Root-growth Characteristics Contributing to Genotypic Variation in Nitrogen Efficiency of Bottle Gourd and Rootstock Potential for Watermelon

In this study, two hydroponic experiments were conducted in nutrient solution growth system. Experiments were conducted in growth chamber of Erciyes University, Agricultural Faculty in Kayseri, Turkey. In the first experiment, 10 local Turkish bottle gourd genotypes and two commercial watermelon cultivars were screened under 2 N doses (0.3 mM and 3.0 mM N) in RBD design with three replications for six weeks. In the second experiment, four genotypes (N-efficient: 70-07 and 07-45, N-inefficient: 35-10 and 45-07) were selected and used as rootstock for grafting with N-inefficient watermelon cultivar (Crimson Sweet) under 2 N doses. The grafted N-efficient gourd genotypes (07-45 and 70-07) significantly contributed to growth and biomass production of the N-inefficient watermelon plants as compared to non-grafted control plants and thus showed a higher rootstock potential for watermelon. The N-efficiency of some gourd genotypes was associated with vigor root growth and active root system particularly at low N conditions. These traits could be useful characters to select ‘N-efficient’ bottle gourd rootstocks for sustainable agriculture in the future.

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Root-growth characteristics contributing to genotypic variation in nitrogen efficiency of oilseed rape

Journal of Plant Nutrition and Soil Science ◽

10.1002/jpln.201100301 ◽

2012 ◽

Vol 175 (3) ◽

pp. 489-498 ◽

Cited By ~ 22

Author(s):

Abdullah Ulas ◽

Gunda Schulte auf'm Erley ◽

Mahmoud Kamh ◽

Franz Wiesler ◽

Walter J. Horst

Keyword(s):

Root Growth ◽

Oilseed Rape ◽

Genotypic Variation ◽

Growth Characteristics ◽

Nitrogen Efficiency

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Root-growth Characteristics Contributing to Nitrogen Efficiency of Reciprocally Grafted Potatoes (Solanum tuberosum L.) Under Hyroponic Conditions

Gesunde Pflanzen ◽

10.1007/s10343-021-00560-8 ◽

2021 ◽

Author(s):

Firdes Ulas ◽

Halit Yetisir ◽

Abdullah Ulas

Keyword(s):

Solanum Tuberosum ◽

Root Growth ◽

Solanum Tuberosum L ◽

Growth Characteristics ◽

Nitrogen Efficiency

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Capturing in-field root system dynamics with the RootTracker

10.1101/2020.11.14.382002 ◽

2020 ◽

Author(s):

Jeffrey J. Aguilar ◽

Matt Moore ◽

Logan Johnson ◽

Rachel F. Greenhut ◽

Eric Rogers ◽

...

Keyword(s):

Root Growth ◽

System Dynamics ◽

Root System ◽

System Architecture ◽

Mechanical Stability ◽

Genotypic Variation ◽

Root Systems ◽

Root System Architecture ◽

Rapid Responses ◽

The Face

AbstractOptimizing root system architecture offers a promising approach to developing stress tolerant cultivars in the face of climate change, as root systems are critical for water and nutrient uptake as well as mechanical stability. However, breeding for optimal root system architecture has been hindered by the difficulty in measuring root growth in the field. Here, we describe a technology, the RootTracker (RT), which employs capacitance touch sensors to monitor in-field root growth over time. Configured in a cylindrical shutter-like fashion around a planted seed, 264 electrodes are individually charged multiple times over the course of an experiment. Signature changes in the measured capacitance and resistance readings indicate when a root has touched or grown close to an electrode. Using the RootTracker, we have measured root system dynamics of commercial maize hybrids growing in both typical Midwest field conditions and under different irrigation regimes. We observed rapid responses of root growth to water deficits and found evidence for a “priming response” in which an early water deficit causes more and deeper roots to grow at later time periods. There was genotypic variation among hybrid maize lines in their root growth in response to drought, indicating a potential to breed for root systems adapted for different environments.

