Induce Cancer Cell Death Research Articles

Green synthesis and in vitro photodynamic efficacy of hypericin: Cytotoxicity assessment on MCF-7 breast cancer cells

Photodynamic therapy (PDT) is a minimally invasive therapy for treating cancers, infectious diseases and several other conditions. It uses light as an activator and component called photosensitizer. Hypericin is a natural photosensitizer which garnered a lot of attention due to its potential use in PDT for cancer treatment. Historically, hypericin has been used for millennia in herbal therapy because of its antiviral and antidepressant properties. However, the traditional synthesis of hypericin requires certain chemicals that are harmful to the environment and human health. To overcome this problem, scientists have been working towards the developing a green synthesis approach for producing hypericin. This study focuses on the green synthesis and assessment of the photosensitizer hypericin from the dried leaves of Hypericum perforatum (St. John's Wort) and its photodynamic efficacy were evaluated in vitro using MCF7 breast cells. An eco-friendly method was employed for extracting and purifying the hypericin.. This green synthesis approach uses fewer chemicals and solvents that minimize the hazard to the environment and health. The formation of hypericin was characterized using FTIR and UV–Vis-NIR spectrophotometers and the morphology was analyzed by HRTEM. The FTIR spectrum confirmed the presence of hydroxyl and carbonyl groups and the UV–Vis-NIR peaks exhibited the characterstic absorption peak at 589 nm. The spherical shaped morphology was seen in HRTEM. As hypericin is hydrophobic in nature, polyvinylpyrrolidone (PVP), a biodegradable, non-toxic material makes the former hydrophilic by producing hypericin-PVP compound. MTT assay and AO-EB staining assay established that hypericin exhibited the highest cell death in MCF7 cancer cells via apoptosis. The results demonstrate hypericin's efficacy in inducing cancer cell death through apoptosis and oxidative stress. Thus, hypericin proved its potential to be a promising natural photosensitizer in the future.

Abstract I005: Exploiting the immunoregulatory effect of double-stranded RNAs for cancer therapeutics

Abstract Introns are found in all eukaryotes and are one of the defining characteristics of eukaryotes. After transcription, pre-mRNAs undergo splicing, and introns are excised in the lariat structure. Since excised introns are degraded quickly after debranching, they have been considered as byproducts of gene expression, and their post-splicing role in the cells remains unclear. Here, we find that the inhibition of intron debranching process by depleting a debranching enzyme, DBR1, results in hyperactivation of protein kinase R (PKR) due to accumulation of intron lariat-derived transposable elements (TEs) that can adopt double-stranded secondary structure. Through in vitro PKR-binding assay, we show that PKR strongly binds to intron lariat RNAs harboring TEs, especially inverted Alu repeats. Interestingly, these TE-containing lariat RNAs are retained in the nucleus, but are released to the cytosol during mitosis, where they activate PKR, resulting in aberrant mitotic progression and apoptosis. We further exploit the lariat RNA-PKR interaction during mitosis and show that DBR1 depletion and anti-mitotic chemotherapy drugs can synergistically induce cancer cell death both in vitro and in vivo. Lastly, we perform docking simulation-based screening of DBR1-inhibitory small molecules. Collectively, our findings underscore the significance of intron turnover in avoiding innate immune activation and further suggest a potential strategy to enhance the efficacy of anti-mitotic drugs by targeting intron processing. Citation Format: Keonyong Lee, Jayoung Ku, Tria Asri Widowati, Namwook Kim, Soo Young Park, Han Suk Ryu,Yoosik Kim. Exploiting the immunoregulatory effect of double-stranded RNAs for cancer therapeutics [abstract]. In: Proceedings of the AACR Special Conference in Cancer Research: RNAs as Drivers, Targets, and Therapeutics in Cancer; 2024 Nov 14-17; Bellevue, Washington. Philadelphia (PA): AACR; Mol Cancer Ther 2024;23(11_Suppl):Abstract nr I005.

Tumor integrin-targeted glucose oxidase enzyme promotes ROS-mediated cell death that combines with interferon alpha therapy for tumor control.

