scholarly journals A PIP-mediated osmotic stress signaling cascade plays a positive role in the salt tolerance of sugarcane

2021 ◽  
Vol 21 (1) ◽  
Author(s):  
Hanchen Tang ◽  
Qing Yu ◽  
Zhu Li ◽  
Feng Liu ◽  
Weihua Su ◽  
...  
Keyword(s):  
Plasma Membrane ◽  
Salt Stress ◽  
Salt Tolerance ◽  
Osmotic Stress ◽  
Hybridization Experiment ◽  
Signaling Cascade ◽  
Stress Signaling ◽  
Ion Leakage ◽  
Positive Role ◽  
Expression Levels

Abstract Background Plasma membrane intrinsic proteins (PIPs) are plant channel proteins involved in water deficit and salinity tolerance. PIPs play a major role in plant cell water balance and responses to salt stress. Although sugarcane is prone to high salt stress, there is no report on PIPs in sugarcane. Results In the present study, eight PIP family genes, termed ScPIP1–1, ScPIP1–2, ScPIP1–3, ScPIP1–4, ScPIP2–1, ScPIP2–2, ScPIP2–4 and ScPIP2–5, were obtained based on the sugarcane transcriptome database. Then, ScPIP2–1 in sugarcane was cloned and characterized. Confocal microscopy observation indicated that ScPIP2–1 was located in the plasma membrane and cytoplasm. A yeast two-hybridization experiment revealed that ScPIP2–1 does not have transcriptional activity. Real time quantitative PCR (RT-qPCR) analysis showed that ScPIP2–1 was mainly expressed in the leaf, root and bud, and its expression levels in both below- and aboveground tissues of ROC22 were up-regulated by abscisic acid (ABA), polyethylene glycol (PEG) 6000 and sodium chloride (NaCl) stresses. The chlorophyll content and ion leakage measurement suggested that ScPIP2–1 played a significant role in salt stress resistance in Nicotiana benthamiana through the transient expression test. Overexpression of ScPIP2–1 in Arabidopsis thaliana proved that this gene enhanced the salt tolerance of transgenic plants at the phenotypic (healthier state, more stable relative water content and longer root length), physiologic (more stable ion leakage, lower malondialdehyde content, higher proline content and superoxide dismutase activity) and molecular levels (higher expression levels of AtKIN2, AtP5CS1, AtP5CS2, AtDREB2, AtRD29A, AtNHX1, AtSOS1 and AtHKT1 genes and a lower expression level of the AtTRX5 gene). Conclusions This study revealed that the ScPIP2–1-mediated osmotic stress signaling cascade played a positive role in plant response to salt stress.

scholarly journals Characterization of Interactions between the Soybean Salt-Stress Responsive Membrane-Intrinsic Proteins GmPIP1 and GmPIP2

Agronomy ◽  
2021 ◽  
Vol 11 (7) ◽  
pp. 1312
Author(s):  
Jia Liu ◽  
Weicong Qi ◽  
Haiying Lu ◽  
Hongbo Shao ◽  
Dayong Zhang
Keyword(s):  
Plasma Membrane ◽  
Salt Stress ◽  
Salt Tolerance ◽  
Expression Profiles ◽  
Expression Patterns ◽  
Gene Expression Profiles ◽  
Early Gene ◽  
Plant Responses ◽  
Constitutive Overexpression ◽  
Important Trait

