Your search keyword '"HYDROTROPISM"' showing total 276 results

1. Formulation and evaluation of salicylic acid hydrogel based on hydrotropic solubility enhancement technique

Author

Sara Assif Younis and Nozad Rashid Hussein

Subjects

salicylic acid, hydrotropism, sodium citrate, sodium acetate, gel, Medicine

Abstract

Background and objective: Salicylic acid (SA) has keratolytic activities and it is used topically to treat dandruff and seborrheic dermatitis. The hydrotropic phenomenon in pharmaceutical preparations is utilized to enhance the solubility of water-insoluble drug molecules that promoted to prepare the salicylic acid as a hair gel for local effect and it can extend its keratolytic action for a longer period compared to the salicylic acid solution. Methods: Preformulation study was performed to exclude any unwanted chemical interaction between SA and excipients using Fourier-transform infrared spectroscopy (FTIR). The solubility of SA was determined separately in sodium acetate and sodium citrate solutions at a concentration of 1, 3, and 5 %w/v, using distilled water as a solvent. An optimum gel formulation was developed and it was used to prepare the SA gel formulation. Characterizations were performed in terms of physical appearance, viscosity, pH, and spreadability, in-vitro studies were performed in physiological pH, and ex-vivo diffusion studies were performed utilizing rats’ skin. Results: FTIR did not show any chemical interaction between the drug and sodium citrate. The hydrotropic solution of sodium citrate with a concentration of 5% w/v increased the solubility of SA by 28 folds, while the sodium acetate solutions with a concentration of 5% w/v increased the solubility of SA by 19 folds. The optimum gel formula (F1) with a drug content of 97% showed a slow dissolution rate and minimum diffusion through the skin. Conclusion: The hydrotropic solubilization technique significantly influenced the solubilization of salicylic acid in the water and the highest solubility rate was achieved from 5% w/v sodium citrate solution. The formulated hydrogels using carbopol 971P as gelling agent decreased the diffusion rate of SA.

Published

2024

2. The link between hydrotropism and phototropism in Arabidopsis roots.

Author

Yadav, Arpita

Subjects

*PHOTOTROPISM, *VIRAL tropism, *ARABIDOPSIS, *GUANINE nucleotide exchange factors, *ROOT growth, *ARABIDOPSIS thaliana

Abstract

Keywords: Auxin; gravitropism; hydrotropism; phototropism; roots EN Auxin gravitropism hydrotropism phototropism roots 4892 4895 4 09/15/23 20230913 NES 230913 When exposed to one-sided blue light, the roots of plants such as I Arabidopsis thaliana i exhibit negative phototropism and curve away from the light. Transgenic I GNOMpro:GNOM-GFP i roots showed perfect phototropism, identical to wild-type roots, but transgenic I SMBpro:GNOM-GFP i and I SCRpro:GNOM-GFP i roots showed reduced phototropism. Overall, the study shows that MIZ1 acts in the cortex of the Arabidopsis root elongation zone not only in hydrotropism but also in phototropism (Fig. [12] found out that the same tissues in Arabidopsis roots involved in MIZ1- and GNOM/MIZ2-regulated hydrotropism are also required for phototropism. [Extracted from the article]

Published

2023

3. MIZU-KUSSEI1 (MIZ1) and GNOM/MIZ2 control not only positive hydrotropism but also phototropism in Arabidopsis roots.

Author

Pang, Lei, Kobayashi, Akie, Atsumi, Yuka, Miyazawa, Yutaka, Fujii, Nobuharu, Dietrich, Daniela, Bennett, Malcolm J, and Takahashi, Hideyuki

Subjects

*PHOTOTROPISM, *ARABIDOPSIS, *FLUORESCENT proteins, *WATER supply, *BLUE light, *ROOT growth, *ARABIDOPSIS thaliana

Abstract

In response to unilateral blue light illumination, roots of some plant species such as Arabidopsis thaliana exhibit negative phototropism (bending away from light), which is important for light avoidance in nature. MIZU-KUSSEI1 (MIZ1) and GNOM/MIZ2 are essential for positive hydrotropism (i.e. in the presence of a moisture gradient, root bending towards greater water availability). Intriguingly, mutations in these genes also cause a substantial reduction in phototropism. Here, we examined whether the same tissue-specific sites of expression required for MIZ1- and GNOM/MIZ2-regulated hydrotropism in Arabidopsis roots are also required for phototropism. The attenuated phototropic response of miz1 roots was completely restored when a functional MIZ1–green fluorescent protein (GFP) fusion was expressed in the cortex of the root elongation zone but not in other tissues such as root cap, meristem, epidermis, or endodermis. The hydrotropic defect and reduced phototropism of miz2 roots were restored by GNOM/MIZ2 expression in either the epidermis, cortex, or stele, but not in the root cap or endodermis. Thus, the sites in root tissues that are involved in the regulation of MIZ1- and GNOM/MIZ2-dependent hydrotropism also regulate phototropism. These results suggest that MIZ1- and GNOM/MIZ2-mediated pathways are, at least in part, shared by hydrotropic and phototropic responses in Arabidopsis roots. [ABSTRACT FROM AUTHOR]

Published

2023

4. Hydrotropism: Understanding the Impact of Water on Plant Movement and Adaptation.

Author

Gul, Malik Urfa, Paul, Anand, S, Manimurugan, and Chehri, Abdellah

Subjects

PLANT-water relationships, PLANT adaptation, AQUATIC plants, ABSORPTION of water in plants, WATER consumption, SOIL texture, LEAF physiology

Abstract

Hydrotropism is the movement or growth of a plant towards water. It is a type of tropism, or directional growth response, that is triggered by water. Plants are able to detect water through various stimuli, including changes in moisture levels and changes in water potential. The purpose of this study is to provide an overview of how root movement towards water and plant water uptake are stabilized. The impact of hydrotropism on plants can be significant. It can help plants to survive in environments where water is scarce, and it can also help them to grow more efficiently by directing their roots towards the most nutrient-rich soil. To make sure that plant growth and water uptake are stabilized, plants must sense water. Flowing down the roots, being absorbed by roots, and evaporating from the leaves are all processes that are governed by plant physiology and soil science. Soil texture and moisture affect water uptake. Hydraulic resistances can impede plants' water absorption, while loss of water and water movement can change plants' water potential gradients. Growth causes water potential gradients. Plants respond to gradient changes. Stomata and aquaporins govern water flow and loss. When water is scarce, stomatal closure and hydraulic conductance adjustments prevent water loss. Plants adapt to water stream changes by expanding their roots towards water and refining the architecture of their roots. Our study indicates that water availability, or gradients, are impacted by systemic and local changes in water availability. The amount of water available is reflected in plant turgor. There is still a lot of work to be done regarding the study of how the loss and availability of water affect plant cells, as well as how biophysical signals are transformed in a certain way during their transmission into chemical signals so that pathways such as abscisic acid response or organ development can be fed with information. [ABSTRACT FROM AUTHOR]

Published

2023

5. Evidence for root adaptation to a spatially discontinuous water availability in the absence of external water potential gradients.

Author

Lind, Kara R., Siemianowski, Oskar, Yuan, Bin, Sizmur, Tom, VanEvery, Hannah, Banerjee, Souvik, and Cademartiri, Ludovico

Subjects

*WATER supply, *WATER vapor, *PLANT roots, *CONCENTRATION gradient, *WATER

Abstract

We hereby show that root systems adapt to a spatially discontinuous pattern of water availability even when the gradients of water potential across them are vanishingly small. A paper microfluidic approach allowed us to expose the entire root system of Brassica rapa plants to a square array of water sources, separated by dry areas. Gradients in the concentration of water vapor across the root system were as small as 10-4·mM·m-1 (~4 orders of magnitude smaller than in conventional hydrotropism assays). Despite such minuscule gradients (which greatly limit the possible influence of the well-understood gradient-driven hydrotropic response), our results show that 1) individual roots as well as the root system as a whole adapt to the pattern of water availability to maximize access to water, and that 2) this adaptation increases as water sources become more rare. These results suggest that either plant roots are more sensitive to water gradients than humanmade water sensors by 3-5 orders of magnitude, or they might have developed, like other organisms, mechanisms forwater foraging that allow them to findwater in the absence of an external gradient in water potential. [ABSTRACT FROM AUTHOR]

Published

2021

6. Comparative analysis reveals gravity is involved in the MIZ1-regulated root hydrotropism.

Author

Li, Ying, Yuan, Wei, Li, Luocheng, Dai, Hui, Dang, Xiaolin, Miao, Rui, Baluška, František, Kronzucker, Herbert J, Lu, Congming, Zhang, Jianhua, and Xu, Weifeng

Subjects

*COMPARATIVE studies, *GRAVITY, *GEOTROPISM, *ROOT growth, *SOIL moisture

Abstract

Hydrotropism is the directed growth of roots toward the water found in the soil. However, mechanisms governing interactions between hydrotropism and gravitropism remain largely unclear. In this study, we found that an air system and an agar–sorbitol system induced only oblique water-potential gradients; an agar–glycerol system induced only vertical water-potential gradients; and a sand system established both oblique and vertical water-potential gradients. We employed obliquely oriented and vertically oriented experimental systems to study hydrotropism in Arabidopsis and tomato plants. Comparative analyses using different hydrotropic systems showed that gravity hindered the ability of roots to search for obliquely oriented water, whilst facilitating roots' search for vertically oriented water. We found that the gravitropism-deficient mutant aux1 showed enhanced hydrotropism in the oblique orientation but impaired root elongation towards water in the vertical orientation. The miz1 mutant exhibited deficient hydrotropism in the oblique orientation but normal root elongation towards water in the vertical orientation. Importantly, in contrast to miz1 , the miz1 / aux1 double mutant exhibited hydrotropic bending in the oblique orientation and attenuated root elongation towards water in the vertical orientation. Our results suggest that gravitropism is required for MIZ1-regulated root hydrotropism in both the oblique orientation and the vertical orientation, providing further insight into the role of gravity in root hydrotropism. [ABSTRACT FROM AUTHOR]

Published

2020

7. Hydrotropism in the primary roots of maize.

Author

Wang, Yafang, Afeworki, Yohannes, Geng, Sisi, Kanchupati, Praveena, Gu, Muyu, Martins, Chidi, Rude, Brady, Tefera, Haileselassie, Kim, Yongjun, Ge, Xijin, Auger, Donald, Chen, Sixue, Yang, Peizhi, Hu, Tianming, and Wu, Yajun

