Three ferritin subunit analogs in Chinese giant salamander (Andrias davidianus) and their response to microbial stimulation.

Ferritin, an evolutionarily conserved iron-binding protein, plays important roles in iron storage and detoxification and in host immune response to invading stimulus as well. In the present study, we identified three ferritin subunit analog cDNAs from Chinese giant salamander (Andrias davidianus). All the three ferritin subunit cDNAs had a putative iron responsive element in the 5'-untranslated region. Two deduced ferritin subunits (designated as cgsFerH and cgsFerM) had the highest identity of 90% to H type subunit of vertebrate ferritins, while another deduced ferritin subunit (designated as cgsFerL) had the highest identity of 84% to L type subunit of vertebrate ferritins. The Chinese giant salamander ferritin (cgsFer) was widely expressed in various tissues, with highest expression for cgsFerH and cgsFerL in liver and highest expression for cgsFerM in spleen. Infection of Chinese giant salamander with A. davidianus ranavirus showed significant induction of cgsFer expression. Both lipopolysaccharide and iron challenge drastically augmented cgsFer expression in the splenocytes and hepatocytes from Chinese giant salamander. In addition, recombinant cgsFers bound to ferrous iron in a dose-dependent manner, with significant ferroxidase activity. Furthermore, the recombinant cgsFer inhibited the growth of the pathogen Vibrio anguillarum. These results indicated that cgsFer was potential candidate of immune molecules involved in acute phase response to invading microbial pathogens in Chinese giant salamander possibly through its regulatory roles in iron homeostasis.

Biological functions of hCG and hCG-related molecules.

BACKGROUND: hCG is a term referring to 4 independent molecules, each produced by separate cells and each having completely separate functions. These are hCG produced by villous syncytiotrophoblast cells, hyperglycosylated hCG produced by cytotrophoblast cells, free beta-subunit made by multiple primary non-trophoblastic malignancies, and pituitary hCG made by the gonadotrope cells of the anterior pituitary. RESULTS AND DISCUSSION: hCG has numerous functions. hCG promotes progesterone production by corpus luteal cells; promotes angiogenesis in uterine vasculature; promoted the fusion of cytotrophoblast cell and differentiation to make syncytiotrophoblast cells; causes the blockage of any immune or macrophage action by mother on foreign invading placental cells; causes uterine growth parallel to fetal growth; suppresses any myometrial contractions during the course of pregnancy; causes growth and differentiation of the umbilical cord; signals the endometrium about forthcoming implantation; acts on receptor in mother's brain causing hyperemesis gravidarum, and seemingly promotes growth of fetal organs during pregnancy. Hyperglycosylated hCG functions to promote growth of cytotrophoblast cells and invasion by these cells, as occurs in implantation of pregnancy, and growth and invasion by choriocarcinoma cells. hCG free beta-subunit is produced by numerous non-trophoblastic malignancies of different primaries. The detection of free beta-subunit in these malignancies is generally considered a sign of poor prognosis. The free beta-subunit blocks apoptosis in cancer cells and promotes the growth and malignancy of the cancer. Pituitary hCG is a sulfated variant of hCG produced at low levels during the menstrual cycle. Pituitary hCG seems to mimic luteinizing hormone actions during the menstrual cycle.

Role of the intra-A-chain disulfide bond of insulin-like peptide 3 in binding and activation of its receptor, RXFP2.

INSL3 is a member of the insulin-IGF-relaxin superfamily and plays a key role in male fetal development and in adult germ cell maturation. It is the cognate ligand for RXFP2, a leucine-rich repeat containing G-protein coupled receptor. To date, and in contrast to our current knowledge of the key structural features that are required for the binding of INSL3 to RXFP2, comparatively little is known about the key residues that are required to elicit receptor activation and downstream cell signaling. Early evidence suggests that these are contained principally within the A-chain. To further explore this hypothesis, we have undertaken an examination of the functional role of the intra-A-chain disulfide bond. Using solid-phase peptide synthesis together with regioselective disulfide bond formation, two analogs of human INSL3 were prepared in which the intra-chain disulfide bond was replaced, one in which the corresponding Cys residues were substituted with the isosteric Ser and the other in which the Cys were removed altogether. Both of these peptides retained nearly full RXFP2 receptor binding but were devoid of cAMP activity (receptor activation), indicating that the intra-A-chain disulfide bond makes a significant contribution to the ability of INSL3 to act as an RXFP2 agonist. Replacement of the disulfide bond with a metabolically stable dicarba bond yielded two isomers of INSL3 that each exhibited bioactivity similar to native INSL3. This study highlights the critical structural role played by the intra-A-chain disulfide bond of INSL3 in mediating agonist actions through the RXFP2 receptor.

