Your search keyword '"Floret development"' showing total 44 results

1. Phenotypic and transcriptome profiling of spikes reveals the regulation of light regimens on spike growth and fertile floret number in wheat.

Author

Guo, Xiaolei, Zhang, Zhen, Li, Junyan, Zhang, Siqi, Sun, Wan, Xiao, Xuechen, Sun, Zhencai, Xue, Xuzhang, Wang, Zhimin, and Zhang, Yinghua

Subjects

*PHENOTYPES, *GENE regulatory networks, *TRANSCRIPTOMES, *GENE expression, *ANTHER, *GROWTH, *WHEAT

Abstract

The spike growth phase is critical for the establishment of fertile floret (grain) numbers in wheat (Triticum aestivum L.). Then, how to shorten the spike growth phase and increase grain number synergistically? Here, we showed high‐resolution analyses of floret primordia (FP) number, morphology and spike transcriptomes during the spike growth phase under three light regimens. The development of all FP in a spike could be divided into four distinct stages: differentiation (Stage I), differentiation and morphology development concurrently (Stage II), morphology development (Stage III), and polarization (Stage IV). Compared to the short photoperiod, the long photoperiod shortened spike growth and stimulated early flowering by shortening Stage III; however, this reduced assimilate accumulation, resulting in fertile floret loss. Interestingly, long photoperiod supplemented with red light shortened the time required to complete Stages I–II, then raised assimilates supply in the spike and promoted anther development before polarization initiation, thereby increasing fertile FP number during Stage III, and finally maintained fertile FP development during Stage IV until they became fertile florets via a predicted dynamic gene network. Our findings proposed a light regimen, critical stages and candidate regulators that achieved a shorter spike growth phase and a higher fertile floret number in wheat. Summary statement: A light regimen could achieve a 'shorter spike growth phase' and 'higher fertile floret number' in wheat by regulating gene expression, assimilate accumulation and morphology development in the critical stages of floret development. [ABSTRACT FROM AUTHOR]

Published

2024

2. Advantageous spike-to-stem competition for assimilates contributes to the reduction in grain number loss in wheat spikes under water deficit stress

Author

Juan Li, Zimeng Liang, Yakun Li, Kexin Wang, Vinay Nangia, Fei Mo, and Yang Liu

Subjects

Drought stress, Floret development, Source-to-sink relationship, 13C-photosynthate distribution, Sucrose utilization, Agriculture (General), S1-972, Agricultural industries, HD9000-9495

Abstract

This study was conducted to investigate the mechanisms of assimilate distribution and sugar metabolism in spike-stem that inhibit the formation of fertile florets and grains per spike in winter wheat under pre-reproductive drought stress. Two winter wheat cultivars, CH58 (relatively strongly drought tolerant) and LH6 (relatively weakly drought tolerant), were subjected to successive soil drought treatments from jointing to heading during the 2020–2022 growing seasons. The results showed that pre-reproductive drought stress intensified the degradation and abortion of wheat florets. Compared to CH58, the decrease in the number of fertile florets and grains per spike of LH6 under drought stress increased by an average of 5.3%−8.0% and 8.3%−9.0%, respectively. Drought significantly inhibited the distribution of 13C-photosynthates in wheat spikes (15.7%−24.7%) and stems (8.5%−11.7%) during the booting stage. The number of differentially expressed genes enriched in starch and sucrose metabolic pathways was much higher in the spike and stem of LH6 than in those of CH58. Drought significantly reduced sucrose and hexose in young spikes but increased hexose and fructan concentrations in stems. Compared to LH6, the higher invertase activity and accompanying high expression of sugar transporter protein (STP) in CH58 spikes under drought stress contributed to the utilization of sucrose in young spikes. Additionally, under severe drought, the higher fructan concentration and expression of sugar transport proteins (SWEET and SUT) in the stem of CH58 improved the ability of the stem to transport assimilates to young spikes and thus alleviated the loss of grain number per spike. Exogenous spermidine optimized hexose and sucrose allocation in young wheat spikes and stems after drought stress, thereby increasing the number of fertile florets under drought stress. Overall, the ability of the dominant spike to utilize sugar and the ability to compete for assimilates between the spike and stem contribute to the resistance to drought stress-induced grain reduction in the spike. Exogenous chemicals can regulate the number of fertile florets through this pathway, thereby promoting the formation of wheat grain number.

Published

2024

3. Raised bed planting promotes grain number per spike in wheat grown after rice by improving spike differentiation and enhancing photosynthetic capacity

Author

Xiang-bei DU, Min XI, Zhi WEI, Xiao-fei CHEN, Wen-ge WU, and Ling-cong KONG

Subjects

grain number, floret development, photosynthetic capacity, wheat grown after rice, Agriculture (General), S1-972

Abstract

The yield of wheat in wheat–rice rotation cropping systems in the Yangtze River Plain, China, is adversely impacted by waterlogging. A raised bed planting (RBP) pattern may reduce waterlogging and increase the wheat yield after rice cultivation by improving the grain number per spike. However, the physiological basis for grain formation under RBP conditions remains poorly understood. The present study was performed over two growing seasons (2018/2019 and 2019/2020) to examine the effects of the planting pattern (i.e., RBP and flat planting (FP)) on the floret and grain formation features and leaf photosynthetic source characteristics of wheat. The results indicated that implementation of the RBP pattern improved the soil–plant nitrogen (N) supply during floret development, which facilitated balanced floret development, resulting in a 9.5% increase in the number of fertile florets per spike. Moreover, the RBP pattern delayed wheat leaf senescence and increased the photosynthetic source capacity by 13.9%, which produced more assimilates for grain filling. Delayed leaf senescence was attributed to the resultant high leaf N content and enhanced antioxidant metabolism. Correspondingly, under RBP conditions, 7.6–8.6% more grains per spike were recorded, and the grain yield was ultimately enhanced by 10.4–12.7%. These results demonstrate that the improvement of the spike differentiation process and the enhancement of the leaf photosynthetic capacity were the main reasons for the increased grain number per spike of wheat under the RBP pattern, and additional improvements in this technique should be achievable through further investigation.

Published

2023

4. Morphological Characteristics and Expression Patterns of CmCYC2c of Different Flower Shapes in Chrysanthemum morifolium.

Author

Qiu, Taijia, Li, Song, Zhao, Kunkun, Jia, Diwen, Chen, Fadi, and Ding, Lian

Subjects

ORNAMENTAL plants, CHRYSANTHEMUMS, FLOWER development, FLOWERS, IN situ hybridization, CUT flowers

Abstract

The chrysanthemum is widely used as a cut flower, potted flower, and garden flower worldwide and has high ornamental, edible, and medicinal value. The flower heads, composed of ray florets and disc florets, are the most diverse in terms of morphology among ornamental plants. Here, we compared and analyzed the developmental processes of different capitulum types as well as ray florets and disc florets. Morphological differentiation of the two florets occurred on the dorsal domain of the petals at stage Ⅳ of flower development, and differences in stamen development occurred at stage Ⅴ. The dorsal domain of the ray florets and the early stage of flower development were also an essential site and period, respectively, for the differences among capitulum types. In situ hybridization revealed that CmCYC2c, whose homologs are involved in the specification of floret identity in Asteraceae, was expressed in both the dorsal and ventral domains of the ray petals in the tubular-type chrysanthemum, whereas, it was differentially transcribed in the ray petals of flat- and spoon-type chrysanthemum cultivars and had lower or no expression in the dorsal domain and higher expression in the ventral domain at stage Ⅳ. Our study indicates that the expression pattern of CmCYC2c on the dorsal domain of the ray floret at stage Ⅳ contributes to the formation of diverse flower head types in chrysanthemums. [ABSTRACT FROM AUTHOR]

Published

2023

5. 不同水分条件下施磷对冬小麦穗花发育及产量的影响.

Author

张艳艳, 关涵文, 刘淋茹, 贺 利, 段剑钊, 王晨阳, 郭天财, and 冯 伟

Abstract

Copyright of Acta Agronomica Sinica is the property of Crop Science Society of China and its content may not be copied or emailed to multiple sites or posted to a listserv without the copyright holder's express written permission. However, users may print, download, or email articles for individual use. This abstract may be abridged. No warranty is given about the accuracy of the copy. Users should refer to the original published version of the material for the full abstract. (Copyright applies to all Abstracts.)

Published

2023

6. Heat stress responses vary during floret development in European spring barley cultivars.

Author

Callens, Cindy, Fernandez-Goméz, José, Tucker, Matthew R., Dabing Zhang, and Wilson, Zoe A.

Subjects

X-ray computed microtomography, HORDEUM, SPRING, FEMALE reproductive organs, MALE reproductive organs, CORN, WHEAT, BARLEY

Abstract

The Poaceae, or grasses, include many agriculturally important cereal crops such as rice (Oryza sativa), maize (Zea mays), barley (Hordeum vulgare) and bread wheat (Triticum aestivum). Barley is a widely grown cereal crop used for stock feed, malting and brewing. Abiotic stresses, particularly global warming, are the major causes of crop yield losses by affecting fertility and seed set. However, effects of heat stress on reproductive structures and fertility in barley have not been extensively investigated. In this study we examined three commercial European spring barley varieties under high temperature conditions to investigate the effects on floret development. Using a combination of fertility assays, X-ray micro computed tomography, 3-dimensional modelling, cytology and immunolabelling, we observed that male reproductive organs are severely impacted by increased temperature, while the female reproductive organs are less susceptible. Importantly, the timing of stress relative to reproductive development had a significant impact on fertility in a cultivar-dependent manner, this was most significant at pollen mitosis stage with fertility ranged from 31.6-56.0% depending on cultivar. This work provides insight into how heat stress, when applied during male pollen mother cell meiosis and pollen mitosis, affects barley fertility and seed set, and also describes complementary invasive and non-invasive techniques to investigate floret development. This information will be used to identify and study barley cultivars that are less susceptible to heat stress at specific stages of floral development. [ABSTRACT FROM AUTHOR]

Published

2023

7. Morphological Characteristics and Expression Patterns of CmCYC2c of Different Flower Shapes in Chrysanthemum morifolium

Author

Taijia Qiu, Song Li, Kunkun Zhao, Diwen Jia, Fadi Chen, and Lian Ding

Subjects

inflorescence forms, flat petal, spoon petal, tubular petal, dorsal petal, floret development, Botany, QK1-989

Abstract

The chrysanthemum is widely used as a cut flower, potted flower, and garden flower worldwide and has high ornamental, edible, and medicinal value. The flower heads, composed of ray florets and disc florets, are the most diverse in terms of morphology among ornamental plants. Here, we compared and analyzed the developmental processes of different capitulum types as well as ray florets and disc florets. Morphological differentiation of the two florets occurred on the dorsal domain of the petals at stage Ⅳ of flower development, and differences in stamen development occurred at stage Ⅴ. The dorsal domain of the ray florets and the early stage of flower development were also an essential site and period, respectively, for the differences among capitulum types. In situ hybridization revealed that CmCYC2c, whose homologs are involved in the specification of floret identity in Asteraceae, was expressed in both the dorsal and ventral domains of the ray petals in the tubular-type chrysanthemum, whereas, it was differentially transcribed in the ray petals of flat- and spoon-type chrysanthemum cultivars and had lower or no expression in the dorsal domain and higher expression in the ventral domain at stage Ⅳ. Our study indicates that the expression pattern of CmCYC2c on the dorsal domain of the ray floret at stage Ⅳ contributes to the formation of diverse flower head types in chrysanthemums.

