Your search keyword '"Edible Grain physiology"' showing total 328 results

1. Natural variation in LONELY GUY-Like 1 regulates rice grain weight under warmer night conditions.

Author

Sandhu J, Irvin L, Chandaran AK, Oguro S, Paul P, Dhatt B, Hussain W, Cunningham SS, Quinones CO, Lorence A, Adviento-Borbe MA, Staswick P, Morota G, and Walia H

Subjects

Genome-Wide Association Study, Gene Expression Regulation, Plant, Genetic Variation, Oryza genetics, Oryza growth & development, Oryza physiology, Plant Proteins genetics, Plant Proteins metabolism, Edible Grain genetics, Edible Grain growth & development, Edible Grain physiology

Abstract

Global nighttime temperatures are rising at twice the rate of daytime temperatures and pose a challenge for rice (Oryza sativa) production. High nighttime temperature (HNT) stress affects rice yield by reducing grain weight, size, and fertility. Although the genes associated with these yield parameters have been identified and characterized under normal temperatures, the genetic basis of grain weight regulation under HNT stress remains less explored. We examined the natural variation for rice single grain weight (SGW) under HNT stress imposed during grain development. A genome-wide association analysis identified several loci associated with grain weight under HNT stress. A locus, SGW1, specific to HNT conditions resolved to LONELY GUY-Like 1 (LOGL1), which encodes a putative cytokinin-activation enzyme. We demonstrated that LOGL1 contributes to allelic variation at SGW1. Accessions with lower LOGL1 transcript abundance had higher grain weight under HNT. This was supported by the higher grain weight of logl1-mutants relative to the wild type under HNT. Compared to logl1-mutants, LOGL1 over-expressers showed increased sensitivity to HNT. We showed that LOGL1 regulates the thiamin biosynthesis pathway, which is under circadian regulation, which in turn is likely perturbed by HNT stress. These findings provide a genetic source to enhance rice adaptation to warming night temperatures and improve our mechanistic understanding of HNT stress tolerance pathways., Competing Interests: Conflict of interest statement. None declared., (© The Author(s) 2024. Published by Oxford University Press on behalf of American Society of Plant Biologists.)

Published

2024

2. Photosynthetic performance of glumes of oat spikelets is more stable for grain-filling stage under drought stress.

Author

Zeng H, Yi K, Yang S, Jiang Y, Mao P, Yu Y, Feng Y, Dong Y, Dou L, and Li M

Subjects

Chlorophyll metabolism, Plant Leaves metabolism, Plant Leaves physiology, Stress, Physiological, Gene Expression Regulation, Plant, Photosystem I Protein Complex metabolism, Edible Grain physiology, Edible Grain genetics, Edible Grain growth & development, Edible Grain metabolism, Plant Proteins metabolism, Plant Proteins genetics, Photosynthesis physiology, Avena genetics, Avena metabolism, Avena growth & development, Avena physiology, Droughts, Photosystem II Protein Complex metabolism

Abstract

Drought stress affects plant photosynthesis, leading to a reduction in the quality and yield of crop production. Non-foliar organs play a complementary role in photosynthesis during plant growth and development and are important sources of energy. However, there are limited studies on the performance of non-foliar organs under drought stress. The photosynthetic-responsive differences of oat spikelet organs (glumes, lemmas and paleas) and flag leaves to drought stress during the grain-filling stage were examined. Under drought stress, photosynthetic performance of glume is more stable. Intercellular CO 2 concentration (Ci), chlorophyll b, maximum photochemical efficiency of photosystem II. (Fv/Fm), and electron transport rate (ETR) were significantly higher in the glume compared to the flag leaf. The transcriptome data revealed that stable expression of the RCCR gene under drought stress was the main reason for maintaining higher chlorophyll content in the glume. Additionally, no differential expression genes (DEGs) related to Photosystem Ⅰ (PSI) reaction centers were found, and drought stress primarily affects the Photosystem II (PSII) reaction center. In spikelets, the CP43 and CP47 subunits of PSII and the AtpB subunit of ATP synthase were increased on the thylakoid membrane, contributing to photosynthetic stabilisation of spikelets as a means of supplementing the limited photosynthesis of the leaves under drought stress. The results enhanced understanding of the photosynthetic performance of oat spikelet during the grain-filling stage, and also provided an important basis on improving the photosynthetic capacity of non-foliar organs for the selection and breeding new oat varieties with high yield and better drought resistance., Competing Interests: Declaration of competing interest The authors declare that they have no known competing financial interests or personal relationships that could have appeared to influence the work reported in this paper., (Copyright © 2024 Elsevier Masson SAS. All rights reserved.)

Published

2024

3. Physiological traits, crop growth, and grain quality of quinoa in response to deficit irrigation and planting methods.

Author

Mirsafi SM, Sepaskhah AR, and Ahmadi SH

Subjects

Edible Grain growth & development, Edible Grain physiology, Crops, Agricultural growth & development, Crops, Agricultural physiology, Droughts, Seeds growth & development, Seeds physiology, Crop Production methods, Water metabolism, Chenopodium quinoa physiology, Chenopodium quinoa growth & development, Chenopodium quinoa metabolism, Agricultural Irrigation methods

Abstract

Climate change has become a concern, emphasizing the need for the development of crops tolerant to drought. Therefore, this study is designed to explore the physiological characteristics of quinoa that enable it to thrive under drought and other extreme stress conditions by investigating the combined effects of irrigation water levels (100%, 75%, and 50% of quinoa's water requirements, WR as I1, I2 and I3) and different planting methods (basin, on-ridge, and in-furrow as P1, P2 and P3) on quinoa's physiological traits and gas exchange. Results showed that quinoa's yield is lowest with on-ridge planting and highest in the in-furrow planting method. Notably, the seed protein concentrations in I2 and I3 did not significantly differ but they were 25% higher than those obtained in I1, which highlighted the possibility of using a more effective irrigation method without compromising the seed quality. On the other hand, protein yield (PY) was lowest in P2 (mean of I1 and I2 as 257 kg ha -1 ) and highest in P3 (mean of I1 and I2 as 394 kg ha -1 , 53% higher). Interestingly, PY values were not significantly different in I1 and I2, but they were lower significantly in I3 by 28%, 27% and 20% in P1, P2, and P3, respectively. Essential plant characteristics including plant height, stem diameter, and panicle number were 6.1-16.7%, 6.4-24.5%, and 18.4-36.5% lower, respectively, in I2 and I3 than those in I1. The highest Leaf Area Index (LAI) value (5.34) was recorded in the in-furrow planting and I1, while the lowest value was observed in the on-ridge planting method and I3 (3.47). In I3, leaf temperature increased by an average of 2.5-3 o C, particularly during the anthesis stage. The results also showed that at a similar leaf water potential (LWP) higher yield and dry matter were obtained in the in-furrow planting compared to those obtained in the basin and on-ridge planting methods. The highest stomatal conductance (gs) value was observed within the in-furrow planting method and full irrigation (I1P3), while the lowest values were obtained in the on-ridge and 50%WR (I3P2). Finally, photosynthesis rate (An) reduction with diminishing LWP was mild, providing insights into quinoa's adaptability to drought. In conclusion, considering the thorough evaluation of all the measured parameters, the study suggests using the in-furrow planting method with a 75%WR as the best approach for growing quinoa in arid and semi-arid regions to enhance production and resource efficiency., (© 2024. The Author(s).)

Published

2024

4. Spectral-genomic chain-model approach enhances the wheat yield component prediction under the Mediterranean climate.

Author

Sadeh R, Ben-David R, Herrmann I, and Peleg Z

Subjects

Mediterranean Region, Genomics methods, Edible Grain genetics, Edible Grain growth & development, Edible Grain physiology, Phenotype, Machine Learning, Plant Breeding methods, Triticum genetics, Triticum growth & development, Triticum physiology, Climate

Abstract

In light of the changing climate that jeopardizes future food security, genomic selection is emerging as a valuable tool for breeders to enhance genetic gains and introduce high-yielding varieties. However, predicting grain yield is challenging due to the genetic and physiological complexities involved and the effect of genetic-by-environment interactions on prediction accuracy. We utilized a chained model approach to address these challenges, breaking down the complex prediction task into simpler steps. A diversity panel with a narrow phenological range was phenotyped across three Mediterranean environments for various morpho-physiological and yield-related traits. The results indicated that a multi-environment model outperformed a single-environment model in prediction accuracy for most traits. However, prediction accuracy for grain yield was not improved. Thus, in an attempt to ameliorate the grain yield prediction accuracy, we integrated a spectral estimation of spike number, being a major wheat yield component, with genomic data. A machine learning approach was used for spike number estimation from canopy hyperspectral reflectance captured by an unmanned aerial vehicle. The spectral-based estimated spike number was utilized as a secondary trait in a multi-trait genomic selection, significantly improving grain yield prediction accuracy. Moreover, the ability to predict the spike number based on data from previous seasons implies that it could be applied to new trials at various scales, even in small plot sizes. Overall, we demonstrate here that incorporating a novel spectral-genomic chain-model workflow, which utilizes spectral-based phenotypes as a secondary trait, improves the predictive accuracy of wheat grain yield., (© 2024 The Author(s). Physiologia Plantarum published by John Wiley & Sons Ltd on behalf of Scandinavian Plant Physiology Society.)

Published

2024

5. Molecular mechanisms underlying low temperature inhibition of grain filling in maize (Zea mays L.): coordination of growth and cold responses.

Author

Xu C, Wang X, Wu Y, Gao J, Zhang P, Zhao Y, Liu X, Wang P, and Huang S

Subjects

Glucosyltransferases metabolism, Glucosyltransferases genetics, Photosynthesis, Starch metabolism, Edible Grain growth & development, Edible Grain genetics, Edible Grain physiology, Plant Proteins metabolism, Plant Proteins genetics, Seeds growth & development, Seeds genetics, Seeds metabolism, Brassinosteroids metabolism, Steroids, Heterocyclic pharmacology, Steroids, Heterocyclic metabolism, Zea mays growth & development, Zea mays genetics, Zea mays metabolism, Zea mays physiology, Cold Temperature, Gene Expression Regulation, Plant

Abstract

Low temperature (LT) greatly restricts grain filling in maize (Zea mays L.), but the relevant molecular mechanisms are not fully understood. To better understand the effect of LT on grain development, 17 hybrids were subjected to LT stress in field trials over 3 years, and two hybrids of them with contrasting LT responses were exposed to 30/20°C and 20/10°C for 7 days during grain filling in a greenhouse. At LT, thousand-kernel weight declined, especially in LT-sensitive hybrid FM985, while grain-filling rate was on average about 48% higher in LT-tolerant hybrid DK159 than FM985. LT reduced starch synthesis in kernel mainly by suppression of transcript levels and enzyme activities for sucrose synthase and hexokinase. Brassinolide (BR) was abundant in DK159 kernel, and genes involved in BR and cytokinin signals were inducible by stress. LT downregulated the genes in light-harvesting complex and photosystem I/II subunits, accompanied by reduced photosynthetic rate and Fv/Fm in ear leaf. The LT-tolerant hybrid could maintain a high soluble sugar content and fast interconversion between sucrose and hexose in the stem internode and cob, improving assimilate allocation to kernel at LT stress and paving the way for simultaneous growth and LT stress responses., (© 2024 Society for Experimental Biology and John Wiley & Sons Ltd.)

Published

2024

6. Improving resilience to high temperature in drought: water replenishment enhances sucrose and amino acid metabolisms in maize grain.

