Phospholipase Dα1 mediates the high-Mg
Arabidopsis thaliana
CIPK9
HAK5
high magnesium
ion homeostasis
phospholipase D
potassium
Journal
Plant, cell & environment
ISSN: 1365-3040
Titre abrégé: Plant Cell Environ
Pays: United States
ID NLM: 9309004
Informations de publication
Date de publication:
10 2020
10 2020
Historique:
received:
30
12
2019
revised:
13
06
2020
accepted:
14
06
2020
pubmed:
26
6
2020
medline:
12
2
2021
entrez:
26
6
2020
Statut:
ppublish
Résumé
Intracellular levels of Mg
Substances chimiques
Arabidopsis Proteins
0
PLDA1 protein, Arabidopsis
EC 3.1.4.4
Phospholipase D
EC 3.1.4.4
Magnesium
I38ZP9992A
Potassium
RWP5GA015D
Types de publication
Journal Article
Research Support, Non-U.S. Gov't
Langues
eng
Sous-ensembles de citation
IM
Pagination
2460-2475Informations de copyright
© 2020 John Wiley & Sons Ltd.
Références
Bargmann, B. O. R., Laxalt, A. M., ter Riet, B., van Schooten, B., Merquiol, E., Testerink, C., … Munnik, T. (2009). Multiple PLDs required for high salinity and water deficit tolerance in plants. Plant and Cell Physiology, 50, 78-89.
Bradshaw, H. D., Jr. (2005). Mutations in CAX1 produce phenotypes characteristic of plants tolerant to serpentine soils. New Phytologist, 167, 81-88.
Caballero, F., Botella, M. A., Rubio, L., Fernandez, J. A., Martinez, V., & Rubio, F. (2012). A Ca2+-sensitive system mediates low-affinity K+ uptake in the absence of AKT1 in Arabidopsis plants. Plant and Cell Physiology, 53, 2047-2059.
Chen, H., Yu, X., Zhang, X., Yang, L., Huang, X., Zhang, J., … Li, W. (2018). Phospholipase Dα1-mediated phosphatidic acid change is a key determinant of desiccation-induced viability loss in seeds. Plant Cell and Environment, 41, 50-63.
Chen, Z. C., Peng, W. T., Li, J., & Liao, H. (2018). Functional dissection and transport mechanism of magnesium in plants. Seminars in Cell and Developmental Biology, 74, 142-152.
Cheng, N. H., Pittman, J. K., Barkla, B. J., Shigaki, T., & Hirschi, K. D. (2003). The Arabidopsis cax1 mutant exhibits impaired ion homeostasis, development, and hormonal responses and reveals interplay among vacuolar transporters. Plant Cell, 15, 347-364.
Choudhury, S. R., & Pandey, S. (2017). Phosphatidic acid binding inhibits RGS1 activity to affect specific signaling pathways in Arabidopsis. Plant Journal, 90, 466-477.
Clough, S. J., & Bent, A. F. (1998). Floral dip: A simplified method for Agrobacterium-mediated transformation of Arabidopsis thaliana. Plant Journal, 16, 735-743.
Conn, S. J., Conn, V., Tyerman, S. D., Kaiser, B. N., Leigh, R. A., & Gilliham, M. (2011). Magnesium transporters, MGT2/MRS2-1 and MGT3/MRS2-5, are important for magnesium partitioning within Arabidopsis thaliana mesophyll vacuoles. New Phytologist, 190, 583-594.
Coskun, D., Britto, D. T., & Kronzucker, H. J. (2014). The physiology of channel-mediated K+ acquisition in roots of higher plants. Physiologia Plantarum, 151, 305-312.
deVrije, T., & Munnik, T. (1997). Activation of phospholipase D by calmodulin antagonists and mastoparan in carnation petals. Journal of Experimental Botany, 48, 1631-1637.
Diem, B., & Godbold, D. L. (1993). Potassium, calcium and magnesium antagonism in clones of Populus trichocarpa. Plant and Soil, 155, 411-414.
