Induction of apoptosis in non-small lung carcinoma cell line (H1299) by combination of anti-asthma drugs with gemcitabine and cisplatin.

Gemcitabine and cisplatin are commonly used in chemotherapy, however, these drugs may cause severe cytotoxic side effects. Theophylline and aminophylline are commonly used as anti-asthma drugs and can block anti-phosphodiesterase activity. We examined whether these methylxanthins could effect lung cancer cell survival and synergise with gemcitabine and cisplatin to induce apoptosis. We found that theophylline induced apoptosis in the cultured H1299 cell line already at concentrations of 30 microg/ml, reaching an ED50% at 100 microg/ml. In contrast, aminophylline induced apoptosis at concentrations of 300 microg/ml and 17% apoptosis was evident at concentrations as high as 900 microg/ml, which is a lethal dose for in vivo treatment. Cisplatin induced apoptosis with ED50% of 0.8 microg/ml, while gemcitabine induced apoptosis with ED50% of 20 ng/ml. Using a combination of 20 microg/ml of theophylline (calculated as an effective but not toxic anti-asthma drug) with 10 ng/ml gemcitabine or with 0.3 microg/ml cisplatin significantly elevated incidence of apoptosis compared to gemcitabine or cisplatin alone at similar concentrations. In contrast, an observed synergistic effect between aminophylline and gemcitabine was evident only at concentrations of 80 microg/ml and 10 ng/ml respectively. However, no effect was apparent in combination doses of aminophylline (80 microg/ml) with cisplatin (0.3 microg/ml). The combined treatments involved reduction in the intracellular level of the anti-apoptotic Bcl-2 gene product. This corresponded with the extent of apoptosis induced by the various drug combinations. Thus, theophylline is significantly more effective than aminophylline in increasing the sensitivity of the H1299 lung cancer cells to the induction of cell death by gemcitabine and cisplatin. Thus, combination of theophylline with these drugs may permit a reduction in the effective dose needed in chemotherapy treatment of lung cancer patients.

Gonadotropin-induced gene regulation in human granulosa cells obtained from IVF patients: modulation of genes coding for growth factors and their receptors and genes involved in cancer and other diseases.

Gonadotropins play a crucial role in ovarian homeostasis and fertilization. However, hypergonadotropin stimulation has been thought to increase the risk for ovarian cancer. Moreover, some correlation between high levels of gonadotropins in the circulation and Alzheimer's disease has been implicated, with no clear evidence on the molecular mechanism involved. Using DNA microarray technology and RNA from gonadotropin-stimulated human granulosa cells, which comprise the main bulk of the ovarian follicular somatic cells, we discovered that stimulation of cells with saturating doses of gonadotropins gives rise to the expression of genes coding for presenilin 1 and 2, along with the up-regulation of genes involved in steroidogenesis such as StAR, cytochrome P450scc enzyme system and aromatase. Moreover, gonadotropin stimulation in these cells dramatically elevates activity of genes coding for epiregulin and amphiregulin, which can bind and activate the EGF receptor and ERB4. These gene products may elevate the risk for ovarian, breast, endometrial and other non-gynecological cancers. Gene transcripts for oncogenes and tumor markers such as pleiomorphic adenoma gene-like 1 (Plagl1) tumor antigen (L6) and claudin 3 were markedly elevated following LH and FSH stimulation. In parallel, downregulation in ovarian cancer 1 (DOC1) and suppression of tumorigenicity (ST5) genes was observed, suggesting a potential increase for cancer development. In contrast, increase in tumor rejection antigen (gp96) 1 and decrease in connective tissue growth factor (CTGF), transforming growth factor-beta 1 induced transcript 1 (TGFB1Il), pim-1 oncogene (PIM1), v-maf musculoaponeurotic fibrosarcoma oncogene homologue (MAF) and CD24 antigen may be associated with a decreased risk for specific cancers. In conclusion, gonadotropin stimulation may modulate specific sets of gene transcripts that may either elevate or reduce the risk for specific diseases.

