Microsoft Word - 1-Agra_30328 1 Original Article Biosci. J., Uberlândia, v. 33, n. 1, p. 1-9, Jan./Feb. 2017 PHOTOSYNTHETIC PRODUCTION OF WHEAT UNDER PRECISION PLANTING PATTERNS IN NORTHERN CHINA PRODUÇÃO FOTOSSINTÉTICA DE TRIGO ATRAVÉS DE PADRÕES DE PLANTAÇÃO DE PRECISÃO NO NORTE DA CHINA Zhen ZHANG 1,2 ; Xiang Min MAO 1 ; Wen Wen ZHONG 2 ; Zhi Bo FENG 2 ; Xun Bo ZHOU 1 1. Guangxi Colleges and Universities Key Laboratory of Crop Cultivation and Farming System, Agricultural College of Guangxi University, Nanning, 530004 China. whyzxb@gmail.com; 2. College of Agronomy, Shandong Agricultural University, Tai’an, 271018 China; Z. ZHANG and X. M. MAO are co-first author. ABSTRACT: Winter wheat (Triticum aestivum) is cultivated across a wide region; however, water is scarce during the growing season of wheat in the Northern Plain of China. Therefore, winter wheat should be irrigated to maintain a stable and high grain yield. The aim of this field study was to develop a water-conserving precision planting pattern for winter wheat that is grown in the Northern China Plain with the purpose of exploring the benefits in maintaining water and effects on wheat productivity. To accomplish this, several production variables and photosynthetic indexes were measured, including the number of stems, the leaf area index (LAI), photosynthetically available radiation (PAR), net photosynthetic rate, and grain yield. The study was carried out during the 2011–2012 and 2012–2013 winter wheat growing seasons. The experiment included a double-row planting pattern (DRPP) and a single-row planting pattern (SRPP), both of which were either irrigated or rainfed. The area of each plot was 9 m2, and the experimental design was a randomized blocks design with three replicates. All results were analyzed with an ANOVA, the F test, and the LSD (p ≤ 0.05) for means comparison. PAR capture ratios in the DRPP were higher than those in the SRPP at 50–120 cm above the ground. The photosynthetic traits of flag leaves under irrigated conditions were not significantly influenced by the respective planting pattern. However, at a growth stage of 80 under the rainfed conditions, the mean photosynthetic rate within flag leaves in the DRPP was higher than that in the SRPP. Furthermore, the DRPP under rainfed conditions was more likely to increase the apparent quantum yield (AQY) of flag leaves than the yield obtained under irrigation. These results suggest that DRPP optimizes the canopy PAR distribution in winter wheat and contributes to the maintenance of a higher photosynthetic capacity in the flag leaves under water stress (the rainfed condition). This relationship may be applied in demonstration trials to encourage winter wheat farmers to incorporate the use of DRPP in the drought-prone areas, which are subjected to insufficient precipitation during the growing stage of wheat in Northern China. KEYWORDS: Triticum aestivum. Photosynthetic active radiation (PAR) capture ratio. Net photosynthetic rate. Leaf area index. Yield components. INTRODUCTION Wheat (Triticum aestivum) is an important food crop in Northern China. An uneven spatial and temporal distribution of precipitation makes wheat vulnerable to water deficits during growing development (DENG et al., 2006; ZHOU et al., 2015). The Tai’an region receives precipitation that reaches a maximum level of 200 mm in the growing season of winter wheat. However, this precipitation does not satisfy the requirements of the winter wheat (SACKS et al., 2010). Therefore, it is important to develop methods to better maintain the available water for the crop population, which determines the wheat yield. Both water pollution and water level declines in North China have increased in severity, and water shortages can limit agricultural production. Rampino et al. (2006) indicated that the insufficient availability of water is a serious environmental concern and poses a limitation for the normal growth, development, and yield of crops. With the goal of solving the serious water deficits in the agricultural regions of Northern