Carrimycin, a first in-class anti-cancer agent, targets selenoprotein H to induce nucleolar oxidative stress and inhibit ribosome biogenesis

Targeting mineral metabolism in cancer: Insights into signaling pathways and therapeutic strategies

Cancer remains the second leading cause of death worldwide, emphasizing the critical need for effective treatment and control strategies. Essential minerals such as copper, iron, zinc, selenium, phosphorous, calcium, and magnesium are integral to various biological processes and significantly influence cancer progression through altered metabolic pathways. For example, dysregulated copper levels promote tumor growth, while cancer cells exhibit an increased dependency on iron for signaling and redox reactions. Zinc influences tumor development through pathways such as Akt-p21. Selenium, primarily through its role in selenoproteins, exhibits anticancer potential but may also contribute to tumor progression. Similarly, dietary phosphate exacerbates tumorigenesis, metastasis, and angiogenesis through signaling pathway activation. Calcium, the most abundant mineral in the body, is tightly regulated within cells, and its dysregulation is a hallmark of various cancers. Magnesium deficiency, on the other hand, promotes cancer progression by fostering inflammation and free radical-induced DNA mutations. Interestingly, magnesium also plays a dual role, with low levels enhancing epithelial-mesenchymal transition (EMT), a critical process in cancer metastasis. This complex interplay of essential minerals underscores their potential as therapeutic targets. Dysregulation of these minerals and their pathways could be exploited to selectively target cancer cells, offering novel therapeutic strategies. This review summarizes current research on the abnormal accumulation or depletion of these microelements in tumor biology, drawing evidence from animal models, cell lines, and clinical samples. We also highlight the potential of these minerals as biomarkers for cancer diagnosis and prognosis, as well as therapeutic approaches involving metal chelators, pharmacological agents, and nanotechnology. By highlighting the intricate roles of these minerals in cancer biology, we aim to inspire further research in this critical yet underexplored area of oncology.

The synergistic antitumour effect of Carrimycin combined with 5-fluorouracil on colorectal cancer

5-Fluorouracil (5-FU)-based chemotherapy often leads to drug resistance and adverse reactions in individuals with colorectal cancer (CRC). Carrimycin (CAM), a drug with notable antitumour effects across various tumour types, including hepatocellular carcinoma, glioblastoma, and small-cell lung carcinoma, offers an alternative owing to its limited side effects. Combination therapy is a common strategy to mitigate the negative effects of 5-FU and enhance its therapeutic efficacy. This study aimed to investigate the potential synergistic antitumour effects of CAM and 5-FU on HCT-15 and HT-29 CRC cell lines. Using computational analysis, we identified and quantified the synergistic effects of CAM and 5-FU. The combination therapy significantly outperformed 5-FU alone in inhibiting cell proliferation, colony formation, cell cycle progression, and migration. Additionally, it markedly increased the levels of reactive oxygen species and induced DNA damage. Furthermore, RNA-seq analysis revealed that the JNK and p38 MAPK signalling pathways were activated by this combination. In addition, the synergistic effects of the combination therapy were validated in a mouse subcutaneous tumour graft model. In conclusion, CAM enhances the sensitivity of CRC cells to 5-FU both in vitro and in vivo, suggesting its potential as a promising candidate for combination cancer therapy.

Advancements and challenges of R-loops in cancers: Biological insights and future directions

R-loops involve in various biological processes under human normal physiological conditions. Disruption of R-loops can lead to disease onset and affect the progression of illnesses, particularly in cancers. Herein, we summarized and discussed the regulative networks, phenotypes and future directions of R-loops in cancers. In this review, we highlighted the following insights: (1) R-loops significantly influence cancer development, progression and treatment efficiency by regulating key genes, such as PARPs, BRCA1/2, sex hormone receptors, DHX9, and TOP1. (2) Currently, the ATM, ATR, cGAS/STING, and noncanonical pathways are the main pathways that involve in the regulatory network of R-loops in cancer. (3) Cancer biology can be modulated by R-loops-regulated phenotypes, including RNA methylation, DNA and histone methylation, oxidative stress, immune and inflammation regulation, and senescence. (4) Regulation of R-loops induces kinds of drug resistance in various cancers, suggesting that targeting R-loops maybe a promising way to overcome treatment resistance. (5) The role of R-loops in tumorigenesis remains controversial, and senescence may be a crucial research direction to unravel the mechanism of R-loop-induced tumorigenesis. Looking forward, further studies are needed to elucidate the specific mechanisms of R-loops in cancer, laying the groundwork for preclinical and clinical research.

