Characterizing Changes from a Century of Genetic Improvement of Soybean Cultivars in Northeast China

Wu, Tingting; Sun, Shi; Wang, Caijie; Wen-cheng, LU; Sun, Bincheng; Song, Xiqing; Han, Xianpei; Tai, Guo; Man, Wei–Qun; Cheng, Yongqiang; Niu, Jianguang; Fu, Lixin; Song, Wenwen; Jiang, Bingjun; Hou, Wensheng; Wu, Cunxiang; Han, Tianfu

doi:10.2135/cropsci2015.01.0023

Cited by 28 publications

(24 citation statements)

References 27 publications

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“…Our database, primarily from small‐plot experiments, showed similar yield gain per year to the 25.8 kg ha −1 yr −1 reported by FAO between 1960 and 2014 (FAO, 2017). Historical time trends for soybean yield average increase have been documented in the United States (23 kg ha −1 yr −1 ; Long, 2013; Rowntree et al, 2013; Specht et al, 2014; Wilson et al, 2014), China (11 kg ha −1 yr −1 ; Wu et al, 2015), Argentina (44.33 kg ha −1 yr −1 ; de Felipe et al, 2016), and Brazil (41 kg ha −1 yr −1 ; de Toledo, 1990). Our database indicates that yield improvement was mostly associated with increased biomass and little or no change in HI, in agreement with previous studies (Schapaugh and Wilcox, 1980; Spaeth et al, 1984; Johnson and Major, 1986).…”

Section: Discussionmentioning

confidence: 99%

Shifts in Soybean Yield, Nutrient Uptake, and Nutrient Stoichiometry: A Historical Synthesis‐Analysis

2018

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Few studies have investigated changes over time in nutrient uptake and yield, in addition to the study of nutrient stoichiometry as a metric of nutrient limitations in soybean [Glycine max (L.) Merr.]. A comprehensive synthesis‐analysis was performed by compiling a global historical soybean database of yield, total biomass, and nutrient (N, P, and K) content and concentration in studies published from 1922 to 2015. This period was divided in three eras based on genetically modified soybean events: Era I (1922–1996), Era II (1997–2006), and Era III (2007–2015). The main findings of this review are: (i) seed yield improved from 1.3 Mg ha−1 in the 1930s to 3.2 Mg ha−1 in the 2010s; (ii) yield increase was primarily driven by increase in biomass rather than harvest index (HI); (iii) both N and P HIs increased over time; (iv) seed nutrient concentration remained stable for N and declined for both P (18%) and K (13%); (v) stover nutrient concentration remained stable for N, diminished for P, and increased for K; (vi) nutrient ratios portray different trends for N/P (Era I and III > II), N/K (Era I > II and III), and K/P (Era II and III > I); (vii) yield per unit of nutrient uptake (internal efficiency) increased for N (33%) and P (44%) and decreased for K (11%); and (viii) variations in nutrient internal efficiency were primarily explained by increase in nutrient HI for N and K, but equally explained by both HI for P and seed P concentration. These findings have implications for soybean production and integrated nutrient management to improve yield, nutrient use efficiency, and seed nutrient composition.

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Section: Discussionmentioning

confidence: 99%

Shifts in Soybean Yield, Nutrient Uptake, and Nutrient Stoichiometry: A Historical Synthesis‐Analysis

2018

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“…Our previous studies on changing trends in agronomic traits in these widely grown soybean cultivars indicated that, in North East China, newer cultivars had earlier flowering, shorter plants with fewer branches, higher lodging resistance and higher yields per plant than older cultivars, and in the YHH region, modern cultivars had shorter plants, fewer nodes, higher lodging resistance, more seeds per pod and heavier seeds than older cultivars (Wu et al 2015;Wang et al 2016). These results may shed light on strategies for soybean root improvement in different production regions.…”

Section: Suggestions For Root-trait Improvement In Soybean Breedingmentioning

confidence: 97%

“…In the past century through to 2015, more than 2400 soybean cultivars were developed in China (Wang et al 2016). During this time, yield, agronomic and phenological traits of soybean have markedly improved (Zheng et al 2006;Tian et al 2007;Zhao et al 2008Zhao et al , 2012Xu et al 2011;Wang et al 2015;Wu et al 2015;Qin et al 2017). Modern soybean varieties tend to have greater root weight, root volume, root surface and lateral root length than older varieties (Yang et al 2001).…”

Section: Introductionmentioning

confidence: 99%

Evaluation by grafting technique of changes in the contribution of root-to-shoot development and biomass production in soybean (Glycine max) cultivars released from 1929 to 2006 in China

Cao

Sun

et al. 2019

Crop Pasture Sci.

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Root traits are essential for optimising nutrient and water absorption and anchorage. However, changes in root traits and the contribution of root-to-shoot growth and development of soybean (Glycine max (L.) Merr.) across a century of breeding are poorly documented. In this study, we adopted a grafting technique, using 55 cultivars released in the three main soybean-production regions in China as rootstocks in a pot experiment and 24 cultivars from the Yellow-Huai-Hai Valley (YHH) region as rootstocks in a field experiment, with cv. Zigongdongdou as the common scion. Changes in soybean roots, including dry weight (DW) of roots, lateral root number (LRN) and taproot length (TRL), and their contribution to shoot development and biomass formation, including shoot DW, plant height and node number, were evaluated under optimal conditions in 2011. Aboveground traits declined with year of release in the YHH region and did not vary over time in the northern Heilongjiang province and mid-south Heilongjiang region except for shoot DW. The root traits root DW, LRN and TRL were similar over years of release in the pot and field experiments. The results suggest that the newer cultivars have lesser shoot growth and root capacity but the same amount of root growth as older cultivars. Root traits did not change during selection, suggesting that improvement in soybean root traits should be an aim in future breeding.

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“…To determine the genetic basis of yield increase, cultivars released in different years should be sown in a common environment (Specht et al, 1999;De Bruin e Pedersen, 2008;. Such research carried out in several soybean-producing countries has shown plant-specific morphophysiological changes for each site because of yield improvement Yu et al, 2009;Jin et al, 2010;Koester et al, 2016;Wu et al, 2015). The increase of soybean yield in Brazil, carried out through breeding, was not accompanied by researches that could clarify the morphophysiological changes that occurred in the plant, and their contribution to the main objective of breeding.…”

Section: Introductionmentioning

confidence: 99%

“…Modern North American soybean cultivars partition more carbohydrates into grains(Koester et al, 2014). In this context, among the yield components that contributed most to yield increase was the number of grains per plant, both in Chinese(Jin et al, 2010;Wu et al, 2015) and in North American(De Bruin e Pedersen, 2008; cultivars.…”

mentioning

confidence: 99%

How breeding of Brazilian soybean cultivars modified morphophysiological attributes of plants?

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Characterizing Changes from a Century of Genetic Improvement of Soybean Cultivars in Northeast China

Cited by 28 publications

References 27 publications

Shifts in Soybean Yield, Nutrient Uptake, and Nutrient Stoichiometry: A Historical Synthesis‐Analysis

Shifts in Soybean Yield, Nutrient Uptake, and Nutrient Stoichiometry: A Historical Synthesis‐Analysis

Evaluation by grafting technique of changes in the contribution of root-to-shoot development and biomass production in soybean (Glycine max) cultivars released from 1929 to 2006 in China

How breeding of Brazilian soybean cultivars modified morphophysiological attributes of plants?

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