17 results on '"Focus Issue on Architecture and Plasticity"'
Search Results
2. Capturing in-field root system dynamics with RootTracker
- Author
-
Fletcher O’Neil, Jeffrey Aguilar, Sam Farrow, Matt Moore, Logan Johnson, Jesse B. Windle, Philip N. Benfey, Drew Walker, Jake L. Edwards, Jake Thystrup, Eric Rogers, and Rachel F. Greenhut
- Subjects
Technology ,Root (linguistics) ,Irrigation ,AcademicSubjects/SCI01280 ,Physiology ,Plant Science ,Root system ,Environment ,Plant Roots ,Zea mays ,Nutrient ,Stress, Physiological ,Signaling and Response ,Genetics ,Cultivar ,Electrodes ,Hybrid ,Mathematics ,AcademicSubjects/SCI01270 ,AcademicSubjects/SCI02288 ,AcademicSubjects/SCI02287 ,AcademicSubjects/SCI02286 ,Water ,Focus Issue on Architecture and Plasticity ,Agronomy ,Mechanical stability ,Breakthrough Technologies, Tools, and Resources ,Field conditions - Abstract
Optimizing root system architecture offers a promising approach to developing stress tolerant cultivars in the face of climate change, as root systems are critical for water and nutrient uptake as well as mechanical stability. However, breeding for optimal root system architecture has been hindered by the difficulty in measuring root growth in the field. Here, we describe the RootTracker, a technology that employs impedance touch sensors to monitor in-field root growth over time. Configured in a cylindrical, window shutter-like fashion around a planted seed, 264 electrodes are individually charged multiple times over the course of an experiment. Signature changes in the measured capacitance and resistance readings indicate when a root has touched or grown close to an electrode. Using the RootTracker, we have measured root system dynamics of commercial maize (Zea mays) hybrids growing in both typical Midwest field conditions and under different irrigation regimes. We observed rapid responses of root growth to water deficits and found evidence for a “priming response” in which an early water deficit causes more and deeper roots to grow at later time periods. Genotypic variation among hybrid maize lines in their root growth in response to drought indicated a potential to breed for root systems adapted for different environments. Thus, the RootTracker is able to capture changes in root growth over time in response to environmental perturbations., RootTracker, a technology that employs impedance touch sensors, enables monitoring in-field root growth over time.
- Published
- 2021
3. Wild emmer introgression alters root-to-shoot growth dynamics in durum wheat in response to water stress
- Author
-
Tian Gao, Tala Awada, Kan Liu, Assaf Distelfeld, Feiyu Zhu, Hongfeng Yu, Chi Zhang, Harkamal Walia, Harel Bacher, Zvi Peleg, and Balpreet K. Dhatt
- Subjects
0106 biological sciences ,0301 basic medicine ,Physiology ,Range (biology) ,Vegetative reproduction ,Introgression ,Plant Science ,Biology ,Genetic Introgression ,Plant Roots ,01 natural sciences ,Genetic analysis ,03 medical and health sciences ,Stress, Physiological ,Genetics ,Cultivar ,Triticum ,Dehydration ,fungi ,Water stress ,Genetic Variation ,food and beverages ,Focus Issue on Architecture and Plasticity ,Adaptation, Physiological ,Droughts ,Phenotype ,030104 developmental biology ,Agronomy ,Shoot ,Adaptation ,Plant Shoots ,010606 plant biology & botany - Abstract
Water deficit during the early vegetative growth stages of wheat (Triticum) can limit shoot growth and ultimately impact grain productivity. Introducing diversity in wheat cultivars to enhance the range of phenotypic responses to water limitations during vegetative growth can provide potential avenues for mitigating subsequent yield losses. We tested this hypothesis in an elite durum wheat background by introducing a series of introgressions from a wild emmer (Triticum turgidum ssp. dicoccoides) wheat. Wild emmer populations harbor rich phenotypic diversity for drought-adaptive traits. To determine the effect of these introgressions on vegetative growth under water-limited conditions, we used image-based phenotyping to catalog divergent growth responses to water stress ranging from high plasticity to high stability. One of the introgression lines exhibited a significant shift in root-to-shoot ratio in response to water stress. We characterized this shift by combining genetic analysis and root transcriptome profiling to identify candidate genes (including a root-specific kinase) that may be linked to the root-to-shoot carbon reallocation under water stress. Our results highlight the potential of introducing functional diversity into elite durum wheat for enhancing the range of water stress adaptation.
