Anticancer Research Articles

Use of traditional Chinese medicine bezoars and bezoar-containing preparations in hepatocarcinoma

This manuscript used network pharmacology and experimental verification to analyze the anti-hepatocarcinoma mechanism of action of bezoars in traditional Chinese medicine (TCM), discovering that it can affect the immune cells within the tumor microenvironment and related pathways to produce inhibitory effects in liver cancer. In TCM, bezoars have a unique therapeutic advantage in the prevention and treatment of tumors. They play an anti-tumorigenic role by regulating the immune microenvironment through multi-component, multi-target and multi-pathway mechanisms. With the application of nanotechnology, bezoars and their compound preparations have been developed into anti-cancer drugs with unique therapeutic advantages, providing novel treatment options for tumor patients.

Retraction Note: Application of zinc oxide nano-tube as drug-delivery vehicles of anticancer drug.

Retraction Note: Application of zinc oxide nano-tube as drug-delivery vehicles of anticancer drug.

Development and In-Vitro Evaluation of Doxorubicin-Loaded Methacrylate Gelatin (GelMa)-Acrylamide Hydrogels for the Treatment of Malignant Pleural Mesothelioma.

Malignant pleural mesothelioma (MPM) is the most prevalent subtype of malignant mesothelioma that affects the pleural lining of the lungs. Conventionally, chemotherapy via systemic injections has shown limited efficacy due to off-target effects, and inefficacious deposition at the disease site. In our previous study, we reported the development and optimization of UV-initiated methacrylate gelatin (GelMa)-acrylamide based hydrogel formulation for local intracavitary administration of therapies. The current study utilizes a pre-established GelMa formulation for delivering a small molecule chemotherapeutic agent, Doxorubicin (Dox), against in-vitro MPM models. Dox-loaded hydrogel (DLH) precursor solution was prepared by dissolving Dox in the precursor solution. The gels were characterized for physical properties such as gelling time, swelling index, bio adhesion, and injectability and were compared to blank hydrogels. Dox-loaded hydrogels were also tested for therapeutic efficacy in MPM cells in various 2D and 3D cell culture models. It was revealed that Dox-loaded hydrogels retained similar physical properties, including gelling time (< 25s), swelling index (~ 1,200%), bio-adhesion (> 20g detachment force), and injectability (< 2N force for injecting precursor), compared to blank hydrogels. Moreover, the gel formulation effectively sustained the release of hydrophilic Dox HCl over a period of 12days by increasing the degree of crosslinking between GelMa and its crosslinkers. Further, the therapeutic efficacy of Dox was retained even after loading into hydrogels, indicating that no chemical interactions took place between gel excipients and the drug. Studies in MPM cell-based models revealed that DLH showed excellent potential in inhibiting 2D and 3D cell growth, with DLH being more effective than plain Dox in suppressing tumor growth in 3D spheroid models. Overall, the results of the present study suggest that Dox-loaded hydrogels (DLH) may be a good candidate for efficacy study in preclinical mesothelioma models, with strong potential for clinical translation.

An integrated machine learning framework for developing and validating a prognostic risk model of gastric cancer based on endoplasmic reticulum stress-associated genes

BackgroundGastric cancer (GC), a prevalent and deadly malignancy, demonstrates poor survival outcomes. Evidence has emerged indicating that disruptions in endoplasmic reticulum homeostasis are significantly implicated in the onset and progression of various oncological conditions. This study was designed to construct a prognostic model based on genes related to endoplasmic reticulum stress(ERS) to predict survival outcomes in patients with GC. MethodsExpression profiling data for GC samples were extracted and analyzed from TCGA-STAD, revealing 214 genes related to endoplasmic reticulum stress that show differential expression when compared with normal gastric tissue. Building on these insights, a prognostic model was formulated using data from TCGA-STAD and validated through subsequent analyses of GEO datasets. The tumor immune dysfunction and exclusion(TIDE) algorithm was applied to determine the susceptibility of individuals in high- and low-risk categories to immunotherapy. The presence of immune and stromal cells within the tumor microenvironment was assessed with the aid of the ESTIMATE algorithm. Sensitivity variations to prevalent anticancer drugs between the risk groups were evaluated using the Genomics of Drug Sensitivity in Cancer(GDSC) database, and prospective therapeutic agents were confirmed through molecular docking techniques. ResultsThirty-one endoplasmic reticulum stress (ERS)-related differentially expressed genes (DEGs) crucial for prognosis in GC were pinpointed. These DEGs were then used to construct a prognostic model and were considered as independent prognostic factors for GC patients. This risk model proved to have a good predictive performance for estimating the overall survival of these patients. The patients placed into the high-risk group showed worse results and lower sensitivity to immunotherapy. Moreover, five specific targeted therapy drugs, namely BMS-754807, Dasatinib, JQ1, AZD8055 and SB505124, produced better results in the treatment of the high-risk group of patients. ConclusionsA new molecular prognostic model associated with ERS was established and validated for GC and showed relatively good discriminative and predictive ability. This model greatly expands the collection of weapons in the armoury of prognostic analysis in GC.

