Zhujun Jiang

T cells in tumors and provoke a strong antitumor immune response toward primary and abscopal tumors in B16-OVA and CT26 tumor-bearing mice models. The cooperative self-assembled nanoparticle strategy provides a potential candidate of nanomedicine to advance the synergistic cancer chemo-immunotherapy.

PURPOSE: Targeting oncogenic receptors with antibodies has been thought to suppress tumor growth mainly by interrupting oncogenic signals. Recently, the essential role for adaptive immunity, and CD8(+) T cells in particular, has been established as a major factor for anti-HER2/neu-mediated tumor regression. However, the role of CD4(+) T cells is still being defined. The purpose of this study was to explore whether and to what extent CD4(+) T cells are involved in mediating the effects of anti-HER2/neu therapy. EXPERIMENTAL DESIGN: The role of CD4(+) T cells was examined using a transplant model of the rat HER2/neu-overexpressing cell line TUBO. Tumor-bearing mice were treated with anti-neu therapy in conjunction with CD4 depletion or CD40L blockade. The effects of CD4 depletion on the antitumor response were examined by tumor growth analysis and enzyme-linked immunospot (ELISPOT). RESULTS: In addition to CD8(+) T cells, CD4(+) T cells are also essential for anti-neu antibody-mediated tumor regression, but B cells are not required. The role for CD4(+) cells is necessary throughout anti-neu therapy and not limited to helping CD8(+) T cells. Expression of IFN-γ is necessary for anti-neu therapy and IFN-γ induces MHC-II expression in TUBO cells promoting direct recognition by CD4(+) T cells. Furthermore, intratumoral depletion of CD4(+) T cells or blockade of the activating cell-surface protein CD40L inhibits the antitumor response. CONCLUSIONS: This study reveals the essential role of CD4(+) T cell for anti-neu-mediated tumor regression.

Targeted degradation of proteins has emerged as a powerful method for modulating protein homeostasis. Identification of suitable degraders is essential for achieving effective protein degradation. Here, we present a non-covalent degrader construction strategy, based on a modular supramolecular co-assembly system consisting of two self-assembling peptide ligands that bind cell membrane receptors and the protein of interest simultaneously, resulting in targeted protein degradation. The developed lysosome-targeting co-assemblies (LYTACAs) can induce lysosomal degradation of extracellular protein IL-17A and membrane protein PD-L1 in several scavenger receptor A-expressing cell lines. The IL-17A-degrading co-assembly has been applied in an imiquimod-induced psoriasis mouse model, where it decreases IL-17A levels in the skin lesion and alleviates psoriasis-like inflammation. Extending to asialoglycoprotein receptor-related protein degradation, LYTACAs have demonstrated the versatility and potential in streamlining degraders for extracellular and membrane proteins.

Metastasis is the leading cause of death in breast cancer patients. However, the mechanisms underlying metastasis are not well understood and there is no effective treatment in the clinic. Here, we demonstrate that in MMTV-PyMT, a highly malignant spontaneous breast tumor model, IL-25 (also called IL-17E) was expressed by tumor-infiltrating CD4+ T cells and macrophages. An IL-25 neutralization antibody, while not affecting primary tumor growth, substantially reduced lung metastasis. Inhibition of IL-25 resulted in decreased type 2 T cells and macrophages in the primary tumor microenvironments, both reported to enhance breast tumor invasion and subsequent metastasis to the lung. Taken together, our data suggest IL-25 blockade as a novel treatment for metastatic breast tumor.