Notch1 regulates angio-supportive bone marrow-derived cells in mice: relevance to chemoresistance

Host responses to chemotherapy can induce resistance mechanisms that facilitate tumor regrowth. To determine the contribution of bone marrow-derived cells (BMDCs), we exposed tumor-bearing mice to chemotherapeutic agents and evaluated the influx and contribution of a genetically traceable subpopulation of BMDCs (vascular endothelial-cadherin-Cre-enhanced yellow fluorescent protein [VE-Cad-Cre-EYFP]). Treatment of tumor-bearing mice with different chemotherapeutics resulted in a three- to 10-fold increase in the influx of VE-Cad-Cre-EYFP. This enhanced influx was accompanied by a significant increase in angiogenesis. Expression profile analysis revealed a progressive change in the EYFP population with loss of endothelial markers and an increase in mononuclear markers. In the tumor, 2 specific populations of VE-Cad-Cre-EYFP BMDCs were identified: Gr1(+)/CD11b(+) and Tie2(high)/platelet endothelial cell adhesion molecule(low) cells, both located in perivascular areas. A common signature of the EYFP population that exits the bone marrow is an increase in Notch. Inducible inactivation of Notch in the EYFP+ BMDCs impaired homing of these BMDCs to the tumor. Importantly, Notch deletion reduced therapy-enhanced angiogenesis, and was associated with an increased antitumor effect of the chemotherapy. These findings revealed the functional significance of a specific population of supportive BMDCs in response to chemotherapeutics and uncovered a new potential strategy to enhance anticancer therapy.

Targeting exogenous genes to tumor angiogenesis by transplantation of genetically modified hematopoietic stem cells

Michele De Palma

Angiogenic tumor vessels are promising targets for the activity and the selective delivery of cancer therapeutics. The bone marrow contributes different cell types to the tumor stroma, including hematopoietic cells and, as recently suggested, vascular endothelial cells (ECs). Thus, transplantation of genetically modified bone marrow progenitors may represent a vehicle for the transport of gene therapy to tumors. We transduced bone marrow progenitors with lentiviral vectors expressing genes from transcription-regulatory elements of Tie2/Tek gene. When tumors were grown in the transplanted mice, the new vector marked a distinct hematopoietic population that 'homed' to the tumor and closely interacted with vascular ECs at the tumor periphery. These Tie2-expressing mononuclear (TEM) cells had a distinguishable phenotype and were present selectively at angiogenic sites. Unexpectedly, we did not find bone marrow-derived ECs in tumor vessels when we transplanted bone marrow progenitors constitutively expressing a marker gene from the Tie2 or ubiquitously active promoters. By delivering a 'suicide' gene, we selectively eliminated the TEM cells and achieved substantial inhibition of angiogenesis and slower tumor growth without systemic toxicity. Thus, TEM cells may account for the proangiogenic activity of bone marrow-derived cells in tumors, may represent a new target for drug development and may provide the means for selective gene delivery and targeted inhibition of tumor angiogenesis.

Nature Publishing Group2003

Angiopoietin-2 regulates gene expression in TIE2-expressing monocytes and augments their inherent proangiogenic functions

