Canopy Apparent Photosynthetic Characteristics and Yield of Two Spike-Type Wheat Cultivars in Response to Row Spacing under High Plant Density

doi:10.1371/journal.pone.0148582

. 2016 Feb 4;11(2):e0148582.

doi: 10.1371/journal.pone.0148582. eCollection 2016.

Canopy Apparent Photosynthetic Characteristics and Yield of Two Spike-Type Wheat Cultivars in Response to Row Spacing under High Plant Density

Tiening Liu^{1

2}, Zhenlin Wang³, Tie Cai^{1

2}

Affiliations

¹ Key Laboratory of Crop Physi-ecology and Tillage Science in Northwestern Loess Plateau, Ministry of Agriculture/College of Agronomy, Northwest A&F University, Yangling, 712100, Shaanxi, China.
² The Chinese Institute of Water-saving Agriculture, Northwest A&F University, Yangling, 712100, Shaanxi, China.
³ State Key Laboratory of Crop Biology, Agronomy College of Shandong Agricultural University, Taian, 271018, Shandong, China.

PMID: 26845330
PMCID: PMC4741391
DOI: 10.1371/journal.pone.0148582

Canopy Apparent Photosynthetic Characteristics and Yield of Two Spike-Type Wheat Cultivars in Response to Row Spacing under High Plant Density

Tiening Liu et al. PLoS One. 2016.

. 2016 Feb 4;11(2):e0148582.

doi: 10.1371/journal.pone.0148582. eCollection 2016.

Authors

Tiening Liu^{1

2}, Zhenlin Wang³, Tie Cai^{1

2}

Affiliations

¹ Key Laboratory of Crop Physi-ecology and Tillage Science in Northwestern Loess Plateau, Ministry of Agriculture/College of Agronomy, Northwest A&F University, Yangling, 712100, Shaanxi, China.
² The Chinese Institute of Water-saving Agriculture, Northwest A&F University, Yangling, 712100, Shaanxi, China.
³ State Key Laboratory of Crop Biology, Agronomy College of Shandong Agricultural University, Taian, 271018, Shandong, China.

PMID: 26845330
PMCID: PMC4741391
DOI: 10.1371/journal.pone.0148582

Abstract

In northern China, large-spike wheat (Triticum aestivum L) is considered to have significant potential for increasing yields due to its greater single-plant productivity despite its lower percentage of effective tillers, and increasing the plant density is an effective means of achieving a higher grain yield. However, with increases in plant density, the amount of solar radiation intercepted by lower strata leaves is decreased and the rate of leaf senescence is accelerated. Row spacing can be manipulated to optimize the plant spatial distribution under high plant density, therefore improving light conditions within the canopy. Consequently, field experiments were conducted from 2010 to 2012 to investigate whether changes in row spacing under high plant density led to differences in canopy apparent photosynthesis (CAP), individual leaf photosynthesis and grain yield. Two different spike-type winter wheat cultivars, Jimai22 (a small-spike cultivar as a control cultivar) and Wennong6 (a large-spike cultivar), were grown at a constant plant density of 3,600,000 plants ha(-1) (a relatively higher plant density) over a wide range of row spacing as follows: 5-cm row spacing (R0), 15-cm row spacing (R1), 25-cm conventional row spacing (R2), and 35-cm row spacing (R3). The two-year investigations revealed that increased row spacing exhibited a significantly higher light transmission ratio (LT), which improved light conditions within the canopy; however, excessive light leakage losses in R2 and R3 treatments were not favorable to improved irradiation energy utilization efficiency. Aboveground biomass accumulation was influenced by row spacing. Two spike-type wheat accumulated greater biomass under 15-cm row spacing compared to other row spacing treatments, although a markedly improved photosynthetic rate (PN), effective quantum yield of photosystem II (ΦPSII) and maximal efficiency of photosystem II photochemistry (Fv/Fm) in the penultimate and third leaves were observed in R2 and R3 treatments. At the same time, a longer duration of CAP and green leaf area was maintained in R1 during grain filling. Compared with conventional row spacing, Wennong6 in R1 treatment obtained 21.0% and 19.1% higher grain yield in 2011 and 2012, respectively, while for Jimai22 it increased by 11.3% and 11.4%, respectively. A close association of yield with CAP and LAI at mid-grain filling was observed. In conclusion, for the tested growing conditions, decreasing the row spacing to an optimal distance (15 cm) maintained a longer duration of LAI and CAP during grain filling, made a better coordination of group and individual leaf photosynthesis, and accumulated higher aboveground biomass, leading to a greater grain yield. In addition, Wennong6 had a more rational canopy architecture than Jimai22 (improved LT and higher LAI) and CAP under 15-cm row spacing, leading to a higher grain yield, which indicated that the large-spike type cultivar has the potential to obtain higher yields by increasing plant density through optimum row spacing allocation (15 cm).

