Tissue-specific posttranslational processing of pre-prosomatostatin encoded by a metallothionein-somatostatin fusion gene in transgenic mice

The somatostatins are neuropeptides of 14 and 28 amino acids that inhibit the release of growth hormone and other hypophyseal and gastrointestinal peptides. These neuropeptides are cleaved posttranslationally from a common precursor, pre-prosomatostatin. We report here the production and processing of pre-prosomatostatin by transgenic mice carrying a metallothionein-somatostatin fusion gene. The most active site of somatostatin production, as determined by hormone concentrations in the tissues, is the anterior pituitary, a tissue that does not normally synthesize somatostatin-like peptides. Anterior pituitary processed pre-prosomatostatin almost exclusively to the two biologically active peptides, somatostatin-14 and somatostatin-28, whereas the liver and kidney synthesized much smaller quantities of predominantly a 6000 dalton somatostatin-like peptide. The growth of the transgenic mice was normal despite high plasma levels of the somatostatin-like peptides. These studies indicate that proteases which cleave prosomatostatin to somatostatin-28 and somatostatin-14 are not specific to tissues that normally express somatostatin.     

The separation of microsomal membranes and free polyribosomes by gel filtration.

The integrity of polyribosome-membrane complexes in microsomal preparations is dependent on the centrifugal conditions used for their preparation. This paper describes techniques based on gel filtration that enable the rapid and gentle separation of microsomal membranes from both free polyribosomes and soluble protein.     

Fucosylation of exogenous xyloglucans by pea microsomal membranes

Microsomal membrane preparations from growing regions of etiolated pea stems catalyzed the transfer of [14C]fucosyl units from GDP-[U-14C]-L-fucose into exogenously added xyloglucan acceptors, as well as into endogenous xyloglucan. The transfer was more effective using nonfucosylated tamarind seed xyloglucan than with pea wall xyloglucan in which almost all galactose units are already fucosylated. Hydrolysis of products by endo-1,4-beta-D-glucanase yielded in each case radioactive nonasaccharide as the main fucosylated product. UDP-galactose enhanced the fucosylation of endogenous primer but it had little effect on fucosyl transfer to exogenously added xyloglucans. Low-molecular-weight nonfucosylated oligosaccharide fragments up to the octasaccharide Glc4Xyl3Gal (obtained by endoglucanase action on tamarind seed xyloglucan) were ineffectual as fucosyl acceptors but inhibited the fucosylation of endogenous as well as of added xyloglucan. With octasaccharide, the inhibition was competitive in relation to the xyloglucan acceptor (Ki = 70 microM) and noncompetitive in relation to the donor GDP-fucose (Ki = 210 microM). It is concluded that fucosyltransferase acts independently and in a noncoordinated manner from other glycosyltransferases that are required to synthesize xyloglucan. Its active site recognizes a fragment longer than the galactosylated octasaccharide unit before transfucosylation will ensue.     

Fluorescence emitted from microsomal membranes by lipid peroxidation

The fluorescence emitted from rat liver microsomal membranes which had undergone enzymatic and nonenzymatic lipid peroxidation was detected directly. This fluorescence produced in peroxidized membranes increased progressively with peroxidation reaction time, and the fluorescent substances produced were retained in the membranes without being released into the aqueous phase. Extracts of the peroxidized membranes with organic solvents (chloroform/methanol) emitted fluorescence which was also dependent on the peroxidation reaction time. The generation profiles of fluorescence emitted from both the peroxidized membranes and their extracted membrane lipids differed essentially from that of thiobarbituric acid-reactive substances which reached a plateau at a relatively early stage of peroxidation reaction. These results indicate that lipid peroxidation induces stepwise chemical and physical changes in membranes and that the fluorescence from peroxidized membranes will be useful in studying such changes occurring in biological membranes.     

Inactivation of dihydrofolate reductase in vitro by binding to microsomal membranes.

Dihydrofolate reductase was inactivated when incubated with the 27,000 × g pellet of lymphoma. Inactive enzyme was shown to be bound to the microsomal fraction and could be reactivated by urea. No acid-soluble material was produced nor did any change in the molecular weight of the enzyme molecule occur.     

