Heterogeneity of Phase II Enzyme Ligands on Controlling the Progression of Human Gastric Cancer Organoids as Stem Cell Therapy Model

We prepared three-dimensional (3-D) organoids of human stomach cancers and examined the correlation between the tumorigenicity and cytotoxicity of Helicobacter pylori (H. pylori). In addition, the effects of hepatoma-derived growth factor (HDGF) and tumor necrosis factor (TNFα) on the growth and invasion activity of H. pylori-infected gastric cancer organoids were examined. Cytotoxin-associated gene A (CagA)-green fluorescence protein (GFP)-labeled H. pylori was used to trace the infection in gastric organoids. The cytotoxicity of Cag encoded toxins from different species of H. pylori did not affect the proliferation of each H. pylori-infected cancer organoid. To clarify the role of HDGF and TNFα secreted from H. pylori-infected cancer organoids, we prepared recombinant HDGF and TNFα and measured the cytotoxicity and invasion of gastric cancer organoids. HDGF controlled the growth of each organoid in a species-specific manner of H. pylori, but TNFα decreased the cell viability in H. pylori-infected cancer organoids. Furthermore, HDGF controlled the invasion activity of H. pylori-infected cancer organoid in a species-dependent manner. However, TNFα decreased the invasion activities of most organoids. We found different signaling of cytotoxicity and invasion of human gastric organoids in response to HDGF and TNFα during infection by H. pylori. Recombinant HDGF and TNFα inhibited the development and invasion of H. pylori-infected gastric cancer differently. Thus, we propose that HDGF and TNFα are independent signals for development of H. pylori-infected gastric cancer. The signaling of growth factors in 3-D organoid culture systems is different from those in two-dimensional cancer cells.

Enhanced LRP8 expression induced by Helicobacter pylori drives gastric cancer progression by facilitating β-Catenin nuclear translocation

ObjectiveGastric cancer is the second leading cause of cancer-related deaths and the fifth most common malignancy worldwide. In this study, human and mouse gastric cancer organoids were generated to model...

Recent advances in metabolomics have deepened our understandings of the roles that specific modes of metabolism play in the maintenance of stem cells. Several pieces of evidence have demonstrated that cancer stem cells (CSCs) play a key role in the acquisition of drug resistance. Organoid is a novel 3D cell culture system through using the specific niche factors in a dish and is believed to harbor abundant stem cells; cancer organoid could possibly be useful for scrutinizing CSC biology. In this study, we successfully established 5-FU resistant gastric cancer organoids (GCOs) from patient-derived specimens, which were further confirmed by significant changes in the expression of molecules related to 5-FU metabolism. We then performed metabolome analysis using 3 pairs of 5-FU resistant/ parental GCOs and 10 pairs of non-neoplastic gastric organoid/ GCOs generated from the same patients. PCA plotting revealed that 5-FU resistant GCOs showed a distinct signature compared to those of their parental GCOs and 10 pairs of non-neoplastic gastric organoid/ GCOs. Among various significant changes in the metabolic pathways, we focused on the excessive reliance on the energy from TAC cycle in 5-FU resistant GCO because the difference was specifically seen in the comparison between 5-FU resistant and parental GCOs: not found in the comparison between 10 pairs of non-neoplastic gastric organoid and GCOs. We examined IC50 value for Tigecyclin and VLX600, both of which have an inhibitory effect on TCA cycle, by MTT assay using 5-FU resistant GCO and 2 gastric cancer cell lines (MKN-45 and MKN-74). Although there was almost no difference in IC50 values for Tigecyclin and VLX600 between 2 gastric cell lines and their 5-FU resistant cells, IC50 for both of TCA cycle inhibitors in 5-FU resistant GCO was significantly lower compared to that in parental GCO. Further studies are ongoing in order to verify the significance of dependency on TCA cycle, which could potentially lead to the development of new therapy for 5-FU resistant gastric cancer. Citation Format: Naoya Sakamoto, Kazuhito Naka, Shoichi Ukai, Ririno Honma, Daiki Taniyama, Tsuyoshi Takashima, Ryota Maruyama, Kazuaki Tanabe, Hideki Ohdan, Wataru Yasui. Metabolome in 5-FU resistant gastric cancer organoids [abstract]. In: Proceedings of the Annual Meeting of the American Association for Cancer Research 2020; 2020 Apr 27-28 and Jun 22-24. Philadelphia (PA): AACR; Cancer Res 2020;80(16 Suppl):Abstract nr 4762.