China, an increasingly greater number of drought-resistant winter wheat varieties are being cultivated (DONG et al., 2011). Meanwhile, cultivation methods have become increasingly more relevant in dealing with drought. Row spacing is an agronomic practice that affects the canopy structure, light interception, radiation use efficiency, and biomass production in some plants (ACRECHE et al., 2009; MATTERA et al., 2013). The main factors that influence plant growth include light, water, nutrients, and weed competition (BRANT et al., 2009). Appropriate row spacing affects the grain yield by improving the crop population, light distribution, and the relative humidity in the field. Interplant competition will occur when the supply of a single element for growth decreases to a level below the average level of plant groups in the field (AVOLA et al., 2008). If seeds are near enough to each other when they are sown, plants can influence one another and subsequently affect the atmospheric or soil Received: 24/09/15 Accepted: 09/08/16 2 Photosynthetic production… ZHANG, Z. et al. Biosci. J., Uberlândia, v. 33, n. 1, p. 1-9, Jan./Feb. 2017 environment, thereby decreasing growth rates (DE BRUIN; PEDERSEN, 2008). Lack et al. (2012) revealed that planting patterns and drought stress had very significant effects on yields of corn. In the field, the growth of a crop is related to the photosynthetically available radiation (PAR) capture ratio by the canopy (GITELSON et al., 2015). Dry matter accumulation can occur on the ground when leaves intercept incoming photosynthetically available radiation (PAR) (FENG et al., 2014). Stomatal closure is one of the first responses to drought stress, by limiting CO2 absorption, and decreases photosynthetic activity (NAYYAR; GUPTA, 2006). The changes in stomatal gas exchange rates and chlorophyll fluorescence provide information on most components of photosynthetic activity and plant responses to environmental factors such as drought stress (PANDA et al., 2008), which results in different rates of leaf photosynthesis at the grain ripening stage (SAN-OH et al., 2006). The objectives of this study on winter wheat (Triticum aestivum L.) were to assess the effects of a double-row planting pattern (DRPP) relative to a single-row planting pattern (SRPP) at different water conditions on both photosynthetic characteristics and products including stem numbers, LAI, PAR, yield components, and grain yield. The ultimate goal was to develop a new winter wheat water-conserving pattern in Northern China. MATERIAL AND METHODS The two-year study was conducted at the Agronomy Experimental Station of Shandong Agricultural University during the 2011–2012 and 2012–2013 winter wheat growing seasons. The experimental site (36°10′19′′N, 117°9′03′′E) is located in Tai’an, the main winter cultivating region of the Northern Plain in China. The total precipitation and solar radiation in the growing seasons of the winter wheat (from sowing to harvesting) were, respectively, 205.8 mm and 2803 MJ m-2 in 2011–2012 and 195.8 mm and 2961 MJ m-2 in 2012–2013. The precipitation during the winter wheat growing season is shown in Table 1. The total value of accumulated degree units (≥ 0°C) during the growing season for 2011–2013 was 2505.9°C, and the frost-free period was 193 days. Weather data were obtained from the Tai’an Agrometeorological Experimental Station, which was located 500 m from the experimental site. Table 1. Monthly precipitation (mm) during the winter wheat growing season. Years Oct. (Sowing) Nov. Dec. Jan. Feb. Mar. Apr. May Jun. (Harvest) Total 2011–2012 13.4 99.2 14.7 1.8 0.1 25.9 43.7 7.0 0.0 205.8 2012–2013 15.7 18.4 19.0 5.1 13.2 13.6 12.8 98.0 0.0 195.8 The experimental site in the 0–20-cm soil layer is characterized by silt loam soil with a soil organic matter content of 16.2 g kg-1, a total N content of 1.3 g kg-1, an available K content of 95 mg kg-1, and an available P content of 35 mg kg-1 at pH 6.9. Before sowing, 26.1 g m-2 of diammonium hydrogen phosphate, 38.4 g m-2 of urea, and 21.0 g m-2 of potassium