Cytotoxic Effects of Ethanolic Extract of Polypodium Vulgare on Human Malignant Melanoma Cell Line.

BACKGROUND: Melanoma is a malignant tumor that originates from the skin's melanocytes and has the highest death rate from skin cancer. Developing more efficacious anticancer medications with fewer adverse effects is the key to effective cancer management. Natural products are considered relevant and cost-effective sources of treatment. The plant (Polypodium vulgare) is a small and evergreen fern. One of the most important chemical compounds in the extract of this herb is flavonoids, which are thought to have beneficial effects in the treatment of melanoma through antioxidant properties. OBJECTIVES: Due to the limitations of current cancer management and cytotoxic drugs available in the country, the need to study drugs of natural origin has become more prominent. In this regard, the present study aims to investigate the cytotoxic effects of the ethanolic extract of Polypodium vulgare on A375 melanoma cells. METHODS: Polypodium vulgare was extracted in 80% ethanol by the maceration. Then, its effects on the cell death of the melanoma cell line A375 compared to the AGO-1522 cell line as control were measured using the MTT-assay technique. The amount of cellular lipid peroxidation was estimated by TBARS assay. The amount of cellular ROS was calculated by fluorescent reagent 2,7-dichlorofluorescein diacetate. Cytochrome c concentration was measured by a cytochrome c immunoassay kit. RESULTS: In this experiment, the anticancer effects of Polypodium vulgare ethanolic extract on human melanoma cell lines were investigated for the first time. Herb extract with a concentration of 0.123 mg/ml significantly increased the death of A375 melanoma cells (p < 0.001), lipid peroxidation (p < 0.01), and reactive oxygen species (ROS) (p < 0.01) and cytochrome c concentration (p < 0.001). Meanwhile, the same amount was ineffective and safe on AGO-1522 normal fibroblast cells. CONCLUSION: A 0.123 mg/ml concentration of Polypodium vulgare increases apoptosis in melanoma cells. Meanwhile, the same amount was safe on healthy cells. So, it could be considered an effective treatment without side effects in human melanoma.

Short-term administration of Polypodium leucotomos extract does not inhibit CYP3A4-mediated metabolism of midazolam in healthy subjects: an open-label, two-period, fixed-sequence study.

The extract of Polypodium leucotomos is used as a dietary supplement for its ultraviolet radiation-protective properties. Polypodium leucotomos extract reportedly inhibits CYP3A, which is important for drug metabolism in vitro in human microsomes and in vivo in rats. In this study, we explored the inhibitory effect of the P. leucotomos extract on CYP3A4-mediated midazolam metabolism in humans. This open-label, two-period, fixed-sequence study was performed on six healthy, Japanese, male volunteers. During period 1 (control), midazolam (1 mg) was orally administered. After a wash-out period of at least 5 days, period 2 was initiated. Subjects ingested P. leucotomos extract (240 mg) once in the morning and once at noon on the day before midazolam administration, and once the next morning (thrice overall). Midazolam was administered as in period 1. Blood samples were regularly collected for 8 hours after drug administration, and serum midazolam concentration was determined by ultra-fast liquid chromatography-tandem mass spectrometry. The pharmacokinetic parameters of midazolam were calculated and compared between the two periods. The area under the concentration-time curve was 19.18 ± 3.65 ng h/ml, maximum serum concentration was 7.81 ± 1.25 ng/ml, and half-life was 2.32 ± 0.35 hours during period 2. These parameters did not differ from those recorded in period 1 (area under the concentration-time curve: 18.74 ± 2.97 ng h/ml, maximum serum concentration: 8.78 ± 1.67 ng/ml, half-life: 2.52 ± 0.52 h). Therefore, short-term oral administration of P. leucotomos extract did not cause food-drug interactions mediated by CYP3A4 inhibition in humans.

Discovery of polypodiside as a Keap1-dependent Nrf2 activator attenuating oxidative stress and accumulation of extracellular matrix in glomerular mesangial cells under high glucose.

