Hyaluronidase with pH‐responsive Dextran Modification as an Adjuvant Nanomedicine for Enhanced Photodynamic‐Immunotherapy of Cancer

The condensed tumor extracellular matrix (ECM) consisting of cross‐linked hyaluronic acid (HA) is one of key factors that results in the aberrant tumor microenvironment (TME) and the resistance to various types of therapies. Herein, hyaluronidase (HAase) is modified by a biocompatible polymer, dextran (DEX), via a pH‐responsive traceless linker. The formulated DEX‐HAase nanoparticles show enhanced enzyme stability, reduced immunogenicity, and prolonged blood half‐life after intravenous injection. With efficient tumor passive accumulation, DEX‐HAase within the acidic TME would be dissociated to release native HAase, which afterward triggers the breakdown of HA to loosen the ECM structure, subsequently leading to enhanced penetration of oxygen and other therapeutic agents. The largely relieved tumor hypoxia would promote the therapeutic effect of nanoparticle‐based photodynamic therapy (PDT), accompanied by the reverse of the immunosuppressive TME to boost cancer immunotherapy. Interestingly, the therapeutic responses achieved by the combination of PDT and anti‐programmed death‐ligand 1 (anti‐PD‐L1) checkpoint blockade therapy could be significantly enhanced by pretreatment with DEX‐HAase. In addition to destructing tumors with direct light exposure, a robust abscopal effect is achieved after such treatment, which is promising for tumor metastasis inhibition. The work presents a new type of adjuvant nanomedicine to assist photodynamic‐immunotherapy of cancer, by effective modulation of TME.

[1]  Leaf Huang,et al.  Drug delivery systems targeting tumor-associated fibroblasts for cancer immunotherapy. , 2019, Cancer letters.

[2]  Siling Wang,et al.  Tumor Microenvironment‐Activatable Prodrug Vesicles for Nanoenabled Cancer Chemoimmunotherapy Combining Immunogenic Cell Death Induction and CD47 Blockade , 2019, Advanced materials.

[3]  M. Najafi,et al.  Extracellular matrix (ECM) stiffness and degradation as cancer drivers , 2018, Journal of cellular biochemistry.

[4]  Chenjie Xu,et al.  Microneedle-Assisted Topical Delivery of Photodynamically Active Mesoporous Formulation for Combination Therapy of Deep-Seated Melanoma. , 2018, ACS nano.

[5]  Ligeng Xu,et al.  Photosensitizer-crosslinked in-situ polymerization on catalase for tumor hypoxia modulation & enhanced photodynamic therapy. , 2018, Biomaterials.

[6]  Xuesi Chen,et al.  Highly enhanced cancer immunotherapy by combining nanovaccine with hyaluronidase. , 2018, Biomaterials.

[7]  Liangzhu Feng,et al.  Nanoscale covalent organic polymers as a biodegradable nanomedicine for chemotherapy-enhanced photodynamic therapy of cancer , 2018, Nano Research.

[8]  Zhen Gu,et al.  Bacteria-Driven Hypoxia Targeting for Combined Biotherapy and Photothermal Therapy. , 2018, ACS nano.

[9]  Zhuang Liu,et al.  Hollow MnO2 as a tumor-microenvironment-responsive biodegradable nano-platform for combination therapy favoring antitumor immune responses , 2017, Nature Communications.

[10]  Ben Zhong Tang,et al.  Highly Stable Organic Small Molecular Nanoparticles as an Advanced and Biocompatible Phototheranostic Agent of Tumor in Living Mice. , 2017, ACS nano.

[11]  Z. Su,et al.  Breaching the Hyaluronan Barrier with PH20‐Fc Facilitates Intratumoral Permeation and Enhances Antitumor Efficiency: A Comparative Investigation of Typical Therapeutic Agents in Different Nanoscales , 2016, Advanced healthcare materials.

[12]  Kai Yang,et al.  Catalase‐Loaded TaOx Nanoshells as Bio‐Nanoreactors Combining High‐Z Element and Enzyme Delivery for Enhancing Radiotherapy , 2016, Advanced materials.

