The effective natural compounds for inhibiting Cervical cancer

Computational analysis of lupenone derivatives as potential inhibitor of human papillomavirus oncoprotein E6 associated cervical cancer

Cervical cancer remains a major global health challenge, largely driven by persistent infections with high-risk human papillomavirus (HPV). Although preventive vaccines have reduced cervical cancer incidence in some settings, effective therapeutic strategies for established HPV-associated malignancies remain limited. High-risk HPV types (particularly 16 and 18) utilize their E6 oncoprotein to promote ubiquitin-mediated degradation of the tumor suppressor p53, thereby facilitating uncontrolled cell proliferation and immune evasion. Targeting E6 has thus emerged as a key strategy to counteract HPV-driven carcinogenesis. In this work, we employed a comprehensive in silico framework-encompassing density functional theory (DFT), ADMET (absorption, distribution, metabolism, excretion, and toxicity) profiling, molecular docking (including refinement and validation), and molecular dynamics (MD) simulations-to evaluate a series of chemically modified lupenone derivatives as potential HPV oncoprotein inhibitors. Initially, lupenone was modified with different functional groups, and each derivative was screened for drug-likeness via ADMET analysis to confirm pharmacological viability. Concurrently, pharmacophore mapping highlighted key alignments between ligand functional groups and pharmacophoric sites, while DFT calculations elucidated each compound's electronic structure, conformational stability, and chemical reactivity. Subsequent docking assessments against E6 oncoprotein and molecular dynamics simulations further confirmed structural robustness in several top-performing compounds, indicating minimal conformational fluctuations over time. These findings demonstrate the potential of lupenone derivatives as promising scaffolds for anti-HPV therapy. However, in vitro and in vivo investigations are necessary to confirm their efficacy, toxicity profiles, and clinical relevance in mitigating HPV-related cervical cancer.

Mycosubtilin Induces G1 Phase Block and Autophagy in Cervical Cancer HeLa Cells

Cyclic lipopeptides secreted by the probiotic bacterium Bacillus subtilis have attracted much attention due to their antitumor activities and low toxicity. However, the role of Mycosubtilin (Myco) in the prevention and treatment of cervical cancer remains unclear. In the present study, we conducted a systematic evaluation of Myco's anti-cervical cancer effects to identify its molecular mechanism of action using proteomics technology. The results reveal that Myco inhibited the growth of HeLa and SiHa cervical cancer cell lines in a dose-dependent (3-15 µg/mL) and time-dependent (12-48 h) manner and significantly reduced colony formation and migration in HeLa cells, highlighting its potential to suppress tumor spread. Moreover, autophagosome and autolysosome numbers were significantly increased after Myco treatment, and the expression of autophagy-related proteins was significantly modulated, suggesting that autophagy plays a role in its anti-cancer mechanism. Myco treatment also induced G1 phase cell cycle arrest in HeLa cells, as confirmed by proteomics analysis. Myco was shown to induce cell cycle arrest in HeLa cells by regulating the P53 pathway and autophagy-dependent cell death via the PI3K/AKT/mTOR signaling pathway, demonstrating its multidimensional effect on cervical cancer cell growths. Myco treatment significantly inhibited tumor growth in vivo in a nude mouse cervical cancer xenograft model, providing direct evidence of its potential as a therapeutic candidate for cervical cancer. Given its unique anti-cancer mechanism and significant therapeutic efficacy, Myco should be considered a promising therapeutic agent for cervical cancer.

Evaluation of the Bioactive Properties of Essential Oils Associated with Organic Acids Applied in Poultry Nutrition

Evaluation of natural molecules for replacement of growth promoters applied in poultry has been studied, as it can provide a favorable intestinal environment to improve the digestion and absorption capacity of nutrients. Essential oils of oregano, clove, rosemary, and propionic, lactic, and formic organic acids were tested against 30 different species. The antimicrobial potential was tested, with formic acid having the highest mean of inhibition halos (32.09 ± 1.01 mm) and clove EO having an average of 14.36 ± 0.54 mm. The synergy between formic acid and clove was observed against Salmonella Typhimurium (∑FIC 0.37), Salmonella Enteritidis (∑FIC 0.07), and Escherichia coli APEC (∑FIC 0.265). Through the in silico method, the potential of EO and OA to bind the proteins d-glutamate ligase (PDB ID: 1E0D) and DNA gyrase B (PDB ID: 4PRV) was evaluated. It was confirmed that the molecules with the highest binding affinity were formic acid and clove. The antioxidant power was evaluated by the DPPH free radical capture method, and the clove EO showed higher activity (IC50: 3.029 μg mL-1). The results demonstrate that the products have antimicrobial and antioxidant properties, suggesting applicability in synergistic formulations, which may be effective for a wide variety of pathogens in poultry. The association between two natural molecules can be possible substitutes for growth promoters, with applications in feed formulations.

