Targeting OLFML3 in Colorectal Cancer Suppresses Tumor Growth and Angiogenesis, and Increases the Efficacy of Anti-PD1 Based Immunotherapy

Simple Summary Tumor vascularization promotes tumor growth and is intimately connected to immune system function. Despite efforts to use antiangiogenic therapies, their clinical effects are less pronounced than expected. Compensatory angiogenic responses and resistance to treatment are responsible for these limited therapeutic effects. Inhibition of OLFML3 suppresses the growth of colorectal cancer in preclinical models. Our study identified OLFML3 as a key regulator of angiogenesis, lymphangiogenesis, pericyte coverage, tumor-associated macrophage recruitment, and enhanced NKT lymphocyte recruitment associated with its antitumor effects. We also highlight that OLFML3 antibodies increase the efficacy of anti-PD-1-based therapies. These results are in agreement with the high expression of OLFML3 observed in colorectal carcinoma patients associated with shorter relapse-free survival, higher grade, and angiogenic microsatellite stable (CMS4) subtype. Clinically, high OLFML3 expression correlates with reduced disease-free survival in human colorectal cancer patients, suggesting a potential role as a therapeutic target. Abstract The role of the proangiogenic factor olfactomedin-like 3 (OLFML3) in cancer is unclear. To characterize OLFML3 expression in human cancer and its role during tumor development, we undertook tissue expression studies, gene expression analyses of patient tumor samples, in vivo studies in mouse cancer models, and in vitro coculture experiments. OLFML3 was expressed at high levels, mainly in blood vessels, in multiple human cancers. We focused on colorectal cancer (CRC), as elevated expression of OLFML3 mRNA correlated with shorter relapse-free survival, higher tumor grade, and angiogenic microsatellite stable consensus molecular subtype 4 (CMS4). Treatment of multiple in vivo tumor models with OLFML3-blocking antibodies and deletion of the Olfml3 gene from mice decreased lymphangiogenesis, pericyte coverage, and tumor growth. Antibody-mediated blockade of OLFML3 and deletion of host Olfml3 decreased the recruitment of tumor-promoting tumor-associated macrophages and increased infiltration of the tumor microenvironment by NKT cells. Importantly, targeting OLFML3 increased the antitumor efficacy of anti-PD-1 checkpoint inhibitor therapy. Taken together, the results demonstrate that OLFML3 is a promising candidate therapeutic target for CRC.

[1]  B. Imhof,et al.  Olfactomedin‐like 3 promotes PDGF‐dependent pericyte proliferation and migration during embryonic blood vessel formation , 2020, FASEB journal : official publication of the Federation of American Societies for Experimental Biology.

[2]  W. Lee,et al.  Combination of anti-angiogenic therapy and immune checkpoint blockade normalizes vascular-immune crosstalk to potentiate cancer immunity , 2020, Experimental & Molecular Medicine.

[3]  G. Minchiotti,et al.  Nodal-induced L1CAM/CXCR4 subpopulation sustains tumor growth and metastasis in colorectal cancer derived organoids , 2020, Theranostics.

[4]  Ji-Liang Li,et al.  Olfactomedin-like 3: possible functions in embryonic development and tumorigenesis , 2019, Chinese medical journal.

[5]  Alexander von Ehr,et al.  Microglia-Specific Expression of Olfml3 Is Directly Regulated by Transforming Growth Factor β1-Induced Smad2 Signaling , 2018, Front. Immunol..

[6]  Yuji Yamamoto,et al.  Lenvatinib inhibits angiogenesis and tumor fibroblast growth factor signaling pathways in human hepatocellular carcinoma models , 2018, Cancer medicine.

[7]  M. Oliveira,et al.  Interferon-Gamma at the Crossroads of Tumor Immune Surveillance or Evasion , 2018, Front. Immunol..

[8]  Y. Sakai,et al.  Resistance to Anti-Angiogenic Therapy in Cancer—Alterations to Anti-VEGF Pathway , 2018, International journal of molecular sciences.

[9]  S. McArdle,et al.  Immune Landscape of Breast Cancers , 2018, Biomedicines.

[10]  Pornpimol Charoentong,et al.  Targeting immune checkpoints potentiates immunoediting and changes the dynamics of tumor evolution , 2018, Nature Communications.

[11]  Michele De Palma,et al.  Reprogramming Tumor Blood Vessels for Enhancing Immunotherapy. , 2017, Trends in cancer.