[13]  Liangzhu Feng,et al.  Hyaluronidase To Enhance Nanoparticle-Based Photodynamic Tumor Therapy. , 2016, Nano letters.

[14]  A. Theocharis,et al.  Extracellular matrix structure. , 2016, Advanced drug delivery reviews.

[15]  P. B. van Driel,et al.  Combination of Photodynamic Therapy and Specific Immunotherapy Efficiently Eradicates Established Tumors , 2015, Clinical Cancer Research.

[16]  Ye Chen,et al.  Tumor microenvironment: Sanctuary of the devil. , 2015, Cancer letters.

[17]  R. Schreiber,et al.  Metabolic Competition in the Tumor Microenvironment Is a Driver of Cancer Progression , 2015, Cell.

[18]  D. Inman,et al.  Abstract 2345: The collagen-dense tumor microenvironment increases neutrophil recruitment in mouse mammary carcinoma , 2015 .

[19]  J. Buhrman,et al.  High and low molecular weight hyaluronic acid differentially influence macrophage activation. , 2015, ACS biomaterials science & engineering.

[20]  Dong Ki Lee,et al.  Co-delivery of paclitaxel and gemcitabine via CD44-targeting nanocarriers as a prodrug with synergistic antitumor activity against human biliary cancer. , 2015, Biomaterials.

[21]  A. Bullock,et al.  High response rate and PFS with PEGPH20 added to nab-paclitaxel/gemcitabine in stage IV previously untreated pancreatic cancer patients with high-HA tumors: Interim results of a randomized phase II study. , 2015 .

[22]  E. Mardis,et al.  A dendritic cell vaccine increases the breadth and diversity of melanoma neoantigen-specific T cells , 2015, Science.

[23]  Razelle Kurzrock,et al.  PD-L1 Expression as a Predictive Biomarker in Cancer Immunotherapy , 2015, Molecular Cancer Therapeutics.

[24]  Amy Brock,et al.  Nanoparticle targeting of anti-cancer drugs that alter intracellular signaling or influence the tumor microenvironment. , 2014, Advanced drug delivery reviews.

[25]  Maxim N. Artyomov,et al.  Checkpoint Blockade Cancer Immunotherapy Targets Tumour-Specific Mutant Antigens , 2014, Nature.

[26]  S. Gollnick,et al.  Development of photodynamic therapy regimens that control primary tumor growth and inhibit secondary disease , 2014, Cancer Immunology, Immunotherapy.

[27]  P. Bragado,et al.  Mechanisms of disseminated cancer cell dormancy: an awakening field , 2014, Nature Reviews Cancer.

[28]  Denis Wirtz,et al.  Hypoxia and the extracellular matrix: drivers of tumour metastasis , 2014, Nature Reviews Cancer.

[29]  Kun-Ju Lin,et al.  Hyperthermia-mediated local drug delivery by a bubble-generating liposomal system for tumor-specific chemotherapy. , 2014, ACS nano.

[30]  M. Mandalà,et al.  Targeting the PD1/PD-L1 axis in melanoma: biological rationale, clinical challenges and opportunities. , 2014, Critical reviews in oncology/hematology.

[31]  P. Carmeliet,et al.  Tumor hypoxia does not drive differentiation of tumor-associated macrophages but rather fine-tunes the M2-like macrophage population. , 2014, Cancer research.

[32]  P. Choyke,et al.  Improving Conventional Enhanced Permeability and Retention (EPR) Effects; What Is the Appropriate Target? , 2013, Theranostics.

[33]  D. Quail,et al.  Microenvironmental regulation of tumor progression and metastasis , 2014 .

[34]  R. Holcombe,et al.  A phase Ib study of gemcitabine plus PEGPH20 (pegylated recombinant human hyaluronidase) in patients with stage IV previously untreated pancreatic cancer. , 2013 .

[35]  T. Hagemann,et al.  The tumor microenvironment at a glance , 2012, Journal of Cell Science.

[36]  E. Wagner,et al.  Acid-labile traceless click linker for protein transduction. , 2012, Journal of the American Chemical Society.

