Dual character of Toll-like receptor signaling: Pro-tumorigenic effects and anti-tumor functions

As a major class of pattern-recognition receptors, Toll-like receptors (TLRs) play a critical role in defense against invading pathogens. Increasing evidence demonstrates that, in addition to infection, TLRs are involved in other important pathological processes, such as tumorigenesis. Activation of TLRs results in opposing outcomes, pro-tumorigenic effects and anti-tumor functions. TLR signaling can inhibit apoptosis and promote chronic inflammation-induced tumorigenesis. TLR activation in tumor cells and immune cells can induce production of cytokines, increase tumor cell proliferation and apoptosis resistance, promote invasion and metastasis, and inhibit immune cell activity resulting in tumor immune escape. In contrast, the engagement of other TLRs directly induces growth inhibition and apoptosis of tumor cells and triggers activation of immune cells enhancing anti-tumor immune responses. Thus, the interpretation of the precise function of each TLR in tumors is very important for targeting TLRs and using TLR agonists in tumor therapy. We review the role of TLR signaling in tumors and discuss the factors that affect outcomes of TLR activation.     

Immune-mediated eradication of tumors through the blockade of transforming growth factor-beta signaling in T cells

Despite the existence of tumor-specific antigens and demonstrated presence of tumor-specific immune cells, the majority of tumors manage to avoid immune-mediated destruction. Various mechanisms have been suggested for tumor evasion from immune response. One such mechanism is thought to be mediated by transforming growth factor-beta (TGF-beta), an immunosuppressive cytokine found at the site of most tumors. We demonstrate here that T-cell-specific blockade of TGF-beta signaling allows the generation of an immune response capable of eradicating tumors in mice challenged with live tumor cells. In addition, we provide mechanisms through which abrogation of TGF-beta signaling leads to the enhancement of anti-tumor immunity. Our data indicate that T-cell-specific blockade of TGF-beta signaling has strong therapeutic potential to shift the balance of the immune response in favor of anti-tumor immunity.     

TLR4信号转导通路在肿瘤中的作用

慢性炎症与恶性肿瘤密切相关,Toll样受体4（TLR4）在肿瘤中的广泛表达提示其在慢性炎症致瘤机制中发挥重要作用。活化肿瘤细胞TLR4不仅促进肿瘤的生成和转移,而且参与肿瘤的免疫逃逸。另一方面,免疫佐剂又通过激活免疫细胞的TLR4信号产生抗肿瘤免疫。因此,TLR4在肿瘤中起着双刃剑的作用。     

Functions and clinical implications of exosomes in pancreatic cancer

Pancreatic cancer is one of the most aggressive human malignancies and is associated with a dismal prognosis, which can be contributed to its atypical symptoms, metastatic propensity, and significant chemoresistance. Emerging evidence shows that pancreatic cancer cell-derived exosomes (PEXs) play critical roles in tumorigenesis and tumor development, as they are involved in drug resistance, immune evasion and metabolic reprograming, and distant metastasis of pancreatic cancer. Their numerous differentially expressed and functional contents make PEXs promising screening tools and therapeutic targets, which require further exploration. In this review, we focus on the functions of PEX contents and their clinical implications in pancreatic cancer.     

Fas Ligand Promotes Tumor Immune Evasion of Colon Cancer In Vivo

The study of the role of Fas ligand (FasL/CD95L) in tumor immune evasion has been complicated by the discovery that FasL may trigger cytokine secretion and induce inflammation. Antisense suppression of FasL expression by colon tumor cells was used to investigate if a reduction in endogenously expressed FasL in tumors resulted in reduced tumor development and improved anti-tumor immune challenge in vivo. Downregulation of FasL expression had no effect on tumor growth in vitro but significantly reduced tumor development in syngeneic immune-competent mice in vivo. Tumor size was also significantly decreased. Reduced FasL expression by tumor cells was associated with increased lymphocyte infiltration. Moreover, constitutively expressed FasL was not pro-inflammatory. This study indicates that upregulation of FasL expression by colon tumor cells results in an improved anti-tumor immune challenge in vivo, providing functional evidence in favor of the ‘Fas counterattack’ as a mechanism of tumor immune evasion.     

