Circadian rhythms of DNA synthesis in nasopharyngeal carcinoma cells

Nasopharyngeal carcinoma (NPC) occurs frequently in southern China. The circadian rhythm of DNA synthesis of a poorly differentiated NPC human cell line (CNE2) was investigated as an experimental prerequisite for designing chrono-chemotherapy schedules for patients with this disease. Twenty-two nude mice with BALB/c background were synchronized alternatively in 12 h of light and 12 h of darkness (LD12:12) for at least 3 wk prior to the transplantation of a CNE2 tumor fragment into each flank (area of ∼2×2 mm²). Ten days later, a tumor sample (area of ∼5 mm²) was obtained at 3, 9, 15, and 21 h after light onset (HALO) alternatively from different sites in each mouse. Single-cell suspensions were prepared and stained with propidium iodide. Cellular DNA content was measured with flow cytometry. Data were analyzed by ANOVA and cosinor methods. The average proportion of tumor cells in G₁, S or G₂-M phase varied according to circadian time with statistical significance. The maximum occurred at 9 HALO for G1, 2 HALO for S and 21 HALO for G₂-M phase cells. The approximate average distribution patterns of G₁ and G₂-M phases of cosine curve was 24 h. This was not the case for S-phase cells, which displayed a bimodal temporal pattern. Inter-individual variability in peak time was large, possibly due to relatively sparse sampling time. Nevertheless, no more than 6% of the time series displayed a maximum at 3 HALO for G₁, 21 HALO for S and 15 HALO for G₂-M. The cell cycle distribution of this human NPC cell line displayed circadian regulation following implantation into nude mice. The mechanisms involved in this rhythm and its relevance to the chrono-chemotherapy of patients deserve further investigation.     

The tumor supressor function of STGC3 and its reduced expression in nasopharyngeal carcinoma

STGC3 is a novel candidate tumor suppressor gene that was found to be associated with nasopharyngeal carcinoma (NPC) via the cDNA cloning and RACE processes. The biological function of the STGC3 protein and its expression level in nasopharyngeal carcinoma remain unknown. This study aimed to evaluate the STGC3 protein expression level in NPC and to investigate the inhibitory function of STGC3 as a candidate tumor suppressor gene. We assessed the expression of the STGC3 protein in NPC biopsies and normal control specimens via Western blot and immunohistochemical analysis. The expression of STGC3 as induced by doxycycline (Dox) via a tetracycline (Tet)-regulated system in human nasopharyngeal carcinoma cell line CNE2 was also established, and the effect of STGC3 restoration on the biological behavior of CNE2 was observed. A reduced level of STGC3 expression (0.978 ± 0.213 versus 0.324 ± 0.185, P < 0.05) was detected in NPC versus normal nasopharyngeal tissue by Western blot assay. Immunohistochemical assays for STGC3 detected positive staining in the nuclei and cytoplasm of epithelial cells, and the positive expression rate in NPC, 8 of 21 (38%), was lower than that in normal nasopharynx samples, 16 of 22 (72%). After STGC3 expression was restored, the growth capacity and clone formation potential of CNE2 cells in soft agar were significantly suppressed, and the cell percentage in G₀/G₁ phase increased, while the percentage of cells entering the S and G₂ phases decreased. This indicates that an abnormality in STGC3 expression is associated with nasopharyngeal carcinogenesis and that it may play an important role in controlling cell growth and regulating the cell cycle.     

Pharmacological Modulation of Cisplatin Toxicity Rhythms with Buthionine Sulfoximine in Mice Bearing Pancreatic Adenocarcinoma (PO3)

