Target For Anticancer Therapy Research Articles

Heme oxygenase 1 inhibitor discovery and formulation into nanostructured lipid carriers as potent and selective treatment against triple negative metastatic breast cancer

Heme oxygenase-1 (HO-1) has been identified as a potential new target in anticancer therapy, being overexpressed in different tumors and crucial for cell proliferation. Advances in the development of specific HO-1 inhibitors should support the understanding of controlling HO-1 activity as antitumoral strategies, opening the path for future therapeutic applications. In the present study, small series of new HO-1 inhibitors were synthesized by joining a butylimidazolic pharmacophore together with a hydrophobic moiety spaced by a 2-oxybenzamide central linker. The most active and selective HO-1 inhibitor, VP 21–04, 2-(4-(1H-imidazol-1-yl)butoxy)-N-benzyl-5-iodobenzamide (7b) was identified. This ligand showed strong cytotoxic activity against melanoma and breast cancer cell lines. Encapsulation of VP 21–04 in nanostructured lipid carriers (NLC 21–04) was performed to exploit its therapeutic potential by passive-targeting delivery ameliorating water-solubility and toxicity. Interestingly, NLC 21–04 showed a marked antiproliferative effect in both cancer cell lines, and an improved safety profile with a wider therapeutic window when compared to the free drug. Finally, NLC 21–04 showed a marked tumor growth reduction while being safe in an in ovo tumor model, highlighting the therapeutic potential of the developed nanoparticles against triple negative metastatic breast cancer.

Combatting cellular immortality in cancers by targeting the shelterin protein complex

Shelterin proteins (TERF1, TERF2, TPP1, TINF2, POT1) protect telomeres, prevent unwarranted repair activation, and regulate telomerase activity. Alterations in these proteins can lead to cancer progression. This study uses an in-silico approach to examine shelterin in tumour samples across various cancers, employing mutation plots, phylogenetic trees, and sequence alignments. Network pharmacology identified TERF1 as an essential shelterin protein and transcription factors RUNX1, CTCF, and KDM2B as potential biomarkers due to their interactions with miRNAs and shelterin proteins. We performed MCODE analysis to identify subnetworks of ncRNAs interacting with the shelterin proteins. Shelterin expression predicted patient survival in 24 cancer types, with TERF1, TERF2, TINF2, and POT1 significantly expressed in testicular, AML, prostate, breast and renal cancers, respectively, and TPP1 in AML and skin cancer. Spearman and Pearson's analyses showed significant correlations of TERF1 across cancers, with near-significant correlations for all five proteins in different cancer datasets like breast cancer, kidney renal papillary and lung squamous cell carcinoma, skin cutaneous melanoma, etc.,. Shelterin expression correlated with patient survival in breast, renal, lung, skin, uterine, and gastric cancers. Insights into TPP1-associated glycans highlighted glycosylated sites contributing to tumorigenesis. This study provides molecular signatures for further functional and therapeutic research on shelterin, highlighting its potential as a target for anti-cancer therapies and promising prospects for cancer prognosis and prediction.

CD70: An Emerging Anticancer Target in Renal Cell Carcinoma and Beyond.

CD70 is an emerging target for anticancer therapies. It is an ideal antigen target given its limited expression in normal physiologic tissues and propensity to be aberrantly expressed in a variety of malignancies, thus limiting off-target toxicities. It is also heavily involved in immune homeostasis, and disruption of this pathway can help overcome tumor-related immune cell exhaustion. Recent phase I/II trials using cellular therapies targeting CD70, such as chimeric antigen receptor-T cells, have shown promising effectiveness and safety in treating relapsed or refractory renal cell carcinoma. Noncellular therapies targeting CD70, such as antibody-drug conjugates, monoclonal antibodies, radionuclides, and cytokines, are currently under investigation, with early data showing encouraging results as well. Efforts are already underway to further improve and optimize CD70-based therapies.

