Expression pattern of drought stress marker genes in soybean roots under two water deficit systems

Neves-Borges, Anna Cristina; Guimarães-Dias, Fábia; Cruz, Fernanda Pérez; Mesquita, Rosilene Oliveira; Nepomuceno, Alexandre Lima; Romano, Eduardo; Loureiro, Marcelo Ehlers; Grossi-de-Sá, Maria de Fátima; Alves‐Ferreira, Márcio

doi:10.1590/s1415-47572012000200003

Cited by 33 publications

(25 citation statements)

References 52 publications

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“…Throughout this study, we analyzed the response of soybean cultivars to WD and the mechanisms associated with increasing tolerance to this stress triggered by NO. Generally, our results are in agreement with previous studies indicating that cultivar EMBRAPA 48 presents higher tolerance to WD than cultivar BR 16 (Neves-Borges et al 2012, Marcolino-Gomes et al 2013, Arraes et al 2015. In fact, when subjected to WD, plants of cultivar EMBRAPA 48 were able to maintain their biomass, productivity, and photosynthetic rates at levels remarkably higher than those observed for BR 16.…”

Section: Discussionsupporting

confidence: 94%

Improving water use efficiency by changing hydraulic and stomatal characteristics in soybean exposed to drought: the involvement of nitric oxide

Sousa

Menezes‐Silva

Lourenço

et al. 2019

Physiologia Plantarum

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A variety of cellular responses is needed to ensure the plants survival during drought, but little is known about the signaling mechanisms involved in this process. Soybean cultivars (EMBRAPA 48 and BR 16, tolerant and sensitive to drought, respectively) were exposed to the following treatments: control conditions (plants in field capacity), drought (20% of available water in the soil), sodium nitroprusside (SNP) treatment (plants irrigated and treated with 100‐µM SNP [SNP–nitric oxide (NO) donor molecule], and Drought + SNP (plants subjected to drought and SNP treatment). Plants remained in these conditions until the reproductive stage and were evaluated for physiological (photosynthetic pigments, chlorophyll a fluorescence and gas exchange rates), hydraulic (water potential, osmotic potential and leaf hydraulic conductivity) and morpho‐anatomical traits (biomass, venation density and stomatal characterization). Exposure to water deficit considerably reduced water potential in both cultivars and resulted in decrease in photosynthesis and biomass accumulation. The addition of the NO donor attenuated these damaging effects of water deficit and increased the tolerance index of both cultivars. The results showed that NO was able to reduce plant's water loss, while maintaining their biomass production through alteration in stomatal characteristics, hydraulic conductivity and the biomass distribution pattern. These hydraulic and morpho‐anatomical alterations allowed the plants to obtain, transport and lose less water to the atmosphere, even in water deficit conditions.

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Section: Discussionsupporting

confidence: 94%

Improving water use efficiency by changing hydraulic and stomatal characteristics in soybean exposed to drought: the involvement of nitric oxide

Sousa

Menezes‐Silva

Lourenço

et al. 2019

Physiologia Plantarum

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“…Plant dry weight measured at the end of the experiment also showed the same pattern ( P < 0.001) except there was no difference in dry weight between well-watered and saturated plants ( Figure 1B ). The expression of a drought-stress marker, RD20A ( Neves-Borges et al, 2012 ), 3 days after the commencement of water stress, treatments showed a significant increase in expression under drought stress as compared to well-watered and saturated plants (Supplementary Figure S2 ). Feeding by either non-viruliferous or viruliferous aphids did not affect plant water content or dry weight in response to the water-stress treatments (Data not shown).…”

