TNF‐α enhances TGF‐β‐induced endothelial‐to‐mesenchymal transition via TGF‐β signal augmentation

The tumor microenvironment (TME) consists of various components including cancer cells, tumor vessels, cancer‐associated fibroblasts (CAFs), and inflammatory cells. These components interact with each other via various cytokines, which often induce tumor progression. Thus, a greater understanding of TME networks is crucial for the development of novel cancer therapies. Many cancer types express high levels of TGF‐β, which induces endothelial‐to‐mesenchymal transition (EndMT), leading to formation of CAFs. Although we previously reported that CAFs derived from EndMT promoted tumor formation, the molecular mechanisms underlying these interactions remain to be elucidated. Furthermore, tumor‐infiltrating inflammatory cells secrete various cytokines, including TNF‐α. However, the role of TNF‐α in TGF‐β‐induced EndMT has not been fully elucidated. Therefore, this study examined the effect of TNF‐α on TGF‐β‐induced EndMT in human endothelial cells (ECs). Various types of human ECs underwent EndMT in response to TGF‐β and TNF‐α, which was accompanied by increased and decreased expression of mesenchymal cell and EC markers, respectively. In addition, treatment of ECs with TGF‐β and TNF‐α exhibited sustained activation of Smad2/3 signals, which was presumably induced by elevated expression of TGF‐β type I receptor, TGF‐β2, activin A, and integrin αv, suggesting that TNF‐α enhanced TGF‐β‐induced EndMT by augmenting TGF‐β family signals. Furthermore, oral squamous cell carcinoma‐derived cells underwent epithelial‐to‐mesenchymal transition (EMT) in response to humoral factors produced by TGF‐β and TNF‐α‐cultured ECs. This EndMT‐driven EMT was blocked by inhibiting the action of TGF‐βs. Collectively, our findings suggest that TNF‐α enhances TGF‐β‐dependent EndMT, which contributes to tumor progression.     

Increased transforming growth factor‐α levels in human colon carcinoma cell lines over‐expressing protein kinase C

Transforming growth factor‐α (TGF‐α) is synthesized as a membrane‐bound precursor protein, pro‐TGF‐α, that is converted to a soluble form by 2 endoproteolytic cleavages. Several factors have been implicated in the regulation of the second rate‐limiting step, including protein kinase C (PKC). Earlier results indicated a potential role for the conventional class of PKC isozymes in the observed increase in TGF‐α in the conditioned media of 2 human colon carcinoma cell lines. The present study addresses the potential role of specific PKC isozymes in this process using sense and anti‐sense expression vectors for PKC isozymes. Two human colon carcinoma cell lines, HCT 116 and GEO, were transfected with plasmids, leading to the over‐expression of PKC‐α, ‐βI or ‐βII; and the secretion of TGF‐α into the conditioned medium was determined. Over‐expression of either PKC‐βI or PKC‐βII in these cell lines enhanced the levels of TGF‐α in the media 2‐ to 5‐fold. Over‐expression of PKC‐α did not alter the amount of TGF‐α in the media to a significant extent. Transfection of HCT 116 cells with the anti‐sense PKC‐βI cDNA resulted in a reduction in PKC‐βI protein expression. This was accompanied by a decrease in the amount of TGF‐α in the conditioned media. Our results indicate that modulation of PKC‐β protein levels alters the amount of TGF‐α found in the conditioned media from these colon carcinoma cells. Int. J. Cancer 80:72–77, 1999. © 1999 Wiley‐Liss, Inc.     

Tumor vasculature‐targeted delivery of tumor necrosis factor‐α*

BACKGROUND: Recently, considerable efforts have been directed toward antivascular therapy as a new modality to treat human cancers. However, targeting a therapeutic gene of interest to the tumor vasculature with minimal toxicity to other tissues remains the objective of antivascular gene therapy. Tumor necrosis factor‐α (TNF‐α) is a potent antivascular agent but has limited clinical utility because of significant systemic toxicity. At the maximum tolerated doses of systemic TNF‐α, there is no meaningful antitumor activity. Hence, the objective of this study was to deliver TNF‐α targeted to tumor vasculature by systemic delivery to examine its antitumor activity. METHODS: A hybrid adeno‐associated virus phage vector (AAVP) was used that targets tumor endothelium to express TNF‐α (AAVP‐TNF‐α). The activity of AAVP‐TNF‐α was analyzed in various in vitro and in vivo settings using a human melanoma tumor model. RESULTS: In vitro, AAVP‐TNF‐α infection of human melanoma cells resulted in high levels of TNF‐α expression. Systemic administration of targeted AAVP‐TNF‐α to melanoma xenografts in mice produced the specific delivery of virus to tumor vasculature. In contrast, the nontargeted vector did not target to tumor vasculature. Targeted AAVP delivery resulted in expression of TNF‐α, induction of apoptosis in tumor vessels, and significant inhibition of tumor growth. No systemic toxicity to normal organs was observed. CONCLUSIONS: Targeted AAVP vectors can be used to deliver TNF‐α specifically to tumor vasculature, potentially reducing its systemic toxicity. Because TNF‐α is a promising antivascular agent that currently is limited by its toxicity, the current results suggest the potential for clinical translation of this strategy. Cancer 2009. Published 2008 by the American Cancer Society.     

