Fluoride absorption, transportation and tolerance mechanism in <i>Camellia sinensis</i>, and its bioavailability and health risk assessment: a systematic review

Peng, Chuanyi; Xu, Xuefeng; Ren, Yin‐feng; Niu, Huiliang; Yang, Yong; Hou, Ruyan; Wan, Xiaochun; Cai, Hao

doi:10.1002/jsfa.10640

Cited by 28 publications

(3 citation statements)

References 106 publications

(205 reference statements)

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“…The majority of F is quickly transferred as F/F-Al complexes to the leaf cell walls and vacuole across the xylem. The results suggest that tea plants detoxify F and aluminum (Al) simultaneously through cell wall accumulation, vacuole compartmentalization, and F-Al complexes, which may be a mechanism of F tolerance that enables tea to withstand higher F concentrations than most plants (Peng et al, 2020;Luo et al, 2022).…”

Section: Figurementioning

confidence: 99%

The role of plant growth promoting rhizobacteria in strengthening plant resistance to fluoride toxicity: a review

Singh,

Yadav,

Gautam

et al. 2023

Front. Microbiol.

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A wide variety of bacteria are present in soil but in rhizospheric area, the majority of microbes helps plant in defending diseases and facilitate nutrient uptake. These microorganisms are supported by plants and they are known as plant growth-promoting rhizobacteria (PGPR). The PGPRs have the potential to replace chemical fertilizers in a way that is more advantageous for the environment. Fluoride (F) is one of the highly escalating, naturally present contaminants that can be hazardous for PGPRs because of its antibacterial capacity. The interactions of F with different bacterial species in groundwater systems are still not well understood. However, the interaction of PGPR with plants in the rhizosphere region reduces the detrimental effects of pollutants and increases plants’ ability to endure abiotic stress. Many studies reveal that PGPRs have developed F defense mechanisms, which include efflux pumps, Intracellular sequestration, enzyme modifications, enhanced DNA repair mechanism, detoxification enzymes, ion transporter/antiporters, F riboswitches, and genetic mutations. These resistance characteristics are frequently discovered by isolating PGPRs from high F-contaminated areas or by exposing cells to fluoride in laboratory conditions. Numerous studies have identified F-resistant microorganisms that possess additional F transporters and duplicates of the well-known targets of F. Plants are prone to F accumulation despite the soil’s low F content, which may negatively affect their growth and development. PGPRs can be used as efficient F bioremediators for the soil environment. Environmental biotechnology focuses on creating genetically modified rhizobacteria that can degrade F contaminants over time. The present review focuses on a thorough systemic analysis of contemporary biotechnological techniques, such as gene editing and manipulation methods, for improving plant-microbe interactions for F remediation and suggests the importance of PGPRs in improving soil health and reducing the detrimental effects of F toxicity. The most recent developments in the realm of microbial assistance in the treatment of F-contaminated environments are also highlighted.

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Section: Figurementioning

confidence: 99%

The role of plant growth promoting rhizobacteria in strengthening plant resistance to fluoride toxicity: a review

Singh,

Yadav,

Gautam

et al. 2023

Front. Microbiol.

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“…From the study of Zhang et al [190], it was observed that anion blockers inhibited the uptake of F − ions in tea plants (Camellia sinensis), and it was suggested that anion channels might play an essential role in the absorption of F − ions for the tea plants. Tea plants tolerate higher fluoride levels than other plants [218]. It was found that most of the F − ions uptaken by the roots of tea plants were readily transported to the leaves through the xylem [190].…”

Section: Fluoride Uptake and Bioaccumulation In Plants And Foodsmentioning

confidence: 99%

Bioaccumulation of Fluoride in Plants and Its Microbially Assisted Remediation: A Review of Biological Processes and Technological Performance

et al. 2021

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Fluoride is widely found in soil–water systems due to anthropogenic and geogenic activities that affect millions worldwide. Fluoride ingestion results in chronic and acute toxicity, including skeletal and dental fluorosis, neurological damage, and bone softening in humans. Therefore, this review paper summarizes biological processes for fluoride remediation, i.e., bioaccumulation in plants and microbially assisted systems. Bioremediation approaches for fluoride removal have recently gained prominence in removing fluoride ions. Plants are vulnerable to fluoride accumulation in soil, and their growth and development can be negatively affected, even with low fluoride content in the soil. The microbial bioremediation processes involve bioaccumulation, biotransformation, and biosorption. Bacterial, fungal, and algal biomass are ecologically efficient bioremediators. Most bioremediation techniques are laboratory-scale based on contaminated solutions; however, treatment of fluoride-contaminated wastewater at an industrial scale is yet to be investigated. Therefore, this review recommends the practical applicability and sustainability of microbial bioremediation of fluoride in different environments.

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“…Fluorine is a major groundwater and soil pollutant detected across major rice cultivating nations, such as China, India, Pakistan, Bangladesh, Indonesia and Myanmar (Mukherjee and Singh 2020). Alarming level of groundwater fluoride pollution occurs due to unplanned mining of fluoride-rich minerals, such as cryolite, appatite, etc., climatic weathering and edaphic ion-exchange processes (Peng et al 2020). Susheela (1999) reported fluoride level to be as high as 48 mg L −1 in the groundwater across Indian states.…”

Section: Introductionmentioning

confidence: 99%

Functional and molecular characterization of fluoride exporter (FEX) from rice and its constitutive overexpression in Nicotiana benthamiana to promote fluoride tolerance

Banerjee

Roychoudhury

2021

Plant Cell Rep

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Fluoride absorption, transportation and tolerance mechanism in Camellia sinensis, and its bioavailability and health risk assessment: a systematic review

Cited by 28 publications

References 106 publications

The role of plant growth promoting rhizobacteria in strengthening plant resistance to fluoride toxicity: a review

The role of plant growth promoting rhizobacteria in strengthening plant resistance to fluoride toxicity: a review

Bioaccumulation of Fluoride in Plants and Its Microbially Assisted Remediation: A Review of Biological Processes and Technological Performance

Functional and molecular characterization of fluoride exporter (FEX) from rice and its constitutive overexpression in Nicotiana benthamiana to promote fluoride tolerance

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