Salt tolerance is an important trait in soybean cultivation and breeding. Plant responses to salt stress include physiological and biochemical changes that affect the movement of water across the plasma membrane. Plasma membrane intrinsic proteins (PIPs) localize to the plasma membrane and regulate the water and solutes flow. In this study, quantitative real-time PCR and yeast two-hybridization were engaged to analyze the early gene expression profiles and interactions of a set of soybean PIPs (GmPIPs) in response to salt stress. A total of 20 GmPIPs-encoding genes had varied expression profiles after salt stress. Among them, 13 genes exhibited a downregulated expression pattern, including GmPIP1;6, the constitutive overexpression of which could improve soybean salt tolerance, and its close homologs GmPIP1;7 and 1;5. Three genes showed upregulated patterns, including the GmPIP1;6 close homolog GmPIP1;4, when four genes with earlier increased and then decreased expression patterns. GmPIP1;5 and GmPIP1;6 could both physically interact strongly with GmPIP2;2, GmPIP2;4, GmPIP2;6, GmPIP2;8, GmPIP2;9, GmPIP2;11, and GmPIP2;13. Definite interactions between GmPIP1;6 and GmPIP1;7 were detected and GmPIP2;9 performed homo-interaction. The interactions of GmPIP1;5 with GmPIP2;11 and 2;13, GmPIP1;6 with GmPIP2;9, 2;11 and GmPIP2;13, and GmPIP2;9 with itself were strengthened upon salt stress rather than osmotic stress. Taken together, we inferred that GmPIP1 type and GmPIP2 type could associate with each other to synergistically function in the plant cell; a salt-stress environment could promote part of their interactions. This result provided new clues to further understand the soybean PIP–isoform interactions, which lead to potentially functional homo- and heterotetramers for salt tolerance.

scholarly journals RsSOS1 Responding to Salt Stress Might Be Involved in Regulating Salt Tolerance by Maintaining Na+ Homeostasis in Radish (Raphanus sativus L.)

Horticulturae ◽  
2021 ◽  
Vol 7 (11) ◽  
pp. 458
Author(s):  
Wanting Zhang ◽  
Jingxue Li ◽  
Junhui Dong ◽  
Yan Wang ◽  
Liang Xu ◽  
...  
Keyword(s):  
Plasma Membrane ◽  
Salt Stress ◽  
Salt Tolerance ◽  
Functional Characterization ◽  
Vital Role ◽  
Salt Stress Response ◽  
Reading Frame ◽  
Yield And Quality

Radish is a kind of moderately salt-sensitive vegetable. Salt stress seriously decreases the yield and quality of radish. The plasma membrane Na+/H+ antiporter protein Salt Overly Sensitive 1 (SOS1) plays a crucial role in protecting plant cells against salt stress, but the biological function of the RsSOS1 gene in radish remains to be elucidated. In this study, the RsSOS1 gene was isolated from radish genotype ‘NAU-TR17’, and contains an open reading frame of 3414 bp encoding 1137 amino acids. Phylogenetic analysis showed that RsSOS1 had a high homology with BnSOS1, and clustered together with Arabidopsis plasma membrane Na+/H+ antiporter (AtNHX7). The result of subcellular localization indicated that the RsSOS1 was localized in the plasma membrane. Furthermore, RsSOS1 was strongly induced in roots of radish under 150 mmol/L NaCl treatment, and its expression level in salt-tolerant genotypes was significantly higher than that in salt-sensitive ones. In addition, overexpression of RsSOS1 in Arabidopsis could significantly improve the salt tolerance of transgenic plants. Meanwhile, the transformation of RsSOS1△999 could rescue Na+ efflux function of AXT3 yeast. In summary, the plasma membrane Na+/H+ antiporter RsSOS1 plays a vital role in regulating salt-tolerance of radish by controlling Na+ homeostasis. These results provided useful information for further functional characterization of RsSOS1 and facilitate clarifying the molecular mechanism underlying salt stress response in radish.

scholarly journals Rice Na+-Permeable Transporter OsHAK12 Mediates Shoots Na+ Exclusion in Response to Salt Stress

2021 ◽  
Vol 12 ◽  
Author(s):  
Linan Zhang ◽  
Xiangyu Sun ◽  
Yanfang Li ◽  
Xuan Luo ◽  
Shaowen Song ◽  
...  
Keyword(s):  
Plasma Membrane ◽  
Salt Stress ◽  
Salt Tolerance ◽  
Target Gene ◽  
Xylem Sap ◽  
Crop Productivity ◽  
Membrane Transporter ◽  
High Affinity ◽  
Salt Toxicity ◽  
Plasma Membrane Transporter