Biosynthesis of intestinal microvillar proteins. Processing of aminopeptidase N by microsomal membranes.

The biosynthesis of small-intestinal aminopeptidase N (EC 3.4.11.2) was studied in a cell-free translation system derived from rabbit reticulocytes. When dog pancreatic microsomal fractions were present during translation, most of the aminopeptidase N synthesized was found in a membrane-bound rather than a soluble form, indicating that synthesis of the enzyme takes place on ribosomes attached to the rough endoplasmic reticulum. The microsomal fractions process the Mr-115 000 polypeptide, which is the primary translation product of aminopeptidase N, to a polypeptide of Mr 140 000. This was found to be sensitive to the action of endo-beta-N-acetylglucosaminidase H (EC 3.2.1.96), showing that aminopeptidase N undergoes transmembrane glycosylation during synthesis. The position of the signal sequence in aminopeptidase N was determined by a synchronized translation experiment. It was found that microsomal fractions should be added before about 25% of the polypeptide was synthesized to ensure processing to the high-mannose glycosylated form. This suggests that the signal sequence is situated in the N-terminal part of the aminopeptidase N. The size of the cell-free translation product in the absence of microsomal fractions was found to be similar to that on one of the forms of the enzyme obtained from tunicamycin-treated organ-cultured intestinal explants.     

Cyclic AMP metabolism by swine adipocyte microsomal and plasma membranes

Extracellular cyclic AMP is source of extracellular adenosine in brain and kidney. Whether this occurs in adipose tissue is unknown. The present study evaluated the capacity of swine adipocyte plasma membranes to metabolize cyclic AMP to AMP and adenosine, via phosphodiesterase (PDE) and 5'-nucleotidase (5'-NT), respectively. Plasma membranes (PM) and microsomal membranes (MM) were isolated from over-the-shoulder subcutaneous adipose tissue of 3 month-old male miniature swine. The purity of the membrane fractions was determined and PDE and 5'-NT activities in PM and MM fractions were corrected for cross-contamination. The maximal activity of MM-PDE was 7-fold greater than that of PM-PDE. MM-PDE was 100% inhibited by 5 microM cilostamide, while PM-PDE was unaffected by this PDE3B inhibitor. Inhibitors of PDE1, PDE2, PDE4 and PDE5 also failed to inhibit PM-PDE. However, 1 mM DPSPX inhibited PM-PDE activity by 72%. When PM were incubated with 0.8 microM cyclic AMP for 20 min, AMP accumulation was four times that of adenosine. These data demonstrate that cyclic AMP can be converted to AMP and adenosine by the PM-bound enzymes 5'-NT and PDE, and suggest that the PM-PDE responsible for extracellular cyclic AMP metabolism to AMP is distinct from the intracellular MM-PDE.     

Growth-related lipid peroxidation in tumour microsomal membranes and mitochondria.

Microsomes and mitochondria isolated from Morris hepatomas 3924A (fast-growing) and 44 (slow-growing) and Ehrlich ascites tumour cells exhibit a NADPH-dependent peroxidation of endogenous lipids lower than that of the corresponding fractions from rat liver. Moreover, the O2- and ascorbate-dependent lipid peroxidations are decreased in microsomes from the two Morris hepatomas. The peroxidative activity appears to be inversely related to the growth rate of the tumours. It is suggested that the low susceptibility of tumour membranes to peroxidative agents may be a factor responsible for the high mitotic activity of this tissue.     

Alterations in microsomal and plasma membranes during liver regeneration.