Author

Wang X, Wang J, Zhu Y, Qu Z, Liu X, Wang P, and Meng Q

Subjects

Edible Grain physiology, Edible Grain genetics, Hot Temperature, Gene Expression Regulation, Plant, Heat-Shock Response physiology, Zea mays genetics, Zea mays physiology, Zea mays metabolism, Droughts, Amino Acids metabolism, Water metabolism, Sucrose metabolism

Abstract

Heat stress poses a significant threat to maize, especially when combined with drought. Recent research highlights the potential of water replenishment to ameliorate grain weight loss. However, the mitigating mechanisms of heat in drought stress, especially during the crucial early grain-filling stage, remain poorly understood. We investigated the mechanism for mitigating heat in drought stress by water replenishment from the 12th to the 32nd days after silking in a controlled greenhouse experiment (Exp. I) and field trial (Exp. II). A significant reduction in grain weight was observed in heat stress compared to normal conditions. When water replenishment was applied to increase soil water content (SWC) under heat stress, the grain yield exhibited a notable increase ranging from 28.4 to 76.9%. XY335 variety was used for transcriptome sequencing to analyze starch biosynthesis and amino acid metabolisms in Exp. I. With water replenishment, the transcripts of genes responsible for trehalose 6-phosphate phosphates (TPP), alpha-trehalase (TRE), ADP-glcpyrophosphorylase, and starch synthase activity were stimulated. Additionally, the expression of genes encoding TPP and TRE contributed to an enhanced conversion of trehalose to glucose. This led to the conversion of sucrose from glucose-1-phosphate to ADP-glucose and ADP-glucose to amylopectin, ultimately increasing starch production by 45.1%. Water replenishment to boost SWC during heat stress also elevated the levels of essential amino acids in maize, including arginine, serine, tyrosine, leucine, glutamic acid, and methionine, providing valuable support to maize plants in adversity. Field trials further validated the positive impact of water replenishment on SWC, resulting in a notable increase in grain yield ranging from 7.1 to 9.2%. This study highlights the vital importance of adapting to abiotic stress and underscores the necessity of developing strategies to counteract its adverse effects on crop yield., (© 2024 Society for Experimental Biology and John Wiley & Sons Ltd.)

Published

2024

7. The Birth and Death of Floral Organs in Cereal Crops.

Author

Huang Y and Schnurbusch T

Subjects

Photosynthesis physiology, Gene Expression Regulation, Plant, Meristem growth & development, Meristem physiology, Flowers growth & development, Flowers physiology, Flowers genetics, Crops, Agricultural growth & development, Crops, Agricultural physiology, Crops, Agricultural genetics, Edible Grain growth & development, Edible Grain physiology

Abstract

Florets of cereal crops are the basic reproductive organs that produce grains for food or feed. The birth of a floret progresses through meristem initiation and floral organ identity specification and maintenance. During these processes, both endogenous and external cues can trigger a premature floral organ death, leading to reproductive failure. Recent advances in different cereal crops have identified both conserved and distinct regulators governing the birth of a floret. However, the molecular underpinnings of floral death are just beginning to be understood. In this review, we first provide a general overview of the current findings in the field of floral development in major cereals and outline different forms of floral deaths, particularly in the Triticeae crops. We then highlight the importance of vascular patterning and photosynthesis in floral development and reproductive success and argue for an expanded knowledge of floral birth-death balance in the context of agroecology.

Published

2024

8. Ethylene regulates auxin-mediated root gravitropic machinery and controls root angle in cereal crops.

Author

Kong X, Xiong Y, Song X, Wadey S, Yu S, Rao J, Lale A, Lombardi M, Fusi R, Bhosale R, and Huang G

Subjects

Edible Grain drug effects, Edible Grain physiology, Edible Grain growth & development, Edible Grain genetics, Crops, Agricultural genetics, Crops, Agricultural growth & development, Crops, Agricultural physiology, Mutation genetics, Gene Expression Regulation, Plant drug effects, Arabidopsis genetics, Arabidopsis physiology, Arabidopsis drug effects, Arabidopsis growth & development, Plant Proteins metabolism, Plant Proteins genetics, Ethylenes metabolism, Indoleacetic Acids metabolism, Gravitropism drug effects, Gravitropism physiology, Plant Roots drug effects, Plant Roots growth & development, Plant Roots physiology, Plant Roots genetics, Oryza genetics, Oryza physiology, Oryza drug effects, Oryza growth & development, Zea mays drug effects, Zea mays genetics, Zea mays physiology, Zea mays growth & development

Abstract

Root angle is a critical factor in optimizing the acquisition of essential resources from different soil depths. The regulation of root angle relies on the auxin-mediated root gravitropism machinery. While the influence of ethylene on auxin levels is known, its specific role in governing root gravitropism and angle remains uncertain, particularly when Arabidopsis (Arabidopsis thaliana) core ethylene signaling mutants show no gravitropic defects. Our research, focusing on rice (Oryza sativa L.) and maize (Zea mays), clearly reveals the involvement of ethylene in root angle regulation in cereal crops through the modulation of auxin biosynthesis and the root gravitropism machinery. We elucidated the molecular components by which ethylene exerts its regulatory effect on auxin biosynthesis to control root gravitropism machinery. The ethylene-insensitive mutants ethylene insensitive2 (osein2) and ethylene insensitive like1 (oseil1), exhibited substantially shallower crown root angle compared to the wild type. Gravitropism assays revealed reduced root gravitropic response in these mutants. Hormone profiling analysis confirmed decreased auxin levels in the root tips of the osein2 mutant, and exogenous auxin (NAA) application rescued root gravitropism in both ethylene-insensitive mutants. Additionally, the auxin biosynthetic mutant mao hu zi10 (mhz10)/tryptophan aminotransferase2 (ostar2) showed impaired gravitropic response and shallow crown root angle phenotypes. Similarly, maize ethylene-insensitive mutants (zmein2) exhibited defective gravitropism and root angle phenotypes. In conclusion, our study highlights that ethylene controls the auxin-dependent root gravitropism machinery to regulate root angle in rice and maize, revealing a functional divergence in ethylene signaling between Arabidopsis and cereal crops. These findings contribute to a better understanding of root angle regulation and have implications for improving resource acquisition in agricultural systems., Competing Interests: Conflict of interest statement. The authors declare that they have no competing interests., (© The Author(s) 2024. Published by Oxford University Press on behalf of American Society of Plant Biologists. All rights reserved. For commercial re-use, please contact reprints@oup.com for reprints and translation rights for reprints. All other permissions can be obtained through our RightsLink service via the Permissions link on the article page on our site—for further information please contact journals.permissions@oup.com.)

Published

2024

9. Guard cell and subsidiary cell sizes are key determinants for stomatal kinetics and drought adaptation in cereal crops.

Author

Rui M, Chen R, Jing Y, Wu F, Chen ZH, Tissue D, Jiang H, and Wang Y

Subjects

Kinetics, Models, Biological, Water metabolism, Water physiology, Plant Stomata physiology, Droughts, Edible Grain physiology, Adaptation, Physiological, Crops, Agricultural physiology, Cell Size

Abstract

Climate change-induced drought is a major threat to agriculture. C 4 crops have a higher water use efficiency (WUE) and better adaptability to drought than C 3 crops due to their smaller stomatal morphology and faster response. However, our understanding of stomatal behaviours in both C 3 and C 4 Poaceae crops is limited by knowledge gaps in physical traits of guard cell (GC) and subsidiary cell (SC). We employed infrared gas exchange analysis and a stomatal assay to explore the relationship between GC/SC sizes and stomatal kinetics across diverse drought conditions in two C 3 (wheat and barley) and three C 4 (maize, sorghum and foxtail millet) upland Poaceae crops. Through statistical analyses, we proposed a GCSC-τ model to demonstrate how morphological differences affect stomatal kinetics in C 4 Poaceae crops. Our findings reveal that morphological variations specifically correlate with stomatal kinetics in C 4 Poaceae crops, but not in C 3 ones. Subsequent modelling and experimental validation provide further evidence that GC/SC sizes significantly impact stomatal kinetics, which affects stomatal responses to different drought conditions and thereby WUE in C 4 Poaceae crops. These findings emphasize the crucial advantage of GC/SC morphological characteristics and stomatal kinetics for the drought adaptability of C 4 Poaceae crops, highlighting their potential as future climate-resilient crops., (© 2024 The Authors New Phytologist © 2024 New Phytologist Foundation.)

Published

2024

10. ABA biosynthesis gene OsNCED3 contributes to preharvest sprouting resistance and grain development in rice.

Author

Chen Y, Xiang Z, Liu M, Wang S, Zhang L, Cai D, Huang Y, Mao D, Fu J, and Chen L

Subjects

Germination genetics, Plant Dormancy genetics, Abscisic Acid, Seeds physiology, Gene Expression Regulation, Plant, Edible Grain physiology, Oryza physiology

Abstract

Preharvest sprouting (PHS) is an unfavorable trait in cereal crops and causes serious yield loss. However, the molecular mechanism underlying PHS remains largely elusive. Here, we identified a member of 9-cis-epoxycarotenoid dioxygenase family, OsNCED3, which regulates PHS and grain development in rice (Oryza sativa L.). OsNCED3 encodes a chloroplast-localized abscisic acid (ABA) biosynthetic enzyme highly expressed in the embryo of developing seeds. Disruption of OsNCED3 by CRISPR/Cas9-mediated mutagenesis led to a lower ABA and higher gibberellic acid (GA) levels (thus a skewed ABA/GA ratio) in the embryo, promoting embryos growth and breaking seed dormancy before seed maturity and harvest, thus decreased seed dormancy and enhanced PHS in rice. However, the overexpression of OsNCED3 enhanced PHS resistance by regulating proper ABA/GA ratio in the embryo. Intriguingly, the overexpression of OsNCED3 resulted in increased grain size and weight, whereas the disruption of OsNCED3 function decreased grain size and weight. Nucleotide diversity analyses suggested that OsNCED3 may be selected during japonica populations adaptation of seed dormancy and germination. Taken together, we have identified a new OsNCED regulator involved rice PHS and grain development, and provide a potential target gene for improving PHS resistance and grain development in rice., (© 2022 John Wiley & Sons Ltd.)

Published

2023

11. A 'wiring diagram' for source strength traits impacting wheat yield potential.

Author

Murchie EH, Reynolds M, Slafer GA, Foulkes MJ, Acevedo-Siaca L, McAusland L, Sharwood R, Griffiths S, Flavell RB, Gwyn J, Sawkins M, and Carmo-Silva E

Subjects

Phenotype, Photosynthesis physiology, Plant Leaves, Triticum physiology, Edible Grain physiology

Abstract

Source traits are currently of great interest for the enhancement of yield potential; for example, much effort is being expended to find ways of modifying photosynthesis. However, photosynthesis is but one component of crop regulation, so sink activities and the coordination of diverse processes throughout the crop must be considered in an integrated, systems approach. A set of 'wiring diagrams' has been devised as a visual tool to integrate the interactions of component processes at different stages of wheat development. They enable the roles of chloroplast, leaf, and whole-canopy processes to be seen in the context of sink development and crop growth as a whole. In this review, we dissect source traits both anatomically (foliar and non-foliar) and temporally (pre- and post-anthesis), and consider the evidence for their regulation at local and whole-plant/crop levels. We consider how the formation of a canopy creates challenges (self-occlusion) and opportunities (dynamic photosynthesis) for components of photosynthesis. Lastly, we discuss the regulation of source activity by feedback regulation. The review is written in the framework of the wiring diagrams which, as integrated descriptors of traits underpinning grain yield, are designed to provide a potential workspace for breeders and other crop scientists that, along with high-throughput and precision phenotyping data, genetics, and bioinformatics, will help build future dynamic models of trait and gene interactions to achieve yield gains in wheat and other field crops., (© The Author(s) 2022. Published by Oxford University Press on behalf of the Society for Experimental Biology.)