Published

2023

8. Heat stress responses vary during floret development in European spring barley cultivars

Author

Cindy Callens, José Fernandez-Goméz, Matthew R. Tucker, Dabing Zhang, and Zoe A. Wilson

Subjects

barley, heat stress, floret development, meiosis, mitosis, pollen, Plant culture, SB1-1110

Abstract

The Poaceae, or grasses, include many agriculturally important cereal crops such as rice (Oryza sativa), maize (Zea mays), barley (Hordeum vulgare) and bread wheat (Triticum aestivum). Barley is a widely grown cereal crop used for stock feed, malting and brewing. Abiotic stresses, particularly global warming, are the major causes of crop yield losses by affecting fertility and seed set. However, effects of heat stress on reproductive structures and fertility in barley have not been extensively investigated. In this study we examined three commercial European spring barley varieties under high temperature conditions to investigate the effects on floret development. Using a combination of fertility assays, X-ray micro computed tomography, 3-dimensional modelling, cytology and immunolabelling, we observed that male reproductive organs are severely impacted by increased temperature, while the female reproductive organs are less susceptible. Importantly, the timing of stress relative to reproductive development had a significant impact on fertility in a cultivar-dependent manner, this was most significant at pollen mitosis stage with fertility ranged from 31.6-56.0% depending on cultivar. This work provides insight into how heat stress, when applied during male pollen mother cell meiosis and pollen mitosis, affects barley fertility and seed set, and also describes complementary invasive and non-invasive techniques to investigate floret development. This information will be used to identify and study barley cultivars that are less susceptible to heat stress at specific stages of floral development.

Published

2023

9. Variation of floret development and grain setting characteristics in winter wheat responses to delayed sowing.

Author

Zhu, Yuangang, Zhang, Xiu, Xiao, Yanyan, Chu, Jinpeng, and Dai, Zhongmin

Subjects

*SOWING, *WINTER wheat, *WHEAT, *GRAIN yields, *GROWING season, *GRAIN size, *FERTILITY

Abstract

BACKGROUND: Wheat floret development has been a focus of research due to a desire to improve spike fertility, which majorly influences grain yield. Sowing date plays a vital role on grain yield in wheat, and increase in the grain number per spike of winter wheat (Triticum aestivum L.) has been obtained by delayed sowing. During the 2014–2015 and 2015–2016 growing seasons, variation in these developmental patterns was explored involving two winter wheat cultivars (Jimai 22 and Tainong 18) and five sowing dates (24 September; 1, 8, 15 and 22 October). RESULTS: We noticed clear differences in the grain number per spikelet; delayed sowing had a greater impact on the number of fertile florets at anthesis than grain set. Significant differences in the developmental patterns of florets among spikelet positions corresponded to variations in the floret developmental rate, with faster floret development associated with higher floret fertility. Delayed sowing did not affect the grain number near the rachis, but significantly promoted grain set on distal florets. Increased spike dry weight (SDW) did not compensate for floret size or grain weight, mainly due to enhanced assimilate partitioning to florets. CONCLUSION: Delayed sowing significantly affects floret developmental dynamics, causing differences in winter wheat floret fertility. An increased SDW concomitant with improved intra‐spike partitioning before anthesis contributes to increase the distal floret numbers per spike and then optimize winter wheat spike fertility. © 2022 Society of Chemical Industry. [ABSTRACT FROM AUTHOR]

Published

2022

10. Cloning and molecular characterization of Triticum aestivum ornithine amino transferase (TaOAT) encoding genes

Author

Alia Anwar, Maoyun She, Ke Wang, and Xingguo Ye

Subjects

Wheat, Ornithine aminotransferase, Drought tolerance, Salt tolerance, Floret development, Botany, QK1-989

Abstract

Abstract Background Ornithine aminotransferase (OAT, EC:2.6.1.13), alternatively known as ornithine delta aminotransferase (δOAT), is a pyridoxal phosphate (PLP)-dependent enzyme involved in the conversion of ornithine into glutamyl-5-semi-aldehyde (GSA) and vice versa. Up till now, there has been no study on OAT in wheat despite the success of its isolation from rice, maize, and sorghum. This study focuses on identification and molecular characterization of OAT in wheat. Results In total, three homeologous OAT genes in wheat genome were found on chromosome group 5, named as TaOAT-5AL, TaOAT-5BL, and TaOAT-5DL. Sequence alignment between gDNA and its corresponding cDNA obtained a total of ten exons and nine introns. A phylogenetic tree was constructed and results indicated that OATs shared highly conserved domains between monocots and eudicots, which was further illustrated by using WebLogo to generate a sequence logo. Further subcellular localization analysis indicated that they functioned in mitochondria. Protein-protein interactions supported their role in proline biosynthesis through interactions with genes, such as delta 1-pyrroline-5-carboxylate synthetase (P5CS) and pyrroline-5-carboxylate reductase (P5CR), involved in the proline metabolic pathway. Promoter analysis exposed the presence of several stress responsive elements, implying their involvement in stress regulation. Expression profiling illustrated that TaOAT was highly induced in the wheat plants exposed to drought or salt stress condition. Upregulated expression of TaOATs was observed in stamens and at the heading stage. A potential role of TaOAT genes during floret development was also revealed. Furthermore, the transgenic plants overexpressing TaOAT showed enhanced tolerance to drought stress by increasing proline accumulation. In addition, salt tolerance of the transgenic plants was also enhanced. Conclusion TaOATs genes were involved in proline synthesis and nitrogen remobilization because they interacted with genes related to proline biosynthesis enzymes and arginine catabolism. In addition, TaOAT genes had a role in abiotic stress tolerance and a potential role in floret development. The results of this study may propose future research in the improvement of wheat resistance to abiotic stresses.

Published

2020

11. 植物开花素FT的功能及其表观调控机制的研究进展.

Author

蒋甲福, 杨一曼, 王琦, 陈素梅, and 陈发棣

Subjects

*PLANT life cycles, *FLOWER development, *PLANT hormones, *STOMATA, *GERMINATION, *ROOTSTOCKS

Abstract

Flowering is an important developmental phase switch in the life cycle of higher plants. Light, temperature, plant hormones and other factors participate in this regulation process. Florigen FT (FLOWERING LOCUS T) in leaves can integrate the signals of different flowering pathways and play an important role in flowering transition and flower development, and induction of tuberization, seed germination, bud burst, branching and stomatal opening. This review summarizes the research progress of FT function and epigenetic regulation of its expression in recent years, which will provide theoretical guidance for the further study of FT and flowering breeding of new varieties. [ABSTRACT FROM AUTHOR]

Published

2021

12. Advantageous spike-to-stem competition for assimilates contributes to the reduction in grain number loss in wheat spikes under water deficit stress.

Author

Li, Juan, Liang, Zimeng, Li, Yakun, Wang, Kexin, Nangia, Vinay, Mo, Fei, and Liu, Yang

Subjects

*WINTER wheat, *DURUM wheat, *WHEAT, *CARRIER proteins, *GRAIN, *PROTEIN transport, *DROUGHTS, *SUCROSE

Abstract

This study was conducted to investigate the mechanisms of assimilate distribution and sugar metabolism in spike-stem that inhibit the formation of fertile florets and grains per spike in winter wheat under pre-reproductive drought stress. Two winter wheat cultivars, CH58 (relatively strongly drought tolerant) and LH6 (relatively weakly drought tolerant), were subjected to successive soil drought treatments from jointing to heading during the 2020–2022 growing seasons. The results showed that pre-reproductive drought stress intensified the degradation and abortion of wheat florets. Compared to CH58, the decrease in the number of fertile florets and grains per spike of LH6 under drought stress increased by an average of 5.3%−8.0% and 8.3%−9.0%, respectively. Drought significantly inhibited the distribution of 13C-photosynthates in wheat spikes (15.7%−24.7%) and stems (8.5%−11.7%) during the booting stage. The number of differentially expressed genes enriched in starch and sucrose metabolic pathways was much higher in the spike and stem of LH6 than in those of CH58. Drought significantly reduced sucrose and hexose in young spikes but increased hexose and fructan concentrations in stems. Compared to LH6, the higher invertase activity and accompanying high expression of sugar transporter protein (STP) in CH58 spikes under drought stress contributed to the utilization of sucrose in young spikes. Additionally, under severe drought, the higher fructan concentration and expression of sugar transport proteins (SWEET and SUT) in the stem of CH58 improved the ability of the stem to transport assimilates to young spikes and thus alleviated the loss of grain number per spike. Exogenous spermidine optimized hexose and sucrose allocation in young wheat spikes and stems after drought stress, thereby increasing the number of fertile florets under drought stress. Overall, the ability of the dominant spike to utilize sugar and the ability to compete for assimilates between the spike and stem contribute to the resistance to drought stress-induced grain reduction in the spike. Exogenous chemicals can regulate the number of fertile florets through this pathway, thereby promoting the formation of wheat grain number. [Display omitted] • Pre-reproduction drought stress exacerbated the decrease in grain number per spike. • The transfer rate of 13C-photosynthate was linearly related to floret degradation. • Drought-resistant wheat had a greater capacity to catabolize sugar in spike. • Dominant stem-to-spike sugar transfer capacity helped floret resist drought. • Exogenous spermidine optimized the allocation of sugar in spike-stem by drought. [ABSTRACT FROM AUTHOR]

