Hormonal regulation of myosin heavy chain and alpha-actin gene expression in cultured fetal rat heart myocytes

Thyroid hormone regulates the expression of ventricular myosin isoenzymes by causing an accumulation of alpha-myosin heavy chain (MHC) mRNA and inhibiting expression of beta-MHC mRNA. However, the mechanism of thyroid hormone action has been difficult to examine in vivo because of its diverse actions. Accordingly, hormonal control of expression of six MHC isoform mRNAs and cardiac and skeletal alpha-actin mRNAs was studied in primary cultures of fetal rat heart myocytes grown in defined medium. The results indicate that in the absence of thyroid hormone, cultured heart cells express predominantly beta-MHC and cardiac alpha-actin mRNAs. Addition of 3,5,3'-triiodo-L-thyronine (T3) caused a rapid induction of alpha-MHC mRNA and decreased beta-MHC mRNA levels without affecting the skeletal muscle MHC mRNAs. There was an almost parallel change in the myosin isoenzymes. Cardiac alpha-actin mRNA levels were transiently increased by T3 treatment, but skeletal alpha-actin was unaffected. Elimination of insulin and epithelial growth factor from the medium did not alter the effects of T3 on cardiac MHC mRNA expression. Addition of various adrenergic agents to the medium had no appreciable effect on cardiac MHC mRNA expression despite the presence of functionally coupled alpha- and beta-adrenergic receptors. Addition of steroid hormones, muscarinic agents, and glucagon to the medium also had no effect. Thus, under defined conditions, T3 is able to regulate MHC gene expression at a pretranslational level without the need for other exogenous factors.     

Determinants of the contractile properties in the embryonic chicken gizzard and aorta

Smooth muscle is generally grouped into two classes of differing contractile properties. Tonic smooth muscles show slow rates of force activation and relaxation and slow speeds of shortening (V(max)) but force maintenance, whereas phasic smooth muscles show poor force maintenance but have fast V(max) and rapid rates of force activation and relaxation. We characterized the development of gizzard and aortic smooth muscle in embryonic chicks to identify the cellular determinants that define phasic (gizzard) and tonic (aortic) contractile properties. Early during development, tonic contractile properties are the default for both tissues. The gizzard develops phasic contractile properties between embryonic days (ED) 12 and 20, characterized primarily by rapid rates of force activation and relaxation compared with the aorta. The rapid rate of force activation correlates with expression of the acidic isoform of the 17-kDa essential myosin light chain (MLC(17a)). Previous data from in vitro motility assays (Rover AS, Frezon Y, and Trybus KM. J Muscle Res Cell Motil 18: 103-110, 1997) have postulated that myosin heavy chain (MHC) isoform expression is a determinant for V(max) in intact tissues. In the current study, differences in V(max) did not correlate with previously published differences in MHC or MLC(17a) isoforms. Rather, V(max) was increased with thiophosphorylation of the 20-kDa regulatory myosin light chain (MLC(20)) in the gizzard, suggesting that a significant internal load exists. Furthermore, V(max) in the gizzard increased during postnatal development without changes in MHC or MLC(17) isoforms. Although the rate of MLC(20) phosphorylation was similar at ED 20, the rate of MLC(20) dephosphorylation was significantly higher in the gizzard versus the aorta, correlating with expression of the M130 isoform of the myosin binding subunit in the myosin light chain phosphatase (MLCP) holoenzyme. These results indicate that unique MLCP and MLC(17) isoform expression marks the phasic contractile phenotype.     

Regulation of reproduction- and biomarker-related gene expression by sex steroids in the livers and ovaries of adult female western mosquitofish (Gambusia affinis)

To assess the adverse toxicological effects of steroid hormones on western mosquitofish (Gambusia affinis), 180 adult females were exposed to individual or binary combinations of progesterone (1μg/L), testosterone (1μg/L) and 17β-estradiol (1μg/L) for eight days. The expression patterns of vitellogenin, estrogen receptor, androgen receptor, metallothionein, and cytochrome P450 1A genes in mosquitofish varied according to tissue as well as the specificity of steroids. Treatment by progesterone or testosterone alone inhibited target gene expression in the livers. The expression levels of both vitellogenin A and vitellogenin B mRNAs were up-regulated by17β-estradiol, and a parallel induction of estrogen receptor α mRNA expression was also observed in the livers. In addition, 17β-estradiol treatment alone suppressed androgen receptor α, metallothionein and cytochrome P450 1A mRNA expression in the livers. In general, multiple hormone treatments had different effects on target gene expression compared with corresponding hormone alone. The results demonstrate that steroid hormones cause multiple biological responses including the expression of vitellogenin, estrogen receptor and androgen receptor mRNA in the hormone signaling pathways and the expression of metallothionein and cytochrome P450 1A mRNA in the xenobiotic signaling pathway.     