- Published
- 2021
4. The role of auxin and sugar signaling in dominance inhibition of inflorescence growth by fruit load
- Author
-
M. Rabinovich, Harley M. S. Smith, and Marc Goetz
- Subjects
0106 biological sciences ,0301 basic medicine ,Physiology ,Meristem ,Arabidopsis ,Plant Science ,01 natural sciences ,03 medical and health sciences ,Plant Growth Regulators ,Auxin ,Genetics ,Dominance (ecology) ,Arabidopsis thaliana ,Inflorescence ,Sugar ,Vascular tissue ,chemistry.chemical_classification ,Indoleacetic Acids ,biology ,fungi ,food and beverages ,Focus Issue on Architecture and Plasticity ,biology.organism_classification ,Apex (geometry) ,Horticulture ,030104 developmental biology ,chemistry ,Fruit ,Shoot ,Sugars ,Signal Transduction ,010606 plant biology & botany - Abstract
Dominance inhibition of shoot growth by fruit load is a major factor that regulates shoot architecture and limits yield in agriculture and horticulture crops. In annual plants, the inhibition of inflorescence growth by fruit load occurs at a late stage of inflorescence development termed the end of flowering transition. Physiological studies show that this transition is mediated by production and export of auxin from developing fruits in close proximity to the inflorescence apex. In the meristem, cessation of inflorescence growth is controlled in part by the age dependent pathway, which regulates the timing of arrest. Here, results show that the end of flowering transition is a two-step process in which the first stage is characterized by a cessation of inflorescence growth, while immature fruit continue to develop. At this stage, dominance inhibition of inflorescence growth by fruit load correlates with a selective dampening of auxin transport in the apical region of the stem. Subsequently, an increase in auxin response in the vascular tissues of the apical stem where developing fruits are attached marks the second stage for the end of flowering transition. Similar to the vegetative and floral transition, the end of flowering transition correlates with a change in sugar signaling and metabolism in the inflorescence apex. Taken together, our results suggest that during the end of flowering transition, dominance inhibition of inflorescence shoot growth by fruit load is mediated by auxin and sugar signaling.One-sentence summaryDominance inhibition of inflorescence shoot growth by fruit load is involves auxin and sugar signaling during the end of flowering transition.
- Published
- 2021
5. Stress memory gene FaHSP17.8-CII controls thermotolerance via remodeling PSII and ROS signaling in tall fescue
- Author
-
Huawei Xu, Zhengrong Hu, Tao Hu, Maurice Amee, Tao Wang, Ao Liu, Guangyang Wang, Jinmin Fu, Liang Zhang, Liang Chen, Misganaw Wassie, and Aoyue Bi
- Subjects
Chlorophyll ,Festuca ,Thermotolerance ,musculoskeletal diseases ,0106 biological sciences ,Photosystem II ,Physiology ,Mutant ,macromolecular substances ,Plant Science ,Methylation ,01 natural sciences ,Electron Transport ,Histones ,03 medical and health sciences ,Heat acclimation ,Stress, Physiological ,Genetics ,Gene ,Heat-Shock Proteins ,Plant Proteins ,030304 developmental biology ,chemistry.chemical_classification ,0303 health sciences ,Reactive oxygen species ,biology ,Chemistry ,Photosystem II Protein Complex ,food and beverages ,Focus Issue on Architecture and Plasticity ,biology.organism_classification ,Corrigenda ,Cell biology ,Chloroplast ,H3K4me3 ,Reactive Oxygen Species ,Festuca arundinacea ,Heat-Shock Response ,Signal Transduction ,010606 plant biology & botany - Abstract
High temperature is the most limiting factor in the growth of cool-season turfgrass. To cope with high-temperature stress, grass often adopt a memory response by remembering one past recurring stress and preparing a quicker and more robust reaction to the next stress exposure. However, little is known about how stress memory genes regulate the thermomemory response in cool-season turfgrass. Here, we characterized a transcriptional memory gene, Fa-heat shock protein 17.8 Class II (FaHSP17.8-CII) in a cool-season turfgrass species, tall fescue (Festuca arundinacea Schreb.). The thermomemory of FaHSP17.8-CII continued for more than 4 d and was associated with a high H3K4me3 level in tall fescue under heat stress (HS). Furthermore, heat acclimation or priming (ACC)-induced reactive oxygen species (ROS) accumulation and photosystem II (PSII) electron transport were memorable, and this memory response was controlled by FaHSP17.8-CII. In the fahsp17.8-CII mutant generated using CRISPR/Cas9, ACC+HS did not substantially block the ROS accumulation, the degeneration of chloroplast ultra-structure, and the inhibition of PSII activity compared with HS alone. However, overexpression of FaHSP17.8-CII in tall fescue reduced ROS accumulation and chloroplast ultra-structure damage, and improved chlorophyll content and PSII activity under ACC+HS compared with that HS alone. These findings unveil a FaHSP17.8-CII–PSII-ROS module regulating transcriptional memory to enhance thermotolerance in cool-season turfgrass.
