Effects of immunogenic cell death-inducing chemotherapeutics on the immune cell activation and tertiary lymphoid structure formation in melanoma

Efficient chemo-immunotherapy leveraging minimalist electrostatic complex nanoparticle as "in situ" vaccine integrated tumor ICD and immunoagonist

INTRODUCTION

Immunotherapy has unprecedentedly opened up a series of neoteric tactics for cancer treatment. As a burgeoning approach, chemo-immunotherapy has innovatively expanded the accomplishments of conventional chemotherapeutic agents for cancer governing.

OBJECTIVES

An efficacious chemo-immunotherapy leveraging minimalist electrostatic complex nanoparticle (NP) integrated tumor immunogenic cell death (ICD) and immunoagonist was developed as a watertight "in situ" vaccine for cancer therapy through convenient intratumoral administration with minimized systemic toxicity.

METHODS

Chemical-modified pH-sensitive cis-aconityl-doxorubicin (CAD) and immunoadjuvant unmethylated cytosine-phosphate-guanine (CpG) were co-packaged by polycationic polyethylenimine (PEI) though electrostatic-interaction to construct PEI/CpG/CAD NP. By intratumoral injection, this positively charged NP could be detained at tumor site and endocytosed by tumor cells effortlessly. Then, doxorubicin was released through cis-aconityl cleavage induced by endosomal-acidity and further triggered tumor ICD, the moribund tumor cells could release damage-associated molecular patterns (DAMPs) to recruit dendritic cells (DCs). Meanwhile, the entire tumor debris derived into diversified antigens and cooperated with immunostimulatory CpG to excite DC maturation and activated comprehensive antitumor immunity.

RESULTS

Prominent tumor suppression was achieved in aggressive mouse melanoma tumor model, which verified the feasibility and effectiveness of this minimalist CAD/CpG-codelivered NP.

CONCLUSION

This study has provided a convenient and promising paradigm for potent cancer chemo-immunotherapy.

From heterogeneity to prognosis: understanding the complexity of tertiary lymphoid structures in tumors

Tertiary lymphoid structures (TLSs) are aberrant lymphoid tissues found in persistent inflammatory settings, including malignancies, autoimmune disorders, and transplanted organs. The organization and architecture of TLS closely resemble that of secondary lymphoid organs (SLOs). The formation of TLS is an ongoing process, with varying structural features observed at different stages of maturation. The tumor microenvironment (TME) is a multifaceted milieu comprising cells, molecules, and extracellular matrix components in close proximity to the neoplasm. TLS within the TME have the capacity to actively elicit anti-tumor immune responses. TLSs exhibit tumor-specific and individual-specific characteristics, leading to varying immune responses towards tumor immunity based on their distinct cellular components, maturity levels, and spatial distribution. Cell interaction is the foundational elements of tumor immunity. Despite differences in the cellular composition of TLS, B cells and T cells are the main components of tumor-associated TLS。Recent research has highlighted the significance of diverse subtypes of B cells and T cells within TLSs in influencing the therapeutic outcomes and prognostic indicators of individual tumors. This review elucidates the diversity of TLS in terms of cellular composition, developmental stage, anatomical location, and the influence of cytokines on their initiation and progression. Furthermore, the article examines the involvement of B and T cells within TLS and the significance of TLS in relation to tumor prognosis.

Tertiary Lymphoid Structures and Immunotherapy: Challenges and Opportunities

Tertiary lymphoid structures (TLS) are accumulations of lymphoid cells that arise in ectopic sites through the process of lymphoid neogenesis in chronic inflammation in autoimmunity, microbial infections, organ rejection, aging, and cancer. Their cellular composition and function and regulation via members of the lymphotoxin (LT)/tumor necrosis factor (TNF) family resemble that of secondary lymphoid organs (SLOs). Tumor-associated (TA)-TLS can be associated with favorable clinical outcomes. Immunotherapy in the form of immune checkpoint inhibitors (ICI) has contributed to tremendous advances in cancer therapy. However, ICI are effective in only some tumors, can give rise to resistance, and can precipitate immune-related adverse events (irAEs), many of which appear to have hallmarks of autoimmunity and can resemble TLS. TA-TLS correlate with a positive response to immunotherapy, but they can also be associated with susceptibility to irAEs, suggesting that TA-TLS in combination with ICI could lead to uncontrolled autoimmunity. The tumor environment can be manipulated to ensure that, not only the number of TLS, but also their cellular composition and appropriate function allow for judicious combinations of TLS and immunotherapy that can synergize and contribute to better outcomes with a minimum of destructive irAEs. Strategies include directed delivery of lymphoneogenic cytokines and chemokines or vascular growth factors directly, via transgenes or via adenovirus vectors.

Tertiary lymphoid structures in cancer: maturation and induction

Tertiary lymphoid structure (TLS) is an ectopic lymphocyte aggregate formed in peripheral non-lymphoid tissues, including inflamed or cancerous tissue. Tumor-associated TLS serves as a prominent center of antigen presentation and adaptive immune activation within the periphery, which has exhibited positive prognostic value in various cancers. In recent years, the concept of maturity regarding TLS has been proposed and mature TLS, characterized by well-developed germinal centers, exhibits a more potent tumor-suppressive capacity with stronger significance. Meanwhile, more and more evidence showed that TLS can be induced by therapeutic interventions during cancer treatments. Thus, the evaluation of TLS maturity and the therapeutic interventions that induce its formation are critical issues in current TLS research. In this review, we aim to provide a comprehensive summary of the existing classifications for TLS maturity and therapeutic strategies capable of inducing its formation in tumors.