Nanoparticulate Cationic Poly(amino acid)s Block Cancer Metastases by Destructing Neutrophil Extracellular Traps.

Cancer metastasis that is resistant to conventional therapies has become a major cause of patient death. Recent reports indicate that the neutrophil extracellular trap (NET) is closely associated with cancer distant metastases, and the cell-free DNA of NETs has been identified as the ligand of the transmembrane protein CCDC25 of cancer cells, acting as a chemokine to induce cancer cell migration to distant organs. In this work, we present the poly(aspartic acid) based-cationic materials to interfere with the interaction between NET-DNA and CCDC25, and furthermore to inhibit NET-DNA-mediated cancer cell chemotaxis and migration. Because of a stronger binding affinity to DNA and favorable retention in the liver, nanoparticulate poly(aspartic acid) derivatives (cANP) efficiently reduce the level of hepatic NET-DNA infiltration, leading to a significant suppression of cancer metastases in mice and several human metastatic models. Moreover, the cANP exhibits no toxicity to organs of animals during the entire treatment. Thus, this work suggests a strategy for controlling cancer metastases, which will benefit patients in clinics.

Integrated analysis of NET-DNA receptor CCDC25 in malignant tumors: Pan-cancer analysis.

Background: Previously, it was reported that the coiled-coil domain containing 25 (CCDC25) plays a role in the formation of neutrophil extracellular traps (NETs). This study systematically analyzed the expression profiles of CCDC25 in 30 different types of cancer and one type of blood cancer, acute myeloid leukemia. Methods: The GTEx and CCLE databases were used to evaluate the distribution of CCDC25 expression in both normal tissue and cancer cell lines. A comparison was performed between normal tissue and tumor tissue to analyze the differential expression of CCDC25. We assessed the impact of CCDC25 on the clinical outlook in the TCGA pan-cancer data set by analyzing the Kaplan-Meier survival plot and conducting COX regression analysis. Moreover, the association between the expression levels of CCDC25 and the tumor microenvironment in multiple cancers was conducted. Additionally, the investigation also examined the link between CCDC25 and immune neoantigen, tumor mutational burden, microsatellite instability, mismatch repair genes (MMRs), HLA-related genes, and DNA methyltransferase (DNMT). Results: CCDC25 was expressed in nearly all of the 31 normal tissues while exhibiting a moderate to low level of expression in cancer cell lines. While abnormal expression was detected in the majority of malignancies, there was no link found between elevated CCDC25 levels and overall survival, disease-free survival, recurrence-free survival, and disease-free interval in the TCGA comprehensive cancer data set. Nevertheless, the expression of CCDC25 exhibited a notable link with the infiltration levels of activated CD4 memory T cells, quiescent mast cells, dendritic cells in an activated state, T cells that assist in follicle development, M2 macrophages, and neutrophils in various tumors. Conclusions: In most cancers, the results indicate that there is no link between CCDC25 and prognosis. However, CCDC25 can be targeted for therapeutic purposes concerning metastasis and immune infiltration.