Phage display screening of TIGIT-specific antibody for antitumor immunotherapy.

The fully synthetic humanized phage antibody library has the advantages including the minimized immunogenicity, which frequently happened in hybridoma cell-based antibody production. In this paper, using the constructed diverse complementarity determining region gene library and the germline gene as the backbone, we constructed eight single-chain antibody libraries and a combinatorial antibody library with a big capacity of 1.41 × 1010. M13EEA helper phage that was engineered from M13KO7 was applied to prepare phage antibody library. The eukaryotic expression of T-cell immune receptor with Ig and ITIM domain (TIGIT) antigen was used as a target antigen for screening. The screening of antigen-specific single-chain Fc-fused protein was performed through evaluation of binding affinity based on ELISA analysis. The IgG antibody was prepared with the screened single-chain protein. Finally, the CB3 antibody was screened out which exhibits the highest binding affinity with TIGIT with the Kd value of 8.155 × 10-10 M.

[Screening and genomic analysis of a lignocellulose degrading bacterium].

Objective: This study is aimed to screen and identify a bacterium with the ability to degrade lignocellulose, to perform its genomic analysis, and to determine its related enzymatic activities. Methods: Using a bleaching/dyeing method with three kinds of lignin analogues (Azure-B; Phenol red; Guaiacol), we separated and screened a bacterium strain, with a strong ability to degrade lignocellulose, from soil enriched by decaying wood and leaves. We identified the species of this bacterium according to its 16S rRNA gene and core gene sequence analysis. In order to understand the trend of enzymatic activities within a certain period, we used ultraviolet spectrophotometry on manganese peroxidase (MnP), laccase (Lac), carboxymethyl cellulose (CMCase) and filter paper (FPA). The whole genome was sequenced by Illumina MiSeq and 454 GS Junior platforms. The protein sequences were annotated from the whole genome and compared with COG and KEGG databases through BLASTp to determine several potential lignocellulose-degrading enzymes and pathways. Some of the annotated genes were further verified by realtime RT-PCR. Results: We obtained strain S12 which was identified as Raoultella ornithinolytica. The bacterium grew to stationary phase after being incubated in CMC-Na liquid medium for 28 h, at which its cellulose degradation related enzymatic activities reached to peak values. Bioinformatic analysis results showed that strain S12 has some significant genes that encode enzymes working in the lignin degradation pathway, such as peroxidase, Fe-Mn superoxide dismutase, catechol 1,2-dioxygenase, protocatechuate 3, 4-dioxygenase, etc. The expression levels of these genes were higher when strain S12 was grown in a medium with lignin as the unique carbon source than in a medium with glucose as the unique carbon source. Also, strain S12 has a complete cellulose degradation and ethanol generation pathway. Conclusion: Raoultella ornithinolytica S12 has the ability to degrade lignocellulose effectively, which is significant in promoting the development of the lignocellulose application industry.

Complete Genome Sequence of Raoultella ornithinolytica Strain S12, a Lignin-Degrading Bacterium Isolated from Forest Soil.

We report the complete genome sequence of Raoultella ornithinolytica strain S12, isolated from a soil sample collected from areas bordering rotten wood and wet soil on Mt. Zijin, Nanjing. The complete genome of this bacterium may contribute toward the discovery of efficient lignin-degrading pathways.