Effect of silver nanoparticles on the standard soil arthropod Folsomia candida (Collembola) and the eukaryote model organism Saccharomyces cerevisiae

Sillapawattana, Panwad; Gruhlke, Martin C. H.; Schäffer, Andreas

doi:10.1186/s12302-016-0095-4

Cited by 19 publications

(21 citation statements)

References 41 publications

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“…In addition, in fission yeast, the toxic effects of AgNPs are attributed to the generation of ROS through the release of Ag ions inside the cells internalizing AgNPs 34. Consistent with our results, no increase in ROS production in S. cerevisiae BY4741 treated with 4–100 μg/mL PVP-coated AgNPs,15 and a similar effect of AgNPs on the growth of wild-type and single-gene deletion mutants of S. cerevisiae defective in oxidative stress defense (yap1∆, sod1∆, or sod2∆) have been reported.15 However, Sillapawattana et al observed increased ROS production in S. cerevisiae BY4742 and more prominent growth suppression in ctt1, sod2 , or gsh2 deletion mutants compared to wild type when treated with AgNPs 35. Of note, the discordance of our results with those of Sillapawattana et al may be related to the difference in S. cerevisiae strains and culture conditions.…”

Section: Discussionmentioning

confidence: 85%

Silver nanoparticles induce reactive oxygen species-mediated cell cycle delay and synergistic cytotoxicity with 3-bromopyruvate in Candida albicans, but not in Saccharomyces cerevisiae

Lee

Yun

et al. 2019

IJN

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Background: Silver nanoparticles (AgNPs) inhibit the proliferation of various fungi; however, their mechanisms of action remain poorly understood. To better understand the inhibitory mechanisms, we focused on the early events elicited by 5 nm AgNPs in pathogenic Candida albicans and non-pathogenic Saccharomyces cerevisiae. Methods: The effect of 5 nm and 100 nm AgNPs on fungus cell proliferation was analyzed by growth kinetics monitoring and spot assay. We examined cell cycle progression, reactive oxygen species (ROS) production, and cell death using flow cytometry. Glucose uptake was assessed using tritium-labeled 2-deoxyglucose. Results: The growth of both C. albicans and S. cerevisiae was suppressed by treatment with 5 nm AgNPs but not with 100 nm AgNPs. In addition, 5 nm AgNPs induced cell cycle arrest and a reduction in glucose uptake in both fungi after 30 minutes of culture in a dose-dependent manner ( P <0.05). However, in C. albicans only, an increase in ROS production was detected after exposure to 5 nm AgNPs. Concordantly, an ROS scavenger blocked the effect of 5 nm AgNPs on the cell cycle and glucose uptake in C. albicans only. Furthermore, the growth-inhibition effect of 5 nm AgNPs was not greater in S. cerevisiae mutant strains deficient in oxidative stress response genes than it was in wild type. Finally, 5 nm AgNPs together with a glycolysis inhibitor, 3-bromopyruvate, synergistically enhanced cell death in C. albicans ( P <0.05) but not in S. cerevisiae . Conclusion: AgNPs exhibit antifungal activity in a manner that may or may not be ROS dependent, according to the fungal species. The combination of AgNPs with 3-bromopyruvate may be more useful against infection with C. albicans .

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Section: Discussionmentioning

confidence: 85%

Silver nanoparticles induce reactive oxygen species-mediated cell cycle delay and synergistic cytotoxicity with 3-bromopyruvate in Candida albicans, but not in Saccharomyces cerevisiae

Lee

Yun

et al. 2019

IJN

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“…Glutathione reductase (GR) and GST act in concert with the antioxidant compound GSH and play major roles in mediating the tolerance of a P. aeruginosa strain to various herbicides [78]. Similarly, Folsomia candida exposed to AgNPs displayed decreased levels of GSH and increased GST activity [79]. Exposure of P. putida to environmentally relevant concentrations of AgNPs caused ROS production, glutathione depletion, and inactivation of the antioxidant enzymes superoxide dismutase, catalase, and glutathione reductase [72].…”

Section: Resultsmentioning

confidence: 99%

Effects of Silver Nanoparticles on Multiple Drug-Resistant Strains of Staphylococcus aureus and Pseudomonas aeruginosa from Mastitis-Infected Goats: An Alternative Approach for Antimicrobial Therapy