Subjects

*CORN, *AUXIN, *ARABIDOPSIS

Abstract

Summary: Recent studies mainly in Arabidopsis have renewed interest and discussion in some of the key issues in hydrotropism of roots, such as the site of water sensing and the involvement of auxin. We examined hydrotropism in maize (Zea mays) primary roots.We determined the site of water sensing along the root using a nonintrusive method. Kinematic analysis was conducted to investigate spatial root elongation during hydrotropic response. Indole‐3‐acetic acid (IAA) and other hormones were quantified using LC–MS/MS. The transcriptome was analyzed using RNA sequencing.Main results: The very tip of the root is the most sensitive to the hydrostimulant. Hydrotropic bending involves coordinated adjustment of spatial cell elongation and cell flux. IAA redistribution occurred in maize roots, preceding hydrotropic bending. The redistribution is caused by a reduction of IAA content on the side facing a hydrostimulant, resulting in a higher IAA content on the dry side. Transcriptomic analysis of the elongation zone prior to bending identified IAA response and lignin synthesis/wall cross‐linking as some of the key processes occurring during the early stages of hydrotropic response.We conclude that maize roots differ from Arabidopsis in the location of hydrostimulant sensing and the involvement of IAA redistribution. [ABSTRACT FROM AUTHOR]

Published

2020

8. Chemotropic vs Hydrotropic Stimuli for Root Growth Orientation in Microgravity

Author

Luigi Gennaro Izzo, Leone Ermes Romano, Stefania De Pascale, Giacomo Mele, Laura Gargiulo, and Giovanna Aronne

Subjects

chemotropism, Daucus carota, hydrotropism, microgravity, root tropisms, X-ray microtomography, Plant culture, SB1-1110

Abstract

Understanding how plants respond to spaceflight and extraterrestrial environments is crucial to develop life-support systems intended for long-term human explorations. Gravity is a main factor influencing root development and orientation, typically masking other tropisms. Considering that reduced levels of gravity affect many plant responses in space, the interaction of other tropic stimuli in microgravity represents the frontier to be investigated aiming at life-support systems optimization. In this paper we report on MULTITROP (Multiple-Tropism: interaction of gravity, nutrient and water stimuli for root orientation in microgravity), an experiment performed on the International Space Station during the Expedition 52/53. Scientific aim of the experiment was to disentangle hydrotropism from chemotropism for root orientation in absence of the gravity stimulus. Among several species relevant to space farming, Daucus carota was selected for the experiment because of its suitability with the experimental hardware and setup. At launch site, carrot seeds were placed between two disks of inert substrate (one imbibed with water and the other with a disodium phosphate solution) and integrated into a hardware developed, refurbished and flight-certificated by Kayser Italia. Post-flight, a Ground Reference Experiment was performed. Root development and orientation of seedlings grown in microgravity and at 1g condition were measured through 3D-image analysis procedures after imaging with X-ray microtomography. Radicle protruded preferentially from the ventral side of the seed due to the asymmetric position of the embryo. Such a phenomenon did not prevent the achievement of MULTITROP scientific goal but should be considered for further experiments on radicle growth orientation in microgravity. The experiment conducted in space verified that the primary root of carrot shows a positive chemotropism towards disodium phosphate solution in the absence of the gravity stimulus. On Earth, the positive chemotropism was masked by the dominant effect of gravity and roots developed downward regardless of the presence/absence of nutrients in the substrate. Taking advantage of altered gravity conditions and using other chemical compounds, further studies should be performed to deepen our understanding of root chemotropic response and its interaction with other tropisms.

Published

2019

9. Primary Root and Mesocotyl Elongation in Maize Seedlings: Two Organs with Antagonistic Growth below the Soil Surface

Author

Mery Nair Sáenz Rodríguez and Gladys Iliana Cassab

Subjects

primary root, hydrotropism, drought, mesocotyl elongation, deep planting, early vigor, Botany, QK1-989

Abstract

Maize illustrates one of the most complex cases of embryogenesis in higher plants that results in the development of early embryo with distinctive organs such as the mesocotyl, seminal and primary roots, coleoptile, and plumule. After seed germination, the elongation of root and mesocotyl follows opposite directions in response to specific tropisms (positive and negative gravitropism and hydrotropism). Tropisms represent the differential growth of an organ directed toward several stimuli. Although the life cycle of roots and mesocotyl takes place in darkness, their growth and functions are controlled by different mechanisms. Roots ramify through the soil following the direction of the gravity vector, spreading their tips into new territories looking for water; when water availability is low, the root hydrotropic response is triggered toward the zone with higher moisture. Nonetheless, there is a high range of hydrotropic curvatures (angles) in maize. The processes that control root hydrotropism and mesocotyl elongation remain unclear; however, they are influenced by genetic and environmental cues to guide their growth for optimizing early seedling vigor. Roots and mesocotyls are crucial for the establishment, growth, and development of the plant since both help to forage water in the soil. Mesocotyl elongation is associated with an ancient agriculture practice known as deep planting. This tradition takes advantage of residual soil humidity and continues to be used in semiarid regions of Mexico and USA. Due to the genetic diversity of maize, some lines have developed long mesocotyls capable of deep planting while others are unable to do it. Hence, the genetic and phenetic interaction of maize lines with a robust hydrotropic response and higher mesocotyl elongation in response to water scarcity in time of global heating might be used for developing more resilient maize plants.

Published

2021

10. Chemotropic vs Hydrotropic Stimuli for Root Growth Orientation in Microgravity.

Author

Izzo, Luigi Gennaro, Romano, Leone Ermes, De Pascale, Stefania, Mele, Giacomo, Gargiulo, Laura, and Aronne, Giovanna

Subjects

REDUCED gravity environments, X-ray computed microtomography, SPACE environment, ROOT development, CARROTS, CHEMOTAXIS, ROOT growth

Abstract

Understanding how plants respond to spaceflight and extraterrestrial environments is crucial to develop life-support systems intended for long-term human explorations. Gravity is a main factor influencing root development and orientation, typically masking other tropisms. Considering that reduced levels of gravity affect many plant responses in space, the interaction of other tropic stimuli in microgravity represents the frontier to be investigated aiming at life-support systems optimization. In this paper we report on MULTITROP (Multiple-Tropism: interaction of gravity, nutrient and water stimuli for root orientation in microgravity), an experiment performed on the International Space Station during the Expedition 52/53. Scientific aim of the experiment was to disentangle hydrotropism from chemotropism for root orientation in absence of the gravity stimulus. Among several species relevant to space farming, Daucus carota was selected for the experiment because of its suitability with the experimental hardware and setup. At launch site, carrot seeds were placed between two disks of inert substrate (one imbibed with water and the other with a disodium phosphate solution) and integrated into a hardware developed, refurbished and flight-certificated by Kayser Italia. Post-flight, a Ground Reference Experiment was performed. Root development and orientation of seedlings grown in microgravity and at 1g condition were measured through 3D-image analysis procedures after imaging with X-ray microtomography. Radicle protruded preferentially from the ventral side of the seed due to the asymmetric position of the embryo. Such a phenomenon did not prevent the achievement of MULTITROP scientific goal but should be considered for further experiments on radicle growth orientation in microgravity. The experiment conducted in space verified that the primary root of carrot shows a positive chemotropism towards disodium phosphate solution in the absence of the gravity stimulus. On Earth, the positive chemotropism was masked by the dominant effect of gravity and roots developed downward regardless of the presence/absence of nutrients in the substrate. Taking advantage of altered gravity conditions and using other chemical compounds, further studies should be performed to deepen our understanding of root chemotropic response and its interaction with other tropisms. [ABSTRACT FROM AUTHOR]

Published

2019

11. Plasma Membrane-Associated Ca 2+ -Binding Protein PCaP1 is Involved in Root Hydrotropism of Arabidopsis thaliana.

Author

Tanaka-Takada, Natsuki, Kobayashi, Akie, Takahashi, Hideyuki, Kamiya, Takehiro, Kinoshita, Toshinori, and Maeshima, Masayoshi

Published

2019

12. Synergism in the solvation of solvatochromic probes in binary mixtures with ionic liquids.

Author

Poblete, Teresa, Millán, Daniela, and Rezende, Marcos Caroli

Subjects

*LIQUID mixtures, *BINARY mixtures, *IONIC liquids, *SOLVATION, *PROTOGENIC solvents, *STAINS & staining (Microscopy), *EXCITED states

Abstract

[Display omitted] • The preferential solvation of two perichromic probes was studied in binary mixtures with an ionic liquid (IL). • Frequently observed synergism occurred in mixtures where the two components had similar probe polarities. • A parallel was drawn between the observed synergism and the phenomenon of hydrotropism, both caused by ILs. • More generally, ILs are characterized as solvatotropes in solutions of perichromic dyes in binary mixtures. • Solvatotropic ILs form aggregates with the dye and the solvent, leading to synergism and a "hyperpolar" medium. The preferential solvation of two perichromic dyes, 4-amino- N -methylphthalimide (4-AMP) and Nile Red (NR) in binary mixtures of an ionic liquid ([bmim][X], where X = BF 4 , PF 6 , Tf 2 N and DCA) with a protic or non-protic solvent, was investigated, in search of examples of a synergetic or "hyperpolar" behavior. Synergism was generally observed in those mixtures where the two pure components had similar polarity values, according to the employed probe. A parallel was drawn between the observed synergism in these IL mixtures and the phenomenon of hydrotropism, also observed with organic solutes in aqueous IL mixtures. More generally, in binary mixtures with organic solvents, ionic liquids can act as solvatotropes, promoting the dye solvation by formation of solute-specific aggregates with all species present in the mixture. By stabilizing the dipolar excited state of 4-AMP or NR through hydrogen-bonds and electrostatic interactions in these aggregates, a "hyperpolar" milieu is generated, which surpasses the polarities of the two pure components. Solvatotropism seems to offer a more realistic picture than the solvent-exchange model, originally developed for simpler systems, to the phenomenon of preferential solvation in binary mixtures with ionic liquids. [ABSTRACT FROM AUTHOR]

Published

2023

13. Assay system for mesocotyl elongation and hydrotropism of maize primary root in response to low moisture gradient

Author

Mery Nair Sáenz-Rodríguez and Gladys Iliana Cassab López

Subjects

Water, Hydrotropism, Biology, Plant Roots, Tropism, Zea mays, General Biochemistry, Genetics and Molecular Biology, Horticulture, Seedlings, Elongation, Moisture gradient, Biotechnology, Hybrid

Abstract

We designed and validated a test system that simulates a growth environment for Zea mays L. maize seedlings under conditions of low moisture gradient in darkness. This system allowed us to simultaneously measure mesocotyl elongation and the primary root hydrotropic response in seedlings before the emergence phase in a collection of maize hybrids. We found great variation in these two traits with statistically significant reduction of their elongations under the low moisture gradient condition that indicate the richness of maize genetic diversity. Hence, the objective of designing a new test system that evaluates the association between these underground traits with the potential use to measure other traits in maize seedlings related to early vigor was achieved.

Published

2021

14. MIZ1 regulates ECA1 to generate a slow, long-distance phloem-transmitted Ca2+ signal essential for root water tracking in Arabidopsis.