Insulin allosteric behavior: detection, identification, and quantification of allosteric states via 19F NMR.

The insulin hexamer is an allosteric protein widely used in formulations for the treatment of diabetes. The hexamer exhibits positive and negative cooperativity and apparent half-site binding activity, reflecting the interconversion of three allosteric states, designated as T6, T3R3, and R6. The hexamer contains two symmetry-related Zn2+ located 16 A apart on the 3-fold symmetry axis. In the transition of T3 units to R3 units, Zn2+ switches from an octahedral Zn2+ N3O3 complex (N is HisB10, O is H2O) to a distorted tetrahedral Zn2+ N3L complex (L is a monovalent anion). Hence, monovalent anions are allosteric ligands that stabilize R3 units of T3R3 and R6. Herein, we exploit the high sensitivity of 19F NMR chemical shifts and fluorinated carboxylates to reveal subtle differences in the anion-binding sites of T3R3 and R6. We show that the chemical shifts of 4- and 3-trifluoromethylbenzoate and 4- and 2-trifluoromethylcinnamate give bound resonances that distinguish between T3R3 and R6. 3-Trifluoromethylbenzoate and 2-trifluoromethylcinnamate also were shown to bind to the R3 units of T3R3 and R6 in two alternative, slowly interconverting modes with different microenvironments for the CF3 groups. Line width analysis shows that ligand off rates are slower by 1/10(3) than the diffusion limit, indicating a rate-limiting protein conformational transition. These studies confirm that the Seydoux, Malhotra, and Bernhard allosteric model (Bloom, C. R., Choi, W. E., Brzovic, P. S., Ha, J. J., Huang, S. T., Kaarsholm, N. C., and Dunn, M. F. (1995). J. Mol. Biol. 245, 324-330), provides a robust description of the insulin hexamer.

Neuronal activity regulates GABAA receptor subunit expression in organotypic hippocampal slice cultures.

The postnatal expression of GABA(A) receptor subunit mRNAs in the rat brain, including the hippocampus, exhibits a unique temporal and regional developmental profile in vivo, which may be altered by external stimuli. Using the in situ hybridization technique we have now studied the in vitro expression of alpha1,alpha2, alpha 4, alpha 5, beta 1, beta 3, gamma 2, and gamma 3 subunit mRNAs of GABA(A) receptors in organotypic hippocampal slices cultured for 7 days. To find out whether neuronal activity regulates the subunit expression, a subset of cultures was chronically treated either with a GABA(A) receptor antagonist picrotoxin, or by a non-N-methyl-D-aspartate (non-NMDA)-receptor antagonist 6,7-dinitroquinoxaline-2,3-dione (DNQX). In untreated control cultures, the expression pattern of the subunits varied regionally, the most abundantly expressed subunits being alpha 2 and alpha 5 in all subregions. All studied subunits were expressed in CA3a/b and CA1, whereas in CA3c and in granule cells of the dentate gyrus (DG) no signal of alpha 4 and gamma 3 was detected. The drug treatment differently affected the regional subunit expression. In picrotoxin-treated cultures, the expression of alpha1, alpha 5 and gamma 2 mRNAs was significantly increased in pyramidal cell layers, and in DNQX-treated cultures the expression of alpha2 mRNA in CA3c and DG, and that of beta1 in DG. Changes in the expression of GABA(A) receptor subunit mRNAs in treated cultures suggest that neuronal activity can regulate their regional expression in vitro. Since the expression profile in untreated control cultures closely resembled that observed earlier in vivo, organotypic hippocampal slice cultures could serve as a good model system to study the regulatory mechanisms of receptor expression under well-controlled experimental conditions in the developing hippocampus.