Nanobodies in cell-mediated immunotherapy: On the road to fight cancer

The immune system is essential in recognizing and eliminating tumor cells. The unique characteristics of the tumor microenvironment (TME), such as heterogeneity, reduced blood flow, hypoxia, and acidity, can reduce the efficacy of cell-mediated immunity. The primary goal of cancer immunotherapy is to modify the immune cells or the TME to enable the immune system to eliminate malignancies successfully. Nanobodies, known as single-domain antibodies, are light chain-free antibody fragments produced from Camelidae antibodies. The unique properties of nanobodies, including high stability, reduced immunogenicity, enhanced infiltration into the TME of solid tumors and facile genetic engineering have led to their promising application in cell-mediated immunotherapy. They can promote the cancer therapy either directly by bridging between tumor cells and immune cells and by targeting cancer cells using immune cell-bound nanobodies or indirectly by blocking the inhibitory ligands/receptors. The T-cell activation can be engaged through anti-CD3 and anti-4-1BB nanobodies in the bispecific (bispecific T-cell engagers (BiTEs)) and trispecific (trispecific T-cell engager (TriTEs)) manners. Also, nanobodies can be used as natural killer (NK) cell engagers (BiKEs, TriKEs, and TetraKEs) to create an immune synapse between the tumor and NK cells. Nanobodies can redirect immune cells to attack tumor cells through a chimeric antigen receptor (CAR) incorporating a nanobody against the target antigen. Various cancer antigens have been targeted by nanobody-based CAR-T and CAR-NK cells for treating both hematological and solid malignancies. They can also cause the continuation of immune surveillance against tumor cells by stopping inappropriate inhibition of immune checkpoints. Other roles of nanobodies in cell-mediated cancer immunotherapy include reprogramming macrophages to reduce metastasis and angiogenesis, as well as preventing the severe side effects occurring in cell-mediated immunotherapy. Here, we highlight the critical functions of various immune cells, including T cells, NK cells, and macrophages in the TME, and discuss newly developed immunotherapy methods based on the targeted manipulation of immune cells and TME with nanobodies.

[1]  Huajing Wang,et al.  Development of a bispecific antibody targeting PD-L1 and TIGIT with optimal cytotoxicity , 2022, Scientific Reports.

[2]  Jianwei Zhu,et al.  Tumour inhibitory activity on pancreatic cancer by bispecific nanobody targeting PD-L1 and CXCR4 , 2022, BMC Cancer.

[3]  Brian J. Geist,et al.  Enhanced delivery of antibodies across the blood-brain barrier via TEMs with inherent receptor-mediated phagocytosis. , 2022, Med.

[4]  Q. Wen,et al.  S133: OFF-THE-SHELF CD33 CAR-NK CELL THERAPY FOR RELAPSE/REFRACTORY AML: FIRST-IN-HUMAN, PHASE I TRIAL , 2022, HemaSphere.

[5]  K. Imai,et al.  Survival impact of immune cells infiltrating peritumoral area of hepatocellular carcinoma , 2022, Cancer science.

[6]  R. Pytlík,et al.  Chimeric Antigen Receptor Based Cellular Therapy for Treatment Of T-Cell Malignancies , 2022, Frontiers in Oncology.

[7]  M. Arbabi-Ghahroudi Camelid Single-Domain Antibodies: Promises and Challenges as Lifesaving Treatments , 2022, International journal of molecular sciences.

[8]  F. Schmidt,et al.  Nanobodies dismantle post‐pyroptotic ASC specks and counteract inflammation in vivo , 2022, EMBO molecular medicine.

[9]  B. de Strooper,et al.  AAV‐mediated delivery of an anti‐BACE1 VHH alleviates pathology in an Alzheimer's disease model , 2022, EMBO molecular medicine.

[10]  G. Johanning,et al.  Emerging Novel Combined CAR-T Cell Therapies , 2022, Cancers.

[11]  N. Kumari,et al.  Tumor-associated macrophages in cancer: recent advancements in cancer nanoimmunotherapies , 2022, Journal of experimental & clinical cancer research : CR.

[12]  L. Álvarez-Vallina,et al.  Trispecific T-cell engagers for dual tumor-targeting of colorectal cancer , 2022, Oncoimmunology.

[13]  Lin Yang,et al.  Nanobody-based anti-CD22-chimeric antigen receptor T cell immunotherapy exhibits improved remission against B-cell acute lymphoblastic leukemia. , 2022, Transplant immunology.

[14]  Yakun Wan,et al.  Preclinical evaluation of [99mTc]Tc-labeled anti-EpCAM nanobody for EpCAM receptor expression imaging by immuno-SPECT/CT , 2021, European Journal of Nuclear Medicine and Molecular Imaging.

