Development of pH-Sensitive Cationic PEGylated Solid Lipid Nanoparticles for Selective Cancer-Targeted Therapy.

Solid lipid nanoparticles (SLNs) are suitable candidates for the delivery of various anti-cancer drugs. However, currently insufficient tumor-permeability and non-specific uptake by the reticuloendothelial system limits the application of SLNs. Here, we developed novel pH-sensitive cationic polyoxyethylene (PEGylated) SLNs (PEG-SLNs+) that could accumulate long-term at various tumor sites to enhance the therapeutic efficiency of camptothecin (CPT). These CPT-loaded PEG-SLNs+ (CPT-PEG-SLNs+) were spherical nanoparticles, with small size (∼52.3±1.7 nm), positive charge (∼34.3±3.5 mV) and high entrapment efficiency (∼99.4±1.7%). Drug release profile indicated the overall released amount of CPT from CPT-PEG-SLNs+ at pH 5.5 was 20.2% more than at pH 7.4, suggesting CPT-PEG-SLNs+ were a pH-sensitive SLNs. This PEG-SLNs+ could be efficiently uptaken into cells to inhibit the proliferation of CL1-5 cells (IC50 = 0.37 ±0.21 ug/ml) or HCC36 cells (IC50 = 0.16±0.43 ug/ml). In living animal, our PEG-SLNs+ could accumulate long-term (for more than 120 hours) in various types of tumor, including human lung carcinoma (NCI-H358, CRL5802, CL1-5), human colon carcinoma (HCT-116) and human hepatocellular carcinoma (HCC36), and CPT-PEG-SLNs+ could efficiently enhance the therapeutic efficiency of CPT to suppress the growth of the HCC36 or CL1-5 tumors. Therefore, Successful development of these pH-sensitive PEGylated cationic SLNs may provide a selective and efficient drug delivery system for cancer therapy.

Direct coating of culture medium from cells secreting classical swine fever virus E2 antigen on ELISA plates for detection of E2-specific antibodies.

The envelope glycoprotein E2 of classical swine fever virus (CSFV) is widely used as a marker for measuring vaccine efficacy and antibody titer. The glycosylation profile of E2 may affect the immunogenicity of the vaccine and the timing of re-vaccination. In this study, a human embryonic kidney cell line was used to secrete fully-glycosylated CSFV E2, which was then coated onto ELISA plates without purification or adjustment. The resulting E2-secreting medium-direct-coating (E2-mDc) ELISA was successfully used to measure anti-E2 antibody titers in vaccinated and field pig sera samples. Compared with a virus neutralization test (as standard), the E2-mDc ELISA was found to be more accurate (90%) than a commercial CSFV antibody diagnostic kit (62%). In conclusion, the mammalian cell-secreted antigen can provide cheap, accurate and effective assays for vaccine efficacy and disease diagnoses.

Discovery of specific inhibitors for intestinal E. coli ß-glucuronidase through in silico virtual screening.

Glucuronidation is a major metabolism process of detoxification for carcinogens, 4-(methylnitrosamino)-1-(3-pyridy)-1-butanone (NNK) and 1,2-dimethylhydrazine (DMH), of reactive oxygen species (ROS). However, intestinal E. coli ß-glucuronidase (eßG) has been considered pivotal to colorectal carcinogenesis. Specific inhibition of eßG may prevent reactivating the glucuronide-carcinogen and protect the intestine from ROS-mediated carcinogenesis. In order to develop specific eßG inhibitors, we found that 59 candidate compounds obtained from the initial virtual screening had high inhibition specificity against eßG but not human ßG. In particular, we found that compounds 7145 and 4041 with naphthalenylidene-benzenesulfonamide (NYBS) are highly effective and selective to inhibit eßG activity. Compound 4041 (IC50 = 2.8 µM) shows a higher inhibiting ability than compound 7145 (IC50 = 31.6 µM) against eßG. Furthermore, the molecular docking analysis indicates that compound 4041 has two hydrophobic contacts to residues L361 and I363 in the bacterial loop, but 7145 has one contact to L361. Only compound 4041 can bind to key residue (E413) at active site of eßG via hydrogen-bonding interactions. These novel NYBS-based eßG specific inhibitors may provide as novel candidate compounds, which specifically inhibit eßG to reduce eßG-based carcinogenesis and intestinal injury.