Pelophen B is a non-taxoid binding microtubule-stabilizing agent with promising preclinical anticancer properties

Taxanes, such as paclitaxel (PTX), stabilize microtubules and are used as a first-line therapy in multiple cancer types. Disruption of microtubule equilibrium, which plays an essential role in mitosis and cell homeostasis, ultimately results in cell death. Even though PTX is a very potent chemotherapy, its use is associated with major side effects and therapy resistance. Pelophen B (PPH), a synthetic analog of peloruside A, stabilizes microtubules through interaction with a non-taxoid binding site of β-tubulin. We evaluated the anticancer effect of PPH in a variety of tumor types by using established cell lines, early-passage cultures and ex vivo tumor-derived cultures that preserve the 3D architecture of the tumor microenvironment. PPH significantly blocks colony formation capacity, reduces viability and exerts additivity with PTX. Interestingly, PPH overcomes resistance to PTX. Mechanistically, PPH induces a G2/M cell cycle arrest and increases the presence of tubulin polymerization promoting protein (TPPP), inducing lysine 40 acetylation of α-tubulin. Although, results induced by paclitaxel or PPH are concordant, PPH’s unique microtubule binding mechanism enables PTX additivity and ensures overcoming PTX-induced resistance. In conclusion, PPH results in remarkable anti-cancer activity in a range of preclinical models supporting further clinical investigation of PPH as a therapeutic anticancer agent.

Nimotuzumab and irinotecan synergistically induce ROS-mediated apoptosis by endoplasmic reticulum stress and mitochondrial-mediated pathway in cervical cancer.

Irinotecan (CPT-11), a chemotherapeutic agent used to treat several types of cancer, induces cytotoxic effects on healthy cells. The epidermal growth factor receptor (EGFR) plays a crucial role in various forms of cancer. Nimotuzumab (NmAb), a monoclonal antibody that targets the EGFR, is utilized in some countries to treat malignancies that have an overexpression of EGFR. Yet, there is a lack of literature on the potential anticancer properties of the CPT-11 and NmAb combination on in vitro human cervical cancer cells. This study investigates the apoptosis mode of the CPT-11 and NmAb combination on cervical HeLa cancer cells. The Annexin V/propidium iodide staining examination demonstrated that the combination of CPT-11 and NmAb resulted in a decrease in the number of viable cells and more potent induction of cell apoptosis than the effects of CPT-11 or NmAb alone in HeLa cells. Furthermore, the combined treatment resulted in elevated levels of reactive oxygen species (ROS) and Ca2+ compared to the treatment with CPT-11 or NmAb alone. Cells that were pretreated with N-acetyl-l-cysteine, a substance that scavenges ROS, and then treated with CPT-11, NmAb, or a combination of CPT-11 and NmAb exhibited higher numbers of viable cells compared to those treated with CPT-11 or NmAb alone. The combination of CPT-11 and NmAb resulted in significantly higher caspase-3, -8, and -9 activity levels than CPT-11 or NmAb alone, as measured by flow cytometer assay. The combination of CPT-11 and NmAb in HeLa cells resulted in elevated endoplasmic reticulum stress-, mitochondria-, and caspase-mediated proteins compared to treatment with CPT-11 or NmAb alone. According to these observations, NmAb enhances the effectiveness of CPT-11 in fighting cancer by stimulating cell death in the HeLa cells. Therefore, NmAb has the potential to improve the efficacy of CPT-11 as a future cervical cancer treatment in humans.

Reusable Iron-Copper Catalyzed Cross-Coupling of Primary Amides with Aryl and Alkyl Halides: Access to N-Arylamides as Potential Antibacterial and Anticancer Agents.

