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Showing 63 results for Vigor
Mohammad Reza Mirzaei,
Volume 11, Issue 2 (3-2025)
Volume 11, Issue 2 (3-2025)
Abstract
Extended abstract
Introduction: One of the most critical factors in achieving optimal sugar beet root performance at harvest time is appropriate plant density, which depends on high seedling emergence rates and subsequent seedling growth facilitated by using seeds with desirable vigor. Various seedling traits are key determinants of seed vigor and quality in sugar beet.
Materials and Methods: To evaluate germination vigor and seedling growth under laboratory conditions, traits such as maximum germination, hypocotyl length, radicle length, and fresh and dry seedling weights were measured in ten single-cross hybrids derived from crosses between ten male-sterile maternal lines and one paternal line, produced in three different seed production environments. Additionally, correlations between these traits and seedling emergence traits in greenhouse conditions, as well as seed chemical properties, were examined.
Results: The results indicated that seedling traits, which reflect seed vigor, are primarily influenced by two factors: the sugar beet seed production environment and genetics. Analysis of correlation coefficients between laboratory seedling traits and greenhouse seedling emergence traits, as well as seed electrical conductivity, revealed that genotypes with low electrical conductivity and low total soluble solids in the seed pericarp germinated faster and emerged more quickly under greenhouse conditions. Thus, high electrical conductivity in the sugar beet seed pericarp was associated with low seed vigor. Furthermore, significant correlations were observed between seedling emergence speed and mean emergence time in the greenhouse and hypocotyl length in the laboratory, showing positive (+0.91**) and negative (−0.82**) relationships, respectively. Therefore, genotypes with longer hypocotyls in the laboratory exhibited faster seedling emergence in the greenhouse. Consequently, single-cross hybrids such as MS KWS × OT 231, which had greater radicle length (8.49 cm), seedling length (14.66 cm), and radicle-to-hypocotyl ratio (1.37) under laboratory conditions, also showed a significant increase in mean dry shoot weight (1.89 mg) and seedling vigor weight index (8.26) in the greenhouse compared to other single-cross hybrid.
Conclusions: Therefore, it appears that seedling traits and chemical characteristics of sugar beet seeds can be used to predict seedling emergence performance in the greenhouse and potentially in the field. However, for validation and precise assessment, it is recommended that this experiment be conducted under field conditions.
Highlights:
Introduction: One of the most critical factors in achieving optimal sugar beet root performance at harvest time is appropriate plant density, which depends on high seedling emergence rates and subsequent seedling growth facilitated by using seeds with desirable vigor. Various seedling traits are key determinants of seed vigor and quality in sugar beet.
Materials and Methods: To evaluate germination vigor and seedling growth under laboratory conditions, traits such as maximum germination, hypocotyl length, radicle length, and fresh and dry seedling weights were measured in ten single-cross hybrids derived from crosses between ten male-sterile maternal lines and one paternal line, produced in three different seed production environments. Additionally, correlations between these traits and seedling emergence traits in greenhouse conditions, as well as seed chemical properties, were examined.
Results: The results indicated that seedling traits, which reflect seed vigor, are primarily influenced by two factors: the sugar beet seed production environment and genetics. Analysis of correlation coefficients between laboratory seedling traits and greenhouse seedling emergence traits, as well as seed electrical conductivity, revealed that genotypes with low electrical conductivity and low total soluble solids in the seed pericarp germinated faster and emerged more quickly under greenhouse conditions. Thus, high electrical conductivity in the sugar beet seed pericarp was associated with low seed vigor. Furthermore, significant correlations were observed between seedling emergence speed and mean emergence time in the greenhouse and hypocotyl length in the laboratory, showing positive (+0.91**) and negative (−0.82**) relationships, respectively. Therefore, genotypes with longer hypocotyls in the laboratory exhibited faster seedling emergence in the greenhouse. Consequently, single-cross hybrids such as MS KWS × OT 231, which had greater radicle length (8.49 cm), seedling length (14.66 cm), and radicle-to-hypocotyl ratio (1.37) under laboratory conditions, also showed a significant increase in mean dry shoot weight (1.89 mg) and seedling vigor weight index (8.26) in the greenhouse compared to other single-cross hybrid.
