EC:2.4.1.18 - FACTA Search

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Query: EC:2.4.1.18 (branching enzyme)
628 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

The properties of the enzymes involved in the initiation of glycogen biosynthesis in Escherichia coli were studied. It was found that the enzymic activities which transfer the glycosyl residues from UDPglucose or ADPglucose for the glucoprotein synthesis had differing stabilities upon storage at 4 degrees C. The small amount of glycogen and the saccharide firmly bound to the membrane preparation, were degraded during the storage period. The activity measured in fresh and in stored preparations gave different time dependence curves. The stored preparation had a lag period which could be due to the transfer of the first glucose units to the protein. Both UDPglucose and ADPglucose : protein glucosyltransferases were affected in different ways by detergents. Based on the results presented, it may be concluded that both enzymatic activities are due to different enzymes. Furthermore, both enzymatic activities are different from that which transfers glucose from ADPglucose to glycogen. The following mechanism for the de novo synthesis is suggested. Glycogen in E. coli could be initiated by two different enzymes which transfer glucose to a protein acceptor either from UDPglucose or ADPglucose. Once the saccharide linked to the protein has reached a certain size it is almost exclusively enlarged by another ADPglucose-dependent enzyme. The participation of branching enzyme will produce a polysaccharide with the characteristics of glycogen.
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PMID:Initiation of glycogen biosynthesis in Escherichia coli. Studies of the properties of the enzymes involved. 41 19

We have studied through the late foetal period of the rat, the evolution of two enzymes involved in glycogen metabolism of the liver : UDPG glycogen synthetase (a and b forms) and branching enzyme. The activities were measured during the development of normal foetuses and of foetuses experimentally deprived of corticosteroids. In normal foetus the activity of glycogen synthetase and the branching enzyme increased progressively between days 18 and 21 ; but the percentage of glycogen synthetase a increased promptly between days 18 and 19. This variation coincides with the beginning of glycogen accumulation in the liver. In foetuses submitted to corticosteroid shortage, the activity of each enzyme, and the amount of glycogen in the liver, were reduced at term. Cortisol given to the decapited foetus restores subnormal glycogen storage and normal activity of branching enzyme. The activity of synthetase a was slightly increased but remained very low ; only synthetase b was restored to normal. It seems that there is no relationship between the synthesis of glycogen, in the foetal rat liver, and the activity of synthetase a.
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PMID:[Control of glycogen biosynthesis in fetal rat liver]. 81 Jan 80

Electron histochemical techniques for glycogen synthetase has been applied to the living retina of the chick and the polyglucose particles synthesized from UDPG in the paraboloid of the accessory cone were compared with those synthesized by the conventional histochemical techniques. In the retina incubated in the medium for glycogen synthetase in vivo, synthesized polyglucose particles were located in the cytoplasmic matrices and most of the particles were less than 200 A in diameter. These particles were rather well stainable with lead citrate and filled the cytoplasmic matrices. However, the tubular structures were not flattened, but slightly dilated. Compared with polyglucose particles synthesized in vitro by glycogen synthetase, those demonstrated by the in vivo histochemical techniques showed closer resemblance to native glycogen particles in size and stainability with lead citrate. The polyglucose particles synthesized from UDPG by glycogen synthetase were apparently different from those synthesized from glucose-1-phosphate by phosphorylase and branching glycosyltransferase.
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PMID:Polyglucose particles histochemically synthesized by glycogen synthetase activity in the living chick retina. 82 86

Neurospora crassa branching enzyme [EC 2.4.1.18] acted on potato amylopectin or amylose to convert them to highly branched glycogen-type molecules which consisted of unit chains of six glucose units. The enzyme also acted on the amylopectin beta-limit dextrin, indicating that the enzyme acted on internal glucose chains as well as outer chains. By the combined action of N. crassa glycogen synthase [EC 2.4.1.11] and the branching enzyme, a glycogen-type molecule was formed from UDP-glucose. In the presence of primer glycogen, the glucose transfer reaction was accelerated by the addition of branching enzyme. On the other hand, the glucose transfer reaction by glycogen synthase did not occur without primers. When the branching enzyme was added, the glucose transfer occurred after a short time lag. This recovery of the glucose transfer reaction did not occur upon addition of the inactivated branching enzyme. The structure of the product formed by the combined action of the two enzymes was different from that of the intact N. crassa glycogen with respect to the distribution patterns of the unit chains.
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PMID:Mode of action of glycogen branching enzyme from Neurospora crassa. 213 54