While heightened intratumoral levels of reactive oxygen species (ROS) are typically associated with a suppressive tumor microenvironment, under certain conditions ROS contribute to tumor elimination. Treatment approaches, including some chemotherapy and radiation protocols, increase cancer cell ROS levels that influence their mechanism of cell death and subsequent recognition by the immune system. Furthermore, activated myeloid cells rapidly generate ROS upon encounter with pathogens or infected cells to eliminate disease, and recently, this effector function has been noted in cancer contexts as well. Collectively, ROS-induced cancer cell death may help initiate adaptive anti-tumor immune responses that could synergize with current approved immunotherapies, for improved control of solid tumors. In this work, we explore the use of glucose oxidase, an enzyme which produces hydrogen peroxide, a type of ROS, to therapeutically mimic the endogenous oxidative burst from myeloid cells to promote antigen generation within the tumor microenvironment. We engineer the enzyme to target pan-tumor expressed integrins both as a tumor-agnostic therapeutic approach, but also as a strategy to prolong local enzyme activity following intratumoral administration. We found the targeted enzyme potently induced cancer cell death and enhanced cross-presentation by dendritic cells in vitro, and further combined with interferon alpha for long-term tumor control in murine MC38 tumors in vivo. Optimizing the single-dose administration of this enzyme overcomes limitations with immunogenicity noted for other pro-oxidant enzyme approaches. Overall, our results suggest ROS-induced cell death can be harnessed for tumor control, and highlight the potential use of designed enzyme therapies alongside immunotherapy against cancer.

Immunogenic properties of nickel-doped maghemite nanoparticles and the implication for cancer immunotherapy

Nanoparticles are commonly used in diagnostics and therapy. They are also increasingly being implemented in cancer immunotherapy because of their ability to deliver drugs and modulate the immune system. However, the effect of nanoparticles on immune cells involved in the anti-tumor immune response is not well understood. The study reported here showed that nickel-doped maghemite nanoparticles (FN NP) are differentially cytotoxic to cultured mouse and human cancer cell lines, causing their death without negatively impacting the subsequent anticancer immune response. It also found that FN NP induced cell death in the mouse colorectal cancer cell line CT26 and human prostate cancer cell line PC-3, but not in the human prostate cancer cell line LNCaP. The induced cancer cell death did not affect the phenotype and responsivity of the isolated mouse peritoneal macrophages, or ex vivo-generated mouse bone marrow-derived, or human monocyte-derived dendritic cells. Additionally, the induced cancer cell death did not prevent the ex vivo-generated mouse or human dendritic cells from stimulating lymphocytes and enriching cell cultures with cancer cell-reactive T-cells. In conclusion, this study shows that FN NP could be a valuable platform for targeting cancer cells without causing immunosuppressive effects on the subsequent anticancer immune response.

Emerging Role of Gene Therapy in Cancer

Cancer is one of the leading causes of death in the world, and researchers have been persistently studying the treatment of cancer. Although traditional treatment methods such as surgery, chemotherapy and radiotherapy are effective, they are often accompanied by serious side effects, drug resistance or limited effects on certain types of cancer. Therefore, it is urgent to develop more accurate and effective treatment plans. Cancer gene therapy is an innovative method to treat or prevent cancer by introducing or editing genetic material. Gene therapy brings new hope to the treatment of cancer, repairing mutant genes, activating the immune system or directly inducing cancer cell death. This review introduces some hot strategies of cancer gene therapy, including suicide gene therapy, tumor suppressor gene activation, immunotherapy, inhibition of oncogene activation, antiangiogenic gene therapy. The principles, application examples and advantages and disadvantages of these therapies in clinical research are also discussed. In addition, the challenges faced by gene therapy in improving safety and reducing side effects, and points out the direction of future research are also described, aiming to promote the transformation of these innovative therapies into conventional clinical applications.

Antineoplastic with DNA fragmentation assay and anti-oxidant, anti-inflammatory with gene expression activity of Lactobacillus plantarum isolated from local Egyptian milk products

Many lactic acid bacteria (LAB), known for their human health benefits, are derived from milk and utilized in biotherapeutic applications or for producing valuable nutraceuticals. However, the specific role of milk-associated LAB in biotherapeutics remains underexplored. To address this, eight milk product samples were randomly selected from the Egyptian market, diluted, and then cultured anaerobically on MRS agar. Subsequently, 16 suspected LAB isolates were recovered and underwent rapid preliminary identification. Among these isolates, the Lactobacillus plantarum strain with accession number (OQ547261.1) was identified due to its strong antioxidant activity depending on the DPPH assay, L. plantarum displayed notable antioxidant activities of 71.8% and 93.8% at concentrations of 125–1000 µg/mL, respectively. While ascorbic acid showed lower concentrations of 7.81, 3.9, and 1.95 µg/mL which showed activities of 45.1%, 34.2%, and 27.2%, respectively. The anti-inflammatory efficacy of L. plantarum was evaluated based on its capability to prevent hemolysis induced by hypotonic conditions. At a concentration of 1000 µg/mL, L. plantarum could reduce hemolysis by 97.7%, nearly matching the 99.5% inhibition rate achieved by the standard drug, indomethacin, at an identical concentration. Moreover, L. plantarum exhibited high hemolytic activity at 100 µg/mL (14.3%), which decreased to 1.4% at 1000 µg/mL. The abundance of phenolic acids and flavonoids was determined by high-performance liquid chromatography (HPLC) in L. plantarum. Real-time quantitative reverse transcription polymerase chain reaction (qRT-PCR) demonstrated that L. plantarum increased gene expression of the inflammatory marker TLR2 by 133%, and cellular oxidation markers SOD1 and SOD2 by 65% and 74.2%, respectively, while suppressing CRP expression by 33.3%. These results underscore L. plantarum’s exceptional anti-inflammatory and antioxidant activities. Furthermore, L. plantarum induces cancer cell death through necrotic nuclear DNA fragmentation. These findings suggest that L. plantarum is not only suitable for nutraceutical production but also holds potential as a probiotic strain. Future research should focus on enhancing the capacity of this strain across various industries and fostering innovation in multiple fields.