TMIC-04. SPATIAL SEQUENCING OF MEDULLOBLASTOMA REVEALS BIOLOGICAL NICHES CORRELATED WITH HIGH-RISK FEATURES AND RELAPSE

Abstract Medulloblastoma (MB) defines a heterogeneous set of neuroepithelial cancers of the posterior fossa. The MB tumor microenvironment (MB-TME) influences tumor progression and therapy response and has emerged as a growing target for novel therapeutic approaches. Prior single-cell analysis has characterized the MB-TME composition but does not reveal the spatial orientation of components. To address this gap, we performed 10X Visium spatial sequencing on sixteen pediatric MB samples obtained at surgical resection with samples representing the four molecular subtypes (WNT, N=1; SHH, N=6; Group 3, N=2; Group 4, N=5) and two matching samples at diagnosis and relapse. Spatial voxel clustering yielded clusters corresponding to malignant, immune, and stromal components of the TME, including tumor-associated astrocytes (TAAs), macrophages (TAMs), and vascular endothelium. Ten distinct clusters emerged representing malignant cell states, defined primarily by programs of cell cycle progression and neuronal differentiation. Notably, these MB cell clusters were differentially abundant between the MB subgroups, highlighting heterogeneity between disease subtypes. Moreover, examining the patterns of cellular spatial distribution in high-risk (HR) patients revealed dense regions of quiescent MB progenitors, while standard-risk patients showed greater heterogeneity within their TME. Proximity-dependent intercellular signaling further highlighted increased signaling by TAAs and vascular endothelium with decreased heat shock response signaling in HR patients. Comparing samples from relapse to diagnosis, TAMs, TAAs, and vascular endothelium were found to constitute a greater proportion of the TME. Subsequent niche-dependent gene expression and pathway analysis for TAAs localized near tumor vasculature in relapsed samples revealed increased expression of metastasis-associated pathways. Collectively, the results of our study enable new insight into the heterogeneity of the MB-TME, with close spatial association of quiescent MB progenitors correlating with high-risk clinical features. Quiescent MB progenitors have been documented to confer resistance through cellular dormancy, and identifying its molecular drivers may reveal potential targets for anticancer therapy.

PGRMC1 and PAQR4 are promising molecular targets for a rare subtype of ovarian cancer.

The heterogeneity of ovarian cancer (OC) has made developing effective treatments difficult. Nowadays, hormone therapy plays a growing role in the treatment of OC; however, hormone modulators have had only limited success so far. To provide a more rigorous foundation for hormonal therapy for different OC subtypes, the current study used a series of bioinformatics approaches to analyse the expression profiles of genes encoding membrane progesterone (PGRMC1, progestins and the adipoQ receptor [PAQR] family), and androgen (zinc transporter member 9 [ZIP9], OXER1) receptors. Our work investigated also their prognostic value in the context of OC. We found differences in expression of ZIP9 and OXER1 between different OC subtypes, as well as between patient tumour and normal tissues. Expression of mRNA encoding PAQR7 and PAQR8 in a panel of OC cell lines was below the qPCR detection limit and was downregulated in tumour tissue samples, whereas high expression of PGRMC1 and PAQR4 mRNA was observed in rare subtypes of OC cell lines. In addition, chemical inhibition of PGRMC1 reduced the viability of rare OCs represented by COV434 cells. In conclusion, PGRMC1 and PAQR4 are promising targets for anticancer therapy, particularly for rare subtypes of OC. These findings may reflect differences in the observed responses of various OC subtypes to hormone therapy.

SUMOylation regulates the aggressiveness of breast cancer-associated fibroblasts.

