Physiological and biochemical response of soil-grown barley (Hordeum vulgare L.) to cerium oxide nanoparticles

Rico, Cyren M.; Barrios, Ana C.; Tan, Wenjuan; Rubenecia, Rosnah; Lee, Sang C hul; Varela-Ramı́rez, Armando; Peralta-Videa, José R.; Gardea‐Torresdey, Jorge L.

doi:10.1007/s11356-015-4243-y

Cited by 159 publications

(87 citation statements)

References 30 publications

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“…In another study, Rico et al (2015) showed that the chlorophyll content in barley leaves was increased at 125-500 mg/kg nano-CeO 2 , similar to our observations in LOMS leaves. The slight increase in the chlorophyll a (Fig.…”

Section: Impact Of Nano-ceo 2 On Plant Growthsupporting

confidence: 90%

Soil organic matter influences cerium translocation and physiological processes in kidney bean plants exposed to cerium oxide nanoparticles

Majumdar

Peralta-Videa

Trujillo-Reyes

et al. 2016

Science of The Total Environment

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Soil organic matter plays a major role in determining the fate of the engineered nanomaterials (ENMs) in the soil matrix and effects on the residing plants. In this study, kidney bean plants were grown in soils varying in organic matter content and amended with 0-500mg/kg cerium oxide nanoparticles (nano-CeO2) under greenhouse condition. After 52days of exposure, cerium accumulation in tissues, plant growth and physiological parameters including photosynthetic pigments (chlorophylls and carotenoids), net photosynthesis rate, transpiration rate, and stomatal conductance were recorded. Additionally, catalase and ascorbate peroxidase activities were measured to evaluate oxidative stress in the tissues. The translocation factor of cerium in the nano-CeO2 exposed plants grown in organic matter enriched soil (OMES) was twice as the plants grown in low organic matter soil (LOMS). Although the leaf cover area increased by 65-111% with increasing nano-CeO2 concentration in LOMS, the effect on the physiological processes were inconsequential. In OMES leaves, exposure to 62.5-250mg/kg nano-CeO2 led to an enhancement in the transpiration rate and stomatal conductance, but to a simultaneous decrease in carotenoid contents by 25-28%. Chlorophyll a in the OMES leaves also decreased by 27 and 18% on exposure to 125 and 250mg/kg nano-CeO2. In addition, catalase activity increased in LOMS stems, and ascorbate peroxidase increased in OMES leaves of nano-CeO2 exposed plants, with respect to control. Thus, this study provides clear evidence that the properties of the complex soil matrix play decisive roles in determining the fate, bioavailability, and biological transport of ENMs in the environment.

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Section: Impact Of Nano-ceo 2 On Plant Growthsupporting

confidence: 90%

Soil organic matter influences cerium translocation and physiological processes in kidney bean plants exposed to cerium oxide nanoparticles

Majumdar

Peralta-Videa

Trujillo-Reyes

et al. 2016

Science of The Total Environment

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“…The accumulation of nanomaterials in plants has been shown to increase the shoot length, chlorophyll b content, number of adventitious roots, and fresh root weight of rice seedlings [13]. A 500 mg/kg CeO 2 treatment was shown to increase the plant height, chlorophyll content, and biomass of barley without any toxic effects [14]. GO treatments decreased the damage caused by Cu stress by neutralizing the effects of Cu on nutrient accumulation in Lemna minor [3], and TiO 2 nanoparticles have been reported to improve phosphorus uptake and improving plant growth [15].…”

Section: Plant Responses To Nanomaterials Depends On Multiple Factorsmentioning

confidence: 99%

Graphene oxide and indole-3-acetic acid cotreatment regulates the root growth of Brassica napus L. via multiple phytohormone pathways