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Conflict of interest statement

Competing Interests: The author have declared that no competing interests exist.

Figures

**Fig 1. Rainfall, maximum, minimum and mean temperatures (°C) recorded during the growing season (March to June) in 2010–2011 (A) and 2011–2012 (B).**

Fig 2. A schematic diagram showing R₀ (5-cm row spacing), R₁ (15-cm row spacing), R₂ (25-cm row spacing) and R₃ (35-cm row spacing) planting patterns at a density of 3,600,000 plants ha^-1 over two years.

**Fig 3. Effects of row spacing on canopy apparent photosynthesis (CAP) of two spike types of wheat under high plant density over a two-year period (2011 and 2012).**
R₀, R₁, R₂ and R₃ refer to 5-cm row spacing, 15-cm row spacing, 25-cm row spacing and 35-cm row spacing, respectively. The data are means ± standard error (n = 3). Vertical bars indicate the SE.

Fig 4. Effects of row spacing on photosynthetic rate (P_N) of flag (A,B,C,D), penultimate (E,F,G,H) and third leaves (I,J,K,L) of two spike types of wheat under high planting density over a two-year period (2011 and 2012).
R₀, R₁, R₂ and R₃ refer to 5-cm row spacing, 15-cm row spacing, 25-cm row spacing and 35-cm row spacing, respectively. Data are means ± standard error (SE; n = 3). Vertical bars indicate the SE.

Fig 5. Effects of row spacing on F_v/F_m (A,B,C,D) and Φ_PSII (E,F,G,H)of the flag, penultimate and third leaves of two spike types of wheat under high plant density over a two-year period (2011 and 2012).
R₀, R₁, R₂ and R₃ refer to 5-cm row spacing, 15-cm row spacing, 25-cm row spacing and 35-cm row spacing, respectively. Numbers 1, 2 and 3 refer to the flag, penultimate and third leaves, respectively. The data are means ± standard error (SE; n = 3). Vertical bars indicate SE.

**Fig 6. Effects of row spacing on leaf area index (LAI) of two spike types of wheat under high plant density over a two-year period (2011 and 2012).**
R₀, R₁, R₂ and R₃ refer to 5-cm row spacing, 15-cm row spacing, 25-cm row spacing and 35-cm row spacing, respectively. The data are means ± standard error (SE; n = 3). Different small letters in each group indicate significant differences at P<0.05.

**Fig 7. Effects of row spacing on light transmission ratio (LT) at mid-grain filling of two spike types of wheat under high planting density over a two-year period (2011 and 2012).**
R₀, R₁, R₂ and R₃ refer to 5-cm row spacing, 15-cm row spacing, 25-cm row spacing and 35-cm row spacing, respectively. F-layer, P-layer, T-layer and B-layer indicate flag leaf layer, penultimate leaf layer, third leaf layer and bottom leaf layer, respectively. Data are means ± standard error (SE; n = 3). Vertical bars indicate the SE.

**Fig 8. Relationships between LAI (A), CAP (B) at mid-grain filling stage and yield of two spike types of wheat under high plant density.**
Correlation coefficients (R) were calculated, and asterisks (**) represent the significance at the 0.01 probability level (n = 24).

