The Halophyte Species Solanum chilense Dun. Maintains Its Reproduction despite Sodium Accumulation in Its Floral Organs

Bigot, Servane; Pongrac, Paula; Šala, Martin; Elteren, Johannes van; Martínez, Juan-Pablo; Lutts, Stanley; Quinet, Muriel

doi:10.3390/plants11050672

Cited by 6 publications

(4 citation statements)

References 104 publications

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“…Na + content was increased in roots and fruits by a ratio of 2.94 and 1.45, respectively, as compared with fresh water-irrigated plants (Figure 3a,b). It is reported that sodium ions could accumulate in inflorescences, pericarp, and even in tomato seeds under salinity stress, however, in higher amounts compared with data produced in this study [52,53]. Although fruits (the marketable part of the tomato) accumulated more sodium ions under a saline irrigation regime of 3000 ppm NaCl (no BC, 77.8 mg/100 gm), the sodium level in dried fruits was below the risk threshold according to USDA health standards [54].…”

Section: Soil Propertiescontrasting

confidence: 60%

Effect of Biochar Application to Fertile Soil on Tomato Crop Production under Saline Irrigation Regime

et al. 2022

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Biochar application is a promising sustainable strategy for enhancing soil properties thus crop production. However, biochar application to soil certainly alters its biological and physical properties, and could require extra costs. Therefore, biochar suitability to agroecosystems must be proactively estimated. The advantage of biochar addition to poor fertile or weathered soils has been well studies, however, its feasibility to fertile soil under low quality (saline) irrigation water was not frequently studied. Consequently, this work investigates the hypothesis of whether the application of biochar at a rate of 4.8 tons/ha to fertile soil (Nile Valley, Giza, Egypt) would ameliorate the negative effects of saline irrigation regime (3000 ppm) on tomato crop and soil. The results of two seasons experiments showed that saline irrigation significantly reduced tomato crop yield by an average reduction ratio of 51%, and biochar addition could not compensate such reduction. Furthermore, biochar did not reduce accumulated Na+ in fruits or roots. Tomato fruits produced from biochar-added soil were lower in TSS levels (41.7% reduction ratio) yet larger in diameter by approximately 1.5-fold increase. Interestingly, biochar addition into soil greatly promotes the length of stem-borne lateral roots and elevates the expression of LeNR (encodes nitrate reductase enzyme) in leaves yet under fresh irrigation regime. For soil properties, biochar application enhanced the soil properties under either saline or fresh water irrigation conditions. Collectively, it is assumed that biochar application to fertile soil in Nile Valley of Egypt could not alleviate tomato fruits yield reduction affected by applied saline irrigation regime.

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Section: Soil Propertiescontrasting

confidence: 60%

Effect of Biochar Application to Fertile Soil on Tomato Crop Production under Saline Irrigation Regime

et al. 2022

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“…For instance, salt-tolerant wild relatives of tomato, such as S. chilense and S. pennellii , exhibit significantly higher leaf Na + content compared to their more sensitive counterpart, S. lycopersicum - up to ten-fold higher in the case of S. chilense [5,7]. These species seem to have a different strategy from S. lycopersicum , maintaining high levels of sodium leaf content, but investing more in sodium sequestration as suggested by an increased expression of tonoplast-localised NHX-type Na + /H + exchangers compared to their homologues in cultivated tomato [5,7]. In such species, the high accumulation of Na + in the leaves acts as a cheap osmoticum to minimise the high energy cost of osmolyte synthesis.…”

Section: Discussionmentioning

confidence: 99%

“…Native to western South America, numerous wild relatives of tomato, such as S. pennellii, S. chilense, and S. cheesmaniae, are adapted to saline environments. Notably, these species have demonstrated higher salinity tolerance than S. lycopersicum [5][6][7], indicating a promising avenue for identifying salt resistance genes and quantitative trait loci (QTLs).…”

Section: Introductionmentioning

confidence: 99%

Characterization of a major QTL for sodium accumulation in tomato shoot

Héreil,

Guillaume,

Duboscq

et al. 2024

Preprint

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Soil salinity is a serious concern for tomato culture, affecting both yield and quality parameters. Although some genes involved in tomato salt tolerance have been identified, their genetic diversity has been rarely studied. In the present study, we assessed salt tolerance-related traits at juvenile and adult stages in a large core collection and identified salt tolerance QTLs by genome-wide association study (GWAS). The results suggested that a major QTL is involved in leaf sodium accumulation at both physiological stages. We were able to identify the underlying candidate gene, a well-known sodium transporter, called SlHKT1.2. We showed that an eQTL for the expression of this gene colocalized with the sodium content QTL. A polymorphism putatively responsible for its variation was identified in the gene promoter. Finally, to extend the applicability of these results, we carried out the same analysis on a test-cross panel composed of the core collection crossed with a distant line. The results indicated that the identified QTL retained its functional impact even in a hybrid genetic context: this paves the way for its use in breeding programs aimed at improving salinity tolerance in tomato cultivars.

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“…Similarly, Bigot et al [ 27 ] also compared the salt resistance of a crop, tomato ( Solanum lycopersicum ), and a wild relative, S. chilense (Solanaceae), focusing on the reproductive phase, particularly Na localisation in floral organs. Salinity was found to affect reproductive development in the two species, but in different ways.…”

Section: Special Issue Contentsmentioning

confidence: 99%

Wild Halophytes: Tools for Understanding Salt Tolerance Mechanisms of Plants and for Adapting Agriculture to Climate Change

Grigore

Vicente

2023

Plants

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Halophytes, wild plants adapted to highly saline natural environments, represent extremely useful—and, at present, underutilised—experimental systems with which to investigate the mechanisms of salt tolerance in plants at the anatomical, physiological, biochemical and molecular levels. They can also provide biotechnological tools for the genetic improvement of salt tolerance in our conventional crops, such as salt tolerance genes or salt-induced promoters. Furthermore, halophytes may constitute the basis of sustainable ‘saline agriculture’ through commercial cultivation after some breeding to improve agronomic traits. All these issues are relevant in the present context of climate emergency, as soil salinity is—together with drought—the most critical environmental factor in reducing crop yield worldwide. In fact, climate change represents the most serious challenge for agricultural production and food security in the near future. Several of the topics mentioned above—mainly referring to basic studies on salt tolerance mechanisms—are addressed in the articles published within this Special Issue.

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The Halophyte Species Solanum chilense Dun. Maintains Its Reproduction despite Sodium Accumulation in Its Floral Organs

Cited by 6 publications

References 104 publications

Effect of Biochar Application to Fertile Soil on Tomato Crop Production under Saline Irrigation Regime

Effect of Biochar Application to Fertile Soil on Tomato Crop Production under Saline Irrigation Regime

Characterization of a major QTL for sodium accumulation in tomato shoot

Wild Halophytes: Tools for Understanding Salt Tolerance Mechanisms of Plants and for Adapting Agriculture to Climate Change

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