Macrophages Facilitate Resistance to Anti-VEGF Therapy by Altered VEGFR Expression

Dalton, Heather J.; Pradeep, Sunila; McGuire, Michael H.; Hailemichael, Yared; Ma, Shaolin; Lyons, Yasmin; Armaiz-Peña, Guillermo N.; Previs, Rebecca A.; Hansen, Jean M.; Rupaimoole, Rajesha; González-Villasana, Vianey; Cho, Min Soon; Wu, Sherry Y.; Mangala, Lingegowda S.; Jennings, Nicholas B.; Hu, Wei; Langley, Robert R.; Mu, Hong; Andreeff, Michael; Bar‐Eli, Menashe; Overwijk, Willem W.; Ram, Prahlad T.; López-Berestein, Gabriel; Coleman, Robert L.; Sood, Anil K.

doi:10.1158/1078-0432.ccr-17-0647

Cited by 72 publications

(68 citation statements)

References 29 publications

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“…The comparison of resistant versus sensitive tumors to anti-VEGF therapy revealed a higher number of TAMs in the non-responders [66]. In the same line, anti-VEGF mAbs showed higher therapeutic efficacy and higher inhibition of vessel formation, upon depletion of TAMs with zoledronic acid, in several tumor models [67]. This effect was also observed in murine glioblastoma treated with vatalanib, a small protein kinase inhibitor that blocks angiogenesis.…”

Section: Interaction Of Tams With Anti-angiogenic Therapymentioning

confidence: 78%

Current Strategies to Target Tumor-Associated-Macrophages to Improve Anti-Tumor Immune Responses

Anfray

Ummarino

Andón

et al. 2019

Cells

212

196

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: Established evidence demonstrates that tumor-infiltrating myeloid cells promote rather than stop-cancer progression. Tumor-associated macrophages (TAMs) are abundantly present at tumor sites, and here they support cancer proliferation and distant spreading, as well as contribute to an immune-suppressive milieu. Their pro-tumor activities hamper the response of cancer patients to conventional therapies, such as chemotherapy or radiotherapy, and also to immunotherapies based on checkpoint inhibition. Active research frontlines of the last years have investigated novel therapeutic strategies aimed at depleting TAMs and/or at reprogramming their tumor-promoting effects, with the goal of re-establishing a favorable immunological anti-tumor response within the tumor tissue. In recent years, numerous clinical trials have included pharmacological strategies to target TAMs alone or in combination with other therapies. This review summarizes the past and current knowledge available on experimental tumor models and human clinical studies targeting TAMs for cancer treatment.

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Section: Interaction Of Tams With Anti-angiogenic Therapymentioning

confidence: 78%

Current Strategies to Target Tumor-Associated-Macrophages to Improve Anti-Tumor Immune Responses

Anfray

Ummarino

Andón

et al. 2019

Cells

212

196

View full text Add to dashboard Cite

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“…Anti-VEGF therapy, which was proven beneficial in ovarian cancer [20], is indeed known to modify the immune contexture [37] and is expected to reduce the amount of M2 macrophages. On the other hand, there is evidence that the presence of M2 macrophages can be an indication of resistance to anti-VEGF therapy [22,38,39]. It inhibits angiogenesis but can also promote the recruitment of TAM, immature monocytes, and other vascular modulators to the tumor site [39].…”

Section: Discussionmentioning

confidence: 99%

“…The presence of VEGF stimulates both the migration of macrophages to the TME and their polarization toward a more M2 phenotype [17]. Furthermore, macrophages were shown to facilitate resistance to anti-VEGF treatment [22].…”

Section: Introductionmentioning

confidence: 99%

Opposite Macrophage Polarization in Different Subsets of Ovarian Cancer: Observation from a Pilot Study

