Phytoestrogens are some plant compounds exhibiting estrogen-like activities. However, some studies have shown that they also affect the growth of some nonhormone-dependent diseases. In this study, daidzein--one of the most common phytoestrogens--was used to investigate its effects on human cervical cancer cells HeLa in vitro. First, the cell growth was measured by using 3-(4,5-dimethylthiazol-2-yl)-2,5-diphenyl tetrazolium bromide (MTT) assay. Then, the distributions of cell cycle and apoptosis were analyzed with the help of flow cytometry. Finally, the telomerase activity was detected by using real-time quantitative reverse transcription-polymerase chain reaction. The results showed that at the concentrations from 6.25 to 100 micro mol/l, daidzein inhibited the growth of HeLa cells. Flow cytometric analysis showed that cancer cells were arrested at G(0)/G(1) or G(2)/M phase with daidzein. The inductive effects of apoptosis were more obviously observed in low-concentration groups. After HeLa cells were treated with daidzein, the expression of human telomerase catalytic subunit mRNA decreased. These meant that daidzein affected human nonhormone-dependent cervical cancer cells in several ways, including cell growth, cell cycle, and telomerase activity in vitro.
Of all neoplasms found in women, cervical cancer has the third highest incidence and causes the fourth most deaths. All-trans retinoic acid (ATRA) may be with chemopreventive potential on cervical cancer, but the mechanisms underlying is not clear. To investigate the mechanisms, human cervical cancer HeLa cells were treated with ATRA for 1, 2, 3, or 4 days in vitro. We found that ATRA inhibited the growth of HeLa cells in a dose-dependent manner at the concentrations from 0.3 to 9.6 mumol/L. Flow cytometric analysis showed that HeLa cells were arrested at G0/G1 phase by ATRA, and the aneuploidy was found when cells were treated for 4 days, which is the first report that ATRA causes aneuploid cycle in HeLa cells. The expression of human telomerase catalytic subunit messenger RNA was decreased remarkably by ATRA. These findings suggested that the inhibition of telomerase activity and arrest of cells at G0/G1 phase might be the key steps through which ATRA inhibits the proliferation of HeLa cells. Our results provide a possible mechanistic explanation for the growth inhibitory effect of ATRA on HeLa cells. Therefore, retinoids may have therapeutic potential to complement current treatments of cervical cancers.
Phytoestrogens are some plant compounds exhibiting estrogen-like activities. However, some studies have shown that they also affect the growth of some nonhormone-dependent diseases. In this study, daidzein – one of the most common phytoestrogens – was used to investigate its effects on human cervical cancer cells HeLa in vitro. First, the cell growth was measured by using 3-(4,5-dimethylthiazol-2-yl)-2,5-diphenyl tetrazolium bromide (MTT) assay. Then, the distributions of cell cycle and apoptosis were analyzed with the help of flow cytometry. Finally, the telomerase activity was detected by using real-time quantitative reverse transcription-polymerase chain reaction. The results showed that at the concentrations from 6.25 to 100 μmol/l, daidzein inhibited the growth of HeLa cells. Flow cytometric analysis showed that cancer cells were arrested at G0 / G1 or G2 / M phase with daidzein. The inductive effects of apoptosis were more obviously observed in low-concentration groups. After HeLa cells were treated with daidzein, the expression of human telomerase catalytic subunit mRNA decreased. These meant that daidzein affected human nonhormone-dependent cervical cancer cells in several ways, including cell growth, cell cycle, and telomerase activity in vitro.
The effects of E. coli endotoxin administration on hepatic glycogen phosphorylase activities in dogs were investigated. Hepatic glycogen phosphorylase activities in both control and endotoxic dogs were inactivated spontaneously by preincubation of enzyme preparations at 25 degrees C. Total glycogen phosphorylase activity was not significantly altered during preincubation. The activity of glycogen phosphorylase a was increased by 83 and 80% at 1 and 2 hr postendotoxin, respectively, without preincubation; and by 203 and 133% at 1 and 2 hr postendotoxin, respectively, after 30 min preincubation. Without preincubation, the glycogen phosphorylase percentage a activity was increased from the control value of 37 to 58% at 1 hr postendotoxin and to 53% at 2 hr postendotoxin. After 30 min preincubation, the glycogen phosphorylase percentage a activity was increased from the control value of 10 to 28% at 1 hr postendotoxin and to 20% at 2 hr postendotoxin. The time required for half maximum inactivation of percentage a activity was 16.5, 33, and 24 min for control, 1 and 2 hr postendotoxin, respectively. Although the Vmax and Km for glucose-1-P for total glycogen phosphorylase were not affected by endotoxin administration, the Vmax for glucose-1-P for glycogen phosphorylase a was increased by 57.3 and 42.7% at 1 and 2 hr postendotoxin, respectively, with no change in the Km values. Glucose inhibited glycogen phosphorylase a activity both in control and endotoxin-injected dogs, but the I50 value was increased by 35% in endotoxin-injected (2 hr) dogs. AMP activated glycogen phosphorylase b activity both in control and endotoxin-injected dogs with no change in A0.5 values between the two groups.(ABSTRACT TRUNCATED AT 250 WORDS)
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