Peptide inhibitors of transforming growth factor‐β enhance the efficacy of antitumor immunotherapy

Transforming growth factor‐β (TGF‐β) is a cytokine with potent immunosuppressive effects and is overexpressed in many tumors. Therefore, development of molecules able to inhibit TGF‐β is of paramount importance to improve the efficacy of antitumor immunotherapy. TGF‐β inhibitor peptides P144 and P17 were combined with the administration of adjuvant molecules poly(I:C) and agonistic anti‐CD40 antibodies, and their effect on the growth of E.G7‐OVA established tumors and on antitumor immune response was evaluated. Tumor rejection efficacy of a single administration of adjuvants was enhanced from 15 to 70 % when combined with repeated injections of TGF‐β inhibitor peptides. Simultaneous administration of adjuvants and TGF‐β inhibitor peptides was required for maximal therapeutic efficacy. Although tumor cells produced TGF‐β, it was found that the beneficial effect of peptide administration was mainly due to the inhibition of TGF‐β produced by regulatory CD4⁺CD25⁺ T cells rather than by tumor cells. The enhanced antitumor effect was accompanied by a higher activity of dendritic cells, natural killer cells and tumor antigen‐specific T cells, as well as by a decrease in the number of myeloid‐derived suppressor cells. In conclusion, administration of peptide inhibitors of TGF‐β in therapeutic vaccination enhances the efficacy of immunotherapy by increasing antitumor immune responses. These peptide inhibitors may have important applications for current immunotherapeutic strategies. © 2009 UICC     

Inhibition of MK2 suppresses IL‐1β, IL‐6, and TNF‐α‐dependent colorectal cancer growth

Colorectal cancer (CRC) development and progression is associated with chronic inflammation. We have identified the MAPK‐activated protein kinase 2 (MK2) pathway as a primary mediator of inflammation in CRC. MK2 signaling promotes production of proinflammatory cytokines IL‐1β, IL‐6 and TNF‐α. These cytokines have been implicated in tumor growth, invasion and metastasis. For the first time, we investigate whether MK2 inhibition can improve outcome in two mouse models of CRC. In our azoxymethane/dextran sodium sulfate (AOM/DSS) model of colitis‐associated CRC, MK2 inhibitor treatment eliminated murine tumor development. Using the implanted, syngeneic murine CRC cell line CT26, we observe significant tumor volume reduction following MK2 inhibition. Tumor cells treated with MK2 inhibitors produced 80% less IL‐1β, IL‐6 and TNF‐α and demonstrated decreased invasion. Replenishment of downstream proinflammatory MK2‐mediated cytokines (IL‐1β, IL‐6 and TNF‐α) to tumors led to restoration of tumor proliferation and rapid tumor regrowth. These results demonstrate the importance of MK2 in driving proinflammatory cytokine production, its relevance to in vivo tumor proliferation and invasion. Inhibition of MK2 may represent an attractive therapeutic target to suppress tumor growth and progression in patients.     

TGF‐β inactivation and TGF‐α overexpression cooperate in an in vivo mouse model to induce hepatocellular carcinoma that recapitulates molecular features of human liver cancer