[15]  S. Filosa,et al.  Novel approaches in cancer treatment: preclinical and clinical development of small non-coding RNA therapeutics , 2021, Journal of experimental & clinical cancer research : CR.

[16]  M. Rafei,et al.  Cell Therapy: Types, Regulation, and Clinical Benefits , 2021, Frontiers in Medicine.

[17]  Zhaoming Li,et al.  A Single-Arm, Open-Label, Pilot Trial of Autologous CD7-CAR-T Cells for CD7 Positive Relapsed and Refractory T-Lymphoblastic Leukemia/Lymphoma , 2021, Blood.

[18]  Qiuchuan Zhuang,et al.  Tri-Specific CD19xCD20xCD22 VHH CAR-T Cells (LCAR-AIO) Eradicate Antigen-Heterogeneous B Cell Tumors, Enhance Expansion, and Prolong Persistence in Preclinical In Vivo Models , 2021, Blood.

[19]  K. Kashfi,et al.  Macrophage Reprogramming and Cancer Therapeutics: Role of iNOS-Derived NO , 2021, Cells.

[20]  Yuan Yin,et al.  Nanobody-Engineered Natural Killer Cell Conjugates for Solid Tumor Adoptive Immunotherapy. , 2021, Small.

[21]  Guangxian Xu,et al.  Nanobody-armed T cells endow CAR-T cells with cytotoxicity against lymphoma cells , 2021, Cancer cell international.

[22]  M. Geller,et al.  A HER2 Tri-Specific NK Cell Engager Mediates Efficient Targeting of Human Ovarian Cancer , 2021, Cancers.

[23]  A. J. Schuhmacher,et al.  Transportation of Single-Domain Antibodies through the Blood–Brain Barrier , 2021, Biomolecules.

[24]  Ying Yuan,et al.  Donor-Derived CD7 Chimeric Antigen Receptor T Cells for T-Cell Acute Lymphoblastic Leukemia: First-in-Human, Phase I Trial , 2021, Journal of clinical oncology : official journal of the American Society of Clinical Oncology.

[25]  Joanne Sun,et al.  Generation of a safe and efficacious llama single-domain antibody fragment (vHH) targeting the membrane-proximal region of 4-1BB for engineering therapeutic bispecific antibodies for cancer , 2021, Journal for ImmunoTherapy of Cancer.

[26]  Q. Gao,et al.  Single VHH-directed BCMA CAR-T cells cause remission of relapsed/refractory multiple myeloma , 2021, Leukemia.

[27]  M. Sadelain,et al.  Cytokine release syndrome and associated neurotoxicity in cancer immunotherapy , 2021, Nature Reviews Immunology.

[28]  Kevin A. Henry,et al.  Incorporation of a Novel CD16-Specific Single-Domain Antibody into Multispecific Natural Killer Cell Engagers With Potent ADCC. , 2021, Molecular pharmaceutics.

[29]  Yong Zhu,et al.  A Novel Small Molecular Antibody, HER2-Nanobody, Inhibits Tumor Proliferation in HER2-Positive Breast Cancer Cells In Vitro and In Vivo , 2021, Frontiers in Oncology.

[30]  Mengying Hu,et al.  mRNA Delivery of a Bispecific Single‐Domain Antibody to Polarize Tumor‐Associated Macrophages and Synergize Immunotherapy against Liver Malignancies , 2021, Advanced materials.

[31]  Guodong Yang,et al.  Reprogramming Immune Cells for Enhanced Cancer Immunotherapy: Targets and Strategies , 2021, Frontiers in Immunology.

[32]  E. Bremer,et al.  The Role of Macrophages in Cancer Development and Therapy , 2021, Cancers.

[33]  Ansuman T. Satpathy,et al.  Surface proteomics reveals CD72 as a target for in vitro-evolved nanobody-based CAR-T cells in KMT2A/MLL1-rearranged B-ALL. , 2021, Cancer discovery.

[34]  P. Besenius,et al.  Targeted Repolarization of Tumor‐Associated Macrophages via Imidazoquinoline‐Linked Nanobodies , 2021, Advanced science.

[35]  J. Andersen,et al.  Programmable half-life and anti-tumour effects of bispecific T-cell engager-albumin fusions with tuned FcRn affinity , 2021, Communications biology.

[36]  A. Dyer,et al.  Oncolytic herpesvirus expressing PD-L1 BiTE for cancer therapy: exploiting tumor immune suppression as an opportunity for targeted immunotherapy , 2021, Journal for ImmunoTherapy of Cancer.

