Quantification of VGF- and pro-SAAS-derived peptides in endocrine tissues and the brain, and their regulation by diet and cold stress.

Two novel granin-like polypeptides, VGF and pro-SAAS, which are stored in and released from secretory vesicles and are expressed widely in nervous, endocrine, and neuroendocrine tissues, play roles in the regulation of body weight, feeding, and energy expenditure. Both VGF and pro-SAAS are cleaved into peptide fragments, several of which are biologically active. We utilized a highly sensitive and specific radioimmunoassay (RIA) to immunoreactive, pro-SAAS-derived PEN peptides, developed another against immunoreactive, VGF-derived AQEE30 peptides, and quantified these peptides in various mouse tissues and brain regions. Immunoreactive AQEE30 was most abundant in the pituitary, while brain levels were highest in hypothalamus, striatum, and frontal cortex. Immunoreactive PEN levels were highest in the pancreas and spinal cord, and in brain, PEN was most abundant in striatum, hippocampus, pons and medulla, and cortex. Since both peptides were expressed in hypothalamus, a region of the brain that controls feeding and energy expenditure, double label immunofluorescence studies were employed. These demonstrated that 42% of hypothalamic arcuate neurons coexpress VGF and SAAS peptides, and that the intracellular distributions of these peptides in arcuate neurons differed. By RIA, cold stress increased immunoreactive AQEE30 and PEN peptide levels in female but not male hypothalamus, while a high fat diet increased AQEE30 and PEN peptide levels in female but not male hippocampus. VGF and SAAS-derived peptides are therefore widely expressed in endocrine, neuroendocrine, and neural tissues, can be accurately quantified by RIA, and are differentially regulated in the brain by diet and cold stress.

Neuropeptide processing profile in mice lacking prohormone convertase-1.

Prohormone convertase 1 (PC1; also known as PC3) is believed to be responsible for the processing of many neuropeptide precursors. To look at the role PC1 plays in neuropeptide processing in brain and pituitary, we used radioimmunoassays (RIA) as well as quantitative peptidomic methods and examined changes in the levels of multiple neuropeptide products in PC1 knockout (KO) mice. The processing of proenkephalin was impaired in PC1 KO mouse brains with a decrease in the level of Met-Enkephalin immunoreactivity (ir-Met-Enk) and an accumulation of higher molecular weight processing intermediates containing ir-Met-Enk. Processing of the neuropeptide precursor VGF was also affected in PC1 KO mouse brains with a decrease in the level of an endogenous 3 kDa C-terminal peptide. In contrast, the processing of proSAAS into PEN was not altered in PC1 KO mouse brains. Quantitative mass spectrometry was used to analyze a number of peptides derived from proopiomelanocortin (POMC), provasopressin, prooxytocin, chromogranin A, chromogranin B, and secretogranin II. Among them, the levels of oxytocin and peptides derived from chromogranin A and B dramatically decreased in the PC1 KO mouse pituitaries, while the levels of peptides derived from proopiomelanocortin and provasopressin did not show substantial changes. In conclusion, these results support the notion that PC1 plays a key role in the processing of multiple neuroendocrine peptide precursors and also reveal the presence of a redundant system in the processing of a number of physiologically important bioactive peptides.