Consistent with previous results, overexpression of rabbit skeletal muscle glycogen synthase in COS cells did not lead to overaccumulation of glycogen unless activating Ser-->Ala mutations were present at key regulatory phosphorylation sites 2 (Ser7) and 3a (Ser644) in the enzyme. In addition, we found that expression of glycogenin, glycogen branching enzyme, or UDP-glucose pyrophosphorylase alone in COS cells had no effect on the glycogen level. However, coexpression of the hyperactive 2,3a glycogen synthase mutant with either glycogenin or UDP-glucose pyrophosphorylase led to higher glycogen accumulation than that obtained from the expression of glycogen synthase alone. Coexpression of glycogenin with the 2,3a mutant of glycogen synthase led to the appearance of glycogenin with a lower molecular weight suggestive of reduced glucosylation. Increased glycogen synthesis may lead to competition between glycogenin and glycogen synthase for their common substrate UDP-glucose. In summary, we conclude that (i) glycogen synthase is a primary rate-limiting enzyme of glycogen biosynthesis in COS cells, (ii) that phosphorylation of glycogen synthase is regulatory for glycogen accumulation, and (iii) once glycogen synthase is activated, the reaction mediated by UDP-glucose pyrophosphorylase can become rate-determining.
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PMID:Rate-determining steps in the biosynthesis of glycogen in COS cells. 864 5

Rat brain glycogen branching enzyme was partially purified in order to elucidate its mechanism of action. The alpha1,4-alpha1,6-glucan polysaccharide was synthesized using rat brain branching enzyme under two different elongation conditions: Glc-1-P and phosphorylase or UDP-Glc and glycogen synthase. The products obtained demonstrated that the cpolysaccharides synthesized (pattern of the spectra obtained in the presence of Krisman's reagent, lambda max, parameter A and R, % beta-amylolysis and degree of branching) under different incubation times are nearly constant. These results imply that the degree of branching of a polysaccharide depends only on the enzyme specificity.
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PMID:Glycogen brain branching enzyme. 962 Apr 41

Glycogen synthase of bovine retina was found associated with the acid-insoluble and acid-soluble proteoglycogen fractions. The synthase associated with the acid-insoluble proteoglycogen precursor showed an 8-fold lower Km for UDP-glucose than the synthase associated with the acid-soluble fraction, and was inhibited by detergent. A short digestion with pronase resulted in conversion of the acid insoluble fraction into acid-soluble. The results lead us to postulate that the acid-insolubility of the proteoglycogen fraction and the association with retina membrane proposed before, is caused by glycogen synthase strongly associated to its polysaccharide moiety. The enlargement of the polysaccharide moiety during proteoglycogen biosynthesis, from glycogenin linked to a few 11 to 12 glucose units to the acid-insoluble proteoglycogen precursor (Mr 470,000) would be carried out, together with the branching enzyme, by the glycogen synthase showing a low Km for UDP-glucose. The glycogen synthase with the highest Km for UDP-glucose would participate in conversion of the precursor into mature acid-soluble proteoglycogen.
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PMID:Two glycogen synthase activities associated with proteoglycogen in retina. 1068 12

The molecular mechanisms regulating hemicelluloses and pectin biosynthesis are poorly understood. An important question in this regard is how glycosyltransferases are oriented in the Golgi cisternae, and how nucleotide sugars are made available for the synthesis of the polymers. Here we show that the branching enzyme xyloglucan alpha,1-2 fucosyltransferase (XG-FucTase) from growing pea (Pisum sativum) epicotyls was latent and protected against proteolytic inactivation on intact, right-side-in pea stem Golgi vesicles. Moreover, much of the XG-FucTase activity was membrane associated. These data indicate that XG-FucTase is a membrane-bound luminal enzyme. GDP-Fuc uptake studies demonstrated that GDP-Fuc was taken up into Golgi vesicles in a protein-mediated process, and that this uptake was not competed by UDP-Glc, suggesting that a specific GDP-Fuc transporter is involved in xyloglucan biosynthesis. Once in the lumen, Fuc was transferred onto endogenous acceptors, including xyloglucan. GDPase activity was detected in the lumen of the vesicles, suggesting than the GDP produced upon transfer of Fuc was hydrolyzed to GMP and inorganic phosphate. We suggest than the GDP-Fuc transporter and GDPase may be regulators of xyloglucan fucosylation in the Golgi apparatus from pea epicotyls.
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PMID:GDP-fucose uptake into the Golgi apparatus during xyloglucan biosynthesis requires the activity of a transporter-like protein other than the UDP-glucose transporter. 1071 51

