An estrogen receptor in the liver of the viviparous watersnake, Nerodia; characterization and seasonal changes in binding capacity

Molecular cloning, characterization, and chromosome mapping of reptilian estrogen receptors

In many vertebrates, steroid hormones are essential for ovarian differentiation during a critical developmental stage as well as promoting the growth and differentiation of the adult female reproductive system. Although studies have been extensively conducted in mammals and a few fish, amphibians, and bird species, the molecular mechanisms of sex steroid hormone (estrogens) action have been poorly examined in reptiles. Here, we evaluate hormone receptor and ligand interactions in two species of snake, the Okinawa habu (Protobothrops flavoviridis, Viperidae) and the Japanese four-striped rat snake (Elaphe quadrivirgata, Colubridae) after the isolation of cDNAs encoding estrogen receptor α (ESR1) and estrogen receptor β (ESR2). Using a transient transfection assay with mammalian cells, the transcriptional activity of reptilian (Okinawa habu, Japanese four-striped rat snake, American alligator, and Florida red-belly freshwater turtle) ESR1 and ESR2 was examined. All ESR proteins displayed estrogen-dependent activation of transcription via an estrogen-response element-containing promoter; however, the responsiveness to various estrogens was different. Further, we determined the chromosomal locations of the snake steroid hormone receptor genes. ESR1 and ESR2 genes were localized to the short and long arms of chromosome 1, respectively, whereas androgen receptor was localized to a pair of microchromosomes in the two snake species examined. These data provide basic tools that allow future studies examining receptor-ligand interactions and steroid endocrinology in snakes and also expands our knowledge of sex steroid hormone receptor evolution.

Changes in plasma progesterone in relation to vitellogenesis and gestation in the viviparous snake Vipera aspis

Viviparity has arisen from oviparity on more than 100 independent occasions in squamate reptiles, providing an unique opportunity to investigate the ways in which endocrine control of gestation length has been modified by natural selection during this major transition in reproductive modes. Intuitively, the evolution of viviparity might be expected to involve an increasingly important role for the steroid hormone progesterone, rather than estradiol. Unfortunately, published data on this topic in snakes are scarce and often contradictory. Females of the viviparous snake Vipera aspis reproduce with a lower than annual frequency, providing the opportunity to examine steroid profiles simultaneously in vitellogenic, pregnant, and postparturient versus nonreproductive females. From 1990 to 1994, more than 500 blood samples were collected from more than 100 females. Progesterone, estradiol-17beta, and several plasma metabolites were assayed by radioimmunoassay and spectrophotometry. In contrast to earlier studies, we found significant differences between plasma progesterone levels in reproducing (10.5 +/- 9.1 ng ml(-1), N = 168) and nonreproducing (5.1 +/- 4.2 ng ml(-1), N = 121) females. Estradiol reached high levels during vitellogenesis (4.8 +/- 4.0 ng ml(-1), N = 16), and progesterone levels increased during gestation (from 3.7 ng ml(-1) before gestation to 18.7 ng ml(-1) at midgestation). However, experimental elevation of plasma progesterone levels with implants (up to 44.4 ng ml(-1)) did not modify plasma metabolite levels or delay parturition.

Characterization of a specific estrogen receptor in the oviduct of the little skate, Raja erinacea

In this study we report the first estrogen receptor to be characterized in an oviparous elasmobranch. The skate receptor has high affinity for estradiol (Kd = 0.7 nM), binds both estradiol and the synthetic estrogen DES, and exists in low quantities (50-100 fmol/g oviduct). The receptor displays rapid binding kinetics with half-times of 5 min at 22 degrees and 77 min at 4 degrees. DEAE-Sepharose chromatography reveals one receptor moiety which elutes between 0.13 and 0.14 M KCl. By sucrose gradient ultracentrifugation sedimentation coefficients of 3.6 S under high-salt (0.5 M KCl) and 6.0 S under low salt (0.01 M KCl) conditions were obtained. Using Sephadex G200 gel filtration chromatography, a Stokes radius (Rs) of 2.8 nm and an estimated molecular weight of 43 kDa were calculated. DNA-cellulose elution profiles reveal that the receptor elutes as one peak between 0.34 and 0.36 M NaCl (as compared to 0.20-0.22 M NaCl in mammals and birds and 0.55 M for dogfish). Although some differences are noted between the elasmobranch ER and those of other vertebrates (e.g., dissociation kinetics, DNA affinity), in general it can be said that the skate ER is a "classical" ER in most respects. It is suggested that this steroid receptor has played a key role in the reproductive tract functions of nutrient provision, embryo protection, and as a conduit to the external environment since the earliest chordate era, approximately 400 million years ago.