Conclusions: Therefore, it appears that seedling traits and chemical characteristics of sugar beet seeds can be used to predict seedling emergence performance in the greenhouse and potentially in the field. However, for validation and precise assessment, it is recommended that this experiment be conducted under field conditions.
Highlights:
- Differences were observed among genotypes in terms of seed characteristics and the maternal environment in which the seeds were produced.
- Poor sugar beet seed vigor can reduce both the potential emergence percentage and the speed and uniformity of seedling emergence compared to high-vigor seeds.
- Seedling traits in sugar beet are indicators of seed vigor and are influenced by both the seed production environment and genetics.
Kamran Gharehbeygi Tavabea, Hamidreza Balouchi, Mohsen Movahhedi Dehnavi, Ali Moradi, Fatemeh Ebrahimi,
Volume 11, Issue 2 (3-2025)
Volume 11, Issue 2 (3-2025)
Abstract
Extended abstract
Introduction: Poor seedling vigor is one of the major challenges in agriculture, as it reduces seed germination capacity and seedling establishment, directly impacting plant establishment and yield. The use of seed priming methods with chemicals and growth regulators can serve as an effective strategy to enhance seedling vigor and improve biochemical traits and seed germination. In this study, the enhancement of sweet corn seedling vigor through priming with ellagic acid, gibberellin, and potassium nitrate was investigated under accelerated aging conditions.
Materials and Methods: A factorial experiment was conducted in the Seed Technology Laboratory of the Faculty of Agriculture at Yasouj University in 2024, based on a completely randomized design with two factors. The first factor was accelerated seed aging at two levels (aged and non-aged), and the second factor was seed priming at eight levels (no prime, hydropriming, ellagic acid at two concentrations (25 and 100 mg/l), gibberellin at two concentrations (50 and 150 mg/l), and potassium nitrate at two concentrations (15 and 60 mg/l)). Biochemical traits and seed germination characteristics were measured ultimately.
Results: The findings of this study revealed that seed deterioration significantly reduced germination characteristics, including germination percentage and rate, shoot length, root length, and seedling vigor index (length and weight). Additionally, biochemical indices such as soluble sugar content and α-amylase enzyme activity were negatively affected by aging. On the other hand, seed deterioration increased proline content, malondialdehyde levels, and peroxidase enzyme activity, indicating heightened oxidative stress under aging conditions. Priming of deterioration seeds with ellagic acid, gibberellin, and potassium nitrate positively influenced germination characteristics and biochemical indices. Specifically, concentrations of 100 mg/l ellagic acid, 150 mg/l gibberellin, and 15 mg/l potassium nitrate were the most effective pretreatments.
Conclusion: The results of this research demonstrated that pretreatment of deteriorated Basin sweet corn seeds with ellagic acid, gibberellin, and potassium nitrate significantly improved germination and biochemical indices. These treatments mitigated the negative effects of seed aging, enhancing seedling vigor and establishment. Therefore, these priming can be recommended as effective methods to improve the quality of Basin sweet corn seeds under various agricultural conditions.
Highlights:
Introduction: Poor seedling vigor is one of the major challenges in agriculture, as it reduces seed germination capacity and seedling establishment, directly impacting plant establishment and yield. The use of seed priming methods with chemicals and growth regulators can serve as an effective strategy to enhance seedling vigor and improve biochemical traits and seed germination. In this study, the enhancement of sweet corn seedling vigor through priming with ellagic acid, gibberellin, and potassium nitrate was investigated under accelerated aging conditions.
Materials and Methods: A factorial experiment was conducted in the Seed Technology Laboratory of the Faculty of Agriculture at Yasouj University in 2024, based on a completely randomized design with two factors. The first factor was accelerated seed aging at two levels (aged and non-aged), and the second factor was seed priming at eight levels (no prime, hydropriming, ellagic acid at two concentrations (25 and 100 mg/l), gibberellin at two concentrations (50 and 150 mg/l), and potassium nitrate at two concentrations (15 and 60 mg/l)). Biochemical traits and seed germination characteristics were measured ultimately.