Evaluating STING Agonist Impact on Kaposi’s Sarcoma-Associated Virus-related Cancers

Kaposi’s sarcoma-associated herpesvirus (KSHV) is an etiological agent of multiple malignancies associated with compromised immunity, such as Kaposi’s sarcoma (KS) and Primary Effusion Lymphoma (PEL). KSHV infection is lifelong with no available treatment or vaccines and poses a high risk to immunocompromised individuals. The virus is transmitted via the oral and sexual route, and has a biphasic life cycle with a short lytic replication cycle followed by long-term latency, with the expression of few genes making detection difficult. Reactivation from latency results in a cascade of viral gene expression and pathogenesis. Critical to controlling KSHV infection is the cGAS-STING DNA-sensing pathway (STING), known to activate the type I interferon response and induce cancer cell death or growth inhibition. STING exhibits both anti-viral and anti-tumor responses, showing promise as a protein of interest to study for the development of a therapeutic treatment. By examining the in vitro effectiveness of STING agonists in inhibiting KSHV oncogenesis in PEL, the study aimed to provide the foundation for a potential novel therapeutic approach. Six patient-derived PEL cell lines were treated with the STING agonist diaminobenzamidazole (diABZI) in a dose-dependent manner. Four of the PEL cell lines exhibited decreased cell growth, viability, and colony formation, while two PEL cell lines were resistant to treatment, correlating with the presence or absence of STING expression. RNA-sequencing was performed and discovered upregulation of multiple interferon-stimulated genes (ISG) in responsive cell lines. Further investigations will explore STING agonists’ inhibition of PEL oncogenesis in vitro via colony formation and in vivo using a PEL xenograft model with NSG mice. Successful completion of this project will offer insight into potential clinical treatments for targeting KSHV infection and reactivation.

Synergistic Inhibition of Colorectal Cancer Cells by Autocrine Motility Factor Peptide and Glycyrrhetinic Acid.

Anti-cancer peptides are a powerful drug concept that induces cancer cell death through growth inhibition and membrane disruption, providing broad efficacy. The autocrine motility factor (AMF) interacts with the AMF receptor, regulating cancer cell motility, proliferation, metastasis, and angiogenesis through autocrine and paracrine pathways. However, studies verifying the synergistic effect of the combined use of anti-cancer drugs extracted from plants and AMF treatment are insufficient. The effects of AMF-derived peptide sequences were evaluated in HT29 and SW620 colorectal cancer (CRC) cell lines. The study assessed the impact of AMF peptides on cell proliferation, colony formation, the Nicotinamide Adenine Dinucleotide Phosphate/Reduced Nicotinamide Adenine Dinucleotide Phosphate (NADP+/NADPH) ratio, and reactive oxygen species (ROS) generation in these CRC cells. Additionally, the combined effect of AMF peptides and glycyrrhetinic acid (GA), a compound derived from licorice plants, was investigated by analyzing cell proliferation, colony formation, ROS production, and cell cycle progression in CRC cells. AMF peptides significantly inhibited CRC cell growth (p < 0.05), decreased colony formation (p < 0.05), and increased the NADP+/NADPH ratio (p < 0.05) and ROS production (p < 0.001). When combined with GA, AMF peptides enhanced GA's effects on CRC cells, further suppressing cell growth (p < 0.05) and colony formation (p < 0.05) while increasing ROS generation (p < 0.05). The synergy between AMF peptides and GA, derived from licorice plants, suggests the potential for combined peptide-phytochemical therapy for treating CRC.