[37]  Weiqi Wang,et al.  Nanobody-based chimeric antigen receptor T cells designed by CRISPR/Cas9 technology for solid tumor immunotherapy , 2021, Signal Transduction and Targeted Therapy.

[38]  S. Muyldermans,et al.  Development and Characterization of Nanobodies Targeting the Kupffer Cell , 2021, Frontiers in Immunology.

[39]  Xiaoling Lu,et al.  A CTLA-4 blocking strategy based on Nanoboby in dendritic cell-stimulated cytokine-induced killer cells enhances their anti-tumor effects , 2021, BMC cancer.

[40]  A. Jemal,et al.  Global Cancer Statistics 2020: GLOBOCAN Estimates of Incidence and Mortality Worldwide for 36 Cancers in 185 Countries , 2021, CA: a cancer journal for clinicians.

[41]  A. Rajabzadeh,et al.  A VHH-Based Anti-MUC1 Chimeric Antigen Receptor for Specific Retargeting of Human Primary T Cells to MUC1-Positive Cancer Cells , 2020, Cell journal.

[42]  M. Raftery,et al.  Engineering NK Cells for CAR Therapy—Recent Advances in Gene Transfer Methodology , 2021, Frontiers in Immunology.

[43]  R. Becker,et al.  Monoclonal Antibody-Based Immunotherapy and Its Role in the Development of Cardiac Toxicity , 2020, Cancers.

[44]  S. Duan,et al.  Nanobodies targeting immune checkpoint molecules for tumor immunotherapy and immunoimaging (Review) , 2020, International journal of molecular medicine.

[45]  M. Shokrgozar,et al.  Isolation and characterization of nanobodies against epithelial cell adhesion molecule as novel theranostic agents for cancer therapy. , 2020, Molecular immunology.

[46]  S. Ghorashian,et al.  Nanobody Based Tri-Specific Chimeric Antigen Receptor to Treat Acute Myeloid Leukaemia , 2020 .

[47]  H. Ploegh,et al.  Nanobodies in cancer. , 2020, Seminars in immunology.

[48]  Jeffrey S. Miller,et al.  A trispecific killer engager molecule against CLEC12A effectively induces NK cell mediated killing of AML cells , 2020, Leukemia.

[49]  Xiaoyuan Chen,et al.  Activating Macrophage‐Mediated Cancer Immunotherapy by Genetically Edited Nanoparticles , 2020, Advanced materials.

[50]  Tao Chen,et al.  Novel single-domain antibodies against the EGFR domain III epitope exhibit the anti-tumor effect , 2020, Journal of Translational Medicine.

[51]  P. Hari,et al.  Bispecific anti-CD20, anti-CD19 CAR T cells for relapsed B cell malignancies: a phase 1 dose escalation and expansion trial , 2020, Nature Medicine.

[52]  Ashley R Sutherland,et al.  Modular Chimeric Antigen Receptor Systems for Universal CAR T Cell Retargeting , 2020, International journal of molecular sciences.

[53]  M. Simon,et al.  The tumor microenvironment , 2020, Current Biology.

[54]  Yongping Song,et al.  Safety and efficacy of CAR-T cell targeting BCMA in patients with multiple myeloma coinfected with chronic hepatitis B virus , 2020, Journal for ImmunoTherapy of Cancer.

[55]  K. Shah,et al.  Nanobodies: Next Generation of Cancer Diagnostics and Therapeutics , 2020, Frontiers in Oncology.

[56]  Jeffrey S. Miller,et al.  Potent Cytolytic Activity and Specific IL15 Delivery in a Second-Generation Trispecific Killer Engager , 2020, Cancer Immunology Research.

[57]  Erratum: Global cancer statistics 2018: GLOBOCAN estimates of incidence and mortality worldwide for 36 cancers in 185 countries. , 2020, CA: a cancer journal for clinicians.

[58]  R. Bergmann,et al.  Highly Efficient Targeting of EGFR-Expressing Tumor Cells with UniCAR T Cells via Target Modules Based on Cetuximab® , 2020, OncoTargets and therapy.

[59]  M. Bachmann,et al.  Extended half-life target module for sustainable UniCAR T-cell treatment of STn-expressing cancers , 2020, Journal of Experimental & Clinical Cancer Research.

[60]  R. Bergmann,et al.  Extended half-life target module for sustainable UniCAR T-cell treatment of STn-expressing cancers , 2020, Journal of experimental & clinical cancer research : CR.

[61]  Martha E. Zeeman,et al.  Human chimeric antigen receptor macrophages for cancer immunotherapy , 2020, Nature Biotechnology.