[12]  F. Marincola,et al.  Immunogenomic Classification of Colorectal Cancer and Therapeutic Implications , 2017, International journal of molecular sciences.

[13]  Y. Kienast,et al.  Dual angiopoietin-2 and VEGFA inhibition elicits antitumor immunity that is enhanced by PD-1 checkpoint blockade , 2017, Science Translational Medicine.

[14]  C. Hudis,et al.  The role of bevacizumab in solid tumours: A literature based meta-analysis of randomised trials. , 2017, European journal of cancer.

[15]  R. Kerbel,et al.  Implications of vessel co-option in sorafenib-resistant hepatocellular carcinoma , 2016, Chinese journal of cancer.

[16]  R. Stocker,et al.  Biodegradable and plasma‐treated electrospun scaffolds coated with recombinant Olfactomedin‐like 3 for accelerating wound healing and tissue regeneration , 2016, Wound repair and regeneration : official publication of the Wound Healing Society [and] the European Tissue Repair Society.

[17]  P. Yu,et al.  Efficacy of Bevacizumab in the First-Line Treatment of Patients with RAS Mutations Metastatic Colorectal Cancer: a Systematic Review and Network Meta-Analysis , 2016, Cellular Physiology and Biochemistry.

[18]  G. G. Van den Eynden,et al.  Vessel co-option mediates resistance to anti-angiogenic therapy in liver metastases , 2016, Nature Medicine.

[19]  Suzanne F. Jones,et al.  Atezolizumab in combination with bevacizumab enhances antigen-specific T-cell migration in metastatic renal cell carcinoma , 2016, Nature Communications.

[20]  O. Casanovas,et al.  Antiangiogenic resistance via metabolic symbiosis , 2016, Molecular & cellular oncology.

[21]  F. Marmé,et al.  Immunotherapy in Breast Cancer , 2016, Oncology Research and Treatment.

[22]  Shari Pilon-Thomas,et al.  Immune Checkpoint Blockade to Improve Tumor Infiltrating Lymphocytes for Adoptive Cell Therapy , 2016, PloS one.

[23]  Jeffrey S. Morris,et al.  The Consensus Molecular Subtypes of Colorectal Cancer , 2015, Nature Medicine.

[24]  W. Gradishar,et al.  Changing Treatment Paradigms in Metastatic Breast Cancer: Lessons Learned. , 2015, JAMA oncology.

[25]  R. Gacche Compensatory angiogenesis and tumor refractoriness , 2015, Oncogenesis.

[26]  P. Tamboli,et al.  Resistance to Antiangiogenic Therapy Is Associated with an Immunosuppressive Tumor Microenvironment in Metastatic Renal Cell Carcinoma , 2015, Cancer Immunology Research.

[27]  G. Coukos,et al.  Targeting the tumor vasculature to enhance T cell activity , 2015, Current opinion in immunology.

[28]  Jeffrey W Pollard,et al.  Tumor-associated macrophages: from mechanisms to therapy. , 2014, Immunity.

[29]  J. Blay,et al.  Targeting tumor-associated macrophages with anti-CSF-1R antibody reveals a strategy for cancer therapy. , 2014, Cancer cell.

[30]  G. Coukos,et al.  Tumor Endothelium FasL Establishes a Selective Immune Barrier Promoting Tolerance in Tumors , 2014, Nature Medicine.

[31]  A. D. Van den Abbeele,et al.  Bevacizumab plus Ipilimumab in Patients with Metastatic Melanoma , 2014, Cancer Immunology Research.

[32]  R. Ransohoff,et al.  Development, maintenance and disruption of the blood-brain barrier , 2013, Nature Medicine.

[33]  S. Ricardo,et al.  Macrophages and CSF-1 , 2013, Organogenesis.

[34]  Heather Dawson,et al.  Next-generation tissue microarray (ngTMA) increases the quality of biomarker studies: an example using CD3, CD8, and CD45RO in the tumor microenvironment of six different solid tumor types , 2013, Journal of Translational Medicine.

[35]  Dai Fukumura,et al.  Vascular normalization as an emerging strategy to enhance cancer immunotherapy. , 2013, Cancer research.

[36]  B. Imhof,et al.  Targeting Olfactomedin-like 3 Inhibits Tumor Growth by Impairing Angiogenesis and Pericyte Coverage , 2012, Molecular Cancer Therapeutics.