Cancer treatments in general share various detrimental effects in common, especially upregulation of cardiovascular risk factors. Therefore, the science of onco-cardiology should not be restricted in scope to the side effects of each specific cancer drug. In particular, premature aging induced by cancer treatment may contribute to the chronic health problems of cancer survivors. About 1 660 000 people, including more than 12 000 children below the age of 18 years, are newly diagnosed with a malignancy in the United States every year.1 The American Cancer Society reported that in 2016 there are 15.5 million cancer survivors in the United States (http://www.cancer.org/cancer/news/news/report-number-of-cancer-survivors-continues-to-grow). At present, the 5-year survival rate of patients treated for cancer is 67%. Seventy-five percent of children in whom cancer is diagnosed today will live for at least 10 years; 20% will survive for longer than 35 years.1 Although these numbers are impressive compared with those from decades ago, further improvement of cancer survivors’ life span as well as quality of life and functional status is still necessary. Approximately 75% of cancer survivors have some form of chronic health problem. Cardiovascular diseases (CVDs) are the leading cause of morbidity and mortality in this population, particularly after recurrent or second malignancy. The risk of CVD in cancer survivors is 8× higher than that of the general population. The relative risks of coronary artery disease and heart failure in cancer survivors are 10× and 15× higher, respectively, than their siblings without cancer.1 Cancer treatments, including chemotherapy and radiation, can lead to both short- and long-term cardiovascular complications. Evidence of subclinical cardiac and vascular damage was observed in more than 50% of survivors 5 to 10 years after chemotherapy.1 Onco-cardiology is a medical subspecialty concerned with the diagnosis and treatment of CVDs and organ failure mediated by microcirculatory or macrocirculatory …

Oxidative stress and reactive oxygen species (ROS) are associated with diseases such as cancer, cardiovascular complications, inflammation and neurodegeneration. Cellular defense systems must work constantly to control ROS levels and to prevent their accumulation. We report here that the Jun dimerization protein 2 (JDP2) has a critical role as a cofactor for transcription factors nuclear factor-erythroid 2-related factor 2 (Nrf2) and small Maf protein family K (MafK) in the regulation of the antioxidant-responsive element (ARE) and production of ROS. Chromatin immunoprecipitation–quantitative PCR (qPCR), electrophoresis mobility shift and ARE-driven reporter assays were carried out to examine the role of JDP2 in ROS production. JDP2 bound directly to the ARE core sequence, associated with Nrf2 and MafK (Nrf2–MafK) via basic leucine zipper domains, and increased DNA-binding activity of the Nrf2–MafK complex to the ARE and the transcription of ARE-dependent genes. In mouse embryonic fibroblasts from Jdp2-knockout (Jdp2 KO) mice, the coordinate transcriptional activation of several ARE-containing genes and the ability of Nrf2 to activate expression of target genes were impaired. Moreover, intracellular accumulation of ROS and increased thickness of the epidermis were detected in Jdp2 KO mice in response to oxidative stress-inducing reagents. These data suggest that JDP2 is required to protect against intracellular oxidation, ROS activation and DNA oxidation. qPCR demonstrated that several Nrf2 target genes such as heme oxygenase-1, glutamate–cysteine ligase catalytic and modifier subunits, the notch receptor ligand jagged 1 and NAD(P)H dehydrogenase quinone 1 are also dependent on JDP2 for full expression. Taken together, these results suggest that JDP2 is an integral component of the Nrf2–MafK complex and that it modulates antioxidant and detoxification programs by acting via the ARE.

