Effect of 5-fluorouracil on the cell growth and cell cycle kinetics of a mouse ascites tumor growing in vivo

Synthesis of Novel 2-Thiouracil-5-Sulfonamide Derivatives as Potent Inducers of Cell Cycle Arrest and CDK2A Inhibition Supported by Molecular Docking

In an effort to discover potent anticancer agents, 2-thiouracil-5-sulfonamides derivatives were designed and synthesized. The cytotoxic activity of all synthesized compounds was investigated against four human cancer cell lines viz A-2780 (ovarian), HT-29 (colon), MCF-7 (breast), and HepG2 (liver). Compounds 6b,d-g, and 7b showed promising anticancer activity and significant inhibition of CDK2A. Moreover, they were all safe when tested on WI38 normal cells with high selectivity index for cancer cells. Flow cytometric analysis for the most active compound 6e displayed induction of cell growth arrest at G1/S phase (A-2780 cells), S phase (HT-29 and MCF-7 cells), and G2/M phase (HepG2 cells) and stimulated the apoptotic death of all cancer cells. Moreover, 6e was able to cause cycle arrest indirectly through enhanced expression of cell cycle inhibitors p21 and p27. Finally, molecular docking of compound 6e endorsed its proper binding to CDK2A, which clarifies its potent anticancer activity.

DAFODIL: A novel liposome-encapsulated synergistic combination of doxorubicin and 5FU for low dose chemotherapy

PEGylated liposomes have transformed chemotherapeutic use of doxorubicin by reducing its cardiotoxicity; however, it remains unclear whether liposomal doxorubicin is therapeutically superior to free doxorubicin. Here, we demonstrate a novel PEGylated liposome system, named DAFODIL (Doxorubicin And 5-Flurouracil Optimally Delivered In a Liposome) that inarguably offers superior therapeutic efficacies compared to free drug administrations. Delivery of synergistic ratios of this drug pair led to greater than 90% reduction in tumor growth of murine 4T1 mammary carcinoma in vivo. By exploiting synergistic ratios, the effect was achieved at remarkably low doses, far below the maximum tolerable drug doses. Our approach re-invents the use of liposomes for multi-drug delivery by providing a chemotherapy vehicle which can both reduce toxicity and improve therapeutic efficacy. This methodology is made feasible by the extension of the ammonium-sulfate gradient encapsulation method to nucleobase analogues, a liposomal entrapment method once conceived useful only for anthracyclines. Therefore, our strategy can be utilized to efficiently evaluate various chemotherapy combinations in an effort to translate more effective combinations into the clinic.

Cytotoxicity of 5-fluorouracil: Effect on endothelial differentiation via cell cycle inhibition in mouse embryonic stem cells

Embryonic stem cells (ESCs) are known to characteristics for pluripotency and self-renewal, but the precise mechanisms of ES-derived cells to specific toxicants have not been determined. Here, we evaluated the cytotoxicity of 5-fluorouracil (5-FU) and see its effect on cell viability, proliferation, and differentiation in mouse ESC-derived endothelial differentiation. Mouse ESCs were exposed to 5-FU (10 microM) and combined with probucol (50 microM) for 24h, which is an antagonist of 5-FU. Changes in gene expression as a result of 5-FU exposure in mouse ESC-derived endothelial precursor cells (ES-EPCs) were assessed using an oligonucleotide microarray (AB1700). The expression of Oct-4 was decreased during the differentiation of mouse ESCs into endothelial cells; otherwise, the expression of PECAM was increased. Mouse ES-EPCs were shown to have a decrease in viability (49.8%) and PECAM expression, and induce G1/S phase (31.1%/60.6%) when compared with/without treatment of 5-FU. Expression of cell cycle-related proteins was increased in endothelial precursor cells exposed to 5-FU without probucol treatment. From theses results suggest that 5-FU inhibit endothelial differentiation as well as inducing the G1/S phase arrest. We propose that mouse ES-EPCs might be a useful tool for screening the cytotoxicity of compounds in endothelial cells.

Establishment of human papillomavirus infection requires cell cycle progression

Human papillomaviruses (HPVs) are DNA viruses associated with major human cancers. As such there is a strong interest in developing new means, such as vaccines and microbicides, to prevent HPV infections. Developing the latter requires a better understanding of the infectious life cycle of HPVs. The HPV infectious life cycle is closely linked to the differentiation state of the stratified epithelium it infects, with progeny virus only made in the terminally differentiating suprabasal compartment. It has long been recognized that HPV must first establish its infection within the basal layer of stratified epithelium, but why this is the case has not been understood. In part this restriction might reflect specificity of expression of entry receptors. However, this hypothesis could not fully explain the differentiation restriction of HPV infection, since many cell types can be infected with HPVs in monolayer cell culture. Here, we used chemical biology approaches to reveal that cell cycle progression through mitosis is critical for HPV infection. Using infectious HPV16 particles containing the intact viral genome, G1-synchronized human keratinocytes as hosts, and early viral gene expression as a readout for infection, we learned that the recipient cell must enter M phase (mitosis) for HPV infection to take place. Late M phase inhibitors had no effect on infection, whereas G1, S, G2, and early M phase cell cycle inhibitors efficiently prevented infection. We conclude that host cells need to pass through early prophase for successful onset of transcription of the HPV encapsidated genes. These findings provide one reason why HPVs initially establish infections in the basal compartment of stratified epithelia. Only this compartment of the epithelium contains cells progressing through the cell cycle, and therefore it is only in these cells that HPVs can establish their infection. By defining a major condition for cell susceptibility to HPV infection, these results also have potentially important implications for HPV control.