Results: The findings of this study revealed that seed deterioration significantly reduced germination characteristics, including germination percentage and rate, shoot length, root length, and seedling vigor index (length and weight). Additionally, biochemical indices such as soluble sugar content and α-amylase enzyme activity were negatively affected by aging. On the other hand, seed deterioration increased proline content, malondialdehyde levels, and peroxidase enzyme activity, indicating heightened oxidative stress under aging conditions. Priming of deterioration seeds with ellagic acid, gibberellin, and potassium nitrate positively influenced germination characteristics and biochemical indices. Specifically, concentrations of 100 mg/l ellagic acid, 150 mg/l gibberellin, and 15 mg/l potassium nitrate were the most effective pretreatments.
Conclusion: The results of this research demonstrated that pretreatment of deteriorated Basin sweet corn seeds with ellagic acid, gibberellin, and potassium nitrate significantly improved germination and biochemical indices. These treatments mitigated the negative effects of seed aging, enhancing seedling vigor and establishment. Therefore, these priming can be recommended as effective methods to improve the quality of Basin sweet corn seeds under various agricultural conditions.
Highlights:
- Seed deterioration leads to an increase in biochemical indicators such as seed proline content, peroxidase enzyme activity, and seed malondialdehyde content.
- The vigor of Basin sweet corn seeds is improved through pretreatment with gibberellin and ellagic acid.
- The effect of priming before and after artificial deterioration on germination and seed vigor of sweet corn cultivar Basin was compared and investigated.
Abas Sasanian, Ali Bashirzadeh, Seyed Ebrahim Kamali,
Volume 11, Issue 2 (3-2025)
Volume 11, Issue 2 (3-2025)
Abstract
Extended abstract
Introduction: Rice (Oryza sativa L.), one of the world's most crucial cereals, serves as a primary nutritional source for over one-third of the global population. Compared to other grains, rice exhibits greater sensitivity to low-temperature stress. Seed priming as a biotechnological tool is a simple, practical, cost-effective, and eco-friendly approach to enhance plant stress tolerance and improve seed germination. This study investigated the germination and physiological responses of rice seeds to varying intensities and durations of electromagnetic field (EMF) exposure under cold stress conditions.
Materials and Methods: In 2024, a factorial experiment was conducted in a completely randomized design at Islamic Azad University, Astara Branch. The experiment evaluated four levels of EMF intensity (0, 50, 100, and 150 mT), two exposure durations (30 and 60 minutes), and three cold stress levels (10, 15, and 25°C) on the Hashemi rice cultivar, with three replications. Rice seeds were treated in plastic bags under the specified EMF conditions. For seedling establishment, healthy seedlings were transferred to plastic pots containing sand. After 25 days, physiological traits were measured.
Results: Analysis of variance revealed significant effects of EMF intensity, duration, cold stress, and their interactions on most traits. Cold stress significantly increased proline (1.02 µmol g⁻¹ FW) and malondialdehyde (4.40 mmol g⁻¹ FW) while reducing chlorophyll a and b. The highest germination percentage (98.9%), radicle length (69.6 mm), chlorophyll a (0.807 mg g⁻¹ FW), and chlorophyll b (0.99 mg g⁻¹ FW) were observed under 100 mT at 25°C. Additionally, the highest germination rate (0.560 day⁻¹), shoot length (58.63 mm), seedling length (130.8 mm), radicle dry weight (3.25 mg), shoot dry weight (2.21 mg), seedling dry weight (5.46 mg), length-based vigor index (13035.5), and weight-based vigor index (543.5) were recorded at 100 mT, 25°C, and 30 minutes. While cold stress reduced germination and seedling growth, EMF treatment up to 100 mT counteracted these effects across all temperature levels.
Conclusion: EMF treatment up to 100 mT significantly improved germination traits (e.g., percentage, rate) and physiological parameters (e.g., chlorophyll content) in this rice cultivar. These findings highlight the potential of EMF priming to enhance seed germination and stress resilience under cold conditions.
Highlights:
- The effect of the magnetic field was investigated on rice seed germination and physiological traits under cold stress.
- Seed priming with an intensity of 100 mT for 60 minutes under cold stress of 10°C increased proline and malondialdehyde content.
- Higher EMF intensities (up to 100 mT) significantly improved germination at 10°C.
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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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