Changes in hepatic estrogen-receptor concentrations during the annual reproductive and ovarian cycles of a marine teleost, the spotted seatrout, Cynoscion nebulosus

The concentrations of estrogen and vitellogenin in plasma, and hepatic estrogen receptor in cytosolic (ERc) and nuclear (ERn) extracts were elevated throughout the reproductive season in females from a wild population of spotted seatrout, Cynoscion nebulosus. There were significant correlations between plasma estradiol and ERc and between ERn and plasma vitellogenin during the period of ovarian recrudescence (January-May), but not during the remainder of the reproductive season (June-September). During ovarian recrudescence ERc concentrations increased fourfold from 0.78 +/- 0.15 pmol/g liver (N = 26) in nonvitellogenic females to 3.23 +/- 0.26 pmol/g liver (N = 77) in late vitellogenic females and ERn concentrations increased eightfold from 0.16 +/- 0.07 pmol/g liver (N = 26) in nonvitellogenic females to 1.12 +/- 0.45 pmol/g (N = 10) in mid vitellogenic females. However, following this period of ovarian recrudescence, estrogen-receptor concentrations and plasma vitellogenin titers did not fluctuate during the remaining stages of the ovulatory cycle (hydration, ovulation, and spawning). In addition, both hepatic ERc and ERn were elevated for the rest of the seasonal reproductive cycle, during which several ovulatory cycles may have occurred in this multiple-spawning species. The affinity of ERc for estradiol did not vary (Kd = 1.26 +/- 0.06 nM, N = 68) regardless of the stage of ovarian development. Plasma estradiol titers declined in August, near the end of the reproductive season, prior to the decline in estrogen-receptor concentrations. The persistence of the estrogen receptor during the ovulatory cycle suggests that even if plasma estradiol titers declined between successive ovulatory periods, the hepatic responsiveness to estrogenic stimuli would not be diminished and thus vitellogenin synthesis, if interrupted at all, could be resumed soon after spawning.

The role of steroids in reproduction in female elasmobranchs and reptiles

Adequate evidence exists to suggest the importance of temporal changes in steroid hormone ratios in the normal reproductive/vitellogenin cycle in oviparous and viviparous elasmobranchs and reptiles. In oviparous species, where the cycle is relatively short, secretion of gonadal hormones is synchronous; thus inhibitory actions of progesterone (P) on hepatic or reproductive tract functions would be offset by stimulatory actions of estradiol (E), resulting in appropriate vitellogenin secretion and reproductive tract development. In viviparous species, temporal asynchrony of E and P secretion occurs, and the actions of the individual hormones can be more easily dissected out. Thus, during gestation, where P is the dominant hormone, antagonistic or stimulatory actions of E may be prevented, and the inhibitory action of P on vitellogenesis dominant. Hence vitellogenesis is limited to the follicular phase and eggs are retained. Although the elasmobranch and reptilian species discussed here do not form a continuum through phylogenesis, but rather are extant forms of a particular line of evolution, it is possible to extrapolate from these observations to the probable endocrine interactions in a species as viviparity evolves from oviparity. The theoretical intermediate stage would involve; (a) egg retention, (b) extension of the luteal phase and increased P secretion and (c) resulting in E/P asynchrony and potential expression of "independent" P action, egg retention and yolk suppression.

Evolving trends in steroid hormone receptor research

Recent advances have challenged classical notions regarding the nature of steroid hormone receptors in the cell including localization, activation, configuration, and stability. Molecular biology has revealed a remarkable similarity in the primary structure of a wide variety of receptor classes that goes beyond steroid action. Post-translational modification of a primary unit, expressed in response to genetic conservatism, would appear to assure receptor dynamics specific to hormone-, organ-, and tissue-dependent processes, and may even lead to toxicity and oncogenicity.

