Regulation of Plasma Membrane beta-Glucan Synthase from Red Beet Root by Phospholipids : Reactivation of Triton X-100 Extracted Glucan Synthase by Phospholipids

Extraction of red beet root plasma membranes with the detergent Triton X-100 at a level of 2.0% (weight/volume) resulted in the depletion of over 90% of total membrane phospholipid and the reduction of glucan synthase activity by 80 to 90%. Reconstitution of the delipidated Triton X-100, 100,000g fraction in the presence of phospholipids restored glucan synthase activity. The most effective phospholipid was phosphatidyl-ethanolamine, which restored 110 to 144% of the original activity at 0.5% (weight/volume). Glucan synthase in the phospholipid-reactivated Triton X-100-treated fraction was enriched 9-fold in specific activity relative to microsomal membranes but was unstable in digitonin. These results support the hypothesis that glucan synthase activity is regulated by its phospholipid environment.     

beta]-Glucan Synthesis in the Cotton Fiber (IV. In Vitro Assembly of the Cellulose I Allomorph)

In vitro assembly of cellulose from plasma membrane extracts of the cotton (Gossypium hirsutum) fiber was enriched by a combination of 3-(N-morpholino)propanesulfonic acid extraction buffer and two independent digitonin solubilization steps consisting of 0.05% digitonin (SE1) followed by 1% digitonin (SE2). Glucan synthase activity assays revealed that, although the SE2 fraction possessed higher activity, only 8.6% of the in vitro product survived acetic/nitric acid treatment. On the other hand, the SE1 fraction was less active, but 32.1% of the total glucan in vitro product was resistant to acetic/nitric acid. In vitro products synthesized from the SE1 fraction contained [beta]-1,3-glucan and fibrillar cellulose I, whereas the SE2 fraction produced [beta]-1,3-glucan and cellulose II. Both celluloses assembled in vitro were labeled with cellobiohydrolase I-gold complex, and the electron diffraction patterns of both products from SE1 and SE2 revealed cellulose I and cellulose II, respectively. Contamination of native cellulose was ruled out by extensive evidence from autoradiography of the ethanol-insoluble and acetic/nitric acid-insoluble materials, including three different controls.     

Chloroplast and extrachloroplastic starch-degrading enzymes in Pisum sativum L.

The organelles of soybean (Glycine max (L.) Merr.) protoplasts were separated using a recently developed procedure which allows rapid (3-h) recovery of a fraction enriched for coated vesicles (CVs). As determined by marker-enzyme enrichment and ultrastructural analysis of isolated membrane fractions, endoplasmic reticulum, Golgi membranes, glucan-synthase-II (EC 2.4.1.34)-containing membranes (putative plasma membrane), mitochondria, and CVs were enriched in separate fractions in a sucrose density gradient. Glucan synthase I (EC 2.4.1.12) had the highest specific activity in the Golgi-enriched and CV-enriched fractions and was found to comigrate with CVs upon rate-zonal centrifugation of a CV-enriched fraction. For further elucidation of the role of these latter organelles in cell-wall regeneration, freshly isolated protoplasts were pulsed with [³H]glucose for 20 min, and the disappearance of label from the organelles was followed for the ensuing 1 h. Although a CV-enriched fraction contained glucan synthase I, it contained very small amounts of labelled polysaccharide during the period of study. Pulse-chase experiments with [³H]glucose helped to confirm the role of the Golgi apparatus in secretion of matrix polysaccharides by protoplasts.Abbreviations CV(s) coated vesicle(s) - Da dalton - ER endoplasmic reticulum - GSI,II glucan synthase I and II, respecitively Two whom correspondence should be directed. Address after February 1986:Department of Biology, Texas A&M University. College Station, TX 77843-3258, USA     

Preparation of right-side-out plasma membrane vesicles from Penicillium cyclopium: a critical assessment of markers.

