Li Yang, Shi Zhenzhen, Radauer-Preiml Isabella, Andosch Ancuela, Casals Eudald, Luetz-Meindl Ursula, Cobaleda Macarena, Lin Zhoumeng, Jaberi-Douraki Majid, Italiani Paola, Horejs-Hoeck Jutta, Himly Martin, Monteiro-Riviere Nancy A, Duschl Albert, Puntes Victor F, Boraschi Diana
a Institute of Protein Biochemistry , National Research Council , Napoli , Italy.
b Nanotechnology Innovation Center of Kansas State University (NICKS), Department of Anatomy and Physiology , Kansas State University , Manhattan , KS , USA.
Nanotoxicology. 2017 Nov-Dec;11(9-10):1157-1175. doi: 10.1080/17435390.2017.1401142. Epub 2017 Dec 1.
Nanoparticles (NPs) are easily contaminated by bacterial endotoxin (lipopolysaccharide [LPS]). The presence of LPS can be responsible for many immune/inflammatory effects attributed to NPs. In this study, we examined the effects of LPS adsorption on the NP surface on the formation of a biocorona in biological fluids and on the subsequent inflammation-inducing activity of NPs. Different gold (Au) NPs with sizes ranging from 10 to 80 nm and with different surface functionalization (sodium citrate, lipoic acid, and branched polyethyleneimine (BPEI), or polyethylene glycol (PEG)) were exposed to E. coli LPS under different conditions. The binding capacity of LPS to the surface of AuNPs was dose- and time-dependent. LPS attached to sodium citrate and lipoic acid coatings, but did not adhere to BPEI- or PEG-coated NPs. By computational simulation, the binding of LPS to AuNPs seems to follow the Langmuir absorption isotherm. The presence of LPS on AuNP surface interfered and caused a decrease in the formation of the expected biomolecular corona upon incubation in human plasma. LPS-coated AuNPs, but not the LPS-free NPs, induced significant inflammatory responses in vitro. Notably, while free LPS did also induce an anti-inflammatory response, LPS bound to NPs appeared unable to do so. In conclusion, the unintentional adsorption of LPS onto the NP surface can affect the biocorona formation and the inflammatory properties of NPs. Thus, for an accurate interpretation of NP interactions with cells, it is extremely important to be able to distinguish the intrinsic NP biological effects from those caused by biologically active contaminants such as endotoxin.
纳米颗粒(NPs)很容易被细菌内毒素(脂多糖[LPS])污染。LPS的存在可能是许多归因于NPs的免疫/炎症效应的原因。在本研究中,我们研究了NP表面LPS吸附对生物流体中生物冠形成以及随后NPs诱导炎症活性的影响。将不同尺寸(10至80nm)且具有不同表面功能化(柠檬酸钠、硫辛酸、支化聚乙烯亚胺(BPEI)或聚乙二醇(PEG))的金(Au)NPs在不同条件下暴露于大肠杆菌LPS。LPS与AuNPs表面的结合能力呈剂量和时间依赖性。LPS附着于柠檬酸钠和硫辛酸涂层,但不粘附于BPEI或PEG涂层的NPs。通过计算模拟,LPS与AuNPs的结合似乎遵循朗缪尔吸附等温线。AuNP表面存在LPS会干扰并导致在人血浆中孵育时预期生物分子冠的形成减少。LPS包被的AuNPs而非无LPS的NPs在体外诱导了显著的炎症反应。值得注意的是,虽然游离LPS也诱导了抗炎反应,但与NPs结合的LPS似乎无法做到这一点。总之,LPS意外吸附到NP表面会影响生物冠的形成和NPs的炎症特性。因此,为了准确解释NP与细胞的相互作用,能够区分NP的内在生物学效应与由内毒素等生物活性污染物引起的效应极其重要。
