Nanoparticle exposure reactivates latent herpesvirus and restores a signature of acute infection

Christine, Sattler; Moritz, Franco; Chen, Shanze; Steer, Beatrix; Kutschke, David; Irmler, Martin; Beckers, Johannes; Eickelberg, Oliver; Schmitt‐Kopplin, Philippe; Adler, Heiko; Stoeger, Tobias

doi:10.1186/s12989-016-0181-1

Cited by 25 publications

(25 citation statements)

References 69 publications

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“…A body of studies shows particle-induced induction of acute phase response in terms of increased Saa3 transcription and SAA3 release. [13,14,39,40,42,45,46,52,[91][92][93][94][95][96] Furthermore, Saa3 mRNA levels were increased within a few hours and SAA3 protein was measured by ELISA as early as 6 h after LPS instillation accumulating up to 24 h before slowly declining to base levels over a course of days. [97] (unpublished data) However, all these studies were conducted in bronchoalveolar lavage or whole lung tissue, and the responsible cell types have not yet been identified.…”

Section: Cells Expressing Acute Phase Response Proteins In the Lungmentioning

confidence: 99%

Acute Phase Response as a Biological Mechanism‐of‐Action of (Nano)particle‐Induced Cardiovascular Disease

Hadrup

Zhernovkov

Jacobsen

et al. 2020

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Inhaled nanoparticles constitute a potential health hazard due to their size-dependent lung deposition and large surface to mass ratio. Exposure to high levels contributes to the risk of developing respiratory and cardiovascular diseases, as well as of lung cancer. Particle-induced acute phase response may be an important mechanism of action of particleinduced cardiovascular disease. Here, the authors review new important scientific evidence showing causal relationships between inhalation of particle and nanomaterials, induction of acute phase response, and risk of cardiovascular disease. Particle-induced acute phase response provides a means for risk assessment of particle-induced cardiovascular disease and underscores cardiovascular disease as an occupational disease.

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Section: Cells Expressing Acute Phase Response Proteins In the Lungmentioning

confidence: 99%

Acute Phase Response as a Biological Mechanism‐of‐Action of (Nano)particle‐Induced Cardiovascular Disease

Hadrup

Zhernovkov

Jacobsen

et al. 2020

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“…In contrast to our study with TiO 2 ‐NP, nanocarbon black did not alter cell titers of herpes virus after a 2‐h primary infection (Sattler et al. 2017). However, nanocarbon black and double‐walled carbon nanotubes did increase viral titers in alveolar macrophages or mouse lungs with a latent rather than ongoing infection (Sattler et al.…”

Section: Discussionmentioning

confidence: 99%

“…However, nanocarbon black and double‐walled carbon nanotubes did increase viral titers in alveolar macrophages or mouse lungs with a latent rather than ongoing infection (Sattler et al. 2017). Pulmonary exposure of mice to TiO 2 ‐NP 5 days prior to respiratory RSV infection increased the severity of RSV‐induced pneumonia, although lung viral titers were not significantly affected, perhaps due to the high level of viral inoculation used (Hashiguchi et al.…”

Section: Discussionmentioning

confidence: 99%

Nanoparticles increase human bronchial epithelial cell susceptibility to respiratory syncytial virus infection via nerve growth factor-induced autophagy