A plasma membrane fraction was obtained by the combined use of differential centrifugation and aqueous polymer two-phase partitioning techniques. Vanadate-inhibited ATPase and glucan synthase activities were highly enriched in this fraction, although the presence of ATPase activity which was not inhibited by vanadate, nitrate, molybdate, anyimycin A or azide was also detected. Other intracellular membrane marker activities were present at very low or undetectable levels. A further separation step using Percoll density gradient centrifugation resulted in the separation of a fraction which exclusively contained vanadate-inhibited ATPase activity, and was enriched with silicotungstic-acid-staining membrane material. Latency tests performed on the plasma membrane markers showed that the membrane vesicles were in the right-side-out orientation.     

In vitro inhibition of stable 1,3-beta-D-glucan synthase activity from Neurospora crassa.

Glucan synthase activity of Neurospora crassa was isolated by treatment of protoplast lysates with 0.1% 3-[(3-cholamidopropyl)-dimethylammonio]-1-propanesulfonate and 0.5% octylglucoside in 25 mM 4-(2-hydroxyethyl)-1-piperazineethanesulfonic acid buffer, pH 7.4, containing 5 mM EDTA, 1 mM phenylmethylsulfonylfluoride, 200 mM inorganic phosphate, 10 microM GTP, 1 mM DTT, 10 mM sodium fluoride, and 600 mM glycerol. Resulting activity was partially purified by sucrose gradient density sedimentation. Approximately 70% of enzyme activity in the sucrose gradient peak fraction was soluble and enzyme activity was purified 7.3-fold. Partially purified enzyme activity had a half-life of several weeks at 4 degrees C, and a Km(app) of 1.66 +/- 0.28 mM. Inhibitors (Cilofungin, papulacandin B, aculeacin A, echinocandin B, sorbose and UDP) of 1,3-beta-D-glucan synthase activity were tested against crude particulate and detergent treated enzyme fractions and the Ki(app) of each inhibitor determined. It seems likely that this stable preparation of glucan synthase activity may be useful for in vitro enzyme screens for new glucan synthase inhibitors.     

Axonal Transport and Metabolism of Glycoproteins in Rat Sciatic Nerve

The distribution of 5'-nucleotidase activity, dopaminergic [3H]spiperone binding sites, and [3H]quinuclidinyl benzilate (QNB) binding sites in different subcellular fractions of bovine caudate nucleus has been studied. Each activity was enriched in a microsomal (P3) preparation from that tissue. The microsomal preparation was further fractionated by different techniques. First, the P3 fraction, or a sonicated P3 fraction, was fractionated on a discontinuous sucrose density gradient. Second, the P3 fraction, or a digitonin pretreated P3 fraction, was fractionated on a continuous sucrose density gradient. The results obtained demonstrate that 5'-nucleotidase activity does not cofractionate with radioligand binding activity, although no difference between the distributions of [3H]spiperone binding and [3H]QNB binding were seen. It is concluded that the two radioligand binding activities are located on nonglial membranes.     

UDP-Glucose: (1,3)-beta-Glucan Synthase from Daucus carota L. : Characterization, Photoaffinity Labeling, and Solubilization

The membrane-bound UDP-glucose-β-(1,3)-glucan synthase from Daucus carota L. was characterized and a solubilization procedure was developed. The enzyme exhibited maximal activity in the presence of 0.75 millimolar Ca²⁺, 0.5 millimolar EGTA, and 5 millimolar cellobiose at pH 7.5 and 30°C at 1 millimolar UDPG. Reaction products were confirmed to be (1,3)-linked glucan. Polypeptides of 150, 57, and 43 kilodaltons were labeled with the photoactivatible affinity label 5-azido-uridine 5′-β-[³²P] diphosphateglucose. Labeling of the 150 and 57 kilodalton polypeptides was completely protected against by 1 millimolar non-radioactive UDPG suggesting that one or both of these polypeptides may represent the UDPG binding subunit of glucan synthase. Carrot glucan synthase was solubilized with the detergent 3-[(3-cholamidopropyl)dimethylammonio]-1-propane sulfonate (CHAPS) in the absence of divalent cations and chelators; however, the percentage of enzyme which could be solubilized showed variability with membrane source. With microsomal membranes, up to 80% of the enzyme was released with 0.7% CHAPS. Solubilized enzyme was stable for at least 9 hours at 4°C. When more highly purified membrane fractions were isolated from sucrose step gradients a slightly different picture emerged. Activity from the 20/30% interface (Golgi and tonoplast enriched) was readily solubilized and expressed. Activity from the 30/40% interface (plasma membrane enriched) was also solubilized; however, it was necessary to add heat inactivated microsomes to assay mixtures for full activity to be expressed. A requirement for endogenous activators is suggested.     