BackgroundGastric cancer ranks as the fifth most common malignancy worldwide. Of note, this entity shows a rising incidence rate over the last decades. Surgical resection and adjuvant chemotherapy are the...

Gastric cancer (GC) is the third most common cause of cancer‑related death in the world. Annexin A10 (ANXA10), a member of the Annexin family, is a calcium‑/phospholipid‑binding protein; however, little is known concerning its functions. It is still unclear what molecule is involved in the induction of ANXA10. In the present study, we performed immunohistochemistry to evaluate the expression of ANXA10, pancreatic and duodenal homeobox‑1 (PDX1) and mucin phenotype markers in 130GC samples. ANXA10 was detected in 63(48%) of the 130GC cases and loss of ANXA10 was significantly correlated with disease progression and poor clinical outcomes in GC. PDX1 was significantly correlated with ANXA10 in GC cases and cell lines. Although PDX1 was not significantly correlated with the GC cases with any of the mucin phenotypes, ANXA10 was preferentially detected in the GC cases with the gastric mucin phenotype. As a further investigation, we generated organoids derived from human GC and identified the duplication of the mucin phenotypes of GC by immunohistochemistry. The repression effect on cell growth that was observed in the ANXA10‑knockdown cell lines was also clearly observed in the human gastric organoids. We demonstrated that the expression of ANXA10 was correlated with the gastric mucin phenotype and ANXA10 was involved in the induction of PDX1 expression in GC. We also provided evidence that GC organoids represent a powerful tool for scrutinizing the biology of GC, especially with regard to the mucin phenotype.

Gastric cancer is one of the most common malignancies with poor prognosis. The use of organoids to simulate gastric cancer has rapidly developed over the past several years. Patient-derived gastric cancer organoids serve as in vitro models that closely mimics donor characteristics, offering new opportunities for both basic and applied research. The “Human Gastric Cancer Organoid” is part of a series of guidelines for human gastric cancer organoids in China, jointly drafted by experts from the Chinese Society for Cell Biology and its branches, and initially released on October 29, 2024. This standard outlines terminology, technical requirements, assessment protocols, and applies to production, evaluation procedures, and quality control for human gastric cancer organoids. The publication of this guideline aims to assist institutions in endorsing, establishing, and applying best practices, advancing the international standardization of human gastric cancer organoids for clinical development and therapeutic application.

The prognosis of gastric cancer with peritoneal dissemination is poor because of its resistance to chemotherapy. To investigate the mechanism of drug resistance in peritoneal metastasis, cancer organoids were established from the ascites of a patient with peritoneal metastases of gastric cancer. The histological characteristics of the tumors were preserved in the organoids. A co-culture system was established by overlaying human-derived mesothelial cells on gastric cancer organoids embedded in type IA collagen, mimicking peritoneal dissemination foci. When co-cultured with mesothelial cells, the proliferation of ascites-derived gastric cancer organoids and other primary gastric cancer organoids was suppressed. Soluble factors derived from mesothelial cells were involved in suppressing cell proliferation. Organoids in co-culture showed reduced sensitivity to paclitaxel. This co-culture model may provide a useful platform for studying drug resistance mechanisms in the microenvironment of gastric cancer peritoneal metastases.