Poxviruses: Capturing Cytokines and Chemokines

Cytokines play a critical role in the regulation of immune responses and constitute important targets for virus immune evasion mechanisms. One strategy used by large DNA viruses is to encode proteins that mimic cytokines or cytokine receptors, which modulate the activity of cytokines during infection. Poxviruses encode a unique set of proteins that are secreted from the infected cell and function as soluble cytokine receptors or binding proteins and sequester tumor necrosis factor, interleukin-1β, or chemokines. Characterization of these poxvirus proteins is providing information on virus pathogenesis, the function of cytokines, and new strategies for immune modulation and therapeutic intervention.     

Selective autophagy of MHC-I promotes immune evasion of pancreatic cancer

ABSTRACT

Major histocompatibility complex class I (MHC-I) is a key molecule in anti-tumor adaptive immunity. MHC-I is essential for endogenous antigen presentation by cancer cells and subsequent recognition and clearance by CD8⁺ T cells. Defects in MHC-I expression occur frequently in several cancers, leading to impaired antigen presentation, immune evasion and/or resistance to immune checkpoint blockade (ICB) therapy. Pancreatic ductal adenocarcinoma (PDAC), a deadly malignancy with dismal patient prognosis, is resistant to ICB and shows frequent downregulation of MHC-I independent of genetic mutations abrogating MHC-I expression. Previously, we showed that PDAC cells exhibit elevated levels of autophagy and lysosomal biogenesis, which together support the survival and growth of PDAC tumors via both cell-autonomous and non-cell-autonomous mechanisms. In our recent study, we have identified NBR1-mediated selective macroautophagy/autophagy of MHC-I as a novel mechanism that facilitates immune evasion by PDAC cells. Importantly, autophagy or lysosome inhibition restores MHC-I expression, leading to enhanced anti-tumor T cell immunity and improved response to ICB in transplanted tumor models in syngeneic host mice. Our results highlight a previously unknown function of autophagy and the lysosome in regulation of immunogenicity in PDAC, and provide a novel therapeutic strategy for targeting this deadly disease.     

The combination therapy of oncolytic HSV-1 armed with anti-PD-1 antibody and IL-12 enhances anti-tumor efficacy

Cancer immunotherapy is a new therapeutic strategy for cancer treatment that targets tumors by improving or restoring immune system function. Therapies targeting immune checkpoint molecules have exerted potent anti-tumor effects and prolonged the overall survival rate of patients. However, only a small number of patients benefit from the treatment. Oncolytic viruses exert anti-tumor effects by regulating the tumor microenvironment and affecting multiple steps of tumor immune circulation. In this study, we engineered two oncolytic viruses that express mouse anti-PD-1 antibody (VT1093M) or mouse IL-12 (VT1092M). We found that both oncolytic viruses showed significant anti-tumor effects in a murine CT26 colon adenocarcinoma model. Importantly, the intratumoral combined injection with VT1092M and VT1093M inhibited growth of the primary tumor, prevented growth of the contralateral untreated tumor, produced a vaccine-like response, activated antigen-specific T cell responses and prolonged the overall survival rate of mice. These results indicate that combination therapy with the engineered oncolytic virus may represent a potent immunotherapy strategy for cancer patients, especially those resistant to PD-1/PD-L1 blockade therapy.     

Tumor draining lymph nodes,immune response,and radiotherapy: Towards a revisal of therapeutic principles

The tumor-draining lymph nodes (TDLNs) are the primary sites of the development of anti-tumor immunity. Primary tumor irradiation promotes ‘radio-vaccination’ by enhancing the release of tumor antigens and activating the interferon type-I pathway. Activated intratumoral dendritic cells (DCs) enter the lymphatics to reach the TDLNs. The adaptive anti-tumor immune responses are developed, as DCs will present tumor-related antigens to activate CD4+ and CD8+ T-cells. Strong experimental evidence suggests that post-irradiation tumor clearance is strongly dependent on the accumulation of such cytotoxic T-cells in the tumors. However, TDLNs are heavily irradiated during Radiotherapy to eradicate the clinical and subclinical metastatic disease. At the same time, irradiation depletes the critical immune cell population residing in TDLNs and primary tumors, blocking immune response and compromising the effectiveness of immuno-stimulatory interventions. Since TDLNs are essential for T-cell activation by inbound dendritic cells previously activated in the tumor environment, the practice of TDLN-irradiation demands re-evaluation. Interventions to preserve and handle the functional state of regional TDLNs or remote nodes, during or after Radiotherapy, may have great therapeutic importance. TDLNs represent the main playground for educating and expanding tumor-specific cytotoxic immune cells and controlling a delicate balance between immune surveillance and tumor spread. Their activation state may define the outcome of Radiotherapy and the manifestation of abscopal effects. In this critical review, we present the biological and clinical role of TDLNs and propose strategies to include in the design of immuno-radiotherapy trials aiming to eradicate cancer at a local and distant level.     

