The incretin hormone glucagon-like peptide-1 (GLP-1) is an important regulator of postprandial insulin secretion. In addition to its insulinotropic actions on pancreatic beta-cells, GLP-1 enhances glucose disposal by insulin-independent mechanisms, suggesting that GLP-1 receptors are located on extrapancreatic tissues. In this study, we examined the tissue distribution of GLP-1 receptor (GLP-lR) messenger RNA (mRNA) in rat by RNAse protection, RT-PCR, and in situ hybridization. We identified GLP-1R mRNA in the lung, pancreatic islets, stomach, and kidney by the RNAse protection assay. RT-PCR analysis also detected GLP-1R mRNA in the hypothalamus and heart. In situ hybridization experiments identified receptor mRNA in the gastric pits of the stomach, large nucleated cells in the lung, crypts of the duodenum, and pancreatic islets. No localized specific grains were found in kidney, skeletal muscle, heart, liver, or adipocytes. These results indicate that sequences corresponding to the cloned rat islet GLP-1 receptor are expressed in the pancreatic islets, lung, hypothalamus, stomach, heart, and kidney but not in adipose, liver, and skeletal muscle. Further, the GLP-1 receptor expressed in the kidney and heart may be structural variants of the known receptor. Therefore, the observed extrapancreatic actions of GLP-1 may not be strictly confined to interactions with the defined GLP-1 receptor.
Somatomedins (SM) or insulin-like growth factors (IGF) constitute a heterogeneous group of peptides with important growth-promoting effects in vitro as well as in vivo. Amino acid sequences have been determined for only two of them, IGF-I and IGF-II, which are highly homologous. IGF-I, which is identical with SM-C, is composed of 70 amino acid residues and IGF-II contains 73 amino acids and may be identical with SM-A. Other peptides with different charge properties but with similar SM-like or insulin-like behaviour in biological and receptor assays, have been described but have not yet been fully characterized. The liver is known to be a major site of production of these peptides, but many other tissues--especially in the fetus--may synthesize them as well. We report here the nucleotide sequence of a human liver cDNA encoding the complete amino acid sequence of IGF-I. The IGF-I coding region is flanked by sequences encoding an amino-terminal peptide of at least 25 amino acid residues and a carboxyl-terminal peptide of 35 amino acids. This provides evidence that IGF-I is synthesized as a precursor protein and that formation of IGF-I from this precursor requires proteolytic processing at both ends.
The cAMP response element binding protein CREB activates the transcription of genes in response to phosphorylation by cAMP-dependent protein kinase A (PKA) and other protein kinases. Phosphorylated CREB activates transcription by recruiting transcriptional co-activators such as the CREB binding protein. Here, we describe experiments that analyze the effects of phosphorylation on the DNA binding affinity of CREB and the structural characteristics of the CREB/DNA complex in solution. Analysis of deletion mutants of CREB indicate that amino acid sequences within the transactivation domain promote high-affinity binding of CREB to fluorescently labeled oligonucleotides containing cAMP response elements. In vitro experiments indicate that phosphorylation is processive between PKA as the initial kinase and glycogen synthase kinase-3 (GSK-3) but not casein kinase II as the secondary kinase. Fluorescent electrophoretic mobility shift assays show that phosphorylation by PKA results in a 3-5-fold increase in the binding affinity of CREB to both the symmetrical somatostatin CRE (SMS-CRE) and the asymmetric somatostatin upstream element (SMS-UE). Processive phosphorylation of CREB by GSK-3 attenuates the enhanced DNA binding in response to PKA thus acts as an inhibitor of PKA-induced binding. Ferguson plot analyses demonstrate that phosphorylation of CREB by PKA and GSK-3 result in an increase in the spherical size and the net positive surface charge of the CREB/DNA complex. Moreover, these analyses uncovered the unexpected finding that CREB associates as a tetramer both in the presence and absence of DNA. These findings suggest a model by which phosphorylation of CREB alters the secondary structure and charge characteristics of the CREB/DNA complex resulting in an alteration in binding affinity.
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