Analytical study of microsomes and isolated subcellular membranes from rat liver VIII. Subfractionation of preparations enriched with plasma membranes, outer mitochondrial membranes, or Golgi complex membranes

Preparations enriched with plasmalemmal, outer mitochondrial, or Golgi complex membranes from rat liver were subfractionated by isopycnic centrifugation, without or after treatment with digitonin, to establish the subcellular distribution of a variety of enzymes. The typical plasmalemmal enzymes 5'-nucleotidase, alkaline phosphodiesterase I, and alkaline phosphatase were markedly shifted by digitonin toward higher densities in all three preparations. Three glycosyltransferases, highly purified in the Golgi fraction, were moderately shifted by digitonin in both this Golgi complex preparation and the microsomal fraction. The outer mitochondrial membrane marker, monoamine oxidase, was not affected by digitonin in the outer mitochondrial membrane marker, monoamine oxidase, was not affected by digitonin in the out mitochondrial membrane preparation, in agreement wit its behavior in microsomes. With the exception of NADH cytochrome c reductase (which was concentrated in the outer mitochondrial membrane preparation), typical microsomal enzymes (glucose-6-phosphatase, esterase, and NADPH cytochrome c reductase) displayed low specific activities in the three preparations; except for part of the glucose-6-phosphatase activity in the plasma membrane preparation, their density distributions were insensitive to digitonin, as they were in microsomes. The influence of digitonin on equilibrium densities was correlated with its morphological effects. Digitonin induced pseudofenestrations in plasma membranes. In Golgi and outer mitochondrial membrane preparations, a few similarly altered membranes were detected in subfractions enriched with 5'-nucleotidase and alkaline phosphodiesterase I. The alterations of Golgi membranes were less obvious and seemingly restricted to some elements in the Golgi preparation. No morphological modification was detected in digitonin-treated outer mitochondrial membranes. These results indicate that each enzyme is associated with the same membrane entity in all membrane preparations and support the view that there is little overlap in the enzymatic equipment of the various types of cytomembranes.     

Cellulose and Callose Biosynthesis in Higher Plants (I. Solubilization and Separation of (1->3)- and (1->4)-[beta]-Glucan Synthase Activities from Mung Bean)

(1->3)- and (1->4)-[beta]-glucan synthase activities from higher plants have been physically separated by gel electrophoresis in nondenaturing conditions. The two glucan synthases show different mobilities in native polyacrylamide gels. Further separation by sodium dodecyl sulfate-polyacrylamide gel electrophoresis revealed a different polypeptide composition in these synthases. Three polypeptides (64, 54, and 32 kD) seem to be common to both synthase activities, whereas two polypeptides (78 and 38 kD) are associated only with callose synthase activity. Twelve polypeptides (170, 136, 108, 96, 83, 72, 66, 60, 52, 48, 42, and 34 kD) appear to be specifically associated with cellulose synthase activity. The successful separation of (1->3)- and (1->-4)-[beta]-glucan synthase activities was based on the manipulation of digitonin concentrations used in the solubilization of membrane proteins. At low dipitomin concentrations (0.05 and 0.1%), the ratio of the cellulose to callose synthase activity was higher. At higher digitonin (0.5-1%) concentrations, the ratio of the callose to cellulose synthase activity was higher. Rosette-like particles with attached product were observed in samples taken from the top of the stacking gel, where only cellulose was synthesized. Smaller (nonrosette) particles were found in the running gel, where only callose was synthesized. These findings suggest that a higher level of subunit organization is required for in vitro cellulose synthesis in comparison with callose assembly.     