We present, for the first time, an efficient ligand-free iron-copper catalyzed cross-coupling reaction involving a variety of aryl, heteroaryl halides (including chlorides, bromides, and iodides), and alkyl bromides with diverse aryl and aliphatic primary amides, conducted under solvent-minimized conditions. This economically competitive protocol successfully yielded the corresponding cross-coupling products, N-arylamides and N-alkylamides, in good to excellent yields with broad substrate scope (65 examples) and tolerance to several sensitive functionalities (including heterocycles). No conventional work-up is required for this protocol, and the developed method is applicable for gram-scale synthesis. Notably, the catalyst is inexpensive, environmentally friendly, and can be reused at least four times with minimal loss of catalytic activity. A series of experiments, including X-ray photoelectron spectroscopy (XPS), UV spectroscopy, cyclic voltammetry (CV), electron paramagnetic resonance (EPR), and X-ray diffraction (XRD) were conducted to identify the oxidation state of active catalytic species and radical clock experiment was performed using a radical probe to investigate the reaction mechanism. Furthermore, we evaluated the antibacterial and anticancer properties of selected synthesized products (3ii, 3xii, and 3xxxx) in-vitro. The results indicated that the prepared compounds exhibited promising antibacterial and anticancer activities (MTT and Molecular Docking).

Comprehensive genome analysis of hepatitis B virus using nanopore sequencing technology in patients with previously resolved infection and spontaneous reactivation without drug exposure.

A 75-year-old Japanese woman experienced persistent fatigue and progressive jaundice for 6 weeks, and was subsequently diagnosed with acute liver failure. She had not received any immunosuppressive therapies and/or antineoplastic chemotherapy. Blood tests revealed elevated levels of HBsAg, HBV-DNA, and anti-HBc IgG, while anti-HBc IgM was negative. She had undergone hepatitis virus testing 48 weeks earlier, during which HBsAg was negative, indicating that HBV reactivation occurred in a patient with a previously resolved infection, without any drug therapies as triggers, ultimately leading to acute liver failure. Despite receiving multidisciplinary intensive treatment, her condition worsened, resulting in death. Full-length genomic analysis of the HBV strain, performed using nanopore sequencing technology, identified an I126S substitution in HBsAg, known as a vaccine escape mutation, along with a quasispecies consisting primarily of two HBV clone variants: one full-length and the other with a deletion in the nt2,448-nt488 region (sp1 spliced variant). These genetic factors may have contributed to the spontaneous HBV reactivation.

Ulva pertusa Modulated Colonic Oxidative Stress Markers and Clinical Parameters: A Potential Adjuvant Therapy to Manage Side Effects During 5-FU Regimen

One of the most used chemotherapy agents in clinical practice is 5-Fluorouracil (5-FU), a fluorinated pyrimidine in the category of antimetabolite agents. 5-FU is used to treat a variety of cancers, including colon, breast, pancreatic, and stomach cancers, and its efficacy lies in its direct impact on the patient’s DNA and RNA. Specifically, its mechanism blocks the enzymes thymidylate synthetase and uracil phosphatase, inhibiting the synthesis of uracil, which cannot be incorporated into nuclear and cytoplasmic RNA. Despite being one of the most used drugs in oncology, it is associated with several significant side effects, including inflammation of the mouth, loss of appetite, and reduction in blood cells. In our study, we examined the reduction of side effects in a 5-FU regimen administered at doses of 15 mg/kg and 6 mg/kg for 14 days in 6-week-old male Sprague-Dawley rats. On the 14th day, the rats were treated orally for 2 weeks with 100 mg/kg of Ulva pertusa, a well-known seaweed from the Ulvaceae family, which has demonstrated powerful biological properties. The administration of this green alga alleviated the side effects of 5-FU, improving several parameters including body weight, food intake, and diarrhea index. It also helped reduce side effects in the blood, kidneys, and liver. Histological and molecular analyses were conducted on serum and colon tissues from the rats, examining changes in colon structure and the release of oxidative stress markers such as iNOS, COX-2, and nitrotyrosine. Several biochemical indicators, including SOD, CAT, GSH, MDA, and ascorbic acid, were also evaluated. Overall, our data indicated Ulva pertusa to be a promising therapeutic against 5-FU’s adverse effects, therefore, it could be worthwhile to investigate the possibility of using this alga in safer cancer treatment formulations. Certainly, future preclinical and clinical studies could assess the alga’s efficacy in diverse cancer treatment regimens, exploring its role as an adjuvant therapy that may reduce chemotherapy-related toxicity without compromising therapeutic outcomes.

