Progesterone receptor activation is required for folic acid-induced anti-proliferation in colorectal cancer cell lines.

Previously, we demonstrated that folic acid (FA) could inhibit proliferation of colorectal cancer cell lines through activating the folate receptor (FR)α/cSrc/ERK1/2/NFκB/p53 pathway and anti-COLO-205 tumor growth in vivo. Since we recently also demonstrated that female sex hormones could affect the FA's action in regulating endothelial cell proliferation and migration, the aim of this study was to investigate the effect of progesterone (P4) on the FA-induced anti-proliferation in colorectal cancer cells. Treatment with FA significantly reduced the proliferation of the P4 receptor (PR)-positive colon cancer cell lines, COLO-205, HT-29 and LoVo, but did not significantly affect the proliferation of the PR-negative colon cancer cell lines, HCT116 and DLD-1. Pre-treatment with Org 31710, a PR specific antagonist, abolished the FA-induced proliferation inhibition and activation in the signaling pathway involved in regulating proliferation inhibition in these PR positive colorectal cancer cell lines. The involvement of PR in the FA-induced activation of cSrc and up-regulations in cell cycle inhibitory proteins (p21, p27 and p53) was confirmed by knock-down of PR expression using the siRNA technique. Importantly, we show direct protein interaction between FR and PR in COLO-205. Moreover, treatment with FA induced PR activation in COLO-205. Taken together, these data suggest that FA induced proliferation inhibition in colon cancer cells through activation of PR. This finding might explain some of the controversies of FA's effects on cancer growth and provide valuable reference for clinical applications of FA in treating colorectal cancer.

Preparation and Characterization of Folate Targeting Magnetic Nanomedicine Loaded with Gambogenic Acid.

To engineer multifunctional nanomedicines for simultaneous imaging and therapy of cancer cells, we have prepared Gambogenic acid (GNA) loaded folic acid (FA) armed MNPs (FA-GNA-MNPs) to target the folate receptor (FR) positive cancer cells. The FA-GNA-MNPs have been prepared by a facile method, which have been further characterized by SEM, TEM, IR and UV-vis spectra. And the cytotoxicity of FA-GNA-MNPs to HeLa and A549 cells was assessed using the MTT assay. The FA-GNA-MNPs (with loading efficiency of 4.35%) showed sustained liberation of GNA molecules (with 73.46% release in 96 h). The mean particle diameter (MD) of FA-GNA-MNPs and the polydispersity index (PDI) are 254.3 nm and 0.139, respectively. The cytotoxicity of free GNA and FA-GNA-MNPs toward HeLa cells showed that FA-GNA-MNPs was more cytotoxic than GNA. Based on these findings, it suggests that FA-GNA-MNPs would be as a novel multifunctional nanomedicine/theranostic for concurrent targeting, imaging and therapy of the FR-positive cancer cells.

Lipid-Polymer Nanoparticles for Folate-Receptor Targeting Delivery of Doxorubicin.

A biocompatible PLGA-lipid hybrid nanoparticles (NPs) was developed for targeted delivery of anticancer drugs with doxorubicin (DOX). The hydrodynamic diameter and zeta potential of DOX-loaded PLGA-lipid NPs (DNPs) were affected by the mass ratio of Lipid/PLGA or DSPE-PEG-COOH/Lecithin. At the 1:20 drug/polymer mass ratio, the mean hydrodynamic diameter of DNPs was the lowest (99.2 1.83 nm) and the NPs presented the encapsulation efficiency of DOX with 42.69 1.30%. Due to the folate-receptor mediated endocytosis, the PLGA-lipid NPs with folic acid (FA) targeting ligand showed significant higher uptake by folate-receptor-positive MCF-7 cells as compared to PLGA-lipid NPs without folate. Confocal microscopic observation and flow cytometry analysis also supported the enhanced cellular uptake of the FA-targeted NPs. The results indicated that the FA-targeted DNPs exhibited higher cytotoxicity in MCF-7 cells compared with non-targeted NPs. The lipid-polymer nanoparticles provide a solution of biocompatible nanocarrier for cancer targeting therapy.

Cancer targeting potential of folate targeted nanocarrier under comparative influence of tretinoin and dexamethasone.

The objective of this investigation was aimed to explore the cancer targeting potential of folate conjugated dendrimer (polypropylene imine, PPI) under strategic influence of folate receptor up-regulators (all trans Retinoic acid, ATRA and Dexamethasone, DEXA). The folate conjugated dendrimer nanoconjugate (FPPI) was synthesized and characterized by FTIR, and (1)H-NMR spectroscopy. The cell line studies investigations were performed on MCF-7 cells. ATRA and DEXA caused 2.17 and 1.65 folds selective up-regulation of folate receptor respectively, when compared with untreated control, after 48 h of pretreatment. ATRA caused 50.47±2.11% more up regulation of folate receptor, than DEXA treated cell. Both up regulators showed a lag phase of 12 h in up-regulating the folate receptors. After 48 h, the IC50 values of naked docetaxel (DTX) and DTX loaded dendrimer (PPI-DTX) were found to be 678.93±11.99 nM and 663.51±15.23 nM, respectively, while DTX loaded folate-anchored dendrimer (FPPI-DTX) showed a selectively lowered IC50 value of 468.56±20.86 nM. FPPI-DTX further showed a significant reduction in IC50 value in ATRA and DEXA pretreated cells, wherein IC50 values of 184.21 nM and 290.40±14.05 nM, respectively were observed. The study also concludes ATRA to be a superior receptor up-regulator as well as promoter of folate based targeting compared to DEXA.