Section: Resultsmentioning

confidence: 99%

Water Stress Modulates Soybean Aphid Performance, Feeding Behavior, and Virus Transmission in Soybean

et al. 2016

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Little is known about how water stress including drought and flooding modifies the ability of plants to resist simultaneous attack by insect feeding and transmission of insect-vectored pathogen. We analyzed insect population growth, feeding behaviors, virus transmission, and plant amino acid profiles and defense gene expression to characterize mechanisms underlying the interaction between water stress, soybean aphid and aphid-transmitted, Soybean mosaic virus, on soybean plants. Population growth of non-viruliferous aphids was reduced under drought stress and saturation, likely because the aphids spent less time feeding from the sieve element on these plants compared to well-watered plants. Water stress did not impact population growth of viruliferous aphids. However, virus incidence and transmission rate was lowest under drought stress and highest under saturated conditions since viruliferous aphids took the greatest amount time to puncture cells and transmit the virus under saturated conditions and lowest time under drought stress. Petiole exudates from drought-stressed plants had the highest level of total free amino acids including asparagine and valine that are critical for aphid performance. Aphids did not benefit from improved phloem sap quality as indicated by their lower densities on drought-stressed plants. Saturation, on the other hand, resulted in low amino acid content compared to all of the other treatments. Drought and saturation had significant and opposing effects on expression of marker genes involved in abscisic acid (ABA) signaling. Drought alone significantly increased expression of ABA marker genes, which likely led to suppression of salicylic acid (SA)-and jasmonic acid (JA)-related genes. In contrast, ABA marker genes were down-regulated under saturation, while expression of SA-and JA-related genes was upregulated. We propose that the apparent antagonism between ABA and SA/JA signaling pathways contributed to an increase in aphid densities under drought and their decrease under saturation. Taken together, our findings suggests that plant responses to water stress is complex involving changes in phloem amino acid composition and signaling pathways, which can impact aphid populations and virus transmission.

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“…Episodes of drought with a temporary decrease in water availability lead to stress and induce changes in several Common bean drought transcriptome 7 morphological, physiological, biochemical and molecular processes in plants (Mehrotra et al, 2014). Hydroponics is a useful system for studying plant responses to abiotic stresses, including drought, in which the water deprivation occurs 8 Pereira et al abruptly by removing the plant from the nutrient solution (Neves-Borges et al, 2012;Tripathi et al, 2016). As an advantage, hydroponic systems overcome the effects of several abiotic stresses other than water stress, such as the problems of heterogeneity and drainage (Munns et al, 2010), allowing the maintenance of constant conditions such as temperature and relative humidity (Martins et al, 2008), besides the ease of root collecting.…”

Section: Discussionmentioning

confidence: 99%

Genome-wide analysis of the transcriptional response to drought stress in root and leaf of common bean

et al. 2020

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Genes related to the response to drought stress in leaf and root tissue of drought-susceptible (DS) and tolerant (DT) genotypes were characterized by RNA-Seq. In total, 54,750 transcripts, representative of 28,590 genes, were identified; of these, 1,648 were of high-fidelity (merge of 12 libraries) and described for the first time in the Andean germplasm. From the 1,239 differentially expressed genes (DEGs), 458 were identified in DT, with a predominance of genes in categories of oxidative stress, response to stimulus and kinase activity. Most genes related to oxidation-reduction terms in roots were early triggered in DT (T75) compared to DS (T150) suggestive of a mechanism of tolerance by reducing the damage from ROS. Among the KEGG enriched by DEGs up-regulated in DT leaves, two related to the formation of Sulfur-containing compounds, which are known for their involvement in tolerance to abiotic stresses, were common to all treatments. Through qPCR, 88.64% of the DEGs were validated. A total of 151,283 variants were identified and functional effects estimated for 85,780. The raw data files were submitted to the NCBI database. A transcriptome map revealed new genes and isoforms under drought. These results supports a better understanding of the drought tolerance mechanisms in beans.

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Expression pattern of drought stress marker genes in soybean roots under two water deficit systems

Cited by 33 publications

References 52 publications

Improving water use efficiency by changing hydraulic and stomatal characteristics in soybean exposed to drought: the involvement of nitric oxide

Improving water use efficiency by changing hydraulic and stomatal characteristics in soybean exposed to drought: the involvement of nitric oxide

Water Stress Modulates Soybean Aphid Performance, Feeding Behavior, and Virus Transmission in Soybean

Genome-wide analysis of the transcriptional response to drought stress in root and leaf of common bean

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