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Showing 3 results for Sharifzadeh
Fatemeh Ghorbannezhad, Mohsen Zavareh, Farzad Sharifzadeh,
Volume 10, Issue 1 ((Spring and Summer) 2023)
Volume 10, Issue 1 ((Spring and Summer) 2023)
Abstract
Extended abstract
Introduction: Linseed (Linum usitatissimum L.) is a multipurpose crop and is cultivated to obtain oil, fiber, and seeds. Under optimal moisture conditions, the temperature is considered an environmental factor affecting the germination of this crop. Hence, knowing the cardinal temperatures can help farmers to predict the successful germination, emergence, and even yield of linseed and help scientists to develop new cultivars that are more tolerant to high temperatures. Therefore, this study was performed to determine the temperature range and the cardinal temperatures of germination in two linseed genotypes.
Material and methods: The germination response of two linseed genotypes (Golchin genotype and Line 286) to nine temperatures (3, 5, 10, 15, 20, 25, 30, 35, and 40 Celsius degrees) was quantified in a CRD based split-plot experiment with four replications. For this purpose, three nonlinear regression models (beta, segmented, and dent-like) were used to fit to the data and select the superior model. The superior model was selected using the Akaike information index (AIC), the modified Akaike index (AICc), and ∆i.
Results: Findings showed that the beta model had the best performance in estimating the line 286 cardinal temperatures according to its lower AIC (-3.96), AICc (-89.61), and ∆i (0). Accordingly, the base, optimum, and maximum temperature as well as the number of biological hours estimated by this model for Line 286 were 7.18, 24.22, 40.16 Celsius degrees, and 19.25 hours, respectively. In the Golchin genotype, the beta model with the lowest AIC=-3.89 and AICc= -89.083 fitted better compared with the other models. Nonetheless, considering ∆i for beta which was respectively 0, 1.61, and 4.49 for beta, segmented, and dent-like models, Beta and segmented models had a similar accuracy in estimation of cardinal temperatures for Golchin genotype. These findings represent that the suitable temperature range for germination of the Golchin genotype is 3.8- 23.85 Celsius degrees and the range of biological hours to 50% of germination varied from 16.42 to 19.77 hours.
Conclusion: Overall, according to the results of this study, it is possible to predict the time to germination under optimal moisture conditions using the beta model for Line 286 and one of the two beta and segmented models for the Golchin genotype.
Highlights:
1. A suitable model was developed for a suitable prediction of the seed germination percentage of two linseed genotypes (Golchin genotype and Line 286).
2. The cardinal temperatures for two linseed genotypes (Golchin genotype and Line 286) were determined.
Introduction: Linseed (Linum usitatissimum L.) is a multipurpose crop and is cultivated to obtain oil, fiber, and seeds. Under optimal moisture conditions, the temperature is considered an environmental factor affecting the germination of this crop. Hence, knowing the cardinal temperatures can help farmers to predict the successful germination, emergence, and even yield of linseed and help scientists to develop new cultivars that are more tolerant to high temperatures. Therefore, this study was performed to determine the temperature range and the cardinal temperatures of germination in two linseed genotypes.
Material and methods: The germination response of two linseed genotypes (Golchin genotype and Line 286) to nine temperatures (3, 5, 10, 15, 20, 25, 30, 35, and 40 Celsius degrees) was quantified in a CRD based split-plot experiment with four replications. For this purpose, three nonlinear regression models (beta, segmented, and dent-like) were used to fit to the data and select the superior model. The superior model was selected using the Akaike information index (AIC), the modified Akaike index (AICc), and ∆i.
Results: Findings showed that the beta model had the best performance in estimating the line 286 cardinal temperatures according to its lower AIC (-3.96), AICc (-89.61), and ∆i (0). Accordingly, the base, optimum, and maximum temperature as well as the number of biological hours estimated by this model for Line 286 were 7.18, 24.22, 40.16 Celsius degrees, and 19.25 hours, respectively. In the Golchin genotype, the beta model with the lowest AIC=-3.89 and AICc= -89.083 fitted better compared with the other models. Nonetheless, considering ∆i for beta which was respectively 0, 1.61, and 4.49 for beta, segmented, and dent-like models, Beta and segmented models had a similar accuracy in estimation of cardinal temperatures for Golchin genotype. These findings represent that the suitable temperature range for germination of the Golchin genotype is 3.8- 23.85 Celsius degrees and the range of biological hours to 50% of germination varied from 16.42 to 19.77 hours.
Conclusion: Overall, according to the results of this study, it is possible to predict the time to germination under optimal moisture conditions using the beta model for Line 286 and one of the two beta and segmented models for the Golchin genotype.
Highlights:
1. A suitable model was developed for a suitable prediction of the seed germination percentage of two linseed genotypes (Golchin genotype and Line 286).
