Neurotensin receptors were solubilized from mouse brain using the zwitterionic detergent 3-[(3-cholamidopropyl)dimethylammonio]-1-propanesulfonic acid (CHAPS). The binding of 125I-labeled [Tyr3]neurotensin to the soluble fraction was time-dependent, saturable, and reversible. Unlabeled neurotensin and its analogues acetylneurotensin (8-13), neurotensin (9-13), and neurotensin (1-12) competitively antagonized the binding of 125I-labeled [Tyr3]neurotensin to CHAPS-solubilized extracts with relative potencies similar to those observed with membrane-bound receptors. Scatchard analysis of equilibrium binding data indicated that the soluble extract contained a single class of neurotensin binding sites with a Kd of 0.36 nM and a Bm of 63 fmol/mg. As already observed with membrane-bound receptors, the affinity of neurotensin for the soluble binding activity was decreased by Na+ ions. By contrast, soluble receptors were no longer sensitive to GTP and the antihistamine drug levocabastine. A molecular weight of about 100,000 was determined for soluble neurotensin receptors both under native conditions by gel filtration on Ultrogel AcA 34 and under denaturating conditions by sodium dodecyl sulfate-polyacrylamide gel electrophoresis after photoaffinity labeling.
Selective and mixed inhibitors of the three zinc metallopeptidases that degrade neurotensin (NT), e.g. endopeptidase 24-16 (EC 3.4.24.16), endopeptidase 24-11 (EC 3.4.24.11 or neutral endopeptidase, NEP) and endopeptidase 24-15 (EC 3.4.24.15), and leucine-aminopeptidase (type IV-S), that degrades the NT-related peptides, Neuromedin N (NN), are of great interest. On the structural basis of compound JMV 390-1 (N-[3-[(hydroxyamino)carbonyl]-1-oxo-2(R)-benzylpropyl]-L- isoleucyl-L-leucine), which was a full inhibitor of the major NT degrading enzymes, several hydroxamate inhibitors corresponding to the general formula HONHCO-CH2-CH(CH2-C6H5)CO-X-Y-OH (with X-Y = dipeptide) have been synthesized. Compound 7a (X-Y = Ile-Ala) was nearly 40-times more potent in inhibiting EC 24-16 than NEP and more than 800-times more potent than EC 24-15, with an IC50 (12 nM) almost equivalent to that of compound JMV 390-1. Therefore, this compound is an interesting selective inhibitor of EC 24-16, and should be an interesting probe to explore the physiological involvement of EC 24-16 in the metabolism of neurotensin.
Abstract The C‐terminal domain of the prohormone convertase PC1 is involved in targeting of the enzyme to secretory granules in neuroendocrine cells and is subsequently processed in this compartment at an Arg617‐Arg618 site. Three other dibasics are found in the C‐terminal domain of mouse PC1. Here, we examined the role of the four dibasics in targeting PC1 to secretory granules. All 15 possible combinations of dibasic mutations were performed. Wild‐type (WT) and mutant PC1 were stably expressed in neuroendocrine PC12 cells that lacked endogenous PC1. Processing, secretion and intracellular localization of PC1 and its mutants were analyzed. Leaving intact Arg617‐Arg618 and mutating any combination of the three other dibasics yielded proteins that were stored and processed in secretory granules, similarly to WT PC1. Mutating Arg617‐Arg618 alone or with any one of the three remaining dibasics generated proteins that were efficiently stored in secretory granules but were not processed further. Mutating Arg617‐Arg618 with more than one of the remaining dibasics produced proteins that reached the TGN but were not stored in secretory granules and exited the cells through the constitutive secretory pathway. These data demonstrate that the Arg617‐Arg618 plays a prominent role in targeting PC1 to secretory granules.
Mice homozygous for the fat mutation exhibit marked hyperpro-insulinemia and develop late onset obesity. The fat mutation was recently mapped to the gene encoding carboxypeptidase E (CpE), a processing enzyme involved in trimming C-terminal paired basic residues from prohormone-derived peptides. The mutation resulted in a loss of CpE activity that correlated with aberrant proinsulin processing. Neurotensin (NT) and melanin-concentrating hormone (MCH) are two neuropeptides that, among other central effects, inhibit food intake. Here, using RIA techniques coupled to reverse phase HPLC, we analyzed the processing products derived from the NT and MCH precursors in the brain of +/fat and fat/fat mice. Compared to control hypothalamic and brain extracts, fat/fat extracts had markedly reduced levels (>80%) of NT and neuromedin N (NN), another active pro-NT-derived peptide. In contrast, they exhibited high concentrations of biologically inactive NT-KR and NN-KR (NT and NN with a C-terminal Lys-Arg extension), two peptides that were undetectable in control extracts. MCH, which is located at the C-terminus of its precursor, was present in 2- to 3-fold higher amounts in fat/fat than in +/fat hypothalamus. Neuropeptide-Glu-Ile, another pro-MCH-derived neuropeptide separated from MCH by an Arg-Arg sequence, was present in amounts similar to those of MCH in control extracts. In contrast, neuropeptide-Glu-Ile was more than 10 times less abundant than MCH in extracts from obese mice. Our data are consistent with a deficit in CpE activity affecting the maturation of both pro-NT and pro-MCH. This suggests that abnormal neuropeptide and hormone precursor processing is a general phenomenon in fat/fat mice and supports the idea that defects in the production of neuropeptide involved in the control of feeding might lead to the development of obesity in these animals.
Abstract: The study of the pharmacological, biochemical, and transduction properties of the cloned rat brain neurotensin receptor was carried out in thymidine kinase mutant fibroblasts stably transfected with the receptor cDNA. The interaction of neurotensin with transfected fibroblasts leads to a concentration‐dependent stimulation of phosphatidylinositol hydrolysis and intracellular calcium. These effects are totally inhibited by the nonpeptide neurotensin antagonist SR48692. By contrast, this receptor remains unable to modulate intracellular levels of cyclic nucleotides. The transfected neurotensin receptor can be solubilized in an active form by digitonin with an identical pharmacological profile, whereas the detergent 3‐[(3‐cholamidopropyl)dimethylammonio]‐1‐propane‐sulfonic acid is unable to solubilize the binding activity. The binding of iodinated neurotensin to transfected fibroblasts bearing the cloned receptor remains partly undissociated even after an acid washing step, indicating that the transfected neurotensin receptor retains the capacity to be internalized according to a temperature‐dependent mechanism. Indeed, the sequestration of the neurotensin‐receptor complex can be blocked by phenylarsine oxide. Finally, photoaffinity labeling experiments reveal that the cloned rat brain neurotensin receptor is expressed under two forms with molecular masses of 50 and 60 kDa. Labeling and internalization of these two proteins are totally blocked by the neurotensin antagonist SR48692.