sulfate were applied to the soil; half of the total nitrogen (urea) was applied as a base fertilizer before sowing and topdressing in the growth stage GS 30 (the stem elongation stage, ZADOKS et al., 1974). The experimental design included complete randomized blocks with three replicates. Each experimental plot unit was 3 m × 3 m; to prevent the lateral flow of soil water each plot was separated by concrete slabs that were 2 m in depth and 15 cm in width. The structure was buried on all four sides in the field. The treatments were consisted of two planting patterns (SRPP and DRPP; Figure 1) and two water conditions (I, irrigated; R, rainfed). Under the irrigation condition, 60 mm of water was applied on each of the following dates: April 8, May 3, and May 1 in 2012 and April 6, May 3, and May 15 in 2013. The amount of water was measured by a flow meter. Winter wheat (variety Jimai 22) was hand- sown at a density of 200 plants m-1 on October 8, 2011, and October 10, 2012. Crops were harvested on June 13, 2012, and June 8, 2013. 3 Photosynthetic production… ZHANG, Z. et al. Biosci. J., Uberlândia, v. 33, n. 1, p. 1-9, Jan./Feb. 2017 Single-row planting pattern (SRPP) and Double-row planting pattern (DRPP) Figure 1. Schematic diagram showing the precision planting patterns. The stem number was determined in a 1 m2 quarter in each plot at the following growth stages (GS): 20, 28, 32, 35, 45, and 80. Twenty plants per replicate were sampled randomly at the harvest to determine yield components. The following equation was used to calculate the LAI at GS45, GS49, GS71, and GS80: leaf area = leaf length × leaf width × 0.78 (1) At GS45, GS49, GS71, and GS80, radiation and leaf gas exchanges (net photosynthetic rate, Pn; intercellular CO2 concentration, Ci; transpiration rate, Tr; H2O conductance, Cond; apparent quantum yield, AQY) were measured. The canopy radiation, reflection, and underlying radiation were measured aboveground at 0, 50, and 120 cm, using a SunScan Canopy Analysis System (Delta T Devices Ltd., UK). PAR values exceeding 700 µmol m-2 s-1 were measured using a 1.5-m long linear sensor placed between the rows and parallel to each other. The photosynthetic rate and diffusion conductance in flag leaves were determined using a portable infrared gas analyzer (LI-6400; LI-COR Inc., USA) on a clear day from 9 a.m. to 11 a.m. (after the photoperiod began). The diffusion conductance was calculated according to Liu et al. (2015). The quantum flux density (QFD) on a leaf surface, relative humidity and flow rate in the chamber, and leaf temperature were maintained at 1600 µmol m-2 s-1, 60 % to 70 %, 500 µmol s-1, and 30 °C, respectively. Light response curves were obtained from 9 a.m. to 11 a.m. The concentration of CO2, relative humidity and flow rate in the chamber, and leaf temperature were maintained at 400 ppm, 60 % to 70 %, 500 µmol s-1 and 30 °C, respectively. From 200 µ mol m-2 s-1 to 0 µ mol m-2 s-1, the photosynthetic photon flux density (PPFD) was decreased to 50 µ mol m-2 s-1. The AQY of photosynthesis were determined as the slopes of the photosynthesis light response curves. Ten plants with similar growth vigor were harvested as samples by using a sickle for each plot. Spikes m-2, Kernels spike-1, 1000-kernels weight, and grain yield were also measured. A total of 2 m2 summer maize was harvested to measure yield. The experimental data were analyzed by ANOVA and the treatment means were compared using LSD (p ≤ 0.05). RESULTS AND DISCUSSION Winter wheat stem number Obvious differences in the wheat stem number were observed between the different row spacing patterns, and the trend between the irrigated and rainfed treatments was similar (Figure 2). Irrigation and row spacing had significant effects on the growth of single plants. The stem number of SRPP at GS28 and GS32 was greatest during the growing season. On the other hand, the highest stem number was observed at GS32 and GS35 in DRPP. The stem number under irrigated conditions was larger than those under rainfed conditions from GS32 to GS80, but there