The role of cotyledon metabolism in the establishment of quinoa (Chenopodium quinoa) seedlings growing under salinity

Ruffino, Ana María C.; Rosa, Mariana; Hilal, Mirna; González, Juan Antonio Suarez; Prado, Fernando Eduardo

doi:10.1007/s11104-009-9999-8

Cited by 97 publications

(77 citation statements)

References 61 publications

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“…The results presented in Figure 1, Tables 3 and 4 are agreement with Ana Maria et al (2010) who decided that, relative water content, chlorophyll, carotenoids, lipids, and proteins traits in quinoa seedlings were significantly lower under salinity (250 mM NaCl) and Eisa et al (2012) who reported that, the net photosynthesis rates of quinoa plant were greatly decreased by high salinity, being 28% of initial control values at 500 mM NaCl also they reported that salt-induced growth reduction is presumably due to low photosynthetic supply as a Vol. 7, No.…”

Section: Effect Of Salinity On the Vegetative And Physiological Traitssupporting

confidence: 87%

“…There is also evidence to support the view that salt tolerance is a complex physiological trait affecting entirely the plant's life (Flowers, 2004). In addition, the quinoa plant is reported to be tolerant to drought (Garcia et al, 2007), and also resists frost before the flower-bud formation stage (Jacobsen et al, 2005) and salinity (Ruffino et al, 2010;Hariadi et al, 2011). However, the definition of indicators that plant breeders might apply in open field to improve quinoa, for its tolerance or adjustment to saline environments, is still a matter of debate (Razzaghi et al, 2011a).…”

Section: Introductionmentioning

confidence: 95%

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Effect of Irrigation Water Salinity on the Growth of Quinoa Plant Seedlings

Algosaibi¹,

El-Garawany²,

Badran³

et al. 2015

JAS

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The experiment aimed to study the effect of the irrigation water quality on the growth of seedlings and its yield of quinoa plant through some traits i.e., plant height, number of leaves per plant, 1000 grains weight, dry weight per plant , stem diameter, inflorescence length and grain yield per plant. Four treatments were used as follow: T1 (low salinity water, EC 1.25 dS m -1 ), T2 (mix water between low salinity water and agricultural drainage water at ratio 1:1, EC 4 dS m -1 ), T3 (agricultural drainage water, EC 8 dS m -1 ) and T4 (high salinity water, EC 16 dS m -1 ). The treatments application was at the beginning of the plant buds so that the amount of irrigation water up to 75% from field capacity. The significant effects of treatments were found on all tested traits. Also, the results clarified that the rate of chlorophyll ranged between 44.18 (treatment T4) and 53.75 SPAD (treatment T3), water potential of the fourth leaf has ranged from -0.83 to -1.745 MPa for T1 and T3 treatments, respectively, number of leaves per plant was ranged between 26.5 and 28.5 when the plants were irrigated with T4 and T1 irrigation water treatments, respectively. The inflorescence lengths were varied between 8 cm at T4 treatment and 12 cm at T2 treatment. The plant height was ranged between 53.5 cm (T4) and 60.75 cm (T3). The low values of seed yield were recorded at T4 (17.05 g/plant) while the higher values were recorded with T2 treatment (34.08 g/plant). 1000-grain weight values were ranged between 2.97 g at T2 treatment, and 3.49 g at treatment T1.

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Section: Effect Of Salinity On the Vegetative And Physiological Traitssupporting

confidence: 87%

Section: Introductionmentioning

confidence: 95%

Effect of Irrigation Water Salinity on the Growth of Quinoa Plant Seedlings

Algosaibi¹,

El-Garawany²,

Badran³

et al. 2015

JAS

View full text Add to dashboard Cite

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“…The many salt-related studies have ranged from seed germination effects to whole plant growth, physiological to anatomical changes, biochemical composition differences to biomass and yield reduction and covered a very wide range of plant species (Niazi et al, 1987;Katerji et al, 1994;Poljakoff-Mayber et al, 1994;Villiers et al, 1994;Rogers et al, 1995;Reinhardt and Rost, 1995 a, b;Zidan and Elewa, 1995;Huang and Redmann, 1995;Wahid et al, 1998;Croser et al, 2001;Al-Mutawa, 2003;Turhan and Ayaz, 2004;Song et al, 2008;MaiaI et al, 2010;Ruffino et al, 2010).…”

Section: Introductionmentioning

confidence: 99%

The effects of humic acid on growth and ion uptake of mung bean (Vigna radiata (L.) Wilczek) grown under salt stress

Kalyoncu¹,

Akinci²,

Bozkurt³

2017

Afr. J. Agric. Res.