[37]  Philippe Dessen,et al.  Characterization of a Large Panel of Patient-Derived Tumor Xenografts Representing the Clinical Heterogeneity of Human Colorectal Cancer , 2012, Clinical Cancer Research.

[38]  Michele De Palma,et al.  The biology of personalized cancer medicine: Facing individual complexities underlying hallmark capabilities , 2012, Molecular oncology.

[39]  H. Hattori,et al.  Intracranial transplantation of monocyte‐derived multipotential cells enhances recovery after ischemic stroke in rats , 2012, Journal of neuroscience research.

[40]  C. Vogel,et al.  Bevacizumab in the Treatment of Metastatic Breast Cancer: Friend or Foe? , 2012, Current Oncology Reports.

[41]  Ki-Jo Kim,et al.  Role of placenta growth factor in cancer and inflammation , 2012, Experimental & Molecular Medicine.

[42]  G. Coukos,et al.  The parallel lives of angiogenesis and immunosuppression: cancer and other tales , 2011, Nature Reviews Immunology.

[43]  B. Barres,et al.  Pericytes are required for blood–brain barrier integrity during embryogenesis , 2010, Nature.

[44]  N. Nakaya,et al.  Olfactomedin Domain-Containing Proteins: Possible Mechanisms of Action and Functions in Normal Development and Pathology , 2009, Molecular Neurobiology.

[45]  Y. Sasai,et al.  Robust Stability of the Embryonic Axial Pattern Requires a Secreted Scaffold for Chordin Degradation , 2008, Cell.

[46]  Gabriele Bergers,et al.  Modes of resistance to anti-angiogenic therapy , 2008, Nature Reviews Cancer.

[47]  Johanna Andrae,et al.  Role of platelet-derived growth factors in physiology and medicine. , 2008, Genes & development.

[48]  A. Bosserhoff,et al.  Functional implication of BMP4 expression on angiogenesis in malignant melanoma , 2006, Oncogene.

[49]  Steven Song,et al.  The role of pericytes in blood-vessel formation and maintenance. , 2005, Neuro-oncology.

[50]  Kenneth J. Hillan,et al.  Discovery and development of bevacizumab, an anti-VEGF antibody for treating cancer , 2004, Nature Reviews Drug Discovery.

[51]  N. Perelman,et al.  Mechanism of monocyte activation and expression of proinflammatory cytochemokines by placenta growth factor. , 2003, Blood.

[52]  S. Rafii,et al.  Angiogenic Factors Reconstitute Hematopoiesis by Recruiting Stem Cells from Bone Marrow Microenvironment , 2003, Annals of the New York Academy of Sciences.

[53]  M. O. oude Egbrink,et al.  Tumor angiogenesis modulates leukocyte-vessel wall interactions in vivo by reducing endothelial adhesion molecule expression. , 2003, Cancer research.

[54]  Lois E. H. Smith,et al.  Molecular profiling of angiogenesis markers. , 2002, The American journal of pathology.

[55]  L. Benjamin,et al.  Placental growth factor is a survival factor for tumor endothelial cells and macrophages. , 2002, Cancer research.

[56]  Holger Gerhardt,et al.  Lack of Pericytes Leads to Endothelial Hyperplasia and Abnormal Vascular Morphogenesis , 2001, The Journal of cell biology.

[57]  D. Hanahan,et al.  The Hallmarks of Cancer , 2000, Cell.

[58]  B R Johansson,et al.  Pericyte loss and microaneurysm formation in PDGF-B-deficient mice. , 1997, Science.

[59]  K. Alitalo,et al.  Endothelial receptor tyrosine kinases involved in angiogenesis , 1995, The Journal of cell biology.

[60]  A. Kallioniemi,et al.  Bone morphogenetic protein 4 expression in multiple normal and tumor tissues reveals its importance beyond development , 2013, Modern Pathology.

[61]  S. Keam,et al.  Bevacizumab: a review of its use in metastatic colorectal cancer. , 2008, Drugs.

[62]  P. Gimotty,et al.  Endothelin B receptor mediates the endothelial barrier to T cell homing to tumors and disables immune therapy , 2008, Nature Medicine.

[63]  H. Kiyonari,et al.  Gene disruption/knock-in analysis of mONT3: vector construction by employing both in vivo and in vitro recombinations. , 2005, The International journal of developmental biology.

[64]  A. Luttun,et al.  Revascularization of ischemic tissues by PlGF treatment, and inhibition of tumor angiogenesis, arthritis and atherosclerosis by anti-Flt1 , 2002, Nature Medicine.