Author

Shkolnik, Doron, Nuriel, Roye, Bonza, Maria Cristina, Costa, Alex, and Fromm, Hillel

Subjects

*ARABIDOPSIS, *PLANT root physiology, *PLANT roots, *MOISTURE content of plant roots, *ENDOPLASMIC reticulum, *PLANTS

Abstract

Ever since Darwin postulated that the tip of the root is sensitive to moisture differences and that it "transmits an influence to the upper adjoining part, which bends towards the source of moisture" [Darwin C, Darwin F (1880) The Power of Movement in Plants, pp 572-574], the signal underlying this tropic response has remained elusive. Using the FRET-based Cameleon Ca2+ sensor in planta, we show that a water potential gradient applied across the root tip generates a slow, long-distance asymmetric cytosolic Ca2+ signal in the phloem, which peaks at the elongation zone, where it is dispersed laterally and asymmetrically to peripheral cells, where cell elongation occurs. In addition, the MIZ1 protein, whose biochemical function is unknown but is required for root curvature toward water, is indispensable for generating the slow, long-distance Ca2+ signal. Furthermore, biochemical and genetic manipulations that elevate cytosolic Ca2+ levels, including mutants of the endoplasmic reticulum (ER) Ca2+-ATPase isoform ECA1, enhance root curvature toward water. Finally, coimmunoprecipitation of plant proteins and functional complementation assays in yeast cells revealed that MIZ1 directly binds to ECA1 and inhibits its activity. We suggest that the inhibition of ECA1 by MIZ1 changes the balance between cytosolic Ca2+ influx and efflux and generates the cytosolic Ca2+ signal required for water tracking. [ABSTRACT FROM AUTHOR]

Published

2018

15. Hydrotropism: how roots search for water.

Author

Dietrich, Daniela

Subjects

*HYDROTROPISM, *PLANT growth, *AUXIN, *ARABIDOPSIS thaliana, *PLANT hormones, *EFFECT of drought on plants

Abstract

Fresh water is an increasingly scarce resource for agriculture. Plant roots mediate water uptake from the soil and have developed a number of adaptive traits such as hydrotropism to aid water foraging. Hydrotropism modifies root growth to respond to a water potential gradient in soil and grow towards areas with a higher moisture content. Abscisic acid (ABA) and a small number of genes, including those encoding ABA signal transducers, MIZ2/GNOM, and the hydrotropism-specific MIZ1, are known to be necessary for the response in Arabidopsis thaliana, whereas the role of auxin in hydrotropism appears to vary depending on the plant species. This review will describe recent progress characterizing the hormonal regulation of hydrotropism. Recent advances in identifying the sites of hydrotropic perception and response, together with its interaction with gravitropism, will also be discussed. Finally, I will describe putative mechanisms for perception of the water potential gradient and a potential role for hydrotropism in acclimatizing plants to drought conditions. [ABSTRACT FROM AUTHOR]

Published

2018

16. Root-tip-mediated inhibition of hydrotropism is accompanied with the suppression of asymmetric expression of auxin-inducible genes in response to moisture gradients in cucumber roots.

Author

Fujii, Nobuharu, Miyabayashi, Sachiko, Sugita, Tomoki, Kobayashi, Akie, Yamazaki, Chiaki, Miyazawa, Yutaka, Kamada, Motoshi, Kasahara, Haruo, Osada, Ikuko, Shimazu, Toru, Fusejima, Yasuo, Higashibata, Akira, Yamazaki, Takashi, Ishioka, Noriaki, and Takahashi, Hideyuki

Subjects

*CUCUMBERS, *HYDROTROPISM, *GEOTROPISM, *AUXIN, *RNA sequencing

Abstract

In cucumber seedlings, gravitropism interferes with hydrotropism, which results in the nearly complete inhibition of hydrotropism under stationary conditions. However, hydrotropic responses are induced when the gravitropic response in the root is nullified by clinorotation. Columella cells in the root cap sense gravity, which induces the gravitropic response. In this study, we found that removing the root tip induced hydrotropism in cucumber roots under stationary conditions. The application of auxin transport inhibitors to cucumber seedlings under stationary conditions suppressed the hydrotropic response induced by the removal of the root tip. To investigate the expression of genes related to hydrotropism in de-tipped cucumber roots, we conducted transcriptome analysis of gene expression by RNA-Seq using seedlings exhibiting hydrotropic and gravitropic responses. Of the 21 and 45 genes asymmetrically expressed during hydrotropic and gravitropic responses, respectively, five genes were identical. Gene ontology (GO) analysis indicated that the category auxin-inducible genes was significantly enriched among genes that were more highly expressed in the concave side of the root than the convex side during hydrotropic or gravitropic responses. Reverse transcription followed by quantitative polymerase chain reaction (RT-qPCR) analysis revealed that root hydrotropism induced under stationary conditions (by removing the root tip) was accompanied by the asymmetric expression of several auxin-inducible genes. However, intact roots did not exhibit the asymmetric expression patterns of auxin-inducible genes under stationary conditions, even in the presence of a moisture gradient. These results suggest that the root tip inhibits hydrotropism by suppressing the induction of asymmetric auxin distribution. Auxin transport and distribution not mediated by the root tip might play a role in hydrotropism in cucumber roots. [ABSTRACT FROM AUTHOR]

Published

2018

17. Root Plasticity in the Pursuit of Water

Author

Hillel Fromm

Subjects

drought, hydraulic lift, hydropatterning, hydrotropism, phenotypic plasticity, rhizosphere, root system architecture, xerobranching, xerotropism, Botany, QK1-989

Abstract

One of the greatest challenges of terrestrial vegetation is to acquire water through soil-grown roots. Owing to the scarcity of high-quality water in the soil and the environment’s spatial heterogeneity and temporal variability, ranging from extreme flooding to drought, roots have evolutionarily acquired tremendous plasticity regarding their geometric arrangement of individual roots and their three-dimensional organization within the soil. Water deficiency has also become an increasing threat to agriculture and dryland ecosystems due to climate change. As a result, roots have become important targets for genetic selection and modification in an effort to improve crop resilience under water-limiting conditions. This review addresses root plasticity from different angles: Their structures and geometry in response to the environment, potential genetic control of root traits suitable for water-limiting conditions, and contemporary and future studies of the principles underlying root plasticity post-Darwin’s ‘root-brain’ hypothesis. Our increasing knowledge of different disciplines of plant sciences and agriculture should contribute to a sustainable management of natural and agricultural ecosystems for the future of mankind.

Published

2019

18. Gravitropism interferes with hydrotropism via counteracting auxin dynamics in cucumber roots: clinorotation and spaceflight experiments.

Author

Morohashi, Keita, Okamoto, Miki, Yamazaki, Chiaki, Fujii, Nobuharu, Miyazawa, Yutaka, Kamada, Motoshi, Kasahara, Haruo, Osada, Ikuko, Shimazu, Toru, Fusejima, Yasuo, Higashibata, Akira, Yamazaki, Takashi, Ishioka, Noriaki, Kobayashi, Akie, and Takahashi, Hideyuki

Subjects

*GEOTROPISM, *HYDROTROPISM, *PLANT roots, *CUCUMBERS, *ZERO gravity experiments

Abstract

Roots of land plants show gravitropism and hydrotropism in response to gravity and moisture gradients, respectively, for controlling their growth orientation. Gravitropism interferes with hydrotropism, although the mechanistic aspects are poorly understood., Here, we differentiated hydrotropism from gravitropism in cucumber roots by conducting clinorotation and spaceflight experiments. We also compared mechanisms regulating hydrotropism and auxin-regulated gravitropism., Clinorotated or microgravity (μG)-grown cucumber seedling roots hydrotropically bent toward wet substrate in the presence of moisture gradients, but they grew straight in the direction of normal gravitational force at the Earth's surface (1G) on the ground or centrifuge-generated 1G in space. The roots appeared to become hydrotropically more sensitive to moisture gradients under μG conditions in space. Auxin transport inhibitors significantly reduced the hydrotropic response of clinorotated seedling roots. The auxin efflux protein Cs PIN5 was differentially expressed in roots of both clinorotated and μG-grown seedlings; with higher expression in the high-humidity (concave) side than the low-humidity (convex) side of hydrotropically responding roots., Our results suggest that roots become hydrotropically sensitive in μG, and Cs PIN5-mediated auxin transport has an important role in inducing root hydrotropism. Thus, hydrotropic and gravitropic responses in cucumber roots may compete via differential auxin dynamics established in response to moisture gradients and gravity. [ABSTRACT FROM AUTHOR]

Published

2017

19. Auxin transport and response requirements for root hydrotropism differ between plant species.

Author

Yusuke Nakajima, Yoshitaka Nara, Akie Kobayashi, Tomoki Sugita, Yutaka Miyazawa, Nobuharu Fujii, and Hideyuki Takahashi

Subjects

*AUXIN, *HYDROTROPISM, *GEOTROPISM, *VERTICILLIUM, *RICE

Abstract

The direction of auxin transport changes in gravistimulated roots, causing auxin accumulation in the lower side of horizontally reoriented roots. This study found that auxin was similarly involved in hydrotropism and gravitropism in rice and pea roots, but hydrotropism in Lotus japonicus roots was independent of both auxin transport and response. Application of either auxin transport inhibitors or an auxin response inhibitor decreased both hydrotropism and gravitropism in rice roots, and reduced hydrotropism in pea roots. However, Lotus roots treated with these inhibitors showed reduced gravitropism but an unaltered or an enhanced hydrotropic response. Inhibiting auxin biosynthesis substantially reduced both tropisms in rice and Lotus roots. Removing the final 0.2 mm (including the root cap) from the root tip inhibited gravitropism but not hydrotropism in rice seedling roots. These results suggested that modes of auxin involvement in hydrotropism differed between plant species. In rice roots, although auxin transport and responses were required for both gravitropism and hydrotropism, the root cap was involved in the auxin regulation of gravitropism but not hydrotropism. Hydrotropism in Lotus roots, however, may be regulated by a novel mechanism that is independent of both auxin transport and the TIR1/AFBs auxin response pathway. [ABSTRACT FROM AUTHOR]

Published

2017

20. Effects of Hydrotropic Salt on the Nanoscopic Dynamics of DTAB Micelles.

Author

Sharma, V. K., Srinivasan, H., Mitra, S., Garcia-Sakai, V., and Mukhopadhyay, R.