Emerging role of metabolic reprogramming in tumor immune evasion and immunotherapy

Mounting evidence has revealed that the therapeutic efficacy of immunotherapies is restricted to a small portion of cancer patients. A deeper understanding of how metabolic reprogramming in the tumor microenvironment(TME) regulates immunity remains a major challenge to tumor eradication. It has been suggested that metabolic reprogramming in the TME may affect metabolism in immune cells and subsequently suppress immune function. Tumor cells compete with infiltrating immune cells for nutrients and metabolites. Notably, the immunosuppressive TME is characterized by catabolic and anabolic processes that are critical for immune cell function, and elevated inhibitory signals may favor cancer immune evasion. The major energy sources that supply different immune cell subtypes also undergo reprogramming. We herein summarize the metabolic remodeling in tumor cells and different immune cell subtypes and the latest advances underlying the use of metabolic checkpoints in antitumor immunotherapies. In this context, targeting both tumor and immune cell metabolic reprogramming may enhance therapeutic efficacy.     

Metronomic cyclophosphamide treatment in metastasized breast cancer patients: immunological effects and clinical outcome

Severe immune suppression is frequent in late-stage tumor patients and promotes tumor immune evasion and subsequent tumor progression. Regulatory T cells (Treg) are major suppressors of anti-tumor immune responses. Therefore, targeting of Treg has become a key goal of anti-tumor therapy. Several preclinical and clinical observations suggest that Treg can be depleted by cyclophosphamide. Over a period of 3?months, we investigated the effect of metronomic low-dose cyclophosphamide on Treg numbers, suppressive capacity and proliferation on endogenous anti-tumor T-cell responses and on their correlation to clinical outcome in 12 patients with treatment-refractory metastasized breast cancer who received single-agent 50?mg cyclophosphamide p.o. daily. Cyclophosphamide treatment initially caused a significant reduction in circulating Treg by more than 40% (P?=?0.002). However, Treg numbers completely recovered during the treatment due to increased proliferative activity and maintained their suppressive capacity. Treg depletion coincided with a strong increase in breast tumor-reactive T cells (P?=?0.03) that remained at high levels during the whole period. Numbers of tumor-reactive T cells but not of Treg correlated with disease stabilization (P?=?0.03) and overall survival (P?=?0.027). We conclude that metronomic low-dose cyclophosphamide only transiently reduces Treg but induces stable tumor-specific T-cell responses, which correlate with improved clinical outcome in advanced-stage breast cancer patients.     

Pro-tumorigenic function of autophagy in mammary oncogenesis

Autophagy is a highly conserved catabolic cellular process by which cells degrade intracellular constituents in lysosomes, and its dysfunctions have been associated with a variety of human diseases including cancer. Previous studies have linked autophagy to both tumor-suppressive and promoting functions in different contexts, although the pro-tumorigenic function of autophagy has not been examined directly in breast or other cancers in animal models with intact immune functions in vivo. FIP200 (focal adhesion kinase family interacting protein of 200 kD) is a component of the ULK1-Atg13-FIP200-Atg101 complex that is essential for the induction of mammalian autophagy. In our recent study, we show that conditional knockout (KO) of FIP200 in the well-characterized MMTV-PyMT mouse model of human breast cancer significantly suppresses mammary tumorigenesis and progression. Similar to a number of recent studies in Ras-transformed cells, our studies revealed the importance of autophagy in promoting tumorigenesis through regulation of tumor cell glycolysis and proliferation. In addition to the intrinsic defects in proliferation of FIP200-null tumor cells, we also showed that FIP200 deletion in mammary tumor cells triggers increased host anti-tumor immune surveillance, which also contributes to the decreased mammary tumorigenesis and progression. Our study provides the first direct demonstration of a pro-tumorigenic role of autophagy in oncogene-driven tumor models with intact immune functions in vivo. They also suggest FIP200 and other autophagy proteins as potential therapeutic targets for cancer treatment, and raise a number of questions for future studies on the potentially dual functions of autophagy in promoting and suppressing tumorigenesis under different conditions in vivo.     