Antagonistic effects of chronic low frequency stimulation and thyroid hormone on myosin expression in rat fast-twitch muscle

This study investigates effects of chronic low frequency stimulation (CLFS) on myosin heavy (MHC) and light chain (MLC) expression in fast-twitch muscles in hypothyroid, euthyroid, and hyperthyroid rats. The changes at both the mRNA and protein level indicated antagonistic effects of thyroid hormone and CLFS: under euthyroid conditions, CLFS mainly elicited a MHCIIb----MCHIId----MHCIIa transition. Whereas CLFS did not induce the slow MHCI in the euthyroid state, this isoform was present in the hypothyroid state and was further enhanced with CLFS indicating the suppressive effect of thyroid hormone to be stronger than the inductive influence of CLFS. Hyperthyroidism alone suppressed the expression MHCIIa and enhanced a MHCIId to MHCIIb transition. This shift to the faster MHC isoforms was only partially counteracted by CLFS. Thus, it appeared that thyroid hormone had a graded suppressive effect on the expression of MHC isoforms in the order MHCIId less than MHCIIa less than MHCI. Elevated neuromuscular activity partially counteracted these hormone effects. Changes in MLC mRNAs were consistent with those in the MHC pattern, i.e. increases or decreases in MHCIIb led to corresponding changes in the expression of MLC3f. A similar relationship existed for the slow MHCI and the slow MLC isoforms.     

Acute Effects of Sex Steroid Hormones on Susceptibility to Cardiac Arrhythmias: A Simulation Study

Acute effects of sex steroid hormones likely contribute to the observation that post-pubescent males have shorter QT intervals than females. However, the specific role for hormones in modulating cardiac electrophysiological parameters and arrhythmia vulnerability is unclear. Here we use a computational modeling approach to incorporate experimentally measured effects of physiological concentrations of testosterone, estrogen and progesterone on cardiac ion channel targets. We then study the hormone effects on ventricular cell and tissue dynamics comprised of Faber-Rudy computational models. The “female” model predicts changes in action potential duration (APD) at different stages of the menstrual cycle that are consistent with clinically observed QT interval fluctuations. The “male” model predicts shortening of APD and QT interval at physiological testosterone concentrations. The model suggests increased susceptibility to drug-induced arrhythmia when estradiol levels are high, while testosterone and progesterone are apparently protective. Simulations predict the effects of sex steroid hormones on clinically observed QT intervals and reveal mechanisms of estrogen-mediated susceptibility to prolongation of QT interval. The simulations also indicate that acute effects of estrogen are not alone sufficient to cause arrhythmia triggers and explain the increased risk of females to Torsades de Pointes. Our results suggest that acute effects of sex steroid hormones on cardiac ion channels are sufficient to account for some aspects of gender specific susceptibility to long-QT linked arrhythmias.     

Effects of steroid hormones on reproduction- and detoxification-related gene expression in adult male mosquitofish, Gambusia affinis

The molecular mechanisms that mediate fish reproduction and detoxification in response to steroid hormones were studied by using adult male western mosquitofish (Gambusia affinis) as sentinel species. The expression patterns of three vitellogenins (VtgA, VtgB and VtgC), two estrogen receptors (ERα and ERβ), two androgen receptors (ARα and ARβ), metallothionein (MT) and cytochrome P450 1A (CYP1A) in the liver and testis of adult male mosquitofish were assessed through exposure treatments with progesterone (P), testosterone (T) and 17β-estradiol (E2), alone and in combination for eight days. The results showed that expression patterns of Vtg subtype, ER subtype, AR subtype, MT and CYP1A genes in male mosquitofish varied according to tissue and specific hormone stress. Vtg subtype mRNA expression was induced in the liver in E2-added treatments, and an up-regulation of ERα mRNA expression was also observed. In addition, hormone treatments increased three Vtg subtype mRNA expression levels in the testis, at least to some extent. All hormone treatments significantly inhibited ERα, ERβ and ARβ mRNA expression in the testis. Some of hormone treatments could affect MT and CYP1A gene expression in mosquitofish. In general, multiple hormone treatments showed different effects on target gene expression compared with corresponding hormone alone. The results from the present study provided valuable information on the toxicological effects of steroid hormones in mosquitofish.     