Subjects

*HYDROTROPISM, *SALTS, *MOLECULAR dynamics, *AMMONIUM bromide, *LIGHT scattering, *QUASIELASTIC neutron scattering, *DIFFUSION coefficients

Abstract

Effects of a hydrotropic salt, sodium salicylate (NaSal), on the dynamic behavior of cationic dodecyltrimethylammonium bromide (DTAB) micelles as studied using dynamic light scattering (DLS) and quasielastic neutron scattering (QENS) techniques are reported here. DLS study showed that the addition of NaSal leads to a decrease in the apparent diffusion coefficient of the whole micelle indicating micellar growth. QENS data analysis suggested that observed dynamics involves two distinct motions, lateral motion of the surfactant over the curved micellar surface and localized segmental motion of the surfactant. It is found that the addition of NaSal slows down the lateral motion of DTAB while the localized segmental motion of the DTAB chain is not affected much. An atomistic molecular dynamics (MD) simulation was performed to gain further insight into the underlying phenomena. MD simulation results are found to be consistent with the experimental observations. MD simulation revealed that location of the salicylate ions on the micellar surface and their strong electrostatic association with their oppositely charged surfactant headgroup are the major factors in slowing down the lateral motion of the DTAB molecule. In the present work, a quantitative description of the effects of NaSal on the nanoscopic dynamics of DTAB micelles and its correlation with the microstructure of the micelle is provided. [ABSTRACT FROM AUTHOR]

Published

2017

21. Root electrotropism in Arabidopsis does not depend on auxin distribution but requires cytokinin biosynthesis

Author

Maddalena Salvalaio, Nicholas Oliver, Deniz Tiknaz, Maximillian Schwarze, Nicolas Kral, Soo-Jeong Kim, Giovanni Sena, Paul G Allen Family Foundation, Biotechnology and Biological Sciences Research Council (BBSRC), and Imperial College Excellence Fund for Frontier Research

Subjects

Cytokinins, Genotype, Physiology, Plant Biology & Botany, root electrotropism, Arabidopsis, Plant Science, Genes, Plant, Plant Roots, Tropism, Electricity, Gene Expression Regulation, Plant, 500 Naturwissenschaften und Mathematik::580 Pflanzen (Botanik)::580 Pflanzen (Botanik), 07 Agricultural and Veterinary Sciences, Genetics, ELECTRICAL-FIELDS, Science & Technology, Plant Sciences, Genetic Variation, 06 Biological Sciences, ELECTROTAXIS, HYDROTROPISM, GROWTH, Life Sciences & Biomedicine, signal integration

Abstract

Efficient foraging by plant roots relies on the ability to sense multiple physical and chemical cues in soil and to reorient growth accordingly (tropism). Root tropisms range from sensing gravity (gravitropism), light (phototropism), water (hydrotropism), touch (thigmotropism), and more. Electrotropism, also known as galvanotropism, is the phenomenon of aligning growth with external electric fields and currents. Although root electrotropism has been observed in a few species since the end of the 19th century, its molecular and physical mechanisms remain elusive, limiting its comparison with the more well-defined sensing pathways in plants. Here, we provide a quantitative and molecular characterization of root electrotropism in the model system Arabidopsis (Arabidopsis thaliana), showing that it does not depend on an asymmetric distribution of the plant hormone auxin, but instead requires the biosynthesis of a second hormone, cytokinin. We also show that the dose–response kinetics of the early steps of root electrotropism follows a power law analogous to the one observed in some physiological reactions in animals. Future studies involving more extensive molecular and quantitative characterization of root electrotropism would represent a step toward a better understanding of signal integration in plants and would also serve as an independent outgroup for comparative analysis of electroreception in animals and fungi.

Published

2022

22. Hydrotropic Solubilization of Lipophilic Drugs for Oral Delivery: The Effects of Urea and Nicotinamide on Carbamazepine Solubility-Permeability Interplay.

Author

Beig, Avital, Lindley, David, Miller, Jonathan M., Agbaria, Riad, and Dahan, Arik

Subjects

HYDROTROPISM, BIOLOGICAL membranes, NICOTINAMIDE

Abstract

Hydrotropy refers to increasing the water solubility of otherwise poorly soluble compound by the presence of small organic molecules. While it can certainly increase the apparent solubility of a lipophilic drug, the effect of hydrotropy on the drugs' permeation through the intestinal membrane has not been studied. The purpose of this work was to investigate the solubility-permeability interplay when using hydrotropic drug solubilization. The concentration-dependent effects of the commonly used hydrotropes urea and nicotinamide, on the solubility and the permeability of the lipophilic antiepileptic drug carbamazepine were studied. Then, the solubility-permeability interplay was mathematically modeled, and was compared to the experimental data. Both hydrotropes allowed significant concentration-dependent carbamazepine solubility increase (up to ~30-fold). A concomitant permeability decrease was evident both in vitro and in vivo (~17-fold for nicotinamide and ~9-fold for urea), revealing a solubility-permeability tradeoff when using hydrotropic drug solubilization. A relatively simplified simulation approach based on proportional opposite correlation between the solubility increase and the permeability decrease at a given hydrotrope concentration allowed excellent prediction of the overall solubility-permeability tradeoff. In conclusion, when using hydrotropic drug solubilization it is prudent to not focus solely on solubility, but to account for the permeability as well; achieving optimal solubility-permeability balance may promote the overall goal of the formulation to maximize oral drug exposure. [ABSTRACT FROM AUTHOR]

Published

2016

23. Mechanism of Hydrotropic Action of Hydrotrope Sodium Cumene Sulfonate on the Solubility of Di-t-Butyl-Methane: A Molecular Dynamics Simulation Study.

Author

Das, Shubhadip and Paul, Sandip

Subjects

*HYDROTROPISM, *CUMENE, *SOLUBILITY, *METHANE, *MOLECULAR dynamics, *HYDROGEN bonding

Abstract

Hydrotropes are special class of amphiphilic molecules that have an ability to solubilize the insoluble or sparingly soluble molecules in water. To find out the mechanism of hydrotropic action of hydrotropes on hydrophobic molecules, we have carried out classical molecular dynamics simulation of hydrophobic solute di-t-butyl-methane (DTBM) and hydrotrope sodium cumene sulfonate (SCS) in water with a regime of SCS concentrations. Our study demonstrates that, above the minimum hydrotrope concentration (MHC), the self-aggregation of SCS starts, and it creates a micellar-like environment in which the hydrophobic tail part of SCS points inward while its hydrophilic sulfonate group points outward to make favorable contact with water molecules. The formation of the hydrophobic core of SCS cluster creates a hydrophobic environment where the hydrophobic DTBM molecules are encapsulated. Interestingly, the determination of average water-SCS hydrogen bonds further suggests that the aggregate formation of SCS molecules has a negligible influence on it. Moreover, the calculations of Flory-Huggins interaction parameters also reveal favorable interactions between hydrotrope SCS and solute DTBM molecules. The implications of these findings on the mechanism of hydrotrope assisted enhanced solubility of hydrophobic molecules are discussed. [ABSTRACT FROM AUTHOR]

Published

2016

24. Root phenotypic detection of different vigorous maize seeds based on Progressive Corrosion Joining algorithm of image

Author

Wei Lu, Yiming Deng, and Ye Li

Subjects

0106 biological sciences, 0301 basic medicine, Root (linguistics), Progressive Corrosion Joining, Plant Science, Hydrotropism, lcsh:Plant culture, 01 natural sciences, 03 medical and health sciences, Root length, Concentric cylinder, Genetics, lcsh:SB1-1110, lcsh:QH301-705.5, Mathematics, Thinning, Methodology, Root phenotyping, Seed vigor, 030104 developmental biology, lcsh:Biology (General), Root number, Negative correlation, Algorithm, 010606 plant biology & botany, Biotechnology

Abstract

Background The root phenotypes of different vigorous maize seeds vary a lot. Imaging roots of growing maize is a non-invasive, affordable and high throughput approach. However, it’s difficult to get integral root images because of the block of the soil. The paper proposed an algorithm to repair incomplete root images for maize root fast non-invasive phenotyping detection. Results A two-layer transparent stress growth device with two concentric cylinders was developed as mesocosms and the maize seeds were planted in the annulus of it. The maize roots grow in soil against two acrylic plastic surfaces due to the press of the small growing area to acquire more root details during roots visualization and imaging. Even though, parts of the roots are occluded which means that it’s tough to extract the information of root general physical construction. For recovering gaps from disconnected root segments, Progressive Corrosion Joining (PCJ) algorithm was proposed based on the physiological characteristics of hydrotropism, geostrophic and continuity with three steps which are root image thinning, progressive corrosion and joining processing respectively. The experiments indicate that maize phenotyping parameters are negative correlation with seed aging days. And specifically, Root Number (RTN), Root Length (RTL), Root Width (RTW) and Root Extension Length (REL) of unaged and 14-day-aged maize seeds are decreased from 15.40, 82.40 mm, 1.53 mm and 82.20 mm to 4.58, 38.6 mm, 1.35 mm and 55.20 mm, and the growing speed of them are changed from 1.68 per day, 8.80 mm/d, 0.06 mm/d, 9.0 mm/d to 0.70 per day, 4.3 mm/d, 0.05 mm/d and 5.70 mm/d respectively. Whereas Root Extension Angle (REA) is basically irrelevant with the level of maize seed aging. Conclusion The developed double-layer Annular Root Phenotyping Container (ARPC) can satisfy the general physical construction of maize as well as push each root growing along the inner wall of the container which help to acquire more root information. The presented novel PCJ algorithm can recover the missing parts, even for big gaps, of maize roots effectively according to root morphological properties. The experiments show that the proposed method can be applied to evaluate the vigor of maize seeds which has vast application prospect in high throughput root phenotyping area.

Published

2019

25. Abscisic acid induced a negative geotropic response in dark-incubated Chlamydomonas reinhardtii

Author

Adam Gregg, Rhiannon Davies, Ian D. Wilson, Layla Al-Hijab, Heather Macdonald, and Michael Ladomery

Subjects

0301 basic medicine, Light, Photoperiod, Microorganism, Arabidopsis, Taxis Response, Chlamydomonas reinhardtii, lcsh:Medicine, Hydrotropism, Photosynthetic efficiency, Microbiology, Tropism, Article, Gravitropism, 03 medical and health sciences, chemistry.chemical_compound, 0302 clinical medicine, Plant Growth Regulators, Algae, Chlorophyta, Stress, Physiological, lcsh:Science, Abscisic acid, photoperiodism, Multidisciplinary, biology, Chemistry, organic chemicals, fungi, lcsh:R, Water, food and beverages, biology.organism_classification, 030104 developmental biology, Biophysics, Abscisic acid, algae, chlamydomonas reinhardtii, lcsh:Q, Centre for Research in Biosciences, 030217 neurology & neurosurgery, Abscisic Acid, Signal Transduction

Abstract

The phytohormone abscisic acid (ABA) plays a role in stresses that alter plant water status and may also regulate root gravitropism and hydrotropism. ABA also exists in the aquatic algal progenitors of land plants, but other than its involvement in stress responses, its physiological role in these microorganisms remains elusive. We show that exogenous ABA significantly altered the HCO3− uptake of Chamydomonas reinhardtii in a light-intensity-dependent manner. In high light ABA enhanced HCO3− uptake, while under low light uptake was diminished. In the dark, ABA induced a negative geotropic movement of the algae to an extent dependent on the time of sampling during the light/dark cycle. The algae also showed a differential, light-dependent directional taxis response to a fixed ABA source, moving horizontally towards the source in the light and away in the dark. We conclude that light and ABA signal competitively in order for algae to position themselves in the water column to minimise photo-oxidative stress and optimise photosynthetic efficiency. We suggest that the development of this response mechanism in motile algae may have been an important step in the evolution of terrestrial plants and that its retention therein strongly implicates ABA in the regulation of their relevant tropisms.

