NFE2L3 drives hepatocellular carcinoma cell proliferation by regulating the proteasome-dependent degradation of ISGylated p53

The CNC-family transcription factor NRF3: A crucial therapeutic target for cancer treatment

The CNC-bZIP family member NRF3 (NFE2L3) has received limited attention since its discovery. However, recent research has gradually revealed its biological functions, such as involvement in the regulation of cell differentiation, lipid metabolism, and malignant cell proliferation. Under physiological conditions, NRF3 is anchored to the endoplasmic reticulum within the cytoplasm and is biologically inactive. Upon cellular exposure to microenvironmental stresses such as oxidative stress, NRF3 translocates to the nucleus, binds to DNA, and acts as a transcription factor by inducing or repressing the expression of various genes. In terms of tumor regulation, NRF3 exhibits a dual role. It can function as a tumor suppressor to prevent the malignant progression of tumor tissues, protecting the organism from harm. Conversely, current research indicates that NRF3 plays a tumor-promoting role in most tumor tissues. NRF3 enhances the proliferation, migration and invasion of tumor cells by regulating cell cycle-related proteins and enhancing proteasome assembly to degrade tumor suppressors. Studies correlating NRF3 expression with clinical tumor features have found that elevated NRF3 expression is often associated with poor prognoses in various cancers, with patients exhibiting higher NRF3 expression typically having lower survival rates. Several studies suggest that NRF3 could serve as a clinical diagnostic and prognostic marker for tumors. Finally, from the clinical perspective, exploring the feasibility of inhibiting NRF3 activity in tumor treatment provides new insights for the development of NRF3-targeted oncological therapies.

ISGylation: is our genome yearning for such a modification?

ISGylation is the post-translational modification of protein substrates covalently conjugated with the ubiquitin-like protein, interferon-stimulated gene 15 (ISG15). Although initially linked to antiviral immunity, recent evidence highlights important roles for ISGylation in various biological processes, such as maintaining genomic stability, promoting tumourigenesis, and being involved in other pathological conditions. In this review, we examine the molecular mechanisms underlying ISGylation, its interplay with other post-translational modifications, and its involvement in diverse biological and pathological processes. We propose future research directions to advance the field and discuss how ISGylation might be harnessed to ensure human health, particularly genome instability-associated diseases.

Proteasomal Dysfunction in Cancer: Mechanistic Pathways and Targeted Therapies

Proteasomes are the catalytic complexes in eukaryotic cells that decide the fate of proteins involved in various cellular processes in an energy-dependent manner. The proteasomal system performs its function by selectively destroying the proteins labelled with the small protein ubiquitin. Dysfunctional proteasomal activity is allegedly involved in various clinical disorders such as cancer, neurodegenerative disorders, ageing, and so forth, making it an important therapeutic target. Notably, compared to healthy cells, cancer cells have a higher protein homeostasis requirement and a faster protein turnover rate. The ubiquitin-proteasome system (UPS) helps cancer cells increase rapidly and experience less apoptotic cell death. Therefore, understanding UPS is essential to design and discover some effective inhibitors for cancer therapy. Hereby, we have focused on the role of the 26S proteasome complex, mainly the UPS, in carcinogenesis and seeking potential therapeutic targets in treating numerous cancers.

Systematic regulation of immune checkpoint molecules by redox regulators CNC-bZIP transcription factors

BACKGROUND

Although oxidative stress is strongly connected to the initiation and progression of cancer, the underlying molecular pathways remain unknown. The redox regulator CNC-bZIPs are important transcription factor groups that mediate the interplay of environmental cues and intercellular homeostasis. Immune checkpoint molecules (ICMs) are key molecules that mediate the communication between immune cells and tumor cells. This research sought to explore the transcriptional regulatory effects of CNC-bZIPs on ICMs.

METHODS

The potential role of CNC-bZIPs in tumors and the correlation between CNC-bZIPs and ICMs were analyzed by the gene expression characteristics, survival analysis, and correlation analysis in TCGA data. And the transcriptional regulatory effects of CNC-bZIPs on ICMs were verified through cis acting element analysis and promoter activity reporter experiments.

RESULTS

In this study, we found that high expression of CNC-bZIPs predicted poor prognosis, and we determined that CNC-bZIPs are universally connected to ICMs by analyzing gene expression correlation in TCGA tumor data. Specifically, CD47 and CD274 exhibit universally positive correlation with CNC-bZIPs in various tumor tissues. Promoter analysis revealed that there are several ARE elements, which are specifically recognized by CNC-bZIPs, in the promoter regions of CD47 and CD274 genes. Overexpression of NFE2L1 and NFE2L2 was used to explore the regulation of common ICM genes, such as CD47 and CD274, and the transcriptional regulatory effect of CNC-bZIPs on ICMs was confirmed using promoter activity reporter experiments.

