A Transformable Supramolecular Bispecific Cell Engager for Augmenting Natural Killer and T Cell-Based Cancer Immunotherapy

In situ peptide assembly for cell membrane rewiring in tumor therapy

Peptide assembly on the cell membrane is capable of endowing cells with novel biological properties that are distinct from their original states, thereby playing a pivotal role in the regulation of diverse cellular biological events. In practical biomedical scenarios, in order to make peptide assembly more precisely meet the requirements of cells at different physiological stages and conditions to achieve desired effects of cell function regulation, it becomes particularly crucial to conduct precise in situ spatiotemporal control of peptide assembly on the cell membrane, thus attracting great attentions. Particularly for tumor treatment, this artificially manipulated cell surface engineering can achieve excellent anti-tumor effects by altering the cell membrane structure, influencing receptor clustering or interfering with relevant signal pathways. Of note, membrane-anchoring peptides play a key role in these processes. In this review, we focus on three main types of membrane-anchoring peptides, elaborating in detail on how their assembly regulation mechanisms influence the cell membrane remodeling effect, and further exert therapeutic effects on tumors. On this basis, we further introduce a variety of tumor treatment strategies combined with in situ peptide assembly on the cell membrane, and discuss the current opportunities and challenges in this field, aiming to present the overall research panorama and trend of in situ peptide self-assembly on the cell membrane for efficient tumor treatment.

Provoking Lysosome Disruption via In Situ Engineered Double-Network Assemblies for Targeted Cancer Cell Death

Increasing evidence has demonstrated the critical role of lysosomes in tumor progression, as well as their involvement in drug resistance during cancer treatment. However, the exploitation of lysosome-targeting agents to inhibit malignant cell growth is still in high demand. Herein, we report an alkaline phosphatase (ALP)-responsive peptide-based precursor (C1) that selectively induced lysosome dysfunction in uveal melanoma cells via noncontact light manipulation. We demonstrated that C1 was dephosphorylated upon close contact with ALP-upregulated tumor cells, endocytosed, and accumulated in lysosomes. Further light irradiation facilitated the generation of two self-sorting components that self-assembled to form nanofibrils and nanorods, respectively. Mesoscale interactions between these two nanostructures triggered the formation of robust double-network assemblies within lysosomes, resulting in lysosomal membrane permeabilization and tumor cell death. By strategically utilizing ALP activity, light responsiveness, and lysosomal acidity in the design of a self-assembling precursor, we have developed double-network assemblies capable of selectively disrupting lysosomal membrane integrity and effectively inhibiting tumor cells. These findings provide valuable insights for the advancement of lysosome-targeting therapeutic agents.

Whole-Component Antigen Nanovaccines Combined With aTIGIT for Enhanced Innate and Adaptive Anti-tumor Immunity

Using entire tumor cells or tissues that display both common and patient-specific antigens can potentially trigger a comprehensive and long-lasting anti-tumor immune response. However, the limited immunogenicity, low uptake efficiency, and susceptibility to degradation of whole-component antigens present significant challenges. In this study, we employed tumor lysates (TLs) as whole-component antigens, in conjunction with MgAl-layered double hydroxide (MA) as nanoadjuvants and Mn2+ as immunostimulants, to create personalized MMAT (Mn2+-MA-TLs) nanovaccines. After subcutaneous injection of MMAT nanovaccines, the high local concentrations of TLs and Mn2+ facilitated the recruitment and activation of antigen-presenting cells (APCs), thereby inducing a robust adaptive immune response. Remarkably, MMAT nanovaccines enabled lysosomal escape, enhanced antigen cross-presentation, and activated the cyclic GMP-AMP synthase (cGAS)-stimulator of interferon genes (STING) pathway in APCs. Furthermore, MMAT nanovaccines, when combined with the anti-TIGIT monoclonal antibody (aTIGIT), an immune checkpoint inhibitor, not only stimulated T-cell-based adaptive anti-tumor immune responses but also activated the NK-cell-based innate anti-tumor immunity, effectively suppressing tumor growth, recurrence, and metastasis. Thus, the ternary MMAT nanovaccines developed here introduced a pioneered paradigm for the rapid preparation of whole-component tumor antigens with nanoadjuvants and immunostimulants into nanovaccines, offering new prospects for clinical immunotherapies.