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Root System Fibrosity of Sitka Spruce Transplants: Relationship with Root Growth Potential

Forestry An International Journal of Forest Research ◽

10.1093/forestry/63.1.1-a ◽

1990 ◽

Vol 63 (1) ◽

pp. 1-7 ◽

Cited By ~ 17

Author(s):

J. D. DEANS ◽

C. LUNDBERG ◽

M. G. R. CANNELL ◽

M. B. MURRAY ◽

L. J. SHEPPARD

Keyword(s):

Root Growth ◽

Root System ◽

Sitka Spruce ◽

Growth Potential ◽

Root Growth Potential

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Effects of Temperature on Root Morphology and Ectendomycorrhizal Development in Pinusresinosa Ait.

Canadian Journal of Forest Research ◽

10.1139/x75-024 ◽

1975 ◽

Vol 5 (2) ◽

pp. 171-175 ◽

Cited By ~ 5

Author(s):

Hugh E. Wilcox ◽

Ruth Ganmore-Neumann

Keyword(s):

Root Growth ◽

Root System ◽

Root Morphology ◽

Root Systems ◽

Second Order ◽

Root Temperature ◽

First Order ◽

Effects Of Temperature

Seedlings of Pinusresinosa were grown at root temperatures of 16, 21 and 27 °C, both aseptically and after inoculation with the ectendomycorrhizal fungus BDG-58. Growth after 3 months was significantly influenced by the presence of the fungus at all 3 temperatures. The influence of the fungus on root growth was obscured by the effects of root temperature on morphology. The root system at 16 and at 21 °C possessed many first-order laterals with numerous, well developed second-order branches, but those at 27 °C had only a few, relatively long, unbranched first-order laterals. Although the root systems of infected seedlings were larger, the fungus increased root growth in the same pattern as determined by the temperature.

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Regulation of lateral root development by shoot-sensed far-red light via HY5 is nitrate-dependent and involves the NRT2.1 nitrate transporter

10.1101/2021.01.31.428985 ◽

2021 ◽

Author(s):

Kasper van Gelderen ◽

Chiakai Kang ◽

Peijin Li ◽

Ronald Pierik

Keyword(s):

Root Growth ◽

Root System ◽

Lateral Root ◽

Environmental Changes ◽

Red Light ◽

Agar Plate ◽

Nitrate Transporter ◽

Loss Of Function ◽

Lateral Root Development ◽

Nitrate Signaling

AbstractPlants are very effective in responding to environmental changes during competition for light and nutrients. Low Red:Far-Red (low R:FR)-mediated neighbor detection allows plants to compete successfully with other plants for available light. This above-ground signal can also reduce lateral root growth by inhibiting lateral root emergence, a process that might help the plant invest resources in shoot growth. Nitrate is an essential nutrient for plant growth and Arabidopsis thaliana responds to low nitrate conditions by enhancing nutrient uptake and reducing lateral and main root growth. There are indications that low R:FR signaling and low nitrate signaling can affect each other. It is unknown which response is prioritized when low R:FR light- and low nitrate signaling co-occur. We investigated the effect of low nitrate conditions on the low R:FR response of the A. thaliana root system in agar plate media, combined with the application of supplemental Far-Red (FR) light to the shoot. We observed that under low nitrate conditions main and lateral root growth was reduced, but more importantly, that the response of the root system to low R:FR was suppressed. Consistently, a loss-of-function mutant of a nitrate transporter gene NRT2.1 lacked low R:FR-induced lateral root reduction and its root growth was hypersensitive to low nitrate. ELONGATED HYPOCOTYL5 (HY5) plays an important role in the root response to low R:FR and we found that it was less sensitive to low nitrate conditions with regards to lateral root growth. In addition, we found that low R:FR increases NRT2.1 expression and that low nitrate enhances HY5 expression. HY5 also affects NRT2.1 expression, however, it depended on the presence of ammonium in which direction this effect was. Replacing part of the nitrogen source with ammonium also removed the effect of low R:FR on the root system, showing that changes in nitrogen sources can be crucial for root plasticity. Together our results show that nitrate signaling can repress low R:FR responses and that this involves signaling via HY5 and NRT2.1.