Vankerckhoven

Wouters

Mathivet

et al. 2020

Cells

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The role of the innate immune system in ovarian cancer is gaining importance. The relevance of tumor-associated macrophages (TAM) is insufficiently understood. In this pilot project, comprising the immunofluorescent staining of 30 biopsies taken from 24 patients with ovarian cancer, we evaluated the presence of total TAM (cluster of differentiation (CD) 68 expression), M1 (major histocompatibility complex (MHC) II expression), and M2 (anti-mannose receptor C type 1 (MRC1) expression), and the blood vessel diameter. We observed a high M1/M2 ratio in low-grade ovarian cancer compared to high-grade tumors, more total TAM and M2 in metastatic biopsies, and a further increase in total TAM and M2 at interval debulking, without beneficial effects of bevacizumab. The blood vessel diameter was indicative for M2 tumor infiltration (Spearman correlation coefficient of 0.65). These data mainly reveal an immune beneficial environment in low-grade ovarian cancer in contrast to high-grade serous ovarian cancer, where immune suppression is not altered by neoadjuvant therapy.

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“…Several studies have demonstrated TAM accumulation in the tumor mass after chemotherapy and antiangiogenic therapy. Thus, Dalton et al showed that recruitment of macrophages to the TME after anti-VEGF treatment leads to tumor growth as a mechanism of resistance to therapy but that depletion of macrophages inhibited tumor growth and improved the survival of tumor-bearing mice (49). The vascular disrupting agent combretastatin A4-P causes the increased production of CSF-1, CCL2, and CXCL12 that increases monocyte recruitment and TAM accumulation in tumor sites (50).…”

Section: Angiogenesismentioning

confidence: 99%

“…However, only a subset of patients respond efficiently to neoajuvant chemotherapy (NAC). Chemoresistance and chemotherapy-induced immunosuppression can result in the relapse of tumors and are critical for survival in cancer patients (49,104). Numerous studies have examined the molecular mechanisms that promote the chemoresistance of cancer cells, such as the induction of anti-apoptotic regulators, ABC transporters, aberrant transcription factor nuclear factor-κB (NF-κB) activity, and the mechanisms of damaged DNA repair (104)(105)(106).…”

Section: Chemotherapy Tams and Chitinase-like Proteinsmentioning

confidence: 99%

YKL-39 as a Potential New Target for Anti-Angiogenic Therapy in Cancer

2020

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YKL-39 belongs to the evolutionarily conserved family of Glyco_18-containing proteins composed of chitinases and chitinase-like proteins. Chitinase-like proteins (CLPs) are secreted lectins that lack hydrolytic activity due to the amino acid substitutions in their catalytic domain and combine the functions of cytokines and growth factors. One of the major cellular sources that produce CLPs in various pathologies, including cancer, are macrophages. Monocytes recruited to the tumor site and programmed by tumor cells differentiate into tumor-associated macrophages (TAMs), which are the primary source of pro-angiogenic factors. Tumor angiogenesis is a crucial process for supplying rapidly growing tumors with essential nutrients and oxygen. We recently determined that YKL-39 is produced by tumor-associated macrophages in breast cancer. YKL-39 acts as a strong chemotactic factor for monocytes and stimulates angiogenesis. Chemotherapy is a common strategy to reduce tumor size and aggressiveness before surgical intervention, but chemoresistance, resulting in the relapse of tumors, is a common clinical problem that is critical for survival in cancer patients. Accumulating evidence indicates that TAMs are essential regulators of chemoresistance. We have recently found that elevated levels of YKL-39 expression are indicative of the efficiency of the metastatic process in patients who undergo neoadjuvant chemotherapy. We suggest YKL-39 as a new target for anti-angiogenic therapy that can be combined with neoadjuvant chemotherapy to reduce chemoresistance and inhibit metastasis in breast cancer patients.

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Macrophages Facilitate Resistance to Anti-VEGF Therapy by Altered VEGFR Expression

Cited by 72 publications

References 29 publications

Current Strategies to Target Tumor-Associated-Macrophages to Improve Anti-Tumor Immune Responses

Current Strategies to Target Tumor-Associated-Macrophages to Improve Anti-Tumor Immune Responses

Opposite Macrophage Polarization in Different Subsets of Ovarian Cancer: Observation from a Pilot Study

YKL-39 as a Potential New Target for Anti-Angiogenic Therapy in Cancer

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