An artificialed protein corona coating the surface of magnetic nanoparicles:a simple and efficient method for label antibody.

Background: Protein Corona (PC) of nanoparticles is a structure which composed of one or more layers of proteins adsorbed on the surface of nanomaterials, and the formation of PC is a universal process of spontaneous randomness. We take advantage of the formation principle of the PC, developed a simple and efficient method for label protein to nanoparticles. Methods: The artificialed protein corona (APC) on the surface of nanoparticles was synthesized via the artificialed methods of desolvation aggregation and crosslinking with control. Results: The dosage of precipitator and the ratio of protein to magnetic nanoparticles (MNPs)(particle size: 3 nm) were optimized, and the core-shell nanoparticles with narrow particle size (particle size: 10 nm) distribution were obtained. The MNPs with APC were characterized by transmission electron microscopy (TEM) and vibrating sample magnetometer (VSM). Additionally, a hemolysis test on prepared MNPs was conducted with APC. The presence of APC coating on the surface of MNPs showed an improving effect to reduce the cytotoxicity. Cellular toxicity of MNPs with APC was also investigated on HFF1 cell lines. And the cells survival in the presence of APC coated MNPs and display neither reduced metabolism nor cytostatic effect. The functional test of the MNPs with APC showed that proteins can be modified and labeled onto magnetic nanoparticles and retain their original activity. Conclusions: This marking method is gentle and effective. And the properties of the APC propose MNPs as a promising candidate for multifunctional biomedical applications.

Antibody orientational labeling via staphylococcus A protein to improve the sensitivity of gold immunochromatography assays.

The Cry1Ab toxin is usually expressed in genetically modified crops in order to control chewing pests. Although the gold immunochromatography assay (GICA) based on the double-antibody sandwich method has been developed to detect this toxin, its detection sensitivity needs improvement. In this study, Cry1Ab-51 antibodies were immobilized orientationally in a simple and effective way on colloidal gold nanoparticles (CGNPs) using the affinity of staphylococcal protein A (SPA) towards the fragment crystallizable (FC) fragment of mouse immunoglobulin G (IgG). Lateral flow detection test strips, assembled with probes labeled with orientational methods under optimal operational conditions (new probe), were 10 times more sensitive than test strips assembled with probes labeled by adsorption (conventional probe). Experiments showed that the affinity of the new probe was much higher than the conventional probe. The immunochromatography gold strip (ICG strip) assembled using the new probe was highly specific to Cry1Ab with no cross-reaction with other transgenic proteins, and it was proved that the specificity of the new probe had no change. Furthermore, the ICG strips assembled with the new probe could be stored for 12 months under dry conditions without a significant loss of sensitivity. The orientational labeling of the antibodies with SPA on colloidal gold proved to be suitable for improving the sensitivity of the ICG strips.

Neutralizing antibody PR8-23 targets the footprint of the sialoglycan receptor binding site of H1N1 hemagglutinin.

Influenza virus cause seasonal influenza epidemic and seriously sporadic influenza pandemic outbreaks. Hemagglutinin (HA) is an important target in the therapeutic treatment and diagnostic detection of the influenza virus. Variation in the sialic acid receptor binding site leads to strain-specific binding and results in different binding modes to the host receptors. Here, we evaluated the neutralizing activity and hemagglutination inhibition activity of a prepared murine anti-H1N1 monoclonal antibody PR8-23. Then we identified the epitope peptide of antibody PR8-23 by phage display technique from phage display peptide libraries. The identified epitope, 63-IAPLQLGKCNIA-74, containing two α-helix and two ß-fold located at the footprint of the sialoglycan receptor on the RBS in the globular head domain of HA. It broads the growing arsenal of motifs for the amino acids on the globular head domain of HA in sialic acid receptor binding site and neutralizing antibody production.

Identification and characterization of epitopes from influenza A virus hemagglutinin that induce broadly cross-reactive antibodies.

