Theoretical analyses and experimental validation of the effects caused by the fluorinated substituent modification of DNA.

Halogen-modified nucleic acid molecules, such as trifluorothymidine (FTD) and 5-fluorouracil, are widely used in medical science and clinical site. These compounds have a very similar nucleobase structure. It is reported that both of these compounds could be incorporated into DNA. The incorporation of FTD produces highly anti-tumor effect. However, it is not known whether to occur a significant effect by the incorporation of 5-fluorouracil. Nobody knows why such a difference will occur. To understand the reason why there is large differences between trifluorothymidine and 5-fluorouracil, we have performed the molecular dynamics simulations and molecular orbital calculations. Although the active interaction energy between Halogen-modified nucleic acids or and complementary adenine was increased, in only FTD incorporated DNA, more strongly dispersion force interactions with an adjacent base were detected in many thermodynamic DNA conformations. As the results, the conformational changes occur even if it is in internal body temperature. Then the break of hydrogen bonding between FTD and complementary adenine base occur more frequently. The double helix structural destabilization of DNA with FTD is resulted from autoagglutination caused by the bonding via halogen orbitals such as halogen bonding and the general van der Waals interactions such as CH-[Formula: see text], lone pair (LP)-[Formula: see text], and [Formula: see text]-[Formula: see text] interactions. Therefore, it is strongly speculated that such structural changes caused by trifluoromethyl group is important for the anti-tumor effect of FTD alone.

Association of iron metabolic enzyme hepcidin expression levels with the prognosis of patients with pancreatic cancer.

Hepcidin and ferroportin, which are known as key iron regulators, may be used in future treatments of pancreatic ductal adenocarcinoma. Iron is essential for life support; it helps oxygen molecules bind to hemoglobin and acts as an important catalytic enzyme center. However, iron overload is a risk factor for cancer, possibly through the generation of reactive oxygen species (ROS). Hepcidin, which is a peptide hormone mainly generated by the liver, inhibits iron absorption via enterocytes and iron release from macrophages. Notably, hepcidin regulates iron homeostasis in the body by regulating the iron transporter ferroportin. In the present study, it was assumed that high hepcidin expression and low ferroportin expression result in malignancy. Therefore, it was examined whether hepcidin and ferroportin expression levels were correlated with the prognosis of pancreatic cancer in patients. Results revealed that high hepcidin expression levels and low ferroportin expression levels in pancreatic cancer tissue were significantly associated with poor prognosis in the analyses of overall survival (P=0.0140 and 0.0478, respectively). Additionally, there was no significant difference in disease-free survival in the hepcidin- and ferroportin-staining groups. Hepcidin expression correlated with the pathological stage and vascular invasion (P=0.0493 and 0.0400, respectively), and ferroportin expression was correlated with age (P=0.0372). Multivariate analysis of overall survival in the hepcidin-staining group revealed that pathological N factor (pN), adjuvant chemotherapy, and hepcidin expression were independent prognostic factors (P=0.0450, 0.0002, and 0.0049, respectively). Similarly, multivariate analysis of overall survival in the ferroportin-staining group revealed that vascular invasion, and ferroportin expression were independent prognostic factors (P=0.0028, P<0.0001, and P=0.0056, respectively). Thus, hepcidin and ferroportin expressions might be novel prognostic indicators for pancreatic cancer.

A Cancer Reprogramming Method Using MicroRNAs as a Novel Therapeutic Approach against Colon Cancer: Research for Reprogramming of Cancer Cells by MicroRNAs.

BACKGROUND: We previously generated induced pluripotent stem cells by reprograming adipose stem cells through the introduction of microRNAs targeting four transcription factors (Oct3/4, Sox2, c-Myc, and Klf4). In this study, we aimed to reprogram cancer cells using microRNAs to explore their therapeutic potential. METHODS: Mature microRNAs (mir-302a-d, 369-3p and 5p, and mir-200c, as needed) were introduced into colon cancer cells (DLD-1, RKO, and HCT116) using lipofection. RESULTS: The transfected cells exhibited an embryonic stem cell-like morphology and expressed the undifferentiated marker genes Nanog, Oct3/4, SOX2, and Klf4, as well as tumor-related antigen-1-60. These cells expressed neurogenic or adipogenic markers, indicating that reprogramming of the cancer cells was partially successful. Moreover, we found that miRNA-expressing DLD-1 cells showed low proliferative activity in vitro and in vivo, accompanied by increased expression of the tumor suppressor genes p16 (ink4a) and p21 (waf1) . miRNA-expressing DLD-1 cells also exhibited enhanced sensitivity to 5-fluorouracil, possibly through the downregulation of multidrug-resistant protein 8. The reprogrammed cells from DLD-1, RKO, and HCT116 cells exhibited reduced c-Myc expression, in contrast to the high c-Myc expression in the induced pluripotent cancer cells that were generated using four transcription factors. CONCLUSIONS: Our cancer reprogramming method employing simple lipofection of mature microRNAs is safe and well suited for clinical application, because it avoids integration of exogenous genes into the host genome and allows escape from augmentation of c-Myc gene expression.