Ding, Y., Luo, W., & Xu, G. (2006). Characterisation of magnesium nutrition and interaction of magnesium and potassium in rice. Annals of Applied Biology, 149, 111-123.
Fageria, V. D. (2001). Nutrient interaction in crop plants. Journal of Plant Nutrition, 24, 1269-1290.
Fan, L., Zheng, S. Q., Cui, D. C., & Wang, X. M. (1999). Subcellular distribution and tissue expression of phospholipase D, D b, and D g in Arabidopsis. Plant Physiology, 119, 1371-1378.
Guo, K. M., Babourina, O., Christopher, D. A., Borsic, T., & Rengel, Z. (2010). The cyclic nucleotide-gated channel AtCNGC10 transports Ca2+ and Mg2+ in Arabidopsis. Physiologia Plantarum, 139, 303-312.
Guo, L., Mishra, G., Taylor, K., & Wang, X. (2011). Phosphatidic acid binds and stimulates Arabidopsis sphingosine kinases. Journal of Biological Chemistry, 286, 13336-13345.
Guo, W. (2017). Magnesium homeostasis mechanisms and magnesium use efficiency in plants. In M.A. Hossain, T. Kamiya, D. Burritt, L.P. Tran & T. Fujiwara (Eds.), Plant macronutrient use efficiency (pp. 197-213). London: Academic Press.
Guo, W., Cong, Y., Hussain, N., Wang, Y., Liu, Z., Jiang, L., … Chen, K. (2014). The remodeling of seedling development in response to long-term magnesium toxicity and regulation by ABA-DELLA signaling in Arabidopsis. Plant Cell Physiology, 55, 1713-1726.
Guo, W. L., Nazim, H., Liang, Z. S., & Yang, D. F. (2016). Magnesium deficiency in plants: An urgent problem. Crop Journal, 4, 83-91.
Held, K., Pascaud, F., Eckert, C., Gajdanowicz, P., Hashimoto, K., Corratgé-Faillie, C., … Kudla, J. (2011). Calcium-dependent modulation and plasma membrane targeting of the AKT2 potassium channel by the CBL4/CIPK6 calcium sensor/protein kinase complex. Cell Research, 21, 1116-1130.
Hermans, C., Conn, S. J., Chen, J., Xiao, Q., & Verbruggen, N. (2013). An update on magnesium homeostasis mechanisms in plants. Metallomics, 5, 1170-1183.
Hite, R. K., Butterwick, J. A., & MacKinnon, R. (2014). Phosphatidic acid modulation of Kv channel voltage sensor function. Elife, 3, 04366.
Hoagland, D. R., & Arnon, D. I. (1950). The water-culture method for growing plants without soil. California Agricultural Experiment Station Circular, 347, 1-39.
Hong, Y., Zhao, J., Guo, L., Kim, S.-C., Deng, X., Wang, G., … Wang, X. (2016). Plant phospholipases D and C and their diverse functions in stress responses. Progress in Lipid Research, 62, 55-74.
Hong, Y., Zheng, S., & Wang, X. (2008). Dual functions of phospholipase Dα1 in plant response to drought. Molecular Plant, 1, 262-269.
Hong, Y. Y., Devaiah, S. P., Bahn, S. C., Thamasandra, B. N., Li, M. Y., Welti, R., & Wang, X. M. (2009). Phospholipase Dε and phosphatidic acid enhance Arabidopsis nitrogen signaling and growth. Plant Journal, 58, 376-387.
Horie, T., Brodsky, D. E., Costa, A., Kaneko, T., Lo Schiavo, F., Katsuhara, M., & Schroeder, J. I. (2011). K+ transport by the OsHKT2;4 transporter from rice with atypical Na+ transport properties and competition in permeation of K+ over Mg2+ and Ca2+ ions. Plant Physiology, 156, 1493-1507.
Hou, Q., Ufer, G., & Bartels, D. (2016). Lipid signalling in plant responses to abiotic stress. Plant, Cell and Environment, 39, 1029-1048.
Huber, D. M., & Jones, J. B. (2013). The role of magnesium in plant disease. Plant and Soil, 368, 73-85.
