Introduction
Experimental
Results
Cytotoxic effect of various concentrations (20, 40, 60, 80, 100, 120, 140 and 160) μg/mL of F. angulata Boiss. flower and leaf extracts on AGS cells at 24 h and 48 h. A) The percentage of cytotoxicity values were measured with neutral red and B) The percentage of cytotoxicity values were measured with trypan blue assays. Bars are represented by the mean ± S.E.M. of three independent experiments (n = 3). (p <0.05 vs. control group).
| A) Trypan blue assay | |||||||||
|---|---|---|---|---|---|---|---|---|---|
| Concentrationμg/mL | |||||||||
| Plant part | 20 | 40 | 60 | 80 | 100 | 120 | 140 | 160 | |
| Leaves | 24 h | 13.0±2.08 | 25.0±1.52 | 32.0±3.05 | 41.0±2.64 | 51.0±1.52 | 70.0±2.08 | 85.0±1.52 | 100.0±0 |
| 48 h | 22.0±2.51 | 39.67±2.18 | 54.0±1.52 | 66.0±2.30 | 82.0±3.05 | 100.0±0 | 100.0±0 | 100.0±0 | |
| Flowers | 24 h | 10.0±2.513 | 14.67±2.90 | 24.0±2.52 | 29.33±1.20 | 40.0±1.15 | 54.0±3.05 | 76.0±1.73 | 88.0±1.53 |
| 48 h | 15.0±2.08 | 30.0±2.31 | 46.0±1.53 | 62.0±2.52 | 71.0±1.15 | 92.0±2.0 | 100.0±0 | 100.0±0 | |
| S.E.M. = Standard error of the mean. | |||||||||
| B) Neutral red assay | |||||||||
| Concentration μg/mL | |||||||||
| Plant part | 20 | 40 | 60 | 80 | 100 | 120 | 140 | 160 | |
| Leaves | 24 h | 3.85±0.63 | 18.05±1.25 | 38.05±1.47 | 51.67±0.90 | 75.62±1.79 | 84.91±0.41 | 100.0±0 | 100.0±0 |
| 48 h | 19.45±0.26 | 50.87±0.58 | 77.80±0.70 | 100.0±0 | 100.0±0 | 100.0±0 | 100.0±0 | 100.0±0 | |
| Flowers | 24 h | 3.84±1.29 | 8.77±2.32 | 33.04±0.93 | 38.73±0.91 | 49.93±0.76 | 69.27±1.19 | 86.68±0.79 | 100.0±0 |
| 48 h | 14.75±1.79 | 37.06±1.48 | 67.05±0.54 | 85.62±0.92 | 100.0±0 | 100.0±0 | 100.0±0 | 100.0±0 | |
| Plant part tested | Extracts | IC50 (µg/mL) | IC50 (µg/mL) | IC50 (μg/mL) | IC50 (μg/mL) 48 h Neutral Red assay |
|---|---|---|---|---|---|
| Leaves | Ethanolic | 82.20 | 60.41 | 76.65 | 61.70 |
| Flowers | Ethanolic | 101.81 | 74.00 | 89.84 | 63.50 |
DNA fragmentation assay in AGS cells treated with different concentrations of F. angulata Boiss. leaf and flower extracts by 1% agarose gel electrophoresis (M stands for DNA marker, C stands for control, D stands for 1% DMSO–treated cells). A) AGS cells treated with 160 µg/mL (line 1), 200 µg/mL (line 2) leaf extracts for 24 h. B) AGS cells treated with leaf extracts for 48 h. 1 stands for 80 µg/mL. 2 stands for 120 µg/mL. 3 stands for 160 µg/mL. 4 stands for 200 µg/mL. C) AGS cells treated with 200 µg/mL (line 1), 240 µg/mL (line 2) flower extracts for 24 h. D) AGS cells treated with flower extract for 48 h. 1 stands for 120 µg/mL. 2 stands for 160 µg/mL. 3 stands for 200 µg/mL. 4 stands for 240 µg/mL.
Annexin V–FLUOS and PI staining of AGS cells treated with F. angulata Boiss. leaf and flower extracts for 24 h. Early apoptotic cells with only Annexin V–FLUOS positive staining were recognized by green plasma membrane (red arrows), while late stage apoptotic cells with both Annexin V–FLUOS and PI positive staining were observed with green membrane and red nucleus (white arrows). A) and B) Untreated AGS cells observed under inverted microscope and fluorescence microscope, respectively. C) and D) AGS cells treated with 80 μg/mL and 160 μg/mL concentrations of F. angulata Boiss. leaf extracts, respectively. E) and F) AGS cells treated with 80 μg/mL and 160 μg/mL concentrations of F. angulata Boiss. flower extracts, respectively. Magnification 200X
Flow cytometric analysis by Annexin V–FLUOS (FL1-H) in x-axis and PI (FL2-H) in y-axis double staining of AGS cells treated with F. angulata Boiss. leaf and flower extracts at 24 h. Living cell (Annexin V−/PI−) populations were located in the lower left quadrant (LL), the apoptotic cells stained by annexin V and unstained by propidium iodide in the lower right quadrant (LR), late apoptotic (Annexin V+/PI+) populations were located in the upper right quadrant (UR), and necrotic cell (Annexin V−/PI+) populations were presented in the upper left quadrant (UL). Dot plots of Annexin V/PI staining are shown in A) (untreated AGS cells), B) (1% DMSO-treated AGS cells), C) AGS cells treated with 80 μg/mL F. angulata leaf extracts exhibited 14.5% late stage apoptosis and 20.67% early stage apoptosis, D) AGS cells treated with 160 μg/mL of F. angulata Boiss. leaf extracts had 49.13% late stage apoptosis and 26% early stage apoptosis, E) AGS cells treated with 80 μg/mL F. angulata flower extracts showed 25.55% late stage apoptosis, 17.92% early stage apoptosis, F) AGS cells treated with 160 μg/mL F. angulata Boiss. flower extracts showed 45.80% late stage apoptosis, 24.15% early stage apoptosis (P < 0.05).