Integrated stress response plasticity governs normal cell adaptation to chronic stress via the PP2A-TFE3-ATF4 pathway

The integrated stress response (ISR) regulates cell fate during conditions of stress by leveraging the cell’s capacity to endure sustainable and efficient adaptive stress responses. Protein phosphatase 2A (PP2A) activity modulation has been shown to be successful in achieving both therapeutic efficacy and safety across various cancer models. However, the molecular mechanisms driving its selective antitumor effects remain unclear. Here, we show for the first time that ISR plasticity relies on PP2A activation to regulate drug response and dictate cellular survival under conditions of chronic stress. We demonstrate that genetic and chemical modulation of the PP2A leads to chronic proteolytic stress and triggers an ISR to dictate whether the cell lives or dies. More specifically, we uncovered that the PP2A-TFE3-ATF4 pathway governs ISR cell plasticity during endoplasmic reticular and cellular stress independent of the unfolded protein response. We further show that normal cells reprogram their genetic signatures to undergo ISR-mediated adaptation and homeostatic recovery thereby avoiding toxicity following PP2A-mediated stress. Conversely, oncogenic specific cytotoxicity induced by chemical modulation of PP2A is achieved by activating chronic and irreversible ISR in cancer cells. Our findings propose that a differential response to chemical modulation of PP2A is determined by intrinsic ISR plasticity, providing a novel biological vulnerability to selectively induce cancer cell death and improve targeted therapeutic efficacy.

Tumor Microenvironment-Activated In Situ Synthesis of Peroxynitrite for Enhanced Chemodynamic Therapy.

Chemodynamic therapy (CDT) can induce cancer cell death through hydroxyl radicals (·OH) generated from Fenton or Fenton-like reactions. Compared with traditional therapies, CDT effectively overcomes inevitable drug resistance and exhibits low side effects. However, clinical application still faces challenges, primarily due to insufficient ·OH generation and the short-lifetime of ·OH in vivo. To address these challenges, we developed a peroxynitrite (ONOO-)-based CDT nanodrug (DOX@PMOF) composed of MOF-199, NO donor (PArg), and nicotinamide adenine dinucleotide phosphate oxidase 4 (NOX4) activator (doxorubicin, DOX). In DOX@PMOF, MOF-199 serves as both a carrier for loading DOX and a source of Cu+ for triggering CDT. Upon uptake by cancer cells, the high concentration of glutathione (GSH) reduces MOF-199 to Cu+, which then reacts with H2O2 to generate ·OH. Moreover, the released DOX upregulates NOX4 expression, leading to the elevated H2O2 level and thereby promoting a high-efficiency Fenton-like reaction for sufficient ·OH generation. Subsequently, PArg generates abundant NO in response to the tumor microenvironment, leading to a cascade of NO and ·OH for the in situ synthesis of ONOO-. ONOO- is more toxic and has a longer lifetime and diffusion distance than ·OH, resulting in a more effective CDT treatment. To further enhance the in vivo therapeutic effect, we coated DOX@PMOF with a homologous cell membrane to form an active tumor-targeting nanodrug (DOX@MPMOF), which has demonstrated the ability to effectively inhibit tumor growth and metastasis while exhibiting good biosafety.

Exopolysaccharides from the Green Microalga Strain Coelastrella sp. BGV-Isolation, Characterization, and Assessment of Anticancer Potential.

Algal metabolites have been extensively studied as potential anticancer therapeutics. Among them, polysaccharides have attracted much attention because of their beneficial biological effects and safety. In the present research, the chemical characteristics, antitumor, and proapoptotic activities of extracellular polysaccharides (EPS) isolated from a new Bulgarian strain of the green microalga Coelastrella sp. BGV were investigated. A fast and convenient method of precipitation with cold ethanol was used to isolate EPS from the culture medium. The chemical characteristics of the isolated EPS were examined by colorimetric and spectrophotometric analyses, HPSEC-RID and HPLC-UV chromatography, and FT-IR spectroscopy. The results showed that the isolated EPS sample consists of three carbohydrate fractions with different molecular weights (11.5 × 104 Da, 30.7 × 104 Da, and 72.4 × 104 Da, respectively) and contains 7.14 (w/w%) protein. HPLC-UV analysis revealed the presence of galactose and fucose. The total uronic acid content in the sample was 4.5 (w/w%). The IR-FT spectrum of EPS revealed the presence of various functional groups typical of a polysaccharide (or proteoglycan) composed primarily of neutral sugars. The anticancer potential of the obtained EPS was assessed using cell lines with cancerous and non-cancerous origins as in vitro experimental models. The results of the performed MTT assay showed that EPS reduced the viability of the cervical and mammary carcinoma cell lines HeLa and MCF-7, while the control non-cancer cell lines BALB/3T3 and HaCaT were less affected. The HeLa cell line showed the highest sensitivity to the effects of EPS and was therefore used for further studies of its anticancer potential. The ability of EPS to inhibit cancer cell migration was demonstrated by wound-healing (scratch) assay. The cell cycle FACS analysis indicated that the EPS treatment induced significant increases in the sub G1 cell population and decreases of the percentages of cells in the G1, S, and G2-M phases, compared to the control. The fluorescent microscopy studies performed using three different staining methods in combination with Annexin V-FITC flow cytometric analysis clearly demonstrate the ability of EPS to induce cancer cell death via the apoptosis pathway. Moreover, an altered pattern and intensity of the immunocytochemical staining for the apoptosis- and proliferation-related proteins p53, bcl2, and Ki67 was detected in EPS-treated HeLa cancer cells as compared to the untreated controls. The obtained results characterize the new local strain of green microalgae Coelastrella sp. BGV as a producer of EPS with selective antitumor activity and provide an opportunity for further studies of its pharmacological and biotechnological potential.