[62]  Y. Chen,et al.  Systematically optimized BCMA/CS1 bispecific CAR-T cells robustly control heterogeneous multiple myeloma , 2020, bioRxiv.

[63]  Wan-Uk Kim,et al.  The Role of Calcium–Calcineurin–NFAT Signaling Pathway in Health and Autoimmune Diseases , 2020, Frontiers in Immunology.

[64]  R. Glauben,et al.  IL-4 induces M2 macrophages to produce sustained analgesia via opioids. , 2020, JCI insight.

[65]  D. Larsimont,et al.  Retrospective analysis of the immunogenic effects of intra-arterial locoregional therapies in hepatocellular carcinoma: a rationale for combining selective internal radiation therapy (SIRT) and immunotherapy , 2020, BMC Cancer.

[66]  Cai Zhang,et al.  Targeting Natural Killer Cells for Tumor Immunotherapy , 2020, Frontiers in Immunology.

[67]  H. Ploegh,et al.  Improved Antitumor Efficacy of Chimeric Antigen Receptor T Cells that Secrete Single-Domain Antibody Fragments , 2020, Cancer Immunology Research.

[68]  J. Tavernier,et al.  Rapid and Effective Generation of Nanobody Based CARs using PCR and Gibson Assembly , 2020, International journal of molecular sciences.

[69]  G. Adam,et al.  Targeting CD38-Expressing Multiple Myeloma and Burkitt Lymphoma Cells In Vitro with Nanobody-Based Chimeric Antigen Receptors (Nb-CARs) , 2020, Cells.

[70]  C. June,et al.  Bi-specific and Split CAR T Cells Targeting CD13 and TIM3 Eradicate Acute Myeloid Leukemia. , 2020, Blood.

[71]  Xiao-hui Zhang,et al.  Gasdermin E–mediated target cell pyroptosis by CAR T cells triggers cytokine release syndrome , 2020, Science Immunology.

[72]  Yakun Wan,et al.  Preclinical development of a novel CD47 nanobody with less toxicity and enhanced anti-cancer therapeutic potential , 2020, Journal of Nanobiotechnology.

[73]  D. Campana,et al.  NK cells for cancer immunotherapy , 2020, Nature Reviews Drug Discovery.

[74]  S. Muyldermans,et al.  Identification of Nanobodies against the Acute Myeloid Leukemia Marker CD33 , 2020, International journal of molecular sciences.

[75]  Jiayu Liu,et al.  Identification of anti-CD16a single domain antibodies and their application in bispecific antibodies , 2020, Cancer biology & therapy.

[76]  N. Jalili,et al.  Evaluation the potential of recombinant anti-CD3 nanobody on immunomodulatory function. , 2019, Molecular immunology.

[77]  L. Farahmand,et al.  In vivo tumor-suppressing and anti-angiogenic activities of a recombinant anti-CD3ε nanobody in breast cancer mice model. , 2019, Immunotherapy.

[78]  Yakun Wan,et al.  Blocking the PD-1-PD-L1 axis by a novel PD-1 specific nanobody expressed in yeast as a potential therapeutic for immunotherapy. , 2019, Biochemical and biophysical research communications.

[79]  S. Muyldermans,et al.  The Therapeutic Potential of Nanobodies , 2019, BioDrugs.

[80]  B. Hammock,et al.  A Nanobody Against Cytotoxic T-Lymphocyte Associated Antigen-4 Increases the Anti-Tumor Effects of Specific CD8+ T Cells. , 2019, Journal of Biomedical Nanotechnology.

[81]  Shahriyar Abdoli,et al.  Engineered Jurkat Cells for Targeting Prostate-Specific Membrane Antigen on Prostate Cancer Cells by Nanobody-Based Chimeric Antigen Receptor , 2019, Iranian biomedical journal.

[82]  X. Ke,et al.  WNT/β-Catenin Signaling Pathway Regulating T Cell-Inflammation in the Tumor Microenvironment , 2019, Front. Immunol..

[83]  A. Arashkia,et al.  T cell engineered with a novel nanobody‐based chimeric antigen receptor against VEGFR2 as a candidate for tumor immunotherapy , 2019, IUBMB life.

[84]  N. Devoogdt,et al.  Single Domain Antibody-Mediated Blockade of Programmed Death-Ligand 1 on Dendritic Cells Enhances CD8 T-cell Activation and Cytokine Production , 2019, Vaccines.

[85]  L. Álvarez-Vallina,et al.  Carcinoembryonic Antigen (CEA)-Specific 4-1BB-Costimulation Induced by CEA-Targeted 4-1BB-Agonistic Trimerbodies , 2019, Front. Immunol..