Janda, M., Lamparova, L., Zubikova, A., Burketova, L., Martinec, J., & Krckova, Z. (2019). Temporary heat stress suppresses PAMP-triggered immunity and resistance to bacteria in Arabidopsis thaliana. Molecular Plant Pathology, 20, 1005-1012.
Katagiri, T., Takahashi, S., & Shinozaki, K. (2001). Involvement of a novel Arabidopsis phospholipase D, AtPLDδ, in dehydration-inducible accumulation of phosphatidic acid in stress signalling. Plant Journal, 26, 595-605.
Kolesnikov, Y. S., Nokhrina, K. P., Kretynin, S. V., Volotovski, I. D., Martinec, J., Romanov, G. A., & Kravets, V. S. (2012). Molecular structure of phospholipase D and regulatory mechanisms of its activity in plant and animal cells. Biochemistry (Moscow), 77, 1-14.
Krckova, Z., Kocourkova, D., Danek, M., Brouzdova, J., Pejchar, P., Janda, M., … Martinec, J. (2018). The Arabidopsis thaliana non-specific phospholipase C2 is involved in the response to Pseudomonas syringae attack. Annals of Botany, 121, 297-310.
Lerchner, A., Mansfeld, J., Kuppe, K., & Ulbrich-Hofmann, R. (2006). Probing conserved amino acids in phospholipase D (Brassica oleracea var. capitata) for their importance in hydrolysis and transphosphatidylation activity. Protein Engineering, Design & Selection, 19, 443-452.
Li, L., Kim, B.-G., Cheong, Y. H., Pandey, G. K., & Luan, S. (2006). A Ca2+ signaling pathway regulates a K+ channel for low-K response in Arabidopsis. Proceedings of the National Academy of Sciences of the United States of America, 103, 12625-12630.
Li, L., Tutone, A. F., Drummond, R. D., Gardner, R. C., & Luan, S. (2001). A novel family of magnesium transport genes in Arabidopsis. Plant Cell, 13, 2761-2775.
Liu, L. L., Ren, H. M., Chen, L. Q., Wang, Y., & Wu, W. H. (2013). A protein kinase, calcineurin B-like protein-interacting protein kinase9, interacts with calcium sensor calcineurin B-like protein3 and regulates potassium homeostasis under low-potassium stress in Arabidopsis. Plant Physiology, 161, 266-277.
Maathuis, F. J. M., & Amtmann, A. (1999). K+ nutrition and Na+ toxicity: The basis of cellular K+/Na+ ratios. Annals of Botany, 84, 123-133.
McLoughlin, F., Arisz, S. A., Dekker, H. L., Kramer, G., de Koster, C. G., Haring, M. A., … Testerink, C. (2013). Identification of novel candidate phosphatidic acid-binding proteins involved in the salt-stress response of Arabidopsis thaliana roots. Biochemical Journal, 450, 573-581.
McLoughlin, F., Galvan-Ampudia, C. S., Julkowska, M. M., Caarls, L., van der Does, D., Laurière, C., … Testerink, C. (2012). The Snf1-related protein kinases SnRK2.4 and SnRK2.10 are involved in maintenance of root system architecture during salt stress. Plant Journal, 72, 436-449.
Mengutay, M., Ceylan, Y., Kutman, U. B., & Cakmak, I. (2013). Adequate magnesium nutrition mitigates adverse effects of heat stress on maize and wheat. Plant and Soil, 368, 57-72.
Mishra, G., Zhang, W., Deng, F., Zhao, J., & Wang, X. (2006). A bifurcating pathway directs abscisic acid effects on stomatal closure and opening in Arabidopsis. Science, 312, 264-266.
Mogami, J., Fujita, Y., Yoshida, T., Tsukiori, Y., Nakagami, H., Nomura, Y., … Yamaguchi-Shinozaki, K. (2015). Two distinct families of protein kinases are required for plant growth under high external Mg2+ concentrations in Arabidopsis. Plant Physiology, 167, 1039-1057.