was no significant difference between irrigated and rainfed conditions. We ranked the stem number of the different treatments in the following order: DRPP-I > DRPP- R > SRPP-I > DRPP-R. In general, the stem numbers of DRPP were higher than those of SRPP. The results revealed that a reasonable stem tiller number is helpful to build an appropriate group structure, which is the basis of the allocation of resources, including water, light and fertilizer. Irrigation had no obvious effect on the winter wheat stem number, because irrigation was applied at the time of stem elongation. The observed differences in stem number during the growing season were caused by the planting pattern. Therefore, the 4 Photosynthetic production… ZHANG, Z. et al. Biosci. J., Uberlândia, v. 33, n. 1, p. 1-9, Jan./Feb. 2017 influence of row spacing on the tillers is greater than that of irrigation. Growth stage GS20 GS28 GS32 GS35 GS45 GS80 S te m n u m b e r ( m -2 ) 400 600 800 1000 1200 1400 1600 1800 2000 2200 2400 DRPP-I SRPP-I DRPP-R SRPP-R Figure 2. Plant stem number at different growth stages of the winter wheat. Values shown are the means over two years; the error bars represent the SE. SRPP, single row planting pattern; DRPP, double row planting pattern; I, irrigated; R, rainfed. Leaf area index LAI was measured after the flag leaf sheaths unfurled (Figure 3); the values are means of those values registered in the 2011–2012 and 2012–2013 growing seasons. The LAI of all treatments decreased with growth. There was no significant difference in the mean LAI value between DRPP and SRPP under the same growing conditions. The mean LAI under irrigated conditions was significantly higher than that of rainfed conditions for both DRPP and SRPP (p ≤ 0.05). In other words, irrigation had a significant impact on LAI. Growth stage GS45 GS49 GS71 GS80 L A I 0 1 2 3 4 5 6 7 8 DRPP-I SRPP-I DRPP-R SRPP-R Figure 3. Leaf area index (LAI) at different growth stages of the winter wheat. The values shown are the means over two years; the error bars represent the SE. SRPP, single row planting pattern; DRPP, double row planting pattern; I, irrigated; R, rainfed. PAR capture ratio As growth occurred, the PAR capture ratio decreased, and the percentage of the PAR capture ratio at 50–120 cm above the ground increased for all treatments (Figure 4). In DRPP, the PAR capture ratio was significantly higher than that in SRPP under irrigated conditions (p ≤ 0.05), but there was no significant difference between DRPP and SRPP under rainfed conditions (p > 0.05). Given the same growing conditions, the PAR capture ratios at 0–50 cm were similar between the two planting patterns. Under irrigated conditions, at GS45, GS49, GS71, and GS80, PAR capture ratios in DRPP were 64.8%, 65.9%, 53.6%, and 48.6% higher than those under SRPP at 50–120 cm above the ground, respectively. Under rainfed conditions, the corresponding values were 32.0%, 51.4%, 14.8%, and 15.4%, respectively, all higher in DRPP than SRPP. These results imply that DRPP and irrigation both may improve the canopy light distribution. Wang et al. (2014) considered that the senescence of flag leaves resulted in a decreased grain filling rate and grain yield. Therefore, improving the PAR capture ratio in the canopy of wheat may have a crucial impact on 5 Photosynthetic production… ZHANG, Z. et al. Biosci. J., Uberlândia, v. 33, n. 1, p. 1-9, Jan./Feb. 2017 the grain yield. These results indicated that improved planting patterns and irrigation could increase the grain yield. 