Published

2023

12. Physiological and biochemical responses of hybrid maize ( Zea mays L .) varieties grown under heat stress conditions.

Author

Tas T

Subjects

Plant Leaves genetics, Stress, Physiological genetics, Heat-Shock Response genetics, Zea mays genetics, Edible Grain physiology

Abstract

Maize ( Zea mays L .) is the second most commonly produced and consumed crop after wheat globally and is adversely affected by high heat, which is a significant abiotic stress factor. This study was carried out to determine the physiological and biochemical responses of hybrid corn varieties under heat stress ('HS') compared to control ('C') conditions during the 2020 and 2021 growing seasons. The experiment was conducted under natural conditions in the Southeastern region of Turkey, where the most intense temperatures are experienced. This experiment used split plots in randomized blocks with three replications, with 'HS' and 'C' growing conditions applied to the main plots and the different hybrid corn varieties (FAO 650) planted on the sub plots. Mean values of days to 50% tasseling (DT, day), grain yield (GY, kg ha -1 ), leaf water potential (LWP, %), chlorophyll-a (Chl-a, mg g -1 ), cell membrane damage (CMD, %), and total phenol content (TPC, μg g -1 ) were significantly different between years, growing conditions, and hybrid corn varieties. Changes in the climate played a significant role in the differences between the years and growing conditions (GC), while the genetic characteristics of the different corn varieties explained the differences in outcomes between them. The values of DT, GY, LWP, Chl-a, CMD, and TPC ranged from 49.06-53.15 days, 9,173.0-10,807.2 kg ha -1 , 78.62-83.57%, 6.47-8.62 mg g -1 , 9.61-13.54%, and 232.36-247.01 μg g -1 , respectively. Significant correlations were recorded between all the parameters. Positive correlations were observed between all the variables except for CMD. The increased damage to cell membranes under 'HS' caused a decrease in the other measured variables, especially GY. In contrast, the GY increased with decreased CMD. CMD was important in determining the stress and tolerance level of corn varieties under 'HS' conditions. The GY and other physiological parameters of ADA 17.4 and SYM-307 candidate corn varieties surpassed the control hybrid corn cultivars. The results revealed that the ADA 17.4 and SYM-307 cultivars might have 'HS'-tolerate genes., Competing Interests: The authors declare that they have no competing interests., (© 2022 Tas.)

Published

2022

13. The wheat ABA receptor gene TaPYL1-1B contributes to drought tolerance and grain yield by increasing water-use efficiency.

Author

Mao H, Jian C, Cheng X, Chen B, Mei F, Li F, Zhang Y, Li S, Du L, Li T, Hao C, Wang X, Zhang X, and Kang Z

Subjects

Droughts, Edible Grain physiology, Gene Expression Regulation, Plant, Water physiology, Abscisic Acid metabolism, Plant Proteins genetics, Plant Proteins physiology, Receptors, Cytoplasmic and Nuclear physiology, Triticum physiology

Abstract

The role of abscisic acid (ABA) receptors, PYR1/PYL/RCAR (PYLs), is well established in ABA signalling and plant drought response, but limited research has explored the regulation of wheat PYLs in this process, especially the effects of their allelic variations on drought tolerance or grain yield. Here, we found that the overexpression of a TaABFs-regulated PYL gene, TaPYL1-1B, exhibited higher ABA sensitivity, photosynthetic capacity and water-use efficiency (WUE), all contributed to higher drought tolerance than that of wild-type plants. This heightened water-saving mechanism further increased grain yield and protected productivity during water deficit. Candidate gene association analysis revealed that a favourable allele TaPYL1-1B In-442 , carrying an MYB recognition site insertion in the promoter, is targeted by TaMYB70 and confers enhanced expression of TaPYL1-1B in drought-tolerant genotypes. More importantly, an increase in frequency of the TaPYL1-1B In-442 allele over decades among modern Chinese cultivars and its association with high thousand-kernel weight together demonstrated that it was artificially selected during wheat improvement efforts. Taken together, our findings illuminate the role of TaPYL1-1B plays in coordinating drought tolerance and grain yield. In particular, the allelic variant TaPYL1-1B In-442 substantially contributes to enhanced drought tolerance while maintaining high yield, and thus represents a valuable genetic target for engineering drought-tolerant wheat germplasm., (© 2021 The Authors. Plant Biotechnology Journal published by Society for Experimental Biology and The Association of Applied Biologists and John Wiley & Sons Ltd.)

Published

2022

14. CRISPR-Cas9 Mediated Mutation in OsPUB43 Improves Grain Length and Weight in Rice by Promoting Cell Proliferation in Spikelet Hull.

Author

Wu Q, Liu Y, and Huang J

Subjects

CRISPR-Cas Systems, Edible Grain physiology, Gene Editing, Oryza anatomy & histology, Oryza metabolism, Oryza physiology, Plant Proteins genetics, Cell Proliferation, Edible Grain anatomy & histology, Mutation, Oryza enzymology, Ubiquitin-Protein Ligases genetics

Abstract

Grain weight, a crucial trait that determines the grain yield in rice, is influenced by grain size. Although a series of regulators that control grain size have been identified in rice, the mechanisms underlying grain development are not yet well understood. In this study, we identified OsPUB43, a U-box E3 ubiquitin ligase, as an important negative regulator determining the gain size and grain weight in rice. Phenotypes of large grain are observed in ospub43 mutants, whereas overexpression of OsPUB43 results in short grains. Scanning electron microscopy analysis reveals that OsPUB43 modulates the grain size mainly by inhibiting cell proliferation in the spikelet hull. The OsPUB43 protein is localized in the cytoplasm and nucleus. The ospub43 mutants display high sensitivity to exogenous BR, while OsPUB43 -OE lines are hyposensitive to BR. Furthermore, the transient transcriptional activity assay shows that OsBZR1 can activate the expression of OsPUB43 . Collectively, our results indicate that OsPUB43 negatively controls the gain size by modulating the expression of BR-responsive genes as well as MADS-box genes that are required for lemma/palea specification, suggesting that OsPUB43 has a potential valuable application in the enlargement of grain size in rice.

Published

2022

15. Exogenous phytohormones in the regulation of growth and development of cereals under abiotic stresses.

Author

Kosakivska IV, Vedenicheva NP, Babenko LM, Voytenko LV, Romanenko KO, and Vasyuk VA

Subjects

Biomarkers, Cytokinins metabolism, Gene Expression Regulation, Plant, Plant Growth Regulators pharmacology, Signal Transduction, Edible Grain physiology, Plant Development, Plant Growth Regulators metabolism, Plant Physiological Phenomena, Stress, Physiological

Abstract

Abiotic stresses, among which extreme temperatures, salinity, drought, UV radiation, heavy metal pollution, etc., adversely affect the growth and yield of cereals, the most important group of monocotyledonous plants that have met the nutritional and other needs of mankind for thousands of years. To cope with stress, plants deploy certain adaptive strategies that combine morphological, physiological, and biochemical responses, and on which growth and productivity depend. An important place in the formation of such strategies is occupied by phytohormones - signaling biomolecules of a different chemical structure and physicochemical properties, which act in nanomolar concentrations and regulate most physiological and metabolic processes of plants. In this review, the latest literature data concerning the growth and development regulation by exogenous phytohormones in cereals under abiotic stresses have been analyzed and summarized. The effects of priming and foliar treatment with abscisic acid, gibberellins, auxins, cytokinins, brassinosteroids, jasmonic and salicylic acids on the cultivated cereals tolerance to different abiotic stressors are discussed. Peculiarities of bilateral and multilateral hormonal signaling in the formation of responses of cultivated cereals to abiotic stressors after application of exogenous phytohormones are considered. The issue of exogenous phytohormones effects on molecular mechanisms controlling the synthesis of endogenous hormones, their signaling and activity are singled out. It is emphasized that phytohormonal engineering opens new opportunities to increase yields and is seen as an important promising approach to overcoming the cereal losses caused by adverse external factors., (© 2021. The Author(s), under exclusive licence to Springer Nature B.V.)

Published

2022

16. Brassinosteroids and the Tolerance of Cereals to Low and High Temperature Stress: Photosynthesis and the Physicochemical Properties of Cell Membranes.

Author

Sadura I and Janeczko A

Subjects

Brassinosteroids chemistry, Brassinosteroids metabolism, Cell Membrane physiology, Chemical Phenomena, Edible Grain physiology, Photosynthesis, Stress, Physiological, Temperature

Abstract

Cereals, which belong to the Poaceae family, are the most economically important group of plants. Among abiotic stresses, temperature stresses are a serious and at the same time unpredictable problem for plant production. Both frost (in the case of winter cereals) and high temperatures in summer (especially combined with a water deficit in the soil) can result in significant yield losses. Plants have developed various adaptive mechanisms that have enabled them to survive periods of extreme temperatures. The processes of acclimation to low and high temperatures are controlled, among others, by phytohormones. The current review is devoted to the role of brassinosteroids (BR) in cereal acclimation to temperature stress with special attention being paid to the impact of BR on photosynthesis and the membrane properties. In cereals, the exogenous application of BR increases frost tolerance (winter rye, winter wheat), tolerance to cold (maize) and tolerance to a high temperature (rice). Disturbances in BR biosynthesis and signaling are accompanied by a decrease in frost tolerance but unexpectedly an improvement of tolerance to high temperature (barley). BR exogenous treatment increases the efficiency of the photosynthetic light reactions under various temperature conditions (winter rye, barley, rice), but interestingly, BR mutants with disturbances in BR biosynthesis are also characterized by an increased efficiency of PSII (barley). BR regulate the sugar metabolism including an increase in the sugar content, which is of key importance for acclimation, especially to low temperatures (winter rye, barley, maize). BR either participate in the temperature-dependent regulation of fatty acid biosynthesis or control the processes that are responsible for the transport or incorporation of the fatty acids into the membranes, which influences membrane fluidity (and subsequently the tolerance to high/low temperatures) (barley). BR may be one of the players, along with gibberellins or ABA, in acquiring tolerance to temperature stress in cereals (particularly important for the acclimation of cereals to low temperature).

Published

2021

17. A Comparative Transcriptomic Meta-Analysis Revealed Conserved Key Genes and Regulatory Networks Involved in Drought Tolerance in Cereal Crops.

Author

Baldoni E, Frugis G, Martinelli F, Benny J, Paffetti D, and Buti M

Subjects

Binding Sites, Brachypodium genetics, Databases, Genetic, Edible Grain physiology, Gene Expression Regulation, Plant, Hordeum genetics, Oryza genetics, Plant Proteins metabolism, Protein Interaction Maps genetics, Sequence Analysis, RNA, Stress, Physiological genetics, Transcription Factors genetics, Transcription Factors metabolism, Zea mays genetics, Droughts, Edible Grain genetics, Gene Regulatory Networks, Plant Proteins genetics

Abstract

Drought affects plant growth and development, causing severe yield losses, especially in cereal crops. The identification of genes involved in drought tolerance is crucial for the development of drought-tolerant crops. The aim of this study was to identify genes that are conserved key players for conferring drought tolerance in cereals. By comparing the transcriptomic changes between tolerant and susceptible genotypes in four Gramineae species, we identified 69 conserved drought tolerant-related (CDT) genes that are potentially involved in the drought tolerance of all of the analysed species. The CDT genes are principally involved in stress response, photosynthesis, chlorophyll biogenesis, secondary metabolism, jasmonic acid signalling, and cellular transport. Twenty CDT genes are not yet characterized and can be novel candidates for drought tolerance. The k-means clustering analysis of expression data highlighted the prominent roles of photosynthesis and leaf senescence-related mechanisms in differentiating the drought response between tolerant and sensitive genotypes. In addition, we identified specific transcription factors that could regulate the expression of photosynthesis and leaf senescence-related genes. Our analysis suggests that the balance between the induction of leaf senescence and maintenance of photosynthesis during drought plays a major role in tolerance. Fine-tuning of CDT gene expression modulation by specific transcription factors can be the key to improving drought tolerance in cereals.