Cancer-associated fibroblasts (CAFs) are the most abundant stromal cellular component in the tumor microenvironment (TME). CAFs contribute to tumorigenesis and have been proposed as targets for anticancer therapies. Similarly, dysregulation of SUMO machinery components can disrupt the balance of SUMOylation, contributing to tumorigenesis and drug resistance in various cancers, including breast cancer. We explored the role of SUMOylation in breast CAFs and evaluated its potential as a therapeutic strategy in breast cancer. We used pharmacological and genetic approaches to analyse the functional crosstalk between breast tumor cells and CAFs. We treated breast CAFs with the SUMO1 inhibitor ginkgolic acid (GA) at two different concentrations and conditioned media was used to analyse the proliferation, migration, and invasion of breast cancer cells from different molecular subtypes. Additionally, we performed quantitative proteomics (SILAC) to study the differential signalling pathways expressed in CAFs treated with low or high concentrations of GA. We confirmed these results both in vitro and in vivo. Moreover, we used samples from metastatic breast cancer patients to evaluate the use of GA as a therapeutic strategy. Inhibition of SUMOylation with ginkgolic acid (GA) induces death in breast cancer cells but does not affect the viability of CAFs, indicating that CAFs are resistant to this therapy. While CAF viability is unaffected, CAF-conditioned media (CM) is altered by GA, impacting tumor cell behaviour in different ways depending on the overall degree to which SUMO1-SUMOylated proteins are dysregulated. Breast cancer cell lines exhibited a concentration-dependent response to conditioned media (CM) from CAFs. At a low concentration of GA (10µM), there was an increase in proliferation, migration and invasion of breast cancer cells. However, at a higher concentration of GA (30µM), these processes were inhibited. Similarly, analysis of tumor development revealed that at 10µM of GA, the tumors were heavier and there was a greater degree of metastasis compared to the tumors treated with the higher concentration of GA (30µM). Moreover, some of these effects could be explained by an alteration in the activity of the GTPase Rac1 and the activation of the AKT signalling pathway. The results obtained using SILAC suggest that different concentrations of GA affected cellular processes differentially, possibly influencing the secretome of CAFs. Treatment of metastatic breast cancer with GA demonstrated the use of SUMOylation inhibition as an alternative therapeutic strategy. The study highlights the importance of SUMOylation in the tumor microenvironment, specifically in cancer-associated fibroblasts (CAFs). Targeting SUMOylation in CAFs affects their signalling pathways and secretome in a concentration-dependent manner, regulating the protumorigenic properties of CAFs.

BMI-1 in Breast Cancer - Biological Role and Clinical Implications.

Breast cancer is the most frequent cancer among women. Despite extensive research in recent years the molecular basis of breast cancer development, growth and metastasis remains unclear. Numerous studies highlight the involvement of BMI-1 in tumorigenesis. BMI-1 protein is a key component of Polycomb Repressive Complex 1, which by ubiquitinylation of histone H2A, regulates expression of genes involved in various cellular processes including cell cycle, proliferation and programmed cell death. Overexpression of BMI-1 has been often associated with breast cancer development and progression. This review summarizes the current state of knowledge of BMI-1's role in breast cancer biology and its potential significance as prognostic marker and potential target of new anticancer therapy.

Strategic Identification of Anti-Cancer Compounds Targeting PARP15 in DNA Repair Pathways for Enhanced Therapeutic Efficacy

Cancer is a significant worldwide health concern that requires effective therapies. Addressing this critical issue necessitates innovative treatment strategies concentrating on the fundamental causes of cancer progression. The PARP15 protein is essential in cancer progression by facilitating DNA repair pathways, making it a promising target for anti-cancer therapies. This investigation relies on computational strategies, including virtual screening and molecular dynamics simulations, to identify potential inhibitors of PARP15 target protein. Three potential compounds (26646684, 104224077, and 17505556) with notable binding affinities and interaction patterns were selected for further investigation. Compound 17505556 shows significant interactions, suggesting more stable conformation throughout the simulation against the target protein. Compound 17505556 exhibited the highest binding free energy (-34.07 kcal/mol), significantly outperforming the reference inhibitor I4X (-26.70 kcal/mol). This strong binding affinity suggests that 17505556 forms stable and sustained interactions with PARP15, making it the most promising inhibitor among those studied. Other compounds, 26646684 (-28.92 kcal/mol) and 104224077 (-26.83 kcal/mol), also demonstrated favorable binding energies, indicating their potential as viable inhibitors. The overall result of the investigation suggests the compound 17505556 as a possible drug candidate for the inhibition of DNA repair protein, offering novel avenues for developing an anti-cancer drug candidate.

In Silico Screening of 1,3,4-Thiadiazole Derivatives as Inhibitors of Vascular Endothelial Growth Factor Receptor-2 (VEGFR-2).

