Study of 2.5S RNA of 1,4-alpha-glucan branching enzyme by fluorescent methods using ethidium bromide

The fluorescence yield and lifetime of ethidium bromide complexes with 1,4-alpha-glucan branching enzyme and its free nucleic acid component 2.5S RNA were measured. Both fluorescence parameters showed a 10-fold increase in comparison with those characteristics for the free dye. This increase allows to suggest the existence of double-stranded regions in 2.5S RNA both in the free as well as in the protein bound state. The coefficients of fluorescence polarization were also determined for ethidium bromide complexed with free and protein bound 2.5S RNA. They proved to be 13 and 18% respectively. No concentration depolarization was observed in both types of ethidium bromide and ethidium bromide--enzyme--RNA complexes. This proves that the double-stranded regions are rather short and that two ethidium bromide molecules can't be bound to each of them. The binding isotherms were measured for ethidium bromide absorbed on 2.5S RNA and on the holoenzyme. Their parameters napp and rmax are identical in the cases of free and protein bound 2,5S RNA (rmax = 0.046 +/- 0.001). However the binding constants of ethidium bromide complexes with free and protein bound 2.5S RNA differ significantly (Kapp = 2.2 X 10(6) M-1 for free 2.5S RNA and Kapp = 1.6 X 10(6) M-1 for the holoenzyme). The quantity of nucleotides involved in the two double-stranded regions accessible for ethidium binding is estimated to be about 28%. Increasing of Mg2+ ion concentration up to 10(-3) results in a decrease of ethidium bromide binding with double stranded regions. It may be due to a more compact tertiary structure of 2.5S RNA in the presence of Mg2+ in the free as well as in protein bound state.     

Isolation and characterization of glycogen branching enzyme from rabbit liver

Glycogen branching enzyme was isolated from rabbit liver. The highly purified enzyme shows a monomer molecular weight of 71 000 by sodium dodecyl sulfate-polyacrylamide gel electrophoresis and apparent molecular weights of 93 000 by sucrose density gradient sedimentation and 52 000 by gel-exclusion chromatography on Sephacryl S-300. No glucosamine, mannosamine, galactosamine, or sialic acid was detected in the protein. An amino acid analysis is reported. The spectrum of branching enzyme is that of a simple polypeptide, with A1%280nm = 24.6. Highly purified branching enzyme consists of several closely related active enzyme forms that can be resolved by isoelectric focusing in polyacrylamide gel. The major species of pI 5.7 is flanked by less abundant forms of pI 5.6 and 5.8. Seemingly identical enzyme forms are observed in crude extracts of rabbit liver, skeletal muscle, brain, and heart, although the absolute and relative concentrations vary among the tissues. Branching enzyme apparently does not exhibit tissue-specific isoenzymes.     

Toward automated nucleic acid enzyme selection.

Methods for automation of nucleic acid selections are being developed. The selection of aptamers has been successfully automated using a Biomek 2000 workstation. Several binding species with nanomolar affinities were isolated from diverse populations. Automation of a deoxyribozyme ligase selection is in progress. The process requires eleven times more robotic manipulations than an aptamer selection. The random sequence pool contained a 5' iodine residue and the ligation substrate contained a 3' phosphorothioate. Initially, a manual deoxyribozyme ligase selection was performed. Thirteen rounds of selection yielded ligators with a 400-fold increase in activity over the initial pool. Several difficulties were encountered during the automation of DNA catalyst selection, including effectively washing bead-bound DNA, pipetting 50% glycerol solutions, purifying single strand DNA, and monitoring the progress of the selection as it is performed. Nonetheless, automated selection experiments for deoxyribozyme ligases were carried out starting from either a naive pool or round eight of the manually selected pool. In both instances, the first round of selection revealed an increase in ligase activity. However, this activity was lost in subsequent rounds. A possible cause could be mispriming during the unmonitored PCR reactions. Potential solutions include pool redesign, fewer PCR cycles, and integration of a fluorescence microtiter plate reader to allow robotic 'observation' of the selections as they progress.     