Hepatocellular carcinoma (HCC) results from the cumulative effects of deregulated tumor suppressor genes and oncogenes. The tumor suppressor and oncogenes commonly affected include growth factors, receptors and their downstream signaling pathway components. The overexpression of transforming growth factor alpha (TGF‐α) and the inhibition of TGF‐β signaling are especially common in human liver cancer. Thus, we assessed whether TGF‐α overexpression and TGF‐β signaling inactivation cooperate in hepatocarcinogenesis using an in vivo mouse model, MT1/TGFa;AlbCre/Tgfbr2^flx/flx mice (“TGFa;Tgfbr2^hepko”), which overexpresses TGF‐α and lacks a TGF‐β receptor in the liver. TGF‐β signaling inactivation did not alter the frequency or number of cancers in mice with overexpression of TGF‐α. However, the tumors in the TGFa;Tgfbr2^hepko mice displayed increased proliferation and increased cdk2, cyclin E and cyclin A expression as well as decreased Cdkn1a/p21 expression compared to normal liver and compared to the cancers arising in the TGF‐α overexpressing mice with intact TGF‐β receptors. Increased phosphorylated ERK1/2 expression was also present in the tumors from the TGFa;Tgfbr2^hepko mice and correlated with downregulated Raf kinase inhibitor protein expression, which is a common molecular event in human HCC. Thus, TGF‐β signaling inactivation appears to cooperate with TGF‐α in vivo to promote the formation of liver cancer that recapitulates molecular features of human HCC.     

Cellular context‐dependent “colors” of transforming growth factor‐β signaling

Transforming growth factor (TGF)‐β signaling has interesting characteristics in the context of cancer. Although perturbations of TGF‐β signaling are strongly implicated in cancer progression, TGF‐β signaling has both tumor‐suppressive and tumor‐promoting effects. For example, TGF‐β inhibits cancer cell proliferation in some cellular contexts, but promotes it in others. Although several approaches to treating cancer have been considered using TGF‐β‐based therapeutic strategies, the contradictory behaviors of TGF‐β have made these approaches complex. To put them to practical use, either the tumor‐suppressive or tumor‐promoting arm needs to be specifically manipulated. However, there is virtually no method to specifically regulate a certain cell response induced by TGF‐β. In this review, we first consider the basic machinery of TGF‐β signaling, and describe several cell responses induced by TGF‐β stimulation in specific contexts. Mechanisms by which TGF‐β can induce several responses in a cellular context‐dependent fashion are discussed with established paradigms and models. We also address perspectives on the specific control of only a subset of numerous cell responses induced by TGF‐β stimulation. Such methods will aid specific regulation of either the tumor‐suppressive or tumor‐promoting arm of the TGF‐β pathway and in realization of TGF‐β‐based treatment of malignant tumors. (Cancer Sci 2010; 101: 306–312)     

Serum deprivation response inhibits breast cancer progression by blocking transforming growth factor‐β signaling

Serum deprivation response (SDPR), a key substrate for protein kinase C, play a critical role in inducing membrane curvature and participate in the formation of caveolae. However, the function of SDPR in cancer development and progression is still not clear. Here, we found that SDPR is downregulated in human breast cancer. Overexpression of SDPR suppresses cell proliferation and invasion in MDA‐MB‐231 cells, while depletion of SDPR promotes cell proliferation and invasion in MCF10A cells. Subsequently, SDPR depletion induces epithelial–mesenchymal transition (EMT)‐like phenotype. Finally, knockdown of SDPR activates transforming growth factor‐β (TGF‐β) signaling by upregulation of TGF‐β1 expression. In conclusion, our results showed that SDPR inhibits breast cancer progression by blocking TGF‐β signaling. Serum deprivation response suppresses cell proliferation and invasion in breast cancer cells. SDPR depletion induces epithelial–mesenchymal transition by activation of TGF‐β signaling.     

Blockade of transforming growth factor‐β signaling enhances oncolytic herpes simplex virus efficacy in patient‐derived recurrent glioblastoma models

Despite the current standard of multimodal management, glioblastoma (GBM) inevitably recurs and effective therapy is not available for recurrent disease. A subset of tumor cells with stem‐like properties, termed GBM stem‐like cells (GSCs), are considered to play a role in tumor relapse. Although oncolytic herpes simplex virus (oHSV) is a promising therapeutic for GBM, its efficacy against recurrent GBM is incompletely characterized. Transforming growth factor beta (TGF‐β) plays vital roles in maintaining GSC stemness and GBM pathogenesis. We hypothesized that oHSV and TGF‐β inhibitors would synergistically exert antitumor effects for recurrent GBM. Here we established a panel of patient‐derived recurrent tumor models from GBMs that relapsed after postsurgical radiation and chemotherapy, based on GSC‐enriched tumor sphere cultures. These GSCs are resistant to the standard‐of‐care temozolomide but susceptible to oHSVs G47Δ and MG18L. Inhibition of TGF‐β receptor kinase with selective targeted small molecules reduced clonogenic sphere formation in all tested recurrent GSCs. The combination of oHSV and TGF‐βR inhibitor was synergistic in killing recurrent GSCs through, in part, an inhibitor‐induced JNK‐MAPK blockade and increase in oHSV replication. In vivo, systemic treatment with TGF‐βR inhibitor greatly enhanced the antitumor effects of single intratumoral oHSV injections, resulting in cures in 60% of mice bearing orthotopic recurrent GBM. These results reveal a novel synergistic interaction of oHSV therapy and TGF‐β signaling blockade, and warrant further investigations aimed at clinical translation of this combination strategy for GBM patients.     

