Your search keyword '"Du Wenli"' showing total 9 results

1. Study on Light Interception and Biomass Production of Different Cotton Cultivars

Author

Fan Zhengyi, Du Wenli, Yingchun Han, Zhigang Bai, Yang Beifang, Shuchun Mao, Yabing Li, Lu Feng, Guoping Wang, Yaping Lei, and Zhi Xiaoyu

Subjects

0106 biological sciences, Canopy, Leaves, Light, lcsh:Medicine, Cotton, Plant Science, 01 natural sciences, Biochemistry, Plant Products, Cultivar, Biomass, Photosynthesis, lcsh:Science, Plant Growth and Development, Biomass (ecology), Numerical Analysis, Multidisciplinary, Plant Biochemistry, Plant Anatomy, Physics, Electromagnetic Radiation, Agriculture, 04 agricultural and veterinary sciences, Built Structures, Spatial heterogeneity, Photosynthetically active radiation, Physical Sciences, Engineering and Technology, Solar Radiation, Interception, Research Article, Structural Engineering, Crops, Biology, Leaf area index, Gossypium, lcsh:R, Biology and Life Sciences, Fiber Crops, Radiobiology, Plant community, Agronomy, Interpolation, Plant Leaves, 040103 agronomy & agriculture, 0401 agriculture, forestry, and fisheries, lcsh:Q, Mathematics, 010606 plant biology & botany, Crop Science, Developmental Biology

Abstract

Identifying the characteristics of light interception and utilization is of great significance for improving the potential photosynthetic activity of plants. The present research investigates the differences in absorbing and converting photosynthetically active radiation (PAR) among various cotton cultivars. Field experiments were conducted in 2012, 2013 and 2014 in Anyang, Henan, China. Ten cultivars with different maturity and plant architectures were planted at a density of 60,000 plants ha-1 in randomized blocks, with three replicates. The spatial distribution of light in canopy was measured and quantified with a geo-statistical method, according to which the cumulative amount of intercepted radiation was calculated by Simpson 3/8 rules. Finally, light interception was analyzed in association with the biomass accumulation of different cultivars. The key results were: (1) late-maturing varieties with an incompact plant architecture captured more solar radiation throughout the whole growth period than middle varieties with columnar architecture and even more than early varieties with compact architecture, and they produced more biomass; (2) the highest PAR interception ratio and the maximum biomass accumulation rate occurred during the blossoming and boll-forming stage, when leaf area index (LAI) reached its peak; (3) the distribution within the canopy presented a significant spatial heterogeneity, and at late growing stage, the PAR was mainly intercepted by upper canopies in incompact-type plant communities, but was more homogeneous in columnar-type plants; however, the majority of radiation was transmitted through the canopy in compact-type colonies; (4) there was not a consistent variation relationship between the cumulative intercepted PAR (iPAR) and biomass among these cultivars over the three years of the study. Based on these results, we attempted to clarify the distinction in light spatial distribution within different canopies and the patterns of PAR interception in diverse cotton cultivars with different hereditary characters, thereby providing a significant basis for researchers to select cultivars with appropriate growth period and optimal plant architecture for improvement of light interception and utilization.

Published

2016

2. Root growth and spatial distribution characteristics for seedlings raised in substrate and transplanted cotton

Author

Lu Feng, Fan Zhengyi, Guoping Wang, Zhi Xiaoyu, Yabing Li, Yingchun Han, Yaping Lei, Shuchun Mao, Yang Beifang, and Du Wenli

Subjects

0106 biological sciences, Randomized block design, lcsh:Medicine, Soil Science, Crops, Cotton, Plant Science, Horticulture, Gossypium, Plant Roots, 01 natural sciences, Nutrient, Agricultural Soil Science, Transplanting, Biomass, lcsh:Science, Flowering Plants, Plant Growth and Development, Multidisciplinary, biology, Plant Anatomy, lcsh:R, Ecology and Environmental Sciences, Organisms, Biology and Life Sciences, Eukaryota, Fiber Crops, Sowing, Agriculture, 04 agricultural and veterinary sciences, Plants, biology.organism_classification, Agronomy, Root Growth, Lateral Roots, Agricultural soil science, Seedlings, Seedling, 040103 agronomy & agriculture, 0401 agriculture, forestry, and fisheries, lcsh:Q, Planting, Mulch, Research Article, Crop Science, Developmental Biology, 010606 plant biology & botany

