Identification of Ran-binding protein M as a stanniocalcin 2 interacting protein and implications for androgen receptor activity

Stanniocalcin (STC), a glycoprotein hormone originally discovered in fish, has been implicated in calcium and phosphate homeostasis. While fishes and mammals possess two STC homologs (STC1 and STC2), the physiological roles of STC2 are largely unknown compared with those of STC1. In this study, we identified Ran-binding protein M (RanBPM) as a novel binding partner of STC2 using yeast two-hybrid screening. The interaction between STC2 and RanBPM was confirmed in mammalian cells by immunoprecipitation. STC2 enhanced the RanBPM-mediated transactivation of liganded androgen receptor (AR), but not thyroid receptor β, glucocorticoid receptor, or estrogen receptor β. We also found that AR interacted with RanBPM in both the absence and presence of testosterone (T). Furthermore, we discovered that STC2 recruits RanBPM/AR complex in T-dependent manner. Taken together, our findings suggest that STC2 is a novel RanBPM-interacting protein that promotes AR transactivation. [BMB Reports 2014; 47(11): 643-648]     

Evidence for stanniocalcin and a related receptor in annelids

Stanniocalcin (STC) is a prime example of a hormone whose discovery in fish led to its subsequent discovery in mammals. STC is considered to be first and foremost a vertebrate polypeptide hormone with regulatory effects on ion transport, mitochondrial function and steroid hormone synthesis. The gene is widely expressed in both fishes and mammals, and the hormone can operate via both local and endocrine signaling pathways. In spite of the growing catalogue of vertebrate hormones and receptors with homologues in invertebrates, the notion that there might be an invertebrate STC homolog has received scant attention to date. In the present study, we have provided evidence for STC in annelid worms (freshwater leeches). Western blot analysis revealed the presence of two STC immunoreactive (STCir) proteins in leech tissue extracts of 100 and 193 kDa. These same extracts significantly lowered the rate of gill calcium transport upon injection into fish. Similarly, fish STC increased the rate of whole body calcium uptake when administered to leeches, and STC receptors of high affinity were identified on isolated leech plasma membranes. Two discrete populations of STC-positive cells were also identified in leeches using antibodies to fish STC and fish STC cRNA probes. One of the cell types was confined to the skin. The second cell type was confined to the coelomic cavity and identified as an adipose cell, which in leeches is a major repository of fat. Collectively, the data constitutes compelling evidence for the existence of STC-related proteins and receptors in annelids that share structural and functional similarities with those in vertebrates.     

Human stanniocalcin-2 exhibits potent growth-suppressive properties in transgenic mice independently of growth hormone and IGFs

Stanniocalcin (STC)-2 was discovered by its primary amino acid sequence identity to the hormone STC-1. The function of STC-2 has not been examined; thus we generated two lines of transgenic mice overexpressing human (h)STC-2 to gain insight into its potential functions through identification of overt phenotypes. Analysis of mouse Stc2 gene expression indicates that, unlike Stc1, it is not highly expressed during development but exhibits overlapping expression with Stc1 in adult mice, with heart and skeletal muscle exhibiting highest steady-state levels of Stc2 mRNA. Constitutive overexpression of hSTC-2 resulted in pre- and postnatal growth restriction as early as embryonic day 12.5, progressing such that mature hSTC-2-transgenic mice are approximately 45% smaller than wild-type littermates. hSTC-2 overexpression is sometimes lethal; we observed 26-34% neonatal morbidity without obvious dysmorphology. hSTC-2-induced growth retardation is associated with developmental delay, most notably cranial suture formation. Organ allometry studies show that hSTC-2-induced dwarfism is associated with testicular organomegaly and a significant reduction in skeletal muscle mass likely contributing to the dwarf phenotype. hSTC-2-transgenic mice are also hyperphagic, but this does not result in obesity. Serum Ca2+ and PO4 were unchanged in hSTC-2-transgenic mice, although STC-1 can regulate intra- and extracellular Ca2+ in mammals. Interestingly, severe growth retardation induced by hSTC-2 is not associated with a decrease in GH or IGF expression. Consequently, similar to STC-1, STC-2 can act as a potent growth inhibitor and reduce intramembranous and endochondral bone development and skeletal muscle growth, implying that these tissues are specific physiological targets of stanniocalcins.     