Pharmacological network study on the effect of 6-gingerol on cervical cancer using computerized databases

Cervical cancer (CC) is the most frequent cancer in the female population worldwide. Although there are treatments available, they are ineffective and cause adverse effects. 6-gingerol is an active component in ginger with anticancer activity. This research aims to discover the mechanism by which 6-gingerol act as an anticancer agent on CC through a pharmacological network using bioinformatics databases. From MalaCard, Swiss Target Prediction, Comparative Toxicogenomics Database, and Traditional Chinese Medicine Systems Pharmacology Database and Analysis Platform, we obtained the target genes for 6-gingerol and CC and matched them. We got 26 genes and analyzed them in ShinyGO-0.76.3 and DAVID-Bioinformatics Resources. Then, we generated a protein-protein interaction network in Cytoscape and obtained 12 hub genes. Hub genes were analyzed in Gene Expression Profiling Interactive Analysis and TISIDB. In addition, molecular docking studies were performed between target proteins with 6-gingerol using SwissDock database. Finally, molecular dynamics studies for three proteins with the lowest interaction energy were implemented using Gromacs software. According to gene ontology results, 6-gingerol is involved in processes of apoptosis, cell cycle, and protein kinase complexes, affecting mitochondria and pathways related to HPV infection. CTNNB1 gene was negatively correlated with CD8+ infiltration but was not associated with a higher survival rate. Furthermore, the molecular docking study showed that 6-gingerol has a high binding to proteins, and the molecular dynamics showed a stable interaction of 6-gingerol to AKT1, CCNB1, and CTNNB1 proteins. Conclusion, our work helps to understand the anticancer activity of 6-gingerol in CC that should be studied experimentally.Communicated by Ramaswamy H. Sarma.

Unraveling the molecular mechanism of l-menthol against cervical cancer based on network pharmacology, molecular docking and in vitro analysis

Cervical cancer is a major cause of gynecological related mortalities in developing countries. Cisplatin, a potent chemotherapeutic agent used for treating advanced cervical cancer exhibits side effects and resistance development. The current study was aimed to investigate the repurposing of l-menthol as a potential therapeutic drug against cervical cancer. L-menthol was predicted to be non-toxic with good pharmacokinetic properties based on SwissADME and pkCSM analysis. Subsequently, 543 and 1664 targets of l-menthol and cervical cancer were identified using STITCH, BATMAN-TCM, PharmMapper and CTD databases. STRING and Cytoscape analysis of the merged protein-protein interaction network revealed 107 core targets of l- menthol against cervical cancer. M-CODE identified highly connected clusters between the core targets which through KEGG analysis were found to be enriched in pathways related to apoptosis and adherence junctions. Molecular docking showed that l- menthol targeted E6, E6AP and E7 onco-proteins of HPV that interact and inactivate TP53 and Rb1 in cervical cancer, respectively. Molecular docking also showed good binding affinity of l-menthol toward proteins associated with apoptosis and migration. Molecular dynamics simulation confirmed stability of the docked complexes. In vitro analysis confirmed that l-menthol was cytotoxic towards cervical cancer CaSki cells and altered expression of TP53, Rb1, CDKN1A, E2F1, NFKB1, Akt-1, caspase-3, CDH1 and MMP-2 genes identified through network pharmacology approach. Schematic representation of the work flow depicting the potential of l-menthol to target cervical cancer.

The curative effect of some natural active compounds for liver cancer

Cancer is a disease that has become widespread recently and has been studied extensively. It is of great importance to find an active and effective treatment quickly due to the emergence of the disease and its spread to many tissues in the organism by metastasis. In this study, it is aimed to detect active and active substances that are highly effective on cancer cells in a short time by using docking scores, the accuracy of which has been proven by many studies. Today, many medicinal plants are being studied for therapeutic purposes. In this study, the activities of the prominent active substances in these medicinal plants were compared with the docking scores and the molecules with the highest inhibition effect on liver cancer receptors were determined. The data obtained in this study are of great importance in terms of guiding experimental studies by detecting active substances effective on liver cancer by preventing time and material loss. Considering the results obtained from this study, it can be concluded that Cucurbitacin I and Cucurbitacin E, Thymol, Piperine, and Carvacrol are very effective for the inhibition of liver cancer cell receptors.