Abstract

In this study, transplanting cotton seedlings grown in artificial substrate is considered due to recent increased interest in cotton planting labor saving approaches. The nursery methods used for growing cotton seedlings affect root growth. However, the underlying functional responses of root growth to variations in cotton seedling transplanting methods are poorly understood. We assessed the responses of cotton (Gossypium hirsutum L.) roots to different planting methods by conducting cotton field experiments in 2012 and 2013. A one-factor random block design was used with three replications and three different cotton planting patterns (substrate seedling transplanted cotton (SSTC), soil-cube seedling transplanted cotton (ScSTC) and directly sown cotton (DSC). The distributions and variances of the root area density (RAD) and root length density (RLD) at different cotton growing stages and several yield components were determined. Overall, the following results were observed: 1) The RAD and RLD were greatest near the plants (a horizontal distance of 0 cm) but were lower at W20 and W40 cm in the absence of film mulching than at E20 and E40 cm with film mulching. 2) The roots were confined to shallow depths (20-40 cm), and the root depths of SSTC and DSC were greater than the root depths of ScSTC. 3) Strong root growth was observed in the SSTC at the cotton flowering and boll setting stages. In addition, early onset root growth occurred in the ScSTC, and vigorous root growth occurred throughout all cotton growth stages in DSC. 4) The SSTC plants had more lateral roots with higher root biomass (RB) than the ScSTC, which resulted in higher cotton yields. However, the early onset root growth in the ScSTC resulted in greater pre-frost seed cotton (PFSC) yields. These results can be used to infer how cotton roots are distributed in soils and capture nutrients.

Published

2017

3. Adjusting cotton planting density under the climatic conditions of Henan Province, China.

Author

Liu, Liyuan, Li, Chuanzong, Han, Yingchun, Wang, Zhanbiao, Feng, Lu, Zhi, Xiaoyu, Yang, Beifang, Lei, Yaping, Du, Wenli, and Li, Yabing

Subjects

PLANT spacing, COTTON quality, LEAF area index, COTTON growing, COTTON, SEED yield, COTTON yields, COTTONSEED

Abstract

The growth and development of cotton are closely related to climatic variables such as temperature and solar radiation. Adjusting planting density is one of the most effective measures for maximizing cotton yield under certain climatic conditions. The objectives of this study were (1) to determine the optimum planting density and the corresponding leaf area index (LAI) and yield under the climatic conditions of Henan Province, China, and (2) to learn how climatic conditions influence cotton growth, yield, and yield components. A three-year (2013–2015) field experiment was conducted in Anyang, Henan Province, using cultivar SCRC28 across six planting density treatments: 15,000, 33,000, 51,000, 69,000, 87,000, and 105,000 plants ha−1. The data showed that the yield attributes, including seed cotton yield, lint yield, dry matter accumulation, and the LAI, increased as planting density increased. Consequently, the treatment of the maximum density with 105,000 plants ha-1 was the highest-yielding over three years, with the LAIs averaged across the three years being 0.37 at the bud stage, 2.36 at the flower and boll-forming stage, and 1.37 at the boll-opening stage. Furthermore, the correlation between the cotton yield attributes and meteorological conditions indicated that light interception (LI) and the diurnal temperature range were the climatic factors that most strongly influenced cotton seed yield. Moreover, the influence of the number of growing degree days (GDD) on cotton was different at different growth stages. These observations will be useful for determining best management practices for cotton production under the climatic conditions of Henan Province, China. [ABSTRACT FROM AUTHOR]

Published

2019

4. Root growth and spatial distribution characteristics for seedlings raised in substrate and transplanted cotton.

Author

Zhi, Xiaoyu, Han, Yingchun, Li, Yabing, Wang, Guoping, Feng, Lu, Yang, Beifang, Fan, Zhengyi, Lei, Yaping, Du, Wenli, and Mao, Shuchun

