The third intracellular loop of the human somatostatin receptor 5 is crucial for arrestin binding and receptor internalization after somatostatin stimulation

Somatostatin (SS) is a widely distributed polypeptide that exerts inhibitory effects on hormone secretion and cell proliferation by interacting with five different receptors (SST1-SST5). Beta-arrestins have been implicated in regulating SST internalization, but the structural domains mediating this effect are largely unknown. The aim of this study was to characterize the intracellular mechanisms responsible for internalization of human SST5 in the rat pituitary cell line GH3 and to identify the SST5 structural domains involved in this process. To this purpose we evaluated, by fluorescence microscopy and biochemical assay, the ability of wild-type, progressive C-terminal truncated and third cytoplasmatic loop mutants SST5-DsRed to associate with beta-arrestin-enhanced green fluorescent protein and to internalize under SS28 stimulation. The truncated mutants were comparable to the wild-type receptor with respect to recruitment of beta-arrestin-2 and internalization, whereas the third loop mutants R240W, S242A, and T247A showed the abolishment or reduction of arrestin association and a significant reduction of receptor internalization (14.4%, 29%, and 30.9% vs. 52.4% of wild type) and serine phosphorylation upon SS28 stimulation. Moreover, we evaluated the ability of simultaneous mutation of these three residues (R240, S242, and T247) and C-terminal truncated receptors to internalize. The progressive truncation of the C-terminal tail resulted in a progressive increased internalization (21.6%, 36.7%, and 41%, respectively) with respect to the full-length total third-loop mutant (15%). In conclusion, our results indicate the SST5 third intracellular loop as an important mediator of beta-arrestin/receptor interaction and receptor internalization, whereas they suggest that residues 328-347 within the C terminus may play an inhibitory role in receptor internalization.     

Extracellular superoxide dismutase (EC-SOD) gene mutations screening in a sample of Mediterranean population

The main role of superoxide dismutases (SODs) is to eliminate reactive oxygen species in cells and tissues. Extracellular SOD (EC-SOD/SOD3) is a major superoxide scavenger and it is located on cell surfaces and primarily in extracellular matrix, and binds heparan sulfates by its carboxyterminal portion. Human EC-SOD gene is located on chromosome 4 and comprises three exons and two introns. The SOD3 coding sequence is entirely located within exon 3 and has missense polymorphisms. The Arg213Gly mutation affects the function of the carboxyterminus and correlates with several diseases. In this work, we explored genetic variants within EC-SOD gene of subjects living in southern Italy. Four new variations were detected: one was silent mutation, while three were missense variations that give rise to amino acid substitutions at position 131 (F>C), 160 (V>L) and 202 (R>L) in the mature product. The Arg213Gly variant was not found. The missense mutations in the DNA of assayed 2400 chromosomes had frequencies of 5.34% for the F131C variation, 0.25% for the V160L variation and 0.84% for the R202L variation. The effect of these alterations on the metabolic activity and diseases remains to be further explained.