Can modification of sowing date and genotype selection reduce the impact of climate change on sunflower seed production?
Autori
Krstić, MilošMladenov, Velimir
Banjac, Borislav
Babec, Brankica
Dunđerski, Dušan
Ćuk, Nemanja
Gvozdenac, Sonja
Cvejić, Sandra
Jocić, Siniša
Miklič, Vladimir
Ovuka, Jelena
Članak u časopisu (Objavljena verzija)
Metapodaci
Prikaz svih podataka o dokumentuApstrakt
Climate change projections for the 21st century pose great threats to semi-arid regions, impacting seed production and the quality of sunflowers. Crop yields are negatively affected by climate variability, especially in the event of droughts during the crucial growth stages. Understanding the relationships between agrometeorological, genetic, and agronomic factors is crucial for maintaining crop sustainability. Optimal sowing dates are an essential condition for maximizing crop genetic potential, but challenges come from annual weather variations. This study analyzes how sunflower genotypes respond to different sowing dates under climate change and focuses on the conditions for obtaining maximum seed yields and favorable agronomic traits. From 2020 to 2022, the experiment featured six genotypes sown across four different dates at two-week intervals, simulating seed sunflower production. The results obtained by ANOVA indicated that the seed yield and oil yield were significantly affecte...d by the sowing date, the genotype, and their interaction, with coefficients of variation ranging from 7.6% for oil yield to 41.1% for seed yield. Besides seed yield and oil yield, LDA biplot and Discriminant Functions confirmed that seed germination energy also played a significant role in separating genotypes into clusters. A Visual Mixed Model showed that shifting the optimal sowing date (mid-April) to early May allows a reduction in the number of days the plants spend in critical growth stages, thereby escaping stressful conditions during pollination and seed filling. The findings resulted, on average, in increased yields and improved seed quality, which are the primary goals of seed production, but not in increased 1000-seed weight. Notably, high temperatures during the critical sunflower growth stages negatively affected the measured parameters of seed production. The increased precipitation during seed filling boosted the 1000-seed mass and seed yield. Extended flowering reduced the growth rate and seed germination, but longer seed filling increased the 1000-seed mass and seed yield. Our future breeding goals will be to create genotypes with a shorter flowering period and an extended seed-filling period to better respond to climate change.
Ključne reči:
climate change / sunflower / inbred lines / seed production / sowing date / germination / seed yield / 1000 seed weightIzvor:
Agriculture - Basel, 2023, 13, 11, 2149-Izdavač:
- Basel : MDPI
Finansiranje / projekti:
- Ministarstvo nauke, tehnološkog razvoja i inovacija Republike Srbije, institucionalno finansiranje - 200032 (Naučni institut za ratarstvo i povrtarstvo, Novi Sad) (RS-MESTD-inst-2020-200032)
- SmartSun - Creating climate smart sunflower for future challenges (RS-ScienceFundRS-Ideje-7732457)
- CROPINNO - Stepping up scientific excellence and innovation capacity for climate-resilient crop improvement and production (EU-HE-101059784)
- Climate Crops - Centre of Excellence for Innovations in Breeding of Climate-Resilient Crops, Institute of Field and Vegetable Crops
Kolekcije
Institucija/grupa
FiVeRTY - JOUR AU - Krstić, Miloš AU - Mladenov, Velimir AU - Banjac, Borislav AU - Babec, Brankica AU - Dunđerski, Dušan AU - Ćuk, Nemanja AU - Gvozdenac, Sonja AU - Cvejić, Sandra AU - Jocić, Siniša AU - Miklič, Vladimir AU - Ovuka, Jelena PY - 2023 UR - http://fiver.ifvcns.rs/handle/123456789/4019 AB - Climate change projections for the 21st century pose great threats to semi-arid regions, impacting seed production and the quality of sunflowers. Crop yields are negatively affected by climate variability, especially in the event of droughts during the crucial growth stages. Understanding the relationships between agrometeorological, genetic, and agronomic factors is crucial for maintaining crop sustainability. Optimal sowing dates are an essential condition for maximizing crop genetic potential, but challenges come from annual weather variations. This study analyzes how sunflower genotypes respond to different sowing dates under climate change and focuses on the conditions for obtaining maximum seed yields and favorable agronomic traits. From 2020 to 2022, the experiment featured six genotypes sown across four different dates at two-week intervals, simulating seed sunflower production. The results obtained by ANOVA indicated that the seed yield and oil yield were significantly affected by the sowing date, the genotype, and their interaction, with coefficients of variation ranging from 7.6% for oil yield to 41.1% for seed yield. Besides seed yield and oil yield, LDA biplot and Discriminant Functions confirmed that seed germination energy also played a significant role in