Inactivation and activation of various membranal enzymes of the cholesterol biosynthetic pathway by digitonin

The activity of rat liver microsomal squalene epoxidase is inhibited effectively by digitonin. Concentrations of 0.8 to 1.2 mg/ml of digitonin cause total inhibition of microsomal (0.75 mg protein/ml) squalene epoxidase either in microsomes that were pretreated with digitonin and subsequently washed and subjected to epoxidase assay or when digitonin was added directly to the assay. The inhibition of squalene epoxidase by digitonin is concentration-dependent and takes place rapidly within 5 min of exposure of the microsomes to digitonin. Octylglucoside, dimethylsulfoxide, CHAPS, as well as cholesterol or total microsomal lipid extract were ineffective in restoring the digitonin-inhibited squalene epoxidase activity. Epoxidase activity in digitonin-treated microsomes was fully restored by Triton X-100. The reactivation by Triton X-100 displays a concentration optimum with maximal reactivation of the epoxidase (0.7 mg protein/ml) occurring at 0.2% Triton X-100. Microsomal 2,3-oxidosqualene-lanosterol cyclase is also inhibited by digitonin. Higher concentrations of digitonin are required to obtain full inhibition of the cyclase activity and only 40% inhibition of cyclase activity is observed at 1 mg/ml of digitonin. Solubilized (subunit size 55 to 66 kDa) and microsomal (subunit size 97 kDa) 3-hydroxy-3-methylglutaryl CoA reductase are totally unaffected by the same concentration of digitonin. Squalene synthetase, another microsomal enzyme in the biosynthetic pathway of cholesterol, is activated by digitonin. A 2.2-fold activation of squalene synthetase is observed at 0.8 mg/ml of digitonin. The results agree with a model in which squalene, and to a lesser degree 2,3-oxidosqualene, are segregated by digitonin into separate intramembranal pools.(ABSTRACT TRUNCATED AT 250 WORDS)     

A 55 kDa plasma membrane-associated polypeptide is involved in beta-1,3-glucan synthase activity in pea tissue

By glycerol gradient centrifugation of a detergent-solubilized plasma membrane fraction from pea tissue, we find a polypeptide of 55 kDa that copurifies with beta-1,3-glucan synthase activity. An antiserum against this polypeptide adsorbs glucan synthase activity and the 55 kDa polypeptide from digitonin-solubilized plasma membrane. These results indicate that the 55 kDa polypeptide is involved in pea beta-1,3-glucan synthase activity.     

A calmodulin-stimulated Ca2+ pump in rat aorta plasma membranes

An ATP-driven Ca2+-transport system has been characterized in a microsomal fraction from rat aorta. Calmodulin enhanced 2.5-fold 45Ca accumulation by EGTA-treated microsomes incubated with 10 microM Ca2+ (in the absence of oxalate) by increasing markedly the apparent affinity of the transport system for Ca2+. The ionophore A23187 induced a rapid release of the sequestered 45Ca. The vesicles that took up 45Ca were distributed like plasmalemmal marker enzymes when the microsomal fraction was subfractionated by density gradient centrifugation. In particular, these vesicles were markedly shifted towards higher equilibrium densities after addition to the microsomes of 0.2 mg digitonin/mg protein before isopycnic centrifugation. We conclude that the calmodulin-stimulated Ca2+ pump associated with the microsomal fraction is located in plasmalemmal elements.     