In a previous report, we showed that the circadian rhythm of cisplatin (cis-diamminedichloroplatinum, CDDP) toxicity in healthy mice was modified by buthionine sulfoximine (BSO), a specific inhibitor of glutathione (GSH) synthesis. In the present study, the effects of BSO on the rhythms of CDDP toxicity and antitumor efficacy were investigated in mice bearing a transplantable pancreatic adenocarcinoma (PO3). B₆D₂F₁ mice were inoculated widi two 4 mm³ tumor fragments, one in each flank, then were synchronized with an alternation of 12h of light (L) and 12h of darkness (D) (LD 12: 12). Three weeks later, a single dose of CDDP (12 mg/kg iv) was injected at 3h, 7h, 11h, 15h, 19h, or 23h after light onset (HALO) with or without prior BSO (450 mg/kg ip 4h earlier). The antitumor activity of CDDP as assessed by tumor weight change and tumor growth delay was weak in this tumor model irrespective of prior BSO administration or CDDP dosing time. Nevertheless, toxic effects of CDDP as gauged by body weight loss or survival varied significantly according to CDDP dosing time. Body weight loss was least in mice receiving CDDP alone at the mid-to-late active span. Survival rate was 97% in mice treated with CDDP alone and 47% in those receiving prior BSO (χ² = 23.6, p <. 0001). BSO pretreatment further shifted the period of survival or body weight change from 24h to (10 + 24)h, an effect similar to that earlier reported in healthy mice. Thus, PO3 tumor at a measurable stage altered neither the circadian rhythm in CDDP toxicity nor the ultradian rhythm in the toxicity of BSO-CDDP combination. The results suggest that rhythms in target tissues for drug actions can be manipulated with biochemical modulators, thus partly escaping central clock control.     

CHRONOTOXICOLOGY OF FLORFENICOL

Sixty 3-month-old homozygote male mice were studied for circadian rhythmicity in the toxicity of florfenicol overdose. Animals were kept under a regimen of 12h light, 12h darkness (12:12 LD) with food and water available ad libitum. The LD₅₀ (median lethal) dose was determined in a preliminary experiment and was administered to groups of 10 mice at six different clock times (hours) after light onset (HALO): 0, 4, 8, 12, 16, and 20 HALO. Cosinor analysis verified a statistically significant (P <. 04) circadian rhythm in the toxic effect (mortality) of florfenicol. Mortality was greatest when the drug was injected 4h after the commencement of the activity span (16 HALO) and least when injected 4h after the start of the diurnal rest span (4 HALO). Mortality was 2.5 times greater when drug injection was given at 16 HALO than at 4 HALO. (Chronobiology International, 18(3), 567–572, 2001)     

Relationship of atypical melatonin rhythm with two circadian clock outputs in B6D2F(1) mice

Circadian rhythms in body temperature, locomotor activity, and the circadian changes of plasma and pineal melatonin content were investigated in B6D2F(1) mice synchronized by 12 h of light and 12 h of darkness. During 8 wk continuous recording, activity and temperature displayed a marked stable and reproducible circadian rhythm, with both peaks occurring near the middle of darkness. Both 24- and 12-h rhythmic components were also significantly detected. Mean plasma melatonin concentration rose steadily during the light span and reached a maximum (30.6 +/- 10.0 pg/ml) at 11 h after light onset (HALO), then gradually decreased after the onset of darkness to a nadir (4.7 +/- 0.4 pg/ml) at 20 HALO. Mean pineal content followed a pattern parallel to that of plasma concentration (peak at 11 HALO: 17.7 +/- 1.0 pg/gland; trough at 17 HALO: 4.7 +/- 1.0 pg/gland). In addition, a second sharp peak was observed at 21 HALO (20.2 +/- 3.5 pg/gland). Plasma and pineal contents displayed large and statistically significant circadian changes, with a composite rhythm of period (24 + 12 h). This mouse model has predominant production and secretion of melatonin during the day. This possibly contributes to a similar coupling between chronopharmacology mechanisms and the rest-activity cycle in these mice and in human subjects.     

Circadian Rhythm of Irinotecan Tolerability in Mice

The toxicity of irinotecan (CPT-11), a topoisomerase-I inhibitor largely used in cancer patients, was investigated as a function of the circadian time of its administration in mice, with mortality, body weight loss, leukopenia, neutropenia, intestinal lesions, and bone marrow cell cycle phase distribution as end points. Four experiments were performed on a total of 773 male mice standardized with 12 h light/12 h darkness. Irinotecan was administered daily for 4 or 10 consecutive days (D1-4 and D1-10, respectively, in different experiments) at one of six circadian stages expressed in hours after light onset (HALO). The survival curves differed significantly as a function of the dosage and circadian time of drug administration by the D1-10 schedule, with 70% survival at 7 or 11 HALO and 51% at 19 or 23 HALO ( p = 0.039 from log rank test). CPT-11 administration at 19 or 23 HALO resulted in (1) greatest mean body weight loss at nadir; (2) most severe colic and bone marrow lesions and/or slowest recovery; and (3) deepest neutropenia nadir and/or slowest hematologic recovery. These circadian treatment time-related differences were statistically validated. The bone marrow cell cycle data revealed a four to eight-fold larger G2-M phase arrest following irinotecan administration at 19 or 23 HALO in comparison to the other times of drug administration, apparently representative of the repair of more extensive DNA damage ( p < 0.001 from ANOVA) when the medication was given at these circadian times. Overall, CPT-11 was better tolerated by mice treated during the light (animals’ rest) span. The results support the administration of CPT-11 to cancer patients in the second half of the night, during sleep, in order to improve drug tolerability.     