Binding characteristics of the hepatic estrogen receptor of the spotted seatrout, Cynoscion nebulosus

Estrogen receptors were identified in cytosolic and nuclear extracts of livers of adult female spotted seatrout, Cynoscion nebulosus. A single class of high affinity binding sites was found, Kd = 1.26 +/- 0.55 nM (N = 55) for the cytosolic extract and Kd = 1.96 +/- 0.42 nM (N = 8) for the nuclear extract. The Kd did not differ between males and females or between vitellogenic and nonvitellogenic females. The binding in both the cytosolic and nuclear extracts was specific for estrogens (DES greater than E2 much greater than E1 = E3). Receptor concentrations in cytosolic extracts from late vitellogenic females (14.61 +/- 1.07 pmol/g liver, N = 40) were significantly higher than those from nonvitellogenic females (3.91 +/- 0.73 pmol/g liver, N = 7). The nuclear binding capacity of livers from midvitellogenic females (1.12 +/- 0.45 pmol/g liver, N = 10) was significantly higher than the binding capacity in livers from nonvitellogenic females (0.16 +/- 0.07 pmol/g liver, N = 26), but not that of late vitellogenic females (0.80 +/- 0.09 pmol/g liver, N = 77). The concentration of estradiol-binding sites was greatest in the liver (liver much greater than ovary greater than heart greater than spleen greater than muscle greater than brain). No interference from other steroid-binding proteins was detected using a simple dextran-coated charcoal method to separate bound from free hormone. Approximately 14% of the binding in the cytosolic extract had DNA-binding affinity. Estrogen receptor binding activity was maximally extracted from nuclei with buffer containing 0.6 M KCl. Nuclear receptors eluted from gel filtration columns with an apparent molecular weight of 95 kDa.

Two progesterone receptors in the oviduct of the freshwater turtle Chrysemys picta: possible homology to mammalian and avian progesterone receptor systems

Two progesterone receptors in the oviduct of the freshwater turtle Chrysemys picta: possible homology to mammalian and avian receptor systems. Here we report the characterization of two specific progesterone receptors in nuclear extracts of the turtle oviduct. The receptors differ in dissociation constants (2.8 nM vs 27 nM) which can be separated on DEAE-Sepharose, the former eluting at 0.08 M KCl and the latter at 0.20 M KCl. [3H]R5020 photoaffinity labeling SDS-PAGE revealed that the 2.8 nM moiety migrates with an apparent molecular weight of 80 +/- 5 kDa and the 27 nM moiety migrates with an apparent molecular weight of 120 +/- 5 kDa. These receptors are termed PR-A and PR-B due to their molecular mass and elution profiles. DNA-cellulose chromatographic studies show that both bind DNA-cellulose with the PR-A eluting at 0.09 M NaCl and PR-B eluting between 0.20-0.21 M NaCl. In reproductively inactive turtles (from the months of January and February) estradiol is undetectable, and PR-B is absent as determined by Scatchard analysis, [3H]R5020 photoaffinity labeling electrophoretic studies and DEAE-Sepharose and DNA-cellulose chromatography. In these animals PR-B can be replenished by estrogen treatment, suggesting a physiological role for both PR-A and PR-B and dependence of PR-B on estradiol.

A plasma steroid hormone binding protein in the viviparous water snake, Nerodia

A plasma steroid binding protein (SHBP) with medium-high affinity and limited capacity was characterized in the viviparous water snake, Nerodia. This SHBP shows similarity to SHBPs previously described in some other nonmammalian species. A single binding component was detected by Scatchard analyses with a medium-high affinity for testosterone (T), estradiol (E), progesterone (P), and corticosterone (B). Equilibrium dissociation constants (Kd) for these steroids are as follows: T, 3.6 x 10(-8) M; E, 3.7 x 10(-8) M; P, 5.9 x 10(-8) M; B, 12.1 x 10(-8) M. In competition studies (at saturation) the relative binding affinities (RBA) for E (1.0) and T (1.0) were higher than those for P (0.8) and B (0.59). Further analysis of binding specificity for [3H]estradiol at 100-fold excess competitor concentrations revealed that dihydrotestosterone also competes; however, estrone and estriol were relatively poor competitors. Displacement of 3H-E by antiestrogen clomiphene derivatives and synthetic estrogen varied; enclomiphene citrate (67.8%), clomiphene citrate (42.2%), diethylstilbestrol (37.3%), and zuclomiphene citrate (15.2%). The SHBP has a relatively high binding capacity (Bmax = 0.09-0.7 M), which may be correlated with the relatively high circulating plasma steriod levels in this species. Scatchard analysis, disc gel electrophoresis, sucrose gradient centrifugation, and competition studies indicate the presence of a single moiety binding estradiol, testosterone, progesterone, and corticosterone. The estradiol-SHBP complex is unstable, exhibiting very short times of association (t less than 1.5 min) and dissociation (Kd = 0.0165 sec-1, t 1/2 = 18.3 sec). Measurement of SHBP levels throughout the seasonal reproductive cycle revealed high levels of binding in previtellogenic, vitellogenic, early pregnant, and postpartum animals. A significantly lower level of SHBP was detected in mid-late pregnancy.