Denis LeBel

A convenient method for the ATPase assay

Abstract A new method for the determination of inorganic phosphorus released in ATPase assay has been evaluated. The method is based on the reduction of a phosphomolybdate complex by Elon in a copper acetate buffer. In contrast to current methods, there is no interference by ATP with color development. There is also less or no interference by other compounds usually present in ATPase assay media. The method is simple, sensitive, and reproducible.

The major protein of pancreatic zymogen granule membranes (GP-2) is anchored via covalent bonds to phosphatidylinositol☆

GP-2, the major integral protein characteristic of the pancreatic zymogen granule membrane can be released from the membrane by the action of a phosphatidylinositol specific phospholipase C (PI-PLC). In a hydrophobic/hydrophilic phase separation system using the non-ionic detergent Triton X-114, the membrane-bound form of the protein went from the detergent phase into the hydrophilic phase upon action of the phospholipase. PI-PLC solubilization of GP-2 unmasked an antigenic determinant similar to the cross-reacting determinant of the trypanosome variant surface glycoproteins. This determinant being a distinctive feature of the glycan moiety of phosphatidyl-inositol anchored membrane proteins, it established the glycosyl-phosphatidyl-inositol nature of the GP-2 membrane anchor. Since soluble GP-2 is also found in the contents of the granule and is secreted intact into the pancreatic juice, it is likely that one of the mechanisms responsible for its release could be a specific phospholipase. GP-2 is the first glycosyl-phosphatidyl-inositol-anchored protein that is integral to the membrane of an organelle and not located at the surface of the cell.

Simultaneous kinetic determinations of lipase, chymotrypsin, trypsin, elastase, and amylase on the same microtiter plate.

Micromethods are described to determine in 10 min the activity of the five most common pancreatic zymogens: amylase, lipase, trypsin, chymotrypsin, and elastase. Progress of the reactions is monitored at 405 nm, allowing the kinetic determination of the five enzymes on a single 96-well microtiter plate. Amylase activity is measured by the release of p-nitrophenol from a chemically defined substrate. Linearity of the assay is from 10 to 360 U/L of amylase, and activities as low as 0.4 U/L can be easily measured by extending the period of incubation up to 24 h. Chymotrypsin, trypsin, and elastase activities are monitored by the release of p-nitroanilide from specific substrates, and activities are from 25 to 6,500, 15 to 260, and 20 to 600 U/L, respectively. Finally, lipase is determined by the clearing of a commercially available stabilized emulsion of triolein. The lipase determination can be performed from 90 to 3,600 U/L. When microplate methods were compared with conventional procedures, a perfect correspondence was found between the two types of procedure. Factors necessary to convert microplate results to those of conventional assays are provided. These microassays make possible the rapid and simultaneous determination of the three main types of pancreatic hydrolases (a glycohydrolase, three proteases, and a lipase) with < 5 microliters of pancreatic juice by kinetic analysis. They could be easily adopted as routine assays in most research laboratories.

Effect of C-domain N-glycosylation and deletion on rat pancreatic alpha-amylase secretion and activity.

Even though all animal alpha-amylases include glycosylation sequons (Asn-Xaa-Thr/Ser) in their sequences, amylases purified from natural sources are not quantitatively glycosylated. When wild-type rat pancreatic alpha-amylase, which contains two glycosylation sequons, was expressed in animal cell lines the protein displayed a very low rate of glycosylation (approx. 2%), even after Brefeldin A treatment to increase the contact with the glycosylation machinery. Site-directed mutagenesis of the first glycosylation sequon (Asn(410)-->Gln) resulted in 90% of the protein being glycosylated at the second glycosylation sequon (Asn(459)). Mutation of the second sequon completely inhibited glycosylation. In order to ascertain if the interference in the glycosylation of Asn(459) that was eliminated by the Asn(410)-->Gln mutation could be due to the position of the asparagine residue in the Cys(448)-Cys(460) disulphide bridge, these cysteine residues were mutated to serine residues. The resulting mutant was found to be 100% glycosylated. All mutants with mutations in the C-domain had specific activities identical to that of the wild-type enzyme, indicating that enzymic activity is independent of the structure and modification of the C-terminal domain. To further test the independence of the C-domain with respect to the two N-terminal domains of the protein, which harbour the catalytic site, the last seven of the ten beta\beta-strands that make up the beta-sandwich configuration of the domain were deleted. The truncated protein was not secreted from cells and all enzyme activity was destroyed. These observations show that Asn(459) is the only site that can be glycosylated in wild-type amylase, and confirm the relative independence of the C-terminal domain of alpha-amylase with respect to enzyme activity. In addition, they also establish that the C-terminal domain is absolutely essential for the correct post-translational folding of the enzyme that is responsible for its activity and allows for its secretion.

Specific Localization of Membrane Dipeptidase and Dipeptidyl Peptidase IV in Secretion Granules of Two Different Pancreatic Islet Cells

Endocrine cells require several protein convertases to process the precursors of hormonal peptides that they secrete. In addition to the convertases, which have a crucial role in the maturation of prohormones, many other proteases are present in endocrine cells, the roles of which are less well established. Two of these proteases, dipeptidyl peptidase IV (EC 3.4.14.5) and membrane dipeptidase (EC 3.4.13.19), have been immunocytochemically localized in the endocrine pancreas of the pig. Membrane dipeptidase was present exclusively in cells of the islet of Langerhans that were positive for the pancreatic polypeptide, whereas dipeptidyl peptidase IV was restricted to cells positive for glucagon. Both enzymes were observed in the content of secretory granules and therefore would be released into the interstitial space as the granules undergo exocytosis. At this location they could act on secretions of other islet cells. The relative concentration of dipeptidyl peptidase IV was lower in dense glucagon granules, where the immunoreactivity to glucagon was higher, and vice versa for light granules. This suggests that, in A-cells, dipeptidyl peptidase IV could be sent for degradation in the endosomal/lysosomal compartment during the process of granule maturation or could be removed from granules for continuous release into the interstitial space. The intense proteolytic activity that takes place in the endocrine pancreas could produce many potential dipeptide substrates for membrane dipeptidase.