et al. 2017

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Cytotoxic and neuroinflammatory effects of TiO2 nanoparticles (TiO2‐NP) in human airways are mediated by nerve growth factor (NGF), which is also implicated in the pathophysiology of respiratory syncytial virus (RSV) infection. We tested the hypothesis that exposure to TiO2‐NP results in increased susceptibility to RSV infection and exacerbation of airway inflammation via NGF‐mediated induction of autophagy in lower respiratory tract cells. Human primary bronchial epithelial cells were exposed to TiO2‐NP for 24 h prior to infection with recombinant red RSV (rrRSV). Expression of NGF and its TrkA and p75NTR receptors was measured by real‐time PCR and fluorescence‐activated cell sorting (FACS). Autophagy was assessed by beclin‐1 expression analysis. Cell death was studied by FACS after annexin V/propidium iodide staining. rrRSV infection efficiency more than doubled in human bronchial cells pre‐exposed to TiO2‐NP compared to controls. NGF and its TrkA receptor were upregulated in RSV‐infected bronchial cells pre‐exposed to TiO2‐NP compared to controls exposed to either rrRSV or TiO2‐NP alone. Silencing NGF gene expression with siRNA significantly inhibited rrRSV infection. rrRSV‐infected cells pre‐exposed to TiO2‐NP also showed increase in necrotic cell death and reduction in apoptosis, together with 4.3‐fold increase in expression of the early autophagosomal gene beclin‐1. Pharmacological inhibition of beclin‐1 by wortmannin resulted in increased apoptotic rate along with lower viral load. This study shows that TiO2‐NP exposure enhances the infectivity of RSV in human bronchial epithelial cells by upregulating the NGF/TrkA axis. The mechanism of this interaction involves induction of autophagy promoting viral replication and necrotic cell death.

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“…The noted increase in IAV titers could not be duplicated with a simultaneous dual exposure or by exposing the cells to the SWCNTs after infection (Sanpui et al 2014). However, in another study, DWCNTs were able to reactivate latent herpesvirus, suggesting that the infections occurred prior to NP exposure (Sattler et al 2017). There is not an abundance of evidence to suggest that classic additive, synergistic, or antagonistic toxicity occurs under any of these exposure scenarios, but this observation likely depends on the endpoints that are quantified, which have been limited.…”

Section: Nanoparticle and Viral Exposure Routes And Scenariosmentioning

confidence: 96%

“…Spherical carbon nanoparticles (Barras et al 2016) and fullerene (C60) derivatives (Shoji et al 2013) were shown to interfere with HSV-1 and IAV, respectively, whereas exposure to a single dose of TiO 2 nanoparticles exacerbated pneumonia in RSV-infected mice (Hashiguchi et al 2015a). Lastly, a more recent report showed for the first time the ability of double-walled carbon nanotubes (DWCNTs) to reactivate latent herpesvirus (MHV-68) in cells and mice (Sattler et al 2017). They also discovered that these DWCNTs could induce more pronounced effects in terms of reactivating latent virus than carbonaceous spherical nanoparticles.…”

Section: Nanoparticle Exposure and Viral Infectionmentioning

confidence: 99%

Nanomaterial Effects on Viral Infection

Chen

Humes

Saleh

et al. 2020

Interaction of Nanomaterials With the Immune System

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The potential for environmental and occupational exposures of populations to nanomaterials (NMs) has fostered concerns of associated adverse health effects, with a particular emphasis on pulmonary injury and disease. Many studies have revealed that several types of NMs can evoke a variety of biological responses, such as pulmonary inflammation and oxidative stress, which contribute to allergy, fibrosis, and granuloma formation. Less attention has been paid to health effects that may result from exposure to NMs and additional stressors such as pathogens, with a particular focus on susceptibility to viral infection. This chapter will summarize the current body of literature related to NMs and viral exposures with a primary focus on immune modulation. A summary of the studies performed and major findings to date will be discussed, highlighting proposed molecular mechanisms behind NM-driven host susceptibility, challenges, limitations, and future research needs. Specific mechanisms discussed include direct interaction between NMs and biological molecules, activation of pattern recognition receptors (PRRs) and related signaling pathways, production of oxidative stress and mitochondrial dysfunction, inflammasome activation, and modulation of lipid signaling networks.

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Nanoparticle exposure reactivates latent herpesvirus and restores a signature of acute infection

Cited by 25 publications

References 69 publications

Acute Phase Response as a Biological Mechanism‐of‐Action of (Nano)particle‐Induced Cardiovascular Disease

Acute Phase Response as a Biological Mechanism‐of‐Action of (Nano)particle‐Induced Cardiovascular Disease

Nanoparticles increase human bronchial epithelial cell susceptibility to respiratory syncytial virus infection via nerve growth factor-induced autophagy

Nanomaterial Effects on Viral Infection

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