Steroid hormones may regulate autophosphorylation of adenosine-3',5'-monophosphate-dependent protein kinase in target tissues

A protein in rat liver cytosol whose phosphorylation was regulated by hydrocortisone administration in vivo was tentatively identified as the regulatory subunit of a cAMP-dependent protein kinase. Evidence that this protein, whose phosphorylation was regulated by steroid and cyclic AMP, is the regulatory subunit of type-II cAMP-dependent protein kinase included: (a) co-purification of the steroid/cAMP-regulated protein and the regulatory subunit during DEAE-cellulose, Sepharose 4B, and hydroxylapatite column chromatography, (b) co-migration of the two proteins on dodecyl sulfate/polyacrylamide slab gels during the various steps of purification, (c) specific adsorption of the two proteins onto 8(6-aminohexylamino)-cAMP--Sepharose 4B, and (d) a similar pattern of distribution of the two proteins in various subcellular fractions prepared from rat liver homogenate. By each of these criteria, it was found that the steroid/cAMP-regulated protein present in rat liver cytosol behaved identically with the regulatory subunit of type-II cAMP-dependent protein kinase in that tissue. Results qualitatively similar to those obtained in the study of the effect of hydrocortisone on rat liver were also obtained in studies of the effects of other steroid hormones on other target tissues in the rat, including uterus (17 beta-estradiol), ventral prostate and seminal vesicle (testosterone), and epididymal fat pad (hydrocortisone). The tentative identification of the steroid/cAMP-regulated protein as the regulatory subunit of the type-II cAMP-dependent protein kinase in the cytosol of several tissues indicates that autophosphorylation of the regulatory subunit of type-II protein kinase may be regulated by the steroid hormones. The fact that three different classes of steroid hormones appear to affect the phosphorylation of the regulatory subunit of type-II cAMP-dependent protein kinase in their target tissues raises the possibility that this common biochemical action may play an important role in the mechanism of steroid hormone action. It is also possible that this effect of the steroid hormones may provide a molecular basis for some of the known physiological interactions of the steroid hormones with those hormones that act through using cAMP as a second messenger.     

Gonadal Steroids do not Affect Apolipoprotein E Expression in Aging Mouse Cerebral Cortex

The allelic variant of apolipoprotein (Apo) E4 is a known risk factor for the development of most common late onset form of Alzheimer’s disease (AD). As aging is associated with reduced circulating level of gonadal steroid hormones, hormone replacement therapies have been used for the possible treatment of AD. Both estrogen and testosterone have beneficial effects on brain due to interaction with apoE, but the underlying mechanism is still not clear. In this article, we report the effects of gonadectomy and hormone supplementation on apoE protein level in male and female mouse cerebral cortex during normal aging. We could not get any effect of gonadectomy and estradiol or testosterone treatment in adult and old mice of either sex. This suggests that during normal aging apoE protein level is not affected due to steroid hormone withdrawal or supplementation in the mouse cerebral cortex.     

Developmental modulation of myosin expression by thyroid hormone in avian skeletal muscle.

It is well established that a rise in circulating thyroid hormone during the second half of chick embryo development significantly influences muscle weight gain and bone growth. We studied thyroid influence on differentiation in slow anterior latissimus dorsi (ALD) and fast posterior latissimus dorsi (PLD) muscles of embryos rendered hypothyroid by hypophysectomy or administration of an anti-thyroid drug. The expression of native myosins and myosin light chains (MLCs) was studied by electrophoretic analysis, and the myosin heavy chain (MHC) was characterized by immunohistochemistry. The first effects of hypothyroid status were observed at day 21 of embryonic development (stage 46 according to Hamburger and Hamilton). Analysis of myosin isoform expression in PLD muscles of hypothyroid embryos showed persistence of slow migrating native myosins and slow MLCs as well as inhibition of neonatal fast MHC expression, indicating retarded differentiation of this muscle. In ALD muscle, hypothyroidism maintained fast embryonic MHC and induced noticeable amounts of fast MLCs, thus delaying slow muscle differentiation. Our results suggest that thyroid hormones play a role in modulating the appearance of neonatal fast MHC and the disappearance of isomyosins transiently present during embryogenesis. However, T3 supplemental treatment would seem to compensate in part for the effects of hypothyroidism induced by hypophysectomy, suggesting that thyroid hormone might interfere with other factors also accounting for the observed effects.     

Neurotransmitter-controlled steroid hormone receptors in the central nervous system