Synergistic in vivo anticancer effects of 1,7-heptanediol and doxorubicin co-loadedliposomes in highly aggressive breast cancer

Breast cancer holds the highest incidence rate among women. Doxorubicin (DOX) is a potent frontline drug for the treatment of breast cancer. The anticancer mechanisms of DOX include inducing immunogenic cell death in tumor cells, causing damage to tumor DNA, and generating free radicals. However, its pharmacological efficacy and wide use are restricted by its substantial dose-dependent side effects. We have recently revealed that 1,7-Heptanediol (1,7-Hept) severely impairs the bioenergetics and metabolism of aggressive human cancer cells. In the present work, we prepared liposomes co-loaded with DOX and 1,7-Hept (DOX/1,7-Hept-lipo) and assessed their potential synergistic anti-tumor effects. In vitro studies demonstrated that 4T1 cells (the mouse breast cancer cell) exhibited higher sensitivity to 1,7-Hept and DOX/1,7-Hept-lipo could induce ICD of 4T1 cells. Cell viability was markedly reduced when 4T1 cells were treated with a combination of DOX and 1,7-Hept. In a mouse breast cancer model, the DOX/1,7-Hept-lipo exhibited superior anti-tumor efficacy compared to liposomes loaded with individual drugs, resulting in almost total elimination of the tumors at lower doses of DOX with reduced systemic toxicity. Notably, the number of immune cells significantly increased in the tumor microenvironment, and macrophages were more transformed into the anti-tumor M1 phenotype. Our findings suggest strong synergistic anti-tumor effects of DOX and 1,7-Hept, enhancing the efficacy of tumor immunotherapy and mitigating the toxic side effects of DOX.

Peptide Designs for Cell-Interfacing Assemblies

Constructing synthetic materials to interact with cells offers significant promise for understanding natural cellular processes and manipulating cell behaviors beyond nature's capabilities. Peptide assemblies are particular promising in this regard, as they have demonstrated efficacy in promoting cell differentiation, repair, and regeneration as supportive scaffolds. However, distinct gaps persist between natural and synthetic assembly systems in various aspects. This Concept review explores representative studies focusing on developing chemical strategies to design peptide assemblies with precise control over displayed molecules, adjustable molecular dynamics to modulate cell behaviors, and responsiveness to biological stimuli. This paper would inspire more fundamental studies on molecular assemblies and foster inter-disciplinary interests in material applications, advancing the interplay between natural cells and synthetic materials.

Biomimetic Nanomaterials Based on Peptide In Situ Self-Assembly for Immunotherapy Applications

Cancer remains the leading cause of patient death worldwide and its incidence continues to rise. Immunotherapy is rapidly developing due to its significant differences in the mechanism of action from conventional radiotherapy and targeted antitumor drugs. In the past decades, many biomaterials have been designed and prepared to construct therapeutic platforms that modulate the immune system against cancer. Immunotherapeutic platforms utilizing biomaterials can markedly enhance therapeutic efficacy by optimizing the delivery of therapeutic agents, minimizing drug loss during circulation, and amplifying immunomodulatory effects. The intricate physiological barriers of tumors, coupled with adverse immune environments such as inadequate infiltration, off-target effects, and immunosuppression, have emerged as significant obstacles impeding the effectiveness of oncology drug therapy. However, most of the current studies are devoted to the development of complex immunomodulators that exert immunomodulatory functions by loading drugs or adjuvants, ignoring the complex physiological barriers and adverse immune environments of tumors. Compared with conventional biomaterials, biomimetic nanomaterials based on peptide in situ self-assembly with excellent functional characteristics of biocompatibility, biodegradability, and bioactivity have emerged as a novel and effective tool for cancer immunotherapy. This article presents a comprehensive review of the latest research findings on biomimetic nanomaterials based on peptide in situ self-assembly in tumor immunotherapy. Initially, we categorize the structural types of biomimetic peptide nanomaterials and elucidate their intrinsic driving forces. Subsequently, we delve into the in situ self-assembly strategies of these peptide biomimetic nanomaterials, highlighting their advantages in immunotherapy. Furthermore, we detail the applications of these biomimetic nanomaterials in antigen presentation and modulation of the immune microenvironment. In conclusion, we encapsulate the challenges and prospective developments of biomimetic nanomaterials based on peptide in situ self-assembly for clinical translation in immunotherapy.

Intrinsic PD-L1 Degradation Induced by a Novel Self-Assembling Hexapeptide for Enhanced Cancer Immunotherapy

Programmed death-ligand 1 (PD-L1) is a critical immune checkpoint protein that facilitates tumor immune evasion. While antibody-based PD-1/PD-L1 inhibitors have shown promise, their limitations necessitate the development of alternative therapeutic strategies. This work addresses these challenges by developing a hexapeptide, KFM (Lys-Phe-Met-Phe-Met-Lys), capable of both directly downregulating PD-L1 and self-assembling into a ROS-responsive supramolecular hydrogel. This dual functionality allows Gel KFM to function as a localized drug delivery system and a PD-L1 inhibitor. Loading the hydrogel with mitoxantrone (MTX) and metformin (MET) further enhances the therapeutic effect by combining chemotherapy with PD-L1 downregulation. In vitro and in vivo studies demonstrate significant tumor growth inhibition, increased CD8+ T cell infiltration, and reduced intratumoral PD-L1 expression following peritumoral administration. Mechanistically, KFM promotes PD-L1 degradation via a ubiquitin-dependent pathway. This "carrier-free" delivery system expands the role of supramolecular hydrogels beyond passive carriers to active immunotherapeutic agents, offering a promising new strategy for cancer therapy.