Circadian time-dependent differences in murine tolerance to the antihistaminic agent loratadine

Loratadine is a second-generation histamine H(1)-receptor antagonist used in the treatment of allergic diseases. The aim of the study was to assess whether lethal toxicity and motor incoordination (neurotoxicity) of loratadine is circadian rhythm-dependent. A total of 210 male Swiss mice, aged 10 wk, were synchronized for 3 wk to 12 h light (rest span)/12 h dark (activity span). The drug was administered per os. The choice of the sublethal (TD(50) = 82 mg/kg body weight) and the lethal (LD(50) = 4 g/kg body weight) dosage was based on preliminary studies. Each of these two doses was administered to comparable groups of animals at six different circadian time points (1, 5, 9, 13, 17, and 21 Hours After Light Onset [HALO]). The survival duration was dosing time-dependent (chi(2) = 16.96; p < 0.001). Drug dosing at 17 HALO resulted in best (67%) survival rate; whereas, dosing at 9 HALO resulted in poorest (21%) survival rate. Cosinor analyses (with a trial period tau = 24 h) validated a statistically significant circadian rhythm in survival rate (p < 0.04) with an acrophase (peak time ? of best tolerance to loratadine) being at 17.5 HALO +/- 4.65 h. Troughs of motor incoordination were located at the administration times of 5 and 17 HALO (60% and 32% of animals affected, respectively), whereas peaks were located at 9 and 21 HALO (87% and 68% of animals affected, respectively). The 24 h mean of the motor incoordination was 61%, the mean proportion of animals affected by the treatment for the six different circadian times studies. The extent of this neurotoxic effect varied as a function of loratadine dosing time (p < 0.001). A statistically significant ultradian component rhythm (p < 0.01) with a trial period tau = 12 h was also validated. The obtained results show that the dosing time of loratadine at the mid-activity (dark) span seems to be optimal, since it corresponds to the longest (21 vs. 12 days) survival span and to least neurotoxicity.     

Circadian rhythm of irinotecan tolerability in mice

The toxicity of irinotecan (CPT-11), a topoisomerase-I inhibitor largely used in cancer patients, was investigated as a function of the circadian time of its administration in mice, with mortality, body weight loss, leukopenia, neutropenia, intestinal lesions, and bone marrow cell cycle phase distribution as end points. Four experiments were performed on a total of 773 male mice standardized with 12h light/12h darkness. Irinotecan was administered daily for 4 or 10 consecutive days (D1-4 and D1-10, respectively, in different experiments) at one of six circadian stages expressed in hours after light onset (HALO). The survival curves differed significantly as a function of the dosage and circadian time of drug administration by the D1-10 schedule, with 70% survival at 7 or 11 HALO and 51% at 19 or 23 HALO (p=0.039 from log rank test). CPT-11 administration at 19 or 23 HALO resulted in (1) greatest mean body weight loss at nadir; (2) most severe colic and bone marrow lesions and/or slowest recovery; and (3) deepest neutropenia nadir and/or slowest hematologic recovery. These circadian treatment time-related differences were statistically validated. The bone marrow cell cycle data revealed a four to eight-fold larger G2-M phase arrest following irinotecan administration at 19 or 23 HALO in comparison to the other times of drug administration, apparently representative of the repair of more extensive DNA damage (p < 0.001 from ANOVA) when the medication was given at these circadian times. Overall, CPT-11 was better tolerated by mice treated during the light (animals' rest) span. The results support the administration of CPT-11 to cancer patients in the second half of the night, during sleep, in order to improve drug tolerability.     

