Pancreatic cancer stem cell-derived exosomal miR-210 mediates macrophage M2 polarization and promotes gemcitabine resistance by targeting FGFRL1

hnRNPA2B1 promotes the production of exosomal miR-103-3p from endothelial progenitor cells to alleviate macrophage M1 polarization in acute respiratory distress syndrome

BACKGROUND

Macrophage polarization plays a crucial role in acute respiratory distress syndrome (ARDS). Recently, mounting evidence has uncovered that endothelial progenitor cells (EPCs) secreted exosomes (EPCs-Exos) exert obvious therapeutic effects on the pathological inflammatory process of ARDS, but its potential mechanism is rarely reported.

METHODS

The primary mouse EPCs and EPCs-Exos were isolated and identified. Absorption of EPCs-Exos by RAW264.7 cells was examined by PKH-26 staining. The polarization of RAW264.7 cells was evaluated by flow cytometry and RT-qPCR analysis. Molecular interactions were verified by dual luciferase assay, RNA pull-down and RNA immunocoprecipitation assays. ARDS mouse model was established, and pathological changes and expressions of related molecules were detected by HE staining, RT-qPCR and western blotting.

RESULTS

EPCs-Exos could be transferred to macrophages, and effectively reversed LPS-induced polarization of macrophages from M2 to M1 phenotype; however, these changes were diminished by activation of TLR4/NF-κB pathway. MiR-103-3p was proved to be enriched in EPC-Exos and could transfer to macrophage and inactivating TLR4/NF-κB pathway via directly binding to TLR4 3'-UTR. Moreover, miR-103-3p overexpression elevated macrophage M2 polarization and repressed M1 polarization in LPS-treated cells by inhibiting TLR4/NF-κB pathway, and knockdown of miR-103-3p in EPC-Exos abolished the regulatory roles of EPC-Exos on macrophage polarization in vitro, and lung inflammatory injury in vivo. HnRNPA2B1 was proved to interact with miR-103-3p and responsible for its exosomal secretion, which repressed pro-inflammatory macrophage polarization.

CONCLUSION

These findings suggested that hnRNPA2B1-mediated exosomal delivery of miR-103-3p from EPCs protected against macrophage inflammation in ARDS by inactivation of TLR4/NF-κB pathway.

A review of the role of tumor-derived exosomes in cancers treatment and progression

Tumor cells (TCs) produce exosomes (EXOs), nanovesicles formed in endosomes. Tumor-derived exosomes (TDEs) are tiny, bubble-shaped structures formed by TCs that include microRNAs (miRNA), proteins, enzymes, and copies of DNA and RNA. Many different kinds of cancer rely on TDEs. For instance, TDEs play a large role in the tumor microenvironment (TME) and promote tumor spread via many pathways. Furthermore, TDEs impact the efficacy of cancer treatments. Additionally, because of their low immunogenicity, high biocompatibility, and low toxicity, TDEs have been extensively used as drug delivery vehicles for cancer immunotherapy. Consequently, future cancer treatments may benefit from focusing on both the therapeutic function and the tumorigenic pathways of TDEs. Consequently, in this work, we have examined the roles of TDEs in cancer development, such as tumor angiogenesis, immune system evasion, and tumor metastasis. Then, we reviewed TDEs used to transport anticancer medicines, including chemotherapeutic medications, therapeutic compounds (including miRNA), and anticancer nanoparticles. We have concluded by outlining the challenges of clinical translation, including carcinogenicity and medication resistance, and by offering some suggestions for addressing these issues.

Exosomes in bridging macrophage-fibroblast polarity and cancer stemness

Exosome roles in cellular cross-talking within tumor microenvironment (TME) is a critical event in tumorigenesis. Type 2 macrophages (M2), cancer-associated fibroblasts (CAFs) and cancer stem cells (CSCs) are the three most important cells in cancer progression and metastasis, and targeting their connectome route can be an effective anti-cancer strategy. Exosomes mediate bidirectional cross-talking between the three cell types in which exosomes secreted from CSCs promote polarization of M2 macrophages and CAFs, and that M2- and CAF-derived exosomes promote cancer stemness through activation of epithelial-mesenchymal transition (EMT)-related signaling including transforming growth factor (TGF)-β, WNT/β-catenin and epidermal growth factor (EGF). CSC-derived exosomal TGF-β is a key driver of CAF and M2 macrophage polarization, with the latter mediated through activation of signal transducer and activator of transcription 3 (STAT3). β-catenin activity also seems to take important role in exosomal cross-talk between CAFs and stemness state of cancer. Incubation of exosomes with inhibitors of signaling inter-connecting CSCs, M2 and CAFs is a key anti-cancer strategy and a promising supplementary to the routine immunotherapeutic approaches in cancer therapy.