[86]  Yan Zhang,et al.  T Cell Dysfunction in Cancer Immunity and Immunotherapy , 2019, Front. Immunol..

[87]  Yongping Song,et al.  Engineering switchable and programmable universal CARs for CAR T therapy , 2019, Journal of Hematology & Oncology.

[88]  M. Bachmann The UniCAR system: A modular CAR T cell approach to improve the safety of CAR T cells. , 2019, Immunology letters.

[89]  P. Krebs,et al.  Targeting CD47 in Anaplastic Thyroid Carcinoma Enhances Tumor Phagocytosis by Macrophages and Is a Promising Therapeutic Strategy , 2019, Thyroid : official journal of the American Thyroid Association.

[90]  A. Rotte,et al.  Combination of CTLA-4 and PD-1 blockers for treatment of cancer , 2019, Journal of experimental & clinical cancer research : CR.

[91]  W. V. van Weerden,et al.  Construction of a chimeric antigen receptor bearing a nanobody against prostate a specific membrane antigen in prostate cancer , 2019, Journal of cellular biochemistry.

[92]  Yongping Song,et al.  The phase I clinical study of CART targeting BCMA with humanized alpaca-derived single-domain antibody as antigen recognition domain. , 2019, Journal of Clinical Oncology.

[93]  R. Kamm,et al.  Remodeling of the Tumor Microenvironment by a Chemokine/Anti-PD-L1 Nanobody Fusion Protein. , 2019, Molecular pharmaceutics.

[94]  Yuan-fang Liu,et al.  Exploratory trial of a biepitopic CAR T-targeting B cell maturation antigen in relapsed/refractory multiple myeloma , 2019, Proceedings of the National Academy of Sciences.

[95]  Jiayu Liu,et al.  Bp-Bs, a Novel T-cell Engaging Bispecific Antibody with Biparatopic Her2 Binding, Has Potent Anti-tumor Activities , 2019, Molecular therapy oncolytics.

[96]  P. Chames,et al.  Nanobody-CD16 Catch Bond Reveals NK Cell Mechanosensitivity. , 2019, Biophysical journal.

[97]  R. Hynes,et al.  Nanobody-based CAR T cells that target the tumor microenvironment inhibit the growth of solid tumors in immunocompetent mice , 2019, Proceedings of the National Academy of Sciences.

[98]  D. Powell,et al.  The Emergence of Universal Immune Receptor T Cell Therapy for Cancer , 2019, Front. Oncol..

[99]  S. Wong,et al.  Targeting immune cells for cancer therapy , 2019, Redox biology.

[100]  J-Pablo Salvador,et al.  Nanobody: outstanding features for diagnostic and therapeutic applications , 2019, Analytical and Bioanalytical Chemistry.

[101]  J. Vose,et al.  Tolerability and activity of ublituximab, umbralisib, and ibrutinib in patients with chronic lymphocytic leukaemia and non-Hodgkin lymphoma: a phase 1 dose escalation and expansion trial. , 2019, The Lancet. Haematology.

[102]  Kevin A. Henry,et al.  Camelid single-domain antibodies raised by DNA immunization are potent inhibitors of EGFR signaling. , 2019, The Biochemical journal.

[103]  C. Westhoff,et al.  Monoclonal anti‐CD47 interference in red cell and platelet testing , 2018, Transfusion.

[104]  M. Najafi,et al.  Macrophage polarity in cancer: A review , 2018, Journal of cellular biochemistry.

[105]  Huimin,et al.  A novel CD 7 chimeric antigen receptor-modified NK-92 MI cell line targeting T-cell acute lymphoblastic leukemia , 2019 .

[106]  Xuejun Zhu,et al.  A novel CD7 chimeric antigen receptor-modified NK-92MI cell line targeting T-cell acute lymphoblastic leukemia. , 2019, American journal of cancer research.

[107]  B. Lei,et al.  A phase 1, open-label study of LCAR-B38M, a chimeric antigen receptor T cell therapy directed against B cell maturation antigen, in patients with relapsed or refractory multiple myeloma , 2018, Journal of Hematology & Oncology.

[108]  Kevin A. Henry,et al.  Isolation and characterization of camelid single-domain antibodies against HER2 , 2018, BMC Research Notes.

[109]  Juanjuan Zhao,et al.  Universal CARs, universal T cells, and universal CAR T cells , 2018, Journal of Hematology & Oncology.

[110]  C. Deng,et al.  Effect of Stromal Cells in Tumor Microenvironment on Metastasis Initiation , 2018, International journal of biological sciences.

[111]  J. Zapata,et al.  A tumor-targeted trimeric 4-1BB-agonistic antibody induces potent anti-tumor immunity without systemic toxicity , 2018, Nature Communications.