Circadian Rhythms in Toxic Effects of the Serotonin Antagonist Ondansetron in Mice

The aim of the study was to learn whether the lethal and the motor incoordination (ataxia) side effect of ondansetron (Zophren®) administration is dosing‐time dependent. Ondansetron is a serotonin 5‐HT₃ receptor antagonist used primarily to control nausea and vomiting arising from cytotoxic chemo‐ and radiotherapy. A total of 210 male Swiss mice 10 to 12 weeks of age were synchronized for 3 weeks by 12h light (rest span)/12h dark (activity span). Different doses of ondansetron were injected intraperitoneally (i.p.) at fixed times during the day to determine both the sublethal (TD₅₀) and lethal (LD₅₀) doses, which were, respectively, 3.7 ± 0.6 mg/kg and 4.6 ± 0.5 mg/kg. In the chronotoxicologic study a single dose of ondansetron (3.5 mg/kg, i.p.) was administered to different and comparable groups of animals at four different circadian stages [1, 7, 13, and 19h after light onset (HALO)]. The lethal toxicity was statistically significantly dosing time‐dependent (χ² = 21.51, p < 0.0001). Drug dosing at 1 HALO resulted in 100% survival rate whereas drug dosing at 19 HALO was only one‐half that (52%). Similarly, lowest and highest ataxia occurred when ondansetron was injected at 1 and 19 HALO, respectively (χ² = 22.24, p < 0.0001). Effects on rectal temperature were also dosing‐time related (Cosinor analysis, p < 0.0001). The characteristics of the waveform describing the temporal patterns differed between the studied variables, e.g., lethal toxicity and survival rate showing two peaks and rectal temperature showing one peak in the 24h time series waveform pattern. Cosinor analysis also revealed a statistically significant ultradian (τ ≡ 8h) rhythmic component in the considered variables. Differences in curve patterns in toxicity elicited by ondansetron on a per end point basis are hypothesized to represent the phase relations between the identified 24h and 8h periodicities.     

The in Vitro Effect of Metyrapone on Steroid Synthesis in Mice Adrenals at Different Circadian Stages

The circadian rhythm of the in vitro biosynthesis of Cortisol and cortisone in mice adrenals has been documented in the absence and presence of 0.1 μmol metyrapone, an inhibitor of steroid 11β-monooxygenase. After 3 weeks of synchronization with 12 h light: 12 h darkness, adrenalectomy was performed at eight circadian stages: 0, 4, 9, 10, 13, 16, 21, and 22 h after light onset (HALO). Because it has been shown that mice adrenals could convert exogenous 11 -deoxy-cortisol, the synthesis of 11-oxysteroids (Cortisol + cortisone) in adrenal homoge-nates was studied from tritiated precursor. The pattern of steroid synthesis showed a maximum around the end (10 HALO) and a minimum at the beginning of the resting period (0 HALO); the variation was ～ 10%. A similar pattern was observed in the presence of a ～50% inhibiting dose of metyrapone. On the other hand, the percent inhibition of 11-oxysteroids synthesis was greater at the beginning of the resting period (0 HALO) and minimum around the end of the activity span (21 HALO), with an overall variation of 20%. However, the variations were statistically insignificant (unpaired t test).     

Circadian Time‐Effect of Orally Administered Loratadine on Plasma Pharmacokinetics in Mice

Little is known about the chronopharmacokinetics of loratadine, a long‐acting tricyclic antihistamine H₁ widely used in the treatment of allergic diseases. Hence, the pharmacokinetics of loratadine and its major metabolite, desloratadine, were investigated after a 20 mg/kg dose of loratadine had been orally administered to comparable groups of mice (n=33), synchronized for three weeks to 12 h light (rest span)/12 h dark (activity span). The drug was administered at three different circadian times (1, 9, and 17 h after light onset [HALO]). Multiple blood samples were collected over 48 h, and plasma concentrations of loratadine and desloratadine were determined by high performance liquid chromatography. There were no significant differences in T_max of loratadine and desloratadine between treatment‐time different groups. However, the elimination half‐life (t1/2) of the parent compound and its metabolite was significantly longer (p<0.01) following administration at 9 HALO (t1/2 loratadine and desloratadine 5.62 and 4.08 h at 9 HALO vs. 4.29 and 2.6 h at 17 HALO vs. 3.26 and 3.27 at 1 HALO). There were relevant (p<0.05) differences in C_max between the three treated groups for loratadine and desloratadine; 133.05±3.55 and 258.07±14.45 ng/mL at 9 HALO vs. 104.5±2.61 and 188.62±7.20 ng/mL at 1 HALO vs. 94.33±20 and 187.75±10.79 ng/mL at 17 HALO. Drug dosing at 17 HALO resulted in highest loratadine and desloratadine total apparent clearance values: 61.46 and 15.97 L/h/kg, respectively, whereas loratadine and desloratadine clearances (CL) were significantly slower (p<0.05) at the other administration times (loratadine and desloratadine CL was 57.3 and 14.22 L/h/kg at 1 HALO vs. 43.79 and 12.89 L/h/kg at 9 HALO, respectively). The area under the concentration‐time curve (AUC) of loratadine and desloratadine was significantly (p<0.05) greater following drug administration at 9 HALO (456.75 and 1550.57 (ng/mL) · h, respectively); it was lowest following treatment at 17 HALO (325.39 and 1252.53 (ng/mL) · h, respectively). These pharmacokinetic data indicate that the administration time of loratadine significantly affected its pharmacokinetics: the elimination of loratadine and its major metabolite desloratadine.     