0 10 20 30 40 50 60 70 80 90 100 DI SI DR SR DI SI DR SR DI SI DR SR 0-50 cm 50-120 cm C a p tu re r a ti o ( % ) GS49 GS71GS45 GS80 DI SI DR SR Figure 4. PAR capture ratio at different growth stages of the winter wheat. Values shown are the means over two years; the error bars represent the SE. D, double row planting pattern; S, single row planting pattern; I, irrigated; R, rainfed. Net photosynthetic rate (Pn), intercellular CO2 concentration (Ci), transpiration rate (Tr), and H2O conductance (Cond) At GS49 and GS71, Pn values in the flag leaves were similar for both DRPP and SRPP under irrigated conditions. However, under rainfed conditions, Pn values in DRPP were significantly higher than those in SRPP by 44.2% and 41.0%, respectively (p ≤ 0.05). From GS71 to GS80, photosynthetic rates decreased in both DRPP and SRPP. Under rainfed conditions, at GS80, Pn values in DRPP were significantly higher by 54.7% than those in SRPP (p ≤ 0.05). In terms of Ci, there was no significant difference between DRPP and SRPP under the same growing conditions (p > 0.05). Under irrigated conditions, the photosynthetic rate declined from GS71 to GS80 while the Ci of the flag leaves remained constant. However, under rainfed conditions, the Ci of the flag leaves increased by 120.0% between these two stages (Figure 5). Tr and Cond of irrigation were significantly higher than those of rainfed plants (p ≤ 0.05); Tr and Cond of DRPP were 51.1% and 36.1% higher than those of SRPP under rainfed conditions. Plants cultivated in the different patterns under the same planting density produced different dry matter amounts at the ripening stage (HAN et al., 2014). The dry matter accumulation is the ultimate product derived from the photosynthetic characteristics (MASONI et al., 2007). After GS49, the photosynthetic rate of flag leaves in DRPP was significantly higher than in SRPP under rainfed conditions. Thus, photosynthetic characteristics of DRPP showed an obvious advantage under rainfed conditions. Apparent quantum yields (AQY) of flag leaves The mean AQY of flag leaves under rainfed conditions was lower than that of irrigated conditions because of water stress (Figure 6). In SRPP, the AQY of flag leaves under rainfed conditions was 33.0% lower than under irrigated conditions. In DRPP, a difference of 23.6% was observed. The mean AQY of plants in DRPP was 7.9% higher than that in SRPP under irrigated conditions, but this difference was 23.0% under rainfed conditions. This observation indicates that DRPP under rainfed conditions had a higher AQY than under irrigated conditions. Grain yield and yield components The grain yields of DRPP were 6.7% (2011–2012) and 13.5% (2012–2013) higher than those of SRPP under irrigated conditions. The spike number of DRPP were 22.8% (2011–2012) and 25.5% (2012–2013) higher than those of SRPP, but the 1000-kernel weight were 1.4% (2011–2012) and 9.1% (2012–2013) lower in DRPP than those of SRPP, respectively (Table 2). Meanwhile, under rainfed conditions, the kernel number per spike and 1000-kernel weight of DRPP were higher than that of SRPP in 2011–2012, and the kernel number per spike and 1000-kernel weight were not significantly different between SRPP and DRPP in 2012–2013 (p > 0.05). However, in 2011–2012 and 2012–2013, the spike numbers of DRPP were 6.9% and 22.8% higher than those of SRPP, and the grain yields were significantly higher (by 11.3% and 11.0%) than that of SRPP, respectively (p ≤ 0.05). 6 Photosynthetic production… ZHANG, Z. et al. Biosci. J., Uberlândia, v. 33, n. 1, p. 1-9, Jan./Feb. 2017 C i (µ m o l C O 2 m o l- 1 ) 100 150 200 250 300 350 400 P n ( µ o m l m - 2 s -1 ) 0 5 10 15 20 25 30 35 Growth stage GS45 GS49 GS71 GS80 T r (m m o l H 2 O m - 2 s -1 ) 0 2 4 6 8 10 12 Growth stage GS45 GS49 GS71 GS80 C o n d ( m o l H 2 O m - 2 s -1 ) 0.0 .1 .2 .3 .4 .5 .6 DRPP-I SRPP-I DRPP-R SRPP-R Figure 5. Net photosynthetic rate (Pn), intercellular CO2 concentration (Ci), H2O conductance (Cond) and transpiration rate (Tr) at different growth stages of the winter wheat. Values shown are means over two years; the error bars represent the SE. SRPP, single row planting pattern; DRPP, double row planting pattern; I, irrigated; R, rainfed. Treatments DRPP-I SRPP-I DRPP-R SRPP-R A Q Y ( µ m o l C O 2 µ m o l P h o to n ) 0.00 .01 .02 .03 .04 .05 .06 .07 a ab bc c Figure 6. Apparent quantum yield (AQY) of flag leaves under irrigated (I) and rainfed (R) conditions. Values shown are means over two years; the error bars represent the SE. SRPP, single row planting pattern; DRPP, double row planting pattern. 