominee gold) at 11 and 22 DAS] and one hand weeding at 35 and 55 DAS was done to control weeds. Integrated pest management practices involving installing pheromone traps for controlling the adults of Yellow stem borer (scirpophaga incertulus) followed by chemical control by application of DuPont™ ferterra^® (chlorantraniliprole 0.4% GR) @ 4 Kg ha⁻¹ was practiced. At RRS, the field was irrigated after the sowing and pendimethelin @ 1.0 Kg ai ha⁻¹ was applied as pre-emergence herbicide after 1 day of seeding and spot weeding at 35 DAS was used to control weeds. The leaf folder was controlled by application of cartap @ 7.5 Kg ha⁻¹.

Irrigation

At IRRI, sprinkler method of irrigation was used during seedling establishment stage from 1 to 21 days after sowing (DAS) and thereafter surface irrigation was applied once or twice a week depending on weather and crop water status. The irrigated field was allowed to drain naturally through normal seepage and percolation. At NRRP, RARS, NRRI, IRRI-SA, and NAFRI, surface irrigation was applied twice a week or depending on weather and crop water status. The excess water was allowed to drain naturally and also through normal seepage and percolation.

Traits Measured

Across all locations days to 50% flowering (DTF) was recorded when ~50% of the plants in a plot had shown panicle exertion. At maturity, the plant height (PHT) of the randomly selected three plants per plot was measured from the base of the plant to the tip of the highest panicle of the plant using centimeter scale. At maturity, the harvested grains per plot were first threshed and then oven dried for 3 days at a temperature set of 50°C. The grain yield (GY) was calculated after normalizing the plot yield to a moisture content of 14%.

Genotyping of Promising Lines

The polymorphic simple sequence repeats (SSRs) markers in the earlier reported QTL region for anaerobic germination (Angaji et al., 2010), early vegetative vigor, nodal roots, root hair length, root hair density, early and uniform emergence, and grain yield under direct seeding (Sandhu et al., 2015), drought tolerance (Bernier et al., 2007; Venuprasad et al., 2009; Vikram et al., 2011) and gene-specific markers for blast, bacterial blight, and gall midge were identified. The details on the markers used to identify the QTLs/gene is presented in Supplementary Table 1.

Statistical Analysis

Season-Wise Two Stage Analysis

For each season, in the first stage, individual trials (location × season) are analyzed using a mixed model that considers genotypes as fixed and replicate and block within replicate effects as random. Trial-wise broad-sense heritability (H) was calculated as:

\begin{array}{l} H = \frac{{σ^{2}}_{g}}{{σ^{2}}_{g} + \frac{{σ^{2}}_{e}}{r}} \end{array}

where $σ_{g}^{2}$ represents the genotypic variance, $σ_{e}^{2}$ the error variance, and r represents the number of total replications. The first stage analysis produced the adjusted means for the genotypes in environment j having estimated variance-covariance matrix Vj. If adjusted means are sorted by environments (by location, year) and then by genotypes within each environment, the variance covariance matrix across trials “V” is of the block-diagonal form

\begin{array}{l} V = \oplus_{e = 1}^{m n} V_{e} = (\begin{matrix} V_{11} & 0 & \dots & 0 \\ 0 & V_{22} & \dots & 0 \\ ⋮ & ⋮ & ⋱ & ⋮ \\ 0 & 0 & \dots & V m n \end{matrix}) \end{array}

where ⊕ is the direct sum operator, m is the number of sites and n is the number of years, and V_jk is the estimated variance-covariance matrix of adjusted means in the jth environment. The weighting matrix is given by D( ${V_{j k}}^{- 1}$ ), where D( ${V_{j k}}^{- 1}$ ) is a diagonal matrix with diagonal elements equal to those of ${V_{j k}}^{- 1}$ (Smith et al., 2001, 2005). At the second stage, the marginal means for genotypes across environments are obtained using a mixed model is fitted to the table of adjusted means by fixing the error variance. The mixed model is given by