Circadian Dependent Effect of Epidermal Growth Factor,Insulin and Glucagon on Hepatic Pyruvate Kinase and Malic Enzyme of Mice

The influence of epidermal growth factor (EGF), 0.75 μg g^?1; insulin, 1.5 μg g^?1; glucagon, 1.25 ygg^?1 and their combinations on the activities of hepatic pyruvate kinase (PK) and malic enzymes (ME) was monitored. Male CD2F₁ mice were treated toward the end of the light or dark periods, 9 or 23 /tours after /ights on (9 or 23 HALO), and subgroups of six mice were killed at 4,8 or 12 hr post-treatment. PK and ME activities from control mice were well characterized by cosine curves. The PK activity was maximal when ME activity was minimal at the transition from light to dark (9 HALO plus 4 hr) and PK was at a minimum when ME was highest (23 HALO plus 4 hr). Both enzymes were influenced by at least one peptide hormone, and the effects were strongly circadian -stage dependent. The only effect attributed to EGF was an increase of PK activity (23%) 12 hr after injection at 23 HALO. PK activity was increased by insulin (23%) at 23 HALO (4 hr after injection), but not at 9 HALO, and decreased (17%) by glucagon 12 hr after injection at 9 HALO. Several reductions in PK activity in response to various combinations of peptides were observed, and appeared to be caused by glucagon but influenced by insulin. The activity of ME was decreased (33%) in response to insulin 4 hr after injection at 23 HALO but not at 9 HALO and increased (60-70%) by glucagon alone or in combinations with insulin or EGF, or both, at 4 hr after injection at 9 HALO but not at 23 HALO. In general, when ME activity was altered by either insulin or glucagon, PK activity was also altered in the opposite direction, and the effects of glucagon were opposed by insulin.     

Seasonal Modulation of the 8‐and 24‐Hour Rhythms of Ondansetron Tolerance in Mice

Ondansetron (Zophren®) is a serotonin 5HT₃-receptor antagonist used primarily to control nausea and vomiting caused by cytotoxic chemo‐and radio‐therapy. Tolerance to this drug shows both 24 and 8 h periodicities. In this framework, this study aimed to determine whether these ondansetron tolerance rhythms are modulated by season. The chronotoxic effect of a fixed dose (3.5 mg/kg, i.p.) of the drug was investigated with reference to both time of the day and year dependencies. Season‐related studies were performed on 560 male Swiss mice, 10 to 12 wks old, synchronized with L:D=12:12 for three weeks. During a 1 yr span (2005), four 24 h studies were performed with a single dosing time at 1, 7, 13, and 19 hours after light onset (HALO), respectively. Tolerance was assessed daily during a 40‐day span after acute ondansetron treatment. Both χ² test and cosinor methods were used to analyze the time series data. Statistically significant dosing time‐dependent changes were validated in both yearly and daily time scales. The 24 h mean survival rate peaked in spring (92%) compared to fall (72%), the 20% difference being statistically significant (χ² test with p<0.05 and cosinor with p<0.0001 for seasonal rhythm detection and with a peak time, Ø,=April 3±6.6 days). A 24 h rhythm was also detected in each of the seasonal time points. However, the curve pattern was monophasic in fall as well as spring. In fall, a large amplitude (A) circadian rhythm was detected that peaked at 19 HALO, while in the spring, a small circadian rhythm was detected that peaked at 1 HALO. The curve pattern was biphasic in summer (with large A) and in winter (with a small A). The existence of two peaks of equal magnitude in winter (100% survival rate) and in summer (100% and 90%) suggests the presence of both circadian and ultradian rhythms rather than an ultradian component of the 24 h period. The seasonal modulation of ondansetron circadian chronotolerance seems to involve several rhythm parameters: season‐related changes in the 24 h mean (M), amplitude (A), acrophase location (Ø), as well as bimodal curve patterns including the coexistence of rhythms with respectively 24 and 8 h periods in winter and summer. In conclusion, tolerance to ondansetron varies not only according to the 24 and 8 h periods but also according to seasons, which suggests the complexity of ondansetron toxicity rhythms. Seasonal modulation of ondansetron tolerance may also influence the strategies of chemo‐and chrono‐therapy, and it is therefore necessary to take it into account in clinical drug‐delivery protocols to minimize side effects of cytotoxic anticancer and antiemetic agents.     