Published

2024

13. Cloning and molecular characterization of Triticum aestivum ornithine amino transferase (TaOAT) encoding genes.

Author

Anwar, Alia, She, Maoyun, Wang, Ke, and Ye, Xingguo

Subjects

*MOLECULAR cloning, *WHEAT, *TRANSGENIC plants, *VITAMIN B6, *OATS, *GENES, *ORNITHINE

Abstract

Background: Ornithine aminotransferase (OAT, EC:2.6.1.13), alternatively known as ornithine delta aminotransferase (δOAT), is a pyridoxal phosphate (PLP)-dependent enzyme involved in the conversion of ornithine into glutamyl-5-semi-aldehyde (GSA) and vice versa. Up till now, there has been no study on OAT in wheat despite the success of its isolation from rice, maize, and sorghum. This study focuses on identification and molecular characterization of OAT in wheat. Results: In total, three homeologous OAT genes in wheat genome were found on chromosome group 5, named as TaOAT-5AL, TaOAT-5BL, and TaOAT-5DL. Sequence alignment between gDNA and its corresponding cDNA obtained a total of ten exons and nine introns. A phylogenetic tree was constructed and results indicated that OATs shared highly conserved domains between monocots and eudicots, which was further illustrated by using WebLogo to generate a sequence logo. Further subcellular localization analysis indicated that they functioned in mitochondria. Protein-protein interactions supported their role in proline biosynthesis through interactions with genes, such as delta 1-pyrroline-5-carboxylate synthetase (P5CS) and pyrroline-5-carboxylate reductase (P5CR), involved in the proline metabolic pathway. Promoter analysis exposed the presence of several stress responsive elements, implying their involvement in stress regulation. Expression profiling illustrated that TaOAT was highly induced in the wheat plants exposed to drought or salt stress condition. Upregulated expression of TaOATs was observed in stamens and at the heading stage. A potential role of TaOAT genes during floret development was also revealed. Furthermore, the transgenic plants overexpressing TaOAT showed enhanced tolerance to drought stress by increasing proline accumulation. In addition, salt tolerance of the transgenic plants was also enhanced. Conclusion: TaOATs genes were involved in proline synthesis and nitrogen remobilization because they interacted with genes related to proline biosynthesis enzymes and arginine catabolism. In addition, TaOAT genes had a role in abiotic stress tolerance and a potential role in floret development. The results of this study may propose future research in the improvement of wheat resistance to abiotic stresses. [ABSTRACT FROM AUTHOR]

Published

2020

14. Earliness per se×temperature interaction: consequences on leaf, spikelet, and floret development in wheat.

Author

Prieto, Paula, Ochagavía, Helga, Griffiths, Simon, and Slafer, Gustavo A

Subjects

*WHEAT, *FLOWERING time, *ALLELES, *HIGH temperatures, *ASTERACEAE

Abstract

Wheat adaptation can be fine-tuned by earliness per se (Eps) genes. Although the effects of Eps genes are often assumed to act independently of the environment, previous studies have shown that they exhibit temperature sensitivity. The number of leaves and phyllochron are considered determinants of flowering time and the numerical components of yield include spikelets per spike and fertile floret number within spikelets. We studied the dynamics of leaf, spikelet, and floret development in near isogenic lines with either late or early alleles of Eps - D1 under seven temperature regimes. Leaf appearance dynamics were modulated by temperature, and Eps alleles had a greater effect on the period from flag leaf to heading than phyllochron. In addition, the effects of the Eps alleles on spikelets per spike were minor, and more related to spikelet plastochron than the duration of the early reproductive phase. However, fertile floret number was affected by the interaction between Eps alleles and temperature. So, at 9 °C, Eps -early alleles had more fertile florets than Eps -late alleles, at intermediate temperatures there was no significant difference, and at 18 °C (the highest temperature) the effect was reversed, with lines carrying the late allele producing more fertile florets. These effects were mediated through changes in floret survival; there were no clear effects on the maximum number of floret primordia. [ABSTRACT FROM AUTHOR]

Published

2020

15. Maize YABBY genes drooping leaf1 and drooping leaf2 regulate floret development and floral meristem determinacy.

Author

Strable, Josh and Vollbrecht, Erik

Subjects

*GENE regulatory networks, *GENES

Abstract

Floral morphology is shaped by factors that modulate floral meristem activity and size, and the identity, number and arrangement of the lateral organs they form. We report the maize CRABS CLAW co-orthologs drooping leaf1 (drl1) and drl2 are required for development of ear and tassel florets. Pistillate florets of drl1 ears are sterile with unfused carpels that fail to enclose an expanded nucellus-like structure. Staminate florets of drl1 tassels have extra stamens and fertile anthers. Natural variation and transposon alleles of drl2 enhance drl1 mutant phenotypes by reducing floral meristem (FM) determinacy. The drl paralogs are co-expressed in lateral floral primordia, but not within the FM. drl expression together with the more indeterminate mutant FMs suggest that the drl genes regulate FM activity and impose meristem determinacy non-cell autonomously from differentiating cells in lateral floral organs. We used gene regulatory network inference, genetic interaction and expression analyses to suggest DRL1 and ZEA AGAMOUS1 target each other and a common set of downstream genes that function during floret development, thus defining a regulatory module that fine-tunes floret patterning and FM determinacy. [ABSTRACT FROM AUTHOR]

Published

2019

16. Grain number determination in durum wheat as affected by drought stress: An analysis at spike and spikelet level.

Author

Vahamidis, Petros, Karamanos, Andreas J., and Economou, Garyfalia

Subjects

*DURUM wheat, *GRAIN yields, *EFFECT of drought on plants, *PLANT water requirements, *EFFECT of stress on plants, *WHEAT yields, WHEAT genetics

Abstract

Yield studies show that increases in grain yield are always accompanied by an increase in grain number and, hence, further increases in yield potential may require additional improvements in grain number. The improvement of modern durum wheat was mainly based on the introduction of semidwarf genes. A 2‐year field drought stress experiment, concerning two different genotype groups (landraces vs modern cultivars), was carried out under a rainout shelter in order (a) to assess the effect of water deficit on floret dynamics and grain number determination, (b) to explore the relationship between plant water status with grain number per spike and its components (i.e., spikelets per spike, fertile florets per spikelet and grain set) and (c) to quantify the importance of several plant traits in determining the final number of grains per spike and fertile florets per spike when the main source of variation is water availability. Compared to control (well irrigated), grain number per spike was reduced, depending on year, genotype and water availability level, by 12.4–58.7% and this reduction was evident almost in all spikelet positions along the spike. Although there were some doubts in the past about the increased sensitivity of semidwarf cultivars to drought stress, they were not confirmed from our results. In most of the cases, the variation in plant water status (by means of water potential index [WPI]) during floret primordia phase (FPP) explained most of the variance in grain number per spike, fertile florets per spikelet, grain set and fertile spikelets per spike. In general, increasing water stress intensity decreased grain number per spike by an average rate of 13.5 and 9.4 grains per 0.2 MPa decrease in WPI, in modern cultivars and landraces, respectively. However, seasonal and genotypic effects were evident by modifying the slopes of the linear regressions between WPI and the studied plant traits. Commonality analysis revealed that the number of fertile florets per spikelet was the best predictor of grain number per spike, indicating that there is still much space for further improvement for this trait in landraces. However, this trait has been clearly improved in modern cultivars, especially at the basal and central spikelets. Although the number of spikelets per spike was the best unique predictor of the number of grains per spike in modern cultivars, grain set presented the highest total effect. Two different genotype groups (landraces vs modern cultivars) were tested under decreased water availability in order i) to assess the effect of water deficit on floret dynamics and grain number determination, ii) to explore the relationship between plant water status with grain number per spike and its components and iii) to quantify the importance of several plant traits in determining the final number of grains per spike and fertile florets per spike when the main source of variation is water availability. According to wheat ontogeny the reproductive development was separated into 4 phases. This approach had the objective to investigate the distinct role of the initial reproductive developmental events on the determination of the final number of grains per spike in wheat. [ABSTRACT FROM AUTHOR]

Published

2019

17. Photoperiod-sensitivity genes shape floret development in wheat.

Author

Pérez-Gianmarco, Thomas I, Slafer, Gustavo A, and González, Fernanda G

Subjects

*WHEAT, *CULTIVARS, *GENOTYPES, *ALLELES, *CROP yields

Abstract

Lengthening the pre-anthesis period of stem elongation (or late-reproductive phase, LRP) through altering photoperiod sensitivity has been suggested as a potential means to increase the number of fertile florets at anthesis (NFF) in wheat. However, little is known about the effects that the Ppd-1 genes modulating plant response to photoperiod may have on reproductive development. Here, five genotypes with either sensitive (b) or insensitive (a) alleles were grown in chambers under contrasting photoperiods (12 h or 16 h) to assess their effects. The genotypes consisted of the control cultivar Paragon (three Ppd-1b) and four near-isogenic lines of Paragon with Ppd-1a alleles introgressed from: Chinese Spring (Ppd-B1a), GS-100 (Ppd-A1a), Sonora 64 (Ppd-D1a), and Triple Insensitive (three Ppd-1a). Under a 12-h photoperiod, NFF in the genotypes followed the order three Ppd-1b > Ppd-B1a > Ppd-A1a > Ppd-D1a > three Ppd-1a. Under a 16-h photoperiod the differences were milder, but three Ppd-1b still had a greater NFF than the rest. As Ppd-1a alleles shortened the LRP, spikes were lighter and the NFF decreased. The results demonstrated for the first time that Ppd-1a decreases the maximum number of florets initiated through shortening the floret initiation phase, and this partially explained the variations in NFF. The most important impact of Ppd-1a alleles, however, was related to a reduction in survival of floret primordia, which resulted in the lower NFF. These findings reinforce the idea that an increased duration of the LRP, achieved through photoperiod sensitivity, would be useful for increasing wheat yield potential. [ABSTRACT FROM AUTHOR]

