Interaction of nanoparticles with proteins: relation to bio-reactivity of the nanoparticle

Saptarshi, Shruti R.; Duschl, Albert; Lopata, Andreas L.

doi:10.1186/1477-3155-11-26

Cited by 878 publications

(676 citation statements)

References 100 publications

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“…Additionally, the curved (spherical) surface of nanoparticles compared to planar surfaces provide extra flexibility and enhanced surface area to the adsorbed protein molecule. 39 In our study, spherical AgNPs were used, and our results showed a significant increase in the WBC, lymphocyte and granulocyte counts even at extremely low doses (2 mg/kg b.w.). This increase might be due to the spherical nature of the AgNPs inside the mice; this shape provided increased flexibility and an enhanced surface area to the adsorbed NP-PC proteins, resulting in an unwanted immune response even at very low doses.…”

Section: Discussionmentioning

confidence: 99%

“…37 This NP-PC formation is aided by several forces, such as hydrogen bonds, solvation forces, van der Waals interaction, and others. 38,39 Nanoparticles can also modify the structure and therefore, the function of the adsorbed proteins in NP-PCs, which thus alter the overall activity of the nanoparticles. This modification of the adsorbed proteins in NP-PCs may involve specific foldings, which may lead to a change in the conformation of the epitopes of the adsorbed protein.…”

Section: Discussionmentioning

confidence: 99%

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Immunomodulatory properties of silver nanoparticles contribute to anticancer strategy for murine fibrosarcoma

et al. 2015

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The use of nanotechnology in nanoparticle-based cancer therapeutics is gaining impetus due to the unique biophysical properties of nanoparticles at the quantum level. Silver nanoparticles (AgNPs) have been reported as one type of potent therapeutic nanoparticles. The present study is aimed to determine the effect of AgNPs in arresting the growth of a murine fibrosarcoma by a reductive mechanism. Initially, a bioavailability study showed that mouse serum albumin (MSA)-coated AgNPs have enhanced uptake; therefore, toxicity studies of AgNP-MSA at 10 different doses (1-10 mg/kg b.w.) were performed in LACA mice by measuring the complete blood count, lipid profile and histological parameters. The complete blood count, lipid profile and histological parameter results showed that the doses from 2 to 8 mg (IC 50 : 6.15 mg/kg b.w.) sequentially increased the count of leukocytes, lymphocytes and granulocytes, whereas the 9-and 10-mg doses showed conclusive toxicity. In an antitumor study, the incidence and size of fibrosarcoma were reduced or delayed when murine fibrosarcoma groups were treated by AgNP-MSA. Transmission electron micrographs showed that considerable uptake of AgNP-MSA by the sentinel immune cells associated with tumor tissue and a morphologically buckled structure of the immune cells containing AgNP-MSA. Because the toxicity studies revealed a relationship between AgNPs and immune function, the protumorigenic cytokines TNF-a, IL-6 and IL-1b were also assayed in AgNP-MSA-treated and non-treated fibrosarcoma groups, and these cytokines were found to be downregulated after treatment with AgNP-MSA. Cellular & Molecular Immunology

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Section: Discussionmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

Immunomodulatory properties of silver nanoparticles contribute to anticancer strategy for murine fibrosarcoma

et al. 2015

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“…This leads to conformational change in the protein [43]. Thus, the interaction of the nanoparticles with enzymes may be indirect and occurs via nanoparticle-protein corona and not at the bare nanoparticle surface [42]. As nature, size, shape, charge and hydrophobicity of proteins vary depending on plant species and their metabolites, the interactive effect of metabolites with nanoparticles would also be different.…”

Section: Interplay Of Concentration and Timementioning

confidence: 99%

“…An important factor in understanding the mechanism of nanoparticles-induced changes in nitrogenase is to take into account their interaction with proteins. The dispersion of nanoparticles in a biological milieu results in their surface being immediately enveloped by a complex layer of protein known as ''protein corona'' [41,42]. This adsorption of a protein on the surface of nanoparticles strongly depends on its nature, surface chemistry and physicochemical properties.…”