Xie

Fan

et al. 2020

BMC Plant Biol

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Background: Studies have indicated that graphene oxide (GO) could regulated Brassica napus L. root growth via abscisic acid (ABA) and indole-3-acetic acid (IAA). To study the mechanism and interaction between GO and IAA further, B. napus L (Zhongshuang No. 9) seedlings were treated with GO and IAA accordance with a two factor completely randomized design. Results: GO and IAA cotreatment significantly regulated the root length, number of adventitious roots, and contents of IAA, cytokinin (CTK) and ABA. Treatment with 25 mg/L GO alone or IAA (> 0.5 mg/L) inhibited root development. IAA cotreatment enhanced the inhibitory role of GO, and the inhibition was strengthened with increased in IAA concentration. GO treatments caused oxidative stress in the plants. The ABA and CTK contents decreased; however, the IAA and gibberellin (GA) contents first increased but then decreased with increasing IAA concentration when IAA was combined with GO compared with GO alone. The 9-cis-epoxycarotenoid dioxygenase (NCED) transcript level strongly increased when the plants were treated with GO. However, the NCED transcript level and ABA concentration gradually decreased with increasing IAA concentration under GO and IAA cotreatment. GO treatments decreased the transcript abundance of steroid 5-alpha-reductase (DET2) and isochorismate synthase 1 (ICS), which are associated with brassinolide (BR) and salicylic acid (SA) biosynthesis, but increased the transcript abundance of brassinosteroid insensitive 1-associated receptor kinase 1 (BAK1), cam-binding protein 60-like G (CBP60) and calmodulin binding protein-like protein 1, which are associated with BR and SA biosynthesis. Last, GO treatment increased the transcript abundance of 1-aminocyclopropane-1-carboxylic acid synthase 2 (ACS2), which is associated with the ethylene (ETH) pathway.(Continued on next page) Conclusions: Treatment with 25 mg/L GO or IAA (> 0.5 mg/L) inhibited root development. However, IAA and GO cotreatment enhanced the inhibitory role of GO, and this inhibition was strengthened with increased IAA concentration. IAA is a key factor in the response of B. napus L to GO and the responses of B. napus to GO and IAA cotreatment involved in multiple pathways, including those involving ABA, IAA, GA, CTK, BR, SA. Specifically, GO and IAA cotreatment affected the GA content in the modulation of B. napus root growth.

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“…The overall process will eventually trigger oxidative damage and ultimately cell death (Sharma et al, 2012). There are several works reporting that ENMs have a tendency to induce ROS generation Navarro et al, 2008;Lee et al, 2010;Rico et al, 2015aRico et al, , 2015b. Other reports show results pertaining to genetic, hormonal, and other biomolecule disruptions (Atha et al, 2012;Zhao and Liu, 2012).…”

Section: Reactive Oxygen Species (Ros) Production and Other Biochemicmentioning

confidence: 99%

Lessons learned: Are engineered nanomaterials toxic to terrestrial plants?

Reddy

Hernández-Viezcas

Peralta-Videa

et al. 2016

Science of The Total Environment

148

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The expansion of nanotechnology and its ubiquitous applications has fostered unavoidable interaction between engineered nanomaterials (ENMs) and plants. Recent research has shown ambiguous results with regard to the impact of ENMs in plants. On one hand, there are reports that show hazardous effects, while on the other hand, some reports highlight positive effects. This uncertainty whether the ENMs are primarily hazardous or whether they have a potential for propitious impact on plants, has raised questions in the scientific community. In this review, we tried to demystify this ambiguity by citing various exposure studies of different ENMs (nano-Ag, nano-Au, nano-Si, nano-CeO2, nano-TiO2, nano-CuO, nano-ZnO, and CNTs, among others) and their effects on various groups of plant families. After scrutinizing the most recent literature, it seems that the divergence in the research results may be possibly attributed to multiple factors such as ENM properties, plant species, soil dynamics, and soil microbial community. The analysis of the literature also suggests that there is a knowledge gap on the effects of ENMs towards changes in color, texture, shape, and nutritional aspects on ENM exposed plants.

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Physiological and biochemical response of soil-grown barley (Hordeum vulgare L.) to cerium oxide nanoparticles

Cited by 159 publications

References 30 publications

Soil organic matter influences cerium translocation and physiological processes in kidney bean plants exposed to cerium oxide nanoparticles

Soil organic matter influences cerium translocation and physiological processes in kidney bean plants exposed to cerium oxide nanoparticles

Graphene oxide and indole-3-acetic acid cotreatment regulates the root growth of Brassica napus L. via multiple phytohormone pathways

Lessons learned: Are engineered nanomaterials toxic to terrestrial plants?

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