Regulation of mouse renal CYP2J5 expression by sex hormones.

Mouse CYP2J5 is abundant in kidney and active in the metabolism of arachidonic acid to epoxyeicosatrienoic acids. Western blots of microsomes prepared from mouse kidneys demonstrate that after puberty, CYP2J5 protein is present at higher levels in male mice than in female mice. Northern analysis reveals that CYP2J5 transcripts are more abundant in adult male versus female kidneys, indicating that gender differences in renal CYP2J5 expression are regulated at a pretranslational level. Castration of male mice results in decreased renal CYP2J5 expression, and treatment of castrated male mice or female mice with 5alpha-dihydrotestosterone increases expression to levels that approximate those in intact male mice. In contrast, treatment of ovariectomized female mice or castrated male mice with 17beta-estradiol causes a further reduction in CYP2J5 expression. Growth hormone-deficient (lit/lit) mice respond similarly to castration and 5alpha-dihydrotestosterone treatment, indicating that the androgen effects are not mediated by alterations in the growth hormone secretory pattern. Mice that lack a functional androgen receptor (Tfm hemizygous) have reduced levels of renal CYP2J5 and do not respond to 5alpha-dihydrotestosterone treatment. Similarly, wild-type male mice treated with flutamide, an androgen antagonist, exhibit reduced renal CYP2J5 levels. Female estrogen receptor-alpha knockout (alphaERKO) mice, which are known to have elevated circulating testosterone levels, have significantly increased renal CYP2J5 expression compared with wild-type female mice, and these differences are abrogated by ovariectomy or treatment with flutamide. Based on these data, we conclude that the renal expression of CYP2J5 is up-regulated by androgen and down-regulated by estrogen.

Update on animal models developed for analyses of estrogen receptor biological activity.

Targeted disruption of the different ER genes has generated experimental animal models that are very useful in evaluating the distinct and cooperative roles of the two estrogen receptors, ERalpha and ERbeta, in reproductive but also non-reproductive tissues of both sexes. Phenotypic analysis has provided definitive experimental findings for estrogen receptor mediated physiological actions, involving ERalpha in uterine, mammary gland and neuroendocrine sites. ERbeta is involved most dramatically in the ovary as is ERalpha. More detailed studies in combination with tissue specific or inducible ER knock outs will be important for future research.

Molecular determinants of the stereoselectivity of agonist activity of estrogen receptors (ER) alpha and beta.

The two known estrogen receptors, ERalpha and ERbeta, are hormone-inducible transcription factors that have distinct roles in regulating cell proliferation and differentiation. Previously, our laboratory demonstrated that ERalpha exhibits stereoselective ligand binding and transactivation for several structural derivatives and metabolites of the synthetic estrogen diethylstilbestrol. We have previously described the properties of indenestrol A (IA) enantiomers on ERalpha. In the study presented here, the estrogenic properties of the S and R enantiomers of IA, IA-S and IA-R, respectively, were expanded to examine the activity in different cell and promoter contexts using ERalpha and ERbeta. Using human cell lines stably expressing either ERalpha or ERbeta, we found that IA-S was a more potent activator of transcription than IA-R through ERalpha in human endometrial Ishikawa and breast MDA-MB 231 (MDA) cells. Interestingly, IA-R was more potent on ERbeta when compared with ERalpha in MDA, but not in Ishikawa cells, and IA-R exhibited equally low binding affinities to ERalpha and ERbeta in vitro in contrast to its cell line-dependent preferential activation of ERbeta. Alignment of the protein structures of the ligand-binding domains of ERalpha and ERbeta revealed one mismatched residue, Leu-384 in ERalpha and Met-283 in ERbeta, which may be responsible for making contact with the methyl substituent at the chiral carbon of IA-S and IA-R. Mutagenesis and exchange of this one residue showed that the binding of IA-R and IA-S was not affected by this mutation in ERalpha and ERbeta. However, in transactivation studies, IA-R showed higher potency in activating L384M-mutated ERalpha and wild-type ERbeta compared with wild-type ERalpha and M283L-mutated ERbeta in all cell and promoter contexts examined. Furthermore, IA-R-bound ERalpha L384M and wild-type ERbeta displayed enhanced interactions with the nuclear receptor interaction domains of the coactivators SRC-1 and GRIP1. These data demonstrate that a single residue in the ligand-binding domain determines the stereoselectivity of ERalpha and ERbeta for indenestrol ligands and that IA-R shows cell type selectivity through ERbeta.

Genomic structure and identification of a truncated variant message of the mouse estrogen receptor alpha gene.

Estrogen receptor alpha (ERalpha) is a ligand-dependent transcription factor that directs the transcription of a wide number of estrogen-regulated genes. ERalpha mediates the effects of 17-beta-estradiol in both males and females, and was the first estrogen receptor identified. Despite the cloning of the mouse ERalpha cDNA over 15 years ago, the precise genomic organization of the mouse ERalpha gene has not yet been elucidated. In order to determine the structure of this gene, overlapping BAC and P1 clones containing partial genomic sequences of the mouse ERalpha cDNA were obtained from a mouse ES cell genomic library. Using standard restriction fragment analysis followed by Southern blotting, the mouse ERalpha gene was determined to be greater than 220 kb in length. The introns vary widely in size, from 1.8 to 60 kb in length. Sequencing of intron-exon boundaries shows that these boundaries are highly conserved between the human and mouse ERalpha genes. Additionally, we have identified a splice variant message of mouse ERalpha arising from a failure to properly splice at the 3' end of exon 4; the resulting message is predicted to produce a protein lacking the ligand-binding domain. Variant message was detected by RT-PCR in several tissues, including uterus, ovary, mammary gland, placenta and testis.