Munc-18 associates with syntaxin and serves as a negative regulator of exocytosis in the pancreatic beta -cell

The Munc-18 protein (mammalian homologue of the unc-18 gene; also called nSec1 or rbSec1) has been identified as an essential component of the synaptic vesicle fusion protein complex. The cellular and subcellular localization and functional role of Munc-18 protein in pancreatic beta-cells was investigated. Subcellular fractionation of insulin-secreting HIT-T15 cells revealed a 67-kDa protein in both cytosol and membrane fractions. Immunohistochemistry showed punctate Munc-18 immunoreactivity in the cytoplasm of rat pancreatic islet cells. Direct double-labeling immunofluorescence histochemistry combined with confocal laser microscopy revealed the presence of Munc-18 immunoreactivity in insulin-, glucagon-, pancreatic polypeptide-, and somatostatin-containing cells. Syntaxin 1 immunoreactivity was detected in extracts of HIT-T15 cells, which were immunoprecipitated using Munc-18 antiserum, suggesting an intimate association of Munc-18 with syntaxin 1. Administration of Munc-18 peptide or Munc-18 antiserum to streptolysin O-permeabilized HIT-T15 cells resulted in significantly increased insulin release, but did not have any significant effect on voltage-gated Ca(2+) channel activity. The findings taken together show that the Munc-18 protein is present in insulin-secreting beta-cells and implicate Munc-18 as a negative regulator of the insulin secretory machinery via a mechanism that does not involve syntaxin-associated Ca(2+) channels.     

Antidepressant-induced switch of beta 1-adrenoceptor trafficking as a mechanism for drug action

Reduction in surface beta(1)-adrenoceptor (beta1AR) density is thought to play a critical role in mediating the therapeutic long term effects of antidepressants. Since antidepressants are neither agonists nor antagonists for G protein-coupled receptors, receptor density must be regulated through processes independent of direct receptor activation. Endocytosis and recycling of the beta1AR fused to green fluorescent protein at its carboxyl-terminus (beta1AR-GFP) were analyzed by confocal fluorescence microscopy of live cells and complementary ligand binding studies. In stably transfected C6 glioblastoma cells, beta1AR-GFP displayed identical ligand-binding isotherms and adenylyl cyclase activation as native beta1AR. Upon exposure to isoproterenol, a fraction of beta1AR-GFP (10-15%) internalized rapidly and colocalized with endocytosed transferrin receptors in an early endosomal compartment in the perinuclear region. Chronic treatment with the tricyclic antidepressant desipramine (DMI) did not affect internalization characteristics of beta1AR-GFP when challenged with isoproterenol. However, internalized receptors were not able to recycle back to the cell surface in DMI-treated cells, whereas recycling of transferrin receptors was not affected. Endocytosed receptors were absent from structures that stained with fluorescently labeled dextran, and inhibition of lysosomal protease activity did not restore receptor recycling, indicating that beta1AR-GFP did not immediately enter the lysosomal compartment. The data suggest a new mode of drug action causing a "switch" of receptor fate from a fast recycling pathway to a slowly exchanging perinuclear compartment. Antidepressant-induced reduction of receptor surface expression may thus be caused by modulation of receptor trafficking routes.     

Structural features for the mechanism of antitumor action of a dimeric human pancreatic ribonuclease variant

A specialized class of RNases shows a high cytotoxicity toward tumor cell lines, which is critically dependent on their ability to reach the cytosol and to evade the action of the ribonuclease inhibitor (RI). The cytotoxicity and antitumor activity of bovine seminal ribonuclease (BSRNase), which exists in the native state as an equilibrium mixture of a swapped and an unswapped dimer, are peculiar properties of the swapped form. A dimeric variant (HHP2‐RNase) of human pancreatic RNase, in which the enzyme has been engineered to reproduce the sequence of BSRNase helix‐II (Gln28→Leu, Arg31→Cys, Arg32→Cys, and Asn34→Lys) and to eliminate a negative charge on the surface (Glu111→Gly), is also extremely cytotoxic. Surprisingly, this activity is associated also to the unswapped form of the protein. The crystal structure reveals that on this molecule the hinge regions, which are highly disordered in the unswapped form of BSRNase, adopt a very well‐defined conformation in both subunits. The results suggest that the two hinge peptides and the two Leu28 side chains may provide an anchorage to a transient noncovalent dimer, which maintains Cys31 and Cys32 of the two subunits in proximity, thus stabilizing a quaternary structure, similar to that found for the noncovalent swapped dimer of BSRNase, that allows the molecule to escape RI and/or to enhance the formation of the interchain disulfides.     

Shortened {beta}-cell lifespan leads to {beta}-cell deficit in a rodent model of type 2 diabetes

Since the fundamental defect in both type 1 and type 2 diabetes is β-cell failure, there is increasing interest in the capacity, if any, for β-cell regeneration. Insights into typical β-cell age and lifespan during normal development and how these are influenced in diabetes is desirable to realistically establish the prospects for β-cell regeneration as means to reverse the deficit in β-cell mass in diabetes. We assessed the mean β-cell age and lifespan by the classical McKendrick-von Foester equation that describes the age-based heterogeneity of β-cells in terms of the time-varying β-cell formation and loss estimated by a β-cell turnover model. This modeling approach was applied to evaluate β-cell lifespan in a rodent model of type 2 diabetes in comparison with nondiabetic controls. When rats were 10 mo old, mean β-cell lifespan was 1 mo vs. 6 mo in rats with type 2 diabetes vs. controls. A shortened β-cell lifespan in a rat model of type 2 diabetes results in a decrease in mean β-cell age and thus contributes to decreased β-cell mass.     