Stanniocalcin 1 as a pleiotropic factor in mammals

Stanniocalcin (STC)1 is the mammalian homologue of STC which was originally identified as a calcium/phosphate-regulating hormone in bony fishes. STC1 is a homodimeric phosphoglycoprotein with few if any identified unique motifs in its structure with the exception of CAG repeats in the 5'-untranslated region. In contrast to fish STC which is expressed mainly in the corpuscles of Stannius, STC1 is expressed in a wide variety of tissues, but unexpectedly is not detected in the circulation under normal circumstances. Thus, STC1 may play an autocrine/paracrine rather than a classic endocrine role in mammals. Consistent with this, pleiotropic effects of STC1 have been postulated in physiological and measured in pathological situations. There is much current interest in identifying a specific STC1 receptor and putative signaling pathways to which it may be coupled. In this regard, STC1 may regulate intracellular calcium and/or phosphate (Pi) levels. In the skeletal system, for example, Pi uptake in bone-forming osteoblasts via a direct effect of STC1 on expression of the NaPi transporter Pit1 may contribute to bone formation. Here we review current understanding of the role of STC1 and its possible molecular mechanisms in the skeleton and elsewhere.     

Prolactin osmoregulatory function in fishes and its projection on mammals

Prolactin evolution and key role in fish osmoregulation were reviewed. Comparison of fish and mammalian prolactin was made in respect of its structure, producing tissues, regulation of pituitary secretion. Peculiarities of prolactin receptor structure and prolactin-induced signal cascades, tissue distribution and regulation of prolactin receptor expression were compared in fishes and mammals. Data on mechanisms of prolactin action on ionoconservation in teleost fishes at the level of gills, kidney, intestine, and skin were presented. The facts of prolactin participation in the regulation of water and salt balance in mammals were observed. The existence of fundamentally similar mechanisms of osmoregulatory prolactin action in fishes and mammals was accumed and algorithm of their investigation was suggested.     

Melanin-concentrating hormone: A neuropeptide hormone affecting the relationship between photic environment and fish with special reference to background color and food intake regulation

Melanin-concentrating hormone (MCH) was first discovered in the pituitary gland of the chum salmon for its role in the regulation of skin pallor. Currently, MCH is known to be present in the brains of organisms ranging from fish to mammals. MCH has been suggested to be conserved principally as a central neuromodulator or neurotransmitter in the brain. Indeed, MCH is considered to regulate food intake in mammals. In this review, profiles of MCH in the brain and pituitary gland of teleost fishes are described, focusing on the involvement of MCH in background color adaptation and in food intake regulation.     

New Paralogues and Revised Time Line in the Expansion of the Vertebrate GH18 Family

Chitinase enzymes hydrolyse the polysaccharide chitin, an abundant architectural component in invertebrates and fungi. Most mammals encode at least two endochitinases (CHIT1 and CHIA/AMCase), as well as several homologues encoding catalytically inactive chitinase-like proteins or chilectins (all GH18 family proteins). It is becoming increasingly apparent that chitinases and chilectins play an important role in inflammation and their over-expression is correlated with numerous pathological conditions. We have conducted a detailed phylogenomic study of this gene family in order to understand its evolutionary history and the selection forces at work. The family has undergone extensive expansion, initiating with a duplication event at the root of the vertebrate tree generating the ancestors of CHIT1 and CHIA. Our analyses indicate that two further duplications of ancestral CHIA predate the divergence of bony fishes, one leading to a newly identified paralogous group (we have termed CHIO). In fish these sequences fall into two clades bearing the hallmarks of the teleost-specific genome duplication (referred to as 3R). In tetrapods, additional duplications predate and postdate the amphibian/mammalian split and relics of some exist as pseudogenes in the human genome. Expansion and selection of chilectins is pronounced in mammals and CHI3L1 (with a proposed function in immunity) is found in most mammals but not other vertebrates, while CHI3L2 is also evident in reptiles. Notably oviductin (OVGP1) became basic and gained a glycosylated tail with its evolving role in the mammalian reproductive system. In each case, retention of the sugar-binding barrel structure has constrained positive selection to limited sites.     