Exosomes: their role and therapeutic potential in overcoming drug resistance of gastrointestinal cancers

Gastrointestinal cancers are prevalent malignant neoplasms in clinical medicine. The development of drug resistance in gastrointestinal cancers result in tumor recurrence and metastasis and greatly diminish the efficacy of treatment. Exosomes, as the shuttle of intercellular molecular cargoes in tumor micro-environment, secreted from tumor and stromal cells mediate drug resistance by regulating epithelial-mesenchymal transition, drug efflux, stem-like phenotype and cell metabolism. Meanwhile, exosomes have already received tremendous attention in biomedical study as potential drug resistant biomarkers as well as treatment strategy in gastrointestinal cancers. Primary challenge to implement this potential is the ability to obtain high-grade exosomes efficiently; however, exosomes lack standard protocols for their processing and characterization. Furthermore, this field suffers from insufficient standardized reference materials and workflow for purification, detection and analysis of exosomes with defined biological properties. This review summarize the unique biogenesis, composition and novel detection methods of exosomes and informed the underlying correlation between exosomes and drug resistance of gastrointestinal cancers. Moreover, the clinical applications of exosomes are also summarized, might providing novel therapy for the individual treatment of gastrointestinal cancers.

Role of M2 macrophage-derived exosomes in cancer drug resistance via noncoding RNAs

This review summarizes recent findings on the role of M2 tumor-associated macrophages (TAMs) and their exosome-derived non-coding RNAs (ncRNAs) in cancer cell resistance to therapeutics. M2 TAMs promote angiogenesis, suppress immune responses, and facilitate metastasis, thereby creating a tumor-supporting microenvironment. A range of antitumor drugs, including 5-FU, cisplatin, and gemcitabine, are mediated by M2 exosomes, each with distinct mechanisms of action. M2 exosomes transfer drug resistance capabilities via extracellular vesicles, especially exosomes containing miRNAs, lncRNAs, and circRNAs. These exosome mediate the development of tumor drug resistance by regulating signaling pathways such as PI3K/AKT, MAPK/ERK, Wnt/β-catenin M2 exosomes can regulate cellular responses by delivering bioactive molecules, including proteins, lipids, and ncRNA, which can also modulate cellular reactions to ionizing radiation, ultraviolet light, and chemotherapeutic agents. Targeting M2 TAMs and their exosome-mediated ncRNAs may offer new strategies to overcome drug resistance in cancer.

Predicting Drug-miRNA Associations Combining SDNE with BiGRU

It is well recognized that abnormal miRNA expression can result in drug resistance and pose a challenge to miRNA-based treatments. However, the drug-miRNA associations (DMA) are still incompletely understood. Conventional biological experiments have a high failure rate, lengthy cycle times, and expensive expenditures. Consequently, deep learning-based techniques for predicting DMA have been developed. In this work, we propose a novel method named SDNEDMA for DMA prediction that combines SDNE with BiGRU. The two-channel approach is used to combine the attribute and topological features of miRNAs and drugs. To be more precise, we first model the associations between drugs and miRNAs through the known bipartite network, and then utilize SDNE to obtain the topological features. Meanwhile, BiGRU is employed to acquire miRNA k-mer sequence features and drug ECFP fingerprints. Subsequently, both the topological and attribute features are fused jointly to form final features which is aimed to predict the association score for both them. Multiple features drugs and miRNAs are used at the same time, more information is fused, and the features are more accurate, so the prediction performance is better. The experiments show that SDNEDMA outperforms other state-of-the-art methods, yielding AUC of 0.9641 when we use 5-fold cross-validation on the ncDR dataset. SDNEDMA is additionally employed in a case study, showing how accurate and dependable it is. To sum up, the SDNEDMA has the ability to predict DMA with high accuracy and effectiveness, which is really important for drug development.

Harnessing exosomes for targeted drug delivery systems to combat brain cancer

Brain cancer remains a significant challenge in the field of oncology, primarily because of its aggressive nature and the limited treatment options available. Conventional therapies often fall short in effectively targeting tumor cells, while sparing healthy brain tissue from collateral damage. However, exosomes are now recognized as promising nanocarriers for targeted drug delivery. These naturally occurring extracellular vesicles can cross the blood-brain barrier and selectively interact with cancer cells. Utilizing exosomes as drug delivery vehicles offers a novel approach with significant potential for targeted therapy. By encapsulating therapeutic agents within exosomes, drugs can be specifically targeted to tumor cells, maximizing their impact whilst minimizing damage to healthy brain tissue. Furthermore, exosomes can be modified to display molecules that specifically recognize and bind to cancer cells, further enhancing their precision and efficacy. While exosome-based therapies show potential, scalability, purification, and clinical application challenges remain. The scalability of exosome production, purification, and modification techniques remains a hurdle that must be overcome for clinical translation. Additionally, the intricate interactions between the tumor microenvironment and exosomes necessitate further research to optimize therapeutic outcomes. The review explores applications and future perspectives of exosome-based therapies in advancing targeted brain cancer treatment.

