Schwann cell-derived exosomes promote lung cancer progression via miRNA-21-5p

Tumor-associated Schwann cells as new therapeutic target in non-neurological cancers

Cancer neuroscience, a burgeoning field, investigates the complex interactions between cancer and the nervous system, emphasizing how cancer cells exploit neuronal components for growth and metastasis. Tumor-associated Schwann cells (TASc) have emerged as crucial players in the progression of highly innervated cancers, highlighting the intricate relationship between the tumor microenvironment (TME) and the nervous system. This review concludes how TASc, as the most abundant glial cell in the peripheral nervous system, contribute to tumor growth, metastasis, and the remodeling of the TME. Acting similarly to reactive astrocytes in the central nervous system, TASc are implicated in driving perineural invasion (PNI), a distinctive cancer progression pathway facilitating tumor infiltration and metastasis. These TASc not only contribute indirectly to pain but also promote tumor recurrence and poor prognosis. Intrinsic to their role, TASc exhibit unique gene expression profiles and phenotypic transformations, shifting from myelinating to non-myelinating states, thereby actively participating in metastasis and the remodeling of the tumor microenvironment. Targeting TASc represents a novel and promising therapeutic strategy in non-neurological cancers, offering new avenues for clinical intervention.

Extracellular Vesicles: Hermes between cancers and lymph nodes

Cancer is one of the main causes of death and a major obstacle to increasing life expectancy in all countries of the world. Lymph node metastasis (LNM) of in cancer patients indicates poor prognosis and it is an important indication to determine the therapeutic regime. Therefore, more attention should be given to the molecular mechanics of tumor lymphangiogenesis and LNM. Extracellular vesicles (EVs) are nanoscale cargo-bearing membrane vesicles that can serve as key mediators for the intercellular communication. Like Hermes, the messenger of the Greek gods, EVs can be secreted by tumor cells to regulate the LNM process. Many evidence has proved the clinical correlation between EVs and LNM in various cancer types. EVs plays an active role in the process of metastasis by expressing its connotative molecules, including proteins, nucleic acids, and metabolites. However, the clear role of EVs in the process of cancer LNM has not been thoroughly studied yet. In this review, we will summarize the clinical and mechanical findings of EVs regulating role on cancer LNM, and discuss the advanced modification of the research proposal. We propose the "PUMP" principle of EVs in LNM, including Preparation, Unleash, Migration, and Planting.

Intersection between lung cancer and neuroscience: Opportunities and challenges

Lung cancer, which has the highest morbidity and mortality rates worldwide, involves intricate interactions with the nervous system. Research indicates that the nervous system not only plays a role in the origin of lung cancer, but also engages in complex interactions with cancer cells through neurons, neurotransmitters, and various neuroactive molecules during tumor proliferation, invasion, and metastasis, especially in brain metastases. Cancer and its therapies can remodel the nervous system. Despite advancements in immunotherapy and targeted therapies in recent years, drug resistance of lung cancer cells after treatment limits improvements in patient survival and prognosis. The emergence of neuroscience has created new opportunities for the treatment of lung cancer. However, it also presents challenges. This review emphasizes that a deeper understanding of the interactions between the nervous system and lung cancer, along with the identification of new therapeutic targets, may lead to significant advancements or even a revolution in treatment strategies for patients with lung cancer.

Interplay Between Schwann Cells and Peripheral Cancers: Mechanisms and Therapeutic Targets in Cancer Progression

Cancer, a leading global health concern, is characterized by uncontrolled proliferation of cells, high invasion into surrounding tissues, and eventual metastasis to distant organs. The complexity of cancer is further amplified by diverse cellular components within the tumor microenvironment (TME), encompassing both cancerous and non-cancerous cells that fuel tumorigenesis and progression. Schwann cells (SCs), the main glial cells of the peripheral nervous system, have emerged as crucial components within the TME in cancer development. Here, we summarize the multifaceted roles of SCs in tumor growth, epithelial-mesenchymal transition, perineural invasion, and chemotherapy resistance. This review focuses on the effects of SCs on eight distinct peripheral cancer types, particularly pancreatic, lung, and colorectal cancers, along with cancer-related pain, one of the most common symptoms that affect quality of life and prognosis in cancer patients. Furthermore, we emphasize the therapeutic potential of SCs by delving into advanced technologies and clinical strategies related to SCs, which make us advocate for further research to elucidate the events and molecular mechanisms underlying the SC-cancer relationship. Translating these insights into clinical applications may offer new hope for improved cancer management and patient outcomes.