Investigations have been carried out on the alterations of membrane lipids and some enzyme activities during liver regeneration. The results indicated that 32 h after partial hepatectomy the membrane phospholipids per mg protein were augmented. The cholesterol esters were also increased in both microsomal and plasma membranes. The specific radioactivity of the separate phospholipid fractions, estimated by incorporation of 14C-palmitate into the phospholipid molecules, was higher in membranes from partially hepatectomized rats, compared to sham-operated ones, indicating an enhanced phospholipid synthesis. The content and specific radioactivity of diacylglycerols and triacylglycerols was enhanced in both types of membranes from regenerating liver. Moreover, we observed a fluidization of these membranes, which is illustrated by the decrease of the structural order parameter (SDPH) of the lipid bilayer as well as by the elevation of the excimer to monomer fluorescent ratio (IE/IM). 1,6-Diphenyl-1,3,5-hexatriene and pyrene were used as fluorescent probes for determination of the membranes physical state. Palmitoyl-CoA and oleoyl-CoA synthetase, acyl-CoA: lysophosphocholine and acyl-CoA:lysophosphoethanolamine acyltransferase as well as phospholipase C activities were augmented in membranes from partially hepatectomized rats. The biological significance of these alterations in the process of liver regeneration is discussed.     

Rat liver microsomal palmitoyl-coenzyme A synthetase. Structural properties

The structural properties of purified palmitoyl-CoA synthetase from rat liver microsomal material were investigated. The active enzyme has a molecular weight of 168000 and contains about 8.2mol of phospholipid bound/mol of enzyme protein, as well as bound fatty acids. Association of the active enzyme was shown to occur, without impairment of catalytic activity. The lowest-molecular-weight species obtained under denaturing conditions was 27000 daltons.     

Cholesterol exchange between microsomal, mitochondrial and erythrocyte membranes and its enhancement by cytosol.

1. Cholesterol exchanges between isolated rat liver microsomes and mitochondria and between erythrocytes and microsomes or mitochondria during incubation in vitro. The exchange process is temperature dependent and is no accompanied by a net movement of sterol. 2. cholesterol exchange between the membranes was enhanced by the addition of 105 000 x g supernatant fraction (S105) from rat liver. The degree to which sterol exchange was enhanced was dependent on the amount of this supernatant fraction present in the incubation. 3. enhancement of sterol exchange was not observed with heated S105 fraction, but activity was retained after dialysis or aging at 10 degrees C; these results suggest the presence of a cholesterol-exchange protein in the cytosol from rat liver.     

Pyrophosphate-driven proton transport by microsomal membranes of corn coleoptiles

Corn (Zea mays L. cv Trojan T929) coleoptile membranes were fractionated on isopycnic sucrose density gradients. Two peaks of ATP-driven H⁺-transport activity, corresponding to the previously characterized tonoplast (1.07 grams per cubic centimeter) and Golgi (1.13 grams per cubic centimeter) fractions (Chanson and Taiz, Plant Physiol 1985 78: 232-240) were localized. Coincident with these were two peaks of inorganic pyrophosphate (PPi)-driven H⁺-transport. At saturating (3 millimolar) concentrations of Mg²⁺:ATP, the rate of proton transport was further enhanced by the addition of 3 millimolar PPi, and the stimulation was additive, i.e. equal to the sum of the two added separately. The specific PPi analog, imidodiphosphate, antagonized PPi-driven H⁺-transport, but had no effect on ATP-driven transport. Moreover, PPi-dependent proton transport in both tonoplast-enriched and Golgi-enriched fractions was strongly promoted by 50 millimolar KNO₃, unlike the ATP-dependent H⁺-pumps of the same membranes. Taken together, the results indicate that PPi-driven proton transport is mediated by specific membrane-bound H⁺-translocating pyrophosphatases. Both potassium and a permanent anion (NO₃⁻ > Cl⁻), were required for maximum activity. The PPi-driven proton pumps were totally inhibited by N,N′-dicyclohexylcarbodiimide, but were insensitive to 100 millimolar vanadate. The PPi concentration in coleoptile extracts was determined using an NADH oxidation assay system coupled to purified pyrophosphate:fructose 6-phosphate 1-phosphotransferase (EC 2.7.1.90). The total pyrophosphate content of corn coleoptiles was 20 nanomoles/gram fresh weight. Assuming a cytoplasmic location, the calculated PPi concentration is sufficient to drive proton transport at 20% of the maximum rate measured in vitro for the tonoplast-enriched fraction, and 10% of the maximum rate for the Golgi-enriched fraction.     

Rat cerebral cortical synaptoneurosomal membranes. Structure and interactions with imidazobenzodiazepine and 1,4-dihydropyridine calcium channel drugs.