Michele De Palma

TIE2-expressing monocytes/macrophages (TEM) are a highly proangiogenic subset of myeloid cells in tumors. Here, we show that circulating human TEMs are already preprogrammed in the circulation to be more angiogenic and express higher levels of such proangiogenic genes as matrix metalloproteinase-9 (MMP-9), VEGFA, COX-2, and WNT5A than TIE2(-) monocytes. Additionally, angiopoietin-2 (ANG-2) markedly enhanced the proangiogenic activity of TEMs and increased their expression of two proangiogenic enzymes: thymidine phosphorylase (TP) and cathepsin B (CTSB). Three "alternatively activated" (or M2-like) macrophage markers were also upregulated by ANG-2 in TEMs: interleukin-10, mannose receptor (MRC1), and CCL17. To investigate the effects of ANG-2 on the phenotype and function of TEMs in tumors, we used a double-transgenic (DT) mouse model in which ANG-2 was specifically overexpressed by endothelial cells. Syngeneic tumors grown in these ANG-2 DT mice were more vascularized and contained greater numbers of TEMs than those in wild-type (WT) mice. In both tumor types, expression of MMP-9 and MRC1 was mainly restricted to tumor TEMs rather than TIE2(-) macrophages. Furthermore, tumor TEMs expressed higher levels of MRC1, TP, and CTSB in ANG-2 DT tumors than WT tumors. Taken together, our data show that although circulating TEMs are innately proangiogenic, exposure to tumor-derived ANG-2 stimulates these cells to exhibit a broader, tumor-promoting phenotype. As such, the ANG-2-TEM axis may represent a new target for antiangiogenic cancer therapies.

2010

Anti-angiogenic immunotherapy for lung cancer

Ece Kadioglu

Lung cancer is the leading cause of cancer-associated deaths worldwide. Platinum-based chemotherapy is the most common therapeutic approach in advanced non-small cell lung cancer (NSCLC), particularly for tumors that carry non-druggable activating mutations. However, these tumors are generally not eradicated when diagnosed at an advanced stage and are frequently resistant to chemotherapy. Therefore, there is an urgent medical need for new treatments for this frequent cancer type. Immunotherapies are treatments based on increasing the strength of immune responses against cancer. In particular, monoclonal antibodies that block inhibitory "immune-checkpoints" expressed on T cells (e.g., programmed cell death protein 1, or PD1) show clinical efficacy in increasing tumor types. However, these therapies improve survival in only a minority of NSCLC patients, and ongoing efforts are being made for increasing their efficacy through combinatorial treatments. In this regard, growing evidence indicates that tumor angiogenesis is closely associated with immunosuppression. Pro-angiogenic factors, such as vascular endothelial growth factor A (VEGFA) and angiopoietin 2 (ANG2), cause abnormalities and dysfunctions in tumor blood vessels that impair T cell extravasation and anti-tumoral activity. Recent findings in preclinical cancer models show that reprogramming the features of tumor-associated blood vessels by anti-angiogenic drugs may help to increase intratumoral T cell abundance and sensitize refractory tumors to immunotherapy. Nevertheless, the potential of anti-angiogenics in the context of lung cancer immunotherapy is poorly understood. Therefore, the main objective of my project was to audit combinations of anti-angiogenic therapy and immune checkpoint blockade in a genetically engineered mouse model of NSCLC. I first studied the anti-tumoral activity of dual VEGFA and ANG2 inhibition using a bispecific antibody (A2V) in the KrasLSL-G12D/+;p53fl/fl (KP) NSCLC model. I found that A2V, but not single VEGFA or ANG2 blockade, had robust tumor-inhibitory activity in KP mice, which was at least comparable to standard-of-care chemotherapy. However, A2V only moderately increased cytotoxic T cells in the tumors. To potentially increase the immunogenicity of KP tumors, I also generated two KP mouse variants by either co-expressing a surrogate neoantigen or genetically deleting a DNA mismatch repair enzyme in the cancer cells. However, the therapeutic efficacy of A2V was not further improved in spite of a slightly more activated immune response. I next investigated combination therapies involving A2V and PD1 blockade. In contrast to previous findings in other cancer types, the addition of PD1 antibodies deteriorated the efficacy of A2V, likely through enhancing immunosuppressive mechanisms sustained, at least in part, by regulatory T cells and T cell-antagonizing cytokines. In summary, my work supports the potential clinical efficacy of combined VEGFA and ANG2 blockade for lung cancer therapy but provided little evidence for its synergy in association with anti-PD1 therapy.

EPFL2019

Anti-angiogenic immunotherapy for lung cancer

Ece Kadioglu

EPFL2019