Published

2019

18. Plant and Floret Growth at Distinct Developmental Stages During the Stem Elongation Phase in Wheat

Author

Zifeng Guo, Dijun Chen, and Thorsten Schnurbusch

Subjects

detillering, floret development, plant growth, stem elongation phase, wheat anther/ovary size, Plant culture, SB1-1110

Abstract

Floret development is critical for grain setting in wheat (Triticum aestivum), but more than 50% of grain yield potential (based on the maximum number of floret primordia) is lost during the stem elongation phase (SEP, from the terminal spikelet stage to anthesis). Dynamic plant (e.g., leaf area, plant height) and floret (e.g., anther and ovary size) growth and its connection with grain yield traits (e.g., grain number and width) are not clearly understood. In this study, for the first time, we dissected the SEP into seven stages to investigate plant (first experiment) and floret (second experiment) growth in greenhouse- and field-grown wheat. In the first experiment, the values of various plant growth trait indices at different stages were generally consistent between field and greenhouse and were independent of the environment. However, at specific stages, some traits significantly differed between the two environments. In the second experiment, phenotypic and genotypic similarity analysis revealed that grain number and size corresponded closely to ovary size at anthesis, suggesting that ovary size is strongly associated with grain number and size. Moreover, principal component analysis (PCA) showed that the top six principal components PCs explained 99.13, 98.61, 98.41, 98.35, and 97.93% of the total phenotypic variation at the green anther, yellow anther, tipping, heading, and anthesis stages, respectively. The cumulative variance explained by the first PC decreased with floret growth, with the highest value detected at the green anther stage (88.8%) and the lowest at the anthesis (50.09%). Finally, ovary size at anthesis was greater in wheat accessions with early release years than in accessions with late release years, and anther/ovary size shared closer connections with grain number/size traits at the late vs. early stages of floral development. Our findings shed light on the dynamic changes in plant and floret growth-related traits in wheat and the effects of the environment on these traits.

Published

2018

19. 孕穗前期叶面喷赛苗旺对冬小麦穗粒数和粒质量的影响.

Author

郑春风, 任伟, 徐福新, 车军, 杨攀, 吴政卿, 马卫民, and 曹源

Abstract

Copyright of Journal of Henan Agricultural Sciences is the property of Editorial Board of Journal of Henan Agricultural Sciences and its content may not be copied or emailed to multiple sites or posted to a listserv without the copyright holder's express written permission. However, users may print, download, or email articles for individual use. This abstract may be abridged. No warranty is given about the accuracy of the copy. Users should refer to the original published version of the material for the full abstract. (Copyright applies to all Abstracts.)

Published

2018

20. Physiological determinants of fertile floret survival in wheat as affected by earliness per se genes under field conditions.

Author

Prieto, Paula, Ochagavía, Helga, Savin, Roxana, Slafer, Gustavo A., and Griffiths, Simon

Subjects

*WHEAT yields, *GENES, *ALLELES, *CHROMOSOMES, *WHEAT, *ANALYSIS of variance

Abstract

Variations in wheat yield are largely explained by changes in grain number per m 2 which is linked to the number of fertile florets at anthesis. This, in turn is the outcome of developmental processes which control floret initiation and mortality. Earliness ‘ per se ’ ( Eps ) genes are involved in fine-tuning time to anthesis in wheat (and other cereals) but their effect on development prior to anthesis is less well studied. We aimed to determine effects of Eps genes on spike fertility, quantifying aspects of floret developmental which influence this trait. Field experiments were carried out to record floret primordia generation/degeneration dynamics in near isogenic lines (NILs) with contrasting Eps alleles (late flowering vs early flowering alleles; Eps -late and Eps -early, respectively) derived from the Avalon x Cadenza (AxC) cross with the Eps gene on either chromosome 1D or 3 A and from the Spark x Rialto (SxR) cross with the Eps gene on chromosome 1D. Eps NILs varied in spike fertility: Eps -late alleles increased fertility. Although the effect was in general slight, the magnitude was affected by the particular alleles and the cross used to produce the NILs. Differences in the number of fertile florets were explained by differences in the dynamics of floret development. NILs with Eps -late alleles improved the development of a small number of labile florets allowing them to complete their development to become fertile florets instead of dying, as in lines carrying early alleles. Thus, these alleles improved floret fertility mainly through reducing the rate of floret mortality with no influence on the dynamics of floret primordia initiation or in maximum number of floret primordia. Therefore, Eps genes could be exploited in wheat breeding not only to fine-tune time to anthesis but also to improve spike fertility. [ABSTRACT FROM AUTHOR]

Published

2018

21. Dynamics of floret initiation/death determining spike fertility in wheat as affected by Ppd genes under field conditions.

Author

Prieto, Paula, Ochagavía, Helga, Savin, Roxana, Griffiths, Simon, and Slafer, Gustavo A.

Subjects

*WHEAT breeding, *CROP yields, *PLANT genetics, *AGRICULTURAL productivity, *PLANT fertility

Abstract

As wheat yield is linearly related to grain number, understanding the physiological determinants of the number of fertile florets based on floret development dynamics due to the role of the particular genes is relevant. The effects of photoperiod genes on dynamics of floret development are largely ignored. Field experiments were carried out to (i) characterize the dynamics of floret primordia initiation and degeneration and (ii) to determine which are the most critical traits of such dynamics in establishing genotypic differences in the number of fertile florets at anthesis in near isogenic lines (NILs) carrying photoperiod-insensitive alleles. Results varied in magnitude between the two growing seasons, but in general introgression of Ppd-1a alleles reduced the number of fertile florets. The actual effect was affected not only by the genome and the doses but also by the source of the alleles. Differences in the number of fertile florets were mainly explained by differences in the floret generation/degeneration dynamics, and in most cases associated with floret survival. Manipulating photoperiod insensitivity, unquestionably useful for changing flowering time, may reduce spike fertility but much less than proportionally to the change in duration of development, as the insensitivity alleles did increase the rate of floret development. [ABSTRACT FROM AUTHOR]

Published

2018

22. Plant and Floret Growth at Distinct Developmental Stages During the Stem Elongation Phase in Wheat.

Author

Guo, Zifeng, Chen, Dijun, and Schnurbusch, Thorsten

Subjects

WHEAT, WHEAT yields, WHEAT breeding

Abstract

Floret development is critical for grain setting in wheat (Triticum aestivum), but more than 50% of grain yield potential (based on the maximum number of floret primordia) is lost during the stem elongation phase (SEP, from the terminal spikelet stage to anthesis). Dynamic plant (e.g., leaf area, plant height) and floret (e.g., anther and ovary size) growth and its connection with grain yield traits (e.g., grain number and width) are not clearly understood. In this study, for the first time, we dissected the SEP into seven stages to investigate plant (first experiment) and floret (second experiment) growth in greenhouse- and field-grown wheat. In the first experiment, the values of various plant growth trait indices at different stages were generally consistent between field and greenhouse and were independent of the environment. However, at specific stages, some traits significantly differed between the two environments. In the second experiment, phenotypic and genotypic similarity analysis revealed that grain number and size corresponded closely to ovary size at anthesis, suggesting that ovary size is strongly associated with grain number and size. Moreover, principal component analysis (PCA) showed that the top six principal components PCs explained 99.13, 98.61, 98.41, 98.35, and 97.93% of the total phenotypic variation at the green anther, yellow anther, tipping, heading, and anthesis stages, respectively. The cumulative variance explained by the first PC decreased with floret growth, with the highest value detected at the green anther stage (88.8%) and the lowest at the anthesis (50.09%). Finally, ovary size at anthesis was greater in wheat accessions with early release years than in accessions with late release years, and anther/ovary size shared closer connections with grain number/size traits at the late vs. early stages of floral development. Our findings shed light on the dynamic changes in plant and floret growth-related traits in wheat and the effects of the environment on these traits. [ABSTRACT FROM AUTHOR]

Published

2018

23. Floral transitions in wheat and barley: interactions between photoperiod, abiotic stresses, and nutrient status.

Author

Gol, Leonard, Tomé, Filipa, and von Korff, Maria

Subjects

*PLANT reproduction, *PHOTOPERIODISM, *ABIOTIC stress, *PLANT nutrients, *BARLEY

Abstract

The timing of plant reproduction has a large impact on yield in crop plants. Reproductive development in temperate cereals comprises two major developmental transitions. During spikelet initiation, the identity of the shoot meristem switches from the vegetative to the reproductive stage and spikelet primordia are formed on the apex. Subsequently, floral morphogenesis is initiated, a process strongly affected by environmental variation. Recent studies in cereal grasses have suggested that this later phase of inflorescence development controls floret survival and abortion, and is therefore crucial for yield. Here, we provide a synthesis of the early morphological and the more recent genetic studies on shoot development in wheat and barley. The review explores how photoperiod, abiotic stress, and nutrient signalling interact with shoot development, and pinpoints genetic factors that mediate development in response to these environmental cues. We anticipate that research in these areas will be important in understanding adaptation of cereal grasses to changing climate conditions. [ABSTRACT FROM AUTHOR]

Published

2017

24. Cloning and molecular characterization of Triticum aestivum ornithine amino transferase (TaOAT) encoding genes

Author

Maoyun She, Alia Anwar, Ke Wang, and Xingguo Ye

Subjects

0106 biological sciences, 0301 basic medicine, Ornithine aminotransferase, Plant Science, Genetically modified crops, Biology, Sodium Chloride, Genes, Plant, 01 natural sciences, Chromosomes, Plant, Polyethylene Glycols, Polyploidy, 03 medical and health sciences, chemistry.chemical_compound, Complementary DNA, lcsh:Botany, Salt tolerance, Proline, Promoter Regions, Genetic, Gene, Phylogeny, Triticum, Plant Proteins, Ornithine-Oxo-Acid Transaminase, Abiotic stress, food and beverages, Ornithine, Drought tolerance, Droughts, lcsh:QK1-989, Metabolic pathway, 030104 developmental biology, Biochemistry, chemistry, Wheat, Floret development, Transcriptome, 010606 plant biology & botany, Research Article