Published

2019

26. Low ABA concentration promotes root growth and hydrotropism through relief of ABA INSENSITIVE 1-mediated inhibition of plasma membrane H+-ATPase 2

Author

Yue Wang, Yiyong Zhu, Xiaolin Dang, Ying Li, Weifeng Xu, Jianhua Zhang, Wei Yuan, Rui Miao, Irene Garcia-Maquilon, and Pedro L. Rodriguez

Subjects

0106 biological sciences, ATPase, Mutant, Arabidopsis, Hydrotropism, 01 natural sciences, Dephosphorylation, 03 medical and health sciences, Phosphoprotein Phosphatases, BIOQUIMICA Y BIOLOGIA MOLECULAR, Research Articles, 030304 developmental biology, 0303 health sciences, Multidisciplinary, biology, Arabidopsis Proteins, Chemistry, Plant Sciences, Cell Membrane, fungi, Wild type, SciAdv r-articles, food and beverages, Agriculture, biology.organism_classification, Apoplast, Cell biology, Proton-Translocating ATPases, Seedlings, biology.protein, Efflux, Research Article, Abscisic Acid, 010606 plant biology & botany

Abstract

[EN] The hab1-1abi1-2abi2-2pp2ca-1 quadruple mutant (Qabi2-2) seedlings lacking key negative regulators of ABA signaling, namely, clade A protein phosphatases type 2C (PP2Cs), show more apoplastic H+ efflux in roots and display an enhanced root growth under normal medium or water stress medium compared to the wild type. The presence of low ABA concentration (0.1 micromolar), inhibiting PP2C activity via monomeric ABA receptors, enhances root apoplastic H+ efflux and growth of the wild type, resembling the Qabi2-2 phenotype in normal medium. Qabi2-2 seedlings also demonstrate increased hydrotropism compared to the wild type in obliquely-oriented hydrotropic experimental system, and asymmetric H+ efflux in root elongation zone is crucial for root hydrotropism. Moreover, we reveal that Arabidopsis ABA-insensitive 1, a key PP2C in ABA signaling, interacts directly with the C terminus of Arabidopsis plasma membrane H+-dependent adenosine triphosphatase 2 (AHA2) and dephosphorylates its penultimate threonine residue (Thr(947)), whose dephosphorylation negatively regulates AHA2., We are grateful for grant support from the National Key R&D Program of China (2017YFE0118100 and 2018YFD02003025), National Natural Science Foundation of China (nos. 31600209, 31761130073, and 31872169), a Newton Advanced Fellowship (NSFC-RS: NA160430), Fujian Province Education Department Funding (JK2017015), and Research Grant of FAFU (KXGH17005). Work in the laboratory of P.L.R. was supported by the Ministerio de Ciencia, Innovacion y Universidades (MICIU), grant BIO2017-82503-R.

Published

2021

27. The physiology of plant responses to drought

Subjects

Drought, Root, Hydrotropism, Arabidopsis, Water use efficiency, Climate change, Cereals, Crops, Food security, Abiotic stress, Signaling, Stomata, Sorghum

Published

2021

28. Evidence for root adaptation to a spatially discontinuous water availability in the absence of external water potential gradients

Author

Tom Sizmur, Ludovico Cademartiri, Souvik Banerjee, Kara R. Lind, Bin Yuan, Oskar Siemianowski, and Hannah VanEvery

Subjects

Thermotolerance, Multidisciplinary, Plant roots, Arabidopsis Proteins, Acclimatization, Microfluidics, Water source, Foraging, Arabidopsis, Water, Soil science, Salt Tolerance, Hydrotropism, Root system, Biological Sciences, Plants, Adaptation, Physiological, Plant Roots, Tropism, Droughts, Orders of magnitude (bit rate), Gene Expression Regulation, Plant, Environmental science, Adaptation, Water vapor

Abstract

We hereby show that root systems adapt to a spatially discontinuous pattern of water availability even when the gradients of water potential across them are vanishingly small. A paper microfluidic approach allowed us to expose the entire root system of Brassica rapa plants to a square array of water sources, separated by dry areas. Gradients in the concentration of water vapor across the root system were as small as 10-4 mM·m-1 (~4 orders of magnitude smaller than in conventional hydrotropism assays).\ud In spite of such minuscule gradients (which greatly limit the possible influence of the well-understood gradient-driven hydrotropic response), our results show that (i) individual roots as well as the root system as a whole adapt to the pattern of water availability to maximize access to water, and that (ii) this adaptation increases as water sources become more rare. \ud These results suggest that either plant roots are more sensitive to water gradients than humanmade water sensors by 3 to 5 orders of magnitude, or they might have developed, like other organisms, mechanisms for water foraging that allow them to find water in the absence of an external gradient in water potential.

Published

2020

29. Jasmonate biosynthesis arising from altered cell walls is prompted by turgor-driven mechanical compression and guides root hydrotropism

Author

Marlene Zimmer, Stefan Mielke, Hagen Stellmach, Cătălin Voiniciuc, Bettina Hause, Mukesh Kumar Meena, Debora Gasperini, and René Dreos

Subjects

Cell wall, medicine.anatomical_structure, Osmotic concentration, Turgor pressure, Cell, Mutant, medicine, Hydrotropism, Jasmonate, Biology, Intracellular, Cell biology

Abstract

Despite the vital roles of jasmonoyl-isoleucine (JA-Ile) in governing plant growth and environmental acclimation, it remains unclear what intracellular processes lead to its induction. Here, we provide compelling genetic evidence that mechanical and osmotic regulation of turgor pressure represents a key factor in eliciting JA-Ile biosynthesis. After identifying cell wall mutant alleles in KORRIGAN1 (KOR1) with elevated JA-Ile in seedling roots, we found that ectopic JA-Ile resulted from cell non-autonomous signals deriving from enlarged cortex cells compressing inner tissues and stimulating JA-Ile production. Restoring cortex cell size by cell-type-specific KOR1 complementation, by isolating a genetic kor1 suppressor, and by lowering turgor pressure with hyperosmotic treatments, abolished JA-Ile signalling. Strikingly, heightened JA-Ile levels guided kor1 roots towards greater water availability, uncovering a previously unrecognized JA-Ile function in root hydrotropism. Collectively, these findings enhance our understanding of JA-Ile biosynthesis initiation, and reveal a novel role of JA-Ile in orchestrating environmental resilience.

Published

2020

30. Correction to: Molecular mechanisms mediating root hydrotropism: what we have observed since the rediscovery of hydrotropism

Author

Hideyuki Takahashi and Yutaka Miyazawa

Subjects

Plant ecology, Abscisic acid, Current Topics in Plant Research, Hydrotropism, MIZU-KUSSEI1 (MIZ1), Plant biochemistry, Botany, Plant physiology, Auxin, Plant Science, Biology, MIZU-KUSSEI2 (MIZ2)

Abstract

Roots display directional growth toward moisture in response to a water potential gradient. Root hydrotropism is thought to facilitate plant adaptation to continuously changing water availability. Hydrotropism has not been as extensively studied as gravitropism. However, comparisons of hydrotropic and gravitropic responses identified mechanisms that are unique to hydrotropism. Regulatory mechanisms underlying the hydrotropic response appear to differ among different species. We recently performed molecular and genetic analyses of root hydrotropism in Arabidopsis thaliana. In this review, we summarize the current knowledge of specific mechanisms mediating root hydrotropism in several plant species.

Published

2020

31. Light-Dark Modulates Root Hydrotropism Associated with Gravitropism by Involving Amyloplast Response in Arabidopsis

Author

Ying Li, Rui Miao, Luocheng Li, Hui Dai, Wei Yuan, Jianhua Zhang, and Weifeng Xu

Subjects

0301 basic medicine, biology, Chemistry, Mutant, Gravitropism, Arabidopsis, Hydrotropism, biology.organism_classification, Plant Roots, Tropism, General Biochemistry, Genetics and Molecular Biology, Cell biology, 03 medical and health sciences, 030104 developmental biology, 0302 clinical medicine, Darkness, Gene expression, Shoot, Amyloplast, Plastids, 030217 neurology & neurosurgery

Abstract

Summary The role of amyloplasts in the interactions between hydrotropism and gravitropism has been previously described. However, the effect of light-dark on the interactions between the two tropisms remains unclear. Here, by developing a method that makes it possible to mimic natural conditions more closely than the conventional lab conditions, we show that hydrotropism is higher in wild-type Arabidopsis seedlings whose shoots are illuminated but whose roots are grown in the dark compared with seedlings that are fully exposed to light. Root gravitropism is substantially decreased because of the reduction of amyloplast content in the root tip with decreased gene expression in PGM1 (a key starch biosynthesis gene), which may contribute to enhanced root hydrotropism under darkness. Furthermore, the starch-deficient mutant pgm1-1 exhibits greater hydrotropism compared with wild-type. Our results suggest that amyloplast response and starch reduction occur under light-dark modulation, followed by decreased gravitropism and enhanced hydrotropism in Arabidopsis root.

Published

2020

32. Comparative analysis reveals gravity is involved in the MIZ1-regulated root hydrotropism

Author

Herbert J. Kronzucker, Weifeng Xu, František Baluška, Hui Dai, Jianhua Zhang, Congming Lu, Luocheng Li, Wei Yuan, Ying Li, Xiaolin Dang, and Rui Miao

Subjects

0106 biological sciences, 0301 basic medicine, Gravity (chemistry), Physiology, Chemistry, Arabidopsis Proteins, Gravitropism, Root (chord), Arabidopsis, Oblique case, Water, Plant Science, Hydrotropism, 01 natural sciences, Plant Roots, Tropism, Vertical orientation, 03 medical and health sciences, 030104 developmental biology, Biophysics, Amyloplast, Elongation, 010606 plant biology & botany

Abstract

Hydrotropism is the directed growth of roots toward the water found in the soil. However, mechanisms governing interactions between hydrotropism and gravitropism remain largely unclear. In this study, we found that an air system and an agar–sorbitol system induced only oblique water-potential gradients; an agar–glycerol system induced only vertical water-potential gradients; and a sand system established both oblique and vertical water-potential gradients. We employed obliquely oriented and vertically oriented experimental systems to study hydrotropism in Arabidopsis and tomato plants. Comparative analyses using different hydrotropic systems showed that gravity hindered the ability of roots to search for obliquely oriented water, whilst facilitating roots’ search for vertically oriented water. We found that the gravitropism-deficient mutant aux1 showed enhanced hydrotropism in the oblique orientation but impaired root elongation towards water in the vertical orientation. The miz1 mutant exhibited deficient hydrotropism in the oblique orientation but normal root elongation towards water in the vertical orientation. Importantly, in contrast to miz1, the miz1/aux1 double mutant exhibited hydrotropic bending in the oblique orientation and attenuated root elongation towards water in the vertical orientation. Our results suggest that gravitropism is required for MIZ1-regulated root hydrotropism in both the oblique orientation and the vertical orientation, providing further insight into the role of gravity in root hydrotropism.