Cloning and characterization of a zebrafish Y2 receptor

The NPY receptors belong to the superfamily of G-protein coupled receptors and in mammals this family has five members, named Y1, Y2, Y4, Y5, and Y6. In bony fish, four receptors have been identified, named Ya, Yb, Yc and Y7. Yb and Y7 arose prior to the split between ray-fined fishes and tetrapods and have been lost in mammals. Yc appeared as a copy of Yb in teleost fishes. Ya may be an ortholog of Y4, but surprisingly no unambiguous receptor ortholog to any of the mammalian subtypes has yet been identified in bony fishes. Here we present the cloning and pharmacological characterization of a Y2 receptor in zebrafish, Danio rerio. To date, this is the first Y2 receptor outside mammals and birds that has been characterized pharmacologically. Phylogenetic analysis and synteny confirmed that this receptor is orthologous to mammalian Y2. We show that the receptor is pharmacologically most similar to chicken Y2 which leads to the conclusion that Y2 has acquired several novel characteristics in mammals. Y2 from zebrafish binds very poorly to the Y2-specific antagonist BIIE0246. Our pharmacological characterization supports our previous conclusions regarding the binding pocket of BIIE0246 in the human Y2 receptor.     

Nuclear targeting of stanniocalcin to mammary gland alveolar cells during pregnancy and lactation

In most mammalian tissues, the stanniocalcin-1 gene (STC-1) produces a 50-kDa polypeptide hormone known as STC50. Within the ovaries, however, the STC-1 gene generates three higher-molecular-mass variants known as big STC. Big STC is targeted locally to corpus luteal cells to block progesterone release. During pregnancy and lactation, however, ovarian big STC production increases markedly, and the hormone is released into the serum. During lactation, this increase in hormone production is dependent on a suckling stimulus, suggesting that ovarian big STC may have regulatory effects on the lactating mammary gland. In this report, we have addressed this possibility. Our results revealed that virgin mammary tissue contained large numbers of membrane- and mitochondrial-associated STC receptors. However, as pregnancy progressed into lactation, there was a decline in receptor densities on both organelles and a corresponding rise in nuclear receptor density, most of which were on milk-producing, alveolar cells. This was accompanied by nuclear sequestration of the ligand. Sequestered STC resolved as one approximately 135-kDa band in the native state and therefore had the appearance of a big STC variant. However, chemical reduction collapsed this one band into six closely spaced, lower-molecular-mass species (28-41 kDa). Mammary gland STC production also underwent a dramatic shift during pregnancy and lactation. High levels of STC gene expression were observed in mammary tissue from virgin and pregnant rats. However, gene expression then fell to nearly undetectable levels during lactation, coinciding with the rise in nuclear targeting. These findings have thus shown that the mammary glands are indeed targeted by STC, even in the virgin state. They have further shown that there are marked changes in this targeting pathway during pregnancy and lactation, accompanied by a switch in ligand source (endogenous to exogenous). They also represent the first example of nuclear targeting by STC.     

Upregulated expression of stanniocalcin-1 during adipogenesis

Stanniocalcin-1 (STC-1) is a 56-kDa homodimeric protein originally discovered in bony fish, where it protects against toxic levels of environmental calcium by lowering the uptake of calcium via the gills and by increasing the reabsorption of phosphate in the kidney. Here we report expression of STC-1 in mammalian white and brown fat tissue. Coexpression of STC-1 and perilipin confirmed the presence of STC-1 in mature fat cells. Neoplastic adipocytes in well-differentiated liposarcomas also stained for STC-1, while the frequency of STC-1-positive cells was lower in high-grade liposarcomas. The kinetics of STC-1 expression during adipogenesis was investigated in 3T3-LI cells, which can be induced to adipocyte differentiation. Untreated 3T3-L1 cells displayed negligible amounts of STC-1, whereas 3T3-L1 cells, treated with an adipogenic cocktail, upregulated the expression of STC-1 concomitantly with acquisition of the adipocytic phenotype. We have previously reported a high expression of STC-1 in postmitotically differentiated neurons and megakaryocytes. We have also shown that expression of STC-1 confers increased resistance to hypoxic and oxidative stress in neurons. Given this, our findings suggest that STC-1, also in terminally differentiated adipocytes, may function as a "survival factor", which contributes to the maintenance of the integrity of mature adipose tissue.     