7 Photosynthetic production… ZHANG, Z. et al. Biosci. J., Uberlândia, v. 33, n. 1, p. 1-9, Jan./Feb. 2017 Table 2. Grain yield and yield components of double row planting pattern (DRPP) and single row planting pattern (SRPP) under different water conditions. Treatments Spikes (m-2) Kernels (spike-1) 1000-kernel weight (g) Grain yield (g m-2) 2011–2012 Rainfed DRPP 678a 28.7a 35.4 703a SRPP 634b 24.2b 34.1 632b LSD0.05 44 2.3 NS 29 Irrigated DRPP 641a 27.8 34.3 781a SRPP 522b 27.2 34.8 732b LSD0.05 58 NS NS 34 2012–2013 Rainfed DRPP 693a 25.3 33.9 604a SRPP 582b 24.5 32.9 544b LSD0.05 112 NS NS 54 Irrigated DRPP 722a 26.5 37.8b 850a SRPP 575b 26.8 41.6a 749b LSD0.05 97 NS 3.0 61 Means with different letters in a column are significantly different (p ≤ 0.05) CONCLUSIONS The double-row planting pattern was better than the single-row planting pattern in terms of all traits. The double-row planting pattern increased the photosynthetic active radiation capture ratio at 50–120 cm above the ground, the photosynthetic rate, the transpiration rate, the H2O conductance, the apparent quantum yield, the grain yield, and the yield components under rainfed conditions. These results suggest that the double-row planting pattern can be extended to improve the wheat yield in the drought-prone areas of Northern China. ACKNOWLEDGMENTS The research was supported by the National High Technology Research and Development Program of China Project (2013AA102903), Guangxi Natural Science Foundation (2015GXNSFAA139049) and Starting Foundation for Doctors of Guangxi University (XBZ160072). RESUMO: O trigo de inverno (Triticum aestivum) é cultivado em uma vasta região; no entanto, a água é escassa durante a estação de crescimento do trigo na Planície do Norte da China. Assim, o trigo de inverno deve ser irrigado para manter um rendimento de grãos estável e elevado. O objetivo deste trabalho de campo foi o de desenvolver um padrão de plantação de precisão que conserve a água para o trigo de inverno que é cultivado na Planície do Norte da China com o propósito de explorar os benefícios da retenção de água e os efeitos na produtividade do trigo. Para isso, diversas variáveis de produção e índices fotossintéticos foram medidos, incluindo o número de hastes, o índice de área da folha (do inglês, LAI - leaf area index), a radiação fotossinteticamente disponível (do inglês, PAR - photosynthetically available radiation), taxa fotossintética líquida e o rendimento de grãos. O estudo foi conduzido durante as estações de crescimento do trigo de inverno em 2011-2012 e 2012-2013. O experimento incluiu um padrão de plantação em fila dupla (do inglês, DRPP - double-row planting pattern) e um padrão de plantação em fila única (do inglês, SRPP - single-row planting pattern), em ambos os casos ou foram irrigados artificialmente ou através da chuva (regadio e sequeiro). A área de cada lote de terra foi de 9 m2, e o delineamento experimental foi um de blocos aleatórios com três repetições. Todos os resultados foram analisados com uma ANOVA, um teste F, e um LSD (p ≤ 0.05) para a comparação das médias. As taxas de captura de PAR no DRPP foram maiores do que aquelas no SRPP a 50-120 cm acima do solo. As características fotossintéticas das folhas-bandeira (do inglês, flag leaves) sob condições de irrigação artificial não foram significativamente influenciadas pelo respectivo padrão de plantação. No entanto, num estágio de crescimento de 80% abaixo das condições de irrigação pela chuva, a taxa fotossintética média dentre as folhas-bandeira no DRPP foi maior que aquela observada no SRPP. Além disso, o DRPP sob condições de irrigação pela chuva foi mais suscetível ao aumento do rendimento quântico aparente (do inglês, AQY - apparent quantum yield) das folhas-bandeira do que o rendimento obtido através da irrigação artificial. Estes resultados sugerem que o DRPP otimiza a distribuição PAR do dossel no trigo de inverno e contribui para a manutenção de uma maior capacidade fotossintética nas folhas bandeira sob estresse hídrico (a condição de sequeiro). 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