Chronotoxicology of florfenicol

Sixty 3-month-old homozygote male mice were studied for circadian rhythmicity in the toxicity of florfenicol overdose. Animals were kept under a regimen of 12h light, 12h darkness (12:12 LD) with food and water available ad libitum. The LD50 (median lethal) dose was determined in a preliminary experiment and was administered to groups of 10 mice at six different clock times (hours) after light onset (HALO): 0, 4, 8, 12, 16, and 20 HALO. Cosinor analysis verified a statistically significant (P < .04) circadian rhythm in the toxic effect (mortality) of florfenicol. Mortality was greatest when the drug was injected 4h after the commencement of the activity span (16 HALO) and least when injected 4h after the start of the diurnal rest span (4 HALO). Mortality was 2.5 times greater when drug injection was given at 16 HALO than at 4 HALO.     

The in Vitro Effect of Metyrapone on Steroid Synthesis in Mice Adrenals at Different Circadian Stages

The circadian rhythm of the in vitro biosynthesis of Cortisol and cortisone in mice adrenals has been documented in the absence and presence of 0.1 μmol metyrapone, an inhibitor of steroid 11β-monooxygenase. After 3 weeks of synchronization with 12 h light: 12 h darkness, adrenalectomy was performed at eight circadian stages: 0, 4, 9, 10, 13, 16, 21, and 22 h after light onset (HALO). Because it has been shown that mice adrenals could convert exogenous 11 -deoxy-cortisol, the synthesis of 11-oxysteroids (Cortisol + cortisone) in adrenal homoge-nates was studied from tritiated precursor. The pattern of steroid synthesis showed a maximum around the end (10 HALO) and a minimum at the beginning of the resting period (0 HALO); the variation was ∼ 10%. A similar pattern was observed in the presence of a ∼50% inhibiting dose of metyrapone. On the other hand, the percent inhibition of 11-oxysteroids synthesis was greater at the beginning of the resting period (0 HALO) and minimum around the end of the activity span (21 HALO), with an overall variation of 20%. However, the variations were statistically insignificant (unpaired t test).     

6-O-Angeloylenolin induced cell-cycle arrest and apoptosis in human nasopharyngeal cancer cells

High incidence of lymph node spread and distant metastasis make poor prognosis in human nasopharyngeal carcinoma (NPC). Therefore, better treatments for NPC are needed. This study investigated the anticancer activity of 6-O-angeloylenolin, a plant-derived sesquiterpene lactone, on human nasopharyngeal cancer (CNE) cells. 6-O-Angeloylenolin was found to significantly inhibit the proliferation of CNE cells. The rate of inhibition was comparable to that of cisplatin, a well known chemotherapeutic agent used to treat NPC. Further mechanistic studies revealed that 6-O-angeloylenolin caused cell-cycle arrest in the S and G2/M phases and, subsequently, the induction of apoptosis. Rapid repressions of cyclin D1, cyclin D3, p27, cdc25c and p-cdc25c (Ser216) were observed after 1-h treatment, followed by decreases in the expression of CDK4, cdc2 and p-cdc2 (Tyr15) after 12 h. Down-regulations of p-Rb (Ser780), p21^Waf1/Cip1, cyclin A, and cyclin E were also detected as later events. Two early events that marked the occurrence of apoptosis were phosphatidylserine exposure and mitochondria membrane potential depletion, which occurred after 12 h of treatment, while a sub-G1 peak was also detected after 36-h treatment. Apoptosis induction was further confirmed by other apoptotic features, including nuclear fragmentation, and PARP cleavage. Moreover, 6-O-angeloylenolin caused the release of cytochrome c and AIF to the cytosol by regulating the expression of the Bcl-2 family proteins. However, pretreatment of the general caspase inhibitor failed to attenuate the apoptosis induction effect, suggesting that apoptosis induction of 6-O-angeloylenolin was independent of caspase activation. While 6-O-angeloylenolin also triggered the activation of Akt, ERK and JNK, only the JNK inhibitor significantly decreased the extent of cell death and apoptosis in CNE cells. Taken together, these results suggest the potential applicability of 6-O-angeloylenolin as a candidate for NPC treatment.     