Published

2021

18. The Adaptation and Tolerance of Major Cereals and Legumes to Important Abiotic Stresses.

Author

Rane J, Singh AK, Kumar M, Boraiah KM, Meena KK, Pradhan A, and Prasad PVV

Subjects

Agriculture, Climate Change, Droughts, Extreme Weather, Oryza physiology, Salinity, Temperature, Triticum physiology, Zea mays physiology, Acclimatization physiology, Edible Grain physiology, Fabaceae physiology, Poaceae physiology, Stress, Physiological physiology

Abstract

Abiotic stresses, including drought, extreme temperatures, salinity, and waterlogging, are the major constraints in crop production. These abiotic stresses are likely to be amplified by climate change with varying temporal and spatial dimensions across the globe. The knowledge about the effects of abiotic stressors on major cereal and legume crops is essential for effective management in unfavorable agro-ecologies. These crops are critical components of cropping systems and the daily diets of millions across the globe. Major cereals like rice, wheat, and maize are highly vulnerable to abiotic stresses, while many grain legumes are grown in abiotic stress-prone areas. Despite extensive investigations, abiotic stress tolerance in crop plants is not fully understood. Current insights into the abiotic stress responses of plants have shown the potential to improve crop tolerance to abiotic stresses. Studies aimed at stress tolerance mechanisms have resulted in the elucidation of traits associated with tolerance in plants, in addition to the molecular control of stress-responsive genes. Some of these studies have paved the way for new opportunities to address the molecular basis of stress responses in plants and identify novel traits and associated genes for the genetic improvement of crop plants. The present review examines the responses of crops under abiotic stresses in terms of changes in morphology, physiology, and biochemistry, focusing on major cereals and legume crops. It also explores emerging opportunities to accelerate our efforts to identify desired traits and genes associated with stress tolerance.

Published

2021

19. Evolutionary innovations driving abiotic stress tolerance in C4 grasses and cereals.

Author

Pardo J and VanBuren R

Subjects

Adaptation, Physiological, Biological Evolution, Carbon metabolism, Edible Grain physiology, Poaceae physiology, Stress, Physiological

Abstract

Grasslands dominate the terrestrial landscape, and grasses have evolved complex and elegant strategies to overcome abiotic stresses. The C4 grasses are particularly stress tolerant and thrive in tropical and dry temperate ecosystems. Growing evidence suggests that the presence of C4 photosynthesis alone is insufficient to account for drought resilience in grasses, pointing to other adaptations as contributing to tolerance traits. The majority of grasses from the Chloridoideae subfamily are tolerant to drought, salt, and desiccation, making this subfamily a hub of resilience. Here, we discuss the evolutionary innovations that make C4 grasses so resilient, with a particular emphasis on grasses from the Chloridoideae (chloridoid) and Panicoideae (panicoid) subfamilies. We propose that a baseline level of resilience in chloridoid ancestors allowed them to colonize harsh habitats, and these environments drove selective pressure that enabled the repeated evolution of abiotic stress tolerance traits. Furthermore, we suggest that a lack of evolutionary access to stressful environments is partially responsible for the relatively poor stress resilience of major C4 crops compared to their wild relatives. We propose that chloridoid crops and the subfamily more broadly represent an untapped reservoir for improving resilience to drought and other abiotic stresses in cereals., (© The Author(s) 2021. Published by Oxford University Press on behalf of American Society of Plant Biologists.)

Published

2021

20. Genetic control and phenotypic characterization of panicle architecture and grain yield-related traits in foxtail millet (Setaria italica).

Author

Zhi H, He Q, Tang S, Yang J, Zhang W, Liu H, Jia Y, Jia G, Zhang A, Li Y, Guo E, Gao M, Li S, Li J, Qin N, Zhu C, Ma C, Zhang H, Chen G, Zhang W, Wang H, Qiao Z, Li S, Cheng R, Xing L, Wang S, Liu J, Liu J, and Diao X

Subjects

Chromosome Mapping methods, Edible Grain genetics, Genome, Plant, High-Throughput Nucleotide Sequencing, Plant Proteins genetics, Polymorphism, Single Nucleotide, Setaria Plant genetics, Chromosomes, Plant genetics, Edible Grain physiology, Gene Expression Regulation, Plant, Phenotype, Plant Proteins metabolism, Quantitative Trait Loci, Setaria Plant physiology

Abstract

Key Message: Multi-environment QTL mapping identified 23 stable loci and 34 co-located QTL clusters for panicle architecture and grain yield-related traits, which provide a genetic basis for foxtail millet yield improvement. Panicle architecture and grain weight, both of which are influenced by genetic and environmental factors, have significant effects on grain yield potential. Here, we used a recombinant inbred line (RIL) population of 333 lines of foxtail millet, which were grown in 13 trials with varying environmental conditions, to identify quantitative trait loci (QTL) controlling nine agronomic traits related to panicle architecture and grain yield. We found that panicle weight, grain weight per panicle, panicle length, panicle diameter, and panicle exsertion length varied across different geographical locations. QTL mapping revealed 159 QTL for nine traits. Of the 159 QTL, 34 were identified in 2 to 12 environments, suggesting that the genetic control of panicle architecture in foxtail millet is sensitive to photoperiod and/or other environmental factors. Eighty-eight QTL controlling different traits formed 34 co-located QTL clusters, including the triple QTL cluster qPD9.2/qPL9.5/qPEL9.3, which was detected 23 times in 13 environments. Several candidate genes, including Seita.2G388700, Seita.3G136000, Seita.4G185300, Seita.5G241500, Seita.5G243100, Seita.9G281300, and Seita.9G342700, were identified in the genomic intervals of multi-environmental QTL or co-located QTL clusters. Using available phenotypic and genotype data, we conducted haplotype analysis for Seita.2G002300 and Seita.9G064000,which showed high correlations with panicle weight and panicle exsertion length, respectively. These results not only provided a basis for further fine mapping, functional studies and marker-assisted selection of traits related to panicle architecture in foxtail millet, but also provide information for comparative genomics analyses of cereal crops., (© 2021. The Author(s), under exclusive licence to Springer-Verlag GmbH Germany, part of Springer Nature.)

Published

2021

21. Olympic grains.

Subjects

Edible Grain physiology, Plant Leaves growth & development, Plant Physiological Phenomena, Plant Roots growth & development, Plant Stems growth & development

Published

2021

22. Improving rice eating and cooking quality by coordinated expression of the major starch synthesis-related genes, SSII and Wx, in endosperm.

Author

Huang L, Gu Z, Chen Z, Yu J, Chu R, Tan H, Zhao D, Fan X, Zhang C, Li Q, and Liu Q

Subjects

Cooking, Edible Grain enzymology, Edible Grain physiology, Food Quality, Oryza enzymology, Oryza physiology, Plant Proteins genetics, RNA Interference, Starch genetics, Starch Synthase genetics, Edible Grain genetics, Endosperm genetics, Gene Expression Regulation, Plant, Oryza genetics, Starch biosynthesis

Abstract

Key Message: Coordinated regulation of amylose and amylopectin synthesis via manipulation of SSII-2, SSII-3 and Wx expression in endosperm can improve rice eating and cooking quality. With increasing rice consumption worldwide, many researchers are working to increase the yield and improve grain quality, especially eating and cooking quality (ECQ). The rice ECQ is mainly controlled by the expression of starch synthesis-related genes (SSRGs) in endosperm. Although the Wx and SSII-3/SSIIa/ALK genes, two major SSRGs, have been manipulated to improve rice ECQ via various breeding approaches, new methods to further improve ECQ are desired. In our previous study, we enhanced rice ECQ by knocking down SSII-2 expression in the japonica Nipponbare cultivar (carrying the Wx b allele) via RNA interference. Herein, the SSII-2 RNAi was introduced into two Nipponbare-derived near-isogenic lines (NILs), Nip(Wx a ) and Nip(wx), carrying Wx a and wx alleles respond for high and no amylose levels, respectively. Analysis of physicochemical properties revealed that the improved grain quality of SSII-2 RNAi transgenic lines was achieved by coordinated downregulating the expression of SSII-2, SSII-3 and Wx. To further confirm this conclusion, we generated ssii-2, ssii-3 and ssii-2ssii-3 mutants via CRISPR/Cas9 technique. The amylopectin structure of the resulting ssii-2sii-3 mutants was similar to that in SSII-2 RNAi transgenic lines, and the absence of SSII-2 decreased the amylose content, gelatinisation temperature and rapid visco-analyser profile, indicating essential roles for SSII-2 in the regulation of amylopectin biosynthesis and amylose content in rice endosperm. The effect of SSII-2 was seen only when the activity of SSII-3 was very low or lacking. Our study provides novel approaches and valuable germplasm resources for improving ECQ via plant breeding., (© 2021. The Author(s), under exclusive licence to Springer Nature B.V.)

Published

2021

23. Meta-analysis of genome-wide association studies reveal common loci controlling agronomic and quality traits in a wide range of normal and heat stressed environments.

Author

Joukhadar R, Thistlethwaite R, Trethowan R, Keeble-Gagnère G, Hayden MJ, Ullah S, and Daetwyler HD

Subjects

Australia, Edible Grain genetics, Edible Grain physiology, Gene-Environment Interaction, Genetic Association Studies, Genotype, Phenotype, Polymorphism, Single Nucleotide, Triticum physiology, Heat-Shock Response, Quantitative Trait Loci, Triticum genetics

Abstract

Key Message: Several stable QTL were detected using metaGWAS analysis for different agronomic and quality traits under 26 normal and heat stressed environments. Heat stress, exacerbated by global warming, has a negative influence on wheat production worldwide and climate resilient cultivars can help mitigate these impacts. Selection decisions should therefore depend on multi-environment experiments representing a range of temperatures at critical stages of development. Here, we applied a meta-genome wide association analysis (metaGWAS) approach to detect stable QTL with significant effects across multiple environments. The metaGWAS was applied to 11 traits scored in 26 trials that were sown at optimal or late times of sowing (TOS1 and TOS2, respectively) at five locations. A total of 2571 unique wheat genotypes (13,959 genotypes across all environments) were included and the analysis conducted on TOS1, TOS2 and both times of sowing combined (TOS1&2). The germplasm was genotyped using a 90 k Infinium chip and imputed to exome sequence level, resulting in 341,195 single nucleotide polymorphisms (SNPs). The average accuracy across all imputed SNPs was high (92.4%). The three metaGWAS analyses revealed 107 QTL for the 11 traits, of which 16 were detected in all three analyses and 23 were detected in TOS1&2 only. The remaining QTL were detected in either TOS1 or TOS2 with or without TOS1&2, reflecting the complex interactions between the environments and the detected QTL. Eight QTL were associated with grain yield and seven with multiple traits. The identified QTL provide an important resource for gene enrichment and fine mapping to further understand the mechanisms of gene × environment interaction under both heat stressed and unstressed conditions.