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Contemporary Concepts of Root System Architecture of Urban Trees

Arboriculture & Urban Forestry ◽

10.48044/jauf.2010.020 ◽

2010 ◽

Vol 36 (4) ◽

pp. 149-159

Author(s):

Susan Day ◽

P. Eric Wiseman ◽

Sarah Dickinson ◽

J. Roger Harris

Keyword(s):

Built Environment ◽

Root Growth ◽

Root System ◽

Root Architecture ◽

Root Systems ◽

Growth Patterns ◽

Urban Trees ◽

Rooting Depth ◽

Similar Species ◽

Urban Settings

Knowledge of the extent and distribution of tree root systems is essential for managing trees in the built environment. Despite recent advances in root detection tools, published research on tree root architecture in urban settings has been limited and only partially synthesized. Root growth patterns of urban trees may differ considerably from similar species in forested or agricultural environments. This paper reviews literature documenting tree root growth in urban settings as well as literature addressing root architecture in nonurban settings that may contribute to present understanding of tree roots in built environments. Although tree species may have the genetic potential for generating deep root systems (>2 m), rooting depth in urban situations is frequently restricted by impenetrable or inhospitable soil layers or by underground infrastructure. Lateral root extent is likewise subject to restriction by dense soils under hardscape or by absence of irrigation in dry areas. By combining results of numerous studies, the authors of this paper estimated the radius of an unrestricted root system initially increases at a rate of approximately 38 to 1, compared to trunk diameter; however, this ratio likely considerably declines as trees mature. Roots are often irregularly distributed around the tree and may be influenced by cardinal direction, terrain, tree lean, or obstacles in the built environment. Buttress roots, tap roots, and other root types are also discussed.

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Imaging local soil kinematics during the first days of maize root growth in sand

Scientific Reports ◽

10.1038/s41598-021-01056-1 ◽

2021 ◽

Vol 11 (1) ◽

Author(s):

Floriana Anselmucci ◽

Edward Andò ◽

Gioacchino Viggiani ◽

Nicolas Lenoir ◽

Chloé Arson ◽

...

Keyword(s):

Plant Growth ◽

Root Growth ◽

Shear Strain ◽

Root System ◽

Capillary Rise ◽

Image Correlation ◽

Root Tip ◽

Soil System ◽

Local Soil ◽

Initial Soil

AbstractMaize seedlings are grown in Hostun sand with two different gradings and two different densities. The root-soil system is imaged daily for the first 8 days of plant growth with X-ray computed tomography. Segmentation, skeletonisation and digital image correlation techniques are used to analyse the evolution of the root system architecture, the displacement fields and the local strain fields due to plant growth in the soil. It is found that root thickness and root length density do not depend on the initial soil configuration. However, the depth of the root tip is strongly influenced by the initial soil density, and the number of laterals is impacted by grain size, which controls pore size, capillary rise and thus root access to water. Consequently, shorter root axes are observed in denser sand and fewer second order roots are observed in coarser sands. In all soil configurations tested, root growth induces shear strain in the soil around the root system, and locally, in the vicinity of the first order roots axis. Root-induced shear is accompanied by dilative volumetric strain close to the root body. Further away, the soil experiences dilation in denser sand and compaction in looser sand. These results suggest that the increase of porosity close to the roots can be caused by a mix of shear strain and steric exclusion.

