In vitro studies on the subcellular location of glucosidase I and glucosidase II in dog pancreas

When programmed with yeast prepro--factor mRNA, the heterologous reticulocyte/dog pancreas translation system synthesizes two pheromone related polypeptides, a cytosolically located primary translation product (pp--F_cyt, 21 kDa) and a membrane-specific and multiply glycosylated e-factor precursor (pp--F₃, 27.5 kDa). Glycosylation of the membrane specific pp--F₃ species is competitively inhibited by synthetic peptides containing the consensus sequence Asn-Xaa-Thr as indicated by a shift of its molecular mass from 27.5 kDa to about 19.5 kDa (pp--F₀) , whereas the primary translation product pp--Fcyt is not affected. Likewise, only the glycosylated pp--F₃ structure is digested by Endo H yielding a polypeptide with a molecular mass between PP--F₀ and pp--Fcyt. These observations strongly suggest that the primary translation product is proteolytically processed during/on its translocation into the lumen of the microsomal vesicles. We believe that this proteolytic processing is due to the cleavage of a signal sequence from the pp--Fcyt species, although this interpretation contradicts previous data from other groups. The distinct effect exerted by various glycosidase inhibitors (e.g. 1-deoxynojirimycin, N-methyl-dNM, 1-deoxymannojirimycin) on the electrophoretic mobility of the pp--F₃ polypeptide indicates that its oligosaccharide chains are processed to presumbly Man₉-GlcNAc₂ structures under thein vitro conditions of translation. This oligosaccharide processing is most likely to involve the action of glucosidase I and glucosidase II as follows from the specificity of the glycosidase inhibitors applied and the differences of the molecular mass observed in their presence. In addition, several arguments suggest that both trimming enzymes are located in the lumen of the microsomal vesicles derived from endoplasmic reticulum membranes.Abbreviations dNM 1-deoxynojirimycin - N-Me-dNM N-methyl-dNM - dMM 1-deoxymannojirimycin - CCCP carbonylcyanide m-chlorophenyl hydrazone     

Crystal-associated matrix components in rat incisor enamel

Summary Sections of glutaraldehyde-OsO₄-fixed, plastic-embedded rat incisor enamel were left untreated, stained, decalcifed (1% formic acid in 10% sodium citrate), or decalcified-stained. The presence of apatite crystals was monitored with electron diffraction. After brief decalcification and staining, apatite crystals and matrix components were visualized in the same field. The ghost was continuous with crystal fragments, and the coat appeared as a dense line next to crystals and ghosts. Position of ghosts and crystals at the ameloblast-enamel junction (AEJ) of the secretion zone suggested that there may be a lag of no more than 1/5 min between the elaboration of ghost and crystal. A major change in enamel morphology occurs between the AEJ and the deep enamel of the secretion zone. The ghost becomes thinner, the coat more pronounced, and the crystal enlarges. There is only little change from the deep secretion to the maturation zone enamel.     

DNA binding properties of a 110 kDa nucleolar protein.

A single strand specific DNA binding protein was purified to homogeneity from calf thymus nucleoprotein. The monomeric protein is elongated in shape and has a molecular mass of 110 kDa. Since immunocytochemistry revealed that the protein is predominantly located in the nucleolus we refer to it as the 110 kDa nucleolar protein. The protein binds not only to single stranded DNA but also to single stranded RNA, including homopolymeric synthetic RNA. We have used the single stranded DNA binding properties of the 110 kDa protein in model studies to investigate its effects on the configuration of nucleic acid. Our results are: only 50-55 protein molecules are sufficient to saturate all binding sites on the 6408 nucleotides of phage fd DNA; protein binding cause a compaction of single stranded DNA; large nucleoprotein aggregates are formed in the presence of divalent cations; this is due to protein-protein interactions which occur at moderately high concentrations of magnesium-, calcium or manganese ions; the protein induces the reassociation of complementary nucleic acid sequences. We speculate that the 110 kDa protein performs similar reactions in vivo and may have a function related to the processing and packaging of preribosomal RNA.     

Non-linearities in cortical simple cells and the possible detection of zero crossings

A theory of early visual information processing proposed by Marr and co-workers suggests that simple cortical cells may be involved in the detection of zero crossing in the retinal output. We have tested this theory by using pairs of adjacent edges (staircases stimuli) and recording from edge-specific simple cells in cat striate cortex. The zero crossing hypothesis gives rise for such stimuli to non-obvious predictions that were generally confirmed by the experiment.     

CO2 sensitive receptors on labial palps ofRhodogastria moths (Lepidoptera: Arctiidae): physiology,fine structure and central projection

Summary The tips of the labial palps ofRhodogastria possess a pit housing uniform sensilla (Fig. 1), histologically characterized by wall-pores and receptor cells with lamellated outer dendrites (Fig. 2). The receptor cell axons project to glomeruli in the deutocerebrum (cf. Fig. 3) which are not innervated by antennal receptors. From their histology as well as from their central projection these sense organs are identical with palpal pit organs of other Lepidoptera (Lee et al. 1985; Kent et al. 1986; Lee and Altner 1986).Physiologically, the palp-pit receptors respond uniformly; they are most excitable by stimulation with carbon dioxide (Fig. 6) while they exhibit relatively moderate responses to various odorants (Fig. 4). The responses to CO₂ (Fig. 7) show a steep dose-response characteristic. In ambient atmosphere (i.e., ca. 0.03% CO₂) the cells are in an excited condition already; the seeming spontaneous activity exhibited in air is decreased if the preparation is kept under N₂ or O₂ or CO₂-free air (Figs. 7, 10). There is hardly any adaptation of the responses to continuous or repeated stimulation (Fig. 8). Perhaps CO₂ sensitivity is correlated with sensilla characterized by both wall-pores and lamellated dendrites. Pilot tests indicate that CO₂ perception might be widespread in the Lepidoptera (cf. Fig. 12), but the biological significance remains obscure.     