Angiogenesis plays a pivotal role in the growth, survival, and metastasis of solid tumors, with Vascular Endothelial Growth Factor Receptor-2 (VEGFR-2) being overexpressed in many human solid tumors, making it an appealing target for anti-cancer therapies. This study aimed to identify potential lead compounds with azole moiety exhibiting VEGFR-2 inhibitory effects. A ligand-based pharmacophore model was constructed using the X-ray crystallographic structure of VEGFR-2 complexed with tivozanib (PDB ID: 4ASE) to screen the ZINC15 database. Following virtual screening, six compounds demonstrated promising docking scores and drug-likeness comparable to tivozanib. These hits underwent detailed pharmacokinetic analysis to assess their absorption, distribution, metabolism, excretion, and toxicity (ADMET) properties. Furthermore, Density Functional Theory (DFT) analysis was employed to investigate the molecular orbital properties of the top hits from molecular docking. Molecular dynamics (MD) simulations were conducted to evaluate the conformational stability of the complexes over a 100 ns run. Results indicated that the compounds (ZINC8914312, ZINC8739578, ZINC8927502, and ZINC17138581) exhibited the most promising lead requirements for inhibiting VEGFR-2 and suppressing angiogenesis in cancer therapy. This integrated approach, combining pharmacophore modeling, molecular docking, ADMET studies, DFT analysis, and MD simulations, provides valuable insights into the identification of potential anti-cancer agents targeting VEGFR-2.

The mechanism of cytokine regulation of cancer occurrence and development in the tumor microenvironment and its application in cancer treatment: a narrative review.

The occurrence and development of tumors in human tissues widely depend on their surrounding environment, known as the tumor microenvironment (TME), which comprises various cells, molecules, and blood vessels. Through modifications, organization, and integration, these elements serve as potential therapeutic targets in anti-cancer therapy, supporting and promoting the proliferation, invasion, and metabolism of tumor cells. Cytokines within TME are responsible for immune cell activation, proliferation, and differentiation, thereby influencing the tumor's behavior. This article reviews the use of cytokines in tumor immunotherapy and combs the network signals that cytokines mediate in the development of malignancies. A literature search of international sources was carried out on the PubMed and Web of Science databases, using main keywords such as "tumor immunotherapy", "cytokines", "chemokines", "tumor microenvironment", "recombinant cytokine engineering", and "tumor necrosis factor superfamily". The review provides a thorough summary of the functions of tumor necrosis factor superfamilies, chemokines, and interleukins within the TME as well as their therapeutic uses. Their potential as novel targets for tumor treatment is also evaluated. Furthermore, this paper focuses on various feasible strategies for recombinant cytokines reported in recent years, especially the cytokine engineering methods for targeting tumors. Ultimately, this paper contributes to an enhanced understanding among researchers of the mechanisms underlying the impact of the TME on disease development, thereby laying a solid foundation for the future development of new tumor therapies based on cytokines within the TME. Cytokine immunotherapy holds promise on antitumor therapy. It is anticipated that the effectiveness of tumor treatment and the quality of life for tumor patients will continue to improve with ongoing research and development in this field.

Regulation of PI3K signaling in cancer metabolism and PI3K-targeting therapy.

The phosphatidylinositol-3-kinase (PI3K) signaling plays a key role in various cellular functions and is frequently activated in cancer, making it an attractive therapeutic target. The PI3K signaling pathway influencing glucose metabolism, lipid synthesis, nucleotide production, and protein synthesis, all of which contribute to cancer cell proliferation and survival. It enhances glucose uptake through the activation of glucose transporters and glycolysis, while also promoting lipid synthesis via downstream factors like mTORC1. This pathway boosts nucleotide synthesis by regulating transcription factors like MYC, activating key enzymes for purine and pyrimidine production. Additionally, due to its essential role in cancer cell growth, the PI3K pathway is a key target for anticancer therapies. However, treatment using PI3K inhibitors alone has limitations, including drug resistance and significant side effects such as hyperglycemia, fatigue, and liver dysfunction. Clinical trials have led to the development of isoform-specific PI3K inhibitors to reduce toxicity. Combining PI3K inhibitors with other treatments, such as hormone therapy or surgery, may improve efficacy and minimize side effects. Further research is needed to fully understand the mechanisms of PI3K inhibitors and improve individualized treatment approaches. In this review, we introduce the characteristic of three classes of PI3Ks, discuss the regulation of cancer metabolism including the control of glucose uptake, glycolysis, de novo lipid synthesis, nucleotide synthesis and protein synthesis, and review the current statuses of different PI3K inhibitors therapy.