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Root Morphology and Secretion of two subtropical tree species to NH4+-N and NO3–-N Deposition

10.21203/rs.3.rs-65378/v1 ◽

2020 ◽

Author(s):

Rui Zhang ◽

Yi Wang ◽

Zhichun Zhou

Keyword(s):

Root Growth ◽

Root System ◽

Root Morphology ◽

Tree Species ◽

Southern China ◽

N Deposition ◽

Fibrous Root ◽

Nitrogen And Phosphorus ◽

Root Absorption ◽

Tap Root

Abstract Background: Both NH4+ and NO3– are capable of greatly influencing plants’ growth and biomass. However, the belowground responses of subtropical trees to either NH4+ or NO3– deposition remain poorly understood. Here, we discuss how these two forms of N deposition can affect root development, and experimentally analyzed how they could impact nitrogen and phosphorus absorption in two types (broadleaved with a fibrous root system vs. conifer with a tap root system) of subtropical tree species. Results: In a greenhouse in southern China, 1-year-old S. superba and P. massoniana seedlings grown on P-limited and P-normal soil were treated with NaNO3 and NH4Cl solutions of 0, 80, and 200 kg N ha–1 year–1, corresponding to the control, N80, and N200 groups, respectively. Root phenotype characteristics and metabolism ability were measured after 8 months of growth. The results showed that the root morphology and physiology variables differed significantly between the two species under different N and P treatments. Although S. superba had a larger quantity of roots than P. massoniana, both its root growth rate and root absorption were respectively lower and weaker. N addition differentially affected root growth and activity as follows: (1) NO3–-N80 and NH4+-N80 increased root growth and activity of the two species, but NH4+-N80 led to thicker roots in S. superba; (2) NO3–-N200 and NH4+-N200 had inhibitory effects on the roots of P. massoniana, for which NH4+-N200 led to thinner and longer roots and even the death of some roots; and (3) NH4+-N could promote metabolic activity in thicker roots (> 1.5 mm) and the NO3–-N was found to stimulate activity in thinner roots (0.5–1.5 mm) in the fibrous root system having a larger quantity of roots, namely S. superba. By contrast, NO3–-N and NH4+-N had an opposite influence upon functioning in the tap root system with a slender root, namely P. massoniana. Conclusion: We conclude P. massoniana has a much higher root absorption efficiency; however, nitrogen deposition is more beneficial to the root growth of S. superba.

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Two Wheat Cultivars with Contrasting Post-Embryonic Root Biomass Differ in Shoot Re-Growth after Defoliation: Implications for Breeding Grazing Resilient Forages

Plants ◽

10.3390/plants8110470 ◽

2019 ◽

Vol 8 (11) ◽

pp. 470

Author(s):

Paez-Garcia ◽

Liao ◽

Blancaflor

Keyword(s):

Winter Wheat ◽

Root Growth ◽

Root System ◽

Aboveground Biomass ◽

Root Traits ◽

Shoot Biomass ◽

Wheat Cultivars ◽

Leaf Clipping ◽

The Impact ◽

Embryonic Root

The ability of forages to quickly resume aboveground growth after grazing is a trait that enables farmers to better manage their livestock for maximum profitability. Leaf removal impairs root growth. As a consequence of a deficient root system, shoot re-growth is inhibited leading to poor pasture performance. Despite the importance of roots for forage productivity, they have not been considered as breeding targets for improving grazing resilience due in large part to the lack of knowledge on the relationship between roots and aboveground biomass re-growth. Winter wheat (Triticum aestivum) is extensively used as forage source in temperate climates worldwide. Here, we investigated the impact of leaf clipping on specific root traits, and how these influence shoot re-growth in two winter wheat cultivars (i.e., Duster and Cheyenne) with contrasting root and shoot biomass. We found that root growth angle and post-embryonic root growth in both cultivars are strongly influenced by defoliation. We discovered that Duster, which had less post-embryonic roots before defoliation, reestablished its root system faster after leaf cutting compared with Cheyenne, which had a more extensive pre-defoliation post-embryonic root system. Rapid resumption of root growth in Duster after leaf clipping was associated with faster aboveground biomass re-growth even after shoot overcutting. Taken together, our results suggest that lower investments in the production of post-embryonic roots presents an important ideotype to consider when breeding for shoot re-growth vigor in dual purpose wheat.

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