\begin{array}{l} \hat{Y_{i j k}} = μ + g_{i} + y_{k} + g y_{i k} + l_{j} + l y_{j k} + g l_{i j} + g y l_{i j k} + ϵ_{i j k} \hat{Y_{i j k}} \end{array}

is the adjusted mean of the ith genotype in the jth location and kth year, μ is the overall mean, g_i is the main effect of the ith genotype, l_j is the main effect of the jth location, y_k is the main effect of the kth year, ly_jk is the interaction of the jth location with the kth year, gy_ik is the interaction of the ith genotype with the kth year, gl_ij is the interaction of the ith genotype with the jth location, gyl_ijk is the interaction of the ith genotype with the jth location in the kth year, ϵ_ijk is the error. The error variance matrix will be a diagonal matrix. The error variance matrix is given by D(Ve⁻¹), where D (Ve⁻¹) is a diagonal matrix with diagonal elements equal to those of Ve⁻¹. The residual variance is set to unity. The model is fitted using PROC HPMIXED. HPMIXED is suitable when there are a large number of observations, or a large number of random effects or large number of levels of fixed effects like in the present case. Damesa et al. (2017) provide the SAS macro to calculate the weights proposed by Smith et al. (2001) and for the second stage of the two-stage analysis.

Yield Stability Analysis

A total of 48 advanced breeding lines that were tested in five or more than five trials were included in the yield stability analysis. The location × year × season combination is now considered as an “environment (E).” Stability was assessed using the three generally used models, (i) Shukla stability variance model (Shukla, 1972), (ii) Eberhart–Russell model (Eberhart and Russell, 1966), and (iii) Finlay-Wilkinson model (Finlay and Wilkinson, 1963) and the AMMI-1 (Additive Main effects and Multiplicative model with one multiplicative term) (Gauch, 1988, 1992). The best-fitting model was chosen based on the lowest AIC (Akaike Information Criterion) value. The stability models were fitted into the genotype × environment means within a mixed-model framework where the effect of the genotypes was considered as fixed and the trials were random (Piepho, 1998, 1999; Raman et al., 2011).

Results

Trial-Wise Means and Heritability

At IRRI, under the aerobic condition the mean DTF varied from 66 to 83 days, the mean plant PHT varied from 97 to 129 cm and mean GY from 4,035 to 6,433 Kg ha⁻¹. The heritability's (H) of the trials for GY varied from moderate to high (0.54 to 0.86) at IRRI (Table 3). In Bangladesh, the mean DTF ranged from 86 to 99 days, PHT from 93 to 112 cm, and mean grain yield varied from 2,528 to 5,064 Kg ha⁻¹ with estimated heritability for the grain yield ranging from 0.78 to 0.90. In Nepal, the phenotypic variability under aerobic conditions varied from 75 to 92 days for DTF, 95 to 120 cm for mean PHT and 2,085 to 4,793 Kg ha⁻¹ for mean grain yield (Table 3). In India, the variability for mean DTF ranged from 67 to 95 days, the mean PHT from 93 to 112 and mean GY from 3,300 to 4,712 Kg ha⁻¹. At NAFRI, Lao PDR, under aerobic condition the DTF ranged from 82 to 89 days, mean PHT from 89 to 98 cm and mean grain yield 3,315 to 3,525 Kg ha⁻¹. The estimated broad sense heritability for grain yield ranged from 0.48 to 0.78, 0.65 to 0.90, and 0.59 to 0.71 in Nepal, India and Lao PDR, respectively (Table 3).

TABLE 3

Table 3. Descriptive agronomic traits statistics across different ecosystems, seasons, and years under aerobic conditions.

Season-Wise Two Stage Analysis

The analysis indicated significant genotype × location interaction for yield and PHT under both wet and dry seasons. The genotype x season interaction was non-significant for all traits in the case of dry season and 0 for all traits in wet season trials. The genotype × season × location interaction for yield was non-significant in both seasons indicating that at each location the genotypes did not significantly vary in their performances across seasons (Table 4). The genotype × season × location interaction for DTF was significant in dry season.

TABLE 4

Table 4. REML parameters of the two-stage analysis across the locations and years for each season.