- Published
- 2021
6. The molecular and genetic regulation of shoot branching
- Author
-
Zhiwei Luo, Bart J. Janssen, and Kimberley C. Snowden
- Subjects
Physiology ,Growth phase ,Cell Plasticity ,Meristem ,food and beverages ,Plant Science ,Biology ,Focus Issue on Architecture and Plasticity ,Phenotype ,Cell biology ,Branching (linguistics) ,Magnoliopsida ,Plant Growth Regulators ,Gene Expression Regulation, Plant ,Axillary bud ,Shoot ,Genetics ,Gene Regulatory Networks ,Gene ,Plant Shoots - Abstract
The architecture of flowering plants exhibits both phenotypic diversity and plasticity, determined, in part, by the number and activity of axillary meristems and, in part, by the growth characteristics of the branches that develop from the axillary buds. The plasticity of shoot branching results from a combination of various intrinsic and genetic elements, such as number and position of nodes and type of growth phase, as well as environmental signals such as nutrient availability, light characteristics, and temperature (Napoli et al., 1998; Bennett and Leyser, 2006; Janssen et al., 2014; Teichmann and Muhr, 2015; Ueda and Yanagisawa, 2019). Axillary meristem initiation and axillary bud outgrowth are controlled by a complex and interconnected regulatory network. Although many of the genes and hormones that modulate branching patterns have been discovered and characterized through genetic and biochemical studies, there are still many gaps in our understanding of the control mechanisms at play. In this review, we will summarize our current knowledge of the control of axillary meristem initiation and outgrowth into a branch.
- Published
- 2021
7. Phototropin-mediated perception of light direction in leaves regulates blade flattening
- Author
-
Laure Allenbach Petrolati, Martina Legris, Bogna Maria Szarzynska-Erden, Christian Fankhauser, and Martine Trevisan
- Subjects
0106 biological sciences ,Phototropins ,Phototropin ,animal structures ,Light ,AcademicSubjects/SCI01280 ,Physiology ,Mutant ,Arabidopsis ,Plant Science ,Biology ,01 natural sciences ,Hypocotyl ,03 medical and health sciences ,Auxin ,Signaling and Response ,Genetics ,Arabidopsis thaliana ,Research Articles ,Phototropism ,030304 developmental biology ,chemistry.chemical_classification ,0303 health sciences ,AcademicSubjects/SCI01270 ,Indoleacetic Acids ,Phytochrome ,AcademicSubjects/SCI02288 ,AcademicSubjects/SCI02287 ,AcademicSubjects/SCI02286 ,fungi ,food and beverages ,Focus Issue on Architecture and Plasticity ,biology.organism_classification ,Cell biology ,Plant Leaves ,chemistry ,sense organs ,Signal Transduction ,010606 plant biology & botany - Abstract
One conserved feature among angiosperms is the development of flat thin leaves. This developmental pattern optimizes light capture and gas exchange. The blue light (BL) receptors phototropins are required for leaf flattening, with the null phot1phot2 mutant showing curled leaves in Arabidopsis (Arabidopsis thaliana). However, key aspects of their function in leaf development remain unknown. Here, we performed a detailed spatiotemporal characterization of phototropin function in Arabidopsis leaves. We found that phototropins perceive light direction in the blade, and, similar to their role in hypocotyls, they control the spatial pattern of auxin signaling, possibly modulating auxin transport, to ultimately regulate cell expansion. Phototropin signaling components in the leaf partially differ from hypocotyls. Moreover, the light response on the upper and lower sides of the leaf blade suggests a partially distinct requirement of phototropin signaling components on each side. In particular, NON PHOTOTROPIC HYPOCOTYL 3 showed an adaxial-specific function. In addition, we show a prominent role of PHYTOCHROME KINASE SUBSTRATE 3 in leaf flattening. Among auxin transporters, PIN-FORMED 3,4,7 and AUXIN RESISTANT 1 (AUX1)/LIKE AUXIN RESISTANT 1 (LAX1) are required for the response while ABCB19 has a regulatory role. Overall, our results show that directional BL perception by phototropins is a key aspect of leaf development, integrating endogenous and exogenous signals., Phototropins perceive light direction in the leaf and control the auxin signaling pattern to regulate blade flattening.