Published

2020

33. The physiology of plant responses to drought

Author

Ana I. Caño-Delgado, Aditi Gupta, Andres Rico-Medina, Ministerio de Economía y Competitividad (España), European Research Council, Generalitat de Catalunya, European Commission, and Fundación Tatiana Pérez de Guzmán el Bueno

Subjects

0106 biological sciences, 0301 basic medicine, Crops, Agricultural, Arabidopsis, Physiology, Cereals, Crops, Hydrotropism, 01 natural sciences, 03 medical and health sciences, Plant Growth Regulators, Arabidopsis thaliana, Climate change, Water-use efficiency, Stomata, Sorghum, 2. Zero hunger, Multidisciplinary, biology, Drought, Abiotic stress, Crop yield, fungi, food and beverages, Water, Water use efficiency, Food security, 15. Life on land, biology.organism_classification, Signaling, Droughts, 030104 developmental biology, Root, Genetic Engineering, Flux (metabolism), 010606 plant biology & botany, Abscisic Acid, Signal Transduction

Abstract

Drought alone causes more annual loss in crop yield than all pathogens combined. To adapt to moisture gradients in soil, plants alter their physiology, modify root growth and architecture, and close stomata on their aboveground segments. These tissue-specific responses modify the flux of cellular signals, resulting in early flowering or stunted growth and, often, reduced yield. Physiological and molecular analyses of the model plant Arabidopsis thaliana have identified phytohormone signaling as key for regulating the response to drought or water insufficiency. Here we discuss how engineering hormone signaling in specific cells and cellular domains can facilitate improved plant responses to drought. We explore current knowledge and future questions central to the quest to produce high-yield, drought-resistant crops., A.I.C.-D. has received funding from the European Research Council (ERC) under the European Union’s Horizon 2020 research and innovation programme (grant agreement 683163). A.I.C.-D. is a recipient of a BIO2016-78150-P grant funded by the Spanish Ministry of Economy and Competitiveness and Agencia Estatal de Investigación (MINECO/AEI) and Fondo Europeo de Desarrollo Regional (FEDER). A.G. has received funding by a postdoctoral fellowship from the “Severo Ochoa Programme for Centers of Excellence in R&D” 2016–2019 from the Ministerio de Ciencia e Innovación (SEV-2015-0533). A.G. and A.R.-M. have received funding from ERC-2015-CoG–683163 granted to the A.I.C.-D. laboratory. A.R.-M. is a predoctoral fellow from Fundación Tatiana Pérez de Guzmán el Bueno. This work was supported by the CERCA Programme/Generalitat de Catalunya.

Published

2020

34. Integration of nutrient and water availabilities via auxin into the root developmental program

Author

Ying Liu and Nicolaus von Wirén

Subjects

chemistry.chemical_classification, Root (linguistics), Indoleacetic Acids, Ecology, fungi, Foraging, Water, food and beverages, Nutrients, Plant Science, Hydrotropism, Biology, Plant Roots, Root foraging, Plant Breeding, Nutrient, chemistry, Auxin, Soil water

Abstract

In most soils, the spatial distribution of nutrients and water in the rooting zone of plants is heterogeneous and changes over time. To access localized resources more efficiently, plants induce foraging responses by modulating individual morphological root traits, such as the length of the primary root or the number and length of lateral roots. These adaptive responses require the integration of exogenous and endogenous nutrient- or water-related signals into the root developmental program. Recent studies corroborated a central role of auxin in shaping root architectural traits in response to fluctuating nutrient and water availabilities. In this review, we highlight current knowledge on nutrient- and water-related developmental processes that impact root foraging and involve auxin as a central player. A deeper understanding and exploitation of these auxin-related processes and mechanisms promises advances in crop breeding for higher resource efficiency.

Published

2022

35. BR-INSENSITIVE1 regulates hydrotropic response by interacting with plasma membrane H+-ATPases in Arabidopsis

Author

Jianping Liu, Luocheng Li, Rui Miao, Weifeng Xu, Yingjiao Zhang, Wei Yuan, Ying Li, Wei Siao, and Qian Zhang

Subjects

0106 biological sciences, 0301 basic medicine, Short Communication, ATPase, Arabidopsis, Plant Science, Hydrotropism, Plant Roots, 01 natural sciences, 03 medical and health sciences, Brassinosteroids, Receptor, biology, Arabidopsis Proteins, Cell Membrane, fungi, Plasma, biology.organism_classification, Apoplast, Proton-Translocating ATPases, 030104 developmental biology, Membrane, biology.protein, Biophysics, Moisture gradient, 010606 plant biology & botany

Abstract

Arabidopsis roots sense the moisture gradient in soils and grow toward an area with higher water potential – a process called hydrotropism. Our previous study has shown that the apoplastic proton extrusion in root tips is influenced by brassinosteroids (BRs) receptor BR-INSENSITIVE1 (BRI1) and is crucial for hydrotropic response in Arabidopsis. Here we show that BRI1 interacts directly not only with Arabidopsis plasma membrane H+-ATPase 2 (AHA2) but also with Arabidopsis plasma membrane H+-ATPase 7 (AHA7). Therefore, BRI1 may affect hydrotropic response via regulating the activities of AHA2 and AHA7.

Published

2018

36. Comparative Analysis of Arabidopsis Ecotypes Reveals a Role for Brassinosteroids in Root Hydrotropism

Author

Herbert J. Kronzucker, Jianhua Zhang, Wei Yuan, Meng Wang, Yan Ren, Ying Li, Weifeng Xu, Rui Miao, and Na Zhang

Subjects

0106 biological sciences, 0301 basic medicine, chemistry.chemical_classification, biology, Ecotype, Physiology, Mutant, Plant Science, Hydrotropism, biology.organism_classification, 01 natural sciences, 03 medical and health sciences, chemistry.chemical_compound, 030104 developmental biology, chemistry, Auxin, Arabidopsis, Genetics, Biophysics, Arabidopsis thaliana, Efflux, Abscisic acid, 010606 plant biology & botany

Abstract

Plant roots respond to soil moisture gradients and remodel their growth orientation toward water through hydrotropism, a process vital for acclimation to a changing soil environment. Mechanisms underlying the root hydrotropic response, however, remain poorly understood. Here, we examined hydrotropism in 31 Arabidopsis (Arabidopsis thaliana) ecotypes collected from different parts of the world and grown along moisture gradients in a specially designed soil-simulation system. Comparative transcriptome profiling and physiological analyses were carried out on three selected ecotypes, Wassilewskija (Ws), Columbia (Col-0) (strongly hydrotropic), Col-0 (moderately hydrotropic), and C24 (weakly hydrotropic), and in mutant lines with altered root hydrotropic responses. We show that H+ efflux, Ca2+ influx, redox homeostasis, epigenetic regulation, and phytohormone signaling may contribute to root hydrotropism. Among phytohormones, the role of brassinosteroids (BRs) was examined further. In the presence of an inhibitor of BR biosynthesis, the strong hydrotropic response observed in Ws was reduced. The root H+ efflux and primary root elongation also were inhibited when compared with C24, an ecotype that showed a weak hydrotropic response. The BR-insensitive mutant bri1-5 displayed higher rates of root growth inhibition and root curvature on moisture gradients in vertical or oblique orientation when compared with wild-type Ws. We also demonstrate that BRI1 (a BR receptor) interacts with AHA2 (a plasma membrane H+-ATPase) and that their expression patterns are highly coordinated. This synergistic action may contribute to the strong hydrotropism observed in Ws. Our results suggest that BR-associated H+ efflux is critical in the hydrotropic response of Arabidopsis roots.

Published

2018

37. Hydrotropic Properties of Alkyl and Aryl GlycerolMonoethers.

Author

Moity, Laurianne, Shi, Yan, Molinier, Valérie, Dayoub, Wissam, Lemaire, Marc, and Aubry, Jean-Marie

Subjects

*HYDROTROPISM, *ETHERS, *HYDROPHOBIC surfaces, *ALKYL compounds, *CATALYSTS, *SUBSTITUENTS (Chemistry), *COMPARATIVE studies

Abstract

Threepentyl and three aryl 1-O-monoglyceryl ethersprepared via a green catalytic route were investigated as hydrotropicsolvents. Their amphiphilicities were quantified by comparing theirso-called “fish” diagrams constructed with oils of increasinghydrophobicity (EACN). For the same number of carbon atoms, the presenceof a methyl substituent in β position makes the hydrotrope slightlymore hydrophobic, as evidenced by the more hydrophobic optimal oil.Branched isomers are also less efficient since they require higherconcentrations to get microemulsions. The presence of an aromaticmoiety within the hydrophobic chain increases the solubility of thehydrotrope in water in comparison to the alkyl derivative that hasthe same number of carbon atoms. It also modifies significantly theassociative behavior in oil/water systems: Benzylglycerol monoetheris able to form Winsor III systems, just as the pentyl derivatives,but with much more polar oils, whereas phenylglycerol is not. In oil/watersystems, all glycerol-derived amphiphiles exhibit a twice-lower temperature-sensitivitycompared to their ethyleneglycol counterparts. The pentyl and benzyl1-O-monoglyceryl ethers can be classified as amphiphilicsolvents, or “solvo-surfactants”, as regards to theirsurface-active properties and good solubilizing abilities. [ABSTRACT FROM AUTHOR]

Published

2013

38. MIZ1-regulated hydrotropism functions in the growth and survival of Arabidopsis thaliana under natural conditions.

Author

Iwata, Satoru, Miyazawa, Yutaka, Fujii, Nobuharu, and Takahashi, Hideyuki

Subjects

*PLANT-water relationships, *HYDROTROPISM, *ARABIDOPSIS, *ARABIDOPSIS thaliana, *BIOMASS

Abstract

Background and Aims Root hydrotropism is a response to water-potential gradients that makes roots bend towards areas of higher water potential. The gene MIZU-KUSSEI1 (MIZ1) that is essential for hydrotropism in Arabidopsis roots has previously been identified. However, the role of root hydrotropism in plant growth and survival under natural conditions has not yet been proven. This study assessed how hydrotropic response contributes to drought avoidance in nature. Methods An experimental system was established for the study of Arabidopsis hydrotropism in soil. Characteristics of hydrotropism were analysed by comparing the responses of the miz1 mutant, transgenic plants overexpressing MIZ1 (MIZ1OE) and wild-type plants. Key Results Wild-type plants developed root systems in regions with higher water potential, whereas the roots of miz1 mutant plants did not show a similar response. This pattern of root distribution induced by hydrotropism was more pronounced in MIZ1OE plants than in wild-type plants. In addition, shoot biomass and the number of plants that survived under drought conditions were much greater in MIZ1OE plants. Conclusions These results show that hydrotropism plays an important role in root system development in soil and contributes to drought avoidance, which results in a greater yield and plant survival under water-limited conditions. The results also show that MIZ1 overexpression can be used for improving plant productivity in arid areas. [ABSTRACT FROM PUBLISHER]

Published

2013

39. PYRABACTIN RESISTANCE1-LIKE8 Plays an Important Role for the Regulation of Abscisic Acid Signaling in Root.

Author

Antoni, Regina, Gonzalez-Guzman, Miguel, Rodriguez, Lesia, Peirats-Llobet, Marta, Pizzio, Gaston A., Fernandez, Maria A., De Winne, Nancy, De Jaeger, Geert, Dietrich, Daniela, Bennett, Malcom J., and Rodriguez, Pedro L.