2. The cardinal temperatures for two linseed genotypes (Golchin genotype and Line 286) were determined.
Mohammad Rezaee Chermehini, Farzad Sharifzadeh, Manijeh Sabokdast,
Volume 11, Issue 1 ((Spring and Summer) 2024)
Volume 11, Issue 1 ((Spring and Summer) 2024)
Abstract
Extended abstract
Introduction: In order to improve seed germination under environmental stress conditions such as salinity, one of the solutions is to use seed priming. Despite this advantage of priming, the longevity of primed seeds usually decreases and it has been observed that using post-priming treatments such as heat shock can improve the longevity of primed seeds. This research investigates the effect of seed priming with salicylic acid, methyl jasmonate, and brassinosteroid under salinity stress and the effect of heat shock after priming on improving the longevity of primed seeds.
Materials and Methods: The effect of seed priming with hormonal substances such as methyl jasmonate at three concentrations of 1, 100, and 1000 micromolar and brassinosteroid at three concentrations of 25, 75, and 100 mg/liter on increasing the seed germination traits of Suaeda fruticosa was investigated under salinity stress during separate experiments. In both studied hormones, priming temperatures of 5, 10, and 15°C were used for 1 and 2 days. Hormonal seed priming with salicylic acid at a concentration of 25 mg L-1 for 2 days at 10°C -obtained from the previous results (unpublished)- was used for comparison with those of the studied treatments. To determine the most suitable accelerated aging stress for evaluating and determining the best heat shock treatment, the accelerated aging test of seeds was carried out for two, four, six, eight, and ten days. In this research, to improve the longevity of primed seeds, they were exposed to heat shock treatment at temperatures of 30, 35, and 40°C for 1, 2, 3, and 4 hours after seed priming.
Results: Both seed priming treatments with methyl jasmonate and brassinosteroid significantly increased all the tested germination traits compared to the control (without priming). This increase in traits such as germination percentage, vigor index, and seedling length in seed priming with methyl jasmonate was 46.4%, 67%, and 41%, respectively, and in the case of priming with brassinosteroid was 32%, 44%, and 38%, respectively. Also, in this research, the heat shock treatment at 40°C for four hours after priming had a significant and positive effect on seed germination. Application of the mentioned treatment increased germination by 60% at the end of the aging period compared with the control (without the application of heat shock).
Conclusions: Despite the significant increase in germination percentage by each of the hormonal substances like methyl jasmonate and brassinosteroid, the comparison of the best treatment combination of these substances with salicylic acid showed that seed priming with 25 mg L-1 of salicylic acid for two days at 10°C caused a significant increase in the percentage of germination under salinity stress. Also, the heat-shock post-priming treatment significantly improved the longevity of primed seeds.
Highlights:
Introduction: In order to improve seed germination under environmental stress conditions such as salinity, one of the solutions is to use seed priming. Despite this advantage of priming, the longevity of primed seeds usually decreases and it has been observed that using post-priming treatments such as heat shock can improve the longevity of primed seeds. This research investigates the effect of seed priming with salicylic acid, methyl jasmonate, and brassinosteroid under salinity stress and the effect of heat shock after priming on improving the longevity of primed seeds.
Materials and Methods: The effect of seed priming with hormonal substances such as methyl jasmonate at three concentrations of 1, 100, and 1000 micromolar and brassinosteroid at three concentrations of 25, 75, and 100 mg/liter on increasing the seed germination traits of Suaeda fruticosa was investigated under salinity stress during separate experiments. In both studied hormones, priming temperatures of 5, 10, and 15°C were used for 1 and 2 days. Hormonal seed priming with salicylic acid at a concentration of 25 mg L-1 for 2 days at 10°C -obtained from the previous results (unpublished)- was used for comparison with those of the studied treatments. To determine the most suitable accelerated aging stress for evaluating and determining the best heat shock treatment, the accelerated aging test of seeds was carried out for two, four, six, eight, and ten days. In this research, to improve the longevity of primed seeds, they were exposed to heat shock treatment at temperatures of 30, 35, and 40°C for 1, 2, 3, and 4 hours after seed priming.
Results: Both seed priming treatments with methyl jasmonate and brassinosteroid significantly increased all the tested germination traits compared to the control (without priming). This increase in traits such as germination percentage, vigor index, and seedling length in seed priming with methyl jasmonate was 46.4%, 67%, and 41%, respectively, and in the case of priming with brassinosteroid was 32%, 44%, and 38%, respectively. Also, in this research, the heat shock treatment at 40°C for four hours after priming had a significant and positive effect on seed germination. Application of the mentioned treatment increased germination by 60% at the end of the aging period compared with the control (without the application of heat shock).
Conclusions: Despite the significant increase in germination percentage by each of the hormonal substances like methyl jasmonate and brassinosteroid, the comparison of the best treatment combination of these substances with salicylic acid showed that seed priming with 25 mg L-1 of salicylic acid for two days at 10°C caused a significant increase in the percentage of germination under salinity stress. Also, the heat-shock post-priming treatment significantly improved the longevity of primed seeds.