Soil salinity has become a major stress factor that reduces crop productivity worldwide. Sodium (Na+) toxicity in a number of crop plants is tightly linked with shoot Na+ overaccumulation, thus Na+ exclusion from shoot is crucial for salt tolerance in crops. In this study, we identified a member of the high-affinity K+ transport family (HAK), OsHAK12, which mediates shoots Na+ exclusion in response to salt stress in rice. The Oshak12 mutants showed sensitivity to salt toxicity and accumulated more Na+ in the xylem sap, leading to excessive Na+ in the shoots and less Na+ in the roots. Unlike typical HAK family transporters that transport K+, OsHAK12 is a Na+-permeable plasma membrane transporter. In addition, OsHAK12 was strongly expressed in the root vascular tissues and induced by salt stress. These findings indicate that OsHAK12 mediates Na+ exclusion from shoot, possibly by retrieving Na+ from xylem vessel thereby reducing Na+ content in the shoots. These findings provide a unique function of a rice HAK family member and provide a potential target gene for improving salt tolerance of rice.

scholarly journals Exogenously Applied Nitric Oxide Enhances Salt Tolerance in Rice (Oryza sativa L.) at Seedling Stage

Agronomy ◽  
2018 ◽  
Vol 8 (12) ◽  
pp. 276 ◽  
Author(s):  
Teferi Adamu ◽  
Bong-Gyu Mun ◽  
Sang-Uk Lee ◽  
Adil Hussain ◽  
Byung-Wook Yun
Keyword(s):  
Nitric Oxide ◽  
Salt Stress ◽  
Salt Tolerance ◽  
Oryza Sativa L ◽  
Abiotic Factors ◽  
Farming Systems ◽  
Small Scale ◽  
Positive Role ◽  
Leaf Chlorosis ◽  
Tolerant Genotype

Salinity is one of the major abiotic factors that limit rice production worldwide. Previous trends show that salt concentration in rivers is increasing consistently, posing potentially adverse threats in the near future. Thus, crops currently being cultivated, particularly in small-scale farming systems, are under high threat from salinity. In this study, we investigated the mitigating effect of nitric oxide (NO) on salt stress in rice based on the assessment of changes in the transcript levels of different genes and the phenotypic response of rice genotypes. We observed that exogenously applied NO increased the expression levels of OsHIPP38, OsGR1, and OsP5CS2 in the susceptible genotype of rice, whereas in the tolerant genotype, the effect of NO was mainly in counteracting the salt-induced gene expression that diverts cellular energy for defense. Moreover, seedlings that were pretreated with NO showed high biomass production under salt stress conditions, indicating the positive role of NO against salt-induced leaf chlorosis and early senescence. The effect of NO-mediated enhancement was more pronounced in the salt tolerant genotype. Therefore, the use of NO with the integration of tolerant genes or genotypes will enhance salt tolerance levels in rice.

scholarly journals ThCOL2 Improves the Salt Stress Tolerance of Tamarix hispida

2021 ◽  
Vol 12 ◽  
Author(s):  
Xiaojin Lei ◽  
Bing Tan ◽  
Zhongyuan Liu ◽  
Jing Wu ◽  
Jiaxin Lv ◽  
...  
Keyword(s):  
Transcription Factor ◽  
Salt Stress ◽  
Salt Tolerance ◽  
Cell Damage ◽  
Expression Patterns ◽  
Nacl Stress ◽  
Tamarix Hispida ◽  
Resistance Response ◽  
Expression Levels ◽  
Qrt Pcr