separating genotypes into clusters. A Visual Mixed Model showed that shifting the optimal sowing date (mid-April) to early May allows a reduction in the number of days the plants spend in critical growth stages, thereby escaping stressful conditions during pollination and seed filling. The findings resulted, on average, in increased yields and improved seed quality, which are the primary goals of seed production, but not in increased 1000-seed weight. Notably, high temperatures during the critical sunflower growth stages negatively affected the measured parameters of seed production. The increased precipitation during seed filling boosted the 1000-seed mass and seed yield. Extended flowering reduced the growth rate and seed germination, but longer seed filling increased the 1000-seed mass and seed yield. Our future breeding goals will be to create genotypes with a shorter flowering period and an extended seed-filling period to better respond to climate change. PB - Basel : MDPI T2 - Agriculture - Basel T1 - Can modification of sowing date and genotype selection reduce the impact of climate change on sunflower seed production? IS - 11 SP - 2149 VL - 13 DO - 10.3390/agriculture13112149 ER -
@article{ author = "Krstić, Miloš and Mladenov, Velimir and Banjac, Borislav and Babec, Brankica and Dunđerski, Dušan and Ćuk, Nemanja and Gvozdenac, Sonja and Cvejić, Sandra and Jocić, Siniša and Miklič, Vladimir and Ovuka, Jelena", year = "2023", abstract = "Climate change projections for the 21st century pose great threats to semi-arid regions, impacting seed production and the quality of sunflowers. Crop yields are negatively affected by climate variability, especially in the event of droughts during the crucial growth stages. Understanding the relationships between agrometeorological, genetic, and agronomic factors is crucial for maintaining crop sustainability. Optimal sowing dates are an essential condition for maximizing crop genetic potential, but challenges come from annual weather variations. This study analyzes how sunflower genotypes respond to different sowing dates under climate change and focuses on the conditions for obtaining maximum seed yields and favorable agronomic traits. From 2020 to 2022, the experiment featured six genotypes sown across four different dates at two-week intervals, simulating seed sunflower production. The results obtained by ANOVA indicated that the seed yield and oil yield were significantly affected by the sowing date, the genotype, and their interaction, with coefficients of variation ranging from 7.6% for oil yield to 41.1% for seed yield. Besides seed yield and oil yield, LDA biplot and Discriminant Functions confirmed that seed germination energy also played a significant role in separating genotypes into clusters. A Visual Mixed Model showed that shifting the optimal sowing date (mid-April) to early May allows a reduction in the number of days the plants spend in critical growth stages, thereby escaping stressful conditions during pollination and seed filling. The findings resulted, on average, in increased yields and improved seed quality, which are the primary goals of seed production, but not in increased 1000-seed weight. Notably, high temperatures during the critical sunflower growth stages negatively affected the measured parameters of seed production. The increased precipitation during seed filling boosted the 1000-seed mass and seed yield. Extended flowering reduced the growth rate and seed germination, but longer seed filling increased the 1000-seed mass and seed yield. Our future breeding goals will be to create genotypes with a shorter flowering period and an extended seed-filling period to better respond to climate change.", publisher = "Basel : MDPI", journal = "Agriculture - Basel", title = "Can modification of sowing date and genotype selection reduce the impact of climate change on sunflower seed production?", number = "11", pages = "2149", volume = "13", doi = "10.3390/agriculture13112149" }
Krstić, M., Mladenov, V., Banjac, B., Babec, B., Dunđerski, D., Ćuk, N., Gvozdenac, S., Cvejić, S., Jocić, S., Miklič, V.,& Ovuka, J.. (2023). Can modification of sowing date and genotype selection reduce the impact of climate change on sunflower seed production?. in Agriculture - Basel Basel : MDPI., 13(11), 2149. https://doi.org/10.3390/agriculture13112149
Krstić M, Mladenov V, Banjac B, Babec B, Dunđerski D, Ćuk N, Gvozdenac S, Cvejić S, Jocić S, Miklič V, Ovuka J. Can modification of sowing date and genotype selection reduce the impact of climate change on sunflower seed production?. in Agriculture - Basel. 2023;13(11):2149. doi:10.3390/agriculture13112149 .
Krstić, Miloš, Mladenov, Velimir, Banjac, Borislav, Babec, Brankica, Dunđerski, Dušan, Ćuk, Nemanja, Gvozdenac, Sonja, Cvejić, Sandra, Jocić, Siniša, Miklič, Vladimir, Ovuka, Jelena, "Can modification of sowing date and genotype selection reduce the impact of climate change on sunflower seed production?" in Agriculture - Basel, 13, no. 11 (2023):2149, https://doi.org/10.3390/agriculture13112149 . .