Carrimycin, as One of the Drugs in Combination Therapy, for the Treatment of Carbapenem-Resistant Acinetobacter Baumannii Infection

Purpose

Infection with carbapenem-resistant Acinetobacter baumannii (CRAB) is a tough nut to crack. Carrimycin is a novel recombinant macrolide antibiotic, and has good anti-infection effects in vivo. At present, it is rarely reported for treatment of CRAB infection. We present a case where a patient with COVID-19 complicated by CRAB infection was successfully treated with a combination therapy including carrimycin, offering clinical insights and experience.

Patients and Methods

The patient infected with CRAB was cured by carrimycin combined with tigecycline and amikacin ultimately. We analyzed and summarized the therapeutic regimen and disease feature to provide reference for clinical treatment.

Results

The patient was admitted to emergency observation wards with fever and was diagnosed with COVID-19 pneumonia. During the treatment, his condition worsened. He had a fever, cough, and expectoration. After 3 days of empirical treatment with meropenem, tested positive for A. baumannii infection by the next-generation sequencing, and CRAB was detected in blood and sputum culture. Then, he was administered with tigecycline and amikacin immediately for 5 days, however the therapeutic effect was not significant. The patient still remained in a high inflammatory response. Ultimately, the treatment regimen was changed to carrimycin combined with tigecycline and amikacin for 7 days, and then carrimycin combined with tigecycline for 10 days, the patient's clinical condition gradually improved. The patient received carrimycin monotherapy for 7 days, then discharged.

Conclusion

Carrimycin may be a bright alternative for CRAB infection as one of the drugs in combination therapy, especially in a patient with hyperinflammatory response.

Transcriptomic analysis of hydrogen peroxide-induced liver dysfunction in Cyprinus carpio: Insights into protein synthesis and metabolism

Hydrogen peroxide (H2O2), a prevalent reactive oxygen species (ROS) found in natural aquatic environments, has garnered significant attention for its potential toxicity in fish. However, the molecular mechanisms underlying this toxicity are not yet comprehensively understood. This study aimed to assess H2O2-induced liver dysfunction in common carp (Cyprinus carpio) and elucidate the underlying molecular mechanisms via biochemical and transcriptomic analyses. Common carp were divided into normal control (NC) and H2O2-treated groups (1 mM H2O2), the latter of which was exposed to H2O2 for 1 h per day over a period of 14 days. Serum biochemical analyses indicated that exposure to H2O2 resulted in moderate liver damage, characterized by elevated alanine aminotransferase (ALT) activity and lowered albumin (Alb) level. Concurrently, H2O2 exposure induced oxidative stress and modified the hepatic metabolic enzyme levels. Transcriptome analysis highlighted that 1358 and 1188 genes were significantly downregulated and upregulated, respectively, in the H2O2-treated group. These differentially expressed genes (DEGs) were significantly enriched in protein synthesis and a variety of metabolic functions such as peptide biosynthetic processes, protein transport, ribonucleoprotein complex biogenesis, oxoacid metabolic processes, and tricarboxylic acid metabolic processes. Dysregulation of protein synthesis is principally associated with the downregulation of three specific pathways: ribosome biogenesis, protein export, and protein processing in the endoplasmic reticulum (ER). Furthermore, metabolic abnormalities were primarily characterized by inhibition of the citrate cycle (TCA) and fatty acid biosynthesis. Significantly, anomalies in both protein synthesis and metabolic function may be linked to aberrant regulation of the insulin signaling pathway. These findings offer innovative insights into the mechanisms underlying H2O2 toxicity in aquatic animals, contributing to the assessment of ecological risks.

The semisynthesis of nucleolar human selenoprotein H

The human selenoprotein H is the only selenocysteine-containing protein that is located in the cell's nucleolus. In vivo studies have suggested that it plays some role in DNA binding, consumption of reactive oxygen species, and may serve as a safeguard against cancers. However, the protein has never been isolated and, as a result, not yet fully characterized. Here, we used a semi-synthetic approach to obtain the full selenoprotein H with a S43T mutation. Using biolayer interferometry, we also show that the Cys-containing mutant of selenoprotein H is capable of binding DNA with sub-micromolar affinity. Employing state-of-the-art expressed protein ligation (EPL), our devised semi-synthetic approach can be utilized for the production of numerous, hard-to-obtain proteins of biological and therapeutic relevance.