Benign non-immune cells in tumor microenvironment

The tumor microenvironment (TME) is a highly complex and continuous evolving ecosystem, consisting of a diverse array of cellular and non-cellular components. Among these, benign non-immune cells, including cancer-associated fibroblasts (CAFs), adipocytes, endothelial cells (ECs), pericytes (PCs), Schwann cells (SCs) and others, are crucial factors for tumor development. Benign non-immune cells within the TME interact with both tumor cells and immune cells. These interactions contribute to tumor progression through both direct contact and indirect communication. Numerous studies have highlighted the role that benign non-immune cells exert on tumor progression and potential tumor-promoting mechanisms via multiple signaling pathways and factors. However, these benign non-immune cells may play different roles across cancer types. Therefore, it is important to understand the potential roles of benign non-immune cells within the TME based on tumor heterogeneity. A deep understanding allows us to develop novel cancer therapies by targeting these cells. In this review, we will introduce several types of benign non-immune cells that exert on different cancer types according to tumor heterogeneity and their roles in the TME.

Revolutionizing lung cancer treatment: harnessing exosomes as early diagnostic biomarkers, therapeutics and nano-delivery platforms

Lung cancer, known for its high morbidity and mortality rates, remains one of the most critical health challenges globally. Conventional treatment options, such as chemotherapy and surgery, are often limited by high costs, significant side effects, and often yield a poor prognosis. Notably, recent research has shed light on the potential therapeutic roles of exosomes, which essentially influence lung cancer's development, diagnosis, treatment, and prognosis. Exosomes have been revealed for their exceptional properties, including natural intercellular communication, excellent biocompatibility, minimal toxicity, prolonged blood circulation ability, and biodegradability. These unique characteristics position exosomes as highly effective drug delivery systems, nanotherapeutics, and potential diagnostic and prognostic biomarkers in lung cancer. This review provides a comprehensive review of the physiological and pathological roles of exosomes in lung cancer, emphasizing their potential as innovative diagnostic biomarkers, therapeutics, and delivery platforms. By harnessing their unique properties, exosomes are poised to revolutionize the diagnosis and treatment of lung cancer, offering a promising avenue for more personalized and effective therapies.

CREB1/CRTC2 regulated tubular epithelial-derived exosomal miR-93-3p promotes kidney injury induced by calcium oxalate via activating M1 polarization and macrophage extracellular trap formation

BACKGROUND

Calcium oxalate (CaOx) crystals are known to cause renal injury and trigger inflammatory responses. However, the role of exosome-mediated epithelial-macrophage communication in CaOx-induced kidney injury remains unclear.

METHODS

To identify key molecules, miRNA sequencing was conducted on exosomes derived from CaOx-treated (CaOx-exo) and control (Ctrl-exo) epithelial cells, identifying miR-93-3p as significantly upregulated. A combination of dual-luciferase reporter assays, Western blot, RT-qPCR, immunofluorescence staining, flow cytometry, electrophoretic mobility shift assay (EMSA), and chromatin immunoprecipitation-qPCR (CHIP-qPCR) was used to explore the regulation of miR-93-3p by CREB1/CRTC2 and its downstream effects on NFAT5/Akt1/NIK/NF-κB2 signaling in macrophages. The functional roles of NFAT5 in macrophage polarization and macrophage extracellular traps (METs) formation were further evaluated both in vitro and in vivo.

RESULTS

Epithelial exosomes stimulated by CaOx crystals were found to promote kidney injury via macrophage polarization and METs formation. Treatment with NIK SMI1, a NIK inhibitor, or CI-amidine, a METs inhibitor, mitigated crystal deposition and CaOx-induced kidney damage. Overexpression of NFAT5 in a CaOx-induced mouse model reduced renal injury and crystal deposition, downregulated NIK and NF-κB2 levels, and decreased the number of M1-polarized macrophages. Mechanistic studies revealed that miR-93-3p directly targets NFAT5 mRNA, as confirmed by dual-luciferase assays, qRT-PCR, and Western blot. Additionally, we demonstrated that CREB1/CRTC2 acts as a transcriptional activator of miR-93-3p. Inhibition of miR-93-3p partially reversed NIK/NF-κB2 activation and alleviated kidney injury.