Highlights:
- Seed priming significantly increases the seed germination characteristics of the Forssk plant against high salinity stress.
- As the aging period increases, the primed seeds experience a significant drop in germination compared with the control.
- Heat shock immediately after priming can significantly increase the longevity of primed seeds compared with the control.
Ramin Piri, Farzad Sharifzadeh, Naser Majnounhosseini,
Volume 11, Issue 1 ((Spring and Summer) 2024)
Volume 11, Issue 1 ((Spring and Summer) 2024)
Abstract
Extended abstract
Introduction: Currently, temperature and salinity stresses are spreading globally, which have a detrimental impact on the performance of various plants, particularly during seed germination and seedling growth stages. Therefore, the objective of this laboratory study was to examine the influence of temperature treatments and salinity levels on germination characteristics and initial seedling growth of kochia.
Materials and Methods: In the first experiment, temperature at nine levels (1, 5, 10, 15, 20, 25, 30, 35, and 40°C), and in the second experiment, salinity (osmotic potential at six levels (no stress, -0.4, -0.8, -1.2, -1.6, and -1.8 MPa) were considered as experimental treatments. In order to determine the cardinal temperatures (base, optimal, and ceiling) of germination in kochia seeds, non-linear regression models including the segmented, dent-like, and modified beta models were used.
Results: In the first experiment, the response of kochia germination rate was predicted by a segmented function with R2, RMSE, and AIC (Akaike) values of 0.92, 1.32, and 65.69, respectively, which indicates the high accuracy and precision of this model in predicting the cardinal temperatures of kochia seed germination compared with the other two models. In this model, the estimated base temperature for germination was 0.7°C, the optimal temperature was 20°C, and the ceiling temperature was 44.3°C. In the second experiment, salinity stress negatively affected the characteristics of seed germination in kochia, including germination percentage, germination rate, percentage of normal seedlings, seedling length, and seedling vigor index. The highest germination percentage of kochia seeds was observed under salt-free conditions with 88.66%, which decreased to 13% under -1.8 MPa salinity conditions.
Conclusions: In general, the results showed that the segmented model is more efficient and accurate than the other two models in predicting germination of kochia seeds under different temperature treatments. Also, increasing levels of salinity stress significantly reduced germination potential and seedling growth of kochia seeds, so that at a stress level of -1.8 MPa, germination rate decreased by 75% compared with stress-free condition.
Highlights:
Introduction: Currently, temperature and salinity stresses are spreading globally, which have a detrimental impact on the performance of various plants, particularly during seed germination and seedling growth stages. Therefore, the objective of this laboratory study was to examine the influence of temperature treatments and salinity levels on germination characteristics and initial seedling growth of kochia.
Materials and Methods: In the first experiment, temperature at nine levels (1, 5, 10, 15, 20, 25, 30, 35, and 40°C), and in the second experiment, salinity (osmotic potential at six levels (no stress, -0.4, -0.8, -1.2, -1.6, and -1.8 MPa) were considered as experimental treatments. In order to determine the cardinal temperatures (base, optimal, and ceiling) of germination in kochia seeds, non-linear regression models including the segmented, dent-like, and modified beta models were used.
Results: In the first experiment, the response of kochia germination rate was predicted by a segmented function with R2, RMSE, and AIC (Akaike) values of 0.92, 1.32, and 65.69, respectively, which indicates the high accuracy and precision of this model in predicting the cardinal temperatures of kochia seed germination compared with the other two models. In this model, the estimated base temperature for germination was 0.7°C, the optimal temperature was 20°C, and the ceiling temperature was 44.3°C. In the second experiment, salinity stress negatively affected the characteristics of seed germination in kochia, including germination percentage, germination rate, percentage of normal seedlings, seedling length, and seedling vigor index. The highest germination percentage of kochia seeds was observed under salt-free conditions with 88.66%, which decreased to 13% under -1.8 MPa salinity conditions.
Conclusions: In general, the results showed that the segmented model is more efficient and accurate than the other two models in predicting germination of kochia seeds under different temperature treatments. Also, increasing levels of salinity stress significantly reduced germination potential and seedling growth of kochia seeds, so that at a stress level of -1.8 MPa, germination rate decreased by 75% compared with stress-free condition.
Highlights:
- The cardinal temperatures (base, optimum, and ceiling temperatures) of kochia seed germination were determined.
- This research introduced 1°C temperature and -1.8 MPa of salinity level as low temperature stress and critical salinity, respectively.
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Seed Science and Technology, Seed Physiology, Seed Ecology, Modeling, Seed Health, Germination Characteristics, Seed Dormancy, Seed Ageing, Seed Storage, Seed PrimingVote
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