Human papillomaviruses (HPV), which comprise more than 100 genotypes, are the most prevalent sexually transmitted infection and are associated with multiple human cancers including all cervical cancers, many other anogenital cancers, and 25% of head and neck cancers. The HPV life cycle is closely linked to epithelial differentiation of skin keratinocytes, with initial infection occurring only in the undifferentiated proliferating basal compartment of the epithelium and progeny virus production only in the terminally differentiated suprabasal compartment. So far, little is known about how host cells restrict the HPV life cycle to specific stages of skin cell development. Here, by identifying small molecule inhibitors of HPV infection, we discovered that cell cycle progression through mitosis is critical for the establishment of HPV infection. In addition, our further chemical genetic dissection of this process showed that early steps of mitosis are required for HPV infection and early gene expression. Our findings provide one reason why HPV only infects undifferentiated proliferating cells and provide new leads for the development of preventive and therapeutic strategies against HPV infection.

Effect of 5-fluorouracil on G1 phase cell cycle regulation in oral cancer cell lines

5-fluorouracil (5-FU) has been widely used for chemotherapy of head and neck cancer, and is known to affect the cell cycle and induce apoptotic death of cancer cells. However, the molecular actions of 5-FU on the cell cycle regulatory mechanism have not been fully explained. Herein we analyzed the effects of 5-FU on the expression of G1/S-related cell cycle regulators in oral cancer cell lines. In vitro 5-FU treatment of oral cancer cells resulted in an increase in G1/S phase cells. p21 expression was augmented by 5-FU without any notable changes in p53 expression. A remarkable up-regulation of cyclin E and a concomitant down-regulation of cyclin D were observed after 24 h 5-FU treatment. Our results suggest that 5-FU-induced changes in cell cycle regulation of oral cancer cells might associate with an alteration of G1 cyclins expression. p21 was remarkably up-regulated, but it was speculated that its activity might be cancelled by an increased binding to CDK4.

Effect of 5-fluorouracil on cell cycle regulatory proteins in human colon cancer cell line

We investigated the effects of 5-fluorouracil (5-FU) on cell cycle-regulating proteins in RPMI 4788 cells. 5-FU inhibited cell growth dose-dependently and this growth inhibition was accompanied with cell cycle accumulation in early S phase and increased expression of cyclin A. When cells were released from short-term treatment (3 or 24 h) with 5-FU, the cell cycle started to progress again and cyclin A protein levels decreased. Cyclin A-associated kinase activity assay showed that cyclin A-cyclin-dependent kinase (Cdk) 2 kinase activity was altered by 5-FU treatment concomitantly with the changes in cell cycle state seen in flow cytometric analysis. Furthermore, the elevation of cyclin A protein level by 5-FU treatment was observed in three other human cancer cell lines, DLD-1, H226Br and T.Tn. These results suggest that cyclin A protein levels in cancer cells are increased by 5-FU, and the cyclin A function and degradation mechanism remain normal.

Absence of misincorporation of pyrimidines in DNA after treatment with a combination of cisplatin (CIS-diammine-dichloro-platinum) amd 5-fluorouracil of mouse sarcoma cells

The effects on incorporation into DNA of the deoxyribonucleotides dCTP and dTTP and the DNA synthesis rate after treatment with cisplatin (CDDP), 5-fluorouracil (5-FU) or a combination of CDDP and 5-FU were studied in ascites sarcoma (Bp8) growing in mice. Single administration of CDDP gave an early (1 h) transient increase in the DNA-synthesis followed by a decrease. 5-FU as single agent did increase the rate of DNA synthesis after 6 h with a maximum at 10 h. The combination of CDDP and 5-FU markedly increased the rate of DNA synthesis up to 6 h as compared to single drug treatment. Although the dCTP pool increased after combined treatment, while the dTTP pool was unchanged, no alterations in the proportions of dTTP and dCTP incorporated into DNA could be detected. Hence, misincorporation of pyrimidines is not the mechanism for the synergistic effect of the combination of CDDP and 5-FU.

Effects of developmental stage and tissue type on embryo/fetal DNA distributions and 5-fluorouracil-induced cell-cycle perturbations

Cell-cycle analysis of nuclei obtained from the circulating erythroblasts (gestational day [GD] 11-16), livers (GD 14-19), and whole embryos (GD 10-13) or remaining (extrahepatic) tissues (GD 14-16) of rat embryos/fetuses revealed age- and tissue-dependent variations in the relative percentages of cells in the G0/G1, S, and G2/M phases of the cell cycle. With development, the rate of cell proliferation declined resulting in decreases in the relative percentage of S-phase cells and increases in the G0/G1 percentage, while the percentage of G2/M-phase cells remained relatively constant. Comparing tissue cell-cycle profiles during development, erythroblasts exhibited the most rapid age-dependent decline in S-phase percentage (from 75% at GD 11 to 8% by GD 14), embryos/extrahepatic tissues exhibited a more gradual reduction (from 55% at GD 10 to 14% by GD 15), while the hepatic isolates exhibited a relatively constant S-phase percentage of approximately 40% from GD 14 to GD 18 before decreasing to 23% at GD 19. These age-dependent variations suggest that cell-cycle distribution may be useful in staging embryogenesis and in detecting abnormal development. To determine how these developmental and organ-specific cell-cycle variations affect toxic response, we sampled GD 11-13 embryos 6 hr after maternal administration of a teratogenic dose of 5-fluorouracil (5-FU), a thymidylate synthetase inhibitor that induces S-phase accumulation. The results indicate that, on a relative basis, the amount of induced S-phase accumulation in erythroblasts and whole embryos 6 hr postdosing increased with development.(ABSTRACT TRUNCATED AT 250 WORDS)