The dNTPase enzyme activity is inhibited by nucleic acids and contains a heat-insensitive component

The dNTpase enzyme has previously been shown to specifically hydrolyse monodeoxyribonucleoside triphosphates (dNTPs). The remnant nucleotide resulting from this hydrolysis lacks the terminal phosphate and is covalently attached as part of a 3 kDa species, which we have termed the product nucleotide binding particle or "PNBP." PNBP is resistant to numerous nucleases and RNases, suggesting that it is not a nucleic acid polymer. Given that the exclusive specificity of dNTPase for dNTPs suggests some associative cellular role for the enzyme in polynucleotide maintenance, the interaction of dNTPase with various nucleic acids has now been examined. It is demonstrated that dNTPase activity is significantly inhibited by addition of single-stranded DNA or tRNA, but not rRNA. The data presented also suggest that thio-dATP can substitute for conventional phosphoester dATP in the enzymatic reaction. It is also demonstrated that the dNTPase enzyme comprises both heat/proteolysis/denaturant stable and heat/proteolysis/denaturant-sensitive components and we propose that this stable component may be the precursor to liganded PNBP.     

Procedure for the simultaneous large-scale isolation of pullulanase and 1,4-alpha-glucan phosphorylase from Klebsiella pneumoniae involving liquid-liquid separations.

A procedure for the simultaneous large-scale isolation of pullulanase and 1,4-alpha-glucan phosphorylase from Klebsiella pneumoniae is described. The pullulanase is solubilized from the cell wall by cholate treatment; cells and cell debris are removed by partition in a poly(ethylene glycol) (PEG)-dextran two-phase system and from the upper (PEG) phase of this system the pullulanase is isolated by ultrafiltration and precipitation with N-cetyl,N-,N-,N-trimethyl ammonium bromide to a purity of about 80% with a yield of 70%. The preparations are free of alpha-amylase activity. The cell containing dextran-rich phase is passed through a Manton-Gaulin homogenizer. Then the phosphorylase is separated from the cell debris by partition in a second PEG-dextran system. From the top phase of this system the phosphorylase is isolated by distribution in a PEG-salt two-phase system followed by batch adsorption on carboxymethyl-Sephadex in a yield of 55%, a purity of around 90%, and nearly free of glycosyltransferase activity. All steps in the isolation of the two enzymes can be performed easily in a large scale.     

血管内膜增生过程中核酸代谢相关酶活性变化的研究

目的和方法：应用血管内皮剥脱后再狭窄模型,动态观察胸腹主动脉壁核膜核苷三磷酸酶及核酸代谢和糖代谢相关酶5’—核苷酸酶、腺苷脱氨酶和琥珀酸脱氢酶活性的变化。探讨其与血管平滑肌细胞增生和新生内膜形成的关系。结果：血管内皮剥脱后,胸腹主动脉壁核膜核苷三磷酸酶活性持续升高,与血管内膜增厚程度相平行;血管平滑肌细胞收缩型标志蛋白α-肌动蛋白表达降低及合成型标志蛋白骨桥蛋白表达上调,说明血管平滑肌细胞发生了表型转化,由分化型转变成为去分化型;5’核苷酸酶、腺苷脱氨酶和琥珀酸脱氢酶活性表现为先升后降,三种酶活性均于血管平滑肌细胞增殖旺盛期(术后3～7d)达峰值。结论：细胞内参与mRNA转运及糖、核酸代谢的一系列酶活性的变化是新生内膜形成的生化基础。     

Pyrophosphate-condensing activity linked to nucleic acid synthesis.