Vasohibin‐2 is required for epithelial–mesenchymal transition of ovarian cancer cells by modulating transforming growth factor‐β signaling

Vasohibin‐2 (VASH2) is a homolog of VASH1, an endothelium‐derived angiogenesis inhibitor. Vasohibin‐2 is mainly expressed in cancer cells, and has been implicated in the progression of cancer by inducing angiogenesis and tumor growth. Although VASH2 has been recently reported to be involved in epithelial–mesenchymal transition (EMT), its precise roles are obscure. The aim of the present study was to clarify the role of VASH2 in the EMT of cancer cells in relation to transforming growth factor‐β (TGF‐β) signaling, which is a major stimulator of EMT. Decreased expression of VASH2 in ovarian cancer cells significantly repressed the expression of TGF‐β type I receptor, namely activin receptor‐like kinase 5. Transforming growth factor‐β1‐induced phosphorylation of Smad2 and Smad3 was markedly decreased in VASH2 knockdown cells while the expression of Smad2 and Smad3 was unchanged. Accordingly, the responses to TGF‐β1 shown by promoter assay and plasminogen activator inhibitor type 1 expression were significantly attenuated in VASH2 knockdown cells. Furthermore, knockdown of VASH2 in cancer cells abrogated the TGF‐β1‐induced reduced expression of epithelial markers including E‐cadherin, and the elevated expression of mesenchymal markers including fibronectin, ZEB2, and Snail2, suggesting that endogenous VASH2 is required for TGF‐β1‐induced EMT. In accordance with these results, the effects of TGF‐β1 on cell morphology, migration, invasion, and MMP2 expression were also abrogated when VASH2 was knocked down. These results indicate that VASH2 played a significant role in the EMT by modulating the TGF‐β signaling. We propose that VASH2 would be a novel molecular target for the prevention of EMT in cancers.     

Blockade of TGF‐β enhances tumor vaccine efficacy mediated by CD8+ T cells

Though TGF‐β inhibition enhances antitumor immunity mediated by CD8⁺ T cells in several tumor models, it is not always sufficient for rejection of tumors. In this study, to maximize the antitumor effect of TGF‐β blockade, we tested the effect of anti‐TGF‐β combined with an irradiated tumor vaccine in a subcutaneous CT26 colon carcinoma tumor model. The irradiated tumor cell vaccine alone in prophylactic setting significantly delayed tumor growth, whereas anti‐TGF‐β antibodies alone did not show any antitumor effect. However, tumor growth was inhibited significantly more in vaccinated mice treated with anti‐TGF‐β antibodies compared to vaccinated mice without anti‐TGF‐β, suggesting that anti‐TGF‐β synergistically enhanced irradiated tumor vaccine efficacy. CD8⁺ T‐cell depletion completely abrogated the vaccine efficacy, and so protection required CD8⁺ T cells. Depletion of CD25⁺ T regulatory cells led to the almost complete rejection of tumors without the vaccine, whereas anti‐TGF‐β did not change the number of CD25⁺ T regulatory cells in unvaccinated and vaccinated mice. Though the abrogation of CD1d‐restricted NKT cells, which have been reported to induce TGF‐β production by MDSC through an IL‐13‐IL‐4R‐STAT6 pathway, partially enhanced antitumor immunity regardless of vaccination, abrogation of the NKT cell‐IL‐13‐IL‐4R‐STAT‐6 immunoregulatory pathway did not enhance vaccine efficacy. Taken together, these data indicated that anti‐TGF‐β enhances efficacy of a prophylactic vaccine in normal individuals despite their not having the elevated TGF‐β levels found in patients with cancer and that the effect is not dependent on TGF‐β solely from CD4⁺CD25⁺ T regulatory cells or the NKT cell‐IL‐13‐IL‐4R‐STAT‐6 immunoregulatory pathway.     