Subjects

ROOT growth, SEEDLINGS, COTTON, PLANTING, EXPERIMENTAL agriculture

Abstract

In this study, transplanting cotton seedlings grown in artificial substrate is considered due to recent increased interest in cotton planting labor saving approaches. The nursery methods used for growing cotton seedlings affect root growth. However, the underlying functional responses of root growth to variations in cotton seedling transplanting methods are poorly understood. We assessed the responses of cotton (Gossypium hirsutum L.) roots to different planting methods by conducting cotton field experiments in 2012 and 2013. A one-factor random block design was used with three replications and three different cotton planting patterns (substrate seedling transplanted cotton (SSTC), soil-cube seedling transplanted cotton (ScSTC) and directly sown cotton (DSC). The distributions and variances of the root area density (RAD) and root length density (RLD) at different cotton growing stages and several yield components were determined. Overall, the following results were observed: 1) The RAD and RLD were greatest near the plants (a horizontal distance of 0 cm) but were lower at W20 and W40 cm in the absence of film mulching than at E20 and E40 cm with film mulching. 2) The roots were confined to shallow depths (20–40 cm), and the root depths of SSTC and DSC were greater than the root depths of ScSTC. 3) Strong root growth was observed in the SSTC at the cotton flowering and boll setting stages. In addition, early onset root growth occurred in the ScSTC, and vigorous root growth occurred throughout all cotton growth stages in DSC. 4) The SSTC plants had more lateral roots with higher root biomass (RB) than the ScSTC, which resulted in higher cotton yields. However, the early onset root growth in the ScSTC resulted in greater pre-frost seed cotton (PFSC) yields. These results can be used to infer how cotton roots are distributed in soils and capture nutrients. [ABSTRACT FROM AUTHOR]

Published

2017

5. Light Spatial Distribution in the Canopy and Crop Development in Cotton

Author

Guoping Wang, Yabing Li, Shuchun Mao, Zhi Xiaoyu, Lu Jianhua, Yingchun Han, Fan Zhengyi, Du Wenli, Lu Feng, and Yang Beifang

Subjects

Canopy, Light, Randomized block design, lcsh:Medicine, Crops, Cotton, Spatial distribution, Crop, Plant Products, Botany, Biomass, Plant breeding, Photosynthesis, Leaf area index, lcsh:Science, Mathematics, Gossypium, Multidisciplinary, lcsh:R, Biology and Life Sciences, Fiber Crops, Agriculture, Ideotype, Agronomy, Plant Leaves, Photosynthetically active radiation, lcsh:Q, Algorithms, Research Article, Crop Science

Abstract

The partitioning of light is very difficult to assess, especially in discontinuous or irregular canopies. The aim of the present study was to analyze the spatial distribution of photosynthetically active radiation (PAR) in a heterogeneous cotton canopy based on a geo-statistical sampling method. Field experiments were conducted in 2011 and 2012 in Anyang, Henan, China. Field plots were arranged in a randomized block design with the main plot factor representing the plant density. There were 3 replications and 6 densities used in every replicate. The six plant density treatments were 15,000, 33,000, 51,000, 69,000, 87,000 and 105,000 plants ha(-1). The following results were observed: 1) transmission within the canopy decreased with increasing density and significantly decreased from the top to the bottom of the canopy, but the greatest decreases were observed in the middle layers of the canopy on the vertical axis and closing to the rows along the horizontal axis; 2) the transmitted PAR (TPAR) of 6 different cotton populations decreased slowly and then increased slightly as the leaves matured, the TPAR values were approximately 52.6-84.9% (2011) and 42.7-78.8% (2012) during the early cotton developmental stage, and were 33.9-60.0% (2011) and 34.5-61.8% (2012) during the flowering stage; 3) the Leaf area index (LAI) was highly significant exponentially correlated (R(2) = 0.90 in 2011, R(2) = 0.91 in 2012) with the intercepted PAR (IPAR) within the canopy; 4) and a highly significant linear correlation (R(2) = 0.92 in 2011, R(2) = 0.96 in 2012) was observed between the accumulated IPAR and the biomass. Our findings will aid researchers to improve radiation-use efficiency by optimizing the ideotype for cotton canopy architecture based on light spatial distribution characteristics.