- Published
- 2021
8. Mechanisms of far-red light-mediated dampening of defense against Botrytis cinerea in tomato leaves
- Author
-
Courbier, Sarah, Snoek, Basten L, Kajala, Kaisa, Li, Linge, van Wees, Saskia C M, Pierik, Ronald, Sub Plant Ecophysiology, Sub Bioinformatics, Sub Plant-Microbe Interactions, Plant Ecophysiology, Theoretical Biology and Bioinformatics, Plant Microbe Interactions, Sub Plant Ecophysiology, Sub Bioinformatics, Sub Plant-Microbe Interactions, Plant Ecophysiology, Theoretical Biology and Bioinformatics, and Plant Microbe Interactions
- Subjects
AcademicSubjects/SCI01280 ,Light ,Physiology ,Cyclopentanes ,Plant Science ,Biology ,Shade avoidance ,Solanum lycopersicum ,Gene expression ,Signaling and Response ,Genetics ,Plant Immunity ,Oxylipins ,Research Articles ,Plant Diseases ,Botrytis cinerea ,AcademicSubjects/SCI01270 ,Phytochrome ,AcademicSubjects/SCI02288 ,Inoculation ,AcademicSubjects/SCI02287 ,AcademicSubjects/SCI02286 ,fungi ,food and beverages ,Far-red ,Focus Issue on Architecture and Plasticity ,biology.organism_classification ,Horticulture ,Shoot ,Botrytis ,Disease Susceptibility ,Solanum - Abstract
Plants detect neighboring competitors through a decrease in the ratio between red and far-red light (R:FR). This decreased R:FR is perceived by phytochrome photoreceptors and triggers shade avoidance responses such as shoot elongation and upward leaf movement (hyponasty). In addition to promoting elongation growth, low R:FR perception enhances plant susceptibility to pathogens: the growth–defense tradeoff. Although increased susceptibility in low R:FR has been studied for over a decade, the associated timing of molecular events is still unknown. Here, we studied the chronology of FR-induced susceptibility events in tomato (Solanum lycopersicum) plants pre-exposed to either white light (WL) or WL supplemented with FR light (WL+FR) prior to inoculation with the necrotrophic fungus Botrytis cinerea (B.c.). We monitored the leaf transcriptional changes over a 30-h time course upon infection and followed up with functional studies to identify mechanisms. We found that FR-induced susceptibility in tomato is linked to a general dampening of B.c.-responsive gene expression, and a delay in both pathogen recognition and jasmonic acid-mediated defense gene expression. In addition, we found that the supplemental FR-induced ethylene emissions affected plant immune responses under the WL+FR condition. This study improves our understanding of the growth–immunity tradeoff, while simultaneously providing leads to improve tomato resistance against pathogens in dense cropping systems., The low red:far-red ratio enhances tomato susceptibility to the necrotrophic fungus Botrytis cinerea via delayed early pathogen detection and dampening of jasmonic acid-mediated defense activation.
- Published
- 2021
9. A digital sensor to measure real-time leaf movements and detect abiotic stress in plants
- Author
-
Sebastien Carpentier, Batist Geldhof, Bram Van de Poel, David Eyland, and Jolien Pattyn
- Subjects
Crops, Agricultural ,AcademicSubjects/SCI01280 ,Physiology ,Movement ,Measure (physics) ,Plant Science ,Zea mays ,Petiole (botany) ,Solanum lycopersicum ,Inertial measurement unit ,Stress, Physiological ,Circadian Clocks ,Genetics ,Signaling and Response ,Sensory cue ,Mathematics ,Digital Technology ,AcademicSubjects/SCI01270 ,Abiotic stress ,AcademicSubjects/SCI02288 ,AcademicSubjects/SCI02287 ,fungi ,AcademicSubjects/SCI02286 ,food and beverages ,Ranging ,Musa ,Lettuce ,Focus Issue on Architecture and Plasticity ,Digital sensors ,Plant Leaves ,Plant species ,Breakthrough Technologies, Tools, and Resources ,Biological system - Abstract
Plant and plant organ movements are the result of a complex integration of endogenous growth and developmental responses, partially controlled by the circadian clock, and external environmental cues. Monitoring of plant motion is typically done by image-based phenotyping techniques with the aid of computer vision algorithms. Here we present a method to measure leaf movements using a digital inertial measurement unit (IMU) sensor. The lightweight sensor is easily attachable to a leaf or plant organ and records angular traits in real-time for two dimensions (pitch and roll) with high resolution (measured sensor oscillations of 0.36 ± 0.53° for pitch and 0.50 ± 0.65° for roll). We were able to record simple movements such as petiole bending, as well as complex lamina motions, in several crops, ranging from tomato to banana. We also assessed growth responses in terms of lettuce rosette expansion and maize seedling stem movements. The IMU sensors are capable of detecting small changes of nutations (i.e. bending movements) in leaves of different ages and in different plant species. In addition, the sensor system can also monitor stress-induced leaf movements. We observed that unfavorable environmental conditions evoke certain leaf movements, such as drastic epinastic responses, as well as subtle fading of the amplitude of nutations. In summary, the presented digital sensor system enables continuous detection of a variety of leaf motions with high precision, and is a low-cost tool in the field of plant phenotyping, with potential applications in early stress detection., An inertial measurement unit is capable of measuring dynamic and complex plant organ movements in real-time, and is suitable for early abiotic stress detection.