Investigation of Folate-Functionalized Magnetic-Gold Nanoparticles Based Targeted Drug Delivery for Liver: In Vitro, In Vivo and Docking Studies.

Magnetic nanoparticles used for targeted drug administration present a promising approach in cancer treatment owing to its notable advantages, such as targeted and enhanced encapsulation ability and improved bio protection compared with conventional drug delivery methods. Au shell-iron core nanoparticles (Fe3O4@Au) were manufactured by a chemical process, coated with dextran to encapsulate curcumin, and functionalized for precision drug delivery using folic acid to combat liver cancer. Dynamic light scattering, scanning electron microscopy, transmission electron microscopy, vibrational spectroscopy, and magnetometry were applied to assess the synthesis of the Fe3O4@Au-DEX-CU-FA compound. The mean size, zeta potential, and polydispersity of Fe3O4@Au-DEX-CU-FA were 63.3 ± 2.33 nm, -68.3 ± 1.78 mV, and 0.041 ± 0.008, respectively. Molecular docking models were created to examine the relationship between Fe3O4@Au-CU and BCL-XL, BAK, and to identify potential binding sites. The loading efficiency and release profile tests examined the medication delivery system's ability. MTT assay was subsequently utilized to determine the optimal dosage and therapeutic efficacy of Fe3O4@Au-DEX-CU-FA on cancer SNU-449 and healthy THLE-2 cell lines. Flow cytometry demonstrated that Fe3O4@Au-DEX-CU-FA effectively induced cancer cell death. Fe3O4@Au-DEX-FA showed a regulated release profile of free curcumin at 37 °C and pH values of 7.4 and 5.4. Real-time PCR revealed increased BAK expression and decreased BCL-XL expression. Nude tumor-bearing mice were used for in vivo experiments. Fe3O4@Au-DEX-CU-FA treatment dramatically reduced the swelling size compared with free CU and control treatments. It also resulted in a longer lifespan, expanded splenocyte proliferation, increased IFN-γ levels, and decreased IL-4 levels. The regular cells showed no cytotoxic effect compared with the cancer type, confirming that Fe3O4@Au-DEX-CU-FA maintained its potent anticancer actions. The data suggests that Fe3O4@Au-DEX-CU-FA possesses a promising potential as a therapeutic agent for combating tumors.

Hydroxychloroquine loaded hollow apoferritin nanocages for cancer drug repurposing and autophagy inhibition

Hydroxychloroquine sulfate (HCQ) is currently being repurposed for cancer treatment. The antitumor mechanism of HCQ is inhibition of cellular autophagy, but its therapeutic potential is severely limited by poor solubility, lack of tumor targeting and lower cellular uptake. Therefore, utilization of human H-chain apoferritin (HFn) composed only of heavy subunits is an attractive approach for tumor targeting drug delivery. This study focused on pH-triggered encapsulation of HCQ within the inner cavity of HFn to form HFn@HCQ nanoparticles for tumor-targeted drug delivery. Characterization using a range of techniques has been used to confirm the successful establishment of HFn@HCQ. HFn@HCQ exhibited pH-responsive release behavior, with almost no drug release at pH 7.4, but 80% release at pH 5.0. Owing to its intrinsic binding to transferrin receptor 1 (TfR1), HFn@HCQ was significantly internalized through TfR1-mediated endocytosis, with a 4.4-fold difference of internalization amount across cell lines. Additionally, HFn@HCQ enhanced the antitumor effect against four different cancer cell lines when compared against HCQ alone, especially in TfR1 high-expressing cells, where the inhibitory effect was 3-fold higher than free HCQ. The autophagy inhibition of HFn@HCQ has been demonstrated, which is a major pathway to induce cancer cell death. According to current findings, HFn based drug delivery is a promising strategy to target and kill TfR1 overexpressing tumor cells.