Glucagon-like Peptide-1 (GLP-1) and the Control of Glucose Metabolism in Mammals and Teleost Fish

Glucose metabolism in mammalian species and teleost fish iscontrolled by different metabolic pathways. These include differencesin the function of several major hormones, especially insulinand GLP-1. The major physiological role of GLP-1 in mammalsis to connect the consumption of nutrients with glucose metabolism.The glucose lowering effects of GLP-1 in the postprandial stateof mammals are regulated predominantly through metabolic pathwaysthat integrate different physiological processes. These are:(i) stimulation of insulin release from the pancreatic ß-cellduring hyperglycemia and (ii) inhibition of nutrient absorptionin the gastrointestinal tract. These effects are mediated bya same type of a highly selective GLP-1 receptor, often referredto as the "pancreatic GLP-1 receptor." In teleost fish GLP-1increases glucose levels through the activation of glycogenolysisand gluconeogenesis from liver. Functional characterizationof the recombinant GLP-1 receptor from zebrafish, which is thefirst example of a recombinant fish GLP-1 receptor, demonstratedthat zebrafish GLP-1 receptor has a binding specificity towardsa wider range of GLP-1 structures than the mammalian GLP-1 receptor.This property of the zebrafish GLP-1 receptor, and most likelyother fish GLP-1 receptors, sets apart the structure of thezebrafish GLP-1 receptor from the structures of mammalian GLP-1receptors. These differences in the binding specificity betweenthe zebrafish and mammalian GLP-1 receptors might reflect inpart the differences in the mechanism by which GLP-1 regulatesglucose metabolism in mammals and teleost fish.     

MHC variation and tissue transplantation in fish

Major histocompatibility complex (MHC) genes were originally discovered because of their role in tissue rejection in mammals and have subsequently been implicated in the incidence of autoimmune diseases and resistance to infectious diseases. Here we present the first demonstration that a gene defined by molecular sequence in the fish MHC, specifically a class II locus, plays an important role in tissue rejection. This effect in the endangered Gila topminnows appears to be additive and depends on the number of MHC alleles shared between the host and the recipient fish of the scale transplants. In addition, there was lower success of scale transplants in MHC-matched individuals in a population with high microsatellite variation than in a population with low variation. This suggests that other loci, presumably other MHC loci, play a significant role in transplantation success in fishes, as they do in mammals.     

Stanniocalcin in terminally differentiated mammalian cells

Stanniocalcin (STC) is a glycoprotein hormone originally found in teleost fish, where it regulates the calcium/phosphate homeostasis, and protects the fish against toxic hypercalcemia. STC was considered an exclusive fish protein, until the cloning of cDNA for human (in 1995) and murine (in 1996) STC. We originally reported a high constitutive content of STC in mammalian brain neurons, and found that the expression of STC occurred concomitantly with terminal differentiation of neural cells. Since then, we have investigated the expression of STC in relation to terminal cell differentiation also in mammalian hematopoietic tissue, and fat tissues. In this review we summarize our findings on STC expression during postmitotic differentiation in three different cell systems; in neural cells, in megakaryocytes and in adipocytes. We also present findings, suggesting that STC plays a role for maintaining the integrity of terminally differentiated mammalian cells.     

Urokinase-type Plasminogen Activator-like Proteases in Teleosts Lack Genuine Receptor-binding Epidermal Growth Factor-like Domains

