In 1988, insulin-like growth factor-binding protein-1 (IGFBP-1) became the first characterized member of a group of structurally related soluble proteins which specifically bind and modulate the actions of the IGFs. Since then, a wealth of information has accumulated regarding the physiology of this dynamic serum protein. In this review, we update our 1993 summary (Lee PDK et al. Proc Soc Exp Biol Med 204:4-29) of the status of IGFBP-1 research. The IGFBP-1 protein sequence contains 12 N-terminal and 6 C-terminal cysteine residues which are conserved in other mammalian IGFBP-1 sequences and amongst other IGFBPs; both of the cysteine-rich regions are required for optimal IGF binding. The nonconserved IGFBP-1 midregion may act as both a hinge which defines ligand binding characteristics and as a specific target for protease activity. Integrin-binding and phosphorylation sites within the IGFBP-1 sequence have functional significance in vitro, but their physiologic relevance in vivo have not been defined. The human IGFBP-1 and IGFBP-3 genes are contiguous and located in close proximity to the homeobox A (HOXA) gene cluster on chromosome 7. The other IGFBP genes, located on chromosomes 2, 12, and 17, are also associated with HOX clusters, suggesting evolutionary linkage of the IGFBP and HOX gene families. Similarities between the hIGFBP-1 and phosphoenolpyruvate kinase (PEPCK) promoters, including regions conferring insulin, glucocorticoid, and cyclic adenosine-monophosphate responses, are consistent with our previous hypothesis that IGFBP-1 is involved in regulation of glucose metabolism. The tissue-specific patterns of IGFBP-1 gene expression in liver, kidney, decidua, and ovary may be due to stimulation of IGFBP-1 transcription by hepatic nuclear factor 1 (HNF1) proteins. Clinical and basic studies of IGFBP-1 physiology have been aided by several recently developed assay methods. Numerous investigations have confirmed that insulin, via inhibition of IGFBP-1 transcription, is the primary determinant of IGFBP-1 expression both in vitro and in vivo. IGF-I and IGF-II also have specific inhibitory effects on IGFBP-1 expression. Glucocorticoids and cAMP stimulate IGFBP-1 transcription, but these effects are observed only in conditions of low or absent insulin effect. Other stimulants of IGFBP-1 expression include thyroid hormones and epidermal growth factor. Phorbol ester stimulation of IGFBP-1 expression can supersede the effects of insulin in vitro;however, the mechanism and in vivo correlates of this effect have not been determined. Cytokines and, perhaps, growth hormones may affect IGFBP-1 expression, perhaps by altering the regulatory actions of insulin; this effect may have important clinical relevance. IGFBP-1 expression is upregulated in liver and (nonhuman) kidney during postinjury regeneration. The IGF-inhibitory actions of IGFBP-1 has been confirmed by numerous in vitro studies and several in vivo animal investigations, including administration of recombinant IGFBP-1 and IGFBP-1 transgenic models. IGFBP-1 has ...
A high-throughput, retrovirus-mediated mutagenesis method based on gene trapping in embryonic stem cells was used to identify a novel mouse gene. The human ortholog encodes a transmembrane protein containing five extracellular immunoglobulin-like domains that is structurally related to human NEPHRIN, a protein associated with congenital nephrotic syndrome. Northern analysis revealed wide expression in humans and mice, with highest expression in kidney. Based on similarity to NEPHRIN and abundant expression in kidney, this protein was designated NEPH1 and embryonic stem cells containing the retroviral insertion in the Neph1 locus were used to generate mutant mice. Analysis of kidney RNA from Neph1 ؊/؊ mice showed that the retroviral insertion disrupted expression of Neph1 transcripts. Neph1 ؊/؊ pups were represented at the expected normal Mendelian ratios at 1 to 3 days of age but at only 10% of the expected frequency at 10 to 12 days after birth, suggesting an early postnatal lethality. The Neph1 ؊/؊ animals that survived beyond the first week of life were sickly and small but without edema, and all died between 3 and 8 weeks of age. Proteinuria ranging from 300 to 2,000 mg/dl was present in all Neph1 ؊/؊ mice. Electron microscopy demonstrated NEPH1 expression in glomerular podocytes and revealed effacement of podocyte foot processes in Neph1 ؊/؊ mice. These findings suggest that NEPH1, like NEPHRIN, may play an important role in maintaining the structure of the filtration barrier that prevents proteins from freely entering the glomerular urinary space.NEPHRIN is a transmembrane protein of the immunoglobulin (Ig) superfamily that is expressed by epithelial podocytes of developing glomeruli (13, 17). Congenital nephrotic syndrome of the Finnish type results from mutations in NPHS1, the human gene encoding NEPHRIN, indicating a role for NEPHRIN in maintaining the filtration barrier that prevents proteins from freely entering the glomerular urinary space (6,17). Recent studies localized NEPHRIN to the slit diaphragms that form the junctions between podocyte foot processes interdigitating along the glomerular basement membrane. This and other studies suggest that NEPHRIN proteins extending toward each other from adjacent podocyte foot processes may interdigitate in a zipper-like structure to form the crucial filtration barrier in the slit diaphragm. The eight Ig-like domains of each NEPHRIN protein, which are of the C2 type of Ig domain known to be involved in cell-cell interactions, are thought to provide the homophilic interactions that bind these NEPHRIN proteins together (13, 17).We use a high-throughput mutagenesis method based on gene trapping in embryonic stem (ES) cells that allows automated production of sequence tags from the trapped and mutated genes (20). These ES cell clones are stored in a library called Omnibank, and the sequence tag from the gene trapped in each clone, referred to as the Omnibank sequence tag or OST, is entered into a searchable database. A protein with Ig domains was identified with...