Purification of 1,3-β-Glucan Synthase from Neurospora crassa by Product Entrapment

Awald, P., Zugel, M., Monks, C., Frost, D., and Selitrennikoff, C. P. 1993. Purification of 1,3-β-glucan synthase from Neurospora crassa by product entrapment. Experimental Mycology, 17, 130-141. 1,3-β-Glucan synthase activity of the ascomycete Neurospora crassa was purified ∼700-fold from hyphae. Hyphae were disrupted by bead-beating, and membrane-enriched fractions were obtained by high-speed centrifugation. Membranes were treated with (3-[(3-cholamidopropyl)dimethyl-ammoniol]I-propanesulfonate) and octyl-β-D-glucoside to solubilize enzyme activity. Soluble glucan synthase activity was incubated with substrate (UDP-glucose) and purified by centrifugation of enzyme associated with glucan (product entrapment). Purification was specific for UDP-glucose, the optimal concentration being 0.25 mM; no other nucleotide diphosphate sugar was able to significantly product-entrap enzyme activity. Partially purified enzyme activity formed β(1,3)-linked glucan, had a mean specific activity of 1900 nmol glucose incorporated/min/mg protein, a K_m,app of 0.7 mM, and a V_max of 0.5 nmol glucose incorporated/min. Separation of partially purified enzyme activity by SDS-PAGE showed a number of proteins copurifying with enzyme activity; computer analysis of digitized gel images revealed that proteins of 21, 25, 28, 45, 53, and 78 kDa were enriched. These results reinforce the view that 1,3-β-glucan synthase activity of fungi is a multimeric enzyme.     

A single step separation of PS 1, PS 2 and chlorophyll-antenna particles from spinach chloroplasts

After solubilization of photosynthetic membranes by digitonin, three main protein pigment complexes were isolated by electrophoresis with deoxycholate as detergent.The band with the slowest mobility, fraction 1, had PS 1 activity and was devoid of PS 2 activity. This fraction was four times enriched in P700 when compared with chloroplasts. Fraction 1 had little chl b, a long wavelength absorption maximum in the red, a maximum of low temperature emission fluorescence at 730nm, and a circular dichroism spectrum characteristic of PS 1 enriched fraction.Fraction 2 exhibited a PS 2 activity and no PS 1 activity. It was enriched five times in PS 2 reaction centre and had little chl b and carotenoids. The absorption maximum was at 674 nm and the low temperature fluorescence emission maximum was at 700 nm. Fraction 2 might be useful PS 2 enriched particle because of the great stability of this fraction with regard to photochemical activity and also rapidity and simplicity of its preparation.Fraction 3, which had the fastest migration, was devoid of photochemical activities; It was rich in chl b and had the fluorescence and the circular dichroism spectrum characteristic of an antenna complex.Abbreviations PS 1 (2) photosystem 1 (2) - chl chlorophyll - car carotenoid - Q primary plastoquinone electron acceptor - P700 primary electron donor of PS 1 - P680 primary electron donor of PS 2 - K₃Fe(CN)₆ potassium ferricyanide - DCMU dichlorophenyldimethylurea - DCPIP dichlorophenolindophenol - DPC diphenyl-carbazide     

Membrane fractionation and enrichment of callose synthase from pollen tubes of Nicotiana alata Link et Otto

The callose synthase (UDP-glucose: 1,3-β-d-glucan 3-β-d-glucosyl transferase; EC 2.4.1.34) enzyme (CalS) from pollen tubes of Nicotiana alata Link et Otto is responsible for developmentally regulated deposition of the cell wall polysaccharide callose. Membrane preparations from N. alata pollen tubes grown in liquid culture were fractionated by density-gradient centrifugation. The CalS activity sedimented to the denser regions of the gradient, approximately 1.18 g · ml⁻¹, away from markers for Golgi, endoplasmic reticulum and mitochondria, and into fractions enriched in ATPase activity and in membranes staining with phosphotungstic acid at low pH. This suggests that pollen-tube CalS is localised in the plasma membrane. Callose synthase activity from membranes enriched by downward centrifugation was solubilised with digitonin, which gave a 3- to 4-fold increase in enzyme activity, and the solubilised activity was then enriched a further 10-fold by product entrapment. The complete procedure gave final CalS specific activities up to 1000-fold higher than those of pollen-tube homogenates. Sodium dodecyl sulfate-polyacrylamide gel electrophoresis showed that several polypeptides co-fractionated with CalS activity through purification, with a polypeptide of 190 kDa being enriched in product-entrapment pellets. Received: 24 September 1997 / Accepted: 12 November 1997     

