SUMMARY Antibodies (Abs) that preferentially target oncogenic receptors have been increasingly used for cancer therapy, but tumors often acquire intrinsic Ab-resistance after prolonged and costly treatment. Here, we arm the Ab with IFNβ and observed that it is more potent than first generation of Ab for controlling Ab-resistant tumors. This strategy controls Ab-resistance by rebridging suppressed innate and adaptive immunity in tumor microenvironment. Mechanistically, Ab-IFNβ therapy primarily and directly targets intra-tumoral dendritic cells, which re-activate CTL by increasing antigen cross presentation within the tumor microenvironment. Additionally, blocking PD-L1, which is induced by Ab-IFNβ treatment, overcomes treatment-acquired resistance and completely eradicates established tumors. Therefore, this study establishes a nextgeneration Ab-based immunotherapy that targets and eradicates established Ab-resistant tumors.
Accumulating evidence has demonstrated that myeloid-derived suppressor cells (MDSCs), a heterogeneous population of cells, play an important role in the subversion, inhibition, and downregulation of the immune response to cancer. However, the characteristics of these cells, particularly clinical relevance, in malignant tumors remain unclear due to a lack of specific markers. In this study, we characterized peripheral CD14(+)HLA-DR(-/low) cells, a new human MDSC subpopulation, in 89 patients with non-small cell lung cancer (NSCLC). As expected, both frequency and absolute number of CD14(+)HLA-DR(-/low) cells were significantly increased in the peripheral blood of NSCLC patients compared with that of the healthy controls and indicated an association with metastasis, response to chemotherapy, and progression-free survival. These cells showed decreased expression of CD16 and CD86 compared with HLA-DR(+) monocytes. Unlike classical monocytes, these populations showed significantly decreased allostimulatory activity and showed the ability to inhibit autologous T cell proliferation and IFN-γ production in a cell-contact-dependent manner. Furthermore, we demonstrated that CD14(+)HLA-DR(-/low) cells expressed the NADPH oxidase component gp91(phox) and generated high level of reactive oxygen species (ROS). Moreover, inactivation of ROS reversed their immunosuppressive capacity on T cell response. These results prove, for the first time, the existence of ROS-producing CD14(+)HLA-DR(-/low) myeloid-derived suppressor cells in NSCLC patients, which mediate tumor immunosuppression and might thus represent a potential target for therapeutic intervention.
Flaviviruses are a group of human pathogenic, enveloped RNA viruses that includes dengue (DENV), yellow fever (YFV), West Nile (WNV), and Japanese encephalitis (JEV) viruses. Cross-reactive antibodies against Flavivirus have been described, but most of them are generally weakly neutralizing. In this study, a novel monoclonal antibody, designated mAb 2A10G6, was determined to have broad cross-reactivity with DENV 1–4, YFV, WNV, JEV, and TBEV. Phage-display biopanning and structure modeling mapped 2A10G6 to a new epitope within the highly conserved flavivirus fusion loop peptide, the 98DRXW101 motif. Moreover, in vitro and in vivo experiments demonstrated that 2A10G6 potently neutralizes DENV 1–4, YFV, and WNV and confers protection from lethal challenge with DENV 1–4 and WNV in murine model. Furthermore, functional studies revealed that 2A10G6 blocks infection at a step after viral attachment. These results define a novel broadly flavivirus cross-reactive mAb with highly neutralizing activity that can be further developed as a therapeutic agent against severe flavivirus infections in humans.
Background:The epitope and the TNF␣ inhabitation mechanism of Adalimumab remain unclear. Results: The crystal structure of the TNF␣ in complex with Adalimumab is reported at a resolution of 3.1 Å. Conclusion:The epitope of Adalimumab provided information that Adalimumab may have clinical advantage compared with Infliximab. Significance: These data reveal the Adalimumab's mechanism of TNF␣ inhibition and its advantages compared with other TNF inhibitors in clinical practice. TNF␣-targeting therapy with the use of the drugs Etanercept, Infliximab, and Adalimumab is used in the clinical treatment of various inflammatory and immune diseases. Although all of these reagents function to disrupt the interaction between TNF␣ and its receptors, clinical investigations showed the advantages of Adalimumab treatment compared withEtanercept and Infliximab. However, the underlying molecular mechanism of action of Adalimumab remains unclear. In our previous work, we presented structural data on how Infliximab binds with the E-F loop of TNF␣ and functions as a TNF␣ receptorbinding blocker. To further elucidate the variations between TNF␣ inhibitors, we solved the crystal structure of TNF␣ in complex with Adalimumab Fab. The structural observation and the mutagenesis analysis provided direct evidence for identifying the Adalimumab epitope on TNF␣ and revealed the mechanism of Adalimumab inhibition of TNF␣ by occupying the TNF␣ receptor-binding site. The larger antigenantibody interface in TNF␣ Adalimumab also provided information at a molecular level for further understanding the clinical advantages of Adalimumab therapy compared with Infliximab.TNF is an immunity-modulating cytokine required for immune processes. The unregulated activities of TNFs can lead to the development of inflammatory diseases. Excess amounts of TNF␣ expressed in cells are associated with the development of immune diseases, including rheumatoid arthritis, Crohn's disease, psoriatic arthritis, and inflammatory bowel disease (1, 2). The function of TNF␣ requires smooth interaction with its two receptors, TNF receptor 1 (TNFR1) 4 and TNF receptor 2 (TNFR2). Blocking the interaction between TNF␣ and TNFRs has successfully been developed as a therapy in treating inflammatory or autoimmune diseases (3,4). TNF␣ neutralization therapies, including the use of a soluble TNFR2-Fc recombinant (Etanercept), a mouse-human chimera mAb (Infliximab), or a human mAb (Adalimumab), have been introduced in the past decades for the management of rheumatoid arthritis and other immune diseases (5).Although all of these TNF␣ blockers function by interrupting the TNF␣-TNFR interaction, information on whether the different TNF␣ inhibitors have similar clinical efficacy remains controversial because of the lack of randomized clinical trial meta-analyses. In the early stages of clinical usage of Infliximab, its discontinuation was reported to result in loss of response. This largely affected patients who received long term treatment and later discontinued use (6). Approximately 10% of...
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