[112]  Sathish Kumar Mungamuri,et al.  Blocking immunoinhibitory receptor LILRB2 reprograms tumor-associated myeloid cells and promotes antitumor immunity , 2018, The Journal of clinical investigation.

[113]  E. Giralt,et al.  Blocking EGFR Activation with Anti-EGF Nanobodies via Two Distinct Molecular Recognition Mechanisms. , 2018, Angewandte Chemie.

[114]  Hon Cheung Lee,et al.  Anti-Multiple Myeloma Activity of Nanobody-Based Anti-CD38 Chimeric Antigen Receptor T Cells. , 2018, Molecular pharmaceutics.

[115]  B. Devreese,et al.  Targeting Protumoral Tumor-Associated Macrophages with Nanobody-Functionalized Nanogels through Strain Promoted Azide Alkyne Cycloaddition Ligation. , 2018, Bioconjugate chemistry.

[116]  L. Álvarez-Vallina,et al.  Bispecific light T-cell engagers for gene-based immunotherapy of epidermal growth factor receptor (EGFR)-positive malignancies , 2018, Cancer Immunology, Immunotherapy.

[117]  Jiayu Liu,et al.  Site-specific PEGylation of an anti-CEA/CD3 bispecific antibody improves its antitumor efficacy , 2018, International journal of nanomedicine.

[118]  J. Steinbach,et al.  From mono- to bivalent: improving theranostic properties of target modules for redirection of UniCAR T cells against EGFR-expressing tumor cells in vitro and in vivo , 2018, Oncotarget.

[119]  D. Ahmadvand,et al.  Development of specific nanobodies (VHH) for CD19 immuno-targeting of human B-lymphocytes , 2018, Iranian journal of basic medical sciences.

[120]  R. Pazdur,et al.  FDA Approval Summary: Tocilizumab for Treatment of Chimeric Antigen Receptor T Cell‐Induced Severe or Life‐Threatening Cytokine Release Syndrome , 2018, The oncologist.

[121]  M. Ernst,et al.  Targeting Macrophages in Cancer: From Bench to Bedside , 2018, Front. Oncol..

[122]  J. Koch,et al.  CD16A Activation of NK Cells Promotes NK Cell Proliferation and Memory-Like Cytotoxicity against Cancer Cells , 2018, Cancer Immunology Research.

[123]  Lestat R. Ali,et al.  Targeting Cytokine Therapy to the Pancreatic Tumor Microenvironment Using PD-L1–Specific VHHs , 2018, Cancer Immunology Research.

[124]  H. Abken,et al.  Nanobody Based Dual Specific CARs , 2018, International journal of molecular sciences.

[125]  Xiao-mei Yang,et al.  Screening and antitumor effect of an anti-CTLA-4 nanobody , 2017, Oncology reports.

[126]  F. Koch-Nolte,et al.  Nanobodies and Nanobody-Based Human Heavy Chain Antibodies As Antitumor Therapeutics , 2017, Front. Immunol..

[127]  S. Muyldermans,et al.  Nanobody-Based Delivery Systems for Diagnosis and Targeted Tumor Therapy , 2017, Front. Immunol..

[128]  K. Shimada,et al.  Regulatory T Cells and Tumor-Associated Macrophages in the Tumor Microenvironment in Non-Muscle Invasive Bladder Cancer Treated with Intravesical Bacille Calmette-Guérin: A Long-Term Follow-Up Study of a Japanese Cohort , 2017, International journal of molecular sciences.

[129]  L. Álvarez-Vallina,et al.  ATTACK, a novel bispecific T cell-recruiting antibody with trivalent EGFR binding and monovalent CD3 binding for cancer immunotherapy , 2017, Oncoimmunology.

[130]  Jiayu Liu,et al.  BiHC, a T-Cell–Engaging Bispecific Recombinant Antibody, Has Potent Cytotoxic Activity Against Her2 Tumor Cells1 , 2017, Translational oncology.

[131]  S. M. Mousavi Gargari,et al.  Targeting Colorectal Cancer Cell Lines Using Nanobodies; AgSK1as a Potential Target. , 2017, Iranian journal of biotechnology.

[132]  Aiwu Zhou,et al.  Structural basis of a novel PD-L1 nanobody for immune checkpoint blockade , 2017, Cell Discovery.

[133]  M. Monteiro,et al.  Immune modulation of some autoimmune diseases: the critical role of macrophages and neutrophils in the innate and adaptive immunity , 2017, Journal of Translational Medicine.

[134]  J. Steinbach,et al.  A novel nanobody-based target module for retargeting of T lymphocytes to EGFR-expressing cancer cells via the modular UniCAR platform , 2017, Oncoimmunology.

