Tissue-specific Physical and Biological Microenvironments Modulate the Behavior of Cervical Squamous Cell Carcinoma.

The mechanisms controlling the aggressiveness and survival of cervical SCC cells remain unclear. We investigated how the physical and biological microenvironments regulate the growth, apoptosis and invasiveness of cervical cancer cells. Dynamic flow and air exposure were evaluated as physical microenvironmental factors, and stromal fibroblasts were evaluated as a biological microenvironmental factor. To investigate any regulatory effects of these microenvironmental factors, we established a new culture model which concurrently replicates fluid streaming, air exposure and cancer-stromal interactions. Three cervical cancer cell lines were cultured with or without NIH 3T3 fibroblasts. Air exposure was realized using a double-dish culture system. Dynamic flow was created using a rotary shaker. Dynamic flow and air exposure promoted the proliferative activity and decreased the apoptosis of cervical cancer cells. Fibroblasts regulated the invasive ability, growth and apoptosis of cervical cancer cells. Extracellular signal-regulated kinase and p38 signaling were regulated either synergistically or independently by dynamic flow, air exposure and cellular interactions, depending on the cervical cancer cell type. This study demonstrates that the physical and biological microenvironments interact to regulate the aggressiveness and survival of cervical cancer cells. Our simple culture system is a promising model for developing further treatment strategies for various types of cancer.

Cytological Appearances of Ovarian Seromucinous Borderline Tumor in Ascites: Presentation of 2 Cases.

BACKGROUND: Seromucinous borderline tumor (SMBT) is a rare neoplasm which was newly defined in the 2014 WHO classification. Although the clinical and histopathological characteristics of SMBT have been well described, its cytological characteristics have not. We recently experienced 2 cases of SMBT which were defined by cytological findings of ascites. CASE PRESENTATION: Case 1 was a 65-year-old Japanese woman. Preoperative imaging studies revealed abundant ascites and a cystic tumor, with a solid component measuring 13 cm on the left ovary. Radical surgery was performed during the intraoperative diagnosis of ovarian borderline tumor, made by histological examinations of frozen tumor sections. The cytological smears of preoperatively and intraoperatively collected ascites showed many atypical cells resembling reactive mesothelial cells. Alcian-blue staining of cell block sections revealed intracytoplasmic mucin, and the results of immunohistochemistry were consistent with SMBT. The final pathological diagnosis of tumor was SMBT. Case 2 was a 28-year-old Japanese woman. Preoperative imaging studies revealed a small amount of ascites and cystic tumors with solid components in the bilateral ovaries. She initially underwent fertility preservation surgery. SMBT was suspected by cytological examination of smears of intraoperatively collected ascites and the findings of cell block. She underwent additional radical surgery based on a final pathological diagnosis of SMBT. CONCLUSION: In our experience, the tumor cells of SMBT in ascites mimicked reactive mesothelial cells. The nuclear atypia of SMBTs was intermediate between that of reactive mesothelial cells and serous carcinoma. The immunohistochemistry and mucin staining using cell block were very helpful for facilitating the cytodiagnosis of SMBT.

Mesenchymal cells and fluid flow stimulation synergistically regulate the kinetics of corneal epithelial cells at the air-liquid interface.

PURPOSE: In vivo microenvironments are critical to tissue homeostasis and wound healing, and the cornea is regulated by a specific microenvironment complex that consists of cell-cell interactions, air-liquid interfaces, and fluid flow stimulation. In this study, we aimed to clarify the effects of and the correlations among these three component factors on the cell kinetics of corneal epithelial cells. METHODS: Human corneal epithelial-transformed (HCE-T) cells were cocultured with either primary rat corneal fibroblasts or NIH 3T3 fibroblasts. We employed a double-dish culture method to create an air-liquid interface and a gyratory shaker to create fluid flow stimulation. Morphometric and protein expression analyses were performed for the HCE-T cells. RESULTS: Both the primary rat fibroblasts and the NIH 3T3 cells promoted HCE-T cell proliferation, and the presence of fluid flow synergistically enhanced this effect and inhibited the apoptosis of HCE-T cells. Moreover, fluid flow enhanced the emergence of myofibroblasts when cocultured with primary rat fibroblasts or NIH 3T3 cells. Extracellular signal-regulated kinase and p38 signaling were regulated either synergistically or independently by both fluid flow and cellular interaction between the HCE-T and NIH 3T3 cells. CONCLUSION: The cell-cell interaction and fluid flow stimulation in the air-liquid interface synergistically or independently regulated the behavior of HCE-T cells. Fluid flow accelerated the phenotypic change from corneal fibroblasts and NIH 3T3 cells to myofibroblasts. Elucidation of the multicomponent interplay in this microenvironment will be critical to the homeostasis and regeneration of the cornea and other ocular tissues.