Diabetic nephropathy (DN) is a severe microvascular complication of diabetes mellitus. High glucose has resulted in oxidative stress and following renal fibrosis as the crucial nodes of this disease. Nuclear factor erythroid 2-related factor 2 (Nrf2) is a transcription factor regulating transcription of many antioxidant genes and suppressing synthesis of extracellular matrix. To discover Nrf2 activators targeting DN, we have evaluated polypodiside using cell-based assays. The results showed polypodiside inhibited the high glucose-induced self-limited proliferation of glomerular meangial cells. Activation of Nrf2 and enhanced transcription to antioxidant response elements were observed in the presence of polypodiside. Oxidative stress and accumulation of extracellular matrix induced by high glucose in glomerular meangial cells have been ameliorated by polypodiside. Further investigations revealed the effects of polypodiside on glomerular meangial cells were associated with activation of Nrf2. Co-immunoprecipitation of Nrf2 disclosed polypodiside disrupted the Kelch-like ECH-associated protein-1 (Keap1)-Nrf2 interaction. Molecular docking elucidated polypodiside could enter the Nrf2 binding cavity of Keap1 via interacting with the residues encompassing that cavity. These findings indicate polypodiside is a Keap1-dependent Nrf2 activator affording the catabatic effects against oxidative stress and accumulation of extracellular matrix in glomerular meangial cells under high glucose.

Guard cells in fern stomata are connected by plasmodesmata, but control cytosolic Ca2+ levels autonomously.

Recent studies have revealed that some responses of fern stomata to environmental signals differ from those of their relatives in seed plants. However, it is unknown whether the biophysical properties of guard cells differ fundamentally between species of both clades. Intracellular micro-electrodes and the fluorescent Ca2+ reporter FURA2 were used to study voltage-dependent cation channels and Ca2+ signals in guard cells of the ferns Polypodium vulgare and Asplenium scolopendrium. Voltage clamp experiments with fern guard cells revealed similar properties of voltage-dependent K+ channels as found in seed plants. However, fluorescent dyes moved within the fern stomata, from one guard cell to the other, which does not occur in most seed plants. Despite the presence of plasmodesmata, which interconnect fern guard cells, Ca2+ signals could be elicited in each of the cells individually. Based on the common properties of voltage-dependent channels in ferns and seed plants, it is likely that these key transport proteins are conserved in vascular plants. However, the symplastic connections between fern guard cells in mature stomata indicate that the biophysical mechanisms that control stomatal movements differ between ferns and seed plants.

Zinc tolerance and accumulation in the ferns Polypodium cambricum L. and Pteris vittata L.

Zn uptake and compartmentalisation were studied in two ferns, the European Polypodium cambricum L., a possible Zn tolerant, and the sub-tropical Pteris vittata L., an As accumulator also able to accumulate Zn. Ferns growing in hydroponic systems were exposed to Zn concentrations ranging from non-toxic to lethal doses (0, 50, 125, 250, 500 mg kg(-1) as ZnSO4). After treatments, the following analyses were made: photosynthetic efficiency (Handy PEA), anatomical symptoms (optical and scanning electron microscopy), determination of Zn in fronds, rhizome and roots (atomic emission spectrometry, ICP-AES). Both species showed high bioconcentration and bioaccumulation factors, but low translocation factor, indicating Zn sequestration in the root/rhizome system. P. cambricum was more resistant to Zn, while P. vittata suffered from unrestricted uptake leading to macro- and microscopical damages and plant death. Data suggest that P. cambricum could be suitable for phytostabilisation of Zn-contaminated soils in temperate areas.

Phenolic compound localisation in Polypodium vulgare L. rhizomes after mannitol-induced dehydration and controlled desiccation.