The means of entries tested in 3 or more years for these traits are shown in Table 5. Among genotypes tested in four or more trials the best five performers in both the seasons were IR 97057-10-1-1-2, IR 91328-43-6-2-1, IR 91326-19-2-1-2, IR 92521-146-3-3-2, IR 91326-7-13-1-1, IR 97041-8-1-1-1. The best performers in wet season that were tested in five or more trials were IR 91326-19-2-1-2, IR 92521-146-3-3-2, IR 91328-43-6-2-1, IR 91326-7-13-1-1, and IR 97041-8-1-1-1 (Table 5). The best performers in dry season that were tested in five or more trials were IR 92521-172-5-1-1, IR 97041-8-1-1-1, IR 91328-43-6-2-1, IR 92521-146-3-3-2, and IR 92521-173-1-3-2 (Table 5).

TABLE 5

Table 5. Mean performances of lines tested in 3 or more trials (site × year) for days to 50% flowering (days), plant height (cm), and grain yield (Kg ha⁻¹) across years and location.

Stability Analysis

AMMI-1 model was the best fitting stability model (AIC = 542.6). Entries IR 97046-42-2-1-2, IR 93835-167-2-2-1, and IR 97041-5-1-1-2 and the checks IRRI 132 and UPLRi 7 had relatively large factor loadings indicating higher sensitivity to changing environmental conditions. Of these the best yielder was IR 97046-42-2-1-2 (4,346.14 Kg ha⁻¹ during wet season and 2,754.22 Kg ha⁻¹ during dry season across five trials). The best performers were IR 92521-143-7-2-1, IR 93835-74-2-1-1, IR12L355, IR 97043-33-4-1-1 and IR 97041-8-1-1-1. Of this IR12L355 yielded 4174.34 Kg ha⁻¹ during wet season and 3,830.73 Kg ha⁻¹ during dry season.

The second-best model was the Finlay-Wilkinson model (AIC = 602.3). Based on the Finlay-Wilkinson regression model, a regression coefficient approximating to the value of 1.0 indicates an average stability. When it is allied with high yield, the genotype possesses general adaptability and when allied with low mean yield, the genotype is poorly adapted to all studied environments. This includes entries IR 92521-172-5-1-1, IR 93835-70-2-2-1, IR 92521-146-3-3-2, IR 91326-20-1-1-2, and IRRI 148. Of these IRRI 148 was moderately good yielding, 3,552.42 Kg ha⁻¹ during wet season and 3,160.87 Kg ha⁻¹ dry season. Note that IRRI 148 was tested in five trials at IRRI only. IR 93835-70-2-2-1 yielded 3,550.98 Kg ha⁻¹ and 3,001.65 Kg ha⁻¹ in wet and dry season respectively and IR 97041-8-1-1-1 yielded 3374.60 Kg ha⁻¹ and 2,904.00 Kg ha⁻¹ in wet and dry season, respectively.

Regression coefficient value (rescaled beta) provides estimation about the adaptability of genotype across different environments and locations and helps plant breeders to select the high yielding stable genotypes. Regression coefficient increasing above the value of 1.0 for the genotypes IR 92521-173-1-3-2, IR 93835-70-2-2-1, IR 91326-20-2-1-2, IRRI 132, and IR 97041-8-1-1-1, represents the adaptability of these genotypes to high yielding environment with more sensitivity to the environmental change (Fageria, 1992). Regression coefficients decreasing below the value 1.0 (Fageria, 1992) for the genotypes IR 92521-143-7-2-1, IR 92521-143-2-2-1, and IR 97043-33-4-1-1 indicates high resistance to the change in environment with adaptability to low-yielding environments.