Purification and characterization of the apical plasma membrane of the rat pancreatic acinar cell

SummaryA method is described for the rapid purification of the apical plasma membrane from the rat pancreatic acinar cell. It makes use of wheat germ agglutinin affinity chromatography to selectively bind vesicles with N-acetyl glucosamine present at their surface. Particular conditions (150 mm NaCl) had then to be used to keep membrane vesicles in the coveted orientation, i.e. as right-side-out vesicles. Due to its specific apical location in many epithelial cells, γ-glutamyltranspeptidase was chosen to monitor the purification procedure. The final fraction was enriched in γ-glutamyltranspeptidase by a factor of 75 relative to the homogenate. Na,K-ATPase, a strict basolateral membrane marker, was not detectable in the fraction. No membranes originating from other compartments, more particularly expected from zymogen granules, or from other cell types, did contaminate the preparation. As expected for an epithelial cell apical plasmalemma, lipid composition showed a very high ratio of glycolipids (37.5%). The absence of membrane-bound GP-2, and the exceptionally high specific activity of γ-glutamyltranspeptidase suggest that the apical membrane would not be made up by the exocytosis of secretory granule, but instead by the fusion of specialized secretory vesicles very likely originating from the constitutive secretory pathway. In conclusion, this report describes a method of obtaining a fraction highly enriched in the secretory apex of the pancreatic exocrine cell that would be directly involved in exocytosis with zymogen granules and also in local anion transport.

Different patterns of proteins are secreted by the pig pancreas when stimulated by secretin alone or in combination with caerulein

The protein compositions of pig pancreatic secretions collected under stimulation by secretin alone or in combination with caerulein were compared by SDS polyacrylamide gel electrophoresis. Different sets of proteins were observed in these two different conditions. One of the major proteins secreted under secretin alone was immunologically similar to the 92 kDa glycoprotein characteristic of the pig zymogen granule membrane. Since its proportion in the two secretions was drastically different and since this protein is exclusively found in the acinar cell, these observations support the view that the proteins released by the pig pancreas under secretin stimulation alone, and under the combination of secretin + caerulein do not originate from the same intracellular pool of the acinar cell and that the secretin-induced secretion does not derive from zymogen granules.

In vitro stability of pancreatic zymogen granules: roles of pH and calcium.

Purified preparations of pancreatic zymogen granules have the peculiar property of lysing instantaneously at neutral pH, a property clearly irreconcilable with the cytoplasmic pH of the acinar cell. Two important factors known for regulating the stability of secretory granules are calcium and pH. Fluorescence microscopy of acinar cells in the presence of weak bases showed that zymogen granules have an acidic pH. In vivo, abolition of the ΔpH by NH4Cl did not induce any lysis of the granules. In vitro, with purified granules, an acidic intragranular pH was measured. This ΔpH was produced by a Donnan potential. The importance for granule stability of keeping the intragranular pH acidic has been confirmed in vitro by addition of K+ and nigericin to the suspension medium. These conditions produced alkalinization of the granule matrix and caused instantaneous solubilization of the granules.

Efficient binding of regulated secretory protein aggregates to membrane phospholipids at acidic pH.

Some regulated secretory proteins are thought to be targeted to secretory granules through an acidic-dependent aggregation in the trans-Golgi network. In this report we use pancreatic zymogens, a paradigm of regulated proteins, to test this hypothesis, because they qualitatively aggregate upon acidification in vitro. Pig zymogens were found to start to aggregate significantly at pH approximately 6.0, a pH slightly lower than that at which rat zymogens aggregate, but still compatible with the pH of the cell-sorting compartments. When pig zymogen granule membranes were mixed with the zymogens in the aggregation assay, membranes that normally floated on 1 M sucrose were observed to be pelleted by the aggregating zymogens. Rat membranes were pelleted by pig zymogens and vice versa. Igs, typical constitutively secreted proteins, which needed chemical cross-linking to serve as an aggregated protein control, pelleted membranes almost independently of pH. Corresponding cross-linked zymogen-binding ability and pH dependence was unaffected by the chemical modification. Membranes treated with sodium carbonate, pH 11, or with protease K, were still pelleted by zymogens, suggesting that the aggregated zymogens bound to membrane lipids. This hypothesis was confirmed by the efficient pelleting of unilamellar vesicles composed of granule membrane lipids. Vesicles composed of single classes of phospholipids were also pelleted, but with various efficacies. We conclude that pancreatic zymogen aggregates, formed under the acidic conditions of the secretory pathway sorting compartments, have the capacity to bind firmly to membranes through their phospholipid constituents.

Identification of the proteins exposed on the cytoplasmic surface of the pancreatic zymogen granule

Lactoperoxidase-catalyzed 125I-iodination was used to label pancreatic zymogen granules. Membrane proteins facing the cytoplasmic surface were specifically labeled. Two low molecular weight proteins of 17 000 and 15 000 were intensely labeled at 0 degree C. Another small 13 kDa protein was strongly iodinated at 25 degrees C along with some others, including the 29 kDa subunit of the ATP diphosphohydrolase. The major glycoprotein of the granule membrane was not iodinated but the presence of an iodinated 80 kDa protein suggests that proteolytic fragments of the 92 kDa glycoprotein were accessible to iodination on the intact granule. These proteins localized on the cytoplasmic surface of the granule are believed to play a major role in the exocytotic phenomenon of the exocrine pancreas.