Induction of early growth response protein-1 gene expression in the rat ovary in response to an ovulatory dose of human chorionic gonadotropin.

Granulosa cells in a mature ovarian follicle have an abundance of LH/hCG receptors that respond rapidly to an ovulatory surge in gonadotropins. Within minutes, membrane signal transduction sets in motion metabolic changes that lead to follicular rupture. This study provides evidence that the initial ovarian response to such an ovulatory stimulus includes induction of the immediate-early transcription factor gene for early growth response protein-1 (Egr-1). Immature Wistar rats were primed with 10 IU equine CG (eCG), sc, and 48 h later the 12-h ovulatory process was initiated by 10 IU hCG, sc. Ovarian RNA was extracted at 0, 0.5, 1, 2, 4, 8, 12, and 24 h after the primed animals were injected with hCG. The RNA extracts were used for RT-PCR differential display for random detection of gene expression in the stimulated ovarian tissue. Northern analysis of one of the differentially amplified complementary DNAs confirmed that it was part of a gene that was significantly up-regulated within 1 h after the ovaries had been stimulated by hCG. Maximum transcription was at 4 h after hCG, and expression declined to 0 h control levels by 24 h after hCG. Subcloning and sequence analysis revealed that the complementary DNA matched the gene for Egr-1. In situ hybridization indicated that the Egr-1 messenger RNA was in the granulosa layer of mature follicles. Western blotting confirmed the temporal pattern of Egr-1 expression detected by differential display, Northern analysis and in situ hybridization. The Egr-1 protein is approximately 84 kDa. In conclusion, the data show that expression of the zinc finger transcription factor Egr-1 is an early event in the cascade of inflammatory-like changes that occur in an ovulatory follicle in response to a trophic hormone.

Characterization of ovarian carbonyl reductase gene expression during ovulation in the gonadotropin-primed immature Rat.

In this differential-display polymerase chain reaction-based study, four different primer sets generated cDNA fragments of ovarian carbonyl reductase genes that were uniquely expressed during the ovulatory process in eCG-primed immature rats. The temporal pattern of expression of this aldo-keto reductase gene was delineated by extracting ovarian RNA at 0, 2, 4, 8, 12, and 24 h after induction of ovulation via injection of the primed animals with hCG. The results showed that at least four homologous forms of this gene were transcribed during ovulation. Northern blot analyses indicated a 14-fold increase in ovarian mRNA for carbonyl reductase, with expression reaching a peak at 8 h after hCG treatment and then declining to negligible levels during the next 16 h. In situ hybridization revealed that most of the transcription was in the thecal connective tissue of the ovary and was absent from the granulosa layer of ovarian follicles. Treatment of the animals with ovulation-blocking doses of epostane (an inhibitor of progesterone synthesis) or indomethacin (an inhibitor of prostanoid synthesis) did not reduce the expression of ovarian carbonyl reductase. Nevertheless, the temporal pattern of expression of carbonyl reductase after the induction of ovulation suggests that this enzyme activity is at least indirectly associated with the ovulatory process.

7- and 10-substituted camptothecins: dependence of topoisomerase I-DNA cleavable complex formation and stability on the 7- and 10-substituents.

7-Alkyl, 7-alkyl-10-hydroxy, 7-alkyl-10-methoxy, and 7-alkyl-10, 11-methylenedioxy analogs of camptothecin have been synthesized and evaluated for their ability to trap human DNA topoisomerase I in cleavable complexes. The 7-alkyl chain lengths varied linearly from methyl to butyl. The concentration required to produce cleavable complexes with purified topoisomerase I in 50% of the plasmid DNA (EC(50)) was reduced by 1 order of magnitude by the introduction of a 10-methoxy or 7-alkyl group compared with camptothecin. The EC(50) values were reduced by 2 orders of magnitude with a 10-hydroxy or 10, 11-methylenedioxy moiety compared with camptothecin. The steady-state EC(50) concentrations for all of the analogs tested were slightly dependent on substitution at the 7-position, but this dependence was least with the 10-methoxy series. The kinetics of the reversibility of the complexes formed with all analogs was only slightly influenced by the length of the 7-substitution, with the trend that ethyl or greater lengths led to slightly reduced rate constants for cleavable complex reversal. These results were also observed for DNA-protein cross-link formation by the analogs in isolated CEM cell nuclei. Our data indicate that in vitro cleavable complex stability, as determined by the apparent rate constants for complex dissociation, does not reflect the in vitro biological activity of these camptothecin analogs. However, complex stability in vivo may be important for the antitumor activity of the compounds.

Water soluble 20(S)-glycinate esters of 10,11-methylenedioxycamptothecins are highly active against human breast cancer xenografts.

Water-soluble 20(S)-glycinate esters of two highly potent 10,11-methylenedioxy analogues of camptothecin (CPT) have been synthesized and evaluated for their ability to eradicate human breast cancer tumor xenografts. The glycinate ester moiety increases the water solubility of the 10,11-methylenedioxy analogues 4-16-fold. However, in contrast to CPT-11, a water-soluble CPT analogue that was recently approved for second line treatment of colorectal cancer, the 20(S)-glycinate esters do not require carboxylesterase for conversion to their active forms. The glycinate esters are hydrolyzed to their parent, free 20(S)-hydroxyl active analogues in phosphate buffer (pH 7.5) and in mouse and human plasma. The glycinate esters are also 20-40-fold less potent than CPT-11 in inhibiting human acetylcholinesterase. In vivo, we examined 20(S)-glycinate-10,11-methylenedioxycamptothecin, 20(S)-glycinate-7-chloromethyl-10,11-methylenedioxycamptothecin, and CPT-11. We found that the two 10,11-methylenedioxy analogues had antitumor activity against breast cancer xenografts that was comparable to that of CPT-11. Our results indicate that water-soluble 20(S)-glycinate esters of highly potent CPT analogues provide compounds that maintain biological activity, do not require interactions with carboxylesterases, and do not inhibit human acetylcholinesterase.

Actinomycin D binds to metastable hairpins in single-stranded DNA.

We have examined the role of DNA composition in the binding of actinomycin D to single-stranded DNA. By using the fluorescent analogue 7-aminoactinomycin D, we were able to monitor binding of the drug to ssDNA with single base changes distant from the 5'-TAGT-3' site previously determined to be a high-affinity site for actinomycin D binding (Wadkins et al. (1996) J. Mol. Biol. 262, 53-68). Our binding studies indicated that secondary structures in the ssDNA were likely to be responsible for binding the drug. A series of six low-melting DNA hairpins containing all or part of the 5'-TAGT-3' binding site were synthesized. The highest Tm observed for the melting of these hairpins was 34.2 +/- 0.3 degrees C, and it depended on the length of the stem region. These metastable hairpins were stabilized by 7-aminoactinomycin D, with the drug shifting the Tm for the drug-hairpin complex to approximately 45 degrees C. The hairpins showed very high affinity (Kd approximately 0.1 microM) for 7-aminoactinomycin D, with some dependence on stem length. Digestion of the hairpins in the presence and absence of drug using mung bean nuclease, which specifically interacts with the loop region of hairpin DNA, revealed that the stable hairpins (i) contain a number of non-Watson-Crick base pairs, and (ii) undergo a conformational change in the loop region upon binding 7-aminoactinomycin D. Our results suggest that stabilization of unusual hairpins by actinomycin D may be an important aspect of the potent transcription inhibition activity of this drug.