Atorvastatin calcium alleviates UVB-induced HaCat cell senescence and skin photoaging

Excessive exposure to ultraviolet radiation B (UVB) has been shown to contribute to the aging of human skin cells. Previous research has demonstrated that atorvastatin calcium (Ato) can mitigate the aging effects caused by chemotherapy drugs. However, it remains unclear whether Ato can alleviate skin aging induced by ultraviolet radiation. In this study, through in vitro experiments with Hacat cells, we found that Ato can significantly reduce the UVB-induced increased expression of age-related protein p16 and age-related gene p21, and also reduce the up-regulation of inflammatory factors such as IL-1 and IL-6. Besides, it can reduce the expression of metallomatrix protein (MMP1 and MMP9), and inhibit cell senescence and inflammatory damage. Similarly, we found that Ato can enhance skin collagen fiber reduction and collagen volume decrease, repair skin photoaging and damage induced by UVB rays, and speed up the rate at which the wounded location heals in vivo using Balb/c mice. In the mechanism, Ato markedly decreased the expression of p-p38, p-p65, p-mTOR in vivo and in vitro, suggesting that it may act on Mitogen-activated protein kinase (MAPK), Nuclear factor κB (NF- κB) and Mammalian target of rapamycin (mTOR) signaling pathways to produce above marked effects. In conclusion, Ato obviously relieved UVB-induced photoaging and damage, thus providing evidence for its potential in mitigating skin aging caused by ultraviolet radiation.

Coptisine enhances the sensitivity of chemoresistant breast cancer cells by inhibiting the function and expression of ABC transporters

BackgroundMultidrug resistance (MDR), mainly caused by ATP-binding cassette transporters (ABCTs) efflux, makes it difficult for many anticancer drugs to treat breast cancer (BC). Phytochemicals can reverse cancer’s MDR by modifying ABC transporter expression and function, as well as working synergistically with anticancer drugs to target other molecules. The reversal effect of the isoquinoline alkaloid coptisine (COP) was assessed on four breast cell lines; Two sensitive MCF-7 cell lines with positive estrogen, androgen, progesterone, and glucocorticoid receptors, as well as MDB-MB-231 cells with negative estrogen, progesterone, and HER2 receptors, and two doxorubicin-resistant cell lines, MCF-7/ADR and MDB-MB-231/ADR.MethodsThe cytotoxicity of COP and its ability to improve doxorubicin (DOX) cytotoxicity were assessed using the MTT assay. The effectiveness of COP in reversing DOX resistance was evaluated by calculating resistance ratio (RR) values, combination index (CI), and isobologram (IB). The inhibitory effect of COP on ABCT efflux function in comparison to verapamil (VER) was evaluated by measuring the cellular accumulation of Rho123 using flow cytometry. The impact of COP, either alone or in combination with DOX, on the gene expression of ABCTs (P-gp/MDR1, BCRP, and MRP1) of investigated cell lines was assessed by RT-PCR.ResultsThe COP showed modest cytotoxicity on the examined cell lines. In MCF-7/ADR and MDA-MB-231/ADR cells, COP (31 μM) enhanced DOX cytotoxicity with CI (0.77 and 0.75), RR (2.58 and 3.33), and IB suggesting synergism. COP significantly inhibits ABCT function in resistant BC cell lines, increases Rho123 accumulation, and decreases efflux more than VER; 2.1 and 1.2-fold, respectively. The combination of COP and DOX had a strong inhibitory effect on ABCT function (3.1 and 3.9 times VER, P&amp;lt; 0.001) and downregulated the genes and protein expression of ABCT.ConclusionCOP reversed ABCT-mediated multidrug resistance in vitro, indicating its potential as a multidrug resistance-reversing agent in cancer chemotherapy.

