Juan Carlos Alvarez‐Pizarro scite author profile

An effective strategy for re-establishing K+ and Na+ homeostasis is a challenge for the improvement of plant performance in saline soil. Specifically, attempts to understand the mechanisms of Na+ extrusion from plant cells, the control of Na+ loading in the xylem and the partitioning of the accumulated Na+ between different plant organs are ongoing. Our goal was to provide insight into how an external nitrogen source affects Na+ accumulation in Sorghum bicolor under saline conditions. The NH4+ supply improved the salt tolerance of the plant by restricting Na+ accumulation and improving the K+/Na+ homeostasis in shoots, which was consistent with the high activity and expression of Na+/H+ antiporters and proton pumps in the plasma membrane and vacuoles in the roots, resulting in low Na+ loading in the xylem. Conversely, although NO3--grown plants had exclusion and sequestration mechanisms for Na+, these responses were not sufficient to reduce Na+ accumulation. In conclusion, NH4+ acts as an efficient signal to activate co-ordinately responses involved in the regulation of Na+ homeostasis in sorghum plants under salt stress, which leads to salt tolerance.

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Salt-induced changes on H+-ATPase activity, sterol and phospholipid content and lipid peroxidation of root plasma membrane from dwarf-cashew (Anacardium occidentale L.) seedlings

Alvarez‐Pizarro

Gomes-Filho

Lacerda

et al. 2009

Plant Growth Regul

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The effects of NaCl stress on the growth, water relation, gas exchange, tissue mineral content, and on H ? -ATPase activity, lipid composition and peroxidation of root plasma membrane-enriched fractions of two genotypes (CCP06 and BRS189, sensitive and tolerant to salt stress, respectively) of dwarf-precocious cashew were studied. Growth reduction was higher in CCP06 than in BRS189. Net photosynthesis decreased in both genotypes, CCP06 being more affected. Roots of BRS189 accumulated higher amount of Na ? than those of CCP06 at both salt treatments, whereas Cl -increase was higher only at 8 dS m -1 . NaCl at 8 dS m -1 did not modify the plasma membrane H ? -ATPase activity in CCP06 roots, but significantly increased it in BRS189 roots. Lipid peroxidation was lower in BRS189 than in CCP06 roots. Salinity induced higher accumulation of proline in BRS189 roots. Total phospholipids and free sterols content increased significantly in root plasma membrane of CCP06. However, in BRS189, a slight reduction of free sterols content and no changes in total phospholipids content were observed. Thus, the results suggest that the ability of cashew seedlings to adapt to salt stress is, at least in part, dependent upon the maintenance of integrity and protection against oxidative damage of plasma membrane, which could favor the activation of plasma membrane H ? -ATPase, as a cellular mechanism to regulate ion exclusion from the shoot.

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Seed reserve composition and mobilization during germination and early seedling establishment of Cereus jamacaru D.C. ssp. jamacaru (Cactaceae)

Alencar

Innecco

Gomes-Filho

et al. 2012

An. Acad. Bras. Ciênc.

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Cereus jamacaru, a Cactaceae found throughout northeast Brazil, is widely used as cattle food and as an ornamental and medicinal plant. However, there has been little information about the physiological and biochemical aspects involved in its germination. The aim of this study was to investigate its reserve mobilization during germination and early seedling growth. For this, C. jamacaru seeds were germinated in a growth chamber and collected at 0, 2, 4, 5, 6, 8 and 12 days after imbibition for morphological and biochemical analyses. Dry seeds had wrinkled seed coats and large, curved embryos. Lipids were the most abundant reserve, comprising approximately 55% and 65% of the dry mass for cotyledons and the hypocotylradicle axis, respectively. Soluble sugars and starch were the minor reserves, corresponding to approximately 2.2% of the cotyledons' dry mass, although their levels showed significant changes during germination. Soluble proteins corresponded to 40% of the cotyledons' dry mass, which was reduced by 81% at the final period of germination compared to dry seeds. C. jamacaru seed can be classified as an oil seed due to its high lipid content. Moreover, lipids were the main reserve mobilized during germination because their levels were strongly reduced after seed germination, while proteins were the second most utilized reserve in this process.

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Putative role of glutamine in the activation of CBL/CIPK signalling pathways during salt stress in sorghum

Miranda

Alvarez‐Pizarro

Costa

et al. 2017

Plant Signaling & Behavior

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The salt overly sensitive (SOS) pathway is the only mechanism known for Na extrusion in plant cells. SOS pathway activation involves Ca-sensing proteins, such as calcineurin B-like (CBL) proteins, and CBL-interacting protein kinases (CIPKs). In this signalling mechanism, a transit increase in cytosolic Ca concentration triggered by Na accumulation is perceived by CBL (also known as SOS3). Afterward, SOS3 physically interacts with a CIPK (also known as SOS2), forming the SOS2/SOS3 complex, which can regulate the number downstream targets, controlling ionic homeostasis. For instance, the SOS2/SOS3 complex phosphorylates and activates the SOS1 plasmalemma protein, which is a Na/H antiporter that extrudes Na out of the cell. The CBL-CIPK networking system displays specificity, complexity and diversity, constituting a critical response against salt stress and other abiotic stresses. In a study reported in the journal Plant and Cell Physiology, we showed that NH induces the robust activation of transporters for Na homeostasis in root cells, especially the SOS1 antiporter and plasma membrane H-ATPase, differently than does NO. Despite some studies having shown that external NH ameliorates salt-induced effects on ionic homeostasis, there is no evidence that NH per se or some product of its assimilation is responsible for these responses. Here, we speculate about the signalling role behind glutamine in CBL-CIPK modulation, which could effectively activate the SOS pathway in NH-fed stressed plants.

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Ammonium improves tolerance to salinity stress in Sorghum bicolor plants

2015

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