Small angle x-ray scattering has been used to investigate the structure of synaptoneurosomal (SNM) membranes from rat cerebral cortex. Electron micrographs of the preparation showed SNM with classical synaptic appositions intact, other vesicles, occasional mitochondria, and some myelin. An immunoassay for myelin basic protein placed the myelin content of normal rat SNM at less than 2% by weight of the total membrane present. X-Ray diffraction patterns showed five diffraction orders with a unit cell repeat for the membrane of 71 to 78 A at higher hydration states. At lower hydration, 11 orders appeared; the unit cell repeat was 130 A, indicating that the unit cell contained two membranes. Electron density profiles for the 130-A unit cell were determined; they clearly showed the two opposed asymmetrical membranes of the SNM vesicles. SNM membrane/buffer partition coefficients (Kp) of imidazobenzodiazepine and 1,4-dihydropyridine (DHP) calcium channel drugs were measured; Kp's for DHP drugs were approximately five times higher in rabbit light sarcoplasmic reticulum than in SNM. Ro 15-1788 and the DHP BAY K 8644 bind primarily to the outer monolayer of vesicles of intact SNM membranes. Nonspecific equilibrium binding of Ro 15-1788 occurs mainly in the upper acyl chain of the bilayer in lipid extracts of SNM membrane.     

Mannosylation of endogenous and exogenous phosphatidic acid by liver microsomal membranes. Formation of phosphatidylmannose

Hamster liver post-nuclear membranes catalyze the transfer of mannose from GDP-mannose to endogenous dolichyl phosphate and to a second major endogenous acidic lipid. This mannolipid was believed to be synthesized from endogenous retinyl phosphate and was tentatively identified as retinyl phosphate mannose (Ret-P-Man) (De Luca, L. M., Brugh, M. R. Silverman-Jones, C. S. and Shidoji, Y. (1982) Biochem. J. 208, 159-170). To characterize this endogenous mannolipid in more detail, we isolated and purified the mannolipid from incubations containing hamster liver membranes and GDP-[14C]mannose and compared its properties to those of authentic Ret-P-Man. We found that the endogenous mannolipid was separable from authentic Ret-P-Man on a Mono Q anion exchange column, did not exhibit the absorbance spectrum characteristic of a retinol moiety, and was stable to mild acid under conditions which cleave authentic Ret-P-Man. The endogenous mannolipid was sensitive to mild base hydrolysis and mannose was released from the mannolipid by snake venom phosphodiesterase digestion. These properties were consistent with the endogenous acceptor being phosphatidic acid. Addition of exogenous phosphatidic acid, but not phospholipids with a head group blocking the phosphate moiety, to incubations containing hamster liver membranes and GDP-[14C]mannose resulted in the synthesis of a mannolipid with chromatographic and physical properties identical to the endogenous mannolipid. A double-labeled mannolipid was synthesized in incubations containing hamster liver membranes, GDP-[14C]mannose, and [3H]phosphatidic acid. Mannosyl transfer to exogenous phosphatidic acid was saturable with increasing concentrations of phosphatidic acid and GDP-mannose and specific for glycosyl transfer from GDP-mannose. Class E Thy-1-negative mutant mouse lymphoma cell membranes, which are defective in dolichyl phosphate mannose synthesis, also fail to transfer mannose from GDP-mannose to exogenous phosphatidic acid or retinyl phosphate. Amphomycin, an inhibitor of dolichyl phosphate mannose synthesis, blocked mannosyl transfer to the endogenous lipid, and to exogenous retinyl phosphate and phosphatidic acid. We conclude that the same mannosyltransferase responsible for dolichyl phosphate mannose synthesis can also utilize in vitro exogenous retinyl phosphate and phosphatidic acid as well as endogenous phosphatidic acid as mannosyl acceptors.     

Binding of glycoproteins of microsomal and Golgi membranes to lectins.