CXCR2‐mediated tumor‐associated neutrophil recruitment is regulated by IFN‐β

The chemokine receptor CXCR2 and its ligands CXCL1, CXCL2 and CXCL5 play an important role in homing of tumor‐associated neutrophils (TANs) into developing tumors. TANs are known to support the development of blood vessels in growing solid tumors, hence contributing to tumor growth. Here, we show that the migration of neutrophils is influenced by endogenous interferon‐beta (IFN‐β) via regulation of such chemokines and their receptor. We could demonstrate that CXCL1 and CXCL2 gradients are formed in tumor‐bearing mice, i.e., low chemokine level in bone marrow (BM) and high level in the tumor. This supports migration of neutrophils into the tumor. Moreover, expression of CXCR2 was highest on neutrophils from BM and lowest in TANs. Importantly, although IFN‐β appears to have only a minor influence on the expression of CXCR2, it strongly regulates the CXCR2 ligands. In the absence of endogenous IFN‐β, they were expressed significantly higher in tumor‐infiltrating neutrophils. Treatment of such neutrophils from tumor‐bearing Ifnb1^?/? mice with recombinant IFN‐β downregulated CXCR2 ligand expression to wild‐type levels. This explains the reduced migration of neutrophils into tumors and the diminished tumor angiogenesis in IFN‐β‐sufficient mice. Our results add a novel functional aspect of the type I IFN system as effector molecules of natural cancer surveillance and open interesting possibilities for antineutrophil therapies against cancer.     

PD‐L1 expression enhancement by infiltrating macrophage‐derived tumor necrosis factor‐α leads to poor pancreatic cancer prognosis

Immunotherapy using anti‐PD‐1/PD‐L1 antibodies for several types of cancer has received considerable attention in recent decades. However, the molecular mechanism underlying PD‐L1 expression in pancreatic ductal adenocarcinoma (PDAC) cells has not been clearly elucidated. We investigated the clinical significance and regulatory mechanism of PD‐L1 expression in PDAC cells. Among the various cytokines tested, tumor necrosis factor (TNF)‐α upregulated PD‐L1 expression in PDAC cells through NF‐κB signaling. The induction of PD‐L1 expression was also caused by co‐culture with activated macrophages, and the upregulation was inhibited by neutralization with anti‐TNF‐α antibody after co‐culture with activated macrophages. PD‐L1 expression in PDAC cells was positively correlated with macrophage infiltration in tumor stroma of human PDAC tissues. In addition, survival analysis revealed that high PD‐L1 expression was significantly associated with poor prognosis in 235 PDAC patients and especially in patients harboring high CD8‐positive T‐cell infiltration. These findings indicate that tumor‐infiltrating macrophage‐derived TNF‐α could be a potential therapeutic target for PDAC.     

Transforming growth factor‐β induces CD44 cleavage that promotes migration of MDA‐MB‐435s cells through the up‐regulation of membrane type 1‐matrix metalloproteinase

CD44, a transmembrane receptor for hyaluronic acid, is implicated in various adhesion‐dependent cellular processes, including cell migration, tumor cell metastasis and invasion. Recent studies demonstrated that CD44 expressed in cancer cells can be proteolytically cleaved at the ectodomain by membrane type 1‐matrix metalloproteinase (MT1‐MMP) to form soluble CD44 and that CD44 cleavage plays a critical role in cancer cell migration. Here, we show that transforming growth factor‐β (TGF‐β), a multifunctional cytokine involved in cell proliferation, differentiation, migration and pathological processes, induces MT1‐MMP expression in MDA‐MB‐435s cells. TGF‐β‐induced MT1‐MMP expression was blocked by the specific extracellular regulated kinase‐1/2 (ERK1/2) inhibitor PD98059 and the specific phosphoinositide 3‐OH kinase (PI3K) inhibitor LY294002. In addition, treatment with SP600125, an inhibitor for c‐Jun NH₂‐terminal kinase (JNK), resulted in a significant inhibition of MT1‐MMP production. These data suggest that ERK1/2, PI3K, and JNK likely play a role in TGF‐β‐induced MT1‐MMP expression. Interestingly, treatment of MDA‐MB‐435s cells with TGF‐β resulted in a colocalization of MT1‐MMP and CD44 in the cell membrane and in an increased level of soluble CD44. Using an electric cell‐substrate impedance sensing cell‐electrode system, we demonstrated that TGF‐β treatment promotes MDA‐MB‐435s cell migration, involving MT1‐MMP‐mediated CD44 cleavage. MT1‐MMP siRNA transfection‐inhibited TGF‐β‐induced cancer cell transendothelial migration. Thus, this study contributes to our understanding of molecular mechanisms that play a critical role in tumor cell invasion and metastasis. © 2009 Wiley‐Liss, Inc.