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The study aimed to determine the effects of humic acid (HA) on seedlings of a salt-sensitive plant, mung bean (Vigna radiata (L.) Wilczek), grown on 50 mM (S1) and 100 mM (S2) NaCl concentrations. In controlled room conditions, mung bean seedlings were planted in pots containing torf and perlite mixture and salt effects were observed. The growth parameters were plant height, number of leaves, leaf area, leaf and stem fresh and dry weights in which all parameters significantly decreased at both salt levels. Nutrient analyses of Na, K and Ca were conducted by flame photometry (FP), and Mg, Mn, Zn were tested by inductively coupled plasma atomic emission spectrometry (ICP-AES), for the above and below ground parts of mung bean seedlings. Both salt treatments increased Na content significantly, however 10 ml addition of HA to those samples (S1HA and S2HA; 50 mM NaCl and 100 mM NaCl, respectively) caused reductions in Na contents of the above-ground parts of mung bean compared to plants watered with only Hoagland-Arnon solutions (HO). On the other hand, in the roots of mung bean seedlings, Na content rose significantly in S2 compared with control, but the amount of Na in S2HA significantly increased compared with S2 treated plants. K content was significantly decreased in both salt concentrations, while SHA1 and SHA2 caused slight increases in both above and underground parts of seedlings. In the experiment, SHA2 increased the content of K, Mg, Ca, Mn and Zn in the root of mung bean seedlings compared with both S1 and S2 treatments.

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“…Mannitol, proline and myo-inositol are the compatible solutes present in quinoa (Ruffino et al, 2010) with the ability to scavenge ROS (Szabados and Savouré, 2010). Tolerance of quinoa to salinity may be credited to its efficient retention of K + (Ruffino et al, 2010).…”

Section: Introductionmentioning

confidence: 99%

“…Tolerance of quinoa to salinity may be credited to its efficient retention of K + (Ruffino et al, 2010). Salinity caused a decrease in transpiration and thus gas exchange in quinoa (Sanchez et al, 2003).…”

Section: Introductionmentioning

confidence: 99%

Exploring the Potential of Quinoa Accessions for Salt Tolerance in Soilless Culture

Saleem¹,

Basra²,

Afzal³

et al. 2017

IJAB

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Pakistan has more than 6 million hectares of salt affected land and quinoa is tested as a facultative halophyte having super food characteristics. A hydroponic study was conducted to explore salt tolerance of two quinoa accessions, Ames-13737 (Q7) and PI-634919 (Q9) under a range of NaCl levels (0, 100, 200 and 300 mM) in wirehouse during 2016. Plant nursery was raised, and at four leaf stage, the seedlings were transferred to plastic tubs containing 20 L half strength Hoagland's solution as nutrient source. Salinity was developed incrementally to avoid osmotic shock after two days of transplanting. Results showed that growth (shoot length, root length and dry weight/plant) reduced drastically in Q9 by increasing the salinity level as compared to Q7. However, a comparable growth was observed in Q-7 at 0 and 100 mM i.e. the dry weight at 0 and 100 mM salinity were 0.8643 g and 0.8125 g, respectively. Furthermore, genotype Q7 was found better than Q9 by producing 10% more dry weight (0.2790 g) at the highest salinity level which was linked to 57% more leaf K + accumulation (28.64 mg K + g -1 dry weight) as compared to Q9 (12.54 mg K + g -1 dry weight). It is concluded that tolerance of Q7 to salt stress might be due to more absorption of K + by the roots at increased Na + level.

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The role of cotyledon metabolism in the establishment of quinoa (Chenopodium quinoa) seedlings growing under salinity

Cited by 97 publications

References 61 publications

Effect of Irrigation Water Salinity on the Growth of Quinoa Plant Seedlings

Effect of Irrigation Water Salinity on the Growth of Quinoa Plant Seedlings

The effects of humic acid on growth and ion uptake of mung bean (Vigna radiata (L.) Wilczek) grown under salt stress

Exploring the Potential of Quinoa Accessions for Salt Tolerance in Soilless Culture

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