Background: The prognosis of gastric cancer (GC) is improving due to the development of chemotherapy, however, intrinsic or acquired resistance to anti-cancer drugs is still a major clinical challenge. Oxaliplatin (L-OHP) is one of the anti-cancer drugs used as first-line treatment for GC. As with other anti-cancer drugs, although acquired resistance to L-OHP is a major problem, no biomarkers are clinically available for L-OHP response. Recently, cancer stem cells (CSCs) were shown to be involved in the acquisition of drug resistance. Hence, the major goal is to discover novel predictive biomarkers and overcome L-OHP resistance in GC in relation to CSCs. Methods: We used the organoid model; a culture method that allows 3D in vitro culturing of tissue-like structures and is presumed to contain many stem/progenitor cells. We established three independent L-OHP-resistant gastric cancer organoids (GCOs) by adding increasing doses of L-OHP in the culture medium over time. Gene expression profiles of the pairs of parental and resistant organoids were evaluated using microarray analysis. We analyzed the microarray data of L-OHP-resistant GCOs with our previous study from 5-fluorouracil (5-FU)-resistant GCOs (GSE154127). We validated the upregulated genes in the L-OHP-resistant GCOs by qRT-PCR. To confirm the use of upregulated genes as a novel biomarker, we immunohistochemically evaluated the expression levels in GC tissue samples. Furthermore, we analyzed the effects of knockdown using both GC cell lines and GCOs. Results: Through the comparison of the data, we detected myoferlin (MYOF) to be a candidate gene responsible only for L-OHP resistance. qRT-PCR results confirmed the results of the microarray and found that high expression of MYOF correlated significantly with the IC50 of L-OHP in GCOs. Immunohistochemistry analysis for MYOF using 132 GC cases showed that high expression of MYOF was significantly associated with poor prognosis, T grade, N grade, and lymphatic invasion, and showed MYOF to be an independent prognostic indicator, especially in the GC patients treated with platinum-based chemotherapy. The knockdown or inhibition of MYOF by WJ460 in GC cell line and GCOs enhanced L-OHP sensitivity while it reduced cell growth, spheroid/organoid formation, migration, invasion, and in vivo tumorigenesis. Conclusion: We highlight that MYOF is highly involved in L-OHP resistance and tumor progression in GC. Our results indicate that MYOF could be a promising biomarker in GC to predict L-OHP sensitivity and tumor progression and a potential candidate gene as a therapeutic target. Citation Format: Kenji Harada, Naoya Sakamoto, Shoichi Ukai, Tsuyoshi Takashima, Ryota Maruyama, Daiki Taniyama, Kazuaki Tanabe, Hideki Ohdan, Wataru Yasui. Identification of MYOF as a novel biomarker by using oxaliplatin-resistant gastric cancer organoid model [abstract]. In: Proceedings of the American Association for Cancer Research Annual Meeting 2022; 2022 Apr 8-13. Philadelphia (PA): AACR; Cancer Res 2022;82(12_Suppl):Abstract nr 6186.

Metastasis is a major factor leading to an unfavorable prognosis in gastric cancer (GC). However, factors driving GC metastasis are not fully understood. Single-cell transcriptome analysis was done on three primary GC samples, one adjacent nontumor sample, and six GC metastasis samples (GSE163558) to clarify cellular composition characteristics, differential genes, and screen genes related to epithelial-mesenchymal transition (EMT). Effects of GPX3 on GC growth and metastasis were assessed through in vitro cell experiments, a GC liver metastasis model, a GC organoid model, and an organoid xenograft nude mouse model. The primary tumor samples showed a higher proportion of epithelial cells, and analysis revealed a significant reduction in GPX3 levels in GC metastasis samples within the subpopulation of epithelial cells undergoing EMT. Cell experiments demonstrated low expression of GPX3 in GC cells, and overexpression of GPX3 inhibited cell migration, invasion, and EMT in GC cells. Further validation in a nude mouse liver metastasis model confirmed the repressive role of GPX3 in GC metastasis. Additionally, GPX3 could inhibit the growth of patient-derived GC organoids and impede tumor growth and metastasis in an organoid xenograft nude mouse model. This study, based on single-cell transcriptome analysis, revealed the potential inhibitory factor GPX3 in metastatic GC and validated its effects on GC growth and metastasis using GC cells and organoids in vitro and in vivo experiments. These findings offer insights into understanding GC heterogeneity and targeting GPX3 in GC therapeutic strategies.