Four subunits of the acetylcholine receptor molecule, obtained from the electric organ of $\text{Torpedo ocellata}$, have been isolated using polyacrylamide gel electrophoresis, and assayed by titration with a fluorescent lanthanide, terbium, and by affinity-labeling with $\text{p}$-($\text{N}$-maleimido)benzyl [trimethyl-³H] ammonium iodide. The site with which the activator-analogue affinity label reacts, as well as the terbium-binding sites, are mainly associated with the smallest of the subunits of an apparent molecular weight of 40,000. Calcium competes with terbium for these binding sites. The affinity for terbium is the same in the intact molecule as in the subunit (K_Tb ? 19 ± 1 μM), but the affinity for calcium decreases by a factor of 4 (K_Ca ? 4 mM) in the subunit. Hydrolysis of the receptor, catalyzed by trypsin and chymotrypsin, to peptides with an apparent molecular weight of 8000 or less, does not affect the terbium-binding sites. These experiments indicate that the binding sites for neural activators and for calcium are associated with the same subunit, and that the terbium- and calcium-binding sites reflect structural properties of the polypeptide chain rather than the three-dimensional structure of the protein.     

Glycoprotein biosynthesis. Rat liver microsomal glucosidases which process oligosaccharides.

Asparagine-linked oligosaccharides of glycoproteins undergo extensive modification or "processing" following their attachment to protein. A key step in post-glycosylation processing is the sequential removal of glucose residues from the protein-linked oligosaccharide. We have studied rat liver preparations which catalyze removal of glucose from Glc3Man9GlcNAc, Glc2Man9GlcNAc, and Glc1Man9GlcNAc. Detergent solubilization studies, inhibitor studies, and temperature-activity profiles indicate that at least two distinct glucosidases are present in the membranes. One of these glucosidases removes the distal glucose from Glc3Man9GlcNAc, and the other glucosidase sequentially removes glucose from Glc2Man9GlcNAc and Glc1Man9GlcNAc. The latter glucosidase has been solubilized from the microsomal memrbranes and purified 12-fold. The glucosidases, which are integral membrane proteins, are localized in the rough and smooth microsomes and appear to be located on the cisternal surface of the microsomal vesicles. These glucosidases are suggested to be of biological importance in catalyzing the initial events in the post-glycosylation processing of cellular glycoprotein.     

Effect of t-butyl hydroperoxide on liver microsomal membranes and microsomal calcium sequestration

In vitro exposure of hepatocytes or liver microsomes to t-butyl hydroperoxide resulted in a marked decrease of liver microsomal calcium pump activity. Decreased calcium pump activity was dependent upon both concentration and time. Liver microsomes could be protected from this effect by glutathione or dithiothreitol. In addition to decreased calcium pump activity, exposure of liver microsomes to t-butyl hydroperoxide produced a concentration-dependent aggregation of microsomal membrane protein as determined by polyacrylamide gel electrophoresis. Inhibition of microsomal calcium pump activity was observed when intact hepatocytes were incubated, in vitro, with t-butyl hydroperoxide. However, aggregation of microsomal membrane protein was not observed when hepatocytes were incubated with t-butyl hydroperoxide. The effects produced by exposure of liver microsomes to this compound do not appear to be a complete model of actions of the compound on intact cells.     

In vitro processing of tomato proteinase inhibitor I by barley microsomal membranes: a system for analysis of cotranslational processing of plant endomembrane proteins

A plant-derived in vitro system for the study of cotranslational processing of plant endomembrane proteins has been developed and used to investigate cotranslational proteolytic processing of tomato proteinase inhibitor I. Translation of the inhibitor I precursor in wheat germ lysate supplemented with barley aleurone microsomal membranes resulted in cotranslational import of the protein into microsomal vesicles and cleavage of the signal sequence. NH₂-terminal sequence analysis of the translocated inhibitor I processing intermediate showed that the signal sequence was cleaved between Ala₂₃ and Arg₂₄ of the precursor protein. Parallel experiments using dog pancreas microsomal membranes indicated an identical site of cleavage, suggesting that the substrate determinants for signal sequence processing are conserved across kingdoms. The plant-derived processing system used for this study may be valuable for analysis of cotranslational processing of other plant preproteins and for characterizing the components of the cotranslational import machinery in plants.