Abstract

Background Ornithine aminotransferase (OAT, EC:2.6.1.13), alternatively known as ornithine delta aminotransferase (δOAT), is a pyridoxal phosphate (PLP)-dependent enzyme involved in the conversion of ornithine into glutamyl-5-semi-aldehyde (GSA) and vice versa. Up till now, there has been no study on OAT in wheat despite the success of its isolation from rice, maize, and sorghum. This study focuses on identification and molecular characterization of OAT in wheat. Results In total, three homeologous OAT genes in wheat genome were found on chromosome group 5, named as TaOAT-5AL, TaOAT-5BL, and TaOAT-5DL. Sequence alignment between gDNA and its corresponding cDNA obtained a total of ten exons and nine introns. A phylogenetic tree was constructed and results indicated that OATs shared highly conserved domains between monocots and eudicots, which was further illustrated by using WebLogo to generate a sequence logo. Further subcellular localization analysis indicated that they functioned in mitochondria. Protein-protein interactions supported their role in proline biosynthesis through interactions with genes, such as delta 1-pyrroline-5-carboxylate synthetase (P5CS) and pyrroline-5-carboxylate reductase (P5CR), involved in the proline metabolic pathway. Promoter analysis exposed the presence of several stress responsive elements, implying their involvement in stress regulation. Expression profiling illustrated that TaOAT was highly induced in the wheat plants exposed to drought or salt stress condition. Upregulated expression of TaOATs was observed in stamens and at the heading stage. A potential role of TaOAT genes during floret development was also revealed. Furthermore, the transgenic plants overexpressing TaOAT showed enhanced tolerance to drought stress by increasing proline accumulation. In addition, salt tolerance of the transgenic plants was also enhanced. Conclusion TaOATs genes were involved in proline synthesis and nitrogen remobilization because they interacted with genes related to proline biosynthesis enzymes and arginine catabolism. In addition, TaOAT genes had a role in abiotic stress tolerance and a potential role in floret development. The results of this study may propose future research in the improvement of wheat resistance to abiotic stresses.

Published

2020

25. Developmental patterns and rates of organogenesis across modern and well-adapted wheat cultivars

Author

European Commission, Ministerio de Economía y Competitividad (España), Ministerio de Ciencia e Innovación (España), Universidad de Lleida, Ochagavía, Helga [0000-0002-1050-681X], Ochagavía, Helga, Prieto, Paula, Savin, Roxana, Slafer, Gustavo A., European Commission, Ministerio de Economía y Competitividad (España), Ministerio de Ciencia e Innovación (España), Universidad de Lleida, Ochagavía, Helga [0000-0002-1050-681X], Ochagavía, Helga, Prieto, Paula, Savin, Roxana, and Slafer, Gustavo A.

Abstract

Genetic gains in wheat yield are required to meet future demand. In order to design strategic crosses, it is essential to quantify the genetic variation among elite cultivars on traits responsible for the adaptation and the generation of yield components. We explored the degree of variation within well-adapted commercial cultivars on developmental phases (vegetative, early reproductive and late reproductive), final leaf number and phyllochron, leaf and spikelet plastochron, number of spikelets, florets, and dynamics of floret primordia development. Variation in flowering time among cultivars was minor but they differed in the partitioning of that time into particular phases. Main differences were found for the length of the late reproductive phase, partly linked to those in final leaf number. Variations on number of fertile florets at anthesis were mostly explained by floret survival, due to differential ability of labile florets to maintain normal development between cultivars. These differences were related to the duration of the floret development, but not to the synchrony of development among florets. These findings provide useful information for breeders when selecting genotypes for strategic crosses, as considering floret survival through duration of floret development in one of the parents (for which these processes shall be characterised in the elite germplasm) might increase the likelihood of transgressive segregation towards high-yielding offspring.

Published

2021

26. Fruiting efficiency: an alternative trait to further rise wheat yield.

Author

Slafer, Gustavo A., Elia, Mónica, Savin, Roxana, García, Guillermo A., Terrile, Ignacio I., Ferrante, Ariel, Miralles, Daniel J., and González, Fernanda G.

Subjects

*FRUIT development, *WHEAT yields, *PRIMORDIA (Botany), *PLANT embryology, *CULTIVARS

Abstract

Further improvements in wheat yields are critical, for which increases in grain number would be required. In the recent past, higher grain number was achieved through increased growth of the juvenile spikes before anthesis, due to the reduction in stem growth. As current cultivars have already an optimum height, alternatives must be identified for further increasing grain number. One of them is increasing fruiting efficiency (grains set per unit of spike dry weight at anthesis). Fruiting efficiency is the final outcome of the fate of floret development and differences in this trait within modern cultivars would be related to higher survival of floret primordia. Then there are two alternative physiological pathways to improve fruiting efficiency by allowing a normal development of most vulnerable floret primordia: an increased allocation of assimilates for the developing florets before anthesis, or reduced demand of the florets for maintaining their normal development. Both alternatives may be possible, and it might be critical to recognize which of them is the actual cause of differences in fruiting efficiency. When considering this trait in breeding we must be aware of potential trade-offs and therefore it must be avoided that increases in fruiting efficiency be constitutively related to decreases in either spike dry weight at anthesis or grain weight. In this review we described fruiting efficiency and its physiological bases, analyzing genetic variation and considering potential drawbacks that must be taken into account to avoid increases in fruiting efficiency being compensated by other traits. [ABSTRACT FROM AUTHOR]

Published

2015

27. Floret development and grain setting characteristics in winter wheat in response to pre-anthesis applications of 6-benzylaminopurine and boron.

Author

Zheng, Chunfeng, Zhu, Yunji, Zhu, Huijie, Kang, Guozhang, Guo, Tiancai, and Wang, Chenyang

Subjects

*WINTER wheat, *WHEAT yields, *WINTER grain, *BENZYLAMINOPURINE, *PLANT growth promoting substances, *BORON in plant nutrition

Abstract

The number of grains per unit land area is the most important component to determine grain yield in wheat. Survival of floret primordia seems to be critical for the determination of grain number, which is related to the number of fertile florets at anthesis and the growth of the florets have been frequently considered the determinant key to establish grain number. The objective of this study was to explore the dynamics pattern of floret generation/degeneration/abortion and the grain setting characteristics in winter wheat under contrasting conditions of foliar spraying. Field experiments were carried out during the 2011–2012 and 2012–2013 growing seasons at the Experiment Station of Henan Agricultural University. The experiment involved the wheat cultivar Yumai 49-198 and three foliar applications; water, 6-benzylaminopurine (6-BA), and boron, which were applied 25 days after the jointing stage. This study analysed in detail floret development in wheat as affected by resource availability (mainly foliar spraying), and found that the degeneration rates of the basal spikelet florets decreased by 24% and 6%, respectively, following application of 6-BA and boron. Similarly, the floret abortion rates were reduced by 73% (6-BA) and 22% (boron) when compared to the water control. The degeneration rates of florets from central spikelets decreased by 15% and 8%, after treatment with 6-BA and boron, respectively, while the abortion rates were reduced by 76% and 44%, respectively, when compared to the control. Spraying 6-BA significantly enhances the process by which florets became grains at different floret and spikelet positions, and especially promoted the grain setting of distal florets, respect to the rachis, into the spikelets ( i.e ., Florets 3 and 4). [ABSTRACT FROM AUTHOR]

Published

2014

28. Developmental patterns and rates of organogenesis across modern and well-adapted wheat cultivars

Author

Paula Prieto, Roxana Savin, Gustavo A. Slafer, Helga Ochagavía, European Commission, Ministerio de Economía y Competitividad (España), Ministerio de Ciencia e Innovación (España), Universidad de Lleida, Ochagavía, Helga [0000-0002-1050-681X], and Ochagavía, Helga

Subjects

0106 biological sciences, Germplasm, Soil Science, Plant Science, Biology, 01 natural sciences, Transgressive segregation, Anthesis, Developmental phases, Genetic variation, Phyllochron, Cultivar, Reproductive development, 2. Zero hunger, Plastochron, Floret survival, 04 agricultural and veterinary sciences, Agronomy, Floret development, 040103 agronomy & agriculture, 0401 agriculture, forestry, and fisheries, Adaptation, Agronomy and Crop Science, 010606 plant biology & botany

Abstract

38 Pags.- 13 Figs.- 2 Tabls. The definitive version is available at: https://www.sciencedirect.com/science/journal/11610301, Genetic gains in wheat yield are required to meet future demand. In order to design strategic crosses, it is essential to quantify the genetic variation among elite cultivars on traits responsible for the adaptation and the generation of yield components. We explored the degree of variation within well-adapted commercial cultivars on developmental phases (vegetative, early reproductive and late reproductive), final leaf number and phyllochron, leaf and spikelet plastochron, number of spikelets, florets, and dynamics of floret primordia development. Variation in flowering time among cultivars was minor but they differed in the partitioning of that time into particular phases. Main differences were found for the length of the late reproductive phase, partly linked to those in final leaf number. Variations on number of fertile florets at anthesis were mostly explained by floret survival, due to differential ability of labile florets to maintain normal development between cultivars. These differences were related to the duration of the floret development, but not to the synchrony of development among florets. These findings provide useful information for breeders when selecting genotypes for strategic crosses, as considering floret survival through duration of floret development in one of the parents (for which these processes shall be characterised in the elite germplasm) might increase the likelihood of transgressive segregation towards high-yielding offspring., Funding was provided by ADAPTAWHEAT (a project funded by the European Commission under the 7th Framework Programme for Research and Technological Development) and by project AGL2012- 35300 funded by the Ministry of Economy and Competitiveness of Spain. HO held a FPI scholarship from the Spanish Ministry of Science and Innovation, and PP held a PhD scholarship from the University of Lleida.