Lipid composition of different preparations of brain Na+, K+-ATPase

The content and composition of phospholipids is determined in beef microsomal and synaptosomal fractions and also in these fractions preparations solubilized with triton X-100 (0.1%) and digitonin (0.2%). It is shown that the microsomal fraction is richer in phospholipids. The solubilized fragments of microsomes have less or the same amount of phospholipids per protein unit than the initial fraction of microsomes, and the solubilized fragments of synaptosomes contain a higher quantity of phospholipids than the initial fraction. The content of phospholipids in "the riton" fragments of synaptosomes is higher than in "those" of microsomes. Contrary to digitonin which solubilizes the active Na+, K+-ATPase complex of microsomes and synaptosomes, triton X-100 solubilizes the active enzyme of microsomes only. A higher total content of phospholipids in "the triton" extracts of synaptosomes does not probably correlate with the presence of Na+, K+-ATPase activity in them. But these extracts are found to contain less phosphatidylserine whose addition recovers Mg2+, Na+, K+-ATPase activity in them. The effect of phosphatidylserine is not strictly specific for "the triton" extracts of synaptosomes, this lipid activates to a definite extent the extracts of microsomes as well. It is shown that at the first stages of bull brain Na+, K+-ATPase purification the total content of phospholipids and cholesterol in the preparations increases but the composition of phospholipids remains unchanged.     

Enrichment of Triadic and Terminal Cisternae Vesicles from Rabbit Skeletal Muscle

An enriched triad and terminal cisternae preparation was achieved from skeletal muscle through alterations of the differential centrifugation and muscle homogenization protocols. Both yield and specific activity (pmoles of radioligand binding per mg protein) were optimized for ³H-PN200-l10 (transverse tubule marker) and ³H-ryanodine (terminal cisternae marker) binding sites. By pelleting crude microsomes between 2,000 an 12,000 × g without any rehomogenizations, we improved both the yield and specific activity of transverse tubule and terminal cisternae markers in crude microsomes by approximately 4-fold to 1000–3000 pmoles binding sites (starting material: approximately 400 grams wet weight fast twitch skeletal muscle), with 10–15 pmoles/mg. Rehomogenization of the 1,000 × g pellet, which is typically discarded, allowed recovery of an additional 5000 pmoles PN200-110 binding sites and an additional 8000 pmoles ryanodine binding sites. Crude microsomes from the rehomogenized 1,000 × g pellets typically displayed specific activities of 20–25 pmoles binding/mg for both ³H-PN200-110 and ³H-ryanodine. Separation of crude microsomes on a sucrose gradient increased specific activity up to a maximum of 50 pmoles/mg in a specific fraction, a five- to ten-fold increase over standard triadic or terminal cisternae preparations. The mean specific activity for enriched triads was 30–40 pmoles/mg for both PN200-110 and ryanodine in pooled fractions, while pooled fractions of enriched terminal cisternae displayed low ³H-PN200-110 binding (3–5 pmoles/mg) and high ³H-ryanodine-specific activity (30–40 pmoles/mg).     

A comparison of microbody membranes with microsomes and mitochondria from plant and animal tissue

