The effects of substance P and carbachol on inositol tris- and tetrakisphosphate formation and cytosolic free calcium in rat parotid acinar cells. A correlation between inositol phosphate levels and calcium entry

Both substance P and carbachol produced increases in inositol tris- and tetrakisphosphate and increased cytosolic free [Ca2+] in dispersed parotid acinar cells loaded with fura-2. The increase in [Ca2+]i in response to each agonist was due to a combination of mobilization of internal Ca2+ and entry of extracellular Ca2+. Kinetic studies of the initial response to substance P, and measurement of peak [Ca2+]i, demonstrated that the initial rapid rise in [Ca2+]i was due to both internal release and entry of Ca2+. Substance P could evoke a greater initial increase in [Ca2+]i and inositol trisphosphate than could carbachol. However, after 1 min in the presence of external Ca2+, the maintained [Ca2+]i level in response to substance P was considerably smaller than that seen with carbachol, an effect apparently due to homologous desensitization of the substance P receptor. The two agonists each produced a similar 4-5-fold increase in inositol tetrakisphosphate levels within 30 s; this level was maintained in the presence of carbachol, but decreased with substance P. Similarly, the level of inositol (1,4,5)-trisphosphate decreased after prolonged incubation with substance P. Thus, the maintained level of [Ca2+]i, and by deduction Ca2+ entry, correlated with the levels of inositol (1,4,5)-trisphosphate and inositol tetrakisphosphate; a result consistent with a possible role for these inositol phosphates in the control of receptor-mediated Ca2+ channels.     

Biological characterization of purified native 20-kDa human growth hormone

Because of the propensity of the 20-kDa variant of human growth hormone (GH) to aggregate with itself and with 22-kDa human GH, it has been difficult to prepare monomeric 20-kDa GH in highly purified form. This has been a major complicating factor in determining whether 20-kDa GH has a biological activity profile distinct from that of 22-kDa GH. In the present study, native 20-kDa GH was isolated from a human GH dimer concentrate and purified by a procedure that included column electrophoresis in agarose suspension as a final separation step. This procedure yielded highly purified monomeric 20-kDa GH, which was contaminated to an extent of less than 1% with 22-kDa GH, and which exhibited only a small degree of dimerization upon storage. The native 20-kDa GH was quite active in stimulating growth in hypophysectomized rats, when growth was assessed by body weight gain, longitudinal bone growth, the stimulation of sulfation of cartilage, and the elevation of serum IGF-1 level. However, in all of these growth assays, the 20-kDa GH was somewhat less active than the native 22-kDa GH to which it was compared; e.g., in the body weight gain and longitudinal bone growth assays, it had an estimated potency of 0.6 relative to the 22-kDa GH. The 20-kDa GH exhibited substantial diabetogenic activity when tested for the ability to raise fasting blood glucose concentration and to impair glucose tolerance in ob/ob mice. Also, the native 20-kDa GH had significant in vitro insulin-like activity, although its potency was approximately 20% that of the native 22-kDa GH to which it was compared. Thus, the biological activity profile of native 20-kDa GH differs from that of 22-kDa GH primarily in that insulin-like activity is markedly attenuated.