The pancreatic -cell recognition of insulin secretagogues. II. Site of action of tolbutamide

The distribution of ³⁵S-labelled tolbutamide was studied in microdissected pancreatic islets of obese-hyperglycemic mice. These islets contain more than 90 % β-cells. A comparison with the uptake of ³H-labelled sucrose, mannitol, or 3-O-methyl-D-glucose revealed that tolbutamide did not enter the β-cells but was restricted to the extracellular space. It is suggested that the β-cell plasma membrane contains a tolbutamide receptor, which is responsible for the recognition of sulfonylureas as insulin secretagogues.     

A conformational basis for the selective action of ara-adenine.

The glycosidic “high anti” conformation is postulated to be the conformation required by the enzymes adenosine kinase and inosine phosphorylase. Purine analogs that are stable in this conformation are either effective substrates or inhibitors of these enzymes. Ara-adenine is shown to be highly unstable in the high anti conformation. The inactivity of ara-adenine as a substrate for both adenosine kinase and inosine phosphorylase is attributed to its inability to assume the high anti conformation specified by these enzymes. That adenosine itself has a local minima in the high anti conformation, as does inosine and guanosine, is required by its ability to inhibit the synthesis of uridylic acid.The minimal cytotoxic properties of ara-adenine is a consequence of its failure, in normal cells, to be converted to the toxic nucleotide form. The ability of ara-adenine to selectively inhibit DNA viruses means that in DNA virus infected cells the conversion of ara-adenine to ara-AMP is facilitated through a mechanism that does not require a substrate high anti conformation.It is apparent that selective antiviral and anticancer nucleoside analogs may be constructed if their conversion to the toxic nucleotide form is prohibited in normal tissues but allowed in cancer cells or virus infected cells. The basis for the selective effects of ara-adenine is that normal cells require a substrate conformation in which ara-adenine is unstable but that certain neoplastic and viral mechanisms for the conversion of ara-adenine to ara-AMP exist which are able to utilize ara-adenine in its stable syn or anti conformations.     

A proposal for the mechanism of carbonic anhydrase action

A new catalytic mechanism is proposed for the hydration of CO₂ by the zinc metalloenzyme carbonic anhydrase. This mechanism identifies the group controlling catalytic activity as an active site histidine, in which the protonated imidazole ring coordinates to zinc, losing a proton. Geometric constraints on the histidine unit make the metal-ligand bond a strained and, therefore, labile one. In the hydration reaction, the metal-bound neutral histidine moiety serves as a proton acceptor for the transient ionization of metal-bound water. Zinc-bound hydroxide attacks the carbon of the substrate to generate metal-bound bicarbonate, and the system regenerates itself by losing the elements of carbonic acid.     

A possible mechanism for the action of some myxoviruses

Summary The redox properties of some myxoviruses [Fowl plaque virus strain Rostock (FPV), New Castle Disease virus strain Italy (NDV), B/Hong Kong, A/Port Chalmers, A/Victoria, A/Scotland, and A/Fort Dix (FD)] have been investigated by means of electron spin resonance (ESR) and electron microscopic studies as well as by the determination of the hemagglutination (HA) titer (antigen efficiency). The results have shown that viruses decrease the spin concentration of Cu²⁺ by acting as a reducing species (electron donor) which will result in the inactivation (oxidation) of the virus. Addition of an oxidizing substance, such as H₂O₂, to a virus suspension also leads to an oxidation of the viruses and, thus, to their inability to reduce Cu²⁺. This result is confirmed by the decrease of the HA titer of viruses with increasing Cu²⁺ concentrations. H₂O₂ could not be applied for the HA titer test since it interacts with the erythrocytes of the chicken blood used for this determination. Therefore, another oxidizing substance (oxidized glutathione, GSS) was selected which exhibited a slightly less pronounced effect than Cu²⁺. Since reduced glutathione (GSH) exerts a similar but less pronounced effect than GSS, it might be concluded that viruses have a redox system of their own and act as reducing or oxidizing substance depending on the biological receptor system. Electron microscopic studies confirm this hypothesis. As can be seen by the electron micrographs, increasing concentrations of either Cu²⁺, GSS, H₂O₂, KMnO₄, or GSH will, finally, result in a complete destruction of the virus. Because of structural similarities it might be assumed that other types of viruses behave very similarly.     

A proposed mechanism for the catalatic action of catalase

A detailed mechanism for catalatic action has been proposed which includes the formation of Chance's catalase compound I in the first step and hydride ion transfer in the second step. The first (oxidative) step involves direct reaction of hematin iron with an ionized H2O2 molecule, followed by an oxidation of the iron to Fe IV. The second step is assumed to depend upon the reductive action of a second H2O2 molecule on Chance's compound I through a catalyzed hybride ion transfer, resulting in the regeneration of uncomplexed catalase. Differences between the catalatic and peroxidative actions of catalase are discussed briefly in respect to the proposed mechanism for catalatic action. The rationale of the proposed mechanism is based to a considerable extent upon the type of ligand binding by the hematin iron of catalase, and this type of ligand bonding is contrasted with ligand binding in methemoglobin, which does not show catalatic activity. Finally, the dispositions of electrons in the outer electronic orbitals of the hematin iron of catalase and methemoglobin are discussed, as a means of justifying formulae presented for catalase and methemoglobin and their derivatives. One of the features of the proposed catalatic mechanism is the assumption, based on electron spin number, that the sixth coordination position around the hematin iron of uncomplexed catalase is unoccupied.