Results are discussed indicating that neurotransmitters affect steroid hormone activity not only by controlling via neuroendocrine events the hypophysial-gonadal and hypophysial-adrenal axes, but also by modulating cell responsiveness to steroids in target cells. Hyper- or hypoactivity of pineal nerves result in enhancement or impairment of estradiol and testosterone effects on pineal metabolism in vivo and in vitro. Pineal cytoplasmic and nuclear estrogen and androgen receptors are modulated by norepinephrine released from nerve endings at the pinealocyte level. Neural activity affects the cycle of depletion-replenishment of pineal estrogen receptors following estradiol administration. Another site of modulation of steroid effects on the pinealocytes is the intracellular metabolism of testosterone and progesterone; nerve activity has a positive effect on testosterone aromatization and a negative effect on testosterone and progesterone 5α-reduction. NE activity on the pineal cells is mediated via β-adrenoceptors and cAMP. In the central nervous system information on the neurotransmitter modulation of steroid hormone action includes the following observations: (a) hypothalamic deafferentation depresses estrogen receptor levels in rat medial basal hypothalamus; (b) changes in noradrenergic transmission affect, via α-adrenoceptors, the estradiol-induced increase of cytosol progestin receptor concentration in guinea pig hypothalamus; (c) cAMP increases testosterone aromatization in cultured neurons from turtle brain; (d) electrical stimulation of dorsal hippocampus augments, and reserpine or 6-hydroxydopamine treatment decrease, corticoid binding in cat hypothalamus. In the adenohypophysis changes in dopaminergic input after median eminence lesions or bromocriptine treatment of rats result in opposite modifications of pituitary estrogen receptor levels. Therefore all these observations support the view that neurotransmitters can modulate the attachment of steroid hormones to their receptors in target cells.     

Expression of peptidylarginine deiminase in the uterine epithelial cells of mouse is dependent on estrogen.

The effects of the steroid hormones estrogen and progesterone on peptidylarginine deiminase protein-L-arginine iminohydrolase, EC 3.5.3.15) levels in adult ovariectomized mouse uterus were studied. The amount of the enzyme in the uterus was considerably diminished by ovariectomy. When the mice were injected with a variety of estrogenic compounds, 17 beta-estradiol-3-benzoate, which was the most potent stimulator of uterine cell proliferation among the estrogens tested, dramatically elevated the enzyme formation of the uterus in a dose- and time-dependent fashion. Results of immunohistochemistry with the antiserum against mouse peptidylarginine deiminase demonstrated that the induction of the enzyme by the estradiol exclusively occurred at the luminal and glandular epithelia, corresponding with the previous findings in the normal estrous cycle. Furthermore, administration of the estradiol significantly increased the content of mRNA coding for peptidylarginine deiminase in uterus, indicating the evidence of regulation in pretranslation. On the other hand, progesterone alone did not restore the enzyme level of the ovariectomized mouse, but moderated the action of estrogen when given in concert with estrogen. Thus, the expression of peptidylarginine deiminase in luminal and glandular epithelia of mouse uterus is controlled by the amount of the steroid hormones estrogen and progesterone.     

Effects of Estrogen and Testosterone on Resting Energy Expenditure in Older Men

The mechanisms by which sex hormones cause changes in body composition are unclear. Sex steroid deficiency might directly reduce energy expenditure/fat oxidation and thereby predispose to increased body fat. Alternatively, sex steroid deficiency could result in lean tissue loss and thus reduced energy expenditure. Our objective was to examine the independent and combined effects of acute testosterone and estrogen withdrawal on respiratory exchange ratio (RER) and resting energy expenditure (REE) in men. The objective of the study was to examine the independent and combined effects of acute estrogen and testosterone withdrawal on RER and REE in men. A total of 54 men aged 50–80 years, BMI range of 17–35 kg/m² underwent a 3‐week eugonadal run‐in hormone‐treatment period involving suppression of endogenous sex steroids using letrozole and leuprolide acetate (Lupron) while sex steroid concentrations were maintained with transdermal testosterone (T) and estradiol (E). A second Lupron injection was then given and participants were randomized to one of the following four 3‐week treatment groups: group A (?T, ?E), group B (?T, +E), group C (+T, ?E), and group D (+T, +E). REE and RER were measured via indirect calorimetry before and after the 3‐week treatment period. Three‐week suppression and/or repletion of estrogen or testosterone did not produce changes in RER or REE within or between groups. We conclude that abrupt changes in sex steroids does not change resting substrate oxidation, indicating that changes that can be observed after more prolonged periods of deficiency are most likely due to direct effects of sex steroids on body composition.     

Regulation by Gonadal Steroids of Estrogen and Progesterone Receptors Along the Reproductive Tract in Female Lambs

The regulation of estrogen and progesterone receptor (ER, PR) expression by estradiol (E2) and progesterone (P4) in the oviduct, uterus and cervix of female lambs was studied. The animals received three intramuscular injections of E2, P4 or vehicle with an interval of 24 h and they were slaugthered 24 h after the third injection. Determinations of ER and PR were performed by binding assays and mRNAs of ERα and PR by solution hybridization. High levels of ER and PR in both cervix and oviduct were found in the female lamb, differing from other mammalian species. No significant effects by either E2 or P4 treatment on ER and PR levels in the cervix and oviduct could be observed. E2 treatment increased the mRNA levels of ERa and PR more than 3-fold in the cervix, while P4 treatment increased the mRNA levels of ERa and PR in the uterus. The results show differential effects of gonadal steroids on sex steroid receptor expression along the reproductive tract in female lambs, suggesting that steroid target tissues can modulate responses to the same circulating levels of steroid hormones.