Published

2021

29. Dynamics of floret initiation/death determining spike fertility in wheat as affected by Ppd genes under field conditions

Author

Gustavo A. Slafer, Roxana Savin, Simon Griffiths, Helga Ochagavía, and Paula Prieto

Subjects

0106 biological sciences, photoperiod insensitivity, Physiology, media_common.quotation_subject, Triticum aestivum, Introgression, Fertility, Flowers, Plant Science, Biology, 01 natural sciences, Photoperiod insensitivity, Anthesis, Genotype, Primordium, Allele, floret survival, Gene, Triticum, Plant Proteins, media_common, 2. Zero hunger, photoperiodism, Late reproductive phase, stem elongation, food and beverages, Floret survival, 04 agricultural and veterinary sciences, Research Papers, Plant Leaves, Horticulture, Floret development, late reproductive phase, 040103 agronomy & agriculture, 0401 agriculture, forestry, and fisheries, Growth and Development, 010606 plant biology & botany

Abstract

Ppd-1a reduced the number of fertile florets due largely to lowering floret survival, and the effect was not proportional to the duration of the late reproductive phase., As wheat yield is linearly related to grain number, understanding the physiological determinants of the number of fertile florets based on floret development dynamics due to the role of the particular genes is relevant. The effects of photoperiod genes on dynamics of floret development are largely ignored. Field experiments were carried out to (i) characterize the dynamics of floret primordia initiation and degeneration and (ii) to determine which are the most critical traits of such dynamics in establishing genotypic differences in the number of fertile florets at anthesis in near isogenic lines (NILs) carrying photoperiod-insensitive alleles. Results varied in magnitude between the two growing seasons, but in general introgression of Ppd-1a alleles reduced the number of fertile florets. The actual effect was affected not only by the genome and the doses but also by the source of the alleles. Differences in the number of fertile florets were mainly explained by differences in the floret generation/degeneration dynamics, and in most cases associated with floret survival. Manipulating photoperiod insensitivity, unquestionably useful for changing flowering time, may reduce spike fertility but much less than proportionally to the change in duration of development, as the insensitivity alleles did increase the rate of floret development.

Published

2018

30. Autophagy regulated by day length determines the number of fertile florets in wheat.

Author

Ghiglione, Hernán O., Gonzalez, Fernanda G., Serrago, Román, Maldonado, Sara B., Chilcott, Charles, Curá, José A., Miralles, Daniel J., Tong Zhu, and Casal, Jorge J.

Subjects

*WHEAT, *MERISTEMS, *PLANT cells & tissues, *PLANT growth, *PLANT development, *DEVELOPMENTAL biology

Abstract

The wheat spikelet meristem differentiates into up to 12 floret primordia, but many of them fail to reach the fertile floret stage at anthesis. We combined microarray, biochemical and anatomical studies to investigate floret development in wheat plants grown in the field under short or long days (short days extended with low-fluence light) after all the spikelets had already differentiated. Long days accelerated spike and floret development and greening, and the expression of genes involved in photosynthesis, photoprotection and carbohydrate metabolism. These changes started while the spike was in the light-depleted environment created by the surrounding leaf sheaths. Cell division ceased in the tissues of distal florets, which interrupted their normal developmental progression and initiated autophagy, thus decreasing the number of fertile florets at anthesis. A massive decrease in the expression of genes involved in cell proliferation, a decrease in soluble carbohydrate levels, and an increase in the expression of genes involved in programmed cell death accompanied anatomical signs of cell death, and these effects were stronger under long days. We propose a model in which developmentally generated sugar starvation triggers floret autophagy, and long days intensify these processes due to the increased carbohydrate consumption caused by the accelerated plant development. [ABSTRACT FROM AUTHOR]

Published

2008

31. Floret fertility in wheat as affected by photoperiod during stem elongation and removal of spikelets at booting

Author

Serrago, Román A., Miralles, Daniel J., and Slafer, Gustavo A.

Subjects

*PLANT fertilization, *WHEAT, *CULTIVARS, *PLANTING

Abstract

Abstract: Spike growth during the stem elongation phase is critical for the establishment of the number of fertile florets (FF). A longer period of spike growth would lead to an increased number of FF and grains in wheat. The aim of this study was: (i) to analyze in three different commercial cultivars the impact of a photoperiod extension (NP+10) during the stem elongation phase on the number of FF and (ii) to determine whether the photoperiod extension effect might be reversed by increasing the availability of assimilates by a direct modification of the source/sink ratio at booting. The number of FF per spike was reduced by extended photoperiod in the experiment sown in an optimum date, though no differences were observed when sown much later, probably due to the poor environmental conditions of a spring sowing. The detrimental effect of lengthening the photoperiod on the number of FF per spike was reversed by trimming the spike at booting in two of the three cultivars analyzed. This reversion, together with the effect of photoperiod extension on FF associated with similar effects on spike growth, may be considered as a confirmation that, at least in part, the detrimental effects of photoperiod extension on FF would be mediated by changes in assimilate supply to the developing florets. No differences were observed between photoperiod treatments on the onset of rapid spike growth; however, extended photoperiod reduced the duration of spike growth phase without differences in the maximum rate of spike growth in two of the three cultivars. Although a positive association was found between the number of FF and spike dry weight at anthesis, differences among cultivars were observed in this relationship, suggesting different carbohydrates partitioning (i.e., FF per unit of spike weight) among them. [Copyright &y& Elsevier]

Published

2008

32. Floret development and spike growth as affected by photoperiod during stem elongation in wheat

Author

González, Fernanda G., Slafer, Gustavo A., and Miralles, Daniel J.

Subjects

*VERNALIZATION, *WHEAT

Abstract

A longer duration of stem elongation (from terminal spikelet initiation to anthesis) would result in a higher wheat yield potential as a consequence of the increase in both spike dry weight and number of fertile florets at anthesis. It is not clearly understood, however, which processes are involved in the increased spike dry weight and whether this variable accounts for the higher number of fertile florets when duration of stem elongation is modified by photoperiod treatments. As vernalization interacts with photoperiod during the stem elongation phase, a better understanding of the role of vernalization is also required. A field experiment was carried out using two wheat cultivars (Buck Manantial (BM) and Eureka Ferrocarril Sur (EFS)) subjected to diverse periods of vernalization (V15 and V50, plants vernalized for 15 and 50 days, respectively) and exposed to different photoperiods (NP+0 and NP+6, natural and 6 h extended photoperiod, respectively) only during the stem elongation phase. Floret development together with stem and spike growth during the stem elongation phase were studied. When the stem elongation phase was exposed to short photoperiod (i) duration of spike growth increased without any change in its growth rate, and (ii) most of the spike growth occurred during minimum stem growth rate as the onset of maximum stem growth rate was delayed. In EFS, the vernalization-sensitive cultivar, the former (i) and (ii) was true only when vernalization requirements were met. For both cultivars, the survival of the initiated floret primordia under short photoperiod increased, independently of vernalization. Both partitioning of assimilates to the spike and a direct photoperiod effect seemed to have been involved in the survival of floret primordia when the stem elongation phase was exposed to short photoperiod. [Copyright &y& Elsevier]

Published

2003

33. Developmental patterns and rates of organogenesis across modern and well-adapted wheat cultivars.

Author

Ochagavía, Helga, Prieto, Paula, Savin, Roxana, and Slafer, Gustavo A.

Subjects

*CULTIVARS, *MORPHOGENESIS, *WHEAT, *FLOWERING time, *SYNCHRONIC order

Abstract

[Display omitted] • Anthesis variation among elite wheats was due to changes in late reproductive phase. • Changes in number of fertile florets were related to those in floret survival. • Variation in labile florets development was related to length of floret development. • Synchrony of floret development did not explain differences on floret survival. Genetic gains in wheat yield are required to meet future demand. In order to design strategic crosses, it is essential to quantify the genetic variation among elite cultivars on traits responsible for the adaptation and the generation of yield components. We explored the degree of variation within well-adapted commercial cultivars on developmental phases (vegetative, early reproductive and late reproductive), final leaf number and phyllochron, leaf and spikelet plastochron, number of spikelets, florets, and dynamics of floret primordia development. Variation in flowering time among cultivars was minor but they differed in the partitioning of that time into particular phases. Main differences were found for the length of the late reproductive phase, partly linked to those in final leaf number. Variations on number of fertile florets at anthesis were mostly explained by floret survival, due to differential ability of labile florets to maintain normal development between cultivars. These differences were related to the duration of the floret development, but not to the synchrony of development among florets. These findings provide useful information for breeders when selecting genotypes for strategic crosses, as considering floret survival through duration of floret development in one of the parents (for which these processes shall be characterised in the elite germplasm) might increase the likelihood of transgressive segregation towards high-yielding offspring. [ABSTRACT FROM AUTHOR]

Published

2021

34. Nitrogen allocation and remobilization contributing to low-nitrogen tolerance in stay-green maize.

Author

Liu, Zheng, Hu, Conghui, Wang, Yuna, Sha, Ye, Hao, Zhanhong, Chen, Fanjun, Yuan, Lixing, and Mi, Guohua

Subjects

*CORN, *GRAIN yields, *NITROGEN, *CULTIVARS

Abstract

• Stay-green maize cultivars differ in N allocation and remobilization under low-N stress. • Poor N allocation around silking limits young ear development and reduce floret primordia. • Poor vegetative-N remobilization exacerbates grain abortion and reduces grain weight. Nitrogen (N) efficient cultivars can achieve relatively high grain yield under reduced N input. Normally modern stay-green maize cultivars are high-yielding and more N efficient than the old senescent cultivars. However, less is known about the genotypic difference in N use efficiency (NUE) among stay-green high-yielding cultivars. This information is crucial for further genetic improvement in NUE of the modern stay-green cultivars. In the present study, two stay-green hybrids with different NUE, Zhengdan958 (ZD958, N-efficient) and Liangyu99 (LY99, N-inefficient), were grown under 60 (LN) and 180 kg N ha−1 (HN) conditions in a 4-year field experiment with split-design. The two hybrids did not differ in grain yield under HN. Under LN, grain yield and grain N content of LY99 was 23.6 % and 30.3 % lower compared to that of ZD958, respectively. LY99 had few grain number per row than ZD958. Correspondingly, floret primordia number decreased by 17.7 %, and grain abortion increased by 12.7 % in LY99 compared to ZD958. During critical period around silking, N concentration in the young ear of LY99 is lower than that in ZD958. Also, the maximum absolute ear growth rate and exponential duration of LY99 were 22.2 % and 6.0 % lower than that of ZD958 under LN, respectively. In LN conditions, the two hybrids did not differ in post-silking N accumulation. However, N remobilization from vegetative organs to grains in LY99 was 41.3 % lower than that in ZD935. In conclusion, NUE in stay-green cultivars could be improved by efficient N allocation into the young ear and vegetative-N remobilization during post-silking period under insufficient N supply. [ABSTRACT FROM AUTHOR]

Published

2021

35. Spike growth affects spike fertility through the number of florets with green anthers before floret abortion in wheat.