Comparative analysis of IFN-gamma B7.1 and antisense TGF-beta gene transfer on the tumorigenicity of a poorly immunogenic metastatic mammary carcinoma

Cancer progression is attributed in part to immune evasion strategies that include lack of co-stimulation, down-regulation of cell surface MHC molecules, and secretion of immunosuppressive factors, such as transforming growth factor-beta (TGF-beta). Gene therapy has been employed to counter these mechanisms of immune evasion by transference of B7.1, IFN-gamma or antisense TGF-beta genes into tumor cells, resulting in cell surface expression of B7.1, upregulation of MHC class I and class II molecules, or elimination of tumor-derived TGF-beta, respectively. Although each of these transgenes has been shown to alter tumorigenicity in murine models, a direct comparison of their efficacy has not been performed. In this study, we have employed a very aggressive, poorly immunogenic and highly metastatic mammary model, 4T1, to compare the efficacy of B7.1, IFN-gamma and antisense TGF-beta gene transfer in stimulating an anti-tumor response. We demonstrate that both IFN-gamma and antisense TGF-beta gene expression significantly reduced the tumorigenicity of these cells compared to mock transduced cells, with IFN-gamma having a greater effect. In contrast, B7.1 gene transfer did not affect the tumorigenicity of 4T1 cells. The anti-tumor response directed against antisense TGF-beta-expressing 4T1 tumors was mediated by CD4+ and CD8+ T cells. However, CD8+ T cells, and not CD4+ T cells, appeared to mediate the anti-tumor response against IFN-gamma-expressing tumors. Treatment of tumor-bearing animals with IFN-gamma or antisense TGF-beta gene-modified tumor cell vaccines reduced the number of clonogenic metastases to the lungs and liver compared to treatment with mock-transduced cells. Finally, in a residual disease model in which the primary tumor was excised and mice were vaccinated with irradiated tumor cells, treatment of mice with vaccinations consisting of 4T1 cells expressing both antisense TGF-beta and IFN-gamma genes was the most effective in prolonging survival.     

STING-mediated DNA sensing in cancer immunotherapy

While STING(STimulator of INterferon Genes) has been shown to be essential for cytosolic DNA-triggered innate immune activation, accumulated evidence obtained from various studies suggested that an intrinsic relevance of STING-associated signaling in tumorigenesis can be observed. Also, several clinical trials using immunostimulatory adjuvants, particularly agonistic as well as non-agonistic ligands for STING, have revealed their therapeutic potential not only as vaccine adjuvants but also as anti-tumor agents. However, cases have also been reported where the involvement of STING shows a protective role in tumor growth. Here we summarize recent findings that have pointed towards the STING pathway as an innate immune sensing mechanism driving type I interferon production in the tumor context. Better understanding of this pathway can guide further development of novel immunotherapeutic strategies in the treatment of cancer.     

肿瘤相关巨噬细胞极化的研究进展

肿瘤相关巨噬细胞是肿瘤组织局部浸润的巨噬细胞,在肿瘤组织微环境中,这些巨噬细胞发生M2型极化,从而发挥免疫抑制效应,促进肿瘤增殖。而M2型极化的肿瘤相关巨噬细胞也能够被再次诱导逆向极化形成具有抗肿瘤效应的M1型肿瘤相关巨噬细胞,激发机体产生特异性抗肿瘤免疫应答。促进肿瘤相关巨噬细胞M1型极化由此成为当前抗肿瘤免疫防治研究的热点。将对有关肿瘤相关巨噬细胞极化的新进展进行综述,为抗肿瘤免疫研究提供新的思路。     