Insulin-like growth factor-binding protein (IGFBP)-3 regulates apoptosis in an IGF-independent fashion and has been shown to localize to nuclei. We cloned the nuclear receptor retinoid X receptor-␣(RXR-␣) as an IG-FBP-3 protein partner in a yeast two-hybrid screen. Multiple methodologies showed that IGFBP-3 and RXR-␣ bind each other within the nucleus. IGFBP-3-induced apoptosis was abolished in RXR-␣-knockout cells. IGFBP-3 and RXR ligands were additive in inducing apoptosis in prostate cancer cells. IGFBP-3 enhanced RXR response element and inhibited RARE signaling. Thus, RXR-␣-IGFBP-3 interaction leads to modulation of the transcriptional activity of RXR-␣ and is essential for mediating the effects of IGFBP-3 on apoptosis.
Insulin-like growth factor-binding protein (IGFBP)-1 is one of six homologous proteins that specifically bind and modulate the mitogenic and metabolic actions of insulin-like growth factor (IGF)-I and IGF-II. Of the six IGFBP, IGFBP-1 is the only one that displays rapid dynamic regulation in vivo, with serum levels varying 10-fold or more in relation to meals. The complementary cDNA for IGFBP-1 was first reported in 1988. The predicted 234-amino acid sequence has a molecular mass of 25.3 kDa. The N-terminal and C-terminal regions are highly homologous among rat, human, and bovine sequences, and contain 18 conserved cysteines which are postulated to provide a framework for ligand binding. The 65-residue midregion is less homologous and does not contain cysteines, but does include a Pro-Glu-Ser-Thr (PEST) domain that is typical of rapidly metabolized proteins. The gene for IGFBP-1 has been localized to human chromosome region 7p12-p14, where it is contiguous with the gene for IGFBP-3. IGFBP-1 mRNA and protein expression have been identified in human liver and uterine decidua, and in nonhuman kidney. In vitro and in vivo studies indicate that insulin is the primary regulator of IGFBP-1 expression in these tissues, and that the primary effect of insulin is rapid inhibition of transcription. On the other hand, cortisol, glucagon, and cAMP stimulate IGFBP-1 production. Limited data also show a potent stimulatory effect of phorbol esters. A detailed review of IGFBP-1 levels and physiology in vivo and in vitro is presented. The function of IGFBP-1 is not completely defined. However, several studies demonstrate that IGFBP-1 inhibits IGF binding to cell surface receptors and thereby inhibits IGF-mediated mitogenic and cell metabolic actions. Furthermore, IGFBP-1 regulation by insulin and glucoregulatory hormones in vitro and limited in vivo data are consistent with a role for IGFBP-1 in glucose counterregulation.
FoxO transcription factors are important targets of insulin action. To better understand the role of FoxO proteins in the liver, we created transgenic mice expressing constitutively active FoxO1 in the liver using the ␣1-antitrypsin promoter. Fasting glucose levels are increased, and glucose tolerance is impaired in transgenic (TGN) versus wild type (WT) mice. Interestingly, fasting triglyceride and cholesterol levels are reduced despite hyperinsulinemia, and post-prandial changes in triglyceride levels are markedly suppressed in TGN versus WT mice. Activation of pro-lipogenic signaling pathways (atypical protein kinase C and protein kinase B) and the ability to suppress -hydroxybutyrate levels are not impaired in TGN. In contrast, de novo lipogenesis measured with 3 H 2 O is suppressed by ϳ70% in the liver of TGN versus WT mice after refeeding. Gene-array studies reveal that the expression of genes involved in gluconeogenesis, glycerol transport, and amino acid catabolism is increased, whereas genes involved in glucose utilization by glycolysis, the pentose phosphate shunt, lipogenesis, and sterol synthesis pathways are suppressed in TGN versus WT. Studies with adenoviral vectors in isolated hepatocytes confirm that FoxO1 stimulates expression of gluconeogenic genes and suppresses expression of genes involved in glycolysis, the shunt pathway, and lipogenesis, including glucokinase and SREBP-1c. Together, these results indicate that FoxO proteins promote hepatic glucose production through multiple mechanisms and contribute to the regulation of other metabolic pathways important in the adaptation to fasting and feeding in the liver, including glycolysis, the pentose phosphate shunt, and lipogenic and sterol synthetic pathways.FoxO 2 transcription factors are important targets of insulin and growth factor action, and they contribute to the regulation of cell growth, differentiation, and metabolism (1-3). FoxO proteins form a subgroup within the family of Forkhead box (or Fox) transcription factors (4). Early studies indicated that Forkhead proteins interact with insulin response sequences (IRSs) in the promoter of the IGF-binding protein-1 (IGFBP-1) and the phosphoenolpyruvate carboxykinase (PEPCK) genes (5, 6) and that signaling through phosphatidylinositol 3Ј-kinase and protein kinase B (PKB) mediates IRS-dependent effects of insulin on gene expression (7). Genetic studies of Caenorhabditis elegans revealed that DAF-16, a FoxO transcription factor, is a major target of insulin-like signaling (8, 9). DAF-16 plays an important role in the adaptation to environmental stress, including nutrient restriction, and signaling through phosphatidylinositol 3Ј-kinase and PKB suppresses the function of DAF-16. Subsequent studies revealed that FoxO proteins contain highly conserved PKB phosphorylation sites (corresponding to Thr-24, Ser-256, and Ser-319 in human FoxO1) (10 -12) and that phosphorylation at these sites suppresses transactivation and promotes nuclear exclusion of FoxO proteins through multiple mechanisms (13)...
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