QTLs for Biotic and Abiotic Stress Tolerance/Resistance Present in the Promising Lines

The selected promising aerobic rice genotypes were screened for the presence of QTLs/gene increasing rice adaptability to aerobic condition such as- anaerobic germination, early vegetative vigor, nodal roots, root hair length, rot hair density, early and uniform emergence, and grain yield under direct seeding (Dixit et al., 2015; Sandhu et al., 2015), drought tolerance (Bernier et al., 2007; Khowaja et al., 2009; Venuprasad et al., 2009, 2012; Vikram et al., 2011) and for resistance/tolerance to blast (Fjellstrom et al., 2004; Qu et al., 2006; Koide et al., 2011; Shikari et al., 2013) bacterial blight (Song et al., 1997; Chu et al., 2006; Swamy et al., 2006; Perumalsamy et al., 2010; Ullah et al., 2012), brown plant hopper (Sun et al., 2005; Jairin et al., 2007), and gall midge (Nair et al., 1996; Sama et al., 2012). Among the earlier identified QTLs/genes AG_9.1, qEMM_1.1 qNR_5.1, qEVV_9.1, qRHD_1.1, qRHD₅, qRHD_8.1, qGY_6.1, qDTY_2.1, qDTY_3.1, qDTY_12.1, BPH3, BPH17, GM4, xa4, Xa21, Pita, and Pita2, were identified to be present in the breeding lines providing higher yield and adaptability under aerobic conditions. Among the identified QTLs, the frequency of xa4 gene was highest followed by qAG_9.1, GM4, qDTY_3.1, qDTY_2.1, qGY_6.1, and qDTY_12.1. Among the breeding lines highest number of QTLs were identified in IR 92521-143-7-2-1 and IRRI 148 with 8 QTLs, followed by IR 92521-172-5-1-1 with 7 QTLs and seven genotypes possessing 6 QTLs. It is also evident from the study that qDTY_3.1 either single or in combination with qDTY_12.1 and/or qDTY_2.1, qGY_6.1 provide grain yield stability across different locations under aerobic conditions.

Discussion

Aerobic system of rice cultivation is an efficient, mechanized, resourceful and economically viable alternative to PTR cultivation system. Its benefits include saving of water-labor and energy (Tuong et al., 2005), improved soil physical conditions (Buresh and Haefele, 2010), timely establishment of succeeding crop, reduce GHG emission (Weller et al., 2016), increased agricultural productivity, and environmental sustainability (Bouman et al., 2005). Now a day's aerobic system of rice cultivation is becoming popular in South Asia (India, Bangladesh and Nepal), South East Asia (Cambodia, Myanmar, Lao PDR, Philippines, and Vietnam) and to some extent in the West Africa (Kumar and Ladha, 2011).

Genotype x environment (G × E) interaction arises when different genotypes react differently to the different environments and are paramount in the identification and development of genotypes that perform well over a wide range of growing conditions (Malosetti et al., 2013; Dou et al., 2016). The adjusted mean of genotypes over the environments based on the combined analysis of variance is used to select genotypes that are superior across the test environments and are good performers in comparison with the checks that have a general good adaptability. There were either significant genotype × location or genotype × season × location interactions for the agronomic traits including days to 50% flowering, plant height, and grain yield under aerobic conditions. The existing variability may be due to the variability in topography (Peng et al., 2006), soil types, fertility and organic matter turn over, soil nutrient dynamics (Gao et al., 2006), water regime, nutrient cycle, nutrient availability, and uptake (Belder et al., 2005; Nie et al., 2008; Kreye et al., 2009). Best genotypes in terms of high mean were identified for the wet (WS) and dry seasons (DS) separately (Table 5). Across seasons, the genotypes showed variable grain yield except some genotypes.

General adaptability is a criterion for selecting genotypes, however it is necessary to assess the stability of their performances over varying environmental conditions in large area testing such as the present. Assessing the yield stability has mainly been centered on the analysis of G × E interaction in the cultivar trials. The well-known stability measures can be expressed as parameters of a general mixed model by modeling the covariance structure of G × E interactions (Piepho, 1998). The stable genotypes identified by the two best models were different (Table 6). IR 91326-19-2-1-2 and IR 92521-146-3-3-2 identified by the AMMI-1 were good yielders. IR 97041-8-1-1-1 was identified as a stable genotype by both models (Table 6).