The CONSTANS-LIKE (COL) transcription factor has been reported to play important roles in regulating plant flowering and the response to abiotic stress. To clone and screen COL genes with excellent salt tolerance from the woody halophyte Tamarix hispida, 8 ThCOL genes were identified in this study. The expression patterns of these genes under different abiotic stresses (high salt, osmotic, and heavy metal) and abscisic acid (ABA) treatment were detected using quantitative real-time PCR (qRT-PCR). The expression levels of 8 ThCOL genes changed significantly after exposure to one or more stresses, indicating that these genes were all stress-responsive genes and may be involved in the stress resistance response of T. hispida. In particular, the expression level of ThCOL2 changed significantly at most time points in the roots and leaves of T. hispida under salt stress and after ABA treatments, which may play an important role in the response process of salt stress through a mechanism dependent on the ABA pathway. The recombinant vectors pROKII–ThCOL2 and pFGC5941–ThCOL2 were constructed for the transient transformation of T. hispida, and the transient infection of T. hispida with the pROKII empty vector was used as the control to further verify whether the ThCOL2 gene was involved in the regulation of the salt tolerance response of T. hispida. Overexpression of the ThCOL2 gene in plants under 150 mM NaCl stress increased the ability of transgenic T. hispida cells to remove reactive oxygen species (ROS) by regulating the activity of protective enzymes and promoting a decrease in the accumulation of O2– and H2O2, thereby reducing cell damage or cell death and enhancing salt tolerance. The ThCOL2 gene may be a candidate gene associated with excellent salt tolerance. Furthermore, the expression levels of some genes related to the ABA pathway were analyzed using qRT-PCR. The results showed that the expressions of ThNCED1 and ThNCED4 were significantly higher, and the expressions of ThNCED3, ThZEP, and ThAAO3 were not significantly altered in OE compared with CON under normal conditions. But after 24 h of salt stress, the expressions of all five studied genes all were lower than the normal condition. In the future, the downstream genes directly regulated by the ThCOL2 transcription factor will be searched and identified to analyze the salt tolerance regulatory network of ThCOL2.

scholarly journals Using Osmotic Stress to Stabilize Mannitol Production in Synechocystis sp. PCC6803

2020 ◽  
Author(s):  
Wenyang Wu ◽  
Wei Du ◽  
Ruth Perez Gallego ◽  
Klaas J. Hellingwerf ◽  
Aniek D. van der Woude ◽  
...  
Keyword(s):  
Salt Stress ◽  
Salt Tolerance ◽  
Osmotic Stress ◽  
Compatible Solutes ◽  
Direct Conversion ◽  
Cell Factory ◽  
Medical Sector ◽  
Mannitol Production ◽  
Synechocystis Sp ◽  
Pcc 6803

Abstract Background Mannitol is a C(6) polyol that is used in the food and medical sector as a sweetener and antioxidant, respectively. The sustainable production of mannitol, especially via the direct conversion of CO 2 by photosynthetic cyanobacteria, has become increasingly appealing. However, previous work aiming to achieve mannitol production in the marine Synechococcus sp. PCC 7002 via heterologous expression of mannitol-1-phosphate-5-dehydrogenase ( mtlD ) and mannitol-1-phosphatase ( m1p , in short: a ‘mannitol cassette’), proved to be genetically unstable. Results Here, we explore the stabilizing effect that mannitol production may have on cells faced with osmotic stress, in the freshwater cyanobacterium Synechocystis sp. PCC 6803. We first validated that mannitol can function as a compatible solute in Synechocystis sp. PCC 6803, and in derivative strains in which the ability to produce one or both of the native compatible solutes was impaired. Wild type Synechocystis , complemented with a mannitol cassette, indeed showed increased salt tolerance, which was even more evident in Synechocystis strains in which the ability to synthesize the endogenous compatible solutes was impaired. Next we tested the genetic stability of all these strains with respect to their mannitol productivity, with and without salt stress, during prolonged turbidostat cultivations. The obtained results show that mannitol production under salt stress conditions in the Synechocystis strain that cannot synthesize its endogenous compatible solutes is remarkably stable, while the control strain completely loses this ability in only 6 days. DNA sequencing results of the control groups that lost the ability to synthesize mannitol revealed that multiple types of mutation occurred in the mtlD gene that can explain the disruption of mannitol production. Conclusions Mannitol production in freshwater Synechocsytis sp. PCC6803 confers it with increased salt tolerance. Under this strategy, genetically instability which was the major challenge for mannitol production in cyanobacteria is tackled. This paper marks the first report of utilization of the response to salt stress as a factor that can increase the stability of mannitol production in a cyanobacterial cell factory.

scholarly journals Using Osmotic Stress to Stabilize Mannitol Production in Synechocystis sp. PCC6803

2020 ◽  
Author(s):  
Wenyang Wu ◽  
Wei Du ◽  
Ruth Perez Gallego ◽  
Klaas J. Hellingwerf ◽  
Aniek D. van der Woude ◽  
...  
Keyword(s):  
Salt Stress ◽  
Salt Tolerance ◽  
Osmotic Stress ◽  
Compatible Solutes ◽  
Direct Conversion ◽  
Cell Factory ◽  
Medical Sector ◽  
Mannitol Production ◽  
Synechocystis Sp ◽  
Pcc 6803