Published

2014

6. Study on Light Interception and Biomass Production of Different Cotton Cultivars.

Author

Bai, Zhigang, Mao, Shuchun, Han, Yingchun, Feng, Lu, Wang, Guoping, Yang, Beifang, Zhi, Xiaoyu, Fan, Zhengyi, Lei, Yaping, Du, Wenli, and Li, Yabing

Subjects

LIGHT interception by plants, COTTON varieties, PLANT biomass, PHOTOSYNTHETICALLY active radiation (PAR), LEAF area index, PLANT canopies

Abstract

Identifying the characteristics of light interception and utilization is of great significance for improving the potential photosynthetic activity of plants. The present research investigates the differences in absorbing and converting photosynthetically active radiation (PAR) among various cotton cultivars. Field experiments were conducted in 2012, 2013 and 2014 in Anyang, Henan, China. Ten cultivars with different maturity and plant architectures were planted at a density of 60,000 plants ha-1 in randomized blocks, with three replicates. The spatial distribution of light in canopy was measured and quantified with a geo-statistical method, according to which the cumulative amount of intercepted radiation was calculated by Simpson 3/8 rules. Finally, light interception was analyzed in association with the biomass accumulation of different cultivars. The key results were: (1) late-maturing varieties with an incompact plant architecture captured more solar radiation throughout the whole growth period than middle varieties with columnar architecture and even more than early varieties with compact architecture, and they produced more biomass; (2) the highest PAR interception ratio and the maximum biomass accumulation rate occurred during the blossoming and boll-forming stage, when leaf area index (LAI) reached its peak; (3) the distribution within the canopy presented a significant spatial heterogeneity, and at late growing stage, the PAR was mainly intercepted by upper canopies in incompact-type plant communities, but was more homogeneous in columnar-type plants; however, the majority of radiation was transmitted through the canopy in compact-type colonies; (4) there was not a consistent variation relationship between the cumulative intercepted PAR (iPAR) and biomass among these cultivars over the three years of the study. Based on these results, we attempted to clarify the distinction in light spatial distribution within different canopies and the patterns of PAR interception in diverse cotton cultivars with different hereditary characters, thereby providing a significant basis for researchers to select cultivars with appropriate growth period and optimal plant architecture for improvement of light interception and utilization. [ABSTRACT FROM AUTHOR]

Published

2016

7. Dynamic Quantitative Trait Locus Analysis of Seed Vigor at Three Maturity Stages in Rice.

Author

Liu, Liangfeng, Lai, Yanyan, Cheng, Jinping, Wang, Ling, Du, Wenli, Wang, Zhoufei, and Zhang, Hongsheng

Subjects

QUANTITATIVE genetics, RICE seeds, RICE genetics, SEED quality, GERMINATION, ALLELES in plants, PHENOTYPES

Abstract

Seed vigor is an important characteristic of seed quality. In this study, one rice population of recombinant inbred lines (RILs) was used to determine the genetic characteristics of seed vigor, including the germination potential, germination rate, germination index and time for 50% of germination, at 4 (early), 5 (middle) and 6 weeks (late) after heading in two years. A total of 24 additive and 9 epistatic quantitative trait loci (QTL) for seed vigor were identified using QTL Cartographer and QTLNetwork program respectively in 2012; while 32 simple sequence repeat (SSR) markers associated with seed vigor were detected using bulked segregant analysis (BSA) in 2013. The additive, epistatic and QTL × development interaction effects regulated the dry maturity developmental process to improve seed vigor in rice. The phenotypic variation explained by each additive, epistatic QTL and QTL × development interaction ranged from 5.86 to 40.67%, 4.64 to 11.28% and 0.01 to 1.17%, respectively. The QTLs were rarely co-localized among the different maturity stages; more QTLs were expressed at the early maturity stage followed by the late and middle stages. Twenty additive QTLs were stably expressed in two years which might play important roles in establishment of seed vigor in different environments. By comparing chromosomal positions of these stably expressed additive QTLs with those previously identified, the regions of QTL for seed vigor are likely to coincide with QTL for grain size, low temperature germinability and seed dormancy; while 5 additive QTL might represent novel genes. Using four selected RILs, three cross combinations of seed vigor for the development of RIL populations were predicted; 19 elite alleles could be pyramided by each combination. [ABSTRACT FROM AUTHOR]

