Prosomatostatin is proteolytically processed at the amino terminal segment by subtilase SKI-1.

Processing of prohormones to generate active products typically occurs at basic residues via cleavage by proprotein convertases. A less common type of cleavage is mediated at hydrophobic (L, V, F, N) or small amino acid (A, T, S) residues. Efforts to identify the proteinases responsible for processing precursors at their hydrophobic amino acids has led to the recent cloning of a new type-1 membrane-bound subtilase called SKI-1. The NH2-terminal region of prosomatostatin, previously shown to contain a sorting signal for the regulated secretory pathways, is processed to generate PSST[1-10]. The exact cleavage mechanism is unknown, but has been assumed to involve monobasic processing at Lys13 followed by carboxypeptidase trimming. We found that K13A mutation did not block PSST[1-10] production. Since the prosomatostatin sequence R8-Q9-F10-L11 \ qualifies as a potential SKI-1 substrate, using a vaccinia virus expression system along with HPLC and radioimmunoassays, we observed that overexpression of recombinant SKI-1 in COS-1 and HEK-293 cells significantly increased the production of PSST[1-10]. Additionally, in CHO cells lacking SKI-1, there was a significant reduction in PSST[1-10] production which could be increased upon SKI-1 stimulation. Mutagenesis studies showed that efficient processing of PSST to PSST[1-10] required the RXRXXL motif. However, this NH2-terminal cleavage was not a prerequisite for the formation of SST-14 and SST-28.

A conserved alpha-helix at the amino terminus of prosomatostatin serves as a sorting signal for the regulated secretory pathway.

Mammalian prosomatostatin (PSST) contains the bioactive peptides SST-14 and SST-28 at the COOH-terminal end of the molecule and a putative sorting signal in the propeptide segment for targeting the precursor to the regulated secretory pathway. The NH(2)-terminal segment of PSST consists of an amphipathic alpha-helix, which has been totally conserved throughout vertebrate evolution. We have analyzed the PSST-(3--15) region for sorting function by alanine scanning and deletional mutagenesis. Mutants created were stably expressed in AtT-20 cells. Regulated secretion was studied by analyzing basal and stimulated release of SST-14 LI and by immunocytochemistry for staining of SST-14 LI in punctate granules. Deletion of the PSST-(3--15) segment blocked regulated secretion and rerouted PSST for constitutive secretion as unprocessed precursor. Alanine scanning mutagenesis identified the region Pro(5)--Gln(12) as being important in precursor targeting, with Leu(7) and Leu(11) being critical. Molecular modeling demonstrated that these two residues are located in close proximity on a hydrophobic surface of the alpha-helix. Disruption of the alpha-helix did not impair the ability of PSST to be processed at the COOH terminus to SST-14 and SST-28. Processing, however, was shifted to the early compartments of the secretory pathway rather than storage granules and was relatively inefficient.

Processing of rat preprocortistatin in mouse AtT-20 cells.

Preprocortistatin (PPCST) has been recently identified as a novel somatostatin (SST)-related gene expressed only in brain. PPCST shares 11 of 14 residues with SST-14 at its C-terminal segment, where it features Lys-Lys and Lys-Arg basic sites for cleavage to putative cortistatin (CST)-14 and CST-29 peptides, respectively. Although synthetic replicates of the two putative CST peptides interact with SST receptors, they also display novel effects suggesting independent biological functions. Nothing is currently known about the naturally occurring mature cleavage products of PPCST posttranslational processing. Here we have cloned rat PPCST cDNA, stably expressed it in AtT-20 pituitary cells, and characterized the cellular and releasable products of PPCST processing by HPLC and radioimmunoassay using a SST-14 antibody that recognizes synthetic CST-14 and CST-29. Transfected cells released 120 +/- 21 pg of total CST-LI per plate basally, with an increase to 204 +/- 33 pg per plate with forskolin stimulation (p < 0.05). HPLC chromatograms of cell extracts revealed three peaks corresponding to CST-14, CST-29, and unprocessed PPCST (ratio, 41:55:4.5). CST was released preferentially as CST-14 (63-70%) compared with CST-29 (30-37%) under basal and forskolin-stimulated conditions. These studies demonstrate efficient processing of PPCST to both CST-14 and CST-29 through putative cleavage at both C-terminal dibasic sites of PPCST. Although the two peptides are synthesized approximately equally, CST-14 is released preferentially via the regulated secretory pathway.