Biomimetic Functional Nanocomplexes for Photothermal Cancer Chemoimmunotheranostics

This study presents a novel multimodal cancer theranostic platform developed using tumor cell‐coated biomimetic carbon nanohorn (CNH) complexes that encapsulate the anticancer drug paclitaxel (PTX). This platform combines photothermal therapy, chemotherapy, and immunotherapy to fight against malignant colorectal cancer. These engineered nanocomplexes are designed to deliver sufficient PTX molecules into a targeted solid tumor in a light‐controllable manner while inducing significant photothermal and antitumor immune responses. The outstanding photothermal conversion property of the CNHs under near‐infrared light enables effective cancer cell ablation and awakening of cytotoxic immune responses. Tumor cell membrane‐coated CNHs show improved water dispersibility, immune evasion, and targeting capabilities alongside enhanced immune activation against tumors. The efficacy of the biomimetic functional CNH nanocomplexes is demonstrated through excellent tumor‐targeting, controlled drug‐releasing behavior, and induction of cancer cell death, contributing to a robust antitumor response. This study provides a promising approach to cancer treatment by integrating multiple therapeutic modalities into a single platform, potentially enhancing treatment efficacy to combat intractable cancer.

Engineering Cells for Cancer Therapy.

ConspectusCells, particularly living cells, serve as natural carriers of bioactive substances. Their inherent low immunogenicity and multifunctionality have garnered significant attention in the realm of disease treatment applications, specifically within the domains of cancer immunotherapy and regenerative tissue repair. Nevertheless, several prominent challenges impede their swift translation into clinical applications, including obstacles related to large-scale production feasibility and high utilization costs. To address these issues comprehensively, researchers have proposed the notion of bionic cells that are synthetically generated through chemical or biosynthetic means to emulate cellular functions and behaviors. However, artificial cell strategies encounter difficulties in fully replicating the intricate functionalities exhibited by living cells while also grappling with the complexities associated with design implementation for clinical translation purposes. The convergence of disciplines has facilitated the reform of living cells through a range of approaches, including chemical-, biological-, genetic-, and materials-based methods. These techniques can be employed to impart specific functions to cells or enhance the efficacy of therapy. For example, cells are engineered through gene transduction, surface modifications, endocytosis of drugs as delivery systems, and membrane fusion. The concept of engineered cells presents a promising avenue for enhancing control over living cells, thereby enhancing therapeutic efficacy while concurrently mitigating toxic side effects and ultimately facilitating the realization of precision medicine.In this Account, we present a comprehensive overview of our recent research advancements in the field of engineered cells. Our work involves the application of biological or chemical engineering techniques to manipulate endogenous cells for therapeutics or drug delivery purposes. For instance, to avoid the laborious process of isolating, modifying, and expanding engineered cells in vitro, we proposed the concept of in situ engineered cells. By applying a hydrogel loaded with nanoparticles carrying edited chimeric antigen receptor (CAR) plasmids within the postoperative cavity of glioma, we successfully targeted tumor-associated macrophages for gene editing, leading to effective tumor recurrence inhibition. Furthermore, leveraging platelet's ability to release microparticles upon activation at injury sites, we modified antiprogrammed death 1 (PD-1) antibodies on their surface to suppress postoperative tumor recurrence and provide immunotherapy for inoperable tumors. Similarly, by exploiting bacteria's active tropism toward sites of inflammation and hypoxia, we delivered protein drugs by engineered bacteria to induce cancer cell death through pyroptosis initiation and immunotherapy strategies. In the final section, we summarize our aforementioned research progress while providing an outlook on cancer therapy and the hurdles for clinical translation with potential solutions or future directions based on the concept of engineered cells.