Discovery of organosulfur-based selective HDAC8 inhibitors with anti-neuroblastoma activity

Histone deacetylases (HDACs) are important epigenetic regulators of gene expression and various cellular processes, and are potential targets for anticancer therapy. In particular, HDAC8 is a promising therapeutic target for childhood neuroblastoma. To date, five HDAC inhibitors have been approved as anticancer drugs; however, all are non-selective HDAC inhibitors with various side effects. Furthermore, many promising HDAC inhibitors incorporate hydroxamic acid as a zinc binding group (ZBG), which may be associated with toxicity. Therefore, identification of isoform-selective HDAC inhibitors with novel ZBG is crucial. Here, a series of sulfur-based selective HDAC8 inhibitors featuring a novel ZBG were identified by modifying the early hit, ajoene, a component of garlic. Structure-activity relationship studies uncovered potent and selective HDAC8 inhibitors, and docking studies provided a structural rationale for HDAC8 inhibitory activity. One of the potent compounds, (Z)-1-phenyl-7-(4-methoxyphenyl)-2,3,7-trithiahepta-4-ene-7-oxide (15c), exhibited antiproliferative activity, with a GI50 of 2 µM, against neuroblastoma cell lines. 15c also showed significant in vivo efficacy in a neuroblastoma BE(2)-C xenograft model.

Exosomal miR-502-5p suppresses the progression of gastric cancer by repressing angiogenesis through the Wnt/β-catenin pathway.

Gastric cancer (GC) is a significant global health concern, ranking as the fifth most common cancer and the third leading cause of cancer-related deaths. The role of miR-502-5p in various cancers has been studied, but its specific impact on gastric cancer through exosomes is not well understood. This study aimed to investigate the role and mechanism of exosome-derived miR-502-5p in gastric cancer. Differential expression of miR-502-5p in tissues or serum of GC patients was determined using qRT-PCR. The impact of miR-502-5p on cell proliferation, migration, and invasion was assessed through in vitro and in vivo experiments. The potential of exosome-miR-502-5p to inhibit metastatic ability was also explored by using vivo and vitro assay. Furthermore, the underlying mechanism of miR-502-5p in gastric cancer was investigated using western blotting. It was found that miR-502-5p suppressed the proliferation, migration, and invasion of gastric cancer cells. Exosome-miR-502-5p expression was negatively linked to metastatic ability and demonstrated inhibition of metastasis in vitro and in vivo. Additionally, miR-502-5p appeared to inhibit angiogenesis through the Wnt/β-catenin pathway in gastric cancer. Exosomal miR-502-5p acts as a suppressor in the development and progression of gastric cancer, suggesting its potential as a target for anti-cancer therapy or as a diagnostic biomarker.

Targeting the p90RSK/MDM2/p53 Pathway Is Effective in Blocking Tumors with Oncogenic Up-Regulation of the MAPK Pathway Such as Melanoma and Lung Cancer

In most human tumors, the MAPK pathway is constitutively activated. Since p90RSK is downstream of MAPK, it is often hyperactive and capable of phosphorylating oncogenic substrates. We have previously shown that p90RSK phosphorylates MDM2 at S166, promoting p53 degradation in follicular thyroid carcinomas. Thus, the inhibition of p90RSK restores p53 expression, which in turn inhibits cell proliferation and promotes apoptosis. In the present study, we demonstrated that the p90RSK/MDM2/p53 pathway proved to be an excellent target in the therapy of tumors with MAPK hyperactivation. For this purpose, we selected p53wt melanoma, lung and medullary thyroid carcinoma cell lines with high activation of p90RSK. In these cell lines, we demonstrated that the p90RSK/MDM2/p53 pathway is implicated in the regulation of the cell cycle and apoptosis through p53-dependent transcriptional control of p21 and Bcl-2. Furthermore, with an immunohistochemical evaluation of primary melanomas and lung tumors, which exhibit highly activated p90RSK compared to corresponding normal tissue, we demonstrated that MDM2 stabilization was associated with p90RSK phosphorylation. The results indicate that p90RSK is able to control the proliferative rate and induction of apoptosis through the regulation of p53wt levels by stabilizing MDM2 in selected tumors with constitutively activated MAPKs, making p90RSK a new attractive target for anticancer therapy.

