G protein-coupled receptors function as logic gates for nanoparticle binding and cell uptake

Hild, Wolfgang; Pollinger, K; Caporale, Andrea; Cabrele, Chiara; Keller, Max; Pluym, Nikola; Buschauer, Armin; Rachel, Reinhard; Teßmar, Jörg; Breunig, Miriam; Goepferich, Achim

doi:10.1073/pnas.0912782107

Cited by 46 publications

(34 citation statements)

References 33 publications

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“…In other work, Stadtman and Chock (1997) demonstrated that such a network can act as a flexible computational unit. Similar results were documented by Arkin and Ross (1994), and recently a number of researchers have developed these ideas (Hild et al 2010;Wang 2011).…”

Section: Introductionsupporting

confidence: 71%

Exploring aspects of cell intelligence with artificial reaction networks

et al. 2013

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Section: Introductionsupporting

confidence: 71%

Exploring aspects of cell intelligence with artificial reaction networks

et al. 2013

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“…This activity can alter the fate of NPs decorated with such peptides [273]. In this study, the targeting of quantum dots to G protein-coupled receptors using peptide agonists led to the internalization of the nanomaterial.…”

Section: Active Targeting: Toward Magic Bullet?mentioning

confidence: 93%

Cancer nanotechnology: The impact of passive and active targeting in the era of modern cancer biology

Bertrand

et al. 2014

Advanced Drug Delivery Reviews

2,314

1,814

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Cancer nanotherapeutics are progressing at a steady rate; research and development in the field has experienced an exponential growth since early 2000’s. The path to the commercialization of oncology drugs is long and carries significant risk; however, there is considerable excitement that nanoparticle technologies may contribute to the success of cancer drug development. The pace at which pharmaceutical companies have formed partnerships to use proprietary nanoparticle technologies has considerably accelerated. It is now recognized that by enhancing the efficacy and/or tolerability of new drug candidates, nanotechnology can meaningfully contribute to create differentiated products and improve clinical outcome. This review describes the lessons learned since the commercialization of the first-generation nanomedicines including DOXIL® and Abraxane®. It explores our current understanding of targeted and non-targeted nanoparticles that are under various stages of development, including BIND-014 and MM-398. It highlights the opportunities and challenges faced by nanomedicines in contemporary oncology, where personalized medicine is increasingly the mainstay of cancer therapy. We revisit the fundamental concepts of enhanced permeability and retention effect (EPR) and explore the mechanisms proposed to enhance preferential “retention” in the tumor, whether using active targeting of nanoparticles, binding of drugs to their tumoral targets or the presence of tumor associated macrophages. The overall objective of this review is to enhance our understanding in the design and development of therapeutic nanoparticles for treatment of cancers.

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“…According to Cerdevall et al, the corona could alter biological functions by the high presence of proteins in a restricted cellular area (Cedervall et al 2007). Thereby, this complex may appear to the cell as an exogenous compound, leading to a recognition by G protein-coupled receptors, integrins, and Toll-like transmembrane receptors, acting as gateways to the cell and triggering the proinflammatory response (Hild et al 2010). Thus, due to the presence of a protein corona around them, NPs may 'mislead' the cells, which may recognize these NPs as pathogen-like invaders, such as lipopolysaccharides (LPS) originating from bacterial outer membranes.…”

Section: Mechanisms Of Uptake At Higher Dosementioning

confidence: 99%

Biocompatibility assessment of functionalized magnetic mesoporous silica nanoparticles in human HepaRG cells

et al. 2017

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Magnetic mesoporous silica nanoparticles (M-MSNs) are a promising class of nanoparticles for drug delivery. However, a deep understanding of the toxicological mechanisms of action of these nanocarriers is essential, especially in the liver. The potential toxicity on HepaRG cells of pristine, pegylated (PEG), and lipid (DMPC) M-MSNs were compared. Based on MTT assay and real-time cell impedance, none of these NPs presented an extensive toxicity on hepatic cells. However, we observed by transmission electron microscopy (TEM) that the DMPC and pristine M-MSNs were greatly internalized. In comparison, PEG M-MSNs showed a slower cellular uptake. Whole gene expression profiling revealed the M-MSNs molecular modes of action in a time-and dose-dependent manner. The lowest dose tested (1.6 mg/cm 2 ) induced no molecular effect and was defined as 'No Observed Transcriptional Effect level.' The dose 16 mg/cm 2 revealed nascent but transient effects. At the highest dose (80 mg/cm 2 ), adverse effects have clearly arisen and increased over time. The limit of biocompatibility for HepaRG cells could be set at 16 mg/cm 2 for these NPs. Thanks to a comparative pathway-driven analysis, we highlighted the sequence of events that leads to the disruption of hepatobiliary system, elicited by the three types of MMSNs, at the highest dose. The Adverse Outcome Pathway of hepatic cholestasis was implicated. Toxicogenomics applied to cell cultures is an effective tool to characterize and compare the modes of action of many substances. We propose this strategy as an asset for upstream selection of the safest nanocarriers in the framework of regulation for nanobiosafety. ARTICLE HISTORY

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G protein-coupled receptors function as logic gates for nanoparticle binding and cell uptake

Cited by 46 publications

References 33 publications

Exploring aspects of cell intelligence with artificial reaction networks

Exploring aspects of cell intelligence with artificial reaction networks

Cancer nanotechnology: The impact of passive and active targeting in the era of modern cancer biology

Biocompatibility assessment of functionalized magnetic mesoporous silica nanoparticles in human HepaRG cells

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