Henri Beaufay

The dolichol pathway of protein glycosylation in rat liver. Stimulation by GTP of the incorporation of N-acetylglucosamine in endogenous lipids and proteins of rough microsomes treated with pyrophosphate.

Incorporation of N-acetylglucosamine into endogenous lipid and protein acceptors was investigated on heavy microsomes from rat liver, incubated with UDP-N-acetyl[14C]glucosamine and GDP-mannose in the absence of detergent. This subcellular preparation derived for 95% or more from the rough endoplasmic reticulum and was devoid of Golgi components which contain the enzyme that adds the peripheral N-acetylglucosamine units to glycoproteins. The label was found almost exclusively in dolichyl diphosphate N-acetylglucosamine, except when the subcellular preparation was treated with pyrophosphate and subsequently incubated with the nucleotide sugars in the presence of GTP. Then, the incorporation of N-acetylglucosamine was considerably enhanced, and the additional label was associated with dolichyl diphosphate N,N-diacetylchitobiose, with dolichyl diphosphate oligosaccharides and with proteins. The time-course of N-acetylglucosamine incorporation in these products was compatible with the pathway of dolichyl diphosphate glycoconjugates for the biosynthesis of the core portion of saccharide chains linked to asparagine residues of glycoproteins. The addition of GDP-mannose to the incubation medium was required to produce labeled dolichyl diphosphate oligosaccharides, but not to incorporate N-acetylglucosamine in protein. It is concluded that rough microsomes are capable of assembling dolichol-linked oligosaccharides from exogenous nucleotide precursors and of transferring N,N-diacetylchitobiose, or its mannosylated derivatives, from the lipid intermediate to endogenous proteins. However, these metabolic activities are hindered in the original subcellular preparation, and in the absence of GTP. Although the earliest perceptible effect produced jointly by the treatment with pyrophosphate and by GTP was the synthesis of dolichyl diphosphate N,N-diacetylchitobiose, the primary action of these factors remains uncertain. They may stimulate directly the reaction forming dolichyl diphosphate N,N-diacetylchitobiose from dolichyl diphosphate N-acetylglucosamine, or activate the synthesis of this latter intermediate from a particular pool of dolichyl monophosphate which is readily converted afterwards into disaccharide and oligosaccharide derivatives and glycosylates protein. The requirement for GTP might have a functional meaning, for GTP acted maximally at a concentration distinctly lower than its actual concentration in liver. The detachment of ribosomes from rough vesicles was the major alteration induced by treatment with pyrophosphate. It is suggested that the removal of ribosomes unmasks the membrane sites where GTP acts.

A structural basis of enzymic heterogeneity within liver endoplasmic reticulum

Abstract Earlier studies have evidenced a particular kind of biochemical hetero-geneity within the endoplasmic reticulum of liver cells. Enzymes upon which quantitative data are available are present in the same membranes, in both the rough and smooth portions. However, there are two different distribution patterns: NADPH cytochrome c reductase is more concentrated in the smooth membranes; glucose-6-phosphatase is more uniformly distributed through the rough and smooth portions; the other enzyme distributions conform to one of these patterns designated b and c , respectively. We consider a plausible explanation about this heterogeneity, postulating that enzymes in solution in the cisternal medium and integral membrane proteins of the lumenal aspect are randomly distributed through the whole endoplasmic reticulum (type c enzymes), whereas membrane proteins which expose a large segment at the cytoplasmic aspect are heterogeneously distributed. This latter aspect would consist of two distinct, homogeneous domains; one corresponding to the membrane surfaces in close association with ribosomes; the other containing the enzymes of type b . These domains extensively interpenetrate, accounting for the presence of a significant fraction of the enzymes of type b in the rough microsomes. Experimental data concerning the transmembrane asymmetry of enzymes categorized in groups b and c are briefly reviewed. Relationships between the distributions of NADPH cytochrome c reductase, glucose-6-phosphatase and ribosomes in density gradient analysis are deduced from the assumptions made and confronted with actual density distributions obtained.

Liver Carboxylesterases: Topogenesis of Intracellular and Secreted Forms

In the liver carboxylesterase activity is shared between several isoenzymes which hydrolyse a wide variety of substrates, including therapeutic drugs and xenobiotics. Carboxylesterases act also, in vitro, on endogenous lipid substrates, but the physiological meaning of their action on these compounds is still unclear [1, 2]. Most liver carboxylesterases reside in the lumen of the endoplasmic reticulum (ER) where they are either free, or loosely bound to the inner surface of the membrane [3].

Translocation and proteolytic processing of nascent secretory polypeptide chains: two functions associated with the ribosomal domain of the endoplasmic reticulum.