Therapeutic effect of some natural active compounds for breast cancer

The extracts obtained from plants have been used in the treatment of many diseases since the earliest times. Today, it is of great importance to investigate the effects of the active molecules in these plant extracts at the molecular level together with the analysis. The effect of certain active compounds found in some plants, widely used as medicinal plants, on breast cancer has been investigated using docking. As a result of the docking scores obtained, it can be understood that the active molecules used in this study can be quite effective in controlling breast cancer. Promyelocytic leukemia is an important checkpoint from the literature for breast cancer and the docking energy values of Thymoquinone, Piperine and Carvacrol, as the active molecules in the control of this pathway. This study is very important when evaluated in terms of directing experimental studies by determining the most suitable active substances by comparing the activities of molecules in a short time.

Phytocompounds from the medicinal and dietary plants: Multi-target agents for cancer prevention and therapy

Cervical cancer is the fourth leading cause of cancer death among women worldwide. Due to cervical cancer's high incidence and mortality, there is an unmet demand for effective diagnostic, therapeutic, and preventive agents. At present, the preferred treatment strategies for advanced metastatic cervical cancer include surgery, radiotherapy, and chemotherapy. However, cervical cancer is gradually developing resistance to chemotherapy, thereby reducing its efficacy. Over the last several decades, phytochemicals, a general term for compounds produced from plants, have gained attention for their role in preventing cervical cancer. This role in cervical cancer prevention has garnered attention on the medicinal properties of fruits and vegetables. Phytochemicals are currently being evaluated for their ability to block proteins involved in carcinogenesis and chemoresistance against cervical cancer. Chemoresistance to cancer drugs like cisplatin, doxorubicin, and 5-fluorouracil has become a significant limitation of drug-based chemotherapy. However, the combination of cisplatin with other phytochemicals has been identified as a promising alternative to subjugate cisplatin resistance. Phytochemicals are promising chemo-preventive and chemotherapeutic agents as they possess antioxidant, anti-inflammatory, and anti-proliferative potential against many cancers, including cervical cancer. Furthermore, the ability of the phytochemicals to modulate cellular signaling pathways through up and down regulation of various proteins has been claimed for their therapeutic potential. Phytochemicals also display a wide range of biological functions, including cell cycle arrest, apoptosis induction, inhibition of invasion, and migration in cervical cancer cells. Numerous studies have revealed the critical role of different signaling proteins and their signaling pathways in the pathogenesis of cervical cancer. Here, we review the ability of several dietary phytochemicals to alter carcinogenesis by modulating various molecular targets.

Potential Mechanisms of Plant-Derived Natural Products in the Treatment of Cervical Cancer

Cervical cancer is the second most common gynecological malignancy globally; it seriously endangers women’s health because of its high morbidity and mortality. Conventional treatments are prone to drug resistance, recurrence and metastasis. Therefore, there is an urgent need to develop new drugs with high efficacy and low side effects to prevent and treat cervical cancer. In recent years, plant-derived natural products have been evaluated as potential anticancer drugs that preferentially kill tumor cells without severe adverse effects. A growing number of studies have shown that natural products can achieve practical anti-cervical-cancer effects through multiple mechanisms, including inhibition of tumor-cell proliferation, induction of apoptosis, suppression of angiogenesis and telomerase activity, enhancement of immunity and reversal of multidrug resistance. This paper reviews the therapeutic effects and mechanisms of plant-derived natural products on cervical cancer and provides references for developing anti-cervical-cancer drugs with high efficacy and low side effects.

Trichosanthin inhibits cervical cancer by regulating oxidative stress-induced apoptosis

Based on many studies, trichosanthin (TCS) has an antiviral effect that regulates immune response, and targets cancer cells to exert broad-spectrum anti-tumor pharmacological activities. It is speculated that TCS may be a potential natural active drug for preventing as well as treating cervical cancer. But the clearer impact along with underlying TCS mechanism on cervical cancer are still unclear. The purpose of this study is to investigate the function and potential mechanism of TCS in cervical cancer. We measured the viability of cervical cancer cell lines (HeLa & caski cells) using CCK-8 analysis, detected cell proliferation efficiency through Ki-67 staining, analyzed cell apoptosis rate via flow cytometry as well as annexin V-FITC/PI double staining, performed apoptosis-related protein expression through western blotting, evaluated cell migration along with invasion by wound as well as transwell assays, carried out MMP via JC-1 and Rh123 fluorescent probes, as well as detected intracellular ATP and ROS levels by flow cytometry, respectively, to evaluate the effects of TCS. We found that TCS inhibited viability along with proliferation, induced apoptosis, as well as inhibited HeLa & caski cell migration along with invasion in a time- and dose-dependent manner. Additionally, TCS also reduced MMP, and the production of adenosine triphosphate, as well as induced the increase of intracellular reactive oxygen species in cancer cell lines. In accordance with the present studies, TCS inhibits HeLa & caski cell proliferation along with migration but promotes their apoptosis, which may be mediated by regulating oxidative stress.