Production of bioactive, SUMO-modified, and native-like TNF-α of the rhesus monkey, Macaca mulatta, in Escherichia coli

PDGFRβ-Antagonistic Affibody-Mediated Tumor-Targeted Tumor Necrosis Factor-Alpha for Enhanced Radiotherapy in Lung Cancer

The morbidity and mortality of lung cancer are still the highest among all malignant tumors. Radiotherapy plays an important role in clinical treatment of lung cancer. However, the effect of radiotherapy is not ideal due to the radiation resistance of tumor tissues. Abnormalities in tumor vascular structure and function affect blood perfusion, and oxygen transport is impeded, making tumor microenvironment hypoxic. Tumor hypoxia is the major cause of radiotherapy resistance. By promoting tumor vessel normalization and enhancing vascular transport function, tumor hypoxia can be relieved to reduce radiotherapy resistance and increase tumor radiotherapy sensitivity. In our previous study, a pericytes-targeted tumor necrosis factor alpha (named Z-TNFα) was first constructed and produced by genetically fusing the platelet-derived growth factor receptor β (PDGFRβ)-antagonistic affibody (ZPDGFRβ) to the TNFα, and the Z-TNFα induced normalization of tumor vessels and improved the delivery of doxorubicin, enhancing tumor chemotherapy. In this study, the tumor vessel normalization effect of Z-TNFα in lung cancer was further clarified. Moreover, the tumor hypoxia improvement and radiosensitizing effect of Z-TNFα were emphatically explored in vivo. Inspiringly, Z-TNFα specifically accumulated in Lewis lung carcinoma (LLC) tumor graft and relieved tumor hypoxia as well as inhibited HIF-1α expression. As expected, Z-TNFα significantly increased the effect of radiotherapy in mice bearing LLC tumor graft. In conclusion, these results demonstrated that Z-TNFα is also a promising radiosensitizer for lung cancer radiotherapy.

Construction and characterization of a transmembrane eukaryotic expression vector based on the membrane domain structure of TNF-α

The aim of the present study was to construct a fast-acting, eukaryotic expression vector in eukaryotic cells based on transmembrane-tumor necrosis factor-α (TM-TNF-α) structure. Two types of recombinant eukaryotic expression vectors were constructed, pcDNA3.1-TM-enterokinase-TNF-α and pcDNA3.1-TM-Factor Xa-TNF-α, according to the TNF-α transmembrane segments. Following the generation of these vectors, mouse embryonic 3T3 fibroblasts were transfected and reverse transcription-polymerase chain reaction and western blotting analyses were used to analyze mTNF-α mRNA and protein expression levels, respectively, in total cellular protein extracts and extracellular fluid. The biological activity of TNF-α in the extracellular fluid was then measured using an MTT assay. The vectors were successfully constructed, and mRNA and fusion proteins were detected in the 3T3 cells. Among the fusion proteins, the one observed in pcDNA3.1-TM-FactorXa-TNF-α-transfected 3T3 cells remained as a transmembrane protein. In addition, treatment of L929 cells with TNF-α derived extracellular fluid samples from pcDNA3.1-TM-FactorXa-TNF-α-transfected 3T3 cells was associated with a dose-dependent reduction in in cell-specific activity. The results indicate that proteins expressed using pcDNA3.1-TM-FactorXa-TNF-α vectors form transmembrane proteins. In addition, the results indicate that, only when coupled with FactorXa activity, the extracellular region of TM-TNF-α forms s-TNF-α, and the controlled expression of the fusion protein is initiated.

Molecular cloning, recombinant expression and characterization of GMCSF from the rhesus monkey, Macaca mulatta

Recent studies have found that, in addition to hematopoiesis, granulocyte-macrophage colony-stimulating factor (GMCSF) plays pivotal roles in multiple immune disorders. The gene encoding Macaca mulatta GMCSF (mmGMCSF) was cloned from stimulated peripheral blood mononuclear cells (PBMCs). Concanavalin A (Con A) and mismatched allogeneic antigen-stimulation significantly increased the production of mmGMCSF by monkey PBMCs. The gene encoding mature mmGMCSF was first expressed as a soluble fusion protein in Escherichia coli, and native mmGMCSF was further prepared by protease cleavage. The recombinant mmGMCSF induced antigen-presenting dendritic cells from monkey PBMCs, suggesting a central role of mmGMCSF in the immune system of the rhesus monkey. Although the predicted mature mmGMCSF protein differs from human GMCSF (hGMCSF) at six amino acid residues, mmGMCSF showed a strong ability to support human TF-1 cell survival. Additional co-immunoprecipitation experiments revealed that mmGMCSF cross reacts with the hGMCSF receptor (hGMCSFR). In addition, the hGMCSF-neutralizing agents hGMCSFR-Fc and anti-hGMCSF antibody reduced the biological effects of mmGMCSF on TF-1 cells. These results suggest that recombinant mmGMCSF might be used for the in vitro evaluation of novel hGMCSF-neutralizing agents prior to the in vivo preclinical evaluation of these agents in the rhesus monkey model.