Rat liver microsomes were subfractionated by isopycnic centrifugation in sucrose gradient. The subfractions were assayed for translocation and proteolytic processing of nascent polypeptides in a rabbit reticulocyte lysate programmed with total RNA from human term placenta. The distribution of the translocation and processing of prelactogen through the gradient correlated with that of the microsomal RNA (ribosomes). Microsomes became inactive upon incubation with elastase, but the proteolyzed membranes recovered their activity by recombination with the soluble and active fragment of the docking protein (SRP‐receptor) from dog pancreas. When this fragment was combined with the gradient subfractions, or with the subfractions inactivated by incubation with elastase, the density profile of the translocation activity remained similar to that of RNA. Thus, its distribution cannot be accounted for merely by that of the docking protein; another membrane constituent, still unidentified, is both necessary for translocation of polypeptides and restricted to the rough portions of the endosplamic reticulum. Signal peptidase was assayed in the absence of protein synthesis, by use of preformed prelactogen and detergent‐disrupted microsomes. Its density distribution was also similar to that of RNA. Several components of the endosplamic reticulum now appear to be segregated within restricted areas on either side of the membrane, and to make up a biochemically distinct domain. We propose to call it the ribosomal domain in consideration of its contribution to protein biosynthesis by bound ribosomes. This domain probably accounts for a greater part of the membrane area at the cytoplasmic than at the luminal surface, as postulated earlier to explain how enzymes of the cytoplasmic surface are relatively less abundant in the rough microsomes than those of the luminal surface [Amar‐Costesec A. & Beaufay H. (1981) J. Theor. Biol. 89, 217–230].

Subcellular fractionation of epithelial cells from toad urinary bladder. 1. Assay of marker enzymes and differential centrifugation

We have undertaken the analytical fractionation of epithelial cells from toad urinary bladder, a tissue extensively used to study epithelial transport of ions and water. In an attempt to establish markers for the main subcellular organelles, a number of enzymes were assayed in cell homogenates. The nearly ubiquitous plasma membrane marker 5′‐nucleotidase, and the transferases that donate N‐acetylglucosaminyl, galactosyl, and sialyl residues to glycoproteins and glycolipids in the Golgi complex were not detectable. Glucose‐6‐phosphatase activity was low in relation to that of nonspecific phosphatases and, therefore, not suitable for identifying the endoplasmic reticulum. Like the cytosolic enzyme lactate dehydrogenase, catalase was essentially found in the high‐speed supernatant, with a noteworthy part of aminopeptidase (substrate, leucyl‐ß‐naphthylamide) and NAD glycohydrolase. Other enzymes, including cytochrome c oxidase, acid phosphatase, acid N‐acetyl‐ß‐glucosaminidase, alkaline phosphatase, alkaline phosphodiesterase I, nucleoside diphosphatase (substrate ADP), oligomycin‐resistant Mg++‐ATPase, and mannosyltransferase (acceptor, dolichylphosphate) were fairly active and largely sedimentable. After differential centrifugation, cytochrome oxidase, acid phosphatase, and acid N‐acetyl‐ß‐glucosaminidase were typically associated with the large granule fraction, whereas the other sedimentable enzymes exhibited a broad distribution profile overlapping the nuclear, large granule, and microsome fractions. Their behavior in density equilibrium centrifugation is examined in a companion paper.

Subcellular Fractionation of Epithelial-cells From Toad Urinary-bladder .2. Isopycnic Centrifugation and Effect of Density Perturbants

Cytoplasmic granules obtained from toad urinary bladder epithelial cells were brought to buoyancy in a linear sucrose gradient. The gradient was loaded either with untreated cytoplasmic granules, or with granules treated with Na pyrophosphate (PPi), with digitonin, or with PPi and digitonin in succession. The following enzymes were assayed in the gradient subfractions: oligomycin‐insensitive Mg++‐ATPase, alkaline phosphodiesterase I, alkaline phosphatase, acid N‐acetyl‐β‐glucosaminidase, cytochrome oxidase, nucleoside diphosphatase (substrate, ADP), aminopeptidase (substrate, leucyl‐β‐naphthylamide), and mannosyltransferase (acceptor, dolichylphosphate). Comparison of the density distributions of enzymes in untreated and treated preparations led to the characterization of 4 distinct subcellular entities. In agreement with the properties of mitochondria from other cell types, cytochrome oxidase buoys at 1.18 within a narrow density range and its behavior is not significantly altered by PPi or digitonin. Under all conditions, acid N‐acetyl‐β‐glucosaminidase is recovered over a broad density range in the lower part of the gradient and appears as a qualified lysosomal marker. Mg++‐ATPase, alkaline phosphodiesterase I, and alkaline phosphatase belong to a group with the distinguishing features of a low equilibrium density in native cytoplasmic granules and a marked shift (+0.03 density units) after digitonin treatment. Such properties are typical of the plasma membranes. Part of the aminopeptidase activity probably also belongs to plasma membrane‐derived elements. Minor differences between alkaline phosphatase and the other 2 members of that group make it possible that their distribution domains in the membrane do not overlap or coincide. Finally, mannosyltransferase is identified as an endoplasmic reticulum marker: its distribution is shifted to lower densities after PPi. This treatment releases ribosomes from rough microsomes and accordingly decreases the density of these vesicles. The subcellular localization of nucleoside diphosphatase, which displays distinct properties, is still unclear.