Peptides as Versatile Regulators in Cancer Immunotherapy: Recent Advances, Challenges, and Future Prospects

The emergence of effective immunotherapies has revolutionized therapies for many types of cancer. However, current immunotherapy has limited efficacy in certain patient populations and displays therapeutic resistance after a period of treatment. To address these challenges, a growing number of immunotherapy drugs have been investigated in clinical and preclinical applications. The diverse functionality of peptides has made them attractive as a therapeutic modality, and the global market for peptide-based therapeutics is witnessing significant growth. Peptides can act as immunotherapeutic agents for the treatment of many malignant cancers. However, a systematic understanding of the interactions between different peptides and the host's immune system remains unclear. This review describes in detail the roles of peptides in regulating the function of the immune system for cancer immunotherapy. Initially, we systematically elaborate on the relevant mechanisms of cancer immunotherapy. Subsequently, we categorize peptide-based nanomaterials into the following three categories: peptide-based vaccines, anti-cancer peptides, and peptide-based delivery systems. We carefully analyzed the roles of these peptides in overcoming the current barriers in immunotherapy, including multiple strategies to enhance the immunogenicity of peptide vaccines, the synergistic effect of anti-cancer peptides in combination with other immune agents, and peptide assemblies functioning as immune stimulators or vehicles to deliver immune agents. Furthermore, we introduce the current status of peptide-based immunotherapy in clinical applications and discuss the weaknesses and future prospects of peptide-based materials for cancer immunotherapy. Overall, this review aims to enhance comprehension of the potential applications of peptide-based materials in cancer immunotherapy and lay the groundwork for future research and clinical applications.

On-Demand Elongation of Peptide Nanofibrils at Cellular Interfaces to Modulate Cell-Cell Interactions

Natural cells can achieve specific cell-cell interactions by enriching nonspecific binding molecules on demand at intercellular contact faces, a pathway currently beyond synthetic capabilities. We are inspired to construct responsive peptide fibrils on cell surfaces, which elongate upon encountering target cells while maintaining a short length when contacting competing cells, as directed by a strand-displacement reaction arranged on target cell surfaces. With the display of ligands that bind to both target and competing cells, the contact-induced, region-selective fibril elongation selectively promotes host-target cell interactions via the accumulation of nonspecific ligands between matched cells. This approach is effective in guiding natural killer cells, the broad-spectrum effector lymphocytes, to eliminate specific cancer cells. In contrast to conventional methods relying on target cell-specific binding molecules for the desired cellular interactions, this dynamic scaffold-based approach would broaden the scope of cell combinations for manipulation and enhance the adjustability of cell behaviors for future applications.

Alkaline Phosphatase-Instructed Peptide Assemblies for Imaging and Therapeutic Applications

Self-assembly, a powerful strategy for constructing highly stable and well-ordered supramolecular structures, widely exists in nature and in living systems. Peptides are frequently used as building blocks in the self-assembly process due to their advantageous characteristics, such as ease of synthesis, tunable mechanical stability, good biosafety, and biodegradability. Among the initiators for peptide self-assembly, enzymes are excellent candidates for guiding this process under mild reaction conditions. As a crucial and commonly used biomarker, alkaline phosphatase (ALP) cleaves phosphate groups, triggering a hydrophilicity-to-hydrophobicity transformation that induces peptide self-assembly. In recent years, ALP-instructed peptide self-assembly has made breakthroughs in biological imaging and therapy, inspiring the development of self-assembly biomaterials for diagnosis and therapeutics. In this review, we highlight the most recent advancements in ALP-instructed peptide assemblies and provide perspectives on their potential impact. Finally, we briefly discuss the ongoing challenges for future research in this field.

Recent developments in immunotherapy for gastrointestinal tract cancers

The past few decades have witnessed the rise of immunotherapy for Gastrointestinal (GI) tract cancers. The role of immune checkpoint inhibitors (ICIs), particularly programmed death protein 1 (PD-1) and PD ligand-1 antibodies, has become increasingly pivotal in the treatment of advanced and perioperative GI tract cancers. Currently, anti-PD-1 plus chemotherapy is considered as first-line regimen for unselected advanced gastric/gastroesophageal junction adenocarcinoma (G/GEJC), mismatch repair deficient (dMMR)/microsatellite instability-high (MSI-H) colorectal cancer (CRC), and advanced esophageal cancer (EC). In addition, the encouraging performance of claudin18.2-redirected chimeric antigen receptor T-cell (CAR-T) therapy in later-line GI tract cancers brings new hope for cell therapy in solid tumour treatment. Nevertheless, immunotherapy for GI tumour remains yet precise, and researchers are dedicated to further maximising and optimising the efficacy. This review summarises the important research, latest progress, and future directions of immunotherapy for GI tract cancers including EC, G/GEJC, and CRC.