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References

1. Wang ZF, Wu K, Song LZ, Wang SH, Fan ZX, Zhang FY, et al. (2001) Analysis of yield elements for super high-yielding wheat varieties with different spike-type and selection strategy in Shandong Province. Shandong Agricultural Sciences 4: 6–8.
1. Xu HY, Wang QC, Zhao JS, Xu QZ, Gong XL, Wang ZX (1996) Population photosynthetic ability of wheat and maize to get 15 t/ha grains and comprehensive techniques. Shandong Agricultural Sciences 1: 14–20.
1. Zhu YJ, Guo RL, Guo TC, Zhang QY, Wang ZJ, Wang YH (2001) Effects of spacing form and density on quality of population and grain yield of Lankao906. Journal of Triticeae Crops 21: 62–66.
1. Maddonni GA, Otegui ME, Cirilo AG (2001a) Plant population density, row spacing and hybrid effects on maize canopy architecture and light attenuation. Field Crops Research 71: 183–193.
1. Liu TD, Song FB (2012) Maize photosynthesis and microclimate within the canopies at grain-filling stage in response to narrow-wide row planting patterns. Photosynthetica 50: 1–8.

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This research was supported by the National Basic Research Program of China (973 Program, No. 2009CB118602) and Twelfth Five-Year Science and Technology Support Plan of the People’s Republic of China (2015BAD22B02). The funders had no role in study design, data collection and analysis, decision to publish, or preparation of the manuscript.

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[1] Wang ZF, Wu K, Song LZ, Wang SH, Fan ZX, Zhang FY, et al. (2001) Analysis of yield elements for super high-yielding wheat varieties with different spike-type and selection strategy in Shandong Province. Shandong Agricultural Sciences 4: 6–8.

[2] Wang ZF, Wu K, Song LZ, Wang SH, Fan ZX, Zhang FY, et al. (2001) Analysis of yield elements for super high-yielding wheat varieties with different spike-type and selection strategy in Shandong Province. Shandong Agricultural Sciences 4: 6–8.

[3] Xu HY, Wang QC, Zhao JS, Xu QZ, Gong XL, Wang ZX (1996) Population photosynthetic ability of wheat and maize to get 15 t/ha grains and comprehensive techniques. Shandong Agricultural Sciences 1: 14–20.

[4] Xu HY, Wang QC, Zhao JS, Xu QZ, Gong XL, Wang ZX (1996) Population photosynthetic ability of wheat and maize to get 15 t/ha grains and comprehensive techniques. Shandong Agricultural Sciences 1: 14–20.

[5] Zhu YJ, Guo RL, Guo TC, Zhang QY, Wang ZJ, Wang YH (2001) Effects of spacing form and density on quality of population and grain yield of Lankao906. Journal of Triticeae Crops 21: 62–66.

[6] Zhu YJ, Guo RL, Guo TC, Zhang QY, Wang ZJ, Wang YH (2001) Effects of spacing form and density on quality of population and grain yield of Lankao906. Journal of Triticeae Crops 21: 62–66.

[7] Maddonni GA, Otegui ME, Cirilo AG (2001a) Plant population density, row spacing and hybrid effects on maize canopy architecture and light attenuation. Field Crops Research 71: 183–193.

[8] Maddonni GA, Otegui ME, Cirilo AG (2001a) Plant population density, row spacing and hybrid effects on maize canopy architecture and light attenuation. Field Crops Research 71: 183–193.

[9] Liu TD, Song FB (2012) Maize photosynthesis and microclimate within the canopies at grain-filling stage in response to narrow-wide row planting patterns. Photosynthetica 50: 1–8.

[10] Liu TD, Song FB (2012) Maize photosynthesis and microclimate within the canopies at grain-filling stage in response to narrow-wide row planting patterns. Photosynthetica 50: 1–8.

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Canopy Apparent Photosynthetic Characteristics and Yield of Two Spike-Type Wheat Cultivars in Response to Row Spacing under High Plant Density

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Canopy Apparent Photosynthetic Characteristics and Yield of Two Spike-Type Wheat Cultivars in Response to Row Spacing under High Plant Density

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