Macrophage polarity in cancer: A review

Macrophages are the most abundant cells within the tumor stroma displaying noticeable plasticity, which allows them to perform several functions within the tumor microenvironment. Tumor-associated macrophages commonly refer to an alternative M2 phenotype, exhibiting anti-inflammatory and pro-tumoral effects. M2 cells are highly versatile and multi-tasking cells that directly influence multiple steps in tumor development, including cancer cell survival, proliferation, stemness, and invasiveness along with angiogenesis and immunosuppression. M2 cells perform these functions through critical interactions with cells related to tumor progression, including Th2 cells, cancer-associated fibroblasts, cancer cells, regulatory T cells (Tregs), and myeloid-derived suppressor cells. M2 cells also have negative cross-talks with tumor suppressor cells, including cytotoxic T cells and natural killer cells. Programed death-1 (PD-1) is one of the key receptors expressed in M2 cells that, upon interaction with its ligand PD-L1, plays cardinal roles for induction of immune evasion in cancer cells. In addition, M2 cells can neutralize the effects of the pro-inflammatory and anti-tumor M1 phenotype. Classically activated M1 cells express high levels of major histocompatibility complex molecules, and the cells are strong killers of cancer cells. Therefore, orchestrating M2 reprogramming toward an M1 phenotype would offer a promising approach for reversing the fate of tumor and promoting cancer regression. Macrophage switching toward an anti-inflammatory M1 phenotype could be used as an adjuvant with other approaches, including radiotherapy and immune checkpoint blockades, such as anti-PD-L1/PD-1 strategies.     

CD4+CD25+ T regulatory cells dominate multiple immune evasion mechanisms in early but not late phases of tumor development in a B cell lymphoma model

Tumors use a complex set of direct and indirect mechanisms to evade the immune system. Naturally arising CD4(+)CD25(+)FoxP3(+) T regulatory (Treg) cells have been implicated recently in tumor immune escape mechanism, but the relative contribution of these cells to overall tumor progression compared with other immune evasion mechanisms remains to be elucidated. Using the A20 B cell lymphoma as a transplantable tumor model, we demonstrate that this tumor employs multiple direct (expression of immunoinhibitory molecule PD-L1, IDO, and IL-10, and lack of expression of CD80 costimulatory molecule) and indirect (down-regulation of APC function and induction of Treg cells) immune evasion mechanisms. Importantly, Treg cells served as the dominant immune escape mechanism early in tumor progression because the physical elimination of these cells before tumor challenge resulted in tumor-free survival in 70% of mice, whereas their depletion in animals with established tumors had no therapeutic effect. Therefore, our data suggest that Treg cells may serve as an important therapeutic target for patients with early stages of cancer and that more vigorous combinatorial approaches simultaneously targeting multiple immune evasion as well as immunosurveillance mechanisms for the generation of a productive immune response against tumor may be required for effective immunotherapy in patients with advanced disease.     

The tumor immunosuppressive microenvironment impairs the therapy of anti-HER2/neu antibody

It has been well established that immune surveillance plays critical roles in preventing the occurrence and progression of tumor. More and more evidence in recent years showed the host anti-tumor immune responses also play important roles in the chemotherapy and radiotherapy of cancers. Our previous study found that tumor- targeting therapy of anti-HER2/neu mAb is mediated by CD8⁺ T cell responses. However, we found here that enhancement of CD8⁺ T cell responses by combination therapy with IL-15R/IL-15 fusion protein or anti-CD40, which are strong stimultors for T cell responses, failed to promote the tumor therapeutic effects of anti-HER2/neu mAb. Analysis of tumor microenviornment showed that tumor tissues were heavily infiltrated with the immunosuppressive macrophages and most tumor infiltrating T cells, especially CD8⁺ T cells, expressed high level of inhibitory co-signaling receptor PD-1. These data suggest that tumor microenvironment is dominated by the immunosuppressive strategies, which thwart anti-tumor immune responses. Therefore, the successful tumor therapy should be the removal of inhibitory signals in the tumor microenvironment in combination with other therapeutic strategies.     

Cytokine-driven regulation of NK cell functions in tumor immunity: role of the MICA-NKG2D system

Natural killer (NK) cells are critical players during tumor growth control in immunocompetent hosts. These cells also establish a cross-talk with dendritic cells (DCs) and promote a Th1-mediated immunity. NKG2D is a pivotal receptor that directs the tumoricidal activity of NK cells through the recognition of a group of ligands such as MICA widely expressed on different tumors. Here we will review the most important tumor immune escape mechanisms that compromise the functionality of NKG2D and its cognate ligands, including TGF-beta secretion, tumor shedding of soluble MICA, and additional mechanisms that compromise the tumoricidal activity of NKG2D-expressing cells. Such mechanisms may also dampen the cross-talk between NK cells and DCs during the anti-tumor immune responses. Recent knowledge may lead to innovative approaches to promote efficient NK cell-mediated anti-tumor immune responses.