Transformable Supramolecular Self-Assembled Peptides for Cascade Self-Enhanced Ferroptosis Primed Cancer Immunotherapy

Immunotherapy has received widespread attention for its effective and long-term tumor-eliminating ability. However, for immunogenic "cold" tumors, such as prostate cancer (PCa), the low immunogenicity of the tumor itself is a serious obstacle to efficacy. Here, this work reports a strategy to enhance PCa immunogenicity by triggering cascade self-enhanced ferroptosis in tumor cells, turning the tumor from "cold" to "hot". This work develops a transformable self-assembled peptide TEP-FFG-CRApY with alkaline phosphatase (ALP) responsiveness and glutathione peroxidase 4 (GPX4) protein targeting. TEP-FFG-CRApY self-assembles into nanoparticles under aqueous conditions and transforms into nanofibers in response to ALP during endosome/lysosome uptake into tumor cells, promoting lysosomal membrane permeabilization (LMP). On the one hand, the released TEP-FFG-CRAY nanofibers target GPX4 and selectively degrade the GPX4 protein under the light irradiation, inducing ferroptosis; on the other hand, the large amount of leaked Fe2+ further cascade to amplify the ferroptosis through the Fenton reaction. TEP-FFG-CRApY-induced immunogenic ferroptosis improves tumor cell immunogenicity by promoting the maturation of dendritic cells (DCs) and increasing intratumor T-cell infiltration. More importantly, recovered T cells further enhance ferroptosis by secreting large amounts of interferon-gamma (IFN-γ). This work provides a novel strategy for the molecular design of synergistic molecularly targeted therapy for immunogenic "cold" tumors.

Cell Membrane as A Promising Therapeutic Target: From Materials Design to Biomedical Applications

The cell membrane is a crucial component of cells, protecting their integrity and stability while facilitating signal transduction and information exchange. Therefore, disrupting its structure or impairing its functions can potentially cause irreversible cell damage. Presently, the tumor cell membrane is recognized as a promising therapeutic target for various treatment methods. Given the extensive research focused on cell membranes, it is both necessary and timely to discuss these developments, from materials design to specific biomedical applications. This review covers treatments based on functional materials targeting the cell membrane, ranging from well-known membrane-anchoring photodynamic therapy to recent lysosome-targeting chimaeras for protein degradation. The diverse therapeutic mechanisms are introduced in the following sections: membrane-anchoring phototherapy, self-assembly on the membrane, in situ biosynthesis on the membrane, and degradation of cell membrane proteins by chimeras. In each section, we outline the conceptual design or general structure derived from numerous studies, emphasizing representative examples to understand advancements and draw inspiration. Finally, we discuss some challenges and future directions in membrane-targeted therapy from our perspective. This review aims to engage multidisciplinary readers and encourage researchers in related fields to advance the fundamental theories and practical applications of membrane-targeting therapeutic agents.

Blood-Brain Barrier Penetrating Nanovehicles for Interfering with Mitochondrial Electron Flow in Glioblastoma

Glioblastoma multiforme (GBM) is the most aggressive and lethal form of human brain tumors. Dismantling the suppressed immune microenvironment is an effective therapeutic strategy against GBM; however, GBM does not respond to exogenous immunotherapeutic agents due to low immunogenicity. Manipulating the mitochondrial electron transport chain (ETC) elevates the immunogenicity of GBM, rendering previously immune-evasive tumors highly susceptible to immune surveillance, thereby enhancing tumor immune responsiveness and subsequently activating both innate and adaptive immunity. Here, we report a nanomedicine-based immunotherapeutic approach that targets the mitochondria in GBM cells by utilizing a Trojan-inspired nanovector (ABBPN) that can cross the blood-brain barrier. We propose that the synthetic photosensitizer IrPS can alter mitochondrial electron flow and concurrently interfere with mitochondrial antioxidative mechanisms by delivering si-OGG1 to GBM cells. Our synthesized ABBPN coloaded with IrPS and si-OGG1 (ISA) disrupts mitochondrial electron flow, which inhibits ATP production and induces mitochondrial DNA oxidation, thereby recruiting immune cells and endogenously activating intracranial antitumor immune responses. The results of our study indicate that strategies targeting the mitochondrial ETC have the potential to treat tumors with limited immunogenicity.