- Published
- 2021
10. How plants protect themselves from ultraviolet-B radiation stress
- Author
-
Chen Shi and Hongtao Liu
- Subjects
UVR8 ,food.ingredient ,Physiology ,Ultraviolet Rays ,Acclimatization ,Arabidopsis ,Plant Science ,Models, Biological ,food ,Stress, Physiological ,Genetics ,MYB ,chemistry.chemical_classification ,Reactive oxygen species ,Chemistry ,Abiotic stress ,Arabidopsis Proteins ,fungi ,food and beverages ,Focus Issue on Architecture and Plasticity ,Hypocotyl ,Cell biology ,Flavonoid biosynthesis ,MAP kinase phosphatase ,Photomorphogenesis ,Cotyledon - Abstract
Ultraviolet-B (UV-B) radiation has a wavelength range of 280–315 nm. Plants perceive UV-B as an environmental signal and a potential abiotic stress factor that affects development and acclimation. UV-B regulates photomorphogenesis including hypocotyl elongation inhibition, cotyledon expansion, and flavonoid accumulation, but high intensity UV-B can also harm plants by damaging DNA, triggering accumulation of reactive oxygen species, and impairing photosynthesis. Plants have evolved “sunscreen” flavonoids that accumulate under UV-B stress to prevent or limit damage. The UV-B receptor UV RESISTANCE LOCUS 8 (UVR8) plays a critical role in promoting flavonoid biosynthesis to enhance UV-B stress tolerance. Recent studies have clarified several UVR8-mediated and UVR8-independent pathways that regulate UV-B stress tolerance. Here, we review these additions to our understanding of the molecular pathways involved in UV-B stress tolerance, highlighting the important roles of ELONGATED HYPOCOTYL 5, BRI1-EMS-SUPPRESSOR1, MYB DOMAIN PROTEIN 13, MAP KINASE PHOSPHATASE 1, and ATM- and RAD3-RELATED. We also summarize the known interactions with visible light receptors and the contribution of melatonin to UV-B stress responses. Finally, we update a working model of the UV-B stress tolerance pathway.
- Published
- 2021
11. Lateral root formation and nutrients: nitrogen in the spotlight
- Author
-
Pierre-Mathieu Pélissier, Hans Motte, and Tom Beeckman
- Subjects
EXPRESSION ,Physiology ,Nitrogen ,Acclimatization ,chemistry.chemical_element ,Plant Development ,Root system ,Plant Science ,Biology ,Plant Roots ,SYSTEM ARCHITECTURE ,INITIATION ,Nutrient ,Plant science ,Genetics ,ARABIDOPSIS ROOTS ,Lateral root formation ,Plant Physiological Phenomena ,Lateral root ,Biology and Life Sciences ,Nutrients ,Plants ,Focus Issue on Architecture and Plasticity ,Nutrient starvation ,TRANSCRIPTION FACTORS ,chemistry ,Agronomy ,PHOSPHATE STARVATION ,AFFINITY NITRATE TRANSPORTER ,GROWTH ,AUXIN TRANSPORT ,RESPONSES ,Signal Transduction - Abstract
Lateral roots are important to forage for nutrients due to their ability to increase the uptake area of a root system. Hence, it comes as no surprise that lateral root formation is affected by nutrients or nutrient starvation, and as such contributes to the root system plasticity. Understanding the molecular mechanisms regulating root adaptation dynamics toward nutrient availability is useful to optimize plant nutrient use efficiency. There is at present a profound, though still evolving, knowledge on lateral root pathways. Here, we aimed to review the intersection with nutrient signaling pathways to give an update on the regulation of lateral root development by nutrients, with a particular focus on nitrogen. Remarkably, it is for most nutrients not clear how lateral root formation is controlled. Only for nitrogen, one of the most dominant nutrients in the control of lateral root formation, the crosstalk with multiple key signals determining lateral root development is clearly shown. In this update, we first present a general overview of the current knowledge of how nutrients affect lateral root formation, followed by a deeper discussion on how nitrogen signaling pathways act on different lateral root-mediating mechanisms for which multiple recent studies yield insights.