Plasminogen activation catalyzed by urokinase-type plasminogen activator (uPA) plays an important role in normal and pathological tissue remodeling processes. Since its discovery in the mid-1980s, the cell membrane-anchored urokinase-type plasminogen activator receptor (uPAR) has been believed to be central to the functions of uPA, as uPA-catalyzed plasminogen activation activity appeared to be confined to cell surfaces through the binding of uPA to uPAR. However, a functional uPAR has so far only been identified in mammals. We have now cloned, recombinantly produced, and characterized two zebrafish proteases, zfuPA-a and zfuPA-b, which by several criteria are the fish orthologs of mammalian uPA. Thus, both proteases catalyze the activation of fish plasminogen efficiently and both proteases are inhibited rapidly by plasminogen activator inhibitor-1 (PAI-1). But zfuPA-a differs from mammalian uPA by lacking the exon encoding the uPAR-binding epidermal growth factor-like domain; zfuPA-b differs from mammalian uPA by lacking two cysteines of the epidermal growth factor-like domain and a uPAR-binding sequence comparable with that found in mammalian uPA. Accordingly, no zfuPA-b binding activity could be found in fish white blood cells or fish cell lines. We therefore propose that the current consensus of uPA-catalyzed plasminogen activation taking place on cell surfaces, derived from observations with mammals, is too narrow. Fish uPAs appear incapable of receptor binding in the manner known from mammals and uPA-catalyzed plasminogen activation in fish may occur mainly in solution. Studies with nonmammalian vertebrate species are needed to obtain a comprehensive understanding of the mechanism of plasminogen activation.     

Hypoxic preconditioning induces elevated expression of stanniocalcin-1 in the heart

Animals exposed for a few hours to low oxygen content (8%) develop resistance against further ischemic myocardial damage. The molecular mechanism(s) behind this phenomenon, known as hypoxic preconditioning (HOPC), is still incompletely understood. Stanniocalcin-1 (STC-1) is an evolutionarily conserved glycoprotein originally discovered in fish, in which it regulates calcium/phosphate homeostasis and protects against toxic hypercalcemia. Our group originally reported expression of mammalian STC-1 in brain neurons and showed that STC-1 is a prosurvival factor that guards neurons against hypercalcemic and hypoxic damage. This study investigates the involvement of STC-1 in HOPC-induced cardioprotection. Wild-type mice and IL-6-deficient (Il-6(-/-)) mice were kept in hypoxic conditions (8% O(2)) for 6 h. Myocardial Stc-1 mRNA expression was quantified during hypoxia and after recovery. HOPC triggered a biphasic upregulation of Stc-1 expression in hearts of wild-type mice but not in those of Il-6(-/-) mice. Treatment of cardiomyocyte cells in culture with hypoxia or IL-6 elicited an Stc-1 response, and ectopically expressed STC-1 in HL-1 cells localized to the mitochondria. Our findings indicate that IL-6-induced expression of STC-1 is one molecular mechanism behind the ischemic tolerance generated by HOPC in the heart.     

siRNA及其在哺乳动物中的应用

RNA干扰现象已经在多种生物中发现,但是在多数哺乳动物中尚未发现自然存在RNA干扰的证据。因此最初RNA干扰技术在哺乳动物细胞中的应用受到很大的限制。直到对RNA干扰作用机制有了较深入的了解以后,主要是小干扰RNA的发现使RNA干扰技术在哺乳动物中的应用得以推广。本文介绍了RNA干扰,重点描述了小干扰RNA的发现、特点、现有制备方法以及应用。     

Identification of Nogo-66 receptor (NgR) and homologous genes in fish

The Nogo-66 receptor NgR has been implicated in the mediation of inhibitory effects of central nervous system (CNS) myelin on axon growth in the adult mammalian CNS. NgR binds to several myelin-associated ligands (Nogo-66, myelin associated glycoprotein, and oligodendrocyte-myelin glycoprotein), which, among other inhibitory proteins, impair axonal regeneration in the CNS of adult mammals. In contrast to mammals, severed axons readily regenerate in the fish CNS. Nevertheless, fish axons are repelled by mammalian oligodendrocytes in vitro. Therefore, the identification of fish NgR homologs is a crucial step towards understanding NgR functions in vertebrate systems competent of CNS regeneration. Here, we report the discovery of four zebrafish (Danio rerio) and five fugu (Takifugu rubripes) NgR homologs. Synteny between fish and human, comparable intron-exon structures, and phylogenetic analyses provide convincing evidence that the true fish orthologs were identified. The topology of the phylogenetic trees shows that the extra fish genes were produced by duplication events that occurred in ray-finned fishes before the divergence of the zebrafish and pufferfish lineages. Expression of zebrafish NgR homologs was detected relatively early in development and prominently in the adult brain, suggesting functions in axon growth, guidance, or plasticity.