Emerging Trends in Quinoxaline‐Based Analogs as Protein Kinase Inhibitors: Structural Developments and SAR Insights

AbstractCancer remains a leading cause of mortality and has been recognized as a significant global health concern. Although numerous effective anticancer agents are available; most of the current drugs lack specificity, leading to common side‐effects associated with chemotherapy. Recent research, however, offers promise for developing more targeted and safer anticancer therapies through protein kinase inhibition. Quinoxaline derivatives represent a notable class of heterocyclic compounds. The extensive spectrum of biological activities demonstrated by quinoxalines has garnered substantial research interest. Quinoxaline and its derivatives have emerged as a novel class of chemotherapeutic agents with significant activity against various tumors through protein kinase inhibition. This review aims to elucidate recent advancements in the quinoxaline derivatives targeting protein kinase along with structural developments and structure‐activity relationships associated with these compounds.

The In Vitro Cytotoxic Effect of Elesclomol on Breast Adenocarcinoma Cells Is Enhanced by Concurrent Treatment with Glycolytic Inhibitors

Background/Objectives: Glycolysis and mitochondrial oxidative phosphorylation are the two major metabolic pathways for cellular ATP production. The metabolic plasticity displayed by cancer cells allows them to effectively shift between each of these pathways as a means of adapting to various growth conditions, thus ensuring their survival, proliferation and disease progression. Metabolic plasticity also provides cancer cells with the ability to circumvent many traditional monotherapies aimed at only one or the other of the major ATP-producing pathways. The purpose of this study was to determine the effectiveness of a dual treatment strategy aimed simultaneously at both pathways of ATP production in human breast cancer cells. It was hypothesized that concurrent exposure of these cells to the mitochondria-targeting chemotherapeutic agent, elesclomol, in combination with either of two glycolytic inhibitors, 2-deoxy-D-glucose or 3-bromopyruvate, would yield greater in vitro anticancer effects than those observed for any of the compounds used as a single agent. Methods: Cytotoxicity and clonogenic assays were employed to assess the survival and proliferation of MCF7 and MDA-MB-231 human breast adenocarcinoma cells exposed to the compounds alone and in combination. Results: The data obtained show that the cancer-cell-killing and antiproliferative effects of the dual treatment were significantly enhanced compared to those observed for any of the compounds alone. Conclusions: The results of this study are important in that they suggest the possibility of a novel and effective chemotherapeutic strategy for breast cancer cell killing.

High-Throughput Drug Screening in Chondrosarcoma Cells Identifies Effective Antineoplastic Agents Independent of IDH Mutation

The term chondrosarcoma refers to a rare and heterogeneous group of malignant cartilaginous tumors that are typically resistant to chemotherapy and radiotherapy. Metastatic chondrosarcoma has a poor prognosis, and effective systemic therapies are lacking. Isocitrate dehydrogenase (IDH) mutations represent a potential therapeutic target, but IDH inhibitors alone have shown limited clinical efficacy to date. Although the role of conventional chemotherapy is still subject to debate, some evidence suggests it may provide therapeutic benefits in advanced cases. In this study, we aimed to identify effective compounds for combination therapy in chondrosarcoma. Using high-throughput screening, we evaluated a panel of anticancer agents in IDH1-mutant chondrosarcoma cell lines and their mutant IDH1 knockout derivatives. The top 20 most potent compounds were identified across all cell lines, irrespective of IDH mutation status. Representative drugs selected for further investigation included docetaxel, methotrexate, panobinostat, idarubicin, camptothecin, and pevonedistat. These drugs inhibited colony formation, induced apoptosis and cell cycle arrest, and exhibited synergistic antitumor activity in two-drug combinations. In conclusion, we identified several highly effective agents with potent anti-tumor activity in chondrosarcoma cells, independent of IDH mutation status. These agents represent promising candidates for chondrosarcoma therapy and warrant further preclinical investigation and potential inclusion in clinical trials.

Catalytic Intermolecular Asymmetric [2π + 2σ] Cycloadditions of Bicyclo[1.1.0]butanes: Practical Synthesis of Enantioenriched Highly Substituted Bicyclo[2.1.1]hexanes.