Subjects

*ABSCISIC acid, *PLANT growth regulation, *ARABIDOPSIS thaliana genetics, *ROOT growth, *HYDROTROPISM

Abstract

Abscisic acid (ABA) signaling plays a critical role in regulating root growth and root system architecture. ABA-mediated growth promotion and root tropic response under water stress are key responses for plant survival under limiting water conditions. In this work, we have explored the role of Arabidopsis (Arabidopsis thaliana) PYRABACTIN RESISTANCE1 (PYR1)/PYR1-LIKE (PYL)/REGULATORY COMPONENTS OF ABA RECEPTORS for root ABA signaling. As a result, we discovered that PYL8 plays a nonredundant role for the regulation of root ABA sensitivity. Unexpectedly, given the multigenic nature and partial functional redundancy observed in the PYR/PYL family, the single pyl8 mutant showed reduced sensitivity to ABA-mediated root growth inhibition. This effect was due to the lack of PYL8-mediated inhibition of several clade A phosphatases type 2C (PP2Cs), since PYL8 interacted in vivo with at least five PP2Cs, namely HYPERSENSITIVE TO ABA1 (HAB1), HAB2, ABA-INSENSITIVE1 (ABI1), ABI2, and PP2CA/ABA-HYPERSENSITIVE GERMINATION3 as revealed by tandem affinity purification and mass spectrometry proteomic approaches. We also discovered that PYR/PYL receptors and clade A PP2Cs are crucial for the hydrotropic response that takes place to guide root growth far from regions with low water potential. Thus, an ABA-hypersensitive pp2c quadruple mutant showed enhanced hydrotropism, whereas an ABA-insensitive sextuple pyr/pyl mutant showed reduced hydrotropic response, indicating that ABA-dependent inhibition of PP2Cs by PYR/PYLs is required for the proper perception of a moisture gradient. [ABSTRACT FROM AUTHOR]

Published

2013

40. ROOT HYDROTROPISM: AN UPDATE.

Author

Cassab, Gladys I., Eapen, Delfeena, and Campos, María Eugenia

Subjects

*PLANT-water relationships, *PLANT growth, *HYDROTROPISM, *PLANT roots, *PLANT genetics, *ARABIDOPSIS, *ABSCISIC acid, *CYTOKININS

Abstract

While water shortage remains the single-most important factor influencing world agriculture, there are very few studies on how plants grow in response to water potential, i.e., hydrotropism. Terrestrial plant roots dwell in the soil, and their ability to grow and explore underground requires many sensors for stimuli such as gravity, humidity gradients, light, mechanical stimulations, temperature, and oxygen. To date, extremely limited information is available on the components of such sensors; however, all of these stimuli are sensed in the root cap. Directional growth of roots is controlled by gravity, which is fixed in direction and intensity. However, other environmental factors, such as water potential gradients, which fluctuate in time, space, direction, and intensity, can act as a signal for modifying the direction of root growth accordingly. Hydrotropism may help roots to obtain water from the soil and at the same time may participate in the establishment of the root system. Current genetic analysis of hydrotropism in Arabidopsis has offered new players, mainly AHRI, NHR1, MIZ1, and MIZ2, which seem to modulate how root caps sense and choose to respond hydrotropically as opposed to other tropic responses. Here we review the mechanism(s) by which these genes and the plant hormones abscisic acid and cytokinins coordinate hydrotropism to counteract the tropic responses to gravitational field, light or touch stimuli. The biological consequence of hydrotropism is also discussed in relation to water stress avoidance. [ABSTRACT FROM AUTHOR]

Published

2013

41. MOLECULAR MECHANISMS OF HYDROTROPISM IN SEEDLING ROOTS OF ARABIDOPSIS THALIANA (BRASSICACEAE).

Author

Moriwaki, Teppei, Miyazawa, Yutaka, Kobayashi, Akie, and Takahashi, Hideyuki

Subjects

*HYDROTROPISM, *PLANT roots, *PLANT-water relationships, *MOLECULAR genetics, *ARABIDOPSIS thaliana, *PLANT genes, *GENETIC mutation, *ENDOPLASMIC reticulum, *PLANTS

Abstract

Roots show positive hydrotropism in response to moisture gradients, which is believed to contribute to plant water acquisition. This article reviews the recent advances of the physiological and molecular genetic studies on hydrotropism in seedling roots of Arabidopsis thaliana. We identified M1ZU-KUSSEll (MIZ1) and MIZ2, essential genes for hydrotropism in roots; the former encodes a protein of unknown function, and the latter encodes an ARF-GEF (GNOM) protein involved in vesicle trafficking. Because both mutants are defective in hydrotropism but not in gravitropism, these mutations might affect a molecular mechanism unique to hydrotropism. MIZ1 is expressed in the lateral root cap and cortex of the root proper. It is localized as a soluble protein in the cytoplasm and in association with the cytoplasmic face of endoplasmic reticulum (ER) membranes in root cells. Light and ABA independently regulate MIZ1 expression, which influences the ultimate hydrotropic response. In addition, MIZ1 overexpression results in an enhancement of hydrotropism and an inhibition of lateral root formation. This phenotype is likely related to the alteration of auxin content in roots. Specifically, the auxin level in the roots decreases in the MIZ1 overexpressor and increases in the miz1 mutant. Unlike most gnom mutants, miz2 displays normal morphology, growth, and gravitropism, with normal localization of PIN proteins. It is probable that MIZ1 plays a crucial role in hydrotropic response by regulating the endogenous level of auxin in Arabidopsis roots. Furthermore, the role of GNOM/MIZ2 in hydrotropism is distinct from that of gravitropism. [ABSTRACT FROM AUTHOR]

Published

2013

42. Overexpression of MIZU-KUSSEI1 Enhances the Root Hydrotropic Response by Retaining Cell Viability Under Hydrostimulated Conditions in Arabidopsis thaliana.

Author

Miyazawa, Yutaka, Moriwaki, Teppei, Uchida, Mayumi, Kobayashi, Akie, Fujii, Nobuharu, and Takahashi, Hideyuki

Subjects

*ARABIDOPSIS thaliana genetics, *HYDROTROPISM, *PLANT growth, *PLANT-water relationships, *GENETIC regulation in plants, *PLANT genetics

Abstract

Because of their sessile nature, plants evolved several mechanisms to tolerate or avoid conditions where water is scarce. The molecular mechanisms contributing to drought tolerance have been studied extensively, whereas the molecular mechanism underlying drought avoidance is less understood despite its importance. Several lines of evidence showed that the roots sense the moisture gradient and grow toward the wet area: so-called hydrotropism. We previously identified MIZU-KUSSEI (MIZ) 1 and MIZ2/GNOM as genes responsible for this process. To gain new insight into the molecular mechanism of root hydrotropism, we generated overexpressors of MIZ1 (MIZ1OEs) and analyzed their hydrotropic response. MIZ1OEs had a remarkable enhancement of root hydrotropism. Furthermore, a greater number of MIZ1OE root cells remained viable under hydrostimulated conditions than those of the wild type, which might contribute to retaining root growth under hydrostimulated conditions. Although overexpression of MIZ1 also caused a slight decrease in the root gravitropic response, it was not attributable to the enhanced hydrotropic response. In addition, miz2 mutation or the auxin response inhibitor nullified the enhanced hydrotropic response in MIZ1OEs. Furthermore, the expression of MIZ1 did not alter the expression of typical genes involved in drought tolerance. These results suggest that MIZ1 positively regulates hydrotropism at an early stage and its overexpression results in an enhancement of signal transduction unique to root hydrotropism to increase the degree of hydrotropic root bending. [ABSTRACT FROM AUTHOR]

Published

2012

43. An altered hydrotropic response (ahr1) mutant of Arabidopsis recovers root hydrotropism with cytokinin.

Author

Saucedo, Manuel, Ponce, Georgina, Campos, María Eugenia, Eapen, Delfeena, García, Edith, Luján, Rosario, Sánchez, Yoloxóchitl, and Cassab, Gladys I.

Subjects

*ARABIDOPSIS, *HYDROTROPISM, *CYTOKININS, *PLANT mutation, *EFFECT of stress on plants, *ABSCISIC acid, *GEOTROPISM

Abstract

Roots are highly plastic and can acclimate to heterogeneous and stressful conditions. However, there is little knowledge of the effect of moisture gradients on the mechanisms controlling root growth orientation and branching, and how this mechanism may help plants to avoid drought responses. The aim of this study was to isolate mutants of Arabidopsis thaliana with altered hydrotropic responses. Here, altered hydrotropic response 1 (ahr1), a semi-dominant allele segregating as a single gene mutation, was characterized. ahr1 directed the growth of its primary root towards the source of higher water availability and developed an extensive root system over time. This phenotype was intensified in the presence of abscisic acid and was not observed if ahr1 seedlings were grown in a water stress medium without a water potential gradient. In normal growth conditions, primary root growth and root branching of ahr1 were indistinguishable from those of the wild type (wt). The altered hydrotropic growth of ahr1 roots was confirmed when the water-rich source was placed at an angle of 45° from the gravity vector. In this system, roots of ahr1 seedlings grew downward and did not display hydrotropism; however, in the presence of cytokinins, they exhibited hydrotropism like those of the wt, indicating that cytokinins play a critical role in root hydrotropism. The ahr1 mutant represents a valuable genetic resource for the study of the effects of cytokinins in the differential growth of hydrotropism and control of lateral root formation during the hydrotropic response. [ABSTRACT FROM PUBLISHER]

Published

2012

44. A possible involvement of autophagy in amyloplast degradation in columella cells during hydrotropic response of Arabidopsis roots.

