Effect of Drought Stress during Soybean R2–R6 Growth Stages on Sucrose Metabolism in Leaf and Seed

Du, Yanli; Zhao, Qiang; Chen, Li–Ru; Yao, Xingdong; Zhang, Huijun; Wu, Jianzhong; Xie, Futi

doi:10.3390/ijms21020618

Cited by 101 publications

(76 citation statements)

References 57 publications

(111 reference statements)

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“…In this way, the accumulation of sucrose in sink tissues increases, resulting in a decreased hexose-to-sucrose ratio. In addition, drought stress increases the expression and the activities of acid invertase enzymes in the leaves, leading to irreversible hydrolysis into glucose and fructose [ 59 , 60 ].…”

Section: Discussionmentioning

confidence: 99%

Leaf Soluble Sugars and Free Amino Acids as Important Components of Abscisic Acid—Mediated Drought Response in Tomato

Živanović

Komić

Tosti

et al. 2020

Plants

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Water deficit has a global impact on plant growth and crop yield. Climate changes are going to increase the intensity, duration and frequency of severe droughts, particularly in southern and south-eastern Europe, elevating the water scarcity issues. We aimed to assess the contribution of endogenous abscisic acid (ABA) in the protective mechanisms against water deficit, including stomatal conductance, relative water potential and the accumulation of osmoprotectants, as well as on growth parameters. To achieve that, we used a suitable model system, ABA-deficient tomato mutant, flacca and its parental line. Flacca mutant exhibited constitutively higher levels of soluble sugars (e.g., galactose, arabinose, sorbitol) and free amino acids (AAs) compared with the wild type (WT). Water deficit provoked the strong accumulation of proline in both genotypes, and total soluble sugars only in flacca. Upon re-watering, these osmolytes returned to the initial levels in both genotypes. Our results indicate that flacca compensated higher stomatal conductance with a higher constitutive level of free sugars and AAs. Additionally, we suggest that the accumulation of AAs, particularly proline and its precursors and specific branched-chain AAs in both, glucose and sucrose in flacca, and sorbitol in WT, could contribute to maintaining growth rate during water deficit and recovery in both tomato genotypes.

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Section: Discussionmentioning

confidence: 99%

Leaf Soluble Sugars and Free Amino Acids as Important Components of Abscisic Acid—Mediated Drought Response in Tomato

Živanović

Komić

Tosti

et al. 2020

Plants

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“…Plants subjected to drought stress usually have accumulated soluble sugars, including sucrose, stored in their source leaves ( Figure 3 ). The accumulation of this stored sucrose in the source leaves act as an imperative energy derivative strategy which improves plant tolerance to drought stress condition [ 142 ]. Interestingly, sucrose could also be accumulated in the leaves if there is a low demand for sucrose at the sink cell [ 136 ].…”

Section: Influence Of Environmental Factors On Photo-assimilate Transportmentioning

confidence: 99%

“…This is an indication of increased capacity of sucrose unloading into seeds and activation of sucrose metabolism during the early seed developmental stage under a drought-stress condition [ 138 ]. However, during late seed-filling stages, basipetal sucrose flow from source leaves to seed decreased, leading to an impaired supply of seed (sink) metabolic need, and thus reduced seed weight or yield [ 142 ]. Since these transporters trigger sucrose export from source leaves to the root (sink), especially during the early plant-developmental stage, enhancing sucrose transport to the root is promising to optimize root development under drought stress [ 138 ].…”

Section: Functional Roles Of Sugar Transporters In Mitigating Environmental Stressmentioning

confidence: 99%

Sucrose Utilization for Improved Crop Yields: A Review Article

Aluko

Wang

et al. 2021

IJMS

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Photosynthetic carbon converted to sucrose is vital for plant growth. Sucrose acts as a signaling molecule and a primary energy source that coordinates the source and sink development. Alteration in source–sink balance halts the physiological and developmental processes of plants, since plant growth is mostly triggered when the primary assimilates in the source leaf balance with the metabolic needs of the heterotrophic sinks. To measure up with the sink organ’s metabolic needs, the improvement of photosynthetic carbon to synthesis sucrose, its remobilization, and utilization at the sink level becomes imperative. However, environmental cues that influence sucrose balance within these plant organs, limiting positive yield prospects, have also been a rising issue over the past few decades. Thus, this review discusses strategies to improve photosynthetic carbon assimilation, the pathways actively involved in the transport of sucrose from source to sink organs, and their utilization at the sink organ. We further emphasize the impact of various environmental cues on sucrose transport and utilization, and the strategic yield improvement approaches under such conditions.

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“…Water stress reduced number of full pods per plant by 6.3%, seed yield/plant by 12.8%, and seed size by 6.3% (Table 3). Du et al [13] found that drought prevailing during generative stage, mainly at the middle and late seed filling phases, sucrose movement from leaves to seeds was lessen, and the balance of sucrose metabolism was defected in seeds, rendering in seed mass reduction. Number of full pods per plant and seed size are main attributes of soybean seed yield, the higher the number and the larger the seed size, the higher the yield [14,15,16].…”

Section: Resultsmentioning

confidence: 99%

Response of Soybean Lines to Drought Stress During Reproductive Phase

Suhartina¹,

Purwantoro²,

Nugrahaeni³

et al. 2021

Proceedings of the 3rd KOBI Congress, International and National Conferences (KOBICINC 2020)

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At production centers, soybeans are in a rice-paddy-soybean or paddy-soybean cropping pattern, which is often at risk of crop failure due to drought. Therefore, it is necessary to develop varieties that are more tolerant to drought than existing varieties. The aim of this study was to evaluate soybean lines to drought stress during the reproductive phase. The research was conducted at Ngawi, East Java during dry season of 2016. A total of 34 soybean lines and two check varieties (Grobogan and Dering 1) were tested using a randomized block design and repeated three times. The study consisted of two growing environments, namely optimal conditions (irrigation between planting and R7 phase at intervals of 10-15 days) and drought conditions in the reproductive phase (irrigation was carried out between planting and R2 at intervals of 10-15 days). Drought stress tolerance lines were identified based on their stress tolerance indexes (STI). Research result revealed that five soybean lines were more tolerant than Dering 1 (drought tolerant check), with a stress tolerance index (STI) values of 1.20 to 1.35, which was higher than Dering 1 (STI 1.02) and Grobogan (STI 1.04). Among those five lines, TGm-161-25-10 line, produced the highest seed yield both in the optimal and drought conditions, i.e. 2.60 t / ha and 2.44 t/ha, respectively. Those five selected droughttolerant lines were early maturing with maturity days ranged from 75.0 to 77.3 days and three of those were belong to large seed sizes, i.e. 14.6-15.4 g/100 seeds.

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Effect of Drought Stress during Soybean R2–R6 Growth Stages on Sucrose Metabolism in Leaf and Seed

Cited by 101 publications

References 57 publications

Leaf Soluble Sugars and Free Amino Acids as Important Components of Abscisic Acid—Mediated Drought Response in Tomato

Leaf Soluble Sugars and Free Amino Acids as Important Components of Abscisic Acid—Mediated Drought Response in Tomato

Sucrose Utilization for Improved Crop Yields: A Review Article

Response of Soybean Lines to Drought Stress During Reproductive Phase

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