Abstract Background Mannitol is a C(6) polyol that is used in the food and medical sector as a sweetener and antioxidant, respectively. The sustainable production of mannitol, especially via the direct conversion of CO 2 by photosynthetic cyanobacteria, has become increasingly appealing. However, previous work aiming to achieve mannitol production in the marine Synechococcus sp. PCC 7002 via heterologous expression of mannitol-1-phosphate-5-dehydrogenase ( mtlD ) and mannitol-1-phosphatase ( m1p , in short: a ‘mannitol cassette’), proved to be genetically unstable. Results Here, we explore the stabilizing effect that mannitol production may have on cells faced with osmotic stress, in the freshwater cyanobacterium Synechocystis sp. PCC 6803. We first validated that mannitol can function as a compatible solute in Synechocystis sp. PCC 6803, and in derivative strains in which the ability to produce one or both of the native compatible solutes was impaired. Wild type Synechocystis , complemented with a mannitol cassette, indeed showed increased salt tolerance, which was even more evident in Synechocystis strains in which the ability to synthesize the endogenous compatible solutes was impaired. Next we tested the genetic stability of all these strains with respect to their mannitol productivity, with and without salt stress, during prolonged turbidostat cultivations. The obtained results show that mannitol production under salt stress conditions in the Synechocystis strain that cannot synthesize its endogenous compatible solutes is remarkably stable, while the control strain completely loses this ability in only 6 days. DNA sequencing results of the control groups that lost the ability to synthesize mannitol revealed that multiple types of mutation occurred in the mtlD gene that can explain the disruption of mannitol production. Conclusions Mannitol production in freshwater Synechocsytis sp. PCC6803 confers it with increased salt tolerance. Under this strategy, genetically instability which was the major challenge for mannitol production in cyanobacteria is tackled. This paper marks the first report of both stable mannitol production directly from CO 2 in cyanobacteria, and of the utilization of the response to salt stress as a factor that can stabilize production in a cyanobacterial cell factory.

Review: Unravelling the functional relationship between root anatomy and stress tolerance

2001 ◽  
Vol 28 (10) ◽  
pp. 999 ◽  
Author(s):  
Albino Maggio ◽  
Paul M. Hasegawa ◽  
Ray A. Bressan ◽  
M. Federica Consiglio ◽  
Robert J. Joly
Keyword(s):  
Salt Stress ◽  
Salt Tolerance ◽  
Osmotic Stress ◽  
Stress Tolerance ◽  
Root Morphology ◽  
Critical Role ◽  
Genetic Mutation ◽  
Root Anatomy ◽  
Biophysical Model ◽  
Plant Salt Tolerance

Salinity is a major environmental constraint limiting the yield of crop plants in many semi-arid and arid regions. A recently developed biophysical model for plant growth in saline environments confirms a critical role for root morphology and hydraulic properties in salinity and soil water deficit tolerance. The identification of genes based on correlations between exposure to salt stress and gene expression in roots and other organs has to date proved to be only marginally successful as a strategy for improving plant salt tolerance. Recently, the identification of genes that function in stress tolerance has advanced considerably by using genetic mutation analysis. However, the power of a genetic approach to understanding the specific mechanisms of root adaptation to saline and osmotic stress environments has not been fully exploited. A review of the available, yet still incomplete, collection of root mutants in Arabidopsis and other species demonstrates the potential usefulness of such mutants as tools in the genetic dissection of root function under osmotic stress. Identification of genes responsible for changes in root morphology that might also be advantageous in the presence of salt stress may open new avenues towards the elucidation of critical mechanisms for plant salt tolerance.

scholarly journals Cucurbita Rootstocks Improve Salt Tolerance of Melon Scions by Inducing Physiological, Biochemical and Nutritional Responses