It is postulated as a general concept of cancer stem cells (CSCs) that they can produce cancer cells overtly and repopulate cancer progenitor cells indefinitely. The CSC niche is part of a specialized cancer microenvironment that is important to keep the phenotypes of CSCs. Stem cell- and induced pluripotent stem cell (iPSC)-derived organoids with genetic manipulation are beneficial to the investigation of the regulation of the microenvironment of CSCs. It would be useful to assess the efficiency of the cancer microenvironment on initiation and progression of cancers. To identify CSCs in cancer tissues, normal cell organoids and gastric cancer organoids from the cancerous areas, as well as iPSCs, were established several years ago. However, many questions remain about the extent to which these cultures recapitulate the development of the gastrointestinal tract and the mechanism of Helicobacter pylori-induced cancer progression. To clarify the fidelity of human organoid models, we have noted several key issues for the cultivation of, and differences between, normal and cancerous organoids. We developed precise culture conditions for gastric organoids in vitro to improve the accuracy of the generation of organoid models for therapeutic and medical applications. In addition, the current knowledge on gastrointestinal CSC research, including the topic of CSC markers, cancer cell reprogramming, and application to target cancer cell plasticity through niches, should be reinforced. We discuss the progression of cancers derived from human gastric organoids and the identification of CSCs.

To establish an in vitro study model of gastric cancer, gastric cancer organoid culture system, by biopsy under gastroscope, and to explore and analyze the related factors affecting the success rate of culture, to provide a better in vitro model for the study of gastric cancer. Twenty-six patients with advanced gastric cancer were collected. Organoids were cultured by biopsy under gastroscope. Paraffin sections were made and HE staining was used to compare the consistency of gastroscopic pathological morphology and organoids. To explore the influencing factors of cultivating gastric cancer organoids in combination with clinical data. A total of 26 cases were collected by gastroscopy, and 12 cases of gastric cancer organoids were successfully cultured after identification, with a success rate of about 48%. Its histopathological morphology was highly consistent with that of gastric cancer. According to the pathological type, 21 cases were poorly differentiated adenocarcinoma and 12 cases were successful. Four cases of signet ring cell carcinoma failed. According to the location of the lesion, the success rate of sampling and culture of gastric antrum was significantly lower, which may be related to antral edema and anatomical characteristics of gastric antrum. Some of the failed cases are related to the quality of sampling, technique and contamination of tissue cells. We have successfully established gastric cancer organoids through endoscopic biopsy, and analyzed the factors affecting the success rate of culture from various angles, to improve and enhance the organoid culture technology and provide a better platform for tumor research.

BackgroundNab-paclitaxel has been widely used in treating breast cancer and pancreatic patients for its low toxicity and high efficiency. However, its role in gastric cancer (GC) remains ambiguous. The aim of our study was to test the anti-tumor activity of nab-paclitaxel using GC patient-derived organoids.MethodsBy using the organoid culture system, we describe the establishment of human gastric cancer organoid lines from surgical samples of three patients with gastric cancer. The consistency of these organoids with original cancer tissues was evaluated by histopathological examination. The characteristics of the cancer organoids were tested using immunofluorescence (IF) staining. Using organoids, the anti-tumor efficiencies of nab-paclitaxel, 5-Fu and epirubicin were compared by CCK8 assay and Annexin V-FITC/PI staining.ResultsThree organoids were successfully established and passaged. The morphology of the established GC organoids was consistent with original cancer tissues. The IC50 of nab-paclitaxel was 3.68 μmol/L in hGCO1, 2.41 μmol/L in hGCO2 and 2.91 μmol/L in hGCO3, which was significantly lower than those of 5-FU (72.99 μmol/L in hGCO1, 28.32 μmol/L in hGCO2 and 2.91 μmol/L in hGCO3) and epirubicin (25.85μmol/L in hGCO1, 15.15 μmol/L in hGCO2 and 7.60 μmol/L in hGCO3). When each organoid lines were treated with nab-paclitaxel for increasing period of time, the percentage of the apoptotic cells in each organoid increased accordingly.ConclusionNab-paclitaxel showed strong anti-tumor activity and had the potential to become front-line drug for treating GC patients. Gastric cancer organoid may be a good tool to predict in vivo response to drugs.