CONCLUSION

In this study, the universal and systematic transcriptional regulatory role of the CNC-bZIP transcription factor family on ICMs was discovered. According to this study, the results and conclusions drawn are based on gene expression correlation and promoter activity assays, the CNC-bZIPs/ICMs transcriptional regulatory axis was revealed to be a potential regulatory axis that may drive redox signaling and anti-tumor immune responses.

New insight into the CNC-bZIP member, NFE2L3, in human diseases

Nuclear factor erythroid 2 (NF-E2)-related factor 3 (NFE2L3), a member of the CNC-bZIP subfamily and widely found in a variety of tissues, is an endoplasmic reticulum (ER) membrane-anchored transcription factor that can be released from the ER and moved into the nucleus to bind the promoter region to regulate a series of target genes involved in antioxidant, inflammatory responses, and cell cycle regulation in response to extracellular or intracellular stress. Recent research, particularly in the past 5 years, has shed light on NFE2L3's participation in diverse biological processes, including cell differentiation, inflammatory responses, lipid homeostasis, immune responses, and tumor growth. Notably, NFE2L3 has been identified as a key player in the development and prognosis of multiple cancers including colorectal cancer, thyroid cancer, breast cancer, hepatocellular carcinoma, gastric cancer, renal cancer, bladder cancer, esophageal squamous cell carcinoma, T cell lymphoblastic lymphoma, pancreatic cancer, and squamous cell carcinoma. Furthermore, research has linked NFE2L3 to other cancers such as lung adenocarcinoma, malignant pleural mesothelioma, ovarian cancer, glioblastoma multiforme, and laryngeal carcinoma, indicating its potential as a target for innovative cancer treatment approaches. Therefore, to gain a better understanding of the role of NFE2L3 in disease, this review offers insights into the discovery, structure, function, and recent advancements in the study of NFE2L3 to lay the groundwork for the development of NFE2L3-targeted cancer therapies.

Unveiling the Multifaceted Roles of ISG15: From Immunomodulation to Therapeutic Frontiers

The Interferon Stimulated Gene 15 (ISG15), a unique Ubiquitin-like (Ubl) modifier exclusive to vertebrates, plays a crucial role in the immune system. Primarily induced by interferon (IFN) type I, ISG15 functions through diverse mechanisms: (i) covalent protein modification (ISGylation); (ii) non-covalent intracellular action; and (iii) exerting extracellular cytokine activity. These various roles highlight its versatility in influencing numerous cellular pathways, encompassing DNA damage response, autophagy, antiviral response, and cancer-related processes, among others. The well-established antiviral effects of ISGylation contrast with its intriguing dual role in cancer, exhibiting both suppressive and promoting effects depending on the tumour type. The multifaceted functions of ISG15 extend beyond intracellular processes to extracellular cytokine signalling, influencing immune response, chemotaxis, and anti-tumour effects. Moreover, ISG15 emerges as a promising adjuvant in vaccine development, enhancing immune responses against viral antigens and demonstrating efficacy in cancer models. As a therapeutic target in cancer treatment, ISG15 exhibits a double-edged nature, promoting or suppressing oncogenesis depending on the tumour context. This review aims to contribute to future studies exploring the role of ISG15 in immune modulation and cancer therapy, potentially paving the way for the development of novel therapeutic interventions, vaccine development, and precision medicine.

Nrf3 alleviates oxidative stress and promotes the survival of colon cancer cells by activating AKT/BCL-2 signal pathway

Oxidative stress is closely linked to tumor initiation and development, conferring a survival advantage to cancer cells. Therefore, understanding cancer cells' antioxidant molecular mechanisms is crucial to cancer therapy. In this study, we discovered that H2O2-induced oxidative stress increased Nrf3 expression in colon cancer cells. Overexpression of Nrf3 decreased H2O2-mediated cytotoxicity and apoptosis. Furthermore, Nrf3 reduced reactive oxygen species levels and malondialdehyde concentrations after H2O2 treatment. Mechanistically, H2O2-mediated cell apoptosis involves multiple signaling proteins, including Akt, bcl-2, JNK, and p38. An increase in Nrf3 expression in colon cancer cells treated with H2O2 partly reversed Akt/Bcl-2 inhibition, whereas it decreased activation of p38 and JNK. In addition, we found that increasing Nrf3 decreased stress-associated chemical-induced cell death, resulting in drug resistance. According to these results, Nrf3 is critical for drug resistance and oxidant adaptation.