CONCLUSIONS

CaOx crystals exacerbate renal interstitial injury by promoting M1 macrophage polarization and METs formation through the CREB1/CRTC2-exosomal miR-93-3p-NIK/NF-κB2 signaling pathway. Targeting this pathway may provide therapeutic avenues for mitigating crystal deposition-induced kidney damage.

Natural and Bioengineered Extracellular Vesicles in Diagnosis, Monitoring and Treatment of Cancer

Extracellular vesicles (EVs) are cell derived nanovesicles which are implicated in both physiological and pathological intercellular communication, including the initiation, progression, and metastasis of cancer. The exchange of biomolecules between stromal cells and cancer cells via EVs can provide a window to monitor cancer development in real time for better diagnostic and interventional strategies. In addition, the process of secretion and internalization of EVs by stromal and cancer cells in the tumor microenvironment (TME) can be exploited for delivering therapeutics. EVs have the potential to provide a targeted, biocompatible, and efficient delivery platform for the treatment of cancer and other diseases. Natural as well as engineered EVs as nanomedicine have immense potential for disease intervention. Here, we provide an overview of current knowledge of EVs' function in cancer progression, diagnostic and therapeutic applications for EVs in the cancer setting, as well as current EV engineering strategies.

Tumour-derived exosomal miR-205 promotes ovarian cancer cell progression through M2 macrophage polarization via the PI3K/Akt/mTOR pathway

BACKGROUND

Tumour-associated macrophages (TAMs) are the most abundant immune cells in the tumour environment and are considered similar to M2 macrophages, which facilitate cancer progression. Exosomes, as important mediators of the cross-talk between tumour cells and tumour-associated macrophages, can facilitate the development and metastasis of ovarian cancer by mediating M2 macrophage polarization. However, the exact mechanisms underlying the communication between ovarian cancer (OC) cells and tumour-associated macrophages during OC progression remain unclear.

RESULTS

Here, we demonstrated that high expression of miR-205 was associated with M2 macrophage infiltration, which affected the prognosis of OC patients. Importantly, tumour-derived miR-205 could be transported from OC cells to macrophages via exosomes and promote cancer cell invasion and metastasis by inducing M2-like macrophage polarization. Animal experiments further confirmed that exosomal miR-205-induced M2 macrophages accelerated OC progression in vivo. Mechanistically, miR-205 downregulated PTEN, activating the PI3K/AKT/mTOR signalling pathway, which is critical for M2 polarization.

CONCLUSIONS

These results reveal that exosomal miR-205 plays a pivotal role in macrophage polarization within the OC microenvironment, highlighting its potential as a therapeutic target for OC treatment. This study not only enhances our understanding of the interactions between tumour and immune cells but also opens new avenues for targeted therapies against exosomal miR-205 in ovarian cancer.

The Emerging Role of Schwann Cells in the Tumor Immune Microenvironment and Its Potential Clinical Application

As the primary glial cells in the peripheral nervous system (PNS), Schwann cells (SCs) have been proven to influence the behavior of cancer cells profoundly and are involved in cancer progression through extensive interactions with cancer cells and other stromal cells. Indeed, the tumor microenvironment (TME) is a critical factor that can significantly limit the efficacy of immunotherapeutic approaches. The TME promotes tumor progression in part by reshaping an immunosuppressive state. The immunosuppressive TME is the result of the crosstalk between the tumor cells and the different immune cell subsets, including macrophages, natural killer (NK) cells, dendritic cells (DCs), lymphocytes, myeloid-derived suppressor cells (MDSCs), etc. They are closely related to the anti-tumor immune status and the clinical prognosis of cancer patients. Increasing research demonstrates that SCs influence these immune cells and reshape the formation of the immunosuppressive TME via the secretion of various cytokines, chemokines, and other effector molecules, eventually facilitating immune evasion and tumor progression. In this review, we summarize the SC reprogramming in TME, the emerging role of SCs in tumor immune microenvironment, and the underlying mechanisms involved. We also discuss the possible therapeutic strategies to selectively target SCs, providing insights and perspectives for future research and clinical studies involving SC-targeted treatment.