Nakamura, S., Mano, S., Tanaka, Y., Ohnishi, M., Nakamori, C., Araki, M., … Ishiguro, S. (2010). Gateway binary vectors with the bialaphos resistance gene, bar, as a selection marker for plant transformation. Bioscience, Biotechnology, and Biochemistry, 74, 1315-1319.
Nieves-Cordones, M., Martinez, V., Benito, B., & Rubio, F. (2016). Comparison between Arabidopsis and Rice for main pathways of K+ and Na+ uptake by roots. Frontiers in Plant Science, 7, 992.
Niu, Y., Chen, P., Zhang, Y., Wang, Z., Hu, S., Jin, G., … Guo, L. (2018). Natural variation among Arabidopsis thaliana accessions in tolerance to high magnesium supply. Scientific Reports, 8, 13640.
Novák, D., Vadovič, P., Ovečka, M., Šamajová, O., Komis, G., Colcombet, J., & Šamaj, J. (2018). Gene expression pattern and protein localization of Arabidopsis phospholipase Dα1 revealed by advanced light-sheet and super-resolution microscopy. Frontiers in Plant Science, 9, 371. https://doi.org/10.3389/fpls.2018.00371.
Oda, K., Kamiya, T., Shikanai, Y., Shigenobu, S., Yamaguchi, K., & Fujiwara, T. (2016). The Arabidopsis Mg transporter, MRS2-4, is essential for Mg homeostasis under both low and high Mg conditions. Plant Cell Physiology, 57, 754-763.
Pandey, G. K., Cheong, Y. H., Kim, B. G., Grant, J. J., Li, L. G., & Luan, S. (2007). CIPK9: A calcium sensor-interacting protein kinase required for low-potassium tolerance in Arabidopsis. Cell Research, 17, 411-421.
Pathak, A. N., & Kalra, Y. P. (1971). Antagonism between potassium, calcium and magnesium in several varieties of hybrid corn. Zeitschrift für Pflanzenernährung und Bodenkunde, 130, 118-124.
Pejchar, P., Potocký, M., Novotná, Z., Veselková, Š., Kocourková, D., Valentová, O., … Martinec, J. (2010). Aluminium ions inhibit the formation of diacylglycerol generated by phosphatidylcholine-hydrolysing phospholipase C in tobacco cells. New Phytologist, 188, 150-160.
Pilot, G., Lacombe, B., Gaymard, F., Cherel, I., Boucherez, J., Thibaud, J. B., & Sentenac, H. (2001). Guard cell inward K+ channel activity in Arabidopsis involves expression of the twin channel subunits KAT1 and KAT2. Journal of Biological Chemistry, 276, 3215-3221.
Pokotylo, I., Kravets, V., Martinec, J., & Ruelland, E. (2018). The phosphatidic acid paradox: Too many actions for one molecule class? Lessons from plants. Progress in Lipid Research, 71, 43-53.
Pyo, Y. J., Gierth, M., Schroeder, J. I., & Cho, M. H. (2010). High-affinity K+ transport in Arabidopsis: AtHAK5 and AKT1 are vital for seedling establishment and postgermination growth under low-potassium conditions. Plant Physiology, 153, 863-875.
Ragel, P., Raddatz, N., Leidi, E. O., Quintero, F. J., & Pardo, J. M. (2019). Regulation of K+ nutrition in plants. Frontiers in Plant Science, 10, 281.
Ragel, P., Ródenas, R., García-Martín, E., Andrés, Z., Villalta, I., Nieves-Cordones, M., … Rubio, F. (2015). The CBL-interacting protein kinase CIPK23 regulates HAK5-mediated high-affinity K+ uptake in Arabidopsis roots. Plant Physiology, 169, 2863-2873.
Rubio, F., Aleman, F., Nieves-Cordones, M., & Martinez, V. (2010). Studies on Arabidopsis athak5, atakt1 double mutants disclose the range of concentrations at which AtHAK5, AtAKT1 and unknown systems mediate K+ uptake. Physiologia Plantarum, 139, 220-228.
Ruelland, E., Kravets, V., Derevyanchuk, M., Martinec, J., Zachowski, A., & Pokotylo, I. (2015). Role of phospholipid signalling in plant environmental responses. Environmental and Experimental Botany, 114, 129-143.