Yuan

Peng

Gurunathan

2017

IJMS

257

177

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Recently, silver nanoparticles (AgNPs) have been widely used in various applications as antimicrobial agents, anticancer, diagnostics, biomarkers, cell labels, and drug delivery systems for the treatment of various diseases. Microorganisms generally acquire resistance to antibiotics through the course of antibacterial therapy. Multi-drug resistance (MDR) has become a growing problem in the treatment of infectious diseases, and the widespread use of broad-spectrum antibiotics has resulted in the development of antibiotic resistance by numerous human and animal bacterial pathogens. As a result, an increasing number of microorganisms are resistant to multiple antibiotics causing continuing economic losses in dairy farming. Therefore, there is an urgent need for the development of alternative, cost-effective, and efficient antimicrobial agents that overcome antimicrobial resistance. Here, AgNPs synthesized using the bio-molecule quercetin were characterized using various analytical techniques. The synthesized AgNPs were highly spherical in shape and had an average size of 11 nm. We evaluated the efficacy of synthesized AgNPs against two MDR pathogenic bacteria, namely, Pseudomonas aeruginosa and Staphylococcus aureus, which were isolated from milk samples produced by mastitis-infected goats. The minimum inhibitory concentrations (MICs) of AgNPs against P. aeruginosa and S. aureus were found to be 1 and 2 μg/mL, respectively. Our findings suggest that AgNPs exert antibacterial effects in a dose- and time-dependent manner. Results from the present study demonstrate that the antibacterial activity of AgNPs is due to the generation of reactive oxygen species (ROS), malondialdehyde (MDA), and leakage of proteins and sugars in bacterial cells. Results of the present study showed that AgNP-treated bacteria had significantly lower lactate dehydrogenase activity (LDH) and lower adenosine triphosphate (ATP) levels compared to the control. Furthermore, AgNP-treated bacteria showed downregulated expression of glutathione (GSH), upregulation of glutathione S-transferase (GST), and downregulation of both superoxide dismutase (SOD) and catalase (CAT). These physiological and biochemical measurements were consistently observed in AgNP-treated bacteria, thereby suggesting that AgNPs can induce bacterial cell death. Thus, the above results represent conclusive findings on the mechanism of action of AgNPs against different types of bacteria. This study also demonstrates the promising use of nanoparticles as antibacterial agents for use in the biotechnology and biomedical industry. Furthermore, this study is the first to propose the mode of action of AgNPs against MDR pathogens isolated from goats infected with subclinical mastitis.

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“…Similarly, Sillapawattana et al (2016) Similar to the evaluations carried out with the microfauna, for the meso and macrofauna, it was observed that there is an effect of the NPs on the abundance and diversity of soils. However, in some cases with contradictory results and again, it is suggested that the adverse effects depend on the type of organisms to be evaluated, methods of application of the NPs, doses and the physical and chemical properties of the soil.…”

Section: Negative Effects Of Nps On Soil Organisms (Mesofauna and Mmentioning

confidence: 52%

“…In agriculture, ENP have been designed for reducing the population of arthropods or pathogens (Dubey & Mailapalli, 2016), increasing the control of diseases or weeds (Duhan et al, 2017), or improving the growth rates of crops with environmental benefits or economic profits (Liu, Zhang, & Lal, 2016). In contrast, it has also been discussed the adverse effects of ENP on soil organ-isms´diversity and abundance Wang, Shu, Zhang, & Youbin, 2017 such as fungus (Duhan et al, 2017), collembola (McKee et al, 2017Sillapawattana, Gruhlke, & Schäffer, 2016;Topuz & van Gestel, 2017), isopods (Malev et al, 2017), annelids (Brami, Glover, Butt, & Lowe, 2017;Jesmer, Velicogna, Schwertfeger, Scroggins, & Princz, 2017;Patricia et al, 2017;Romero-Freire, Lofts, Peinado, & van Gestel, 2017), as well as on the symbiotic association of bacteria and plants (Cao, Fen, Lin, & Wang, 2016). The toxic effects of ENP regarding their bioaccumulation and persistence have also been reported on organisms of different trophic levels (Chae, Kim, & An, 2016).…”

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confidence: 99%

Effect of engineered nanoparticles on soil biota: Do they improve the soil quality and crop production or jeopardize them?

et al. 2020

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Nanoscience and nanotechnology have been shown to have the capacity to help study, manipulation,design, and synthesis of new nano-sized materials to manufacture new products with desirable features never seen before. The unique properties of materials at nanoscale opens an excellent possibility for nanotechnology to be used in soil environmental remediation, and water, and air decontamination. In crop management, nanomaterials are used to regulate the controlled release of nutrients, fertilizers, and pesticides. However, it is not only necessary to expose the positive effects by the application of the nanomaterials but also to demonstrate the impacts on soil and nontarget organisms (plants, mesofauna, macrofauna, and soil microbiota). In this context, pieces of evidence on the adverse effects of engineered nanoparticles (ENP) on the physicochemical and biological properties of soils are discussed in this paper. We have found a diversity of contradictory results. The summaries, findings, and conclusions of most of the investigations support the need to understand the biological or physicochemical transformation and transport of ENP in soil, and in the plant-organism relationship. Better understanding regarding the soil biota coupled with the ecological ENP behavior could ensure the safe use of ENP. Nanomaterials can change the physicochemical and biological properties of the soils; consequently, long-term in situ field trials are required, and meanwhile, land-application of nanomaterials should be limited to scientific experiments to fill knowledge gaps to not jeopardize the global food production or the environment and worldwide human health.

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Effect of silver nanoparticles on the standard soil arthropod Folsomia candida (Collembola) and the eukaryote model organism Saccharomyces cerevisiae

Cited by 19 publications

References 41 publications

<p>Silver nanoparticles induce reactive oxygen species-mediated cell cycle delay and synergistic cytotoxicity with 3-bromopyruvate in <em>Candida</em> <em>albicans</em>, but not in <em>Saccharomyces</em> <em>cerevisiae</em></p>

<p>Silver nanoparticles induce reactive oxygen species-mediated cell cycle delay and synergistic cytotoxicity with 3-bromopyruvate in <em>Candida</em> <em>albicans</em>, but not in <em>Saccharomyces</em> <em>cerevisiae</em></p>

Effects of Silver Nanoparticles on Multiple Drug-Resistant Strains of Staphylococcus aureus and Pseudomonas aeruginosa from Mastitis-Infected Goats: An Alternative Approach for Antimicrobial Therapy

Effect of engineered nanoparticles on soil biota: Do they improve the soil quality and crop production or jeopardize them?

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