Screening and identification of the polypeptides specifically binding to the adhesion protein of Myco-plasma genitalium / 中华微生物学和免疫学杂志

Objective To screen and identify the polypeptides specifically binding to the adhesion protein of Mycoplasma genitalium(MgPa) by using the Ph. D.-12TM phage display peptide library for further understanding the biological function and the possible pathogenic mechanism of the MgPa. Methods The Ph. D.-12TM phage display peptide library was used for 3 rounds of biopanning with the purified recombinant MgPa ( rMgPa) as the given target. The phages were collected for amplification after biopanning. The single strand DNA of phage clones were extracted and purified by using the sodium iodide method for further se-quencing. ELISA, competitive binding assay and dot immunobinding assay were performed to analyze the specific binding of positive phages to rMgPa. Results A significant enrichment of phages was achieved after 3 rounds of biopanning. Eleven different phage exogenous sequences (P1-P11) were detected among the 38 phages randomly selected from the agar. Two core sequences were deduced according to the repeating times of amino acids among the 11 polypeptide sequences, which were V-H-W-D-F-R-Q-W-W-Q-P-S and D-W-S-S-W-V-H/Y-R-D-P-Q-T/S. Ten out of the 11 representative phages ( P1-P10 ) specifically combined with the rMgPa. Conclusion Two polypeptides specifically binding to rMgPa were successfully screened out, which provided the tool for further investigation on the biological function of MgPa and the pathogenic mecha-nism of Mycoplasma genitalium.

The distinctive germinal center phase of IgE+ B lymphocytes limits their contribution to the classical memory response.

The mechanisms involved in the maintenance of memory IgE responses are poorly understood, and the role played by germinal center (GC) IgE(+) cells in memory responses is particularly unclear. IgE(+) B cell differentiation is characterized by a transient GC phase, a bias toward the plasma cell (PC) fate, and dependence on sequential switching for the production of high-affinity IgE. We show here that IgE(+) GC B cells are unfit to undergo the conventional GC differentiation program due to impaired B cell receptor function and increased apoptosis. IgE(+) GC cells fail to populate the GC light zone and are unable to contribute to the memory and long-lived PC compartments. Furthermore, we demonstrate that direct and sequential switching are linked to distinct B cell differentiation fates: direct switching generates IgE(+) GC cells, whereas sequential switching gives rise to IgE(+) PCs. We propose a comprehensive model for the generation and memory of IgE responses.