CAVPENET Peptide Inhibits Prostate Cancer Cells Proliferation and Migration through PP1γ-Dependent Inhibition of AKT Signaling.

Protein phosphatase 1 (PP1) complexes have emerged as promising targets for anticancer therapies. The ability of peptides to mimic PP1-docking motifs, and so modulate interactions with regulatory factors, has enabled the creation of highly selective modulators of PP1-dependent cellular processes that promote tumor growth. The major objective of this study was to develop a novel bioactive cell-penetrating peptide (bioportide), which, by mimicking the PP1-binding motif of caveolin-1 (CAV1), would regulate PP1 activity, to hinder prostate cancer (PCa) progression. The designed bioportide, herein designated CAVPENET, and a scrambled homologue, were synthesized using microwave-assisted solid-phase methodologies and evaluated using PCa cell lines. Our findings indicate that CAVPENET successfully entered PCa cells to influence both viability and migration. This tumor suppressor activity of CAVPENET was attributed to inhibition of AKT signaling, a consequence of increased PP1γ activity. This led to the suppression of glycolytic metabolism and alteration in lipid metabolism, collectively representing the primary mechanism responsible for the anticancer properties of CAVPENET. Our results underscore the potential of the designed peptide as a novel therapy for PCa patients, setting the stage for further testing in more advanced models to fully realize its therapeutic promise.

Acid-sensing ion channel 3 is a new potential therapeutic target for the control of glioblastoma cancer stem cells growth

Glioblastoma (GBM) is the most common malignant primary brain cancer that, despite recent advances in the understanding of its pathogenesis, remains incurable. GBM contains a subpopulation of cells with stem cell-like properties called cancer stem cells (CSCs). Several studies have demonstrated that CSCs are resistant to conventional chemotherapy and radiation thus representing important targets for novel anti-cancer therapies. Proton sensing receptors expressed by CSCs could represent important factors involved in the adaptation of tumours to the extracellular environment. Accordingly, the expression of acid-sensing ion channels (ASICs), proton-gated sodium channels mainly expressed in the neurons of peripheral (PNS) and central nervous system (CNS), has been demonstrated in several tumours and linked to an increase in cell migration and proliferation. In this paper we report that the ASIC3 isoform, usually absent in the CNS and present in the PNS, is enriched in human GBM CSCs while poorly expressed in the healthy human brain. We propose here a novel therapeutic strategy based on the pharmacological activation of ASIC3, which induces a significant GBM CSCs damage while being non-toxic for neurons. This approach might offer a promising and appealing new translational pathway for the treatment of glioblastoma.

A Multifunctional Aptamer Decorated Lipid Nanoparticles for the Delivery of EpCAM-targeted CRISPR/Cas9 Plasmid for Efficacious In Vivo Tumor Regression.

Epithelial cell adhesion molecule (EpCAM) gene encodes a type-I trans-membrane glycoprotein that is overexpressed in many cancerous epithelial cells and promotes tumor progression by regulating the expression of several oncogenes like c-myc and other cyclins. Because of this tumorigenic association, the EpCAM gene has been a potential target for anti-cancer therapy in recent days. Herein, it is attempted to knockout the proto-oncogenic EpCAM expression by efficiently delivering an all-in-one Clustered Regularly Interspaced Short Palindromic Repeats (CRISPR) plasmid via a lipid nanoparticle system made out of synthetic stimuli-sensitive lipids. The plasmid possesses the necessary information in the form of a guide RNA targeted to the EpCAM gene. The aptamer decorated system selectively targets EpCAM overexpressed cells and efficiently inhibits the genetic expression. It has explored the pH-responsive property of the developed lipid nanoparticles and monitored their efficacy in various cancer cell lines of different origins with elevated EpCAM levels. The phenomenon has further been validated in vivo in non-immunocompromised mouse tumor models. Overall, the newly developed aptamer decorated lipid nanoparticle system has been proven to be efficacious for the delivery of EpCAM-targeted CRISPR/Cas9 plasmid.