- Published
- 2021
12. Low light intensity delays vegetative phase change
- Author
-
Mingli Xu, R. Scott Poethig, and Tieqiang Hu
- Subjects
0106 biological sciences ,0301 basic medicine ,Light ,AcademicSubjects/SCI01280 ,Physiology ,Arabidopsis ,Plant Science ,01 natural sciences ,Rosette (botany) ,Vegetative phase change ,03 medical and health sciences ,Shade avoidance ,Gene Expression Regulation, Plant ,Gene expression ,Genetics ,Arabidopsis thaliana ,Research Articles ,AcademicSubjects/SCI01270 ,biology ,Arabidopsis Proteins ,AcademicSubjects/SCI02288 ,AcademicSubjects/SCI02287 ,AcademicSubjects/SCI02286 ,Genes, Development and Evolution ,biology.organism_classification ,Focus Issue on Architecture and Plasticity ,Phenotype ,Cell biology ,Light intensity ,MicroRNAs ,030104 developmental biology ,010606 plant biology & botany - Abstract
Plants that develop under low light (LL) intensity often display a phenotype known as the “shade tolerance syndrome (STS)”. This syndrome is similar to the phenotype of plants in the juvenile phase of shoot development, but the basis for this similarity is unknown. We tested the hypothesis that the STS is regulated by the same mechanism that regulates the juvenile vegetative phase by examining the effect of LL on rosette development in Arabidopsis (Arabidopsis thaliana). We found that LL prolonged the juvenile vegetative phase and that this was associated with an increase in the expression of the master regulators of vegetative phase change, miR156 and miR157, and a decrease in the expression of their SQUAMOSA PROMOTER-BINDING PROTEIN-LIKE (SPL) targets. Exogenous sucrose partially corrected the effect of LL on seedling development and miR156 expression. Our results suggest that the response of Arabidopsis to LL is mediated by an increase in miR156/miR157 expression and by factors that repress SPL gene expression independently of miR156/miR157, and is caused in part by a decrease in carbohydrate production. The effect of LL on vegetative phase change does not require the photoreceptors and transcription factors responsible for the shade avoidance syndrome, implying that light intensity and light quality regulate rosette development through different pathways., Arabidopsis plants grown under low light intensity display the shade tolerance syndrome due to transcriptional and post-transcriptional repression of miR156-regulated SPL genes.
- Published
- 2021
13. Meristem transitions and plant architecture—learning from domestication for crop breeding
- Author
-
Natalia Gaarslev, Gwen Swinnen, and Sebastian Soyk
- Subjects
Crops, Agricultural ,AcademicSubjects/SCI01280 ,Physiology ,Meristem ,Plant Science ,Biology ,Models, Biological ,Update ,Crop ,Domestication ,Plant science ,Solanum lycopersicum ,Genetics ,Gene Regulatory Networks ,Architecture ,AcademicSubjects/SCI01270 ,Agroforestry ,AcademicSubjects/SCI02288 ,AcademicSubjects/SCI02287 ,fungi ,AcademicSubjects/SCI02286 ,food and beverages ,Genes, Development and Evolution ,Focus Issue on Architecture and Plasticity ,Plant Breeding - Abstract
Genetic networks that regulate meristem transitions were recurrent targets of selection during crop domestication and allow fine-tuning of plant architecture for improved crop productivity.
