Differential activity of Plasma and Vacuolar Membrane Transporters contributes to Genotypic Differences in Salinity Tolerance in a Halophyte Species, Chenopodium quinoa

Edgar  Bonales-Alatorre; Igor Pottosin; Lana  Shabala; Zhong-Hua Chen; Fanrong  Zeng; Sven-Erik Jacobsen; Sergey  Shabala

doi:10.3390/ijms14059267

Differential activity of Plasma and Vacuolar Membrane Transporters contributes to Genotypic Differences in Salinity Tolerance in a Halophyte Species, Chenopodium quinoa

Edgar Bonales-Alatorre, Igor Pottosin, Lana Shabala, Zhong-Hua Chen, Fanrong Zeng, Sven-Erik Jacobsen, Sergey Shabala

Afgrødevidenskab

64 Citationer (Scopus)

Abstract

Halophytes species can be used as a highly convenient model system to reveal key ionic and molecular mechanisms that confer salinity tolerance in plants. Earlier, we reported that quinoa (Chenopodium quinoa Willd.), a facultative C3 halophyte species, can efficiently control the activity of slow (SV) and fast (FV) tonoplast channels to match specific growth conditions by ensuring that most of accumulated Na+ is safely locked in the vacuole (Bonales-Alatorre et al. (2013) Plant Physiology). This work extends these finding by comparing the properties of tonoplast FV and SV channels in two quinoa genotypes contrasting in their salinity tolerance. The work is complemented by studies of the kinetics of net ion fluxes across the plasma membrane of quinoa leaf mesophyll tissue. Our results suggest that multiple mechanisms contribute towards genotypic differences in salinity tolerance in quinoa. These include: (i) a higher rate of Na+ exclusion from leaf mesophyll; (ii) maintenance of low cytosolic Na+ levels; (iii) better K+ retention in the leaf mesophyll; (iv) a high rate of H+ pumping, which increases the ability of mesophyll cells to restore their membrane potential; and (v) the ability to reduce the activity of SV and FV channels under saline conditions. These mechanisms appear to be highly orchestrated, thus enabling the remarkable overall salinity tolerance of quinoa species.

Originalsprog	Engelsk
Tidsskrift	International Journal of Molecular Sciences (Online)
Vol/bind	14
Udgave nummer	5
Sider (fra-til)	9267-9285
Antal sider	19
ISSN	1661-6596
DOI	https://doi.org/10.3390/ijms14059267
Status	Udgivet - maj 2013

Adgang til dokumentet

10.3390/ijms14059267

Citationsformater

Bonales-Alatorre, E., Pottosin, I., Shabala, L., Chen, Z-H., Zeng, F., Jacobsen, S-E., & Shabala , S. (2013). Differential activity of Plasma and Vacuolar Membrane Transporters contributes to Genotypic Differences in Salinity Tolerance in a Halophyte Species, Chenopodium quinoa. International Journal of Molecular Sciences (Online), 14(5), 9267-9285. https://doi.org/10.3390/ijms14059267

Differential activity of Plasma and Vacuolar Membrane Transporters contributes to Genotypic Differences in Salinity Tolerance in a Halophyte Species, Chenopodium quinoa. / Bonales-Alatorre, Edgar ; Pottosin, Igor; Shabala, Lana et al.

I: International Journal of Molecular Sciences (Online), Bind 14, Nr. 5, 05.2013, s. 9267-9285.

Publikation: Bidrag til tidsskrift › Tidsskriftartikel › Forskning › peer review

Bonales-Alatorre, E, Pottosin, I, Shabala, L, Chen, Z-H, Zeng, F, Jacobsen, S-E & Shabala , S 2013, 'Differential activity of Plasma and Vacuolar Membrane Transporters contributes to Genotypic Differences in Salinity Tolerance in a Halophyte Species, Chenopodium quinoa', International Journal of Molecular Sciences (Online), bind 14, nr. 5, s. 9267-9285. https://doi.org/10.3390/ijms14059267