Glycogen is an important storage reserve of glucose present in many organisms, from bacteria to humans. Its biosynthesis is initiated by a specialized protein, glycogenin, which has the unusual property of transferring glucose from UDP-glucose to form an oligosaccharide covalently attached to itself at Tyr194. Glycogen synthase and the branching enzyme complete the synthesis of the polysaccharide. The structure of glycogenin was solved in two different crystal forms. Tetragonal crystals contained a pentamer of dimers in the asymmetric unit arranged in an improper non-crystallographic 10-fold relationship, and orthorhombic crystals contained a monomer in the asymmetric unit that is arranged about a 2-fold crystallographic axis to form a dimer. The structure was first solved to 3.4 A using the tetragonal crystal form and a three-wavelength Se-Met multi-wavelength anomalous diffraction (MAD) experiment. Subsequently, an apo-enzyme structure and a complex between glycogenin and UDP-glucose/Mn2+ were solved by molecular replacement to 1.9 A using the orthorhombic crystal form. Glycogenin contains a conserved DxD motif and an N-terminal beta-alpha-beta Rossmann-like fold that are common to the nucleotide-binding domains of most glycosyltransferases. Although sequence identity amongst glycosyltransferases is minimal, the overall folds are similar. In all of these enzymes, the DxD motif is essential for coordination of the catalytic divalent cation, most commonly Mn2+. We propose a mechanism in which the Mn2+ that associates with the UDP-glucose molecule functions as a Lewis acid to stabilize the leaving group UDP and to facilitate the transfer of the glucose moiety to an intermediate nucleophilic acceptor in the enzyme active site, most likely Asp162. Following transient transfer to Asp162, the glucose moiety is then delivered to the final acceptor, either directly to Tyr194 or to glucose residues already attached to Tyr194. The positioning of the bound UDP-glucose far from Tyr194 in the glycogenin structure raises questions as to the mechanism for the attachment of the first glucose residues. Possibly the initial glucosylation is via inter-dimeric catalysis with an intra-molecular mechanism employed later in oligosaccharide synthesis.
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PMID:Crystal structure of the autocatalytic initiator of glycogen biosynthesis, glycogenin. 1205 21

The levels of starch and dextrin, free sugars, soluble protein, and enzymes involved in starch metabolism-alpha-amylase, beta-amylase, phosphorylase, Q-enzyme, R-enzyme, and ADP-glucose starch synthetases-were assayed in the leaf sheaths and culm of the rice plant (Oryza sativa L., variety IR8) during growth.Starch accumulation in the leaf sheaths reached a maximum 10 to 11 weeks after transplanting, the time of development of the rice panicle. Maximal concentration of free sugars occurred earlier. Starch and sugars in the leaf sheaths and culm decreased rapidly during grain development.During starch accumulation, the starch granules of the leaf sheaths increased slightly in size and its gelatinization temperature decreased. The molecular size of amylose and amylopectin and amylose content of the starch were similar in both culm and leaf sheaths.Changes in the level of soluble protein paralleled changes in starch level in the leaf sheaths. Among the enzymes, only synthetase bound to the starch granule paralleled the level of starch in the leaf sheaths and in the culm. ADP-glucose, but not UDP-glucose, was utilized as a glucosyl donor by these starch synthetases. Zymograms of these extracts showed only one alpha-amylase band, one beta-amylase band, two phosphorylase bands, and one Q-enzyme band.
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PMID:Starch metabolism in the leaf sheaths and culm of rice. 1665 31

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