Published

2021

24. Physiological and molecular attributes contribute to high night temperature tolerance in cereals.

Author

Schaarschmidt S, Lawas LMF, Kopka J, Jagadish SVK, and Zuther E

Subjects

Hot Temperature, Oryza physiology, Photosynthesis, Plant Growth Regulators metabolism, Seeds growth & development, Starch genetics, Starch metabolism, Edible Grain physiology, Gene Expression Regulation, Plant, Thermotolerance physiology

Abstract

Asymmetric warming resulting in a faster increase in night compared to day temperatures affects crop yields negatively. Physiological characterization and agronomic findings have been complemented more recently by molecular biology approaches including transcriptomic, proteomic, metabolomic and lipidomic investigations in crops exposed to high night temperature (HNT) conditions. Nevertheless, the understanding of the underlying mechanisms causing yield decline under HNT is still limited. The discovery of significant differences between HNT-tolerant and HNT-sensitive cultivars is one of the main research directions to secure continuous food supply under the challenge of increasing climate change. With this review, we provide a summary of current knowledge on the physiological and molecular basis of contrasting HNT tolerance in rice and wheat cultivars. Requirements for HNT tolerance and the special adaptation strategies of the HNT-tolerant rice cultivar Nagina-22 (N22) are discussed. Putative metabolite markers for HNT tolerance useful for marker-assisted breeding are suggested, together with future research directions aimed at improving food security under HNT conditions., (© 2021 The Authors. Plant, Cell & Environment published by John Wiley & Sons Ltd.)

Published

2021

25. High night temperature effects on wheat and rice: Current status and way forward.

Author

Impa SM, Raju B, Hein NT, Sandhu J, Prasad PVV, Walia H, and Jagadish SVK

Subjects

Agriculture methods, Edible Grain physiology, Hot Temperature, Oryza chemistry, Phenotype, Plant Proteins chemistry, Plant Proteins metabolism, Starch chemistry, Triticum chemistry, Oryza physiology, Seeds chemistry, Seeds growth & development, Triticum physiology

Abstract

Rapid increases in minimum night temperature than in maximum day temperature is predicted to continue, posing significant challenges to crop productivity. Rice and wheat are two major staples that are sensitive to high night-temperature (HNT) stress. This review aims to (i) systematically compare the grain yield responses of rice and wheat exposed to HNT stress across scales, and (ii) understand the physiological and biochemical responses that affect grain yield and quality. To achieve this, we combined a synthesis of current literature on HNT effects on rice and wheat with information from a series of independent experiments we conducted across scales, using a common set of genetic materials to avoid confounding our findings with differences in genetic background. In addition, we explored HNT-induced alterations in physiological mechanisms including carbon balance, source-sink metabolite changes and reactive oxygen species. Impacts of HNT on grain developmental dynamics focused on grain-filling duration, post-flowering senescence, changes in grain starch and protein composition, starch metabolism enzymes and chalk formation in rice grains are summarized. Finally, we highlight the need for high-throughput field-based phenotyping facilities for improved assessment of large-diversity panels and mapping populations to aid breeding for increased resilience to HNT in crops., (© 2021 John Wiley & Sons Ltd.)

Published

2021

26. Modification of cereal plant architecture by genome editing to improve yields.

Author

Huang X, Hilscher J, Stoger E, Christou P, and Zhu C

Subjects

Edible Grain genetics, Edible Grain growth & development, Plant Breeding methods, Plant Leaves anatomy & histology, Plant Leaves genetics, Plant Roots anatomy & histology, Plant Roots genetics, Seeds genetics, Seeds growth & development, Edible Grain anatomy & histology, Edible Grain physiology, Gene Editing methods, Plant Proteins genetics

Abstract

Key Message: We summarize recent genome editing studies that have focused on the examination (or reexamination) of plant architectural phenotypes in cereals and the modification of these traits for crop improvement. Plant architecture is defined as the three-dimensional organization of the entire plant. Shoot architecture refers to the structure and organization of the aboveground components of a plant, reflecting the developmental patterning of stems, branches, leaves and inflorescences/flowers. Root system architecture is essentially determined by four major shape parameters-growth, branching, surface area and angle. Interest in plant architecture has arisen from the profound impact of many architectural traits on agronomic performance, and the genetic and hormonal regulation of these traits which makes them sensitive to both selective breeding and agronomic practices. This is particularly important in staple crops, and a large body of literature has, therefore, accumulated on the control of architectural phenotypes in cereals, particularly rice due to its twin role as one of the world's most important food crops as well as a model organism in plant biology and biotechnology. These studies have revealed many of the molecular mechanisms involved in the regulation of tiller/axillary branching, stem height, leaf and flower development, root architecture and the grain characteristics that ultimately help to determine yield. The advent of genome editing has made it possible, for the first time, to introduce precise mutations into cereal crops to optimize their architecture and close in on the concept of the ideotype. In this review, we consider recent genome editing studies that have focused on the examination (or reexamination) of plant architectural phenotypes in cereals and the modification of these traits for crop improvement.

Published

2021

27. The tonoplast-localized transporter OsABCC9 is involved in cadmium tolerance and accumulation in rice.

Author

Yang G, Fu S, Huang J, Li L, Long Y, Wei Q, Wang Z, Chen Z, and Xia J

Subjects

Edible Grain metabolism, Edible Grain physiology, Gene Expression Regulation, Plant, Plant Shoots genetics, Biological Transport genetics, Biological Transport physiology, Cadmium metabolism, Membrane Transport Proteins metabolism, Oryza genetics, Oryza physiology, Plant Roots metabolism, Plant Shoots metabolism

Abstract

Cadmium (Cd) is a highly toxic element to living organisms, and its accumulation in the edible portions of crops poses a potential threat for human health. The molecular mechanisms underlying Cd detoxification and accumulation are not fully understood in plants. In this study, the involvement of a C-type ABC transporter, OsABCC9, in Cd tolerance and accumulation in rice was investigated. The expression of OsABCC9 was rapidly induced by Cd treatment in a concentration-dependent manner in the root. The transporter, localized on the tonoplast, was mainly expressed in the root stele under Cd stress. OsABCC9 knockout mutants were more sensitive to Cd and accumulated more Cd in both the root and shoot compared to the wild-type. Moreover, the Cd concentrations in the xylem sap and grain were also significantly increased in the knockout lines, suggesting that more Cd was distributed from root to shoot and grain in the mutants. Heterologous expression of OsABCC9 in yeast enhanced Cd tolerance along with an increase of intracellular Cd content. Taken together, these results indicated that OsABCC9 mediates Cd tolerance and accumulation through sequestration of Cd into the root vacuoles in rice., (Copyright © 2021 Elsevier B.V. All rights reserved.)

Published

2021

28. Breeding with dominant genic male-sterility genes to boost crop grain yield in the post-heterosis utilization era.

Author

Wan X, Wu S, and Li X

Subjects

Hybrid Vigor physiology, Edible Grain physiology, Plant Breeding methods, Plant Infertility physiology

Abstract

Global food security is facing severe challenges from an ever-growing population, limited resources, and various stresses. Dominant genic male sterility (DGMS) technology combined with modern breeding strategies may create novel cultivation models with ~50% DGMS F 1 hybrids for field production of cross-pollinated crops, boosting crop grain yield to ensure global food security and sustainable agriculture in the post-heterosis utilization era., (Copyright © 2021 The Author. Published by Elsevier Inc. All rights reserved.)

Published

2021

29. Heterologous expression of fungal AcGDH alleviates ammonium toxicity and suppresses photorespiration, thereby improving drought tolerance in rice.

Author

Yan L, Gong Y, Luo Q, Dai GX, Teng Z, He Y, Wu X, Liu C, Tang D, Ye N, Deng G, Lin J, and Liu X

Subjects

Adaptation, Physiological genetics, Adaptation, Physiological physiology, Cell Respiration genetics, Droughts, Edible Grain genetics, Gene Expression Regulation, Plant, Genes, Plant, Plant Growth Regulators metabolism, Stress, Physiological genetics, Stress, Physiological physiology, Ammonium Compounds toxicity, Cell Respiration physiology, Dehydration, Edible Grain physiology, Fungal Proteins metabolism, Oryza genetics, Oryza physiology

Abstract

Drought stress can significantly affect plant growth and agricultural productivity. Thus, it is essential to explore and identify the optimal genes for the improvement of crop drought tolerance. Here, a fungal NADP(H)-dependent glutamate dehydrogenase gene (AcGDH) was isolated from Aspergillus candidus, and heterologously expressed in rice. AcGDH has a high affinity for NH 4 + and increases the ammonium assimilation in rice. AcGDH transgenic plants exhibited a tolerance to drought and alkali stresses, and their photorespiration was significantly suppressed. Our findings demonstrate that AcGDH alleviates ammonium toxicity and suppresses photorespiration by assimilating excess NH 4 + and disturbing the delicate balance of carbon and nitrogen metabolism, thereby improving drought tolerance in rice. Moreover, AcGDH not only improved drought tolerance at the seedling stage but also increased the grain yield under drought stress. Thus, AcGDH is a promising candidate gene for maintaining rice grain yield, and offers an opportunity for improving crop yield under drought stress., (Copyright © 2020 Elsevier B.V. All rights reserved.)

Published

2021

30. Sustainability of agricultural and wild cereals to aerotechnogenic exposure.

Author

Chaplygin V, Mandzhieva S, Minkina T, Sushkova S, Kizilkaya R, Gülser C, Zamulina I, Kravtsova N, Lobzenko I, and Chernikova N

Subjects

Agriculture, Biodegradation, Environmental, Crops, Agricultural metabolism, Crops, Agricultural physiology, Edible Grain drug effects, Edible Grain metabolism, Edible Grain physiology, Metals, Heavy analysis, Poaceae drug effects, Poaceae metabolism, Russia, Soil Pollutants analysis, Species Specificity, Triticum drug effects, Triticum metabolism, Crops, Agricultural drug effects, Metals, Heavy toxicity, Poaceae physiology, Soil Pollutants toxicity

Abstract

In recent decades, the problem of the constantly increasin level of anthropogenic load on the environment is becoming more and more acute. Some of the most dangerous pollutants entering the environment from industrial emissions are heavy metals. These pollutants are not susceptible to biodegradation over time, which leads to their accumulation in the environment in dangerous concentrations. The purpose of this work is to study the sustainability of cultivated and wild plants of the Poaceae family to aerotechnogenic pollution in the soil. The content of heavy metals in couch grass (Elytrigia repens (L.) Nevski), meadow bluegrass (Poa pratensis L.) and soft wheat (Triticum aestivum) plants grown in the impact zone of Novocherkassk Power Station has been analyzed. Contamination of cultivated and wild cereals with Pb, Zn, Ni and Cd has been established. It has been shown that the accumulation of heavy metals is individual for each plant species. An average and close correlation have been established between the total HM content and the content of their mobile forms in the soil and their content in plants. For the plants studied, the translocation factor (TF) and the distribution coefficient (DC) of HM have been calculated. The TF is formed by the ratio of the concentration of an element in the root plant dry weight to the content of its mobile compounds in the soil. The DC value makes it possible to estimate the capacity of the aboveground parts of plants to absorb and accumulate elements under soil pollution conditions and is determined as the ratio of the metal content in the aboveground biomass to its concentration in the roots. TF and DC values have shown a significant accumulation of elements by plants from the soil, as well as their translocation from the root system to the aboveground part. It has been revealed that even within the same Poaceae family, cultural species are more sensitive to man-made pollution than wild-growing ones.