A Novel Triterpenoid Isolated from the Root Bark of Ailanthus excelsa Roxb (Tree of Heaven), AECHL-1 as a Potential Anti-Cancer Agent

Background

We report here the isolation and characterization of a new compound Ailanthus excelsa chloroform extract-1 (AECHL-1) (C₂₉H₃₆O₁₀; molecular weight 543.8) from the root bark of Ailanthus excelsa Roxb. The compound possesses anti-cancer activity against a variety of cancer cell lines of different origin.

Principal Findings

AECHL-1 treatment for 12 to 48 hr inhibited cell proliferation and induced death in B16F10, MDA-MB-231, MCF-7, and PC3 cells with minimum growth inhibition in normal HEK 293. The antitumor effect of AECHL-1 was comparable with that of the conventional antitumor drugs paclitaxel and cisplatin. AECHL-1-induced growth inhibition was associated with S/G₂-M arrests in MDA-MB-231, MCF-7, and PC3 cells and a G₁ arrest in B16F10 cells. We observed microtubule disruption in MCF-7 cells treated with AECHL-1 in vitro. Compared with control, subcutaneous injection of AECHL-1 to the sites of tumor of mouse melanoma B16F10 implanted in C57BL/6 mice and human breast cancer MCF-7 cells in athymic nude mice resulted in significant decrease in tumor volume. In B16F10 tumors, AECHL-1 at 50 µg/mouse/day dose for 15 days resulted in increased expression of tumor suppressor proteins P53/p21, reduction in the expression of the oncogene c-Myc, and downregulation of cyclin D1 and cdk4. Additionally, AECHL-1 treatment resulted in the phosphorylation of p53 at serine 15 in B16F10 tumors, which seems to exhibit p53-dependent growth inhibitory responses.

Conclusions

The present data demonstrate the activity of a triterpenoid AECHL-1 which possess a broad spectrum of activity against cancer cells. We propose here that AECHL-1 is a futuristic anti-cancer drug whose therapeutic potential needs to be widely explored for chemotherapy against cancer.     

Rhythmic Variations of Pharmacokinetic Processes of Cyproterone Acetate in Rabbits

A study about the influence of administration time on pharmacokinetics of Cyproterone acetate in rabbits was performed. Thirty animals were distributed in six groups, each corresponding to a different time: 2, 6, 10, 14, 18 and 22 hours after light onset (HALO). Rabbits received a single intravenous administration of 4 mg kg^-1 Cyproterone acetate. Blood samples were taken and processed by high performance liquid chromatography. Plasmatic data were fitted to a biexponential equation. Concentration at zero time (Co), concentration at zero time extrapolated from the distribution phase (A), hybrid constant for distribution phase and its half life, volume of the central compartment (V_c), volume of distribution at steady state (V_ss), constants for transferring the drug from the central compartment to the exterior (K₁₀) and from the central to the peripheral compartment presented chronobiological variations (p < 0.05) and were fitted to a cosine equation. The following parameters adjusted to circadian rhythms: Co (Acrophase: 1.72 HALO); A (Acrophase: 4.09 HALO); V_c (Acrophase: 11.92 HALO); V_ss (Acrophase: 10.12 HALO) and K₁₀ (Acrophase: 3.59 HALO). It was concluded that pharmacokinetics of intravenously injected CPA in rabbits would behave in a different, though predictable, manner according to the animal's biological clock.