The high percentage of sp3-hybridized carbons and the presence of chiral carbon centers could contribute to increased molecular complexity, enhancing the likelihood of clinical success of drug candidates. Three-dimensional (3D) bridged motifs have recently garnered significant interest in medicinal chemistry. Bicyclo[2.1.1]hexanes (BCHs) are emerging 3D benzene bioisosteres, but the synthesis of chiral, highly substituted BCHs has been underexplored. Herein, we disclose the Lewis acid-catalyzed asymmetric intermolecular [2π + 2σ] cycloaddition of bicyclo[1.1.0]butanes with coumarins, 2-pyrone, or chromenes to access diverse enantioenriched 1,2,3,4-tetrasubstituted BCHs bearing vicinal tertiary-quaternary stereocenters. The key to success is the introduction of chiral bisoxazoline ligands to effectively suppress the side reactions, inhibit significant racemic background reactions, and fine-tune the reactivity and regio-, enantio-, and diastereoselectivities of the reactions. The resulting BCHs hold significant potential as benzene bioisosteres in the synthesis of chiral BCHex-Sonidegib and BCHex-BMS-202, mimicking the anticancer drug Sonidegib and the PD-1/PD-L1 inhibitor BMS-202, respectively. The outcome highlights the positive impact of bioisosteric replacement on physicochemical properties, while maintaining comparable antitumor activity to their aryl-containing counterparts.

A minimalist multifunctional nano-prodrug for drug resistance reverse and integration with PD-L1 mAb for enhanced immunotherapy of hepatocellular carcinoma

Clinical treatment of hepatocellular carcinoma (HCC) with 5-fluorouracil (5-FU), the primary anticancer agent, remains unsatisfactory due to the glutathione (GSH)-associated drug resistance and immunosuppressive microenvironment of HCC. To develop a facile yet robust strategy to overcome 5-FU resistance for enhanced immunotherapy treatment of HCC via all dimensional GSH exhaustion, we report in this study construction of a minimalist prodrug consisting of 5-FU linked to an indoleamine-(2,3)-dioxygenase (IDO) inhibitor (IND) via a disulfide bridge, FU-SS-IND that can further self-assemble into stabilized nanoparticles, FU-SS-IND NPs. Specifically, besides the disulfide linker-induced GSH exhaustion, IND inhibits GSH biosynthesis and enhances the effector function of T cells for turning a “cold” tumor to a “hot” one, which synergistically achieving a tumor inhibition rate (TIR) of 92.5% in a 5-FU resistant mice model. Most importantly, FU-SS-IND NPs could upregulate programmed death ligand 1 (PD-L1) expression on the surface of tumor cells, which enables facile combination with immune checkpoint blockade (ICB) for a ultimate prolonged survival lifetime of 5-FU-resistant tumors-bearing mice. Overall, the minimalist bioreducible nano-prodrug developed herein demonstrates great translatable potential for efficiently reversing drug resistance and enhancing immunotherapy of HCC.

Doxorubicin synergizes bortezomib-induced multiple myeloma cell death by inhibiting aggresome formation and augmenting endoplasmic reticulum/Golgi stress and apoptosis

BackgroundBortezomib is a standard treatment for multiple myeloma (MM), working by the accumulation of toxic misfolded proteins in cancer cells. However, a significant clinical challenge arises from the development of resistance to bortezomib in MM treatment. Aggresome, a subcellular structure enclosed within Vimentin, forms in response to proteasome inhibitors and sequesters misfolded proteins that are transported by histone deacetylase 6 (HDAC6) and Dynein for degradation via autophagy, thereby reducing bortezomib’s cytotoxic effects. Therefore, in this study, we screened several anticancer agents to identify those that could synergize with bortezomib to enhance cell death and block aggresome formation in the MM cell line U266B1.MethodsTo enhance bortezomib’s efficacy, we screened a range of anticancer compounds for their potential to promote cell death and inhibit aggresome formation in U266B1 MM cells. We utilized the trypan blue exclusion assay and immunofluorescence for evaluation, and explored the underlying mechanisms through Western blot analysis.ResultsDoxorubicin enhanced bortezomib-induced cytotoxicity while inhibiting aggresome formation. Mechanistic studies revealed that doxorubicin downregulated key aggresome components, including Vimentin, HDAC6, and Dynein, leading to accumulation of misfolded proteins and augmentation of proapoptotic and necroptotic pathways by intensifying endoplasmic reticulum (ER) and Golgi stress responses. Notably, doxorubicin did not enhance cell death triggered by proteasome inhibitors that do not induce aggresome formation. Furthermore, the combination of bortezomib and doxorubicin failed to produce synergy in the killing of MM cell lines that lacked aggresome-forming ability.ConclusionsDoxorubicin enhances bortezomib-induced cell death in MM by inhibiting aggresome formation and amplifying ER/Golgi stress and apoptosis. This study highlights the potential therapeutic benefits of combining bortezomib with doxorubicin for MM treatment.Graphical

Computational investigation of naturally occurring anticancer agents in regulating Hedgehog pathway proteins.