Microbodies (peroxisomes and glyoxysomes), mitochondria, and microsomes from rat liver, dog kidney, spinach leaves sunflower cotyledons, and castor bean endosperm were isolated by sucrose density-gradient centrifugation. The microbody-limiting membrane and microsomes each contained NADH-cytochrome c reductase and had a similar phospholipid composition. NADH-cytochrome c reductase from plant and animal microbodies and microsomes was insensitive to antimycin A, which inhibited the activity in the mitochondrial fractions. The pH optima of cytochrome c reductase in plant microbodies and microsomes was 7.5–9.0, which was 2 pH units higher than the optima for the mitochondrial form of the enzyme. The activity in animal organelles exhibited a broad pH optimum between pH 6 and 9. Rat liver peroxisomes retained cytochrome c reductase activity, when diluted with water, KCl, or EDTA solutions and reisolated. Cytochrome c reductase activity of microbodies was lost upon disruption by digitonin or Triton X-100, but other peroxisomal enzymes of the matrix were not destroyed. The microbody fraction from each tissue also contained a small amount of NADH-cytochrome b₅ reductase activity. Peroxisomes from spinach leaves were broken by osmotic shock and particles from rat liver by diluting in alkaline pyrophosphate. Upon recentrifugation liver peroxisomes yielded a core fraction containing urate oxidase at a sucrose gradient density of 1.23 g × cm⁻³, a membrane fraction at 1.17 g × cm⁻³ containing NADH-cytochrome c reductase, and soluble matrix enzymes at the top of the gradient.     

Evidence for a UDP-Glucose Transporter in Golgi Apparatus-Derived Vesicles from Pea and Its Possible Role in Polysaccharide Biosynthesis

The Golgi apparatus in plant cells is involved in hemicellulose and pectin biosynthesis. While it is known that glucan synthase I is responsible for the formation of [beta]-l-4-linked glucose (Glc) polymers and uses UDP-Glc as a substrate, very little is known about the topography of reactions leading to the biosynthesis of polysaccharides in this organelle. We isolated from pea (Pisum sativum) stems a fraction highly enriched in Golgi apparatus-derived vesicles that are sealed and have the same topographical orientation that the membranes have in vivo. Using these vesicles and UDP-Glc, we reconstituted polysaccharide biosynthesis in vitro and found evidence for a luminal location of the active site of glucan synthase I. In addition, we identified a UDP-Glc transport activity, which is likely to be involved in supplying substrate for glucan synthase I. We found that UDP-Glc transport is protein mediated. Moreover, our results suggest that UDP-Glc transport is coupled to the exit of a luminal uridine-containing nucleotide via an antiporter mechanism. We suggest that UDP-Glc is transported into the lumen of Golgi and that Glc is transferred to a polysaccharide chain, whereas the nucleotide moiety leaves the vesicle by an antiporter mechanism.     

Chitin and β(1–3) glucan synthases in the protoplastic entomophthorales

(1–3) glucan and chitin synthases were studied in spontaneously produced protoplasts and in the mycelium (hyphal body) of the entomopathogenic Entomophthorale species Entomophaga aulicae, Conidiobolus obscurus and Entomophthora muscae. The absence of wall in protoplasts was correlated to an absence of chitin synthase and to a very low (1–3) glucan synthase activity, whereas these two polysaccharide synthases were present and active in the walled hyphal bodies. Physicochemical properties of chitin and (1–3) glucan synthases such as localization, optimum pH and temperature, activation by disaccharides and proteases were similar to those found in other fungi unable to spontaneously produce protoplasts and could not be related to the ability for protoplastic Entomophthorale species to produce and proliferate under a protoplast form. The absence or the low chitin and glucan synthase activites in Entomophthorale protoplasts was not due to an absence of proteolytic activation of the enzyme. However, all protoplast fractions contained inhibitory substances of glucan and chitin synthase activities. These inhibitors were stable and specific of the protoplast stage. They were not glucanase nor chitinase. These results suggest that the absence of wall synthesis in Entomophthorale protoplasts is due to a continuous inhibition of (1–3) glucan and chitin synthase activities by intracellular compounds and also for glucan synthase by protoplast medium constituents such as NaCl and fetal calf serum.Abbreviations BSA bovine serum albumin - DFP diisopropylfluorophosphate - EDTA ethylenediamine tetraaoetic acid - FCS fetal calf serum - GlcNAc N-acetylglucosamine - TCA trichloroacetic acid - 2 k pellet 2,000 g wall fraction - 140 k pellet 140,000 g particulate fraction - 140 k supernatant 140,000 g soluble fraction