Seed Fatty Acid Changes Germination Response to Temperature and Water Potentials in Six Sesame (Sesamum indicum L.) Cultivars: Estimating the Cardinal Temperatures

Balouchi, Hamidreza; Soltani Khankahdani, Vida; Moradi, Ali; Gholamhoseini, Majid; Piri, Ramin; Heydari, Seyedeh Zahra; Dedicova, Beata

doi:10.3390/agriculture13101936

Cited by 3 publications

(3 citation statements)

References 41 publications

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“…This research underscores that the interaction effect is contingent upon factors such as cultivar type, salinity levels, temperature, and the combined influence of salinity and temperature. Sesame exhibits high polymorphism and is recognised for possessing the greatest genetic diversity among crops [19], with its diverse cultivars exhibiting variations in stress tolerance during the germination phase [1]. The unequal response of cultivars' seed germination to increasing salinity under varying temperatures supports the proposition that the Oltan cultivar likely demonstrates salt tolerance at this stage.…”

Section: Germination Percentagementioning

confidence: 96%

“…Sesame (Sesamum indicum) has long held a distinguished position among oilseeds, celebrated for its culinary and nutritional value and adaptability to diverse environmental conditions [1]. As a versatile crop, sesame boasts an array of applications, from its seeds that yield high-quality oil and a rich source of protein, to the utilisation of its oilcake in animal feed [2].…”

Section: Introductionmentioning

confidence: 99%

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Sesame Germination Dynamics: Unravelling Sesame’s Response to Salinity and Temperature Variability

Gholamhoseini,

Dolatabadian

2024

Seeds

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Sesame (Sesamum indicum), a highly valued oilseed, faces challenges in cultivation, especially in regions susceptible to environmental stressors. This study investigates the interactive effects of salinity and temperature on sesame seed germination. Two cultivars, Darab 1 and Oltan, were subjected to various salinity levels (−3 to −12 bars) and temperatures (15 °C, 20 °C, and 25 °C). Results revealed that at 15 °C, salinity levels beyond -3 bars significantly reduced germination, while at 25 °C, 40% and 62% germination rates were recorded even at −12 bars for Darab 1 and Oltan, respectively. This study highlights the importance of temperature in mitigating the inhibitory effects of salinity on germination. Germination speed exhibited a decline with increasing salinity, particularly at lower temperatures. Shoot and root lengths and dry weights decreased with rising salinity, but Oltan demonstrated greater tolerance than Darab 1. The research emphasises the species-specific nature of temperature-salinity interactions and the intraspecific variability among sesame cultivars. Notably, Oltan, adapted to arid regions with elevated temperatures, displayed increased tolerance to salinity stress. These findings contribute to understanding sesame’s resilience to environmental stressors, aiding in developing resilient cultivars for challenging agricultural landscapes. Overall, temperature is pivotal in influencing sesame seed germination and early seedling growth under salinity stress, offering insights for optimised cultivation practices.

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Section: Germination Percentagementioning

confidence: 96%

Section: Introductionmentioning

confidence: 99%

Sesame Germination Dynamics: Unravelling Sesame’s Response to Salinity and Temperature Variability

Gholamhoseini,

Dolatabadian

2024

Seeds

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“…In any case, the availability of varieties with a higher MUFA content is desirable. On the other hand, the high variability in oleic and linoleic acid content could be of interest for consideration in breeding programs, since different studies in other plant species have shown that increasing the level of polyunsaturated fatty acid can improve seed performance in the field at low temperatures, and seeds with higher oleic content could be more adapted to high temperatures [45,46].…”

Section: Variation Of Fatty Acid Content In Bean Seedmentioning

confidence: 99%

Fatty Acids in Dry Beans (Phaseolus vulgaris L.): A Contribution to Their Analysis and the Characterization of a Diversity Panel

Rodríguez Madrera,

Campa Negrillo,

Ferreira Fernández

2024

Foods

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Dry bean (Phaseolus vulgaris L.) is a crop of high nutritional interest widespread throughout the world. This research had two objectives. On the one hand, the development and validation of an analytical method to quantify fatty acids in dry beans based on the extraction and derivatization in a single step and later quantification by gas chromatography. On the other, its application to characterize the fatty acid content in a diversity panel consisting of 172 lines. The method was successfully validated in terms of accuracy, precision and robustness. Among the 14 fatty acids that constitute the fatty acid profile of dry bean, the most quantitatively important were linolenic acid, the major fatty acid in all cases, with an average value of 6.7 mg/g, followed by linoleic acid (3.9 mg/g), palmitic acid (2.9 mg/g) and oleic acid (1.5 mg/g). The concentrations of fatty acids in dry bean were influenced by the gene pool, with the Mesoamerican gene pool showing a higher content of palmitic, stearic, linoleic and linolenic acids and the Andean gene pool a higher level of cis-vaccenic acid. Also, the expression of fatty acid content showed high heritability. The information generated constitutes a robust database of interest in food technology, nutrition and breeding programs.

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Triangle area model (TAM) for predicting germination: An approach to enhance hydrothermal time model applications

Oveisi,

Alizadeh,

Lorestani

et al. 2024

Current Plant Biology

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Seed Fatty Acid Changes Germination Response to Temperature and Water Potentials in Six Sesame (Sesamum indicum L.) Cultivars: Estimating the Cardinal Temperatures

Cited by 3 publications

References 41 publications

Sesame Germination Dynamics: Unravelling Sesame’s Response to Salinity and Temperature Variability

Sesame Germination Dynamics: Unravelling Sesame’s Response to Salinity and Temperature Variability

Fatty Acids in Dry Beans (Phaseolus vulgaris L.): A Contribution to Their Analysis and the Characterization of a Diversity Panel

Triangle area model (TAM) for predicting germination: An approach to enhance hydrothermal time model applications

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