The sex hormone-binding globulin gene (shbg) is expressed in the liver and testis as well as in several other tissues that play important roles in reproduction. Expression of shbg in the human liver results in the production of plasma sex hormone-binding globulin (SHBG), which regulates the bioavailability of sex steroids in the blood. Although shbg is not expressed in rodent livers postnatally, it gives rise to the androgen-binding protein in their testes upon sexual maturation. Human shbg is also expressed in the testis, but its products and their function are less well characterized. To study the expression of human shbg in different tissues and the consequences of overexpressing this gene in vivo, we have produced several lines of mice containing approximately 11-kilobase (kb; shbg11) or 4.3-kb (shbg4) human shbg genomic fragments that comprise all eight exons encoding SHBG as well as approximately 6 kb or approximately 0.9 kb of 5'-flanking DNA, respectively. Northern blots indicated that human shbg transcripts were most abundant in liver, kidney, and testis of the shbg11 mice. The 4.3-kb shbg transgenes were expressed at similar levels in liver and kidney, but the abundance of human shbg transcripts in their testes was much lower than that in shbg11 mice. Primer extension analysis indicated that transcription starts 60 bp from the translation initiation codon for SHBG in liver and kidney of shbg11 mice, and that the shbg transcripts in their testis are derived from a separate promoter flanking an alternative exon that replaces the exon containing the translation initiation codon for SHBG or androgen-binding protein. At the cellular level, the human shbg transgenes are expressed in clusters of hepatocytes located mainly within the periportal region of hepatic lobules and in the epithelial cells lining the proximal convoluted tubules of the kidney. This results in high levels of human SHBG in serum (1.45-1.72 nmol/ml) and urine (6-16 pmol/ml) of mature male shbg mice. The abundance and distribution of human shbg transcripts in the Sertoli cells of shbg11 mice vary throughout the spermatogenic cycle, with levels increasing in the Sertoli cell cytoplasm until stage VII of spermatogenesis and declining after stage IX. At stages X-XII of spermatogenesis, these transcripts concentrate at the adluminal compartment of the Sertoli cells, and this suggests that they have a role in the elongation phase of spermiogenesis. The presence of human SHBG in the blood of shbg transgenic mice may result in serum levels of testosterone that are 10-100 times higher than those in wild-type littermates. Despite this, their reproductive performance is normal, and there is no obvious phenotypic abnormalities even in animals homozygous for the transgenes.
Stanniocalcin is a glycoprotein hormone that appears to play a paracine/autocrine role in several mammalian tissues. Recently studies have shown that stanniocalcin is highly expressed in the ovaries of mice and humans and we have investigated its expression in the mouse ovary during several physiological states to identify potential functional relationships. During postnatal development the pattern of stanniocalcin (STC) gene expression begins to become thecal-restricted as early as day 5 and achieves the adult pattern of expression by two weeks of age. During postnatal development the primary sites of STC protein localization are the theca and oocytes and after maturation it is also strongly concentrated in the corpora lutea. Over the estrous cycle the pattern of both STC gene expression and protein localization do not show dramatic changes though STC immunoreactivity (STCir) staining appears to be greatest during metestrus I. In the superovulation model, however, we observed a significant increase in STC messenger RNA (mRNA) levels after treatment with hCG implying regulation by LH. During gestation the expression of ovarian STC increases 15-fold and is localized to the theca-interstitial cells with lower expression also being found in the corpora lutea. STC also becomes detectable in the serum for the first time suggesting an endocrine role for STC during gestation. Interestingly, the presence of a nursing litter appears to up-regulate STC gene expression in lactating mice suggesting a role for ovarian STC in lactation. Also striking is the intense STCir staining found in oocytes as they are devoid of STC mRNA, thus implying a role for STC in oocyte maturation. Stanniocalcin, to our knowledge, is unique because no other secreted proteins produced by the ovarian thecal-interstitial compartment are significantly induced during mouse pregnancy. In summary, our data provide evidence for the active regulation of STC expression in the ovary during gestation and lactation and therefore implies that STC is a new regulator of the gestational and nursing state.
The recent discovery of mammalian stanniocalcin (STC) prompted an investigation of its gene structure and expression pattern to study its function and regulation. We show that both the human and mouse genes are composed of four exons spanning about 13 kb, with 85% nucleotide sequence identity in coding regions. Remarkably high sequence conservation between species also exists in the approximately 3-kb 3'-untranslated region. Comparative analysis of the 5'-untranslated region and flanking DNA from the rat and human STC genes showed long stretches of CAG trinucleotide repeats and an additional (CA)25 dinucleotide repeat unique to the rat promoter. An analysis of STC expression in the mouse showed that ovary contained the highest level of messenger RNA, with lower, but detectable, levels in most tissues. In situ hybridization revealed strong, specific hybridization over the thecal-interstitial cells of the ovarian stroma, whereas immunohistochemical analysis indicated that STC was present not only in the stroma, but also in the corpora lutea and oocyte of the developing follicle. Consequently, STC may act as a signaling molecule between the thecal-interstitial cell compartment and the corpus luteum and oocyte, thereby regulating the activity of these structures in some way. These findings suggest that in addition to its role in mineral metabolism, STC has acquired an important function in reproduction during its evolution to mammals.
Human sex hormone-binding globulin (SHBG) is produced by hepatocytes and transports sex steroids in the blood. The rat gene encoding SHBG is expressed transiently in the liver during fetal life, but it is not expressed in the liver postnatally, and the small amounts of SHBG in rat blood are derived from gonadal sources. To study the biosynthesis and function of human SHBG in an in vivo context, we have produced several lines of transgenic mice that contain either 11 kb (shbg11) or 4.3 kb (shbg4) portions of the human shbg locus. The expression and regulation of these transgenes have now been studied during fetal and postnatal development. In situ hybridization of an shbg11 transgenic mouse fetus at 17.5 days postcoitus located human shbg transcripts only in duodenal epithelial cells and hepatocytes. Temporal differences in the hepatic expression of mouse shbg and human shbg transgenes during late fetal development were reflected in corresponding differences in mouse and human SHBG levels in fetal and neonatal mouse blood. Serum concentrations of human SHBG increased during the first weeks of life regardless of gender until about 20 days of age in shbg11 mice, but after this time they continued to increase only in the males. This sexual dimorphism was reflected in corresponding differences in human SHBG messenger RNA (mRNA) abundance in the livers of these animals. However, it was not observed in shbg4 mice, in which hepatic production of plasma SHBG continued to increase after puberty regardless of gender. Serum testosterone and SHBG levels correlated in all sexually mature shbg transgenic mice. Human shbg transcripts were detectable only in testes of shbg11 mice and increased progressively in abundance from 10 days of age until the animal reached sexual maturity at 30 days of age, with appreciable increases occurring well before any changes in serum testosterone concentration. In the kidney, SHBG mRNA levels accumulated earlier in shbg11 than in shbg4 mice, and the expression of both types of transgenes was sexually dimorphic, with much higher SHBG mRNA levels in the kidneys of male mice. As increases in SHBG mRNA in the male kidneys coincided with increases in serum testosterone during sexual maturation, we reasoned that shbg transgene expression is androgen dependent in the kidney. This was confirmed by demonstrating that a decrease in SHBG mRNA abundance in male mouse kidneys after castration could be reversed by 5alpha-dihydrotestosterone treatment. Moreover, exogenous androgen increased human SHBG mRNA levels in the kidneys of female mice. In summary, comparisons of how different human shbg transgenes are expressed in vivo provides information about the positions of potential regulatory sequences that may control the hormonal regulation and tissue-specific expression of this gene during development.
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