Author

Zhang, Zhen, Li, Jing, Hu, Naiyue, Li, Wei, Qin, Weilong, Li, Jinpeng, Gao, Yanmei, Liu, Yang, Sun, Zhencai, Yu, Kang, Wang, Zhimin, and Zhang, Yinghua

Subjects

*ABORTION, *ANTHER, *WHEAT, *IRRIGATION, *CROP growth, *WHEAT yields

Abstract

• The maximum number of floret primordia was hardly affected by treatments. • Florets that have started abortion can not become fertile florets. • Anthers development determines the number of fertile florets. • Nitrogen application accelerated the rates of floret development and hence increased the number of fertile florets. The dynamics of floret initiation/abortion has been explored widely; however, the mechanisms of increasing floret fertility at anthesis in wheat production remain unclear. In this study, morphological and physiological responses of florets per spikelet and per spike to nitrogen and irrigation treatments in the field were investigated. Each spikelet produced the maximum number of living floret primordia (MFP) and showed no difference between treatments at the W7.5 stage; this ability was hardly affected by treatments. We firstly found that gradually abortive florets during W8.5-W10 stages were delayed due to improving assimilates availability in the spike instead of the 4th-5th inthernode; in fact, these florets would be aborted completely and never become fertile florets. Notably, we found that those florets in which the anther turned green (value ≥ 97) at W7.5 always became fertile, and their number showed a significant positive relationship with number of fertile florets (NFF) at W10. Collectively, more available assimilates in spike accelerated anther turning green during period of early floret development, maintained their development normally and becoming fertile florets, but did not make florets that initiate abortion become fertile florets and increase the MFP. [ABSTRACT FROM AUTHOR]

Published

2021

36. TaSPL13 regulates inflorescence architecture and development in transgenic wheat (Triticum aestivum L.).

Author

Li, Li, Shi, Fu, Wang, Yaqiong, Yu, Xiaofen, Zhi, Jingjing, Guan, Yanbin, Zhao, Hongyan, Chang, Junli, Chen, Mingjie, Yang, Guangxiao, Wang, Yuesheng, and He, Guangyuan

Subjects

*WHEAT, *INFLORESCENCES, *TRANSGENIC rice, *SEED development, *WHEAT seeds, *ORYZA

Abstract

• Expression patterns of TaSPLs in different tissues of wheat by RNA-seq. • TaSPL13-2B transgenic rice showing increased panicle branches with more grains. • TaSPL13-2B transgenic wheat with significant increases in florets and grains per spike. The SQUAMOSA promoter-binding protein-like (SPL) proteins play vital roles in plant growth and development in rice (Oryza sative L.) and Arabidopsis thaliana (L.) Heynh. However, few studies regarding the SPL proteins have been reported in wheat. In this study, 56 TaSPLs were clustered into eight groups according to an OsSPL phylogenetic comparison analysis. The expression patterns of TaSPLs in different tissues were analysed by RNA-seq data, and partial results were confirmed by qRT-PCR. Based on the above results, genes such as TaSPL13 and TaSPL15 may be involved in spike or seed development in wheat. Multiple genes that regulate the inflorescence architecture of rice have been identified. Additionally, studies on the genes associated with spikelet development in wheat have been reported relatively rarely. Here, TaSPL13-2B was transferred into wheat cv. Bobwhite. Compared with the wild type, the transgenic lines showed significant increases in the number of florets and grains per spike, indicating that TaSPL13-2B could influence the floret development of wheat. TaSPL13-2B was transferred into rice cv. Nipponbare, which demonstrated that TaSPL13-2B can modify panicle architecture in transgenic rice, with significant increases in panicle length, the number and length of primary branches, and the number of secondary branches. [ABSTRACT FROM AUTHOR]

Published

2020

37. Physiological determinants of fertile florets in wheat: variation between elite cultivars and effects of Ppd and Eps genes

Author

Prieto, Paula, Savin, Roxana, Slafer, Gustavo A., and Universitat de Lleida. Departament de Producció Vegetal i Ciència Forestal

Subjects

Fotoperíode, Desenvolupament floral, Producció vegetal, Photoperiod, Fotoperiodo, Precocidad intrínseca, Floret development, Desarrollo floral, Earliness per se, Precocitat intrínseca

Abstract

El rendimiento del cultivo de trigo se encuentra linealmente relacionado con el número de granos por m2. Entender los determinantes fisiológicos del número de flores fértiles, que es resultado de las diferentes dinámicas del desarrollo floral dadas por variabilidad genética, y determinar el rol particular de los genes de fotoperiodo (Ppd) y precocidad intrínseca (Eps) podría ser útil para lograr mejoras en el número de granos y por lo tanto en el rendimiento. Se llevaron a cabo ensayos a campo, con el objetivo de caracterizar las dinámicas de iniciación y degeneración de primordios florales en un set de cultivares modernos de trigo hexaploide y en líneas isogénicas para Ppd y Eps, y determinar cuáles son los parámetros críticos de esas dinámicas que establecen las diferencias genotípicas en el número de flores fértiles en antesis. Además, se evaluó la interacción entre los genes Eps y la temperatura. Se encontró gran variabilidad en el número de flores fértiles debido a distinto fondo genético entre cultivares elite y debido a la introgresión de alelos insensibles al fotoperiodo. Los efectos en las líneas isogénicas para Eps fueron sutiles y resultaron estar fuertemente relacionados con la temperatura. Las diferencias fueron explicadas principalmente por diferencias en las dinámicas de generación/degeneración de flores y en la mayoría de los casos asociadas a la supervivencia. Mayormente estas diferencias correlacionaron bien con las diferencias en la fase reproductiva tardía. Aquellos cultivares con mayor número de flores fértiles en las poblaciones elite, podrían ser utilizados en los próximos programas de mejoramiento; en el caso de manipular la insensibilidad a fotoperiodo o la precocidad intrínseca, los mejoradores deberían ser cautelosos debido a los efectos que puedan causar sobre el establecimiento de la fertilidad de la espiga., Wheat yield is linearly related to grain number per m2. Understanding the physiological determinants of fertile florets resulted of the different floret development dynamics due to genetic variability and ascertaining the role the particular genes: Photoperiod (Ppd) and earliness per se (Eps) might be useful to achieve improvements in grain number and yield. Field studies were carried out mainly to characterize the dynamics of floret primordia initiation and degeneration in a set of modern cultivars of hexaploid wheat and in Ppd and Eps near isogenic lines (NILs) and to determine which are the most critical parameters of such dynamics in establishing genotypic differences in the number of fertile florets at anthesis. In addition, it was evaluated the interaction between the Eps genes and temperature. High variability was found in the number of fertile florets due to different genetic background among elite cultivars and due to the introgression of the photoperiod insensitivity alleles. Effects among Eps NILs were subtle and presented a strong relationship with the temperature. Differences were mainly explained by differences in the floret generation/degeneration dynamics and in most cases well associated with survival. In most cases, these differences well correlated with differences in the late reproductive phase. Advantageous cultivars with higher number of fertile florets among the elite population tested could be used for the next breeding programs, in the case of manipulating photoperiod insensitivity or the earliness per se, breeders might be careful due to the effects that can caused on the setting of the spike fertility., El rendiment del cultiu de blat es troba linealment relacionat amb el nombre de grans per m2. Entendre els determinants fisiològics del nombre de flors fèrtils, el qual és resultat de les diferents dinàmiques del desenvolupament floral donades per variabilitat genètica, i determinar el rol particular dels gens de fotoperíode (Ppd) i precocitat intrínseca (Eps) podria ser útil per tal d’obtenir millores en el nombre de grans i, per tant, en el rendiment. S’han dut a terme assaigs de camp, amb l’objectiu de caracteritzar les dinàmiques d’iniciació i degeneració de primordis florals en un set de conreus moderns de blat hexaploide i en línies isogèniques per Ppd i Eps, i determinar quins són els paràmetres crítics d’aquestes dinàmiques què estableixen les diferències genotípiques en el nombre de flors fèrtils en antesi. A més a més, es va avaluar la interacció entre els gens Eps i la temperatura. Es va trobar gran variabilitat en el nombre de flors fèrtils donat el diferent fon genètic entre conreus d’elit i degut a la introgressió d’al•lels insensibles al fotoperíode. Els efectes en les línies isogèniques per Eps van ser subtils i van resultar estar freqüentment relacionats amb la temperatura. Les diferències van ser explicades principalment per diferències en les dinàmiques de generació/degeneració de flors i en la majoria dels casos associats a la supervivència. Majoritàriament aquestes diferències van correlacionar bé amb les diferències en la fase reproductiva tardana. Aquells conreus amb un major nombre de flors fèrtils en les poblacions elit, podrien ser utilitzats en els pròxims programes de millora; en el cas de manipular la insensibilitat a fotoperíode o la precocitat intrínseca, els milloradors haurien de ser cautelosos degut als efectes que puguin causar sobre l’establiment de la fertilitat de l’espiga.