Embryonic development in humans is controlled by the Hedgehog pathway, which becomes inactive in mature tissues. Except for tissue maintenance and healing, activation of this pathway results in tumorigenesis with only a few exceptions. The drugs currently in use have shown no effectiveness in blocking the key proteins responsible for tumorigenesis. Therefore, it is crucial to find new inhibitors that can stop the abnormal activation of the pathway. A preliminary Insilco screening of naturally occurring compounds was carried out to identify potential inhibitors of the pathway. Docking of seventeen naturally occurring antitumorigenic compounds against the four key proteins of the regulatory proteins of the Hedgehog pathway using AutoDock v4.2.6 software was carried out. Liriodenine exhibited the strongest binding affinity towards three out of the four regulatory proteins (-7.61 kcal/mol with Smoothened, -8.14 kcal/mol with Patched-I, and -6.15 kcal/mol with Gli-II) of the Hedgehog pathway, whereas 2',4-dihydroxy-3-methoxychalcone displayed the highest binding affinity of -7.04 kcal/mol with the Sonic Hedgehog protein. Additional molecular dynamic simulation was conducted using Gromacs with Liriodenine and 2',4-dihydroxy-3-methoxy chalcone. Every protein-ligand complex underwent simulation using v5.1.4 software for a duration of 100 nanoseconds. The findings from the simulation indicate that Liriodenine and 2',4-dihydroxy-3-methoxy chalcone form a strong bond with their corresponding protein. Our findings show that the two aforementioned molecules have potential as new inhibitors of the pathway and should be further investigated in both invitro and in vivo experiments.

TIP60 enhances cisplatin resistance via regulating ΔNp63α acetylation in SCC

Non-melanoma skin cancer, including basal and squamous cell carcinoma, is the most common form of cancer worldwide, with approximately 5.4 million new cases diagnosed each year in the United States. While the chemotherapeutic drug cisplatin is often used to treat squamous cell carcinoma (SCC) patients, low response rates and disease recurrence are common. In this study, we show that TIP60 and ΔNp63α levels correlate with cisplatin resistance in SCC cell lines, suggesting that TIP60 contributes to the failure of platinum-based drugs in SCC by regulating the stability and transcriptional activity of ΔNp63α. Depletion of endogenous TIP60 or pharmacological inhibition of TIP60 led to a decrease in ΔNp63α protein and acetylation levels in multiple SCC cell lines. We showed that TIP60 upregulates ΔNp63α protein levels in cisplatin-resistant SCC cell lines by protecting it from cisplatin-mediated degradation and increasing its protein stability. Stable expression of TIP60 or ΔNp63α individually promoted resistance to cisplatin and reduced cell death, while loss of either TIP60 or ΔNp63α induced G2/M arrest, increased cell death, and sensitized cells to cisplatin. Moreover, pharmacological inhibition of TIP60 reduced acetylation of ΔNp63α and sensitized resistant cells to cisplatin. Taken together, our study indicates that TIP60-mediated stabilization of ΔNp63α increases cisplatin resistance and provides critical insights into the mechanisms by which ΔNp63α confers cisplatin resistance by promoting cell proliferation and inhibiting apoptosis. Furthermore, our data suggests that inhibition of TIP60 may be therapeutically advantageous in overcoming cisplatin resistance in SCC and other epithelial cancers.

Development and validation of the Normalized Organoid Growth Rate (NOGR) metric in brightfield imaging-based assays

This study focuses on refining growth-rate-based drug response metrics for patient-derived tumor organoid screening using brightfield live-cell imaging. Traditional metrics like Normalized Growth Rate Inhibition (GR) and Normalized Drug Response (NDR) have been used to assess organoid responses to anticancer treatments but face limitations in accurately quantifying cytostatic and cytotoxic effects across varying growth rates. Here, we introduce the Normalized Organoid Growth Rate (NOGR) metric, specifically developed for brightfield imaging-based assays. A label-free image analysis model was applied to segment organoids precisely, track their growth rates over time, and classify viable and dead organoids. Testing eleven phenotypically distinct pancreatic cancer organoid models with five chemotherapeutics demonstrates that the NOGR metric more effectively captures cytostatic and cytotoxic drug effects compared to existing methods. This approach enhances the biological relevance of drug sensitivity assessments on organoids and offers a valuable tool for advancing personalized cancer treatment strategies.