- Published
- 2021
- Full Text
- View/download PDF
14. Root plasticity under abiotic stress
- Author
-
Damian Boer, Scott Hayes, Rumyana Karlova, and Christa Testerink
- Subjects
Crops, Agricultural ,Hot Temperature ,AcademicSubjects/SCI01280 ,Physiology ,Cell Plasticity ,Plant Science ,Root hair ,Biology ,Plasticity ,Plant Roots ,Update ,Aerenchyma formation ,Soil ,Plant Growth Regulators ,Suberin ,Stress, Physiological ,Botany ,Genetics ,Life Science ,Laboratorium voor Plantenfysiologie ,Abiotic component ,AcademicSubjects/SCI01270 ,Abiotic stress ,AcademicSubjects/SCI02288 ,AcademicSubjects/SCI02287 ,Lateral root ,AcademicSubjects/SCI02286 ,fungi ,food and beverages ,Agriculture ,Genes, Development and Evolution ,Focus Issue on Architecture and Plasticity ,Adaptation, Physiological ,Floods ,Droughts ,Cold Temperature ,Casparian strip ,EPS ,Laboratory of Plant Physiology - Abstract
Abiotic stresses increasingly threaten existing ecological and agricultural systems across the globe. Plant roots perceive these stresses in the soil and adapt their architecture accordingly. This review provides insights into recent discoveries showing the importance of root system architecture (RSA) and plasticity for the survival and development of plants under heat, cold, drought, salt, and flooding stress. In addition, we review the molecular regulation and hormonal pathways involved in controlling RSA plasticity, main root growth, branching and lateral root growth, root hair development, and formation of adventitious roots. Several stresses affect root anatomy by causing aerenchyma formation, lignin and suberin deposition, and Casparian strip modulation. Roots can also actively grow toward favorable soil conditions and avoid environments detrimental to their development. Recent advances in understanding the cellular mechanisms behind these different root tropisms are discussed. Understanding root plasticity will be instrumental for the development of crops that are resilient in the face of abiotic stress., Recent discoveries show the importance of root system architecture plasticity for the survival and growth of plants under several abiotic stresses.
- Published
- 2021
15. Woodland strawberry axillary bud fate is dictated by a crosstalk of environmental and endogenous factors
- Author
-
Julie Caruana, Samia Samad, Elli A. Koskela, Amparo Monfort, Jiahui Liang, Timo Hytönen, Javier Andrés, Zhongchi Liu, Producció Vegetal, Genòmica i Biotecnologia, Plant Production Sciences, Strawberry research group, Department of Agricultural Sciences, Viikki Plant Science Centre (ViPS), University of Helsinki, China Scholarship Council, Fondazione Edmund Mach, Ministerio de Economía y Competitividad (España), Ministerio de Ciencia, Innovación y Universidades (España), Agencia Estatal de Investigación (España), European Commission, Academy of Finland, and Ella and Georg Ehrnrooth Foundation
- Subjects
0106 biological sciences ,Physiology ,Vegetative reproduction ,SHOOT ARCHITECTURE ,Apical dominance ,Plant Science ,01 natural sciences ,Architecture and Plasticity ,SIGNALS ,TEMPERATURE ,Research Articles ,Plant Proteins ,2. Zero hunger ,0303 health sciences ,AcademicSubjects/SCI01270 ,AcademicSubjects/SCI02288 ,Stolon ,AcademicSubjects/SCI02287 ,AcademicSubjects/SCI02286 ,food and beverages ,Genes, Development and Evolution ,Fragaria ,Inflorescence ,PHOTOPERIOD ,GROWTH ,DELLA PROTEIN ,STRIGOLACTONE ,GENES ,AcademicSubjects/SCI01280 ,Meristem ,Biology ,Environment ,03 medical and health sciences ,Woodland Strawberry ,SUPPRESSOR ,Axillary bud ,Botany ,Genetics ,030304 developmental biology ,Errata ,Development and Evolution ,fungi ,biology.organism_classification ,11831 Plant biology ,Focus Issue on Architecture and Plasticity ,HOMOLOG ,Genes ,Gene-Environment Interaction ,010606 plant biology & botany - Abstract
Plant architecture is defined by fates and positions of meristematic tissues and has direct consequences on yield potential and environmental adaptation of the plant. In strawberries (Fragaria vesca L. and F. × ananassa Duch.), shoot apical meristems can remain vegetative or differentiate into a terminal inflorescence meristem. Strawberry axillary buds (AXBs) are located in leaf axils and can either remain dormant or follow one of the two possible developmental fates. AXBs can either develop into stolons needed for clonal reproduction or into branch crowns (BCs) that can bear their own terminal inflorescences under favorable conditions. Although AXB fate has direct consequences on yield potential and vegetative propagation of strawberries, the regulation of AXB fate has so far remained obscure. We subjected a number of woodland strawberry (F. vesca L.) natural accessions and transgenic genotypes to different environmental conditions and growth regulator treatments to demonstrate that strawberry AXB fate is regulated either by environmental or endogenous factors, depending on the AXB position on the plant. We confirm that the F. vesca GIBBERELLIN20-oxidase4 (FvGA20ox4) gene is indispensable for stolon development and under tight environmental regulation. Moreover, our data show that apical dominance inhibits the outgrowth of the youngest AXB as BCs, although the effect of apical dominance can be overrun by the activity of FvGA20ox4. Finally, we demonstrate that the FvGA20ox4 is photoperiodically regulated via FvSOC1 (F. vesca SUPPRESSOR OF OVEREXPRESSION OF CONSTANS1) at 18°C, but at higher temperature of 22°C an unidentified FvSOC1-independent pathway promotes stolon development., J.A. was funded by Doctoral Programme of Plant Sciences (University of Helsinki, Finland). J.L. was supported by a grant from China Scholarship council (201906350014). The work carried out by J.C. and Z.L. was supported by an USDA-NIFA grant (11889048) and USDA_Maryland MAES Hatch Project (MD-CBMG-19008; to Z.L.). S.S. received a personal grant from the Fondazione Edmund Mach, Italy (GMPF Ph.D. Fellowship) and belonged to the Doctoral Program of Plant Sciences (University of Helsinki, Finland). A.M. acknowledges financial support from the Spanish Ministry of Science and Innovation-State Research Agency (AEI), through the “Severo Ochoa Programme for Centres of Excellence in R&D” SEV‐2015‐0533 and CEX2019-000902-S. The work was funded by the Academy of Finland (Grant 317306 to T.H.). E.A.K. was funded by a personal grant from Ella och Georg Ehrnrooth foundation (Finland).
