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Immunotherapy has become the major treatment for tumors in clinical practice, but some intractable problems such as the low response rate and high rates of immune-related adverse events still hinder the progress of tumor immunotherapy. Hence, it is essential to explore additional immunotherapy treatment targets. In this review, we focus on the structure, expression and expression-related mechanisms, interactions, biological functions and the progress in preclinical/clinical research of IGSF11 and VISTA in tumors. We cover the progress in recent research with this pair of immune checkpoints in tumor immune regulation, proliferation, immune resistance and predictive prognosis. Both IGSF11 and VISTA are highly expressed in tumors and are modulated by various factors. They co-participate in the functional regulation of immune cells and the inhibition of cytokine production. Besides, in the downregulation of IGSF11 and VISTA, both inhibit the growth of some tumors. Preclinical and clinical trials all emphasize the predictive role of IGSF11 and VISTA in the prognosis of tumors, and that the predictive role of the same gene varies from tumor to tumor. At present, further research is proving the enormous potential of IGSF11 and VISTA in tumors, and especially the role of VISTA in tumor immune resistance. This may prove to be a breakthrough to solve the current clinical immune resistance, and most importantly, since research has focused on VISTA but less on IGSF11, IGSF11 may be the next candidate for tumor immunotherapy.
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Background: The mechanisms involved in the malignant progression of lung adenocarcinoma (LUAD) are still inconclusive. Fibrinogen-like protein 1 (FGL1) and LAG3 are a pair of immune checkpoints that create an inhibitory immune microenvironment in tumors. However, other roles of FGL1 in LUAD have not been extensively studied. Our study aims to explore the role of FGL1 in the malignant progression of LUAD and to provide new therapeutic targets and strategies for LUAD treatment. Methods: Differential gene expression of FGL1 was analyzed using the Gene Expression Profiling Interactive Analysis (GEPIA), Oncomine, UALCAN, and Gene Expression Omnibus (GEO) databases. A pan-cancer analysis was conducted using the Oncomine, TIMER, and UALCAN databases. A total of 140 tumor tissues and paired normal tissues were collected, IHC and immunofluorescence staining were used to explore the expression of FGL1. GeneMANIA database and STRING database were used to analyze gene-gene interaction and protein-protein interaction, respectively. A mutation analysis was conducted using the cBioPortal database, and an immune infiltration analysis was conducted using the TIMER database. A survival analysis was carried out using the GEPIA and PrognoScan database. The knockdown of FGL1 was confirmed by western blot (WB) and immunofluorescence staining. Cell proliferation was tested by cell cycle analysis and real-time cell analysis. RNA sequencing (RNA-seq) was used to explore the differential genes of FGL1 knockdown in LUAD cells. Results: Multiple databases showed that FGL1 was highly expressed in LUAD. The results of IHC indicated that FGL1 was highly expressed in the cytoplasm of LUAD cells. FGL1 was negatively associated with immune infiltration in LUAD. The main mutation of FGL1 is deep deletion, the altered group and high expression group indicated poor prognosis. The downregulation of FGL1 lead to a significantly decreased percentage of PC9 cells in S phase, but had little effect on the proliferation of Jurkat T cells. RNA-seq and GSEA analysis indicated that the differential genes were mainly enriched in MYC-target genes, which suggested that the downregulation of FGL1 inhibited cell proliferation by regulating MYC-target genes. Conclusions: FGL1 exerts in LUAD proliferation in addition to immune regulation. The downregulation of FGL1 inhibits the proliferation of LUAD cells by regulating MYC-target genes. Thus, FGL1 may be a novel therapeutic target in LUAD.
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This study highlights aspects of the latest clinical research conducted on the relationship between immune checkpoints and tumor metastasis. The overview of each immune checkpoint is divided into the following three sections: 1) structure and expression; 2) immune mechanism related to tumor metastasis; and 3) clinical research related to tumor metastasis. This review expands on the immunological mechanisms of 17 immune checkpoints, including TIM-3, CD47, and OX-40L, that mediate tumor metastasis; evidence shows that most of these immune checkpoints are expressed on the surface of T cells, which mainly exert immunomodulatory effects. Additionally, we have summarized the roles of these immune checkpoints in the diagnosis and treatment of metastatic tumors, as these checkpoints are considered common predictors of metastasis in various cancers such as prostate cancer, non-Hodgkin lymphoma, and melanoma. Moreover, certain immune checkpoints can be used in synergy with PD-1 and CTLA-4, along with the implementation of combination therapies such as LIGHT-VTR and anti-PD-1 antibodies. Presently, most monoclonal antibodies generated against immune checkpoints are under investigation as part of ongoing preclinical or clinical trials conducted to evaluate their efficacy and safety to establish a better combination treatment strategy; however, no significant progress has been made regarding monoclonal antibody targeting of CD28, VISTA, or VTCN1. The application of immune checkpoint inhibitors in early stage tumors to prevent tumor metastasis warrants further evidence; the immune-related adverse events should be considered before combination therapy. This review aims to elucidate the mechanisms of immune checkpoint and the clinical progress on their use in metastatic tumors reported over the last 5 years, which may provide insights into the development of novel therapeutic strategies that will assist with the utilization of various immune checkpoint inhibitors.
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LAG3 is the most promising immune checkpoint next to PD-1 and CTLA-4. High LAG3 and FGL1 expression boosts tumor growth by inhibiting the immune microenvironment. This review comprises four sections presenting the structure/expression, interaction, biological effects, and clinical application of LAG3/FGL1. D1 and D2 of LAG3 and FD of FGL1 are the LAG3-FGL1 interaction domains. LAG3 accumulates on the surface of lymphocytes in various tumors, but is also found in the cytoplasm in non-small cell lung cancer (NSCLC) cells. FGL1 is found in the cytoplasm in NSCLC cells and on the surface of breast cancer cells. The LAG3-FGL1 interaction mechanism remains unclear, and the intracellular signals require elucidation. LAG3/FGL1 activity is associated with immune cell infiltration, proliferation, and secretion. Cytokine production is enhanced when LAG3/FGL1 are co-expressed with PD-1. IMP321 and relatlimab are promising monoclonal antibodies targeting LAG3 in melanoma. The clinical use of anti-FGL1 antibodies has not been reported. Finally, high FGL1 and LAG3 expression induces EGFR-TKI and gefitinib resistance, and anti-PD-1 therapy resistance, respectively. We present a comprehensive overview of the role of LAG3/FGL1 in cancer, suggesting novel anti-tumor therapy strategies.