Preparation, Characterisation and Bioactivity Evaluation of Curcumin-Loaded Poly (Lactic-co-Glycolic Acid) Nanoparticles

Background: One of the main challenges with curcumin is its hydrophobic nature, which limits its solubility and bioavailability. This issue can be addressed by using poly (lactic-co-glycolic acid) (PLGA) nanoparticles (NPs). The small size and large surface area of these NPs significantly enhance drug delivery systems by improving the solubility and bioavailability of the drug. Objective: This project focuses on the preparation, characterization, and bioactivity evaluation of curcumin loaded in PLGA NPs, intended for the delivery of curcumin extracted from Curcuma xanthorrhiza, commonly known as ‘temulawak’ or ‘Java turmeric’. Methodology: Curcumin was extracted and stored at 4?C for testing. PLGA-curcumin NPs were synthesized using the single emulsion method. Nanoparticle morphology was analyzed using SEM, while particle size and zeta potential were measured with a Zetasizer. Entrapment efficiency and drug loading capacity were calculated. In vitro release studies in phosphate buffer were conducted using UV-visible spectrophotometry. The cytotoxicity of the curcumin-loaded NPs was tested on MCF-7 breast cancer cells using the MTT assay. Statistical analyses were performed using Minitab 14, and Microsoft Excel was used for graphical representations, with significance set at p &lt; 0.05. Results: The mean particle size of the curcumin NPs was 498.9 nm ± 597.4 nm. The entrapment efficiency and drug loading capacity were 50% and 5%, respectively. The average zeta potential was recorded as -28.7 mV ± 6.19 mV. The in vitro release study did not produce significant results as low concentrations of curcumin were detected. However, the bioactivity of the curcumin-loaded PLGA NPs demonstrated lower cell viability compared to the curcumin extract, suggesting that the PLGA formulation is more effective at inducing cancer cell death. This indicates its potential as a more efficient therapeutic option in cancer treatment. Conclusion: The single emulsion method managed to produce nano-sized particles with good zeta potential and bioactivity on MCF-7 cells. However, further study needs to be done to produce better formulation which can increase entrapment efficiency, drug loading capacity and also in vitro release profile.

Redox-active vitamin C suppresses human osteosarcoma growth by triggering intracellular ROS-iron–calcium signaling crosstalk and mitochondrial dysfunction

Pharmacological vitamin C (VC) has gained attention for its pro-oxidant characteristics and selective ability to induce cancer cell death. However, defining its role in cancer has been challenging due to its complex redox properties. In this study, using a human osteosarcoma (OS) model, we show that the redox-active property of VC is critical for inducing non-apoptotic cancer cell death via intracellular reactive oxygen species (ROS)-iron-calcium crosstalk and mitochondrial dysfunction. In both 2D and 3D OS cell culture models, only the oxidizable form of VC demonstrated potent dose-dependent cytotoxicity, while non-oxidizable and oxidized VC derivatives had minimal effects. Live-cell imaging showed that only oxidizable VC caused a surge in cytotoxic ROS, dependent on iron rather than copper. Inhibitors of ferroptosis, a form of iron-dependent cell death, along with classical apoptosis inhibitors, were unable to completely counteract the cytotoxic effects induced by VC. Further pharmacological and genetic inhibition analyses showed that VC triggers calcium release through inositol 1,4,5-trisphosphate receptors (IP3Rs), leading to mitochondrial ROS production and eventual cell death. RNA sequencing revealed down-regulation of genes involved in the mitochondrial electron transport chain and oxidative phosphorylation upon pharmacological VC treatment. Consistently, high-dose VC reduced mitochondrial membrane potential, oxidative phosphorylation, and ATP levels, with ATP reconstitution rescuing VC-induced cytotoxicity. In vivo OS xenograft studies demonstrated reduced tumor growth with high-dose VC administration, concomitant with the altered expression of mitochondrial ATP synthase (MT-ATP). These findings emphasize VC's potential clinical utility in osteosarcoma treatment by inducing mitochondrial metabolic dysfunction through a vicious intracellular ROS-iron-calcium cycle.