Published

2021

31. Grain filling in barley relies on developmentally controlled programmed cell death.

Author

Radchuk V, Tran V, Hilo A, Muszynska A, Gündel A, Wagner S, Fuchs J, Hensel G, Ortleb S, Munz E, Rolletschek H, and Borisjuk L

Subjects

Edible Grain enzymology, Edible Grain physiology, Hordeum enzymology, Hordeum growth & development, Apoptosis, Cysteine Endopeptidases metabolism, Edible Grain growth & development, Endosperm metabolism, Gene Expression Regulation, Developmental, Gene Expression Regulation, Plant, Hordeum physiology

Abstract

Cereal grains contribute substantially to the human diet. The maternal plant provides the carbohydrate and nitrogen sources deposited in the endosperm, but the basis for their spatial allocation during the grain filling process is obscure. Here, vacuolar processing enzymes have been shown to both mediate programmed cell death (PCD) in the maternal tissues of a barley grain and influence the delivery of assimilate to the endosperm. The proposed centrality of PCD has implications for cereal crop improvement.

Published

2021

32. Citric acid inhibits Cd uptake by improving the preferential transport of Mn and triggering the defense response of amino acids in grains.

Author

Xue W, Wang P, Tang L, Zhang C, Wang C, Huang Y, Zhang X, Li Y, Zhao B, and Liu Z

Subjects

Biological Transport, Environmental Pollution, Metals, Heavy analysis, Oryza metabolism, Plant Leaves metabolism, Plant Roots metabolism, Soil chemistry, Soil Pollutants analysis, Amino Acids metabolism, Cadmium metabolism, Citric Acid pharmacology, Edible Grain physiology, Manganese metabolism, Protective Agents pharmacology

Abstract

Citric acid (CA) can regulate the balance of anions and cations in plants, and improve their resistance to heavy metals. It is not clear if foliar application with CA has any effect on migration of Cd and Mn in rice plant. In this work, a low-Cd-accumulating indica rice line (P7) and a high-Cd-accumulating line (HZ) were used to investigate the influence of CA on the transport of Cd and Mn as well as amino acid metabolism in grains. Content of Cd in grains and other organs increased with the increase of Cd content (0.1-2.4 mg kg -1 ) in soil, while decreased with the foliar application with CA. With the increase of Cd content in rice grains, the content of most amino acids in HZ, P7, HZ+CA and P7 + CA showed an obvious decline trend. Foliar application with CA efficiently raised the Mn:Cd ratio in grains and nodes of both HZ and P7. Meanwhile, the expression levels of OsNramp2, 3 and 5 in panicles were efficiently enhanced by CA application when plants grew in soil with Cd content of 0.6-2.4 mg kg -1 . The increasing effect of CA on the content of 4 amino acids (i.e., Glu, Phe, Thr and Ala) in grains was related to varieties and Cd pollution. These results indicate that foliar application with CA can regulate the transport of Cd and Mn in the opposite directions in tissues and inhibit Cd accumulation in grains by enhancing expression of OsNRAMP 2, 3 or 5 and triggering the defense response of some amino acids in Cd-contaminated environment., (Copyright © 2021 The Authors. Published by Elsevier Inc. All rights reserved.)

Published

2021

33. Endosperm cell size reduction caused by osmotic adjustment during nighttime warming in rice.

Author

Wada H, Chang FY, Hatakeyama Y, Erra-Balsells R, Araki T, Nakano H, and Nonami H

Subjects

Cell Size, Cell Wall metabolism, Cell Wall physiology, Edible Grain metabolism, Edible Grain physiology, Endosperm metabolism, Hot Temperature, Metabolomics methods, Oryza metabolism, Plant Shoots metabolism, Plant Shoots physiology, Seeds metabolism, Seeds physiology, Starch metabolism, Water metabolism, Endosperm physiology, Oryza physiology, Osmosis physiology

Abstract

High night temperature (HNT) often reduces yield in field crops. In rice, HNT during the ripening stage diminishes endosperm cell size, resulting in a considerable reduction in final kernel weight; however, little is known about the underlying mechanisms at cell level. In this study, we performed picolitre pressure-probe-electrospray-ionization mass spectrometry to directly determine metabolites in growing inner endosperm cells of intact seeds produced under HNT conditions, combining with 13 C feeding and water status measurements including in situ turgor assay. Microscopic observation in the inner zone suggested that approximately 24.2% of decrease in cell expansion rate occurred under HNT at early ripening stage, leading to a reduction in cell volume. It has been shown that HNT-treated plants were subjected to mild shoot water deficit at night and endosperm cell turgor was sustained by a decline in osmotic potential. Cell metabolomics also suggests that active solute accumulation was caused by a partial inhibition of wall and starch biosynthesis under HNT conditions. Because metabolites were detected in the single cells, it is concluded that a partial arrest of cell expansion observed in the inner endosperms was caused by osmotic adjustment at mild water deficit during HNT conditions.

Published

2021

34. Albino Plant Formation in Androgenic Cultures: An Old Problem and New Facts.

Author

Żur I, Gajecka M, Dubas E, Krzewska M, and Szarejko I

Subjects

Chlorophyll deficiency, Chlorophyll genetics, Diploidy, Edible Grain genetics, Haploidy, Homozygote, Models, Biological, Molecular Biology methods, Pigments, Biological deficiency, Pigments, Biological genetics, Pollen genetics, Pollen growth & development, Pollen physiology, Regeneration genetics, Regeneration physiology, Edible Grain growth & development, Edible Grain physiology, Pigmentation genetics, Plant Breeding methods

Abstract

High frequency of albino plant formation in isolated microspore or anther cultures is a great problem limiting the possibility of their exploitation on a wider scale. It is highly inconvenient as androgenesis-based doubled haploid (DH) technology provides the simplest and shortest way to total homozygosity, highly valued by plant geneticists, biotechnologists and especially, plant breeders, and this phenomenon constitutes a serious limitation of these otherwise powerful tools. The genotype-dependent tendency toward albino plant formation is typical for many monocotyledonous plants, including cereals like wheat, barley, rice, triticale, oat and rye - the most important from the economical point of view. Despite many efforts, the precise mechanism underlying chlorophyll deficiency has not yet been elucidated. In this chapter, we review the data concerning molecular and physiological control over proper/disturbed chloroplast biogenesis, old hypotheses explaining the mechanism of chlorophyll deficiency, and recent studies which shed new light on this phenomenon., (© 2021. The Author(s), under exclusive license to Springer Science+Business Media, LLC, part of Springer Nature.)

Published

2021

35. Cloning of wheat keto-acyl thiolase 2B reveals a role of jasmonic acid in grain weight determination.

Author

Chen Y, Yan Y, Wu TT, Zhang GL, Yin H, Chen W, Wang S, Chang F, and Gou JY

Subjects

Abscisic Acid metabolism, Acetyl-CoA C-Acyltransferase genetics, Acetyl-CoA C-Acyltransferase isolation & purification, Chlorophyll metabolism, Cloning, Molecular, Codon, Nonsense, Plant Leaves metabolism, Plant Proteins genetics, Plant Proteins isolation & purification, Plants, Genetically Modified, Quantitative Trait Loci, Recombinant Proteins genetics, Recombinant Proteins isolation & purification, Recombinant Proteins metabolism, Acetyl-CoA C-Acyltransferase metabolism, Cyclopentanes metabolism, Edible Grain physiology, Oxylipins metabolism, Plant Proteins metabolism, Triticum physiology

Abstract

Grain weight (GW) is one of the component traits of wheat yield. Existing reports have shown that multiple phytohormones are involved in the regulation of GW in different crops. However, the potential role of jasmonic acid (JA) remains unclear. Here, we report that triticale grain weight 1 (tgw1) mutant, with marked reductions in both GW and JA content, is caused by a premature stop mutation in keto-acyl thiolase 2B (KAT-2B) involved in β-oxidation during JA synthesis. KAT-2B overexpression increases GW in wild type and boosts yield. Additionally, KAT-2B compliments the grain defect in tgw1 and rescues the lethal phenotype of the Arabidopsis kat2 mutant in a sucrose-free medium. Despite the suppression of JA synthesis in tgw1 mutant, ABA synthesis is upregulated, which is accompanied by enhanced expression of SAG3 and reduction of chlorophyll content in leaves. Together, these results demonstrate a role of the JA synthetic gene KAT-2B in controlling GW and its potential application value for wheat improvement.

Published

2020

36. Heterologous expression of heat stress-responsive AtPLC9 confers heat tolerance in transgenic rice.

Author

Liu Y, Liu X, Wang X, Gao K, Qi W, Ren H, Hu H, Sun D, Bai J, and Zheng S

Subjects

Arabidopsis, Edible Grain physiology, Gene Expression Regulation, Plant, Gene Transfer Techniques, Genes, Plant, Oryza physiology, Plant Proteins genetics, Plants, Genetically Modified, Edible Grain genetics, Heat-Shock Response genetics, Heat-Shock Response physiology, Oryza genetics, Stress, Physiological genetics, Thermotolerance genetics, Thermotolerance physiology

Abstract

Background: As global warming becomes increasingly severe, it is urgent that we enhance the heat tolerance of crops. We previously reported that Arabidopsis thaliana PHOSPHOINOSITIDE-SPECIFIC PHOSPHOLIPASE C9 (AtPLC9) promotes heat tolerance., Results: In this study, we ectopically expressed AtPLC9 in rice to examine its potential to improve heat tolerance in this important crop. Whereas AtPLC9 did not improve rice tolerance to salt, drought or cold, transgenic rice did exhibit greater heat tolerance than the wild type. High-throughput RNA-seq revealed extensive and dynamic transcriptome reprofiling in transgenic plants after heat stress. Moreover, the expression of some transcription factors and calcium ion-related genes showed specific upregulation in transgenic rice after heat stress, which might contribute to the enhanced heat tolerance., Conclusions: This study provides preliminary guidance for using AtPLC9 to improve heat tolerance in cereal crops and, more broadly, highlights that heterologous transformation can assist with molecular breeding.

Published

2020

37. Comparative cellular, physiological and transcriptome analyses reveal the potential easy dehulling mechanism of rice-tartary buckwheat (Fagopyrum Tararicum).

Author

Li HY, Wu CX, Lv QY, Shi TX, Chen QJ, and Chen QF

Subjects

Cellulose analysis, Edible Grain chemistry, Edible Grain cytology, Edible Grain physiology, Fagopyrum cytology, Fagopyrum genetics, Fagopyrum physiology, Gene Expression Profiling, Genes, Plant, Polysaccharides analysis, Transcriptome, Edible Grain metabolism, Fagopyrum metabolism, Food Handling

Abstract

Background: Tartary buckwheat has gained popularity in the food marketplace due to its abundant nutrients and high bioactive flavonoid content. However, its difficult dehulling process has severely restricted its food processing industry development. Rice-tartary buckwheat, a rare local variety, is very easily dehulled, but the cellular, physiological and molecular mechanisms responsible for this easy dehulling remains largely unclear., Results: In this study, we integrated analyses of the comparative cellular, physiological, transcriptome, and gene coexpression network to insight into the reason that rice-tartary buckwheat is easy to dehull. Compared to normal tartary buckwheat, rice-tartary buckwheat has significantly brittler and thinner hull, and thinner cell wall in hull sclerenchyma cells. Furthermore, the cellulose, hemicellulose, and lignin contents of rice-tartary buckwheat hull were significantly lower than those in all or part of the tested normal tartary buckwheat cultivars, respectively, and the significant difference in cellulose and hemicellulose contents between rice-tartary buckwheat and normal tartary buckwheat began at 10 days after pollination (DAP). Comparative transcriptome analysis identified a total of 9250 differentially expressed genes (DEGs) between the rice- and normal-tartary buckwheat hulls at four different development stages. Weighted gene coexpression network analysis (WGCNA) of all DEGs identified a key module associated with the formation of the hull difference between rice- and normal-tartary buckwheat. In this specific module, many secondary cell wall (SCW) biosynthesis regulatory and structural genes, which involved in cellulose and hemicellulose biosynthesis, were identified as hub genes and displayed coexpression. These identified hub genes of SCW biosynthesis were significantly lower expression in rice-tartary buckwheat hull than in normal tartary buckwheat at the early hull development stages. Among them, the expression of 17 SCW biosynthesis relative-hub genes were further verified by quantitative real-time polymerase chain reaction (qRT-PCR)., Conclusions: Our results showed that the lower expression of SCW biosynthesis regulatory and structural genes in rice-tartary buckwheat hull in the early development stages contributes to its easy dehulling by reducing the content of cell wall chemical components, which further effects the cell wall thickness of hull sclerenchyma cells, and hull thickness and mechanical strength.