Published

2014

8. Light Spatial Distribution in the Canopy and Crop Development in Cotton.

Author

Zhi, Xiaoyu, Han, Yingchun, Mao, Shuchun, Wang, Guoping, Feng, Lu, Yang, Beifang, Fan, Zhengyi, Du, Wenli, Lu, Jianhua, and Li, Yabing

Subjects

CROP growth, COTTON yields, EFFECT of light on plants, AGRONOMY, CROP science, EXPERIMENTAL agriculture

Abstract

The partitioning of light is very difficult to assess, especially in discontinuous or irregular canopies. The aim of the present study was to analyze the spatial distribution of photosynthetically active radiation (PAR) in a heterogeneous cotton canopy based on a geo-statistical sampling method. Field experiments were conducted in 2011 and 2012 in Anyang, Henan, China. Field plots were arranged in a randomized block design with the main plot factor representing the plant density. There were 3 replications and 6 densities used in every replicate. The six plant density treatments were 15,000, 33,000, 51,000, 69,000, 87,000 and 105,000 plants ha−1. The following results were observed: 1) transmission within the canopy decreased with increasing density and significantly decreased from the top to the bottom of the canopy, but the greatest decreases were observed in the middle layers of the canopy on the vertical axis and closing to the rows along the horizontal axis; 2) the transmitted PAR (TPAR) of 6 different cotton populations decreased slowly and then increased slightly as the leaves matured, the TPAR values were approximately 52.6–84.9% (2011) and 42.7–78.8% (2012) during the early cotton developmental stage, and were 33.9–60.0% (2011) and 34.5–61.8% (2012) during the flowering stage; 3) the Leaf area index (LAI) was highly significant exponentially correlated (R2 = 0.90 in 2011, R2 = 0.91 in 2012) with the intercepted PAR (IPAR) within the canopy; 4) and a highly significant linear correlation (R2 = 0.92 in 2011, R2 = 0.96 in 2012) was observed between the accumulated IPAR and the biomass. Our findings will aid researchers to improve radiation-use efficiency by optimizing the ideotype for cotton canopy architecture based on light spatial distribution characteristics. [ABSTRACT FROM AUTHOR]

Published

2014

9. Dynamic Quantitative Trait Loci Analysis of Seed Reserve Utilization during Three Germination Stages in Rice.

Author

Cheng, Xinxin, Cheng, Jinping, Huang, Xi, Lai, Yanyan, Wang, Ling, Du, Wenli, Wang, Zhoufei, and Zhang, Hongsheng

Subjects

GERMINATION, RICE industry, PLANT genetics, GENE expression in plants, BIOMARKERS

Abstract

In this study, one rice population of recombinant inbred lines (RILs) was used to determine the genetic characteristics of seed reserve utilization during the early (day 6), middle (day 10) and late (day 14) germination stages. The seedling dry weight (SDW) and weight of the mobilized seed reserve (WMSR) were increased, while the seed reserve utilization efficiency (SRUE) decreased, during the process of seed germination. The SDW and WMSR were affected by the seed weight, while the SRUE was not affected by the seed weight. A total of twenty unconditional and twenty-one conditional additive QTLs and eight epistatic QTLs were identified at three germination stages, and the more QTLs were expressed at the late germination stage. Among them, twelve additive and three epistatic QTLs for SDW, eight additive and three epistatic QTLs for WMSR and thirteen additive and two epistatic QTLs for SRUE were identified, respectively. The phenotypic variation explained by each additive QTL, epistatic QTL and QTL × development interaction ranged from 6.10 to 23.91%, 1.79 to 6.88% and 0.22 to 2.86%, respectively. Two major additive QTLs qWMSR7.1 and qSRUE4.3 were identified, and each QTL could explain more than 20% of the total phenotypic variance. By comparing the chromosomal positions of these additive QTLs with those previously identified, eleven QTLs might represent novel genes. The best four cross combinations of each trait for the development of RIL populations were selected. The selected RILs and the identified QTLs might be applicable to improve rice seed reserve utilization by the marker-assisted selection approach. [ABSTRACT FROM AUTHOR]

Published

2013