Section: Interplay Of Concentration and Timementioning

confidence: 99%

Effect of nano-zinc oxide on nitrogenase activity in legumes: an interplay of concentration and exposure time

2015

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Experiments were carried out to study the effect of zinc oxide nanoparticles (nano-ZnO) on nitrogenase activity in legumes. In the first experiment, nodulated roots of cluster bean, moth bean, green gram and cowpea were dipped in Hoagland solution containing 1.5 and 10 lg mL -1 of nano-ZnO for 24 h. Nitrogenase activity in cluster bean, green gram and cowpea roots increased after dipping in solution containing 1.5 lg mL -1 nano-ZnO, but decreased in roots dipped in solution containing 10 lg mL -1 nano-ZnO. However, in moth bean roots, nitrogenase activity decreased after dipping in solution containing either concentration of nano-ZnO. In the second experiment, nodulated roots of green gram were dipped in Hoagland solution containing 1, 4, 6, 8 and 10 lg mL -1 nano-ZnO for 6-30 h before estimating nitrogenase activity. Results showed that an interactive effect of nanoZnO concentration and exposure time influenced nitrogenase activity. The possible reasons behind this effect have been discussed. A model [A = 3.44 ? 0.46t -0.01t 2 -0.002tc 2 (R 2 = 0.81)] involving linear and power components was developed to simulate the response of nitrogenase activity in green gram roots to the concentration and exposure time of nano-ZnO.

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“…The recent review by Saptarshi et al [140] provides a table summarising the approaches that have been utilised in the recent literature to study nanoparticle-protein interactions, with a focus on methods to assess nanoparticle surface driven protein conformational changes and uptake of nanoparticles by cellular structures. An earlier review included a more diverse set of approaches, including ones routinely used for assessment of protein-protein interactions, including NMR, phage display libraries, limited proteolysis and many others [141].…”

Section: Towards Predicting Nanoparticle Fate and Behavior In Livingmentioning

confidence: 99%

The bio-nano-interface in predicting nanoparticle fate and behaviour in living organisms: towards grouping and categorising nanomaterials and ensuring nanosafety by design

et al. 2013

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Abstract:In biological media, nanoparticles acquire a coating of biomolecules (proteins, lipids, polysaccharides) from their surroundings, which reduces their surface energy and confers a biological identity to the particles. This adsorbed layer is the interface between the nanomaterial and living systems and therefore plays a significant role in determining the fate and behaviour of the nanoparticles. This review summarises the state of the art in terms of understanding the bio-nano interface and provides direction for potential future research and recommendations for future priorities and strategies to support the safe implementation of nanotechnologies. The central premise is that nanomaterials must be studied as biological entities under the appropriate exposure conditions and that this should be implemented in study design and reporting for nanosafety assessment. The implications of the bio-nano interface for nanomaterials fate and behaviour are described in light of four interlinked perspectives: the Coating concept; the Translocation concept; the Signalling concept, and the Kinetics concept. A key conclusion is that nanoparticles cannot be viewed as non-interacting species, but rather must be thought of, and studied as, biological entities, where their interaction with the environment is mediated by the proteins and other biomolecules that adsorb to them, and the key parameter to characterise then becomes the nature, composition and evolution of the bionano interface.

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Interaction of nanoparticles with proteins: relation to bio-reactivity of the nanoparticle

Cited by 878 publications

References 100 publications

Immunomodulatory properties of silver nanoparticles contribute to anticancer strategy for murine fibrosarcoma

Immunomodulatory properties of silver nanoparticles contribute to anticancer strategy for murine fibrosarcoma

Effect of nano-zinc oxide on nitrogenase activity in legumes: an interplay of concentration and exposure time

The bio-nano-interface in predicting nanoparticle fate and behaviour in living organisms: towards grouping and categorising nanomaterials and ensuring nanosafety by design

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