[37]  S. Guha,et al.  Cytokine network: new targeted therapy for pancreatic cancer. , 2012, Current pharmaceutical design.

[38]  Melissa H Wong,et al.  Tumor microenvironment complexity: emerging roles in cancer therapy. , 2012, Cancer research.

[39]  Steven A. Rosenberg,et al.  Adoptive immunotherapy for cancer: harnessing the T cell response , 2012, Nature Reviews Immunology.

[40]  Karolina Palucka,et al.  Cancer immunotherapy via dendritic cells , 2012, Nature Reviews Cancer.

[41]  Douglas Hanahan,et al.  Accessories to the Crime: Functions of Cells Recruited to the Tumor Microenvironment Prospects and Obstacles for Therapeutic Targeting of Function-enabling Stromal Cell Types , 2022 .

[42]  Jan C. M. van Hest,et al.  Multi-enzyme systems: bringing enzymes together in vitro , 2012 .

[43]  Lin Zhang,et al.  Tumour hypoxia promotes tolerance and angiogenesis via CCL28 and Treg cells , 2011, Nature.

[44]  A. Oseroff,et al.  Enhanced Systemic Immune Reactivity to a Basal Cell Carcinoma Associated Antigen Following Photodynamic Therapy , 2009, Clinical Cancer Research.

[45]  Donald J. Johann,et al.  Cancer and the tumor microenvironment: a review of an essential relationship , 2009, Cancer Chemotherapy and Pharmacology.

[46]  A. Ohta,et al.  Hypoxia-Adenosinergic Immunosuppression: Tumor Protection by T Regulatory Cells and Cancerous Tissue Hypoxia , 2008, Clinical Cancer Research.

[47]  C. Nicholson,et al.  Diffusion in brain extracellular space. , 2008, Physiological reviews.

[48]  P. Noble,et al.  Hyaluronan in tissue injury and repair. , 2007, Annual review of cell and developmental biology.

[49]  R. Savani,et al.  Hyaluronan-mediated angiogenesis in vascular disease: uncovering RHAMM and CD44 receptor signaling pathways. , 2007, Matrix biology : journal of the International Society for Matrix Biology.

[50]  D. Schmaljohann Thermo- and pH-responsive polymers in drug delivery. , 2006, Advanced drug delivery reviews.

[51]  K. J. Grande-Allen,et al.  Review. Hyaluronan: a powerful tissue engineering tool. , 2006, Tissue engineering.

[52]  B. Pogue,et al.  Synergism of epidermal growth factor receptor-targeted immunotherapy with photodynamic treatment of ovarian cancer in vivo. , 2005, Journal of the National Cancer Institute.

[53]  Robert Stern,et al.  Hyaluronan catabolism: a new metabolic pathway. , 2004, European journal of cell biology.

[54]  D. Marciani Vaccine adjuvants: role and mechanisms of action in vaccine immunogenicity. , 2003, Drug discovery today.

[55]  G. Freeman,et al.  Regulation of PD‐1, PD‐L1, and PD‐L2 expression during normal and autoimmune responses , 2003, European journal of immunology.

[56]  S. Ghatak,et al.  Regulation of Multidrug Resistance in Cancer Cells by Hyaluronan* , 2003, Journal of Biological Chemistry.

[57]  Ivan Stamenkovic,et al.  Extracellular matrix remodelling: the role of matrix metalloproteinases , 2003, The Journal of pathology.

[58]  V. Hascall,et al.  Hyaluronan and tumor growth. , 2002, The American journal of pathology.

[59]  Hong Liu,et al.  Effect of different components of laser immunotherapy in treatment of metastatic tumors in rats. , 2002, Cancer research.

[60]  M. Korbelik,et al.  Cancer treatment by photodynamic therapy combined with adoptive immunotherapy using genetically altered natural killer cell line , 2001, International journal of cancer.

[61]  J. Fraser,et al.  Hyaluronan: its nature, distribution, functions and turnover , 1997, Journal of internal medicine.

[62]  N. Diferrante Turbidimetric measurement of acid mucopolysaccharides and hyaluronidase activity. , 1956 .