[135]  C. Duyckaerts,et al.  Camelid single-domain antibodies: A versatile tool for in vivo imaging of extracellular and intracellular brain targets. , 2016, Journal of controlled release : official journal of the Controlled Release Society.

[136]  C. Meyer-Schwesinger,et al.  Nanobodies that block gating of the P2X7 ion channel ameliorate inflammation , 2016, Science Translational Medicine.

[137]  A. Rezaei,et al.  Iranian Journal of Basic Medical Sciences Preparation and Characterization of a Novel Nanobody against T-cell Immunoglobulin and Mucin-3 (tim-3) , 2022 .

[138]  H. Einsele,et al.  Bispecific T-Cell Engager (BiTE) Antibody Construct Blinatumomab for the Treatment of Patients With Relapsed/Refractory Non-Hodgkin Lymphoma: Final Results From a Phase I Study. , 2016, Journal of clinical oncology : official journal of the American Society of Clinical Oncology.

[139]  Jeffrey S. Miller,et al.  Tetraspecific scFv construct provides NK cell mediated ADCC and self-sustaining stimuli via insertion of IL-15 as a cross-linker , 2016, Oncotarget.

[140]  S. Spranger Mechanisms of tumor escape in the context of the T-cell-inflamed and the non-T-cell-inflamed tumor microenvironment. , 2016, International immunology.

[141]  S. Hiller,et al.  ASC filament formation serves as a signal amplification mechanism for inflammasomes , 2016, Nature Communications.

[142]  H. Ploegh,et al.  A single domain antibody fragment that recognizes the adaptor ASC defines the role of ASC domains in inflammasome assembly , 2016, The Journal of experimental medicine.

[143]  R. Bargou,et al.  Blinatumomab: a CD19/CD3 bispecific T cell engager (BiTE) with unique anti-tumor efficacy , 2016, Leukemia & lymphoma.

[144]  P. He,et al.  A novel bispecific antibody, BiSS, with potent anti-cancer activities , 2016, Cancer biology & therapy.

[145]  Jurgen Del-Favero,et al.  Camelid Ig V genes reveal significant human homology not seen in therapeutic target genes, providing for a powerful therapeutic antibody platform , 2015, mAbs.

[146]  B. '. ’t Hart,et al.  The preclinical pharmacology of the high affinity anti-IL-6R Nanobody® ALX-0061 supports its clinical development in rheumatoid arthritis , 2015, Arthritis Research & Therapy.

[147]  F. Kazemi-Lomedasht,et al.  Inhibition of angiogenesis in human endothelial cell using VEGF specific nanobody. , 2015, Molecular immunology.

[148]  M. Hidalgo,et al.  Inhibition of CD47 Effectively Targets Pancreatic Cancer Stem Cells via Dual Mechanisms , 2015, Clinical Cancer Research.

[149]  M. Ravic,et al.  A phase 1 study of the bispecific anti-CD30/CD16A antibody construct AFM13 in patients with relapsed or refractory Hodgkin lymphoma. , 2011, Blood.

[150]  W. Sellers,et al.  Multivalent nanobodies targeting death receptor 5 elicit superior tumor cell killing through efficient caspase induction , 2014, mAbs.

[151]  M. Shokrgozar,et al.  T cells expressing VHH-directed oligoclonal chimeric HER2 antigen receptors: towards tumor-directed oligoclonal T cell therapy. , 2014, Biochimica et biophysica acta.

[152]  A. Bhattacharya,et al.  P2X7 antagonists as potential therapeutic agents for the treatment of CNS disorders. , 2014, Progress in medicinal chemistry.

[153]  Juan Ma,et al.  Retargeting NK‐92 for anti‐melanoma activity by a TCR‐like single‐domain antibody , 2013, Immunology and cell biology.

[154]  T. Standal,et al.  Anti‐c‐MET Nanobody® – a new potential drug in multiple myeloma treatment , 2013, European journal of haematology.

[155]  M. Shokrgozar,et al.  Genetically engineered T cells bearing chimeric nanoconstructed receptors harboring TAG-72-specific camelid single domain antibodies as targeting agents. , 2013, Cancer letters.

[156]  S. Muyldermans,et al.  Nanobodies and their potential applications. , 2013, Nanomedicine.

[157]  M. Pan,et al.  NFAT gene family in inflammation and cancer. , 2013, Current molecular medicine.

[158]  Min Li,et al.  Antibody therapeutics targeting ion channels: are we there yet? , 2013, Acta Pharmacologica Sinica.

