[Extraction, Characterization and Immune Effect Analysis of Listeria Monocytogenes Membrane Vesicles].

OBJECTIVE: To establish a method for extracting Listeria monocytogenesmembrane vesicles (LM-MVs) and to analyze the characteristics of LM-MVs and their ability to induce innate immune effect in vitro so as to lay the foundation for research into using LM-MVs as vaccine carrier and drug delivery platform. METHODS: The membrane vesicles secreted by Listeria monocytogenes were extracted through a continuous process, including culturing, centrifugation, filtration, ultrafiltration concentration and ultracentrifugation. The morphological characteristics of LM-MVs were observed with transmission electron microscope, and particle size distribution were measured by dynamic light scattering analysis. SDS-PAGE and Western blot were used to analyze the protein composition of LM-MVs. CCK-8 cell proliferation and toxicity determination experiments were done to analyze their effect on the proliferation of innate immune cells, and qPCR was used to analyze their ability to induce innate immune responses. RESULTS: A method for extracting LM-MVs was successfully established. Under the transmission electron microscope, LM-MVs presented a nearly circular film-like structure, and dynamic light scattering analysis showed that their sizes were between 65 and 190 nm. SDS-PAGE and Western blot showed that LM-MVs contained proteins, including listeriolysin O (LLO). CCK-8 cell proliferation and toxicity experiment showed that after intervention with 10, 20 and 50 µg/mL of LM-MVs for 24 hours, the proliferation rate of DC 2.4 mouse dendritic cell line was higher than that of non-interventional DC 2.4 cells ( P<0.05); after intervention with 0.1, 1, 10, 20 and 50 µg/mL of LM-MVs for 24 hours, the proliferation rate of RAW 264.7 cells was higher than that of non-interventional RAW 264.7 cells ( P<0.01). The results of qPCR showed that, after intervention with 50 µg/mL of LM-MVs, the expression levels of tumor necrosis factor (TNF)-α, interleukin (IL)-1ß, IL-6 and IL-10 in RAW 264.7 cells were higher than those of non-intervention control cells ( P<0.05). CONCLUSIONS: The method established in the study can be used to extract LM-MVs. The extracted LM-MVs have a diameter of 65-190 nm and a nearly circular membrane-like structure. They can secrete a variety of protein components and stimulate innate immune responses.

Mass spectrometry-based lipidomics to explore the biochemical effects of naphthalene toxicity or tolerance in a mouse model.

Naphthalene causes mouse airway epithelial injury. However, repeated exposures of naphthalene result in mouse airway tolerance. Previous results showed that toxicity or tolerance was correlated with changes of phosphorylcholine-containing lipids. In this study, a mass spectrometry-based lipidomic approach was applied to examine the effects of naphthalene-induced injury or tolerance in the male ICR mice. The injury model was vehicle x 7 plus 300 mg/kg naphthalene while the tolerant one was 200 mg/kg daily x 7 followed by 300 mg/kg naphthalene on day 8. The lung, liver, kidney, and serum samples were collected for profiles of phosphorylcholine-containing lipids including phosphatidylcholines (PCs) and sphingomyelins (SMs). A partial least-square-discriminate analysis model showed different lung phosphorylcholine-containing lipid profiles from the injured, tolerant, and control groups. Perturbation of diacyl-PCs and plasmenylcholines may be associated with enhanced membrane flexibility and anti-oxidative mechanisms in the lungs of tolerant mice. Additionally, alterations of lyso-PCs and SMs may be responsible for pulmonary dysfunction and inflammation in the lungs of injured mice. Moreover, serum PC(16:0/18:1) has potential to reflect naphthalene-induced airway injuries. Few phosphorylcholine-containing lipid alterations were found in the mouse livers and kidneys across different treatments. This study revealed the changes in lipid profiles associated with the perturbations caused by naphthalene tolerance and toxicity; examination of lipids in serum may assist biomarker development with the potential for application in the human population.

LC-MS-based lipidomics to examine acute rat pulmonary responses after nano- and fine-sized ZnO particle inhalation exposure.

Zinc oxide (ZnO) nano- and fine-sized particles are associated with respiratory toxicity in humans, but the underlying molecular mechanisms remain unclear. Our previous nuclear magnetic resonance-based metabolomic study demonstrated that changes in phosphorylcholine-containing lipids (PC-CLs) in the respiratory system were associated with ZnO particle-induced respiratory toxicity. However, the details of the lipid species associated with adverse effects and possible biomarker signatures have not been identified. Thus, a liquid chromatography-mass spectrometry (LC-MS)-based lipidomics platform was applied to examine the alterations of PC-CL species in the lungs of rats treated with a series of concentrations of nano-sized (35 nm) or fine-sized (250 nm) ZnO particles via inhalation. Principal component analysis (PCA), partial least squares discriminant analysis (PLS-DA), and the Mann-Whitney U (MWU) test with false discovery rate (FDR) control were conducted to explore the perturbed lipid species and to discriminate a potential pulmonary biomarker signature after ZnO particle exposure. The PCA and PLS-DA models revealed that the fine-sized ZnO particle-treated groups and the high-concentration nano-sized group were separated from the control groups as well as from the low and moderate nano-sized groups. The results from the MWU test further suggested that after FDR adjustment, numerous PC-CL species were altered in the high-concentration and moderate-concentration fine-sized groups. Furthermore, our results suggested that lipids involved in anti-oxidation, membrane conformation, and cellular signal transduction were altered in response to ZnO-induced oxidative stress and inflammation. One lipid, PC(18:0/18:1), exhibited good performance (AUC > 0.8) of discriminative ability in distinguishing ZnO particle exposure from the control. These findings not only provide a foundation for the exploration of possible ZnO particle-mediated mechanisms but also suggest a lipid biomarker for ZnO particle exposure.