The Mitochondrial Phosphate Transporters Modulate Plant Responses to Salt Stress via Affecting ATP and Gibberellin Metabolism in Arabidopsis thaliana

ABSTRACT Abiotic stresses such as drought result in large annual economic losses around the world. As sessile organisms, plants cannot escape the environmental stresses they encounter, but instead must adapt to survive. Studies investigating plant responses to osmotic and/or salt stress have largely focused on short-term systemic responses, leaving our understanding of intermediate to longer-term adaptation (24 h - days) lacking. In addition to protein abundance and phosphorylation changes, evidence suggests reversible lysine acetylation may also be important for abiotic stress responses. Therefore, to characterize the protein-level effects of osmotic and salt stress, we undertook a label-free proteomic analysis of Arabidopsis thaliana roots exposed to 300 mM Mannitol and 150 mM NaCl for 24 h. We assessed protein phosphorylation, lysine acetylation and changes in protein abundance, detecting significant changes in 245, 35 and 107 total proteins, respectively. Comparison with available transcriptome data indicates that transcriptome- and proteome-level changes occur in parallel, while PTMs do not. Further, we find significant changes in PTMs and protein abundance involve different proteins from the same networks, indicating a multifaceted regulatory approach to prolonged osmotic and salt stress. In particular, we find extensive protein-level changes involving sulphur metabolism under both osmotic and salt conditions as well as changes in protein kinases and transcription factors that may represent new targets for drought stress signaling. Collectively, we find that protein-level changes continue to occur in plant roots 24 h from the onset of osmotic and salt stress and that these changes differ across multiple proteome levels.

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Expression patterns of nitrate, phosphate, and sulfate transporters in Arabidopsis roots exposed to different nutritional regimes

Botany ◽

10.1139/b11-053 ◽

2011 ◽

Vol 89 (9) ◽

pp. 647-653 ◽

Cited By ~ 20

Author(s):

Shengjie Bao ◽

Lijun An ◽

Sha Su ◽

Zhongjing Zhou ◽

Yinbo Gan

Keyword(s):

Arabidopsis Thaliana ◽

Expression Patterns ◽

Nitrogen Supply ◽

Nitrate Transport ◽

Plant Responses ◽

Nitrate Transporter ◽

Phosphate Transporters ◽

Nutrient Treatment ◽

High Affinity ◽

Nitrate Starvation

Nitrate transporter AtNRT2.1 is the key component of the inducible high-affinity nitrate transport system in Arabidopsis thaliana . AtNRT2.1 is primarily expressed in roots and known to be mainly involved under fluctuating nitrogen supply conditions. It is still unknown whether AtNRT2.1 is involved in plant responses to other nutrient fluctuations. In this study, we found that the expression of AtNRT2.1 was also upregulated by phosphate and sulfate resupply, which may indicate a novel role in regulating phosphate and sulfate responses. Our study also demonstrated that expression of the major Pi transporter (Pht1) family member, AtPHT1;2, was suppressed by nitrate starvation and induced by nitrate resupply and sulfate starvation in comparison to the continuous nutrient treatment. Moreover, this study also showed that expression of sulfur transporter SULTR1;1 and AtNRT2.1 was suppressed by complete nutrient starvation and induced by complete nutrient resupply. These novel results provide strong evidence that there is crosstalk among the nitrate, sulfate, and phosphate transporters in regulating different nutrient fluctuations in Arabidopsis roots.

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Quantitative proteome and PTMome analysis of Arabidopsis thaliana root responses to persistent osmotic and salinity stress

10.1101/2020.12.28.424236 ◽

2020 ◽

Author(s):

MC. Rodriguez ◽

D Mehta ◽

M Tan ◽

RG Uhrig

Keyword(s):

Arabidopsis Thaliana ◽

Salt Stress ◽

Abiotic Stress ◽

Stress Responses ◽

Protein Level ◽

Economic Losses ◽

Plant Responses ◽

Label Free ◽

Proteomic Approach ◽

Stress Dependent

ABSTRACTEnvironmental conditions contributing to abiotic stress such as drought result in large annual economic losses around the world. As sessile organisms, plants cannot escape the environmental stresses they encounter, but instead must adapt to survive. Studies investigating plant responses to osmotic and/or salt stress have largely focused on short-term systemic responses, leaving our understanding of intermediate to longer-term adaptation (24 h - days), less well understood. In addition to protein abundance and phosphorylation changes, evidence suggests reversible protein acetylation may also be important for abiotic stress responses. Therefore, to characterize protein-level effects of osmotic and salt stress, we undertook a label-free proteomic analysis of Arabidopsis thaliana roots exposed to 300 mM Mannitol and 150 mM NaCl for 24 hours. We assessed protein phosphorylation, acetylation and changes in abundance, detecting significant changes in the status of 106, 66 and 447 proteins, respectively. Comparison with available transcriptome data from analogous treatments, indicate that transcriptome- and proteome-level changes occur in parallel. Furthermore, significant changes in abundance, phosphorylation and acetylation involve different proteins from the same networks, indicating a concerted, multifaceted regulatory approach to prolonged osmotic and/or salt stress. Lastly, our quantitative proteomic approach uncovered a new root elongation protein, Armadillo repeat protein 2 (ARO2), which exhibits a salt stress dependent phenotype. Collectively, our findings indicate dynamic protein-level changes continue to occur in plant roots 24 hours from the onset of osmotic and salt stress and that these changes differ across multiple levels of the proteome.

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Salt stress resistance in SmCP-transgenic Arabidopsis thaliana as revealed by transcriptome analysis

Pakistan Journal of Botany ◽

10.30848/pjb2020-3(8) ◽

2019 ◽

Vol 52 (3) ◽

Author(s):

He Li ◽

Liu Zheng ◽

Ying Wang ◽

Xianqi Hu ◽

Zhuchou Lu ◽

...

Keyword(s):

Arabidopsis Thaliana ◽

Salt Stress ◽

Transcriptome Analysis ◽

Stress Resistance ◽

Transgenic Arabidopsis ◽

Transgenic Arabidopsis Thaliana ◽

Salt Stress Resistance

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Faculty Opinions recommendation of The structure of the Arabidopsis thaliana SOS3: molecular mechanism of sensing calcium for salt stress response.

Faculty Opinions – Post-Publication Peer Review of the Biomedical Literature ◽

10.3410/f.1024162.286767 ◽

2005 ◽

Author(s):

Ramón Serrano

Keyword(s):

Arabidopsis Thaliana ◽

Salt Stress ◽

Stress Response ◽

Molecular Mechanism ◽

Salt Stress Response

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Analysis of Arabidopsis thaliana HKT1 and Eutrema salsugineum/botschantzevii HKT1;2 Promoters in Response to Salt Stress in Athkt1:1 Mutant

Molecular Biotechnology ◽

10.1007/s12033-019-00175-5 ◽

2019 ◽

Vol 61 (6) ◽

pp. 442-450 ◽

Cited By ~ 1

Author(s):

Ismat Nawaz ◽

Mazhar Iqbal ◽

Henk W. J. Hakvoort ◽

Albertus H. de Boer ◽

Henk Schat

Keyword(s):

Arabidopsis Thaliana ◽

Salt Stress ◽

Eutrema Salsugineum

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

Agronomy ◽

10.3390/agronomy11071312 ◽

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.

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