Novel Thiazole-Hydrazide Derivatives and Their Anticancer Properties

Objective: Cancer is described as uncontrolled cell division, and it is a major problem in Türkiye, as well as around the world. Current treatment options are insufficient in some cases, particularly the treatment rate for lung cancer cases, which is very low. Meanwhile, current pharmaceuticals have several side effects, such as drug-drug interactions, and cognitive disorders. Additionally, developing drug resistance is a major problem for current and future management of the disease. Accordingly, the search for new molecules or alternative treatment options is actively achieved. Methods: In this study, eight novel thiazole-hydrazide analogs were designed and synthesized, and their structural elucidation was performed via HRMS, 1H-NMR, and 13C-NMR. Their biological activity profile was investigated on A549 lung carcinoma and MCF7 breast adenocarcinoma cells. To determine the selective cytotoxicity on cancer cells, they were also tested against NIH/3T3 healthy cell line. Besides that, an in silico study was performed to understand the binding modes of the compounds. Results: The results showed that in the serial 4f and 4g, the most bulky analogues, showed no inhibition against any cell type, even at the highest concentration tested. On the other hand, 4a, 4b, 4d, 4e, and 4h showed less cytotoxicity on healthy cells than A549 cells, so they exhibited significant cytotoxicity and a selective profile against A549 cancer cells. While they also inhibited MCF7 cells. The major point is that para-chlorophenyl analogs at the fourth position on thiazole (4a and 4d) displayed a better anticancer profile than ortho-chlorophenyl analogs. These two compounds were also investigated for their apoptotic effects using in silico studies. Both experimental and in silicon studies revealed that the combination of thiazole and hydrazinoacetyl has a significant impact against cancer cells, and in silico study also suggested that tri-substitute thiazole ring has anticancer potential that induced cancer cell death via apoptosis. Conclusion: Results of this study was presented that compound 4a was the most potent compound against lung cancer cells (A549) and 4d was the most potent compound against breast cancer cells (MCF-7). Furthermore, analyzing the molecular docking study for promising compounds (4a and 4d) suggested that interactions with the loop region residues have a pivotal role in inducing caspase-3 enzyme activity. It was concluded that hybridization of thiazole and hydrazinoacetyl moieties is responsible for the anticancer activity.

T cell receptor-directed antibody-drug conjugates for the treatment of T cell-derived cancers

T cell-derived cancers are hallmarked by heterogeneity, aggressiveness, and poor clinical outcomes. Available targeted therapies are severely limited due to a lack of target antigens that allow discrimination of malignant from healthy T cells. Here we report a novel approach for the treatment of T cell diseases based on targeting the clonally rearranged T cell receptor displayed by the cancerous T cell population. As a proof of concept, we identified an antibody with unique specificity towards a distinct TCR and developed antibody-drug conjugates, precisely recognizing and eliminating target T cells while preserving overall T cell repertoire integrity and cellular immunity. Our anti-TCR antibody-drug conjugates demonstrated effective receptor-mediated cell internalization, associated with induction of cancer cell death with strong signs of apoptosis. Furthermore, cell proliferation-inhibiting bystander effects observed on target-negative cells may contribute to the molecules’ anti-tumor properties precluding potential tumor escape mechanisms. To our knowledge, this represents the first anti-TCR antibody-drug conjugate designed as custom-tailored immunotherapy for T cell-driven pathologies.

A biochemical assessment of apoptosis-inducing impact of Salinomycin in combination with ciprofloxacin on human leukemia KG1-a stem-like cells in the presence and absence of insulin.

Acute Myeloid Leukemia (AML) is a fast-developing invading cancer that impacts the blood and bone marrow, marked by the rapid proliferation of abnormal white blood cells. Chemotherapeutic agents, a primary treatment for AML, encounter clinical limitations such as poor solubility and low bioavailability. Previous studies have highlighted antibiotics as effective in inducing cancer cell death and potentially preventing metastasis. Besides, insulin is known to activate the PI3K/Akt pathway, often disrupted in cancers, leading to enhanced cell survival and resistance to apoptosis. In light of the above-mentioned points, we examined the anti-cancer impact of antibiotics Ciprofloxacin (CP) and Salinomycin (SAL) and their combination on KG1-a cells in the presence and absence of insulin. This was accomplished by exposing KG1-a cells to different doses of CP and SAL alone, in combination, and with or without insulin for 24-72h. Cell viability was evaluated using the MTT assay. Besides, apoptotic effects were examined using Hoechst staining and Annexin-V/PI flow cytometry. The expression levels of Bax, p53, BIRC5, Akt, PTEN, and FOXO1 were analyzed through Real-Time PCR. CP and SAL demonstrated cytotoxic and notable pro-apoptotic impact on KG1-a cells by upregulating Bax and p53 and downregulating BIRC5, leading to G0/G1 cell cycle arrest and prevention of the PI3K-Akt signaling pathway. Our findings demonstrated that combination of CP and SAL promote apoptosis in the KG1-a cell line by down-regulating BIRC5 and Akt, as well as up-regulating Bax, p53, PTEN, and FOXO1. Additionally, the findings strongly indicated that insulin effectively mitigates apoptosis by enhancing Akt expression and reducing FOXO1 and PTEN gene expression in the cells treated with CP and SAL. Our findings showed that the combined treatment of CP and SAL exhibit a strong anti-cancer effect on leukemia KG1-a cells. Moreover, it was discovered that the PI3K-Akt signaling can be a promising target in leukemia treatment particularly in hyperinsulinemia condition.