Influenza is the most common infectious disease and is caused by influenza A virus (IAV) infection. Hemagglutinin (HA) is an important viral protein of influenza A and is a major component of current IAV vaccines. The side effects associated with IAV vaccination are well studied; however, the HA­induced immunopathological changes have remained largely elusive. The primary objective of the present study was to determine the tissue cross­reactive epitopes of HA proteins. Monoclonal antibodies (McAbs) were generated according to traditional methods using purified HA proteins from influenza vaccine lysates. The specificity of these McAbs was analyzed using western blot analysis and ELISA. Human tissue microarrays were employed for immunohistochemical staining to screen these McAbs. Rat brain tissues were subjected to immunohistochemical staining and electron microscopy to demonstrate the subcellular localization of antibodies targeting specific antigens. A total of 67 hybridoma cell lines positive for McAb against HA antigen were obtained. Three cross­reactive McAbs (H1­13, H1­15 and A1­10) were discovered through tissue screening. Based on the 3 cross­reactive McAbs and the amino acid sequence of HA, the presence of two broadly cross­reactive HA epitopes, 194­WGIHH­198 and 365­WYGYHH­370, was assumed. McAbs against these synthetic epitope peptides were obtained. They reacted with porphyrin ring­containing molecules, including hemoglobin (Hb) and protoporphyrin, and with numerous types of normal tissue. In conclusion, the present study identified two broadly cross­reactive epitopes on HA (194­WGIHH­198 and 365­WYGYHH­370). Antibodies against these epitopes react with Hb and numerous types of important normal tissues/organs. These newly identified cross­reactive epitopes from IAV HA may provide crucial information for influenza research.

Development and characterization of a panel of cross-reactive monoclonal antibodies generated using H1N1 influenza virus.

To characterize the antigenic epitopes of the hemagglutinin (HA) protein of H1N1 influenza virus, a panel consisting of 84 clones of murine monoclonal antibodies (mAbs) were generated using the HA proteins from the 2009 pandemic H1N1 vaccine lysate and the seasonal influenza H1N1(A1) vaccines. Thirty-three (39%) of the 84 mAbs were found to be strain-specific, and 6 (7%) of the 84 mAbs were subtype-specific. Twenty (24%) of the 84 mAbs recognized the common HA epitopes shared by 2009 pandemic H1N1, seasonal A1 (H1N1), and A3 (H3N2) influenza viruses. Twenty-five of the 84 clones recognized the common HA epitopes shared by the 2009 pandemic H1N1, seasonal A1 (H1N1) and A3 (H3N2) human influenza viruses, and H5N1 and H9N2 avian influenza viruses. We found that of the 16 (19%) clones of the 84 mAbs panel that were cross-reactive with human respiratory pathogens, 15 were made using the HA of the seasonal A1 (H1N1) virus and 1 was made using the HA of the 2009 pandemic H1N1 influenza virus. Immunohistochemical analysis of the tissue microarray (TMA) showed that 4 of the 84 mAb clones cross-reacted with human tissue (brain and pancreas). Our results indicated that the influenza virus HA antigenic epitopes not only induce type-, subtype-, and strain-specific monoclonal antibodies against influenza A virus but also cross-reactive monoclonal antibodies against human tissues. Further investigations of these cross-reactive (heterophilic) epitopes may significantly improve our understanding of viral antigenic variation, epidemics, pathophysiologic mechanisms, and adverse effects of influenza vaccines.

Prediction of common epitopes on hemagglutinin of the influenza A virus (H1 subtype).

Influenza A virus infection is a persistent threat to public health worldwide due to hemagglutinin (HA) variation. Current vaccines against influenza A virus provide immunity to viral isolates similar to vaccine strains. Antibodies against common epitopes provide immunity to diverse influenza virus strains and protect against future pandemic influenza. Therefore, it is vital to analyze common HA antigenic epitopes of influenza virus. In this study, 14 strains of monoclonal antibodies with high sensitivity to common epitopes of influenza virus antigens identified in our previous study were selected as the tool to predict common HA epitopes. The common HA antigenic epitopes were divided into four categories by ELISA blocking experiments, and separately, into three categories according to the preliminary results of computer simulation. Comparison between the results of computer simulations and ELISA blocking experiments indicated that at least two classes of common epitopes are present in influenza virus HA. This study provides experimental data for improving the prediction of HA epitopes of influenza virus (H1 subtype) and the development of a potential universal vaccine as well as a novel approach for the prediction of epitopes on other pathogenic microorganisms.