Santa-Maria, G. E., Oliferuk, S., & Moriconi, J. I. (2018). KT-HAK-KUP transporters in major terrestrial photosynthetic organisms: A twenty years tale. Journal of Plant Physiology, 226, 77-90.
Senbayram, M., Gransee, A., Wahle, V., & Thiel, H. (2015). Role of magnesium fertilisers in agriculture: Plant-soil continuum. Crop and Pasture Science, 66, 1219-1229.
Shabala, S., & Hariadi, Y. (2005). Effects of magnesium availability on the activity of plasma membrane ion transporters and light-induced responses from broad bean leaf mesophyll. Planta, 221, 56-65.
Shaul, O., Hilgemann, D. W., de Almeida-Engler, J., van Montagu, M., Inze, D., & Galili, G. (1999). Cloning and characterization of a novel Mg2+/H+ exchanger. EMBO Journal, 18, 3973-3980.
Shen, L., Tian, Q., Yang, L., Zhang, H., Shi, Y., Shen, Y., … Zhang, W. (2020). Phosphatidic acid directly binds with rice potassium channel OsAKT2 to inhibit its activity. Plant Journal, 102, 649-665.
Sun, Y., Kong, X., Li, C., Liu, Y., & Ding, Z. (2015). Potassium retention under salt stress is associated with natural variation in salinity tolerance among Arabidopsis accessions. PLoS One, 10, e0124032.
Sung, T. C., Roper, R. L., Zhang, Y., Rudge, S. A., Temel, R., Hammond, S. M., … Frohman, M. A. (1997). Mutagenesis of phospholipase D defines a superfamily including a trans-Golgi viral protein required for poxvirus pathogenicity. EMBO Journal, 16, 4519-4530.
Takáč, T., Vadovič, P., Pechan, T., Luptovčiak, I., Šamajová, O., & Šamaj, J. (2016). Comparative proteomic study of Arabidopsis mutants mpk4 and mpk6. Scientific Reports, 6, 28306.
Tang, H. X., Vasconcelos, A. C., & Berkowitz, G. A. (1996). Physical association of KAB1 with plant K+ channel α subunits. Plant Cell, 8, 1545-1553.
Tang, R. J., & Luan, S. (2017). Regulation of calcium and magnesium homeostasis in plants: From transporters to signaling network. Current Opinion in Plant Biology, 39, 97-105.
Tang, R. J., Zhao, F. G., Garcia, V. J., Kleist, T. J., Yang, L., Zhang, H. X., & Luan, S. (2015). Tonoplast CBL-CIPK calcium signaling network regulates magnesium homeostasis in Arabidopsis. Proceedings of the National Academy of Sciences, 112, 3134-3139.
Testerink, C., & Munnik, T. (2005). Phosphatidic acid: A multifunctional stress signaling lipid in plants. Trends in Plant Science, 10, 368-375.
Umezawa, T., Sugiyama, N., Takahashi, F., Anderson, J. C., Ishihama, Y., Peck, S. C., & Shinozaki, K. (2013). Genetics and phosphoproteomics reveal a protein phosphorylation network in the abscisic acid signaling pathway in Arabidopsis thaliana. Science Signaling, 6, rs8.
Vergnolle, C., Vaultier, M. N., Taconnat, L., Renou, J. P., Kader, J. C., Zachowski, A., & Ruelland, E. (2005). The cold-induced early activation of phospholipase C and D pathways determines the response of two distinct clusters of genes in Arabidopsis cell suspensions. Plant Physiology, 139, 1217-1233.
Visscher, A. M., Paul, A. L., Kirst, M., Guy, C. L., Schuerger, A. C., & Ferl, R. J. (2010). Growth performance and root transcriptome remodeling of Arabidopsis in response to Mars-like levels of magnesium sulfate. PLoS One, 5, e12348.
Wang, C., Zien, C. A., Afitlhile, M., Welti, R., Hildebrand, D. F., & Wang, X. (2000). Involvement of phospholipase D in wound-induced accumulation of jasmonic acid in Arabidopsis. Plant Cell, 12, 2237-2246.