- Published
- 2021
16. LAZY1-LIKE-mediated gravity signaling pathway in root gravitropic set-point angle control
- Author
-
Masahiko Furutani and Miyo Terao Morita
- Subjects
Gravity (chemistry) ,Physiology ,Chemistry ,Arabidopsis Proteins ,Root (chord) ,Arabidopsis ,Membrane Proteins ,Nuclear Proteins ,Plant Science ,Focus Issue on Architecture and Plasticity ,Plant Roots ,Set point ,Gravitropism ,Genetics ,Biophysics ,Signal transduction ,Gravitation ,Signal Transduction - Abstract
Gravity signaling components contribute to the control of root gravitropic set-point angle through protein polarization relay within columella.
- Published
- 2020
17. The SvFUL2 transcription factor is required for inflorescence determinacy and timely flowering in Setaria viridis
- Author
-
Adriana Chepote, Max Braud, Edoardo Bertolini, Jesus Preciado, Hui Jiang, Jiani Yang, and Andrea L. Eveland
- Subjects
0106 biological sciences ,0301 basic medicine ,Time Factors ,AcademicSubjects/SCI01280 ,Physiology ,Meristem ,Setaria Plant ,Gene regulatory network ,Plant Science ,Flowers ,Biology ,01 natural sciences ,03 medical and health sciences ,Botany ,Genetics ,Gene Regulatory Networks ,Inflorescence ,Gene ,Research Articles ,Panicle ,Plant Proteins ,Meristem determinacy ,AcademicSubjects/SCI01270 ,Setaria viridis ,AcademicSubjects/SCI02288 ,AcademicSubjects/SCI02287 ,fungi ,AcademicSubjects/SCI02286 ,food and beverages ,Genes, Development and Evolution ,biology.organism_classification ,Focus Issue on Architecture and Plasticity ,030104 developmental biology ,Mutation ,Habit (biology) ,010606 plant biology & botany ,Transcription Factors - Abstract
Inflorescence architecture in cereal crops directly impacts yield potential through regulation of seed number and harvesting ability. Extensive architectural diversity found in inflorescences of grass species is due to spatial and temporal activity and determinacy of meristems, which control the number and arrangement of branches and flowers, and underlie plasticity. Timing of the floral transition is also intimately associated with inflorescence development and architecture, yet little is known about the intersecting pathways and how they are rewired during development. Here, we show that a single mutation in a gene encoding an AP1/FUL-like MADS-box transcription factor significantly delays flowering time and disrupts multiple levels of meristem determinacy in panicles of the C4 model panicoid grass, Setaria viridis. Previous reports of AP1/FUL-like genes in cereals have revealed extensive functional redundancy, and in panicoid grasses, no associated inflorescence phenotypes have been described. In S. viridis, perturbation of SvFul2, both through chemical mutagenesis and gene editing, converted a normally determinate inflorescence habit to an indeterminate one, and also repressed determinacy in axillary branch and floral meristems. Our analysis of gene networks connected to disruption of SvFul2 identified regulatory hubs at the intersection of floral transition and inflorescence determinacy, providing insights into the optimization of cereal crop architecture., SvFUL2, an AP1/FUL-like MADS-box transcription factor, integrates flowering time and inflorescence determinacy pathways in the weedy model grass Setaria viridis and reveals functional diversification.
- Published
- 2020
Catalog
Discovery Service for Jio Institute Digital Library
For full access to our library's resources, please sign in.