[159]  Mitchell Ho,et al.  A Human Single-Domain Antibody Elicits Potent Antitumor Activity by Targeting an Epitope in Mesothelin Close to the Cancer Cell Surface , 2013, Molecular Cancer Therapeutics.

[160]  M. Rajabibazl,et al.  A novel VHH nanobody against the active site (the CA domain) of tumor-associated, carbonic anhydrase isoform IX and its usefulness for cancer diagnosis , 2013, Biotechnology Letters.

[161]  M. Shokrgozar,et al.  Development of Oligoclonal Nanobodies for Targeting the Tumor-Associated Glycoprotein 72 Antigen , 2013, Molecular Biotechnology.

[162]  S. Rose-John IL-6 Trans-Signaling via the Soluble IL-6 Receptor: Importance for the Pro-Inflammatory Activities of IL-6 , 2012, International journal of biological sciences.

[163]  L. Weiner,et al.  Bispecific and Trispecific Killer Cell Engagers Directly Activate Human NK Cells through CD16 Signaling and Induce Cytotoxicity and Cytokine Production , 2012, Molecular Cancer Therapeutics.

[164]  J. Bourgeois,et al.  Cell‐penetrating anti‐GFAP VHH and corresponding fluorescent fusion protein VHH‐GFP spontaneously cross the blood‐brain barrier and specifically recognize astrocytes: application to brain imaging , 2012, FASEB journal : official publication of the Federation of American Societies for Experimental Biology.

[165]  J. Armitage,et al.  Non-Hodgkin lymphoma , 2012, The Lancet.

[166]  J. C. Almagro,et al.  Natural and man-made V-gene repertoires for antibody discovery , 2012, Front. Immun..

[167]  O. Finn,et al.  Immuno-oncology: understanding the function and dysfunction of the immune system in cancer. , 2012, Annals of oncology : official journal of the European Society for Medical Oncology.

[168]  Drew M. Pardoll,et al.  The blockade of immune checkpoints in cancer immunotherapy , 2012, Nature Reviews Cancer.

[169]  D. Ahmadvand,et al.  A caspase 8-based suicide switch induces apoptosis in nanobody-directed chimeric receptor expressing T cells , 2012, International Journal of Hematology.

[170]  G. V. van Dongen,et al.  Nanobodies Targeting the Hepatocyte Growth Factor: Potential New Drugs for Molecular Cancer Therapy , 2012, Molecular Cancer Therapeutics.

[171]  D. Ahmadvand,et al.  Nanobody-based chimeric receptor gene integration in Jurkat cells mediated by φC31 integrase. , 2011, Experimental cell research.

[172]  T. Veres,et al.  Molecular imaging of glioblastoma multiforme using anti-insulin-like growth factor-binding protein-7 single-domain antibodies , 2010, British Journal of Cancer.

[173]  A. Mantovani,et al.  Macrophage plasticity and interaction with lymphocyte subsets: cancer as a paradigm , 2010, Nature Immunology.

[174]  Rongzhi Liu,et al.  COMBODY: one‐domain antibody multimer with improved avidity , 2010, Immunology and cell biology.

[175]  K. Yanagihara,et al.  Activated T–cell-mediated Immunotherapy With a Chimeric Receptor Against CD38 in B-cell Non-Hodgkin Lymphoma , 2009, Journal of immunotherapy.

[176]  M. Seman,et al.  Single domain antibodies: promising experimental and therapeutic tools in infection and immunity , 2009, Medical Microbiology and Immunology.

[177]  D. Ahmadvand,et al.  Anti-MUC1 nanobody can redirect T-body cytotoxic effector function. , 2009, Hybridoma.

[178]  L. Alcaraz,et al.  Antagonists of the P2X(7) receptor. From lead identification to drug development. , 2009, Journal of medicinal chemistry.

[179]  S. Muyldermans,et al.  General Strategy to Humanize a Camelid Single-domain Antibody and Identification of a Universal Humanized Nanobody Scaffold* , 2009, Journal of Biological Chemistry.

[180]  C. Sautès-Fridman,et al.  Isolation and characterization of anti-FcgammaRIII (CD16) llama single-domain antibodies that activate natural killer cells. , 2007, Protein engineering, design & selection : PEDS.

[181]  F. Massin,et al.  Comparative T-cell oligoclonality in lung, tumor and lymph nodes in human non-small cell lung cancer. , 2005, Oncology reports.

[182]  D. Bostwick,et al.  Prostate specific membrane antigen expression in prostatic intraepithelial neoplasia and adenocarcinoma , 1998, Cancer.

[183]  G. Tosato,et al.  Interleukin-1 induces interleukin-6 production in peripheral blood monocytes. , 1990, Blood.