Published

2020

38. Loss of rice PARAQUAT TOLERANCE 3 confers enhanced resistance to abiotic stresses and increases grain yield in field.

Author

Alfatih A, Wu J, Jan SU, Zhang ZS, Xia JQ, and Xiang CB

Subjects

Edible Grain physiology, Gene Knockout Techniques, Oryza physiology, Salt Stress, Seedlings growth & development, Seedlings physiology, Stress, Physiological, Edible Grain growth & development, Oryza growth & development, Plant Proteins physiology

Abstract

Plants frequently suffer from environmental stresses in nature and have evolved sophisticated and efficient mechanisms to cope with the stresses. To balance between growth and stress response, plants are equipped with efficient means to switch off the activated stress responses when stresses diminish. We previously revealed such an off-switch mechanism conferred by Arabidopsis PARAQUAT TOLERANCE 3 (AtPQT3) encoding an E3 ubiquitin ligase, knockout of which significantly enhances resistance to abiotic stresses. To explore whether the rice homologue OsPQT3 is functionally conserved, we generated three knockout mutants with CRISPR-Cas9 technology. The OsPQT3 knockout mutants (ospqt3) display enhanced resistance to oxidative and salt stress with elevated expression of OsGPX1, OsAPX1 and OsSOD1. More importantly, the ospqt3 mutants show significantly enhanced agronomic performance with higher yield compared with the wild type under salt stress in greenhouse as well as in field conditions. We further showed that OsPQT3 expression rapidly decreased in response to oxidative and other abiotic stresses as AtPQT3 does. Taken together, these results show that OsPQT3 is functionally well conserved in rice as an off-switch in stress response as AtPQT3 in Arabidopsis. Therefore, PQT3 locus provides a promising candidate for crop improvement with enhanced stress resistance by gene editing technology., (© 2020 John Wiley & Sons Ltd.)

Published

2020

39. The fingerprints of climate warming on cereal crops phenology and adaptation options.

Author

Fatima Z, Ahmed M, Hussain M, Abbas G, Ul-Allah S, Ahmad S, Ahmed N, Ali MA, Sarwar G, Haque EU, Iqbal P, and Hussain S

Subjects

Crops, Agricultural growth & development, Edible Grain growth & development, Population Growth, Adaptation, Physiological, Climate Change, Crops, Agricultural physiology, Edible Grain physiology, Seasons

Abstract

Growth and development of cereal crops are linked to weather, day length and growing degree-days (GDDs) which make them responsive to the specific environments in specific seasons. Global temperature is rising due to human activities such as burning of fossil fuels and clearance of woodlands for building construction. The rise in temperature disrupts crop growth and development. Disturbance mainly causes a shift in phenological development of crops and affects their economic yield. Scientists and farmers adapt to these phenological shifts, in part, by changing sowing time and cultivar shifts which may increase or decrease crop growth duration. Nonetheless, climate warming is a global phenomenon and cannot be avoided. In this scenario, food security can be ensured by improving cereal production through agronomic management, breeding of climate-adapted genotypes and increasing genetic biodiversity. In this review, climate warming, its impact and consequences are discussed with reference to their influences on phenological shifts. Furthermore, how different cereal crops adapt to climate warming by regulating their phenological development is elaborated. Based on the above mentioned discussion, different management strategies to cope with climate warming are suggested.

Published

2020

40. Green revolution 'stumbles' in a dry environment: Dwarf wheat with Rht genes fails to produce higher grain yield than taller plants under drought.

Author

Jatayev S, Sukhikh I, Vavilova V, Smolenskaya SE, Goncharov NP, Kurishbayev A, Zotova L, Absattarova A, Serikbay D, Hu YG, Borisjuk N, Gupta NK, Jacobs B, de Groot S, Koekemoer F, Alharthi B, Lethola K, Cu DT, Schramm C, Anderson P, Jenkins CLD, Soole KL, Shavrukov Y, and Langridge P

Subjects

Dehydration, Edible Grain physiology, Genes, Plant physiology, Plant Breeding, Quantitative Trait, Heritable, Triticum genetics, Triticum physiology, Edible Grain growth & development, Triticum growth & development

Published

2020

41. The Kernel Size-Related Quantitative Trait Locus qKW9 Encodes a Pentatricopeptide Repeat Protein That Aaffects Photosynthesis and Grain Filling.

Author

Huang J, Lu G, Liu L, Raihan MS, Xu J, Jian L, Zhao L, Tran TM, Zhang Q, Liu J, Li W, Wei C, Braun DM, Li Q, Fernie AR, Jackson D, and Yan J

Subjects

Edible Grain genetics, Edible Grain metabolism, Edible Grain physiology, Photosynthesis genetics, Photosynthesis physiology, Zea mays genetics, Zea mays metabolism, Quantitative Trait Loci genetics, Zea mays physiology

Abstract

In maize ( Zea mays ), kernel weight is an important component of yield that has been selected during domestication. Many genes associated with kernel weight have been identified through mutant analysis. Most are involved in the biogenesis and functional maintenance of organelles or other fundamental cellular activities. However, few quantitative trait loci (QTLs) underlying quantitative variation in kernel weight have been cloned. Here, we characterize a QTL, qKW9 , associated with maize kernel weight. This QTL encodes a DYW motif pentatricopeptide repeat protein involved in C-to-U editing of ndhB , a subunit of the chloroplast NADH dehydrogenase-like complex. In a null qkw9 background, C-to-U editing of ndhB was abolished, and photosynthesis was reduced, resulting in less maternal photosynthate available for grain filling. Characterization of qKW9 highlights the importance of optimizing photosynthesis for maize grain yield production., (© 2020 American Society of Plant Biologists. All Rights Reserved.)

Published

2020

42. Insights into the Genetic Architecture of Bran Friability and Water Retention Capacity, Two Important Traits for Whole Grain End-Use Quality in Winter Wheat.

Author

Navrotskyi S, Belamkar V, Baenziger PS, and Rose DJ

Subjects

Edible Grain anatomy & histology, Edible Grain genetics, Phenotype, Plant Breeding, Triticum anatomy & histology, Triticum genetics, Edible Grain physiology, Plant Proteins genetics, Plant Proteins metabolism, Polymorphism, Single Nucleotide, Quantitative Trait Loci, Triticum physiology, Water metabolism

Abstract

Bran friability (particle size distribution after milling) and water retention capacity (WRC) impact wheat bran functionality in whole grain milling and baking applications. The goal of this study was to identify genomic regions and underlying genes that may be responsible for these traits. The Hard Winter Wheat Association Mapping Panel, which comprised 299 lines from breeding programs in the Great Plains region of the US, was used in a genome-wide association study. Bran friability ranged from 34.5% to 65.9% (median, 51.1%) and WRC ranged from 159% to 458% (median, 331%). Two single-nucleotide polymorphisms (SNPs) on chromosome 5D were significantly associated with bran friability, accounting for 11-12% of the phenotypic variation. One of these SNPs was located within the Puroindoline-b gene, which is known for influencing endosperm texture. Two SNPs on chromosome 4A were tentatively associated with WRC, accounting for 4.6% and 4.4% of phenotypic variation. The favorable alleles at the SNP sites were present in only 15% (friability) and 34% (WRC) of lines, indicating a need to develop new germplasm for these whole-grain end-use quality traits. Validation of these findings in independent populations will be useful for breeding winter wheat cultivars with improved functionality for whole grain food applications.

Published

2020

43. Matrix-Assisted Laser Desorption/Ionization-Mass Spectrometry Imaging of Metabolites during Sorghum Germination.

Author

Montini L, Crocoll C, Gleadow RM, Motawia MS, Janfelt C, and Bjarnholt N

Subjects

Edible Grain genetics, Edible Grain physiology, Gene Expression Regulation, Plant, Germination genetics, Germination physiology, Nitriles metabolism, Seeds genetics, Seeds physiology, Sorghum genetics, Sorghum physiology, Spectrometry, Mass, Matrix-Assisted Laser Desorption-Ionization methods

Abstract

Dhurrin is the most abundant cyanogenic glucoside found in sorghum ( Sorghum bicolor) where it plays a key role in chemical defense by releasing toxic hydrogen cyanide upon tissue disruption. Besides this well-established function, there is strong evidence that dhurrin plays additional roles, e.g. as a transport and storage form of nitrogen, released via endogenous recycling pathways. However, knowledge about how, when and why dhurrin is endogenously metabolized is limited. We combined targeted metabolite profiling with matrix-assisted laser desorption/ionization-mass spectrometry imaging to investigate accumulation of dhurrin, its recycling products and key general metabolites in four different sorghum lines during 72 h of grain imbibition, germination and early seedling development, as well as the spatial distribution of these metabolites in two of the lines. Little or no dhurrin or recycling products were present in the dry grain, but their de novo biosynthesis started immediately after water uptake. Dhurrin accumulation increased rapidly within the first 24 h in parallel with an increase in free amino acids, a key event in seed germination. The trajectories and final concentrations of dhurrin, the recycling products and free amino acids reached within the experimental period were dependent on genotype. Matrix-assisted laser desorption/ionization-mass spectrometry imaging demonstrated that dhurrin primarily accumulated in the germinating embryo, confirming its function in protecting the emerging tissue against herbivory. The dhurrin recycling products, however, were mainly located in the scutellum and/or pericarp/seed coat region, suggesting unknown key functions in germination., (© 2020 American Society of Plant Biologists. All Rights Reserved.)

Published

2020

44. Marker Assisted Gene Pyramiding (MAGP) for bacterial blight and blast resistance into mega rice variety "Tellahamsa".

Author

Jamaloddin M, Durga Rani CV, Swathi G, Anuradha C, Vanisri S, Rajan CPD, Krishnam Raju S, Bhuvaneshwari V, Jagadeeswar R, Laha GS, Prasad MS, Satyanarayana PV, Cheralu C, Rajani G, Ramprasad E, Sravanthi P, Arun Prem Kumar N, Aruna Kumari K, Yamini KN, Mahesh D, Sanjeev Rao D, Sundaram RM, and Madhav MS

Subjects

DNA, Plant metabolism, Edible Grain physiology, Genetic Markers, Genotype, Oryza growth & development, Plant Diseases microbiology, Disease Resistance genetics, Genome, Plant, Oryza genetics, Plant Diseases genetics

Abstract

Bacterial blight (BB) and fungal blast diseases are the major biotic constraints that limit rice productivity. To sustain yield improvement in rice, it is necessary to developed yield potential of the rice varieties by incorporation of biotic stress resistance genes. Tellahamsa is a well-adapted popular high yielding rice variety in Telangana state, India. However, the variety is highly susceptible to BB and blast. In this study, simultaneous stepwise transfer of genes through marker-assisted backcross breeding (MABB) strategy was used to introgress two major BB (Xa21 and xa13) and two major blast resistance genes (Pi54 and Pi1) into Tellahamsa. In each generation (from F1 to ICF3) foreground selection was done using gene-specific markers viz., pTA248 (Xa21), xa13prom (xa13), Pi54MAS (Pi54) and RM224 (Pi1). Two independent BC2F1 lines of Tellahamsa/ISM (Cross-I) and Tellahamsa/NLR145 (Cross-II) possessing 92% and 94% recurrent parent genome (RPG) respectively were intercrossed to develop ICF1-ICF3 generations. These gene pyramided lines were evaluated for key agro-morphological traits, quality, and resistance against blast at three different hotspot locations as well as BB at two locations. Two ICF3 gene pyramided lines viz., TH-625-159 and TH-625-491 possessing four genes exhibited a high level of resistance to BB and blast. In the future, these improved Tellahamsa lines could be developed as mega varieties for different agro-climatic zones and also as potential donors for different pre-breeding rice research., Competing Interests: The authors have declared that no competing interests exist.