Wang, X. M., Guo, L., Wang, G. L., & Li, M. Y. (2014). PLD: Phospholipase ds in plant signaling. In X. Wang (Ed.), Phospholipases in plant signaling (pp. 3-26). Berlin, Germany: Springer-Verlag.
Wang, Z., Hassan, M. U., Nadeem, F., Wu, L., Zhang, F., & Li, X. (2019). Magnesium fertilization improves crop yield in most production systems: A meta-analysis. Frontiers in Plant Science, 10, 1727.
Yamanaka, T., Nakagawa, Y., Mori, K., Nakano, M., Imamura, T., Kataoka, H., … Iida, H. (2010). MCA1 and MCA2 that mediate Ca2+ uptake have distinct and overlapping roles in Arabidopsis. Plant Physiology, 152, 1284-1296.
Yan, Y. W., Mao, D. D., Yang, L., Qi, J. L., Zhang, X. X., Tang, Q. L., … Luan, S. (2018). Magnesium transporter MGT6 plays an essential role in maintaining magnesium homeostasis and regulating high magnesium tolerance in Arabidopsis. Frontiers in Plant Science, 9, 274.
Yang, Y., Tang, R. J., Mu, B., Ferjani, A., Shi, J., Zhang, H., … Luan, S. (2018). Vacuolar proton pyrophosphatase is required for high magnesium tolerance in Arabidopsis. International Journal of Molecular Sciences, 19, 3617.
Yao, H. Y., & Xue, H. W. (2018). Phosphatidic acid plays key roles regulating plant development and stress responses. Journal of Integrative Plant Biology, 60, 851-863.
Zhang, L., Li, G., Wang, M., Di, D., Sun, L., Kronzucker, H. J., & Shi, W. (2018). Excess iron stress reduces root tip zone growth through nitric oxide-mediated repression of potassium homeostasis in Arabidopsis. New Phytologist, 219, 259-274.
Zhang, L., Wen, A., Wu, X., Pan, X., Wu, N., Chen, X., … Luan, S. (2019). Molecular identification of the magnesium transport gene family in Brassica napus. Plant Physiology and Biochemistry, 136, 204-214.
Zhang, Q., Lin, F., Mao, T. L., Nie, J. N., Yan, M., Yuan, M., & Zhang, W. H. (2012). Phosphatidic acid regulates microtubule organization by interacting with MAP65-1 in response to salt stress in Arabidopsis. Plant Cell, 24, 4555-4576.
Zhang, W. H., Qin, C. B., Zhao, J., & Wang, X. M. (2004). Phospholipase Dα1-derived phosphatidic acid interacts with ABI1 phosphatase 2C and regulates abscisic acid signaling. Proceedings of the National Academy of Sciences of the United States of America, 101, 9508-9513.
Zhang, Y. Y., Zhu, H. Y., Zhang, Q., Li, M. Y., Yan, M., Wang, R., … Wang, X. M. (2009). Phospholipase Dα1 and phosphatidic acid regulate NADPH oxidase activity and production of reactive oxygen species in ABA-mediated stomatal closure in Arabidopsis. Plant Cell, 21, 2357-2377.
Zhao, J. (2015). Phospholipase D and phosphatidic acid in plant defence response: From protein-protein and lipid-protein interactions to hormone signalling. Journal of Experimental Botany, 66, 1721-1736.
Zhao, J., Wang, C., Bedair, M., Welti, R., Sumner, W. L., Baxter, I., & Wang, X. (2011). Suppression of phospholipase Dγs confers increased aluminum resistance in Arabidopsis thaliana. PLoS ONE, 6(12), e28086. https://doi.org/10.1371/journal.pone.0028086.
Zhao, J., & Wang, X. M. (2004). Arabidopsis phospholipase Da1 interacts with the heterotrimeric G-protein a-subunit through a motif analogous to the DRY motif in G-protein-coupled receptors. Journal of Biological Chemistry, 279, 1794-1800.