A high-density collagen xerogel thread prevents the progression of peritoneal fibrosis.

Peritoneal fibrosis is often provoked by peritoneal dialysis and is an essential precursor condition to the development of encapsulating peritoneal sclerosis. This study aimed to determine the efficacy of a high-density collagen xerogel thread (CXT) for the prevention of peritoneal fibrosis. Female ICR mice received intraperitoneal injections of chlorhexidine gluconate (CG) every other day to induce peritoneal fibrosis. For evaluation, the insertion of CXT or infusion of atelocollagen gel into the peritoneal cavity was conducted on the day before CG injection. For comparison, no collagen treatment after CG injection, and abdominal puncture without CG injection were also performed. Peritoneal fibrosis and inflammation were significantly suppressed by CXT for a long period. CXT prevented mesothelial epithelial-mesenchymal transition, myofibroblast emergence, and inflammatory cell invasion in the peritonitis tissue. In the early phase, atelocollagen gel modulated the expression of the fibrosis-associated protein transforming growth factor (TGF)-ß, connective tissue growth factor (CTGF), and CD105 in the peritoneum under CG-induced inflammation, while CXT did not. In contrast, CXT regulated the expression of CTGF and CD105 in the late phase and maintained antimicrobial protein REG3G at the same level as the Sham group in the early and late phases. Although the precise mechanism remains to be clarified, these findings suggest that CXT may have the potential to be developed as a simple therapeutic device to prevent peritoneal fibrosis, a severe complication in patients undergoing long-term peritoneal dialysis.

Signet Ring Cell Carcinoma of Unknown Primary Complicated with Pulmonary Tumor Thrombotic Microangiopathy and Krukenberg Tumor.

Pulmonary tumor thrombotic microangiopathy (PTTM) is a rare disease that shows hypoxia with severe pulmonary hypertension related to malignant tumor. Diagnosis is difficult due to rapid clinical progression and the need to demonstrate pathological findings from lung biopsy. A 64-year-old woman visited our hospital with hypoxia and pulmonary hypertension. Diffuse granular shadows in the centrilobular area and ground-glass shadows in both lungs and left ovarian tumor were found on radiological imaging. PTTM was suspected, but pulmonary artery blood aspiration by right cardiac catheter failed to detect cancer cells. We could not obtain lung or ovary biopsies because of hypoxia or pulmonary hypertension. The patient died due to respiratory failure. Signet ring cell carcinoma of unknown primary, PTTM, and Krukenberg tumor were diagnosed on autopsy. Since early diagnosis facilitates adequate treatment, physicians should not miss the opportunity for biopsy in cases of suspected PTTM.

Cancer-adipose tissue interaction and fluid flow synergistically modulate cell kinetics, HER2 expression, and trastuzumab efficacy in gastric cancer.

BACKGROUND: Early local tumor invasion in gastric cancer results in likely encounters between cancer cells and submucosal and subserosal adipose tissue, but these interactions remain to be clarified. Microenvironmental mechanical forces, such as fluid flow, are known to modulate normal cell kinetics, but the effects of fluid flow on gastric cancer cells are poorly understood. We analyzed the cell kinetics and chemosensitivity in gastric cancer using a simple in vitro model that simultaneously replicated the cancer-adipocyte interaction and physical microenvironment. METHODS: Gastric cancer cells (MKN7 and MKN74) were seeded on rat adipose tissue fragment-embedded discs or collagen discs alone. To generate fluid flow, samples were placed on a rotatory shaker in a CO2 incubator. Proliferation, apoptosis, invasion, and motility-related molecules were analyzed by morphometry and immunostaining. Proteins were evaluated by western blot analysis. Chemosensitivity was investigated by trastuzumab treatment. RESULTS: Adipose tissue and fluid flow had a positive synergistic effect on the proliferative potential and invasive capacity of gastric cancer cells, and adipose tissue inhibited apoptosis in these cells. Adipose tissue upregulated ERK1/2 signaling in gastric cancer cells, but downregulated p38 signaling. Notably, adipose tissue and fluid flow promoted membranous and cytoplasmic HER2 expression and modulated chemosensitivity to trastuzumab in gastric cancer cells. CONCLUSION: We have demonstrated that cancer-adipocyte interaction and physical microenvironment mutually modulate gastric cancer cell kinetics. Further elucidation of the microenvironmental regulation in gastric cancer will be very important for the development of strategies involving molecular targeted therapy.