Inhibition of growth hormone synthesis by somatostatin in cultured pituitary of rainbow trout

Summary When the pituitary of rainbow trout (Oncorhynchus mykiss) was incubated in a serum-free medium, a high level of growth hormone release as well as an activation of growth hormone synthesis were observed, suggesting the existence of hypothalamic inhibitory factor(s) on growth hormone synthesis. Although an inhibitory effect of somatostatin on growth hormone release is well established in both mammals and teleosts, an effect on growth hormone synthesis has not been demonstrated. In this study, we examined the effect of somatostatin on growth hormone synthesis in organ-cultured trout pituitary using immunoprecipitation and Northern blot analysis. Somatostatin inhibited growth hormone release from the cultured pituitary within 10 min after addition without affecting prolactin release. Incubation of the pituitary with somatostatin also caused a significant reduction in newly-synthesized growth hormone in a dose-related manner, as assessed by incorporation of [³H]leucine into immunoprecipitable growth hormone. There were no changes in the level or molecular length of growth hormone mRNA after somatostatin treatment, as assessed by Northern slot blot and Northern gel blot analyses. Human growth hormone-releasing factor stimulated growth hormone release, although the spontaneous synthesis of growth hormone was not augmented. However, somatostatin-inhibited growth hormone synthesis was restored by growth hormone-releasing factor to the control level. The spontaneous increase in growth hormone synthesis observed in the organ-cultured trout pituitary may be caused, at least in part, by the removal of the inhibitory effect of hypothalamic somatostatin.Abbreviations GH growth hormone - GHRF GH-releasing factor - PRL prolactin - SDS sodium dodecyl sulphate - SRIF somatostatin (somatropin release-inhibiting factor)     

beta-Galactosidase deficient-type mucolipidosis: a complementation study of neuraminidase in somatic cell hybrids

By cell fusion with polyethylene glycol (PEG) a remarkable increase of neuraminidase activity was observed in the fused cells between ML-II and other two neuraminidase deficient disorders, ML-Gal (mucolipidosis, galactosidase deficient type) and ML-I (mucolipidosis I). No complementation was found in the combination of ML-I and ML-Gal. This result suggests that ML-I and ML-Gal may be allelic mutations and belong to the same genetic disorder as a primary neuraminidase deficiency.     

Ultrastructural study on cocoon formation in the freshwater oligochaete,Tubifex hattai

The clitellar epithelium of the freshwater oligochaete, Tubifex hattai, is composed of four types of gland cells (Type I, II, III, and IV), in addition to the cells generally found in the epidermis of this worm. The possible function of these gland cells in cocoon formation was studied with the electron microscope. Type I cells discharge their secretory granules by means of compound exocytosis and provide the materials for the future cocoon membrane. Immediately after completion of the discharge from Type I cells, Type II and III cells simultaneously discharge their secretory granules by means of compound exocytosis. The secretions from Type II cells constitute a colloid in the cocoon lumen and probably cause structural modifications in the future cocoon membrane. The secretory products from Type III cells form the cocoon plug. Although the process of discharge of secretory granules from Type IV cells was not observed, the contribution of these cells to the cocoon formation, producing hoops on the outer surface of the future cocoon membrane and fixing its anterior ends on the clitellum, is inferred from a morphological comparison of the hoop and the structure of the secretory granules.     

Electrical activity of an intestinal epithelial cell line: Hyperpolarizing responses to intestinal secretagogues

Summary Cultured epithelial cells (Intestine 407) derived from fetal human small intestine exhibited spontaneous oscillations of membrane potential between the resting level of about –20 mV and the activated level of about –75mV. The cells were hyperpolarized to the latter level in response to mechanical or electrical stimuli. The hyperpolarizing responses were also elicited by the application of intestinal secretagogues: acetylcholine, histamine, serotonin and vasoactive intestinal polypeptide (VIP). The spontaneous oscillation of membrane potential became prominent and long-lasting in the presence of acetylcholine, histamine, serotonin or VIP. These secretagogue-induced responses were mediated by individual independent receptors on the cell membrane. Muscarinic receptors were responsible for the acetylcholine response, and H₁-receptors for the histamine response. The cells also responded with a slow hyperpolarization to calcium ionophore A23187, which is known to induce intestinal secretion. The spontaneously occurring hyperpolarizing responses and those induced by stimuli were both due to an increase in the K⁺ conductance of the cell membrane. Since acetylcholine, histamine, serotonin and A23187 are known to promote mobilization of cellular Ca²⁺ ions in intestinal secretory cells, it is hypothesized that these electrical activities of the cell are closely related to the receptor stimulation which leads to the Ca²⁺-mediated intestinal secretion.     

Recombinant prosegment peptide acts as a folding catalyst and inhibitor of native pepsin

Porcine pepsin A, a gastric aspartic peptidase, is initially produced as the zymogen pepsinogen that contains an N-terminal, 44 residue prosegment (PS) domain. In the absence of the PS, native pepsin (Np) is irreversibly denatured and when placed under refolding conditions, folds to a thermodynamically stable denatured state. This denatured, refolded pepsin (Rp) state can be converted to Np by the exogenous addition of the PS, which catalyzes the folding of Rp to Np. In order to thoroughly study the mechanism by which the PS catalyzes pepsin folding, a soluble protein expression system was developed to produce recombinant PS peptide in a highly pure form. Using this system, the wild-type and three-mutant PS forms, in which single residue substitutions were made (V4A, R8A and K36A), were expressed and purified. These PS peptides were characterized for their ability to inhibit Np enzymatic activity and to catalyze the folding of Rp to Np. The V4A, R8A and K36A mutant PS peptides were found to have nanomolar inhibition constants, K_i, of 82.4, 58.3 and 95.6 nM, respectively, approximately a two-fold increase from that of the wild-type PS (36.2 nM). All three-mutant PS peptides were found to catalyze Np folding with a rate constant of 0.06 min^? 1, five-fold lower than that of the wild-type. The observation that the mutant PS peptides retained their inhibition and folding-catalyst functionality suggests a high level of resilience to mutations of the pepsin PS.