TABLE 6

Table 6. Promising lines, their stability ranking based on the best fitting models and the mean yield (kg ha⁻¹) of stable genotypes and QTLs present in promising genotypes increasing rice adaptation under aerobic situation and resistance/tolerance to biotic stresses.

In practice, there are not many successful examples of systematic aerobic rice breeding programs. Most of the varieties used for aerobic rice cultivation are the varieties that have been developed for upland conditions (Zhao et al., 2010). The lack of stable high yield appropriate rice varieties is the major limitations to achieve the maximum yield potential under aerobic system of rice cultivation. Mean grain yield of upland adapted rice varieties ranged from 3.0 to 8.8 t ha⁻¹ has been observed under aerobic rice cultivation system (George et al., 2002; Bouman et al., 2005, 2007; Xiaoguang et al., 2005; Atlin et al., 2006; Pinheiro et al., 2006; Feng et al., 2007). The mean GY across locations, seasons and years under aerobic condition was 5.0 t ha⁻¹, indicating the high grain yield potential and adaptability of these genotypes across different ecosystem.

The stable good yielding genotype IR 91326-19-2-1-2 (IR 06A144/IR 55419-04) showed 11% higher yield over Vandana (Philippines), 14.4% over BRRIdhan 29 (Bangladesh), 11.3% over Hardinath, and 3% over Tarahara (Nepal) (Table 7). IR 97041-8-1-1-1 (IRRI 105/IR 78877-163-B-1-1//IR 78878-53-2-2-2/IR03A550) identified as stable genotype by both models showed yield advantage of 20.1% over Vandana (Philippines), 2.9% over BRRIdhan 29 (Bangladesh), 9.4% over Hardinath, 30.1% over Tarahara (Nepal) and 18.8% over Shabhagi dhan (India) (Table 7). Grain yield advantage of 1.0% over locally adapted check Shabhagi dhan in India, 13.6% over Vandana in Philippines, 10.9% over BRRIdhan 29 in Bangladesh, 1.4% over Hardinath and 14.1% over Tarahara in Nepal, and 7.0% over TDK11 in Lao PDR was observed for the genotype IR 92521-146-3-3-2 (Vandana/IR 74371-46-1-1//IR 08L183) (Table 7). IR 93835-70-2-2-1 (IR 07L270//Vandana/IR 74371-46-1-1) showed grain yield advantage of 2.9% over Vandana (Philippines), 6.1% over Hardinath, 1.5% over Tarahara (Nepal) and 24.5% over Shabhagi dhan (India) (Table 7). The good yield advantage of the selected genotypes over the presently existing locally adapted varieties, indicates the suitability of these genotypes to be released as variety for cultivation under aerobic conditions. It is important to highlight here that the identified promising genotypes are the progenies of the crosses involving upland adapted breeding varieties/lines-Vandana, IR03A550, drought tolerant breeding lines IR 74371-46-1-1, IR 78877-163-B-1-1, IR 78878-53-2-2-2, and high yielding lowland adapted breeding lines, IR 07L270, IR 08L183, IR 55419-04 in their pedigree, indicating that these are the potential donors in developing varieties suited to aerobic cultivation conditions. The presence of drought QTLs in addition to the QTLs/genes for biotic and abiotic stress tolerance under aerobic conditions indicating the adaptability of genotypes to both drought and aerobic conditions.

TABLE 7

Table 7. Mean grain yield (Kg ha⁻¹) of selected stable genotypes across different ecosystems and QTLs for traits increasing rice adaptation under aerobic situation and resistance/tolerance to biotic stresses.

Root traits such as nodal root and root hair density may impart better nutrient and water uptake under aerobic condition in these genotypes as indicating by the presence of QTLs; qNR_5.1, qRHD_5.1, and qRHD_1.1. In addition to water-labor-energy saving, the identified genotypes with wider adaptability may serve as novel material for aerobic cultivation with yield advantage of at least 0.5–1.0 t ha⁻¹ over the existing upland varieties. The release of rice varieties including CR dhan 201, CR dhan 202, and CR dhan 204 for aerobic cultivation in India are successful example of development of aerobic rice at IRRI (Sandhu and Kumar, 2017). The other successful example of aerobic rice varieties includes MAS 946-1 and MAS 26 from University of Agricultural Sciences, Bangalore (Gandhi et al., 2012); Han Dao (HD277, HD 297, HD502) from China Agricultural University (CAU), China.