Published

2020

45. Effects of high temperature stress during anthesis and grain filling periods on photosynthesis, lipids and grain yield in wheat.

Author

Djanaguiraman M, Narayanan S, Erdayani E, and Prasad PVV

Subjects

Edible Grain metabolism, Edible Grain physiology, Flowers metabolism, Flowers physiology, Heat-Shock Response, Hot Temperature adverse effects, Plant Transpiration, Triticum growth & development, Triticum metabolism, Edible Grain growth & development, Flowers growth & development, Lipid Metabolism physiology, Photosynthesis physiology, Triticum physiology

Abstract

Background: Short episodes of high temperature (HT) stress during reproductive stages of development cause significant yield losses in wheat (Triticum aestivum L.). Two independent experiments were conducted to quantify the effects of HT during anthesis and grain filling periods on photosynthesis, leaf lipidome, and yield traits in wheat. In experiment I, wheat genotype Seri82 was exposed to optimum temperature (OT; 22/14 °C; day/night) or HT (32/22 °C) for 14 d during anthesis stage. In experiment II, the plants were exposed to OT or HT for 14 d during the grain filling stage. During the HT stress, chlorophyll index, thylakoid membrane damage, stomatal conductance, photosynthetic rate and leaf lipid composition were measured. At maturity, grain yield and its components were quantified., Results: HT stress during anthesis or grain filling stage decreased photosynthetic rate (17 and 25%, respectively) and grain yield plant - 1 (29 and 44%, respectively), and increased thylakoid membrane damage (61 and 68%, respectively) compared to their respective control (OT). HT stress during anthesis or grain filling stage increased the molar percentage of less unsaturated lipid species [36:5- monogalactosyldiacylglycerol (MGDG) and digalactosyldiacylglycerol (DGDG)]. However, at grain filling stage, HT stress decreased the molar percentage of more unsaturated lipid species (36:6- MGDG and DGDG). There was a significant positive relationship between photosynthetic rate and grain yield plant - 1 , and a negative relationship between thylakoid membrane damage and photosynthetic rate., Conclusions: The study suggests that maintaining thylakoid membrane stability, and seed-set per cent and individual grain weight under HT stress can improve the photosynthetic rate and grain yield, respectively.

Published

2020

46. Interactions of Mutiple Biological Fields in Stored Grain Ecosystems.

Author

Wu ZD, Zhang Q, Yin J, Wang XM, Zhang ZJ, Wu WF, and Li FJ

Subjects

Ecosystem, Edible Grain microbiology, Spatio-Temporal Analysis, Temperature, Triticum microbiology, Triticum physiology, Aspergillus physiology, Edible Grain physiology, Food Microbiology, Food Storage instrumentation, Food Storage methods

Abstract

Biological entities such as fungi in stored grain evolve and interact with the environment in similar fashions as physical fields. An experiment was conducted to study the behavior of the biological field of fungi in stored grain, as well as the interactions between the biological field of fungi and the physical fields of temperature and moisture. A framework of the biological field is presented to describe biological systems in which multiple biological entities co-exist and interact among themselves and with the surrounding environment. The proposed biological field describes the spatio-temporal distribution of a biological entity and its ability of influencing (or being influenced by) the surrounding biotic and abiotic entities through exchange of energy, matter, and/or information. The strength of a biological field of fungi was quantified as the rate of energy conversion by fungi from grain starch to heat. The experimental data showed that the strength of biological field of fungi in stored grain varied in both space and time, with the maximum field strength of 120-133 W m -3 occurred at the location where the biological field of fungi interacted strongly with the temperature and moisture fields.

Published

2020

47. Genomic-based root plasticity to enhance abiotic stress adaptation and edible yield in grain crops.

Author

Dwivedi SL, Stoddard FL, and Ortiz R

Subjects

Edible Grain physiology, Genomics, Plant Roots genetics, Poaceae genetics, Poaceae growth & development, Stress, Physiological, Adaptation, Physiological, Edible Grain growth & development, Genome, Plant physiology, Plant Roots physiology, Poaceae physiology

Abstract

Phenotypic plasticity refers to changes expressed by a genotype across different environments and is one of the major means by which plants cope with environmental variability. Multi-fold differences in phenotypic plasticity have been noted across crops, with wild ancestors and landraces being more plastic than crops when under stress. Plasticity in response to abiotic stress adaptation, plant architecture, physio-reproductive and quality traits are multi-genic (QTL). Plasticity QTL (pQTL) were either collocated with main effect QTL and QEI (QTL × environment interaction) or located independently from the main effect QTL. For example, variations in root plasticity have been successfully introgressed to enhance abiotic stress adaptation in rice. The independence of genetic control of a trait and of its plasticity suggests that breeders may select for high or low plasticity in combination with high or low performance of economically important traits. Trait plasticity in stressful environments may be harnessed through breeding stress-tolerant crops. There exists a genetic cost associated with plasticity, so a better understanding of the trade-offs between plasticity and productivity is warranted prior to undertaking breeding for plasticity traits together with productivity in stress environments., Competing Interests: Declaration of Competing Interest The authors declare that they have no conflicts of interest., (Copyright © 2019 Elsevier B.V. All rights reserved.)

Published

2020

48. Terminal drought and heat stress alter physiological and biochemical attributes in flag leaf of bread wheat.

Author

Sattar A, Sher A, Ijaz M, Ul-Allah S, Rizwan MS, Hussain M, Jabran K, and Cheema MA

Subjects

Antioxidants metabolism, Bread, Chlorophyll metabolism, Droughts, Edible Grain growth & development, Edible Grain physiology, Heat-Shock Response physiology, Photosynthesis, Plant Leaves growth & development, Plant Leaves physiology, Water metabolism, Triticum growth & development, Triticum physiology

Abstract

Heat stress along with low water availability at reproductive stage (terminal growth phase of wheat crop) is major contributing factor towards less wheat production in tropics and sub-tropics. Flag leaf plays a pivotal role in assimilate partitioning and stress tolerance of wheat during terminal growth phase. However, limited is known about biochemical response of flag leaf to combined and individual heat and drought stress during terminal growth phase. Therefore, current study investigated combined and individual effect of terminal drought and heat stress on water relations, photosynthetic pigments, osmolytes accumulation and antioxidants defense mechanism in flag leaf of bread wheat. Experimental treatments comprised of control, terminal drought stress alone (50% field capacity during reproductive phase), terminal heat stress alone (wheat grown inside plastic tunnel during reproductive phase) and terminal drought stress + terminal heat stress. Individual and combined imposition of drought and heat stresses significantly (p≤0.05) altered water relations, osmolyte contents, soluble proteins and sugars along with activated antioxidant defensive system in terms of superoxide dismutase (SOD), peroxidase (POD) and ascorbate peroxidase (APX). Turgor potential, POD and APX activities were lowest under individual heat stress; however, these were improved when drought stress was combined with heat stress. It is concluded that combined effect of drought and heat stress was more detrimental than individual stresses. The interactive effect of both stresses was hypo-additive in nature, but for some traits (like turgor potential and APX) effect of one stress neutralized the other. To best of our knowledge, this is the first report on physiological and biochemical response of flag leaf of wheat to combine heat and drought stress. These results will help future studies dealing with improved stress tolerance in wheat. However, detailed studies are needed to fully understand the genetic mechanisms behind these physiological and biochemical changes in flag leaf in response to combined heat and drought stress., Competing Interests: The authors have declared that no competing interests exist.

Published

2020

49. Molecular Markers Associated with Agro-Physiological Traits under Terminal Drought Conditions in Bread Wheat.

Author

Shokat S, Sehgal D, Vikram P, Liu F, and Singh S

Subjects

Chromosome Mapping, Edible Grain physiology, Genetic Markers, Genome-Wide Association Study, Inheritance Patterns, Plant Breeding, Quantitative Trait Loci, Adaptation, Biological, Droughts, Quantitative Trait, Heritable, Stress, Physiological, Triticum physiology

Abstract

Terminal drought stress poses a big challenge to sustain wheat grain production in rain-fed environments. This study aimed to utilize the genetically diverse pre-breeding lines for identification of genomic regions associated with agro-physiological traits at terminal stage drought stress in wheat. A total of 339 pre-breeding lines panel derived from three-way crosses of 'exotics × elite × elite' lines were evaluated in field conditions at Obregon, Mexico for two years under well irrigated as well as drought stress environments. Drought stress was imposed at flowering by skipping the irrigations at pre and post anthesis stage. Results revealed that drought significantly reduced grain yield (Y), spike length (SL), number of grains spikes -1 (NGS) and thousand kernel weight (TKW), while kernel abortion (KA) was increased. Population structure analysis in this panel uncovered three sub-populations. Genome wide linkage disequilibrium (LD) decay was observed at 2.5 centimorgan (cM). The haplotypes-based genome wide association study (GWAS) identified significant associations of Y, SL, and TKW on three chromosomes; 4A (HB10.7), 2D (HB6.10) and 3B (HB8.12), respectively. Likewise, associations on chromosomes 6B (HB17.1) and 3A (HB7.11) were found for NGS while on chromosome 3A (HB7.12) for KA. The genomic analysis information generated in the study can be efficiently utilized to improve Y and/or related parameters under terminal stage drought stress through marker-assisted breeding.

Published

2020

50. Genome of extreme halophyte Puccinellia tenuiflora.

Author

Guo R, Zhao L, Zhang K, Gao D, and Yang C

Subjects

Chromosome Mapping, Droughts, Edible Grain physiology, Gene Expression Profiling, Gene Expression Regulation, Plant, Genomics, Plant Proteins genetics, Poaceae physiology, RNA, Untranslated genetics, Salt-Tolerant Plants physiology, Edible Grain genetics, Genome, Plant, Poaceae genetics, Salt Tolerance genetics, Salt-Tolerant Plants genetics

Abstract

Background: Puccinellia tenuiflora, a forage grass, is considered a model halophyte given its strong tolerance for multiple stress conditions and its close genetic relationship with cereals. This halophyte has enormous values for improving our understanding of salinity tolerance mechanisms. The genetic information of P. tenuiflora also is a potential resource that can be used for improving the salinity tolerance of cereals., Results: Here, we sequenced and assembled the P. tenuiflora genome (2n = 14) through the combined strategy of Illumina, PacBio, and 10× genomic technique. We generated 43.2× PacBio long reads, 123.87× 10× genomic reads, and 312.6× Illumina reads. Finally, we assembled 2638 scaffolds with a total size of 1.107 Gb, contig N50 of 117 kb, and scaffold N50 of 950 kb. We predicted 39,725 protein-coding genes, and identified 692 tRNAs, 68 rRNAs, 702 snRNAs, 1376 microRNAs, and 691 Mb transposable elements., Conclusions: We deposited the genome sequence in NCBI and the Genome Warehouse in National Genomics Data Center. Our work may improve current understanding of plant salinity tolerance, and provides extensive genetic resources necessary for improving the salinity and drought tolerance of cereals.

Published

2020