Investigation of the role of GEM in systemic lupus erythematosus through multi-omics joint analysis

Background

Systemic lupus erythematosus (SLE) is a persistent autoimmune disorder marked by dysregulation of the immune system, resulting in extensive tissue inflammation and subsequent damage. Fibroblasts are essential contributors to the pathogenesis of SLE, particularly in driving the progression of tissue fibrosis and inflammation. Recent research has proposed that the GEM gene may regulate fibroblast activity in SLE. However, the precise molecular mechanisms through which GEM modulates fibroblast functions in the context of SLE are yet to be fully elucidated. Gaining insight into these mechanisms is crucial for uncovering potential therapeutic targets aimed at addressing fibrosis and inflammation associated with SLE.

Methods

Single-cell RNA sequencing was integrated with cell-based assays, such as quantitative reverse transcription PCR (qRT-PCR) and functional cellular experiments, to investigate the underlying mechanisms. The regulatory mechanisms of GEM in fibroblasts were analyzed through functional cell assays.

Results

Differential gene expression in fibroblast subpopulations was identified through single-cell RNA sequencing, with GEM emerging as a key gene implicated in these alterations. Trajectory analysis indicated that GEM expression correlated with fibroblast proliferation and migration. Subsequent experiments confirmed that GEM regulates fibroblast viability and influences SLE disease progression through modulation of cell proliferation, migration, and apoptosis.

Conclusions

GEM is highly differentially expressed in fibroblast subpopulations within SLE, and its altered expression impacts fibroblast proliferation and migration. GEM may regulate fibroblast activity and apoptosis, potentially contributing to the progression of SLE.

Detailed role of SR-A1 and SR-E3 in tumor biology, progression, and therapy

The first host defense systems are the innate immune response and the inflammatory response. Among innate immune cells, macrophages, are crucial because they preserve tissue homeostasis and eradicate infections by phagocytosis, or the ingestion of particles. Macrophages exhibit phenotypic variability contingent on their stimulation state and tissue environment and may be detected in several tissues. Meanwhile, critical inflammatory functions are played by macrophage scavenger receptors, in particular, SR-A1 (CD204) and SR-E3 (CD206), in a variety of pathophysiologic events. Such receptors, which are mainly found on the surface of multiple types of macrophages, have different effects on processes, including atherosclerosis, innate and adaptive immunity, liver and lung diseases, and, more recently, cancer. Although macrophage scavenger receptors have been demonstrated to be active across the disease spectrum, conflicting experimental findings and insufficient signaling pathways have hindered our comprehension of the molecular processes underlying its array of roles. Herein, as SR-A1 and SR-E3 functions are often binary, either protecting the host or impairing the pathophysiology of cancers has been reviewed. We will look into their function in malignancies, with an emphasis on their recently discovered function in macrophages and the possible therapeutic benefits of SR-A1 and SR-E3 targeting.

Molecular insights to therapeutic in cancer: role of exosomes in tumor microenvironment, metastatic progression and drug resistance

Exosomes play a pivotal part in cancer progression and metastasis by transferring various biomolecules. Recent research highlights their involvement in tumor microenvironment remodeling, mediating metastasis, tumor heterogeneity and drug resistance. The unique cargo carried by exosomes garners the interest of researchers owing to its potential as a stage-specific biomarker for early cancer detection and its role in monitoring personalized treatment. However, unanswered questions hinder a comprehensive understanding of exosomes and their cargo in this context. This review discusses recent advancements and proposes novel ideas for exploring exosomes in cancer progression, aiming to deepen our understanding and improve treatment approaches.

The systematic role of pancreatic cancer exosomes: distant communication, liquid biopsy and future therapy

Pancreatic cancer remains one of the most lethal diseases worldwide. Cancer-derived exosomes, benefiting from the protective role of the lipid membrane, exhibit remarkable stability in the circulatory system. These exosomes, released by tumor microenvironment, contain various biomolecules such as proteins, RNAs, and lipids that plays a pivotal role in mediating distant communication between the local pancreatic tumor and other organs or tissues. They facilitate the transfer of oncogenic factors to distant sites, contributing to the compromised body immune system, distant metastasis, diabetes, cachexia, and promoting a microenvironment conducive to tumor growth and metastasis in pancreatic cancer patients. Beyond their intrinsic roles, circulating exosomes in peripheral blood can be detected to facilitate accurate liquid biopsy. This approach offers a novel and promising method for the diagnosis and management of pancreatic cancer. Consequently, circulating exosomes are not only crucial mediators of systemic cell-cell communication during pancreatic cancer progression but also hold great potential as precise tools for pancreatic cancer management and treatment. Exosome-based liquid biopsy and therapy represent promising advancements in the diagnosis and treatment of pancreatic cancer. Exosomes can serve as drug delivery vehicles, enhancing the targeting and efficacy of anticancer treatments, modulating the immune system, and facilitating gene editing to suppress tumor growth. Ongoing research focuses on biomarker identification, drug delivery systems, and clinical trials to validate the safety and efficacy of exosome-based therapies, offering new possibilities for early diagnosis and precision treatment in pancreatic cancer. Leveraging the therapeutic potential of exosomes, including their ability to deliver targeted drugs and modulate immune responses, opens new avenues for innovative treatment strategies.