Genome-wide analysis of ATP-binding cassette (ABC) transporter in Penaeus vannamei and identification of two ABC genes involved in immune defense against Vibrio parahaemolyticus by affecting NF-κB signaling pathway.

The ATP-binding cassette (ABC) transporters have crucial roles in various biological processes such as growth, development and immune defense in eukaryotes. However, the roles of ABC transporters in the immune system of crustaceans remain elusive. In this study, 38 ABC genes were systematically identified and characterized in Penaeus vannamei. Bioinformation analysis revealed that PvABC genes were categorized into ABC A-H eight subfamilies with 17 full-transporters, 11 half transporters and 10 soluble proteins, and multiple immunity-related cis-elements were found in gene promoter regions. Expression analysis showed that most PvABC genes were widely and highly expressed in immune-related tissues and responded to the stimulation of Vibrio parahaemolyticus. To investigate whether PvABC genes mediated innate immunity, PvABCC5, PvABCF1 and PvABCB4 were selected for dsRNA interference experiment. Knockdown of PvABCF1 and PvABCC5 not PvABCB4 increased the cumulative mortality of P. vannamei and bacterial loads in hepatopancreas after infection with V. parahaemolyticus. Further analysis showed that the PvABCF1 and PvABCC5 knockdown decreased expression levels of NF-κB pathway genes and antimicrobial peptides (AMPs). Collectively, these findings indicated that PvABCF1 and PvABCC5 might restrict V. parahaemolyticus challenge by positively regulating NF-κB pathway and then promoting the expression of AMPs, which would contribute to overall understand the function of ABC genes in innate immunity of invertebrates.

[The Influence of Oxygen Incorporation on the Microstructure and Band Gap Properties of the nc-Si Films].

The authors prepared nc-SiOx: H thin films using plasma enhanced chemical vapor deposition methods (PECVD) and investigated the influence of oxygen incorporation on the microstructure and band gap properties of the films. The results indicated that with the increase in oxygen mixing ratio (CO2/SiH4), the grain size of the nanocrystal-silicon grain as well as the crystallinity of the film reduced, and the surface tensile stress of the nanocrystal-silicon grain first increased and then decreased. Fourier infrared absorption spectra analysis indicated that, with the increase in oxygen mixing ratio, the intensity of the oxygen rich Si--O bond increased while that of the silicon rich Si--O bond decreased and the structure factor reduced in the meantime accompanied by the improved order degree of thin films. The structure factor increased when the oxygen mixing ratio exceeded 0.08, which shows that the order degree of thin films dropped. In addition, the optical gap increased and the band tail width first increased and then decreased as a result of the incorporation of the oxygen. As a result, the microstructure and band gap properties of the films can be controlled by incorporating oxygen. And the crystallinity and optical gap of the material was high, and the microstructure of the films was improved at the same time when the oxygen mixing ratio was 0. 08, so it can be used as intrinsic layer of the thin-film solar cells.