Polypodium vulgare L. is a desiccation-tolerant fern that can withstand successive dry periods in its life cycle. To better understand this mechanism, the current study was undertaken to assess the role of phenolic compounds in rhizome dehydration and determine their localisation in the rhizome cells after enforced dehydration in mannitol solution or controlled desiccation with or without abscisic acid (ABA) pretreatment. Phenolic distribution at the subcellular level was studied using gold particle-complexed laccase. Cells from different tissues: cortical parenchyma, endodermis and stelar elements--pericycle, sieve cells and vascular parenchyma were observed under a transmission electron microscope (TEM). The content of phenolic compounds was greater in ABA-untreated rhizomes after enforced dehydration in mannitol solution and subsequent rehydration. After controlled desiccation the phenolic content significantly increased in ABA-untreated rhizomes. A large number of phenolic compound deposits were present in all types of rhizomatous cells. Phenolics were widely distributed in the vacuoles of all cells, and in the secondary cell walls of sieve cells, although scattered labelling was hardly ever observed in the primary cell walls. In dehydrated and plasmolysed cells from the cortex and endodermis, phenolic compounds were present in the apoplastic compartments between the plasma membranes and the cell walls. There is evidence that abscisic acid plays a role as a crucial antioxidant resulting in no damage and a lower level of phenolic increase as compared to ABA-untreated rhizomes. Moreover, the location of phenolics suggests a protective chemical barrier against environmental stresses.

The first cytochrome P450 in ferns. Evidence for its involvement in phytoecdysteroid biosynthesis in Polypodium vulgare.

The fern Polypodium vulgare is a phytoecdysteroid (PE)-producing plant. Cultures of P. vulgare prothalus produce PE, whereas prothalus-derived callus cultures do not. However, this callus line can transform topically applied ecdysone (E) to 20-hydroxyecdysone (20E), which is the last step in the biosynthetic pathway of the main plant PE. This hydroxylation is catalysed by a cytochrome P450 enzyme. E treatment of the callus line results in an increased amount of P450, showing a linear correspondence between the amount of P450 and in vivo E 20-hydroxylation activity, estimated by measuring the bioconversion of E to 20E. This activity can be inhibited by molecules that bind to the P450-heme group. E shows a P450-substrate-binding spectrum with microsomes that overexpress the P450 protein. Finally, a P450 protein was purified from E-treated calli, this being the first P450 to be described in the pterydophyte group.

Biotransformations of putative phytoecdysteroid biosynthetic precursors in tissue cultures of Polypodium vulgare.

Incubation of calli and prothalli of Polypodium vulgare with different tritium-labelled ecdysteroids has led to modification of some previous assumptions about the biosynthesis of ecdysteroids in plants. Thus, 25-deoxy-20-hydroxyecdysone was transformed efficiently in both tissues into 20-hydroxyecdysone (20E), but no 25-deoxyecdysteroids such as pterosterone and inokosterone were formed. Likewise, incubation of 2-deoxyecdysone (2dE) produced exclusively ecdysone (E) and 20E, indicating a high 2-hydroxylase activity in both tissues, despite calli not producing phytoecdysteroids. This 2-hydroxylation was also evident in the transformation of 2,22-dideoxyecdysone (2,22dE) into 22-deoxyecdysone (22dE). Different ecdysteroids that do not occur in P. vulgare were formed in the incubation of 3-dehydro-2,22,25-trideoxyecdysone (3D2,22,25dE) by 3alpha-reduction and 3beta-reduction and 25-hydroxylation processes. The fact that 22,25-dideoxyecdysone and 22dE were the only 2-hydroxylated products formed in this case suggests that only compounds bearing a 3beta-hydroxyl group are substrates for the 2-hydroxylase. Surprisingly, 22-hydroxylation was never observed with either 2,22dE or 3D2,22,25dE, raising the possibility that it could occur at an early step in the biosynthetic pathway. In this respect, labelled 22R-hydroxycholesterol was efficiently converted into E and 20E, whereas 22S-hydroxycholesterol was not transformed into ecdysteroids, because of its unsuitable configuration at C22. Finally, the conversion of 25-hydroxycholesterol into E and 20E was greatly enhanced after thermal treatment of prothalli which induces the release of previously stored ecdysteroids. Thus, P. vulgare prothalli and calli appear to be particularly suitable models for the study of ecdysteroid biosynthesis and its regulation in plants.