Bubble Ticket Trip: Exploring the Mechanism of miRNA Sorting into Exosomes and Maintaining the Stability of Tumor Microenvironment

Exosomes are vesicles ranging from 30 to 100 nanometers in size that show great potential as carriers for therapeutic uses and drug delivery. Enriching a specific set of miRNAs in exosomes emphasizes the existence of particular sorting mechanisms that manage the targeted cargo packaging. The molecular mechanism for miRNA sorting has not been understood. It is crucial to understand the mechanism of exosome encapsulation to develop its therapeutic potential. In this review, we will explore the particular processes through which exosomes naturally encapsulate miRNA, as well as discuss the effect on tumors after encapsulation of miRNAs. We also summarize the effects of targeted drug delivery using genetic engineering and chemical methods to modify exosome-encapsulated miRNA. Finally, gaining insight into how exosome cargo is sorted could be applied in clinical settings for precise drug delivery and to hinder the progression of diseases.

Mind the GAPS: Glia associated with psychological stress

Glial cells are an integral component of the nervous system, performing crucial functions that extend beyond structural support, including modulation of the immune system, tissue repair, and maintaining tissue homeostasis. Recent studies have highlighted the importance of glial cells as key mediators of stress responses across different organs. This review focuses on the roles of glial cells in peripheral tissues in health and their involvement in diseases linked to psychological stress. Populations of glia associated with psychological stress ("GAPS") emerge as a promising target cell population in our basic understanding of stress-associated pathologies, highlighting their role as mediators of the deleterious effects of psychological stress on various health conditions. Ultimately, new insights into the impact of stress on glial cell populations in the periphery may support clinical efforts aimed at improving the psychological state of patients for improved health outcomes.

The intersection of the nervous system and breast cancer

Breast cancer (BC) represents a paradigm of heterogeneity, manifesting as a spectrum of molecular subtypes with divergent clinical trajectories. It is fundamentally characterized by the aberrant proliferation of malignant cells within breast tissue, a process modulated by a myriad of factors that govern its progression. Recent endeavors outline the interplay between BC and the nervous system, illuminate the complex symbiosis between neural structures and neoplastic cells, and elucidate nerve dependence as a cornerstone of BC progression. This includes the neural modulations on immune response, neurovascular formation, and multisystem interactions. Such insights have unveiled the critical impact of neural elements on tumor dynamics and patient prognosis. This revelation beckons a deeper exploration into the neuro-oncological interface, potentially unlocking novel therapeutic vistas. This review endeavors to delineate the intricate mechanisms between the nervous system and BC, aiming to accentuate the implications and therapeutic strategies of this intersection for tumor evolution and the formulation of innovative therapeutic approaches.

Schwann cells in the normal and pathological lung microenvironment

The lungs are a key organ in the respiratory system. They are regulated by a complex network of nerves that control their development, structure, function, and response to various pathological stimuli. Accumulating evidence suggests the involvement of a neural mechanism in different pathophysiological conditions in the lungs and the development and progression of common respiratory diseases. Lung diseases are the chief source of death globally. For instance, lung cancer is the second most commonly diagnosed malignancy, after prostate cancer in men and breast cancer in women, and is the most lethal cancer worldwide. However, although airway nerves are accepted as a mechanistically and therapeutically important feature that demands appropriate emphasizing in the context of many respiratory diseases, significantly less is known about the role of the neuroglial cells in lung physiology and pathophysiology, including lung cancer. New data have uncovered some cellular and molecular mechanisms of how Schwann cells, as fundamental components of the peripheral nervous system, may regulate lung cancer cells' survival, spreading, and invasiveness in vitro and in vivo. Schwann cells control the formation and maintenance of the lung cancer microenvironment and support metastasis formation. It was also reported that the number of lung cancer-associated Schwann cells correlates with patients' survival. Different factors secreted by Schwann cells, including microRNA, are known to sharpen the lung cancer environment by regulating the tumor-neuro-immune axis. Further clinical and experimental studies are required to elucidate the detailed role of Schwann cells in creating and maintaining pulmonary tumor-neuro-immune axis, which will advance our understanding of the pathogenesis of lung cancer and may inform therapeutic hypotheses aiming neoplasms and metastases in the lung.