Published

2016

38. Fruiting efficiency : an alternative trait to further rise wheat yield

Author

Ignacio Ismael Terrile, Roxana Savin, Ariel Ferrante, Gustavo A. Slafer, Daniel J. Miralles, Guillermo Garcia, Mónica Elía, and Fernanda G González

Subjects

Yields, Grain number, Spikes, Yield component, Biomasa, Trigo, Biology, Componentes de Rendimiento, Agronomía, reproducción y protección de plantas, Yield (wine), Granos, Numero de Granos, Dry Matter Content, Biomass, Triticum Durum, Contenido de Materia Seca, Rendimiento, Renewable Energy, Sustainability and the Environment, Spike dry weight, Forestry, Espigas, Agronomy, CIENCIAS AGRÍCOLAS, purl.org/becyt/ford/4.1 [https], Wheat, Floret development, Trait, Eficiencia Reproductiva, Grain, Agricultura, Silvicultura y Pesca, Coeficiente de Fertilidad, Agronomy and Crop Science, Triticum Aestivum, purl.org/becyt/ford/4 [https], Partitioning, Food Science

Abstract

Further improvements in wheat yields are critical, for which increases in grain number would be required. In the recent past, higher grain number was achieved through increased growth of the juvenile spikes before anthesis, due to the reduction in stem growth. As current cultivars have already an optimum height, alternatives must be identifi ed for further increasing grain number. One of them is increasing fruiting effi ciency (grains set per unit of spike dry weight at anthesis). Fruiting effi ciency is the fi nal outcome of the fate of fl oret development and differences in this trait within modern cultivars would be related to higher survival of fl oret primordia. Then there are two alternative physiological pathways to improve fruiting effi ciency by allowing a normal development of most vulnerable fl oret primordia: an increased allocation of assimilates for the developing fl orets before anthesis, or reduced demand of the fl orets for maintaining their normal development. Both alternatives may be possible, and it might be critical to recognize which of them is the actual cause of differences in fruiting effi ciency. When considering this trait in breeding we must be aware of potential trade- offs and therefore it must be avoided that increases in fruiting effi ciency be constitutively related to decreases in either spike dry weight at anthesis or grain weight. In this review we described fruiting effi ciency and its physiological bases, analyzing genetic variation and considering potential drawbacks that must be taken into account to avoid increases in fruiting effi ciency being compensated by other traits Fil: Gustavo A. Slafer. AGROTECNIO; España. Universidad de Lleida. Departamento de Producción Vegetal y Ciencia Forestal; España. Institució Catalana de Recerca i Estudis Avançats; España Fil: Elia, Mónica. Universidad de Lleida. Departamento de Producción Vegetal y Ciencia Forestal; España. AGROTECNIO; España Fil: Savin, Roxana. Universidad de Lleida. Departamento de Producción Vegetal y Ciencia Forestal; España. AGROTECNIO; España Fil: García, Guillermo Ariel. Consejo Nacional de Investigaciones Científicas y Técnicas. Oficina de Coordinación Administrativa Parque Centenario. Instituto de Investigaciones Fisiológicas y Ecológicas Vinculadas a la Agricultura; Argentina. Universidad de Buenos Aires. Facultad de Agronomía. Departamento de Producción Vegetal; Argentina Fil: Terrile, Ignacio Ismael. Instituto Nacional de Tecnología Agropecuaria. Centro Regional Buenos Aires Norte. Estación Experimental Agropecuaria Pergamino; Argentina Fil: Ferrante, Ariel. The University of Queensland. Queensland Alliance for Agriculture and Food Innovation; Australia Fil: Miralles, Daniel Julio. Consejo Nacional de Investigaciones Científicas y Técnicas. Oficina de Coordinación Administrativa Parque Centenario. Instituto de Investigaciones Fisiológicas y Ecológicas Vinculadas a la Agricultura; Argentina. Universidad de Buenos Aires. Facultad de Agronomía. Departamento de Producción Vegetal; Argentina Fil: González, Fernanda Gabriela. Instituto Nacional de Tecnología Agropecuaria. Centro Regional Buenos Aires Norte. Estación Experimental Agropecuaria Pergamino; Argentina. Consejo Nacional de Investigaciones Científicas y Técnicas; Argentina

Published

2015

39. The barley Lent 1 gene promoter drives expression specifically in outer floret organs at anthesis in transgenic wheat

Author

Somleva, Maria N. and Blechl, Ann E.

Published

2005

40. Effects of exogenous hormones on floret development and grain setin wheat

Author

Wang, Zhaolong, Cao, Weixing, Dai, Tingbo, and Zhou, Qin

Published

2001

41. Autophagy regulated by day length determines the number of fertile florets in wheat

Author

Ghiglione, H.O., Gonzalez, F.G., Serrago, R., Maldonado, S.B., Chilcott, C., Curá, J.A., Miralles, D.J., Zhu, T., and Casal, J.J.

Subjects

cell division, autophagy, Sucrose, Photoperiod, Meristem, Triticum aestivum, Flowers, Genes, Plant, Gene Expression Regulation, Plant, wheat, gene expression profiling, carbohydrate metabolism, genetics, Photosynthesis, gene, Triticum, Cell Proliferation, Oligonucleotide Array Sequence Analysis, fertility, growth, development and aging, plant RNA, Cell Death, article, DNA microarray, Gene Expression Regulation, Developmental, gene expression regulation, flower, photoperiodicity, RNA, Plant, Floret development, Transcriptome, metabolism

Abstract

The wheat spikelet meristem differentiates into up to 12 floret primordia, but many of them fail to reach the fertile floret stage at anthesis. We combined microarray, biochemical and anatomical studies to investigate floret development in wheat plants grown in the field under short or long days (short days extended with low-fluence light) after all the spikelets had already differentiated. Long days accelerated spike and floret development and greening, and the expression of genes involved in photosynthesis, photoprotection and carbohydrate metabolism. These changes started while the spike was in the light-depleted environment created by the surrounding leaf sheaths. Cell division ceased in the tissues of distal florets, which interrupted their normal developmental progression and initiated autophagy, thus decreasing the number of fertile florets at anthesis. A massive decrease in the expression of genes involved in cell proliferation, a decrease in soluble carbohydrate levels, and an increase in the expression of genes involved in programmed cell death accompanied anatomical signs of cell death, and these effects were stronger under long days. We propose a model in which developmentally generated sugar starvation triggers floret autophagy, and long days intensify these processes due to the increased carbohydrate consumption caused by the accelerated plant development. © 2008 The Authors.

Published

2008

42. A study of floret development in wheat (Triticum aestivum L.)

Author

Langer, R.H.M. and Hanif, M.

Published

1973

43. Earliness per se x temperature interaction consequences on leaf, spikelet and floret development in wheat

Author

Helga Ochagavía, Paula Prieto, Simon Griffiths, and Gustavo A. Slafer

Subjects

0106 biological sciences, 0301 basic medicine, Temperature sensitivity, Physiology, Triticum aestivum, Plant Science, Flowers, Biology, Flowering time, 01 natural sciences, 03 medical and health sciences, Spikelet number, Phyllochron, Primordium, floret development, Allele, Alleles, Triticum, 2. Zero hunger, Earliness per se (Eps), AcademicSubjects/SCI01210, Plastochron, Significant difference, Temperature, food and beverages, plastochron, Research Papers, spikelet number, Plant Leaves, Horticulture, 030104 developmental biology, 13. Climate action, phyllochron, Floret development, Growth and Development, 010606 plant biology & botany

Abstract

Temperature can reverse the allelic effect of Eps genes. At low temperatures, early alleles of Eps-D1 are associated with increased fertile floret number but at higher temperatures with less., Wheat adaptation can be fine-tuned by earliness per se (Eps) genes. Although the effects of Eps genes are often assumed to act independently of the environment, previous studies have shown that they exhibit temperature sensitivity. The number of leaves and phyllochron are considered determinants of flowering time and the numerical components of yield include spikelets per spike and fertile floret number within spikelets. We studied the dynamics of leaf, spikelet, and floret development in near isogenic lines with either late or early alleles of Eps-D1 under seven temperature regimes. Leaf appearance dynamics were modulated by temperature, and Eps alleles had a greater effect on the period from flag leaf to heading than phyllochron. In addition, the effects of the Eps alleles on spikelets per spike were minor, and more related to spikelet plastochron than the duration of the early reproductive phase. However, fertile floret number was affected by the interaction between Eps alleles and temperature. So, at 9 °C, Eps-early alleles had more fertile florets than Eps-late alleles, at intermediate temperatures there was no significant difference, and at 18 °C (the highest temperature) the effect was reversed, with lines carrying the late allele producing more fertile florets. These effects were mediated through changes in floret survival; there were no clear effects on the maximum number of floret primordia.

44. Photoperiod-sensitivity genes shape floret development in wheat

Author

Thomas I Pérez-Gianmarco, Fernanda G González, and Gustavo A. Slafer

Subjects

0106 biological sciences, 0301 basic medicine, Physiology, Plant Science, 01 natural sciences, Flowering, Fisiología Vegetal, Photoperiod sensitivity, wheat, Genotype, Cultivar, Triticum, floret initiation, 2. Zero hunger, photoperiodism, PPD-1 GENES, Plant physiology, food and beverages, Research Papers, Horticulture, Plant Physiology, Wheat, Period (gene), Photoperiod, Trigo, Flowers, Biology, Genes, Plant, 03 medical and health sciences, Anthesis, Primordium, Floración, Allele, Fotoperiodismo, floret survival, Alleles, FLORET INITIATION, Floret survival, purl.org/becyt/ford/4.5 [https], 030104 developmental biology, Genes, Plant—Environment Interactions, CIENCIAS AGRÍCOLAS, Floret development, photoperiod sensitivity, Ppd-1 genes, Otras Ciencias Agrícolas, purl.org/becyt/ford/4 [https], 010606 plant biology & botany

Abstract

Higher photoperiod sensitivity in wheat is associated with more fertile florets per spike at anthesis due to a longer floret initiation phase, which results in higher numbers of initiated florets, and to increased floret survival., Lengthening the pre-anthesis period of stem elongation (or late-reproductive phase, LRP) through altering photoperiod sensitivity has been suggested as a potential means to increase the number of fertile florets at anthesis (NFF) in wheat. However, little is known about the effects that the Ppd-1 genes modulating plant response to photoperiod may have on reproductive development. Here, five genotypes with either sensitive (b) or insensitive (a) alleles were grown in chambers under contrasting photoperiods (12 h or 16 h) to assess their effects. The genotypes consisted of the control cultivar Paragon (three Ppd-1b) and four near-isogenic lines of Paragon with Ppd-1a alleles introgressed from: Chinese Spring (Ppd-B1a), GS-100 (Ppd-A1a), Sonora 64 (Ppd-D1a), and Triple Insensitive (three Ppd-1a). Under a 12-h photoperiod, NFF in the genotypes followed the order three Ppd-1b > Ppd-B1a > Ppd-A1a > Ppd-D1a > three Ppd-1a. Under a 16-h photoperiod the differences were milder, but three Ppd-1b still had a greater NFF than the rest. As Ppd-1a alleles shortened the LRP, spikes were lighter and the NFF decreased. The results demonstrated for the first time that Ppd-1a decreases the maximum number of florets initiated through shortening the floret initiation phase, and this partially explained the variations in NFF. The most important impact of Ppd-1a alleles, however, was related to a reduction in survival of floret primordia, which resulted in the lower NFF. These findings reinforce the idea that an increased duration of the LRP, achieved through photoperiod sensitivity, would be useful for increasing wheat yield potential.