9,10-Bis[(4-(2-hydroxyethyl)piperazine-1-yl)prop2-yne-1-yl]anthracene: G-Quadruplex Selectivity and Anticancer Activity.

G-Quadruplexes (G4s) are appealing targets for anticancer therapy because of their location in the genome and their role in regulating physiological and pathological processes. In this article, we report the characterization of the molecular interaction and selectivity of OAF89, a 9,10-disubstituted G4-binding anthracene derivative, with different DNA sequences. Advanced analytical methods, including mass spectrometry and nuclear magnetic resonance, were used to conduct the investigation, together with the use of in silico docking and molecular dynamics. Eventually, the compound was tested in vitro to assess its bioactivity against lung cancer cell lines.

Dysregulation of Transposon Transcription Profiles in Cancer Cells Resembles That of Embryonic Stem Cells.

Transposable elements (TEs) comprise a substantial portion of the mammalian genome, with potential implications for both embryonic development and cancer. This study aimed to characterize the expression profiles of TEs in embryonic stem cells (ESCs), cancer cell lines, tumor tissues, and the tumor microenvironment (TME). We observed similarities in TE expression profiles between cancer cells and ESCs, suggesting potential parallels in regulatory mechanisms. Notably, four TE RNAs (HERVH, LTR7, HERV-Fc1, HERV-Fc2) exhibited significant downregulation across cancer cell lines and tumor tissues compared to ESCs, highlighting potential roles in pluripotency regulation. The strong up-regulation of the latter two TEs (HERV-Fc1, HERV-Fc2) in ESCs has not been previously demonstrated and may be a first indication of their role in the regulation of pluripotency. Conversely, tandemly repeated sequences (MSR1, CER, ALR) showed up-regulation in cancer contexts. Moreover, a difference in TE expression was observed between the TME and the tumor bulk transcriptome, with distinct dysregulated TE profiles. Some TME-specific TEs were absent in normal tissues, predominantly belonging to LTR and L1 retrotransposon families. These findings not only shed light on the regulatory roles of TEs in both embryonic development and cancer but also suggest novel targets for anti-cancer therapy. Understanding the interplay between cancer cells and the TME at the TE level may pave the way for further research into therapeutic interventions.

PINK1 insufficiency can be exploited as a specific target for drug combinations inducing mitochondrial pathology-mediated cell death in gastric adenocarcinoma

There exist very limited non-hazardous therapeutic strategies except for surgical resection and lymphadenectomy against gastric cancer (GC) despite being the third leading cause of cancer deaths worldwide. This study proposes an innovative treatment approach against GC using a drug combination strategy that manipulates mitochondrial dynamics in conjunction with the induction of mitochondrial pathology-mediated cell death. Comparative analysis was done with gastric adenocarcinoma and normal cells by qPCR, western blot, microscopic immunocytochemistry, and live cell imaging. In this study, impairment of dynamin-related protein 1 (Drp1)-mediated mitochondrial fission by Mdivi-1 created an imbalance in mitochondrial structural dynamics in indomethacin-treated AGS cells in which mitophagy-regulator protein PINK1 is downregulated. These drug combinations with the individual sub-lethal doses ultimately led to the activation of cell death machinery upregulating pro-apoptotic proteins like Bax, Puma, and Noxa. Interestingly, this combinatorial therapy did not affect normal gastric epithelial cells significantly and also no significant upregulation of death markers was observed. Moreover, the drug combination strategy also retarded cell migration and reduced stemness in GC cells. In summary, this study offers a pioneering specific therapeutic strategy for GC treatment, sparing normal cells providing opportunities for minimal drug-mediated toxicity utilizing mitochondria as a viable and specific target for anti-cancer therapy in gastric cancer.