The genomic regions determining rice adaptation to aerobic situation play an important role in determining the performance of breeding lines under variable aerobic conditions. Interestingly, various marker-assisted introgression studies reported the significant QTL × QTL interactions for drought tolerance related trait in pyramided lines in different backgrounds (Dixit et al., 2012; Kumar et al., 2014; Shamsudin et al., 2016; Vikram et al., 2016; Sandhu et al., 2018). Capturing of such positive interactions for increased performance of QTLs in pyramided lines is necessary in achieving the significant genetic gain. In the present study, qDTY_3.1 either single or in combination with qDTY_12.1 and/or qDTY_2.1, qGY_6.1 provide grain yield stability across different locations under aerobic conditions. A positive interaction of qDTY_12.1 with qDTY_2.3 and qDTY_3.2 (Dixit et al., 2012), qDTY_12.1 with qDTY_2.2 and qDTY_3.1 (Shamsudin et al., 2016), and qDTY_7.1 with qDTY_4.1 and qDTY_9.1 (Sandhu et al., 2018) which significantly increases grain yield under drought have been reported. The genotypes with similar QTL combinations had shown similar yield stability ranking in both the models used in the present study. Introgression of QTLs/gene associated with traits such as anaerobic germination, early uniform emergence, resistance to gall midge and bacterial blight, grain yield under drought and direct seeded conditions may provide grain yield stability under variable growing environments as observed in the present study. There is an urgent need to identify such traits and positive QTLs/gene interactions providing grain yield stability and better nutrient uptake under aerobic conditions.

Conclusions

This work allowed to identify promising genotypes for targeted rice breeding for adaptation to aerobic systems. The development of breeding lines with 0.5–1.0 t ha⁻¹ yield advantage over the existing upland rice varieties and yield stability across different ecosystems and multiple seasons/years would support the cultivation of aerobic rice varieties that can withstand the destabilizing impact of changing climate across Asia. Identification of suitable aerobic cultivars with QTLs/genes providing adaptability and better water-nutrient uptake under shallow rainfed ecosystem shall help extend the domain of aerobic rice cultivation to new areas including irrigated areas with predicted water scarcity and labor shortage problem. The promising genotypes with desirable QTLs/genes may serve as donors in future marker-assisted breeding program. Identification of stable high-yielding genotypes across locations, environments, seasons and years shall help breeders to recommend the identified genotypes for release as varieties to be cultivated by farmers.

Author Contributions

NS was involved in conducting the experiments at IRRI (Philippines), analysis, data interpretation, and drafting of the manuscript. RY and BC were involved in conducting the experiments at NRRP, Hardinath (Nepal). HP was involved in conducting the experiments at RARS, Tarahara (Nepal). KI was involved in conducting the experiments at BRRI, (Bangladesh). CV was involved in conducting the experiments at Hyderabad (India). AA was involved in conducting the experiments at NRRI, Cuttack (India). PX was involved in conducting the experiments at NAFRI, Lao PDR. KB and MR were involved in conducting the experiment at RRS, Kaul (India). MC, PP, and PM was involved in management of experiments at IRRI (Philippines). KR was involved in data analysis. MC was involved in genotyping. AK conceived the study and was involved in critical revision of the manuscript and final approval of the version to be published.

Conflict of Interest Statement

The authors declare that the research was conducted in the absence of any commercial or financial relationships that could be construed as a potential conflict of interest.

Acknowledgments

The authors thank the Asian Development Bank (ADB) and the Government of Finland for providing financial support to the present study through the project TA8441-Development and dissemination of climate resilient rice varieties for water short areas of South Asia and Southeast Asia.

Supplementary Material

The Supplementary Material for this article can be found online at: https://www.frontiersin.org/articles/10.3389/fpls.2019.00159/full#supplementary-material

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