Horticulturae ◽  
2020 ◽  
Vol 6 (4) ◽  
pp. 66
Author(s):  
Abdullah Ulas ◽  
Alim Aydin ◽  
Firdes Ulas ◽  
Halit Yetisir ◽  
Tanveer Fatima Miano
Keyword(s):  
Salt Stress ◽  
Salt Tolerance ◽  
Leaf Area ◽  
Biomass Production ◽  
Ion Leakage ◽  
Hydroponic Experiment ◽  
Leaf Chlorophyll ◽  
High K ◽  
Cucumis Melo L ◽  
Physiological And Biochemical

A hydroponic experiment was conducted to assess whether grafting with Cucurbita rootstocks could improve the salt tolerance of melon scions and to determine the physiological, biochemical, and nutritional responses induced by the rootstocks under salt stress. Two melon (Cucumis melo L.) cultivars (Citirex and Altinbas) were grafted onto two commercial Cucurbita rootstocks (Kardosa and Nun9075). Plants were grown in aerated nutrient solution under deep water culture (DWC) at two electrical conductivity (EC) levels (control at 1.5 dS m−1 and salt at 8.0 dS m−1). Hydroponic salt stress led to a significant reduction in shoot and root growths, leaf area, photosynthetic activity, and leaf chlorophyll and carotenoid contents of both grafted and nongrafted melons. Susceptible plants responded to salt stress by increasing leaf proline and malondialdehyde (MDA), ion leakage, and leaf Na+ and Cl− contents. Statistically significant negative correlations existed between shoot dry biomass production and leaf proline (r = −0.89), leaf MDA (r = −0.85), leaf Na+ (r = −0.90), and leaf (r = 0.63) and root (r = −0.90) ion leakages under salt stress. Nongrafted Citirex tended to be more sensitive to salt stress than Altinbas. The Cucurbita rootstocks (Nun9075 and Kardosa) significantly improved growth and biomass production of grafted melons (scions) by inducing physiological (high leaf area and photosynthesis), biochemical (low leaf proline and MDA), and nutritional (low leaf Na+ and ion leakage and high K+ and Ca++ contents) responses under salt stress. The highest growth performance was exhibited by the Citirex/Nun9075 and Citirex/Kardosa graft combinations. Both Cucurbita cultivars have high rootstock potential for melon, and their significant contributions to salt tolerance were closely associated with inducing physiological and biochemical responses of scions. These traits could be useful for the selection and breeding of salt-tolerant rootstocks for sustainable agriculture in the future.

scholarly journals Characterization of interactions between the soybean plasma membrane- intrinsic proteins GmPIP1s and GmPIP2s responding to salt stress

2020 ◽  
Author(s):  
Weicong Qi ◽  
Jia Liu ◽  
Dayong Zhang ◽  
Haiying Lu ◽  
Hongbo Shao ◽  
...  
Keyword(s):  
Plasma Membrane ◽  
Salt Stress ◽  
Salt Tolerance ◽  
Vital Role ◽  
Plant Responses ◽  
Plasma Membrane Intrinsic Proteins ◽  
Physiological And Biochemical ◽  
Salt And Osmotic Stress

Abstract Background: Salt tolerance is a key trait in soybean breeding and plant responses to salt stress include physiological and biochemical changes that affect the movement of water across the plasma membrane. In this study, we report the interactions of a set of aquaporins, soybean (Glycine max) plasma membrane-intrinsic proteins (GmPIPs), in response to salt stress. Results: GmPIP1;5 and GmPIP1;6 formed hetero-tetramers with GmPIP2;4, GmPIP2;6, GmPIP2;8, GmPIP2;9, GmPIP2;11, and GmPIP2;13. We detected interactions between GmPIP1;6 and GmPIP1;7, but not between GmPIP1;6 and GmPIP1;5. Furthermore, GmPIP2;9 formed homo-tetramers, and this interaction was strengthened under salt and osmotic stress. Expression analysis indicated complex and unique responses to salt stress depending on the duration of the stress. For example, GmPIP2;8, encoding one of the heteromer-forming PIP proteins, was highly up-regulated under early salt stress.Conclusions: Our study highlights the vital role of hetero- and homo-tetramers, in salt tolerance; and improves understanding of the mechanisms by which soybean aquaporin isoforms respond to abiotic stress.

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