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title = "Differential activity of Plasma and Vacuolar Membrane Transporters contributes to Genotypic Differences in Salinity Tolerance in a Halophyte Species, Chenopodium quinoa",

abstract = "Halophytes species can be used as a highly convenient model system to reveal key ionic and molecular mechanisms that confer salinity tolerance in plants. Earlier, we reported that quinoa (Chenopodium quinoa Willd.), a facultative C3 halophyte species, can efficiently control the activity of slow (SV) and fast (FV) tonoplast channels to match specific growth conditions by ensuring that most of accumulated Na+ is safely locked in the vacuole (Bonales-Alatorre et al. (2013) Plant Physiology). This work extends these finding by comparing the properties of tonoplast FV and SV channels in two quinoa genotypes contrasting in their salinity tolerance. The work is complemented by studies of the kinetics of net ion fluxes across the plasma membrane of quinoa leaf mesophyll tissue. Our results suggest that multiple mechanisms contribute towards genotypic differences in salinity tolerance in quinoa. These include: (i) a higher rate of Na+ exclusion from leaf mesophyll; (ii) maintenance of low cytosolic Na+ levels; (iii) better K+ retention in the leaf mesophyll; (iv) a high rate of H+ pumping, which increases the ability of mesophyll cells to restore their membrane potential; and (v) the ability to reduce the activity of SV and FV channels under saline conditions. These mechanisms appear to be highly orchestrated, thus enabling the remarkable overall salinity tolerance of quinoa species.",

author = "Edgar Bonales-Alatorre and Igor Pottosin and Lana Shabala and Zhong-Hua Chen and Fanrong Zeng and Sven-Erik Jacobsen and Sergey Shabala",

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AU - Shabala, Lana

AU - Chen, Zhong-Hua

AU - Zeng, Fanrong

AU - Jacobsen, Sven-Erik

AU - Shabala , Sergey

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N2 - Halophytes species can be used as a highly convenient model system to reveal key ionic and molecular mechanisms that confer salinity tolerance in plants. Earlier, we reported that quinoa (Chenopodium quinoa Willd.), a facultative C3 halophyte species, can efficiently control the activity of slow (SV) and fast (FV) tonoplast channels to match specific growth conditions by ensuring that most of accumulated Na+ is safely locked in the vacuole (Bonales-Alatorre et al. (2013) Plant Physiology). This work extends these finding by comparing the properties of tonoplast FV and SV channels in two quinoa genotypes contrasting in their salinity tolerance. The work is complemented by studies of the kinetics of net ion fluxes across the plasma membrane of quinoa leaf mesophyll tissue. Our results suggest that multiple mechanisms contribute towards genotypic differences in salinity tolerance in quinoa. These include: (i) a higher rate of Na+ exclusion from leaf mesophyll; (ii) maintenance of low cytosolic Na+ levels; (iii) better K+ retention in the leaf mesophyll; (iv) a high rate of H+ pumping, which increases the ability of mesophyll cells to restore their membrane potential; and (v) the ability to reduce the activity of SV and FV channels under saline conditions. These mechanisms appear to be highly orchestrated, thus enabling the remarkable overall salinity tolerance of quinoa species.

AB - Halophytes species can be used as a highly convenient model system to reveal key ionic and molecular mechanisms that confer salinity tolerance in plants. Earlier, we reported that quinoa (Chenopodium quinoa Willd.), a facultative C3 halophyte species, can efficiently control the activity of slow (SV) and fast (FV) tonoplast channels to match specific growth conditions by ensuring that most of accumulated Na+ is safely locked in the vacuole (Bonales-Alatorre et al. (2013) Plant Physiology). This work extends these finding by comparing the properties of tonoplast FV and SV channels in two quinoa genotypes contrasting in their salinity tolerance. The work is complemented by studies of the kinetics of net ion fluxes across the plasma membrane of quinoa leaf mesophyll tissue. Our results suggest that multiple mechanisms contribute towards genotypic differences in salinity tolerance in quinoa. These include: (i) a higher rate of Na+ exclusion from leaf mesophyll; (ii) maintenance of low cytosolic Na+ levels; (iii) better K+ retention in the leaf mesophyll; (iv) a high rate of H+ pumping, which increases the ability of mesophyll cells to restore their membrane potential; and (v) the ability to reduce the activity of SV and FV channels under saline conditions. These mechanisms appear to be highly orchestrated, thus enabling the remarkable overall salinity tolerance of quinoa species.

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