Author

Nakayama, Mayumi, Kaneko, Yasuko, Miyazawa, Yutaka, Fujii, Nobuharu, Higashitani, Nahoko, Wada, Shinya, Ishida, Hiroyuki, Yoshimoto, Kohki, Shirasu, Ken, Yamada, Kenji, Nishimura, Mikio, and Takahashi, Hideyuki

Subjects

SEEDLING roots, GEOTROPISM, TROPISMS, ARABIDOPSIS thaliana, AMYLOPLASTS

Abstract

Seedling roots display not only gravitropism but also hydrotropism, and the two tropisms interfere with one another. In Arabidopsis ( Arabidopsis thaliana) roots, amyloplasts in columella cells are rapidly degraded during the hydrotropic response. Degradation of amyloplasts involved in gravisensing enhances the hydrotropic response by reducing the gravitropic response. However, the mechanism by which amyloplasts are degraded in hydrotropically responding roots remains unknown. In this study, the mechanistic aspects of the degradation of amyloplasts in columella cells during hydrotropic response were investigated by analyzing organellar morphology, cell polarity and changes in gene expression. The results showed that hydrotropic stimulation or systemic water stress caused dramatic changes in organellar form and positioning in columella cells. Specifically, the columella cells of hydrotropically responding or water-stressed roots lost polarity in the distribution of the endoplasmic reticulum (ER), and showed accelerated vacuolization and nuclear movement. Analysis of ER-localized GFP showed that ER redistributed around the developed vacuoles. Cells often showed decomposing amyloplasts in autophagosome-like structures. Both hydrotropic stimulation and water stress upregulated the expression of AtATG18a, which is required for autophagosome formation. Furthermore, analysis with GFP-AtATG8a revealed that both hydrotropic stimulation and water stress induced the formation of autophagosomes in the columella cells. In addition, expression of plastid marker, pt-GFP, in the columella cells dramatically decreased in response to both hydrotropic stimulation and water stress, but its decrease was much less in the autophagy mutant atg5. These results suggest that hydrotropic stimulation confers water stress in the roots, which triggers an autophagic response responsible for the degradation of amyloplasts in columella cells of Arabidopsis roots. [ABSTRACT FROM AUTHOR]

Published

2012

45. Novel QTLs for growth angle of seminal roots in wheat ( Triticum aestivum L.).

Author

Hamada, Alhosein, Nitta, Miyuki, Nasuda, Shuhei, Kato, Kenji, Fujita, Masaya, Matsunaka, Hitoshi, and Okumoto, Yutaka

Subjects

*WHEAT, *PLANT ecology, *PLANT-soil relationships, *PLANT roots, *PLANT chromosomes, *PLANT genetics

Abstract

Aims: Because plants cannot change their environmental circumstances by changing their location, they must instead adapt to a wide variety of environmental conditions, especially soil conditions. One of the most effective ways for a plant to adapt to a given soil condition is by modifying its root system architecture. We aim to identify the genetic factors controlling root growth angle, a trait that affects root system architecture. Methods: The present study consisted of a genetic analysis of the seminal root growth angle in wheat; the parental varieties of the doubled haploid lines (DHLs) used in this study exhibited significantly different root growth directions. Using the 'basket' method, the ratio of deep roots (DRR; the proportion of total roots with GA > 45 degrees) was observed for evaluating deep rooting. Results: We were able to identify novel quantitative trait loci (QTLs) controlling the gravitropic and hydrotropic responses of wheat roots. Moreover, we detected one QTL for seminal root number per seedling (RN) on chromosome 5A and two QTLs for seminal root elongation rate (ER) on chromosomes 5D and 7D. Conclusions: Gravitropic and hydrotropic responses of wheat roots, which play a significant role in establishing root system architecture, are controlled by independent genetic factors. [ABSTRACT FROM AUTHOR]

Published

2012

46. Effects of streamflow variability on the vertical root density distribution of willow cutting experiments

Author

Pasquale, N., Perona, P., Francis, R., and Burlando, P.

Subjects

*STREAMFLOW, *GLOBAL environmental change, *WATER table, *PLANT biomass, *RIPARIAN plants, *PLANT development, *STREAM measurements, *SALIX alba

Abstract

Abstract: The use of riparian tree cuttings for river rehabilitation relies on a good understanding of cutting survival and growth responses to environmental variables. A series of experiments aimed at studying the effects of water table fluctuation induced by streamflow variability on the development of below-ground biomass of riparian tree cuttings was performed on the Thur River (Switzerland). White willow (Salix alba) cuttings were installed in gravel bar plots at various locations to develop an understanding of how topography and flow variability control cutting root development strategies, which in turn can lead to observed different vertical root density distributions in response to varying forms of tropism. In particular, we show that the transient root growth dynamics, eventually create a distribution reflecting the hydrologic conditions experienced towards the end of the growing season. A scaling relationship is presented that is useful to predict the expected depth with the highest root density as a function of soil topography and river discharge statistics. The results have implications for predicting cutting survival and growth, along with a corresponding strengthening of the alluvial sediment, in different flow regimes. This approach is therefore useful to incorporate in morphodynamic models covering the ecological and hydraulics responses of below-ground biomass to floods. [Copyright &y& Elsevier]

Published

2012

47. MIZ1, an essential protein for root hydrotropism, is associated with the cytoplasmic face of the endoplasmic reticulum membrane in Arabidopsis root cells

Author

Yamazaki, Tomokazu, Miyazawa, Yutaka, Kobayashi, Akie, Moriwaki, Teppei, Fujii, Nobuharu, and Takahashi, Hideyuki

Subjects

*HYDROTROPISM, *PLANT roots, *CYTOPLASM, *ENDOPLASMIC reticulum, *ARABIDOPSIS, *PLANT cells & tissues, *PLANT proteins, *GENE expression in plants

Abstract

Abstract: MIZ1 is encoded by a gene essential for root hydrotropism in Arabidopsis. To characterize the property of MIZ1, we used transgenic plants expressing GFP-tagged MIZ1 (MIZ1-GFP) and mutant MIZ1 (MIZ1G235E-GFP) in a miz1-1 mutant. Although both chimeric genes were transcribed, the translational products of MIZ1G235E-GFP did not accumulate in roots. Moreover, MIZ1-GFP complemented the mutant phenotype but not MIZ1G235E-GFP. The signal corresponding to MIZ1-GFP was detected at high levels in cortical cells and lateral root cap cells and accumulated in compartments in cortical cells. MIZ1-GFP was fractionated into a soluble protein fraction and an endoplasmic reticulum (ER) membrane fraction, where it was bound to the surface of the ER membrane at the cytosolic side. [Copyright &y& Elsevier]

Published

2012

48. Hormonal Regulation of Lateral Root Development in Arabidopsis Modulated by MIZ1 and Requirement of GNOM Activity for MIZ1 Function.

Author

Moriwaki, Teppei, Miyazawa, Yutaka, Kobayashi, Akie, Uchida, Mayumi, Watanabe, Chiaki, Fujii, Nobuharu, and Takahashi, Hideyuki

Subjects

*PLANT development, *PLANT hormones, *ROOT formation, *HYDROTROPISM, *GENE expression, *AUXIN, *CYTOKININS, *ARABIDOPSIS thaliana

Abstract

Plant organ development is important for adaptation to a changing environment. Genetic and physiological studies have revealed that plant hormones play key roles in lateral root formation. In this study, we show that MIZU-KUSSEI1 (MIZ1), which was identified originally as a regulator of hydrotropism, functions as a novel regulator of hormonally mediated lateral root development. Overexpression of MIZ1 (MIZ1OE) in roots resulted in a reduced number of lateral roots being formed; however, this defect could be recovered with the application of auxin. Indole-3-acetic acid quantification analyses showed that free indole-3-acetic acid levels decreased in MIZ1OE roots, which indicates that alteration of auxin level is critical for the inhibition of lateral root formation in MIZ1OE plants. In addition, MIZ1 negatively regulates cytokinin sensitivity on r development. Application of cytokinin strongly induced the localization of MIZl-green fluorescent protein to lateral root primordia, which suggests that the inhibition of lateral root development by MIZ1 occurs downstream of cytokinin signaling. Surprisingly, miz2, a weak allele of gnom, suppressed developmental defects in MIZ1OE plants. Taken together, these re suggest that MIZ1 plays a role in lateral root development by maintaining auxin levels and that its function requires GNOM activity. These data provide a molecular framework for auxin-dependent organ development in Arabidopsis (Arabidopsis thaliana). [ABSTRACT FROM AUTHOR]

Published

2011

49. New spectrophotometric estimation of indomethacin capsules with niacinamide as hydrotropic solubilizing agent.

Author

Maheshwari, R. K., Rathore, Amit, Agrawal, Archana, and Gupta, Megha A.

Subjects

*SPECTROPHOTOMETRY, *INDOMETHACIN, *PHARMACEUTICAL encapsulation, *NICOTINAMIDE, *HYDROTROPISM, *SOLUBILIZATION, *INTERMOLECULAR forces

Abstract

Background: Hydrotropic solubilization process involves cooperative intermolecular interaction with several balancing molecular forces, rather than either a specific complexation event or a process dominated by a medium effect, such as co-solvency or salting-in. Materials and Methods: In the present investigation, hydrotropic solution of 2 M niacinamide was employed as the solubilizing agent to solubilize the poorly water-soluble drug, indomethacin, from the capsule dosage form for spectrophotometric determination in ultraviolet region. Results: Hydrotropic agent used did not interfere in the spectrophotometric analysis. In preliminary solubility studies, it was found that there was more than fivefold enhancement in the aqueous solubility of indomethacin (poorly water-soluble drug) in 2 M niacinamide solution as compared to its aqueous solubility at 28 ± 1°C. Conclusion: The proposed method is new, simple, safe, environmentally friendly, economic, accurate and cost-effective and can be successfully employed in routine analysis. [ABSTRACT FROM AUTHOR]

Published

2011

50. Mixed Hydrotropy: Novel Science of Solubility Enhancement.

Author

Maheshwari, R. K. and Jagwani, Y.

Subjects

*HYDROTROPISM, *DRUG solubility, *FUROSEMIDE, *DRUG tablets, *DRUG bioavailability, *MEDICAL emergencies, *SODIUM benzoate

Abstract

Conventional furosemide tablets are practically insoluble in water, have slow onset of action (45-60 min) and poor bioavailability (39-53%), and therefore cannot be given in emergency clinical situations like hypertension or pulmonary edema. So purpose of research was to provide a fast dissolving oral dosage form of furosemide, which can provide quick onset of action by using concept of mixed hydrotropy. Initially solubility of furosemide was determined individually in 4 hydrotropic agents namely urea, sodium acetate, sodium benzoate, sodium citrate at concentration of 10, 20, 30 and 40% w/v solutions using purified water as solvent. Highest solubility was obtained in 40% sodium benzoate solution. Then different combinations of 2, 3 and 4 hydrotropic agents in different ratios were used to determine solubility, so that total concentration of hydrotropic agents was always 40%. Highest solubility was obtained in solution of urea+sodium benzoate+sodium citrate at optimum ratio of 15:20:5. This optimized combination was utilized in preparing solid dispersions by common solvent technique using distilled water as solvent. Solid dispersions were evaluated for flow properties, XRD, DSC, SEM and were also compressed to form tablets. Dissolution studies of conventional and prepared tablets were done using USP Type II apparatus. It was concluded that the concept of mixed hydrotropic solid dispersion is novel, safe and cost-effective technique for enhancing bioavailability of poorly water-soluble drugs by dissolving drug in non-ionized form. The magical enhancement in solubility of furosemide is clear indication of its potential to be used in future for other poorly water-soluble drugs in which low bioavailability is major concern. [ABSTRACT FROM AUTHOR]

Published

2011