Induction of polycystic ovary by testosterone in immature female rats: Modulation of apoptosis and attenuation of glucose/insulin ratio.

Polycystic ovarian syndrome is seen in 5% of fertile aged women. However, there is no satisfactory PCOS model in experimental animals. To induce polycystic ovary phenotype in immature female rats, Wistar rats 21 days of age were injected daily with testosterone propionate 1 mg/100 g body weight dissolved in propylene glycol or propylene glycol for up to 35 days. Seven days of injection with testosterone (T) resulted in the appearance of large cystic follicles and a dramatic accumulation of multi-layer preantral follicles. At 42 days of age puberty in control animals was evident by the appearance of corpora lutea. In contrast in T treated animals no corpora lutea formation was seen even at the age of 56 days. Progesterone in the control animals was elevated at the age of 42 days in contrast with the T treated animals in which progesterone remained low (20% of control). While during 14 days of T injection most of the follicles did not have progressive apoptosis, at 21-35 days of injection (42-56 days of age) the vast majority of follicles became apoptotic. Progressive degeneration of oocytes was evident in T treated animals reaching 70-85% of total oocytes at 21-35 days of T injection compared to 30-40% in control animals. Western blot analysis of ovarian homogenates revealed gradual decrease in Bcl-2 content, evident at 28 and 35 days of T injection compared to control animals. Interestingly, the fasting glucose/insulin ratio was dramatically reduced in T treated animals following 14 days of testosterone treatment compared to controls. Our data suggest that T injection to immature female rats can induce polycystic ovaries, block ovulation and attenuate progesterone production. Moreover, normal/low glucose and high insulin blood levels in the testosterone treated rats raises the possibility that elevated androgens can lead to insulin resistance in this experimental PCOS model.

Gonadotrophin-induced gene regulation in human granulosa cells obtained from IVF patients. Modulation of steroidogenic genes, cytoskeletal genes and genes coding for apoptotic signalling and protein kinases.

Gonadotrophins exert a major effect on ovarian development and on the control of fertilization. By stimulating cells with forskolin (FK), it is possible to study which genes are activated by gonadotrophins via the cAMP cascade, and which by alternative pathways. Using RNA isolated from stimulated cells, we found that 59% of the total genes modulated by LH were also modulated by FK, while 69% of the genes modulated exclusively by FSH were also modulated by FK. Gene transcripts involved in steroidogenesis/progesterone production were highly elevated, while 17beta-hydroxysteroid dehydrogenase was down-regulated. This suggests that a decrease in the conversion of androstenedione to testosterone and estrone to estradiol occurs during luteinization. Down-regulation of genes coding for actin cytoskeleton proteins and cytokeratin 18 was observed in response to gonadotrophin and cAMP stimulation. Several of the genes coding for the microtubule network were also modulated, implying that rearrangement of the cytoskeletal proteins permits better coupling between organelles involved in steroidogenesis. A dramatic change in gene transcripts coding for signalling enzymes was observed following LH stimulation. This includes the down-regulation of adenylyl cyclase 7 and 9, elevation of cAMP-dependent phosphodiesterase, and the up-regulation of a negative regulator of G-protein signalling (RGS16) that may negate gonadotrophin signalling via guanine nucleotide binding proteins. Thus luteinized cells, despite increased gene transcripts to LH/chorionic gonadotrophin (CG) receptors, respond inefficiently to gonadotrophin stimulation, due to attenuation of signal transduction in the cAMP cascade at multiple steps. Novel genes involved in the regulation of apoptosis were found for the first time to be up-regulated by gonadotrophin stimulation, including: BAX inhibitor-1, granulysin and apoptosis repressor with caspase recruitment domain (ARC). These proteins may be involved in a unique alternative pathway of ovarian cell death. Such a pathway could temporarily preserve the mitochondria and progesterone production during the initial stages of granulosa cell apoptosis.