UDP-glucose:digitoxin 16′-O-glucosyltransferase from suspension-cultured Digitalis lanata cells

Suspension cultures from several cell lines of Digitalis lanata, as well as cultures from 6 other plant species were checked for their ability to form purpurea-glycoside A from digitoxin. An in-vitro assay for the UDP-glucose:digitoxin 16-O-glucosyltransferase (DGT, EC 2.4.1.-) has been established based on an HPLC method. The enzyme is located in the soluble fraction. Its pH optimum is at 7.4. No enzyme activity was found in either purified vacuole preparations or lysed vacuoles. Ascorbate (10 mM) increased the transferase activity about 4-fold. Of the sugar nucleotides tested, only UDP-glucose served as a glucosyl donor. Digitoxin, digoxin, -acetyldigitoxin, and -acetyldigoxin are substrates for the glucosyltransferase. The role of the DGT during the biotransformation of cardenolides in Digitalis lanata cell suspension cultures is discussed.Abbreviation DGT UDP-glucose:digitoxin 16-C-glucosyltransferase     

Inhibition of sugar uptake by ascorbic acid in Escherichia coli

The uptake of glucose by the glucose phosphotransferase system in Escherichia coli was inhibited greater than 90% by ascorbate. The uptake of the nonmetabolizable analog of glucose, methyl-alpha-glucoside, was also inhibited to the same extent, confirming that it was the transport process that was sensitive to ascorbate. Similarly, it was the transport function of mannose phosphotransferase for which mannose and nonmetabolizable 2-deoxyglucose were substrates that was partially inhibited by ascorbate. Other phosphotransferase systems, including those for the uptake of sorbitol, fructose and N-acetylglucosamine, but not mannitol, were also inhibited to varying degrees by ascorbate. The inhibitory effect on the phosphotransferase systems was reversible, required the active oxidation of ascorbate, was sensitive to the presence of free-radical scavengers, and was insensitive to uncouplers. Because ascorbate was not taken up by E. coli, it was concluded that the active inhibitory species was the ascorbate free radical and that it was interacting reversibly with a membrane component, possibly the different enzyme IIB components of the phosphotransferase systems. Ascorbate also inhibited other transport systems causing a slight reduction in the passive diffusion of glycerol, a 50% inhibition of the shock-sensitive uptake of maltose, and a complete inhibition of the proton-symport uptake of lactose. Radical scavengers had little or no effect on the inhibition of these systems.     

Surface-charge related actions of polylysine on thylakoid membranes

Polycation binding to the negatively charged surface of chloroplast thylakoid membranes is known to cause an inhibition of photosystem I activity. It also interferes with the cation-dependent rearrangement of chlorophyll proteins in the thylakoid membrane. It was shown that added anions prevented or reversed the inhibition of photosystem I by polylysine without decreasing its binding to the membranes. Anions also caused a change in the interaction of the chlorophyll proteins in polylysine-treated thylakoids as indicated by an increase in the relative fluorescence intensity from photosystem II. In both cases, the relative effectiveness of the anions tested depended on their valence; for example, the tetravalent species Fe(CN)₆^4t- was effective at a concentration at least 2 orders of magnitude lower than the divalent species SO₄^2?. These results suggest that anions act by screening the positive charge of the polylysine-coated membrane surface. Measurements of the response of the anionic fluorescent probe 1-anilinonapthalene-8-sulfonate to an addition of anions to polylysine-treated thylakoids supported this contention. It was concluded that the action of polylysine on photosystem I and on the chlorophyll proteins is mediated by changes of the electrical properties of the thylakoid membrane and may not involve a direct binding of the polycation to the affected membrane proteins.     

Synthesis and characterization of lipid-linked mannosyl oligosaccharides in Volvox carteri f. nagariensis

Particulate membrane fractions from Volvox carteri catalyze the transfer of mannose from GDP-mannose to dolichyl diphosphate-[¹⁴C]chitobiose to form lipid-linked oligosaccharides up to a dolichyl diphospnate-chitobiose-(mannose)₅ structure. Mannosylation of the chitobiosyl lipid requires divalent cations and detergents as solubilizing agents. Depending on the nature of the detergent, the oligosaccharide pattern differs markedly: With deoxycholate or the zwitterionic detergent 314 a lipid-linked trisaccharide accumulates. The nonionic Triton X-100, however, gives rise to a spectrum of compounds up to a heptasaccharide. Enzyme digestion of the tri- and pentasaccharide structure, obtained after mild acid hydrolysis of the corresponding [¹⁴C]glycolipids, revealed that the first mannose is bound via a β-glycosidic linkage to the chitobiosyl core, whereas the outer mannose residues are linked as α-mannosides. Our studies indicate that, in agreement with recent findings in other organisms, the innermost α-mannosidic residues are donated directly from GDP-mannose. The structure of oligosaccharides synthesized by Volvox membranes is thus consistent with results from other eucaryotic species, suggesting a common pathway of N-glycosylation of glycoproteins.