In some preparations of DNA dependent RNA polymerase a new enzymatic activity has been found which catalyzes the condensation of two pyrophosphate molecules, liberated in the process of RNA synthesis, to one molecule of orthophosphate and one molecule of Mg (or Mn) - chelate complex with trimetaphosphate. This activity can also cooperate with DNA-polymerase, on condition that both enzymes originate from the same cells. These results point to two general conclusions. First, energy is conserved in the overall process of nucleic acid synthesis and turnover, so that the process does not require an energy influx from the cell's general resources. Second, the synthesis of nucleic acids is catalyzed by a complex enzyme system which contains at least two separate enzymes, one responsible for nucleic acid polymerization and the other for energy conservation via pyrophosphate condensation.     

The complete amino acid sequence of the human transglutaminase K enzyme deduced from the nucleic acid sequences of cDNA clones.

In order to study the expression and role of transglutaminases in the formation of the cross-linked cell envelope of human epidermis, we have used a synthetic oligonucleotide encoding the consensual active site sequence of known transglutaminase sequences. By Northern blot analysis, newborn foreskin epidermis expresses three different mRNA species of about 3.7, 3.3, and 2.9 kilobases while normal cultured epidermal keratinocytes express only the 3.7- and 2.9-kilobase species. The largest species corresponds to a known ubiquitous tissue type II or transglutaminase C activity, the smallest corresponds to a known type I or transglutaminase K activity, and the mid-sized component apparently encodes a transglutaminase E activity that has recently been shown to be expressed in terminally differentiating epidermis (Kim, H. C., Lewis, M. S., Gorman, J. L., Park, S. C., Girard, J. E., Folk, J. E. & Chung, S. I. (1990) J. Biol. Chem., in press). Using the active site oligonucleotide as a probe, we have isolated and sequenced cDNA clones encoding the transglutaminase K enzyme. The deduced complete protein sequence has 813-amino acid residues of 89.3 kDa, has a pl of 5.7, and is likely to be an essentially globular protein, which are properties expected from the partially purified enzyme. It shares 49-53% sequence homology with the other transglutaminases of known sequence, especially in regions carboxyl-terminal to the active site, and possesses sequences likely to confer its Ca2+ dependence. Interestingly, its larger size is due to extended sequences on its amino and carboxyl termini, absent on the other transglutaminases, that may define its unique properties.     

Comparison of starch branching enzyme I and II from potato.

The in vitro activities of purified potato starch branching enzyme (SBE) I and II expressed in Escherichia coli were compared using several assay methods. With the starch-iodine method, it was found that SBE I was more active than SBE II on an amylose substrate, whereas SBE II was more active than SBE I on an amylopectin substrate. Both enzymes were stimulated by the presence of phosphate. On a substrate consisting of linear dextrins (chain length 8-200 glucose residues), no significant net increase in molecular mass was seen on gel-permeation chromatography after incubation with the enzymes. This indicates intrachain branching of the substrate. After debranching of the products, the majority of dextrins with a degree of polymerization (dp) greater than 60 were absent for SBE I and those with a dp greater than 70 for SBE II. To study the shorter chains, the debranched samples were also analysed by high-performance anion-exchange chromatography. The products of SBE I showed distinct populations at dp 11-12 and dp 29-30, whereas SBE II products had one, broader, population with a peak at dp 13-14. An accumulation of dp 6-7 chains was seen with both isoforms.     

Studies on the activity of aldolase from rabbit muscles in the presence of liposomes]

Electronmicroscopic studies have been made on the structure of liposomes obtained by the method of Bangham [13] with subsequent ultrasonic desintegration. The effect of muscle aldolase on the structure of liposomes was also investigated. Parallel studies were made on the effect of storage of liposomes upon the activity of aldolase. It was shown that liposomes obtained from chromatographically pure egg lecithin present discrete partially aggregated bodies, 1.000-3.000 A in size, composed by concentric layers, which have a dimension of approximately 40 A and periodicity of about 70 A. Interaction of these particles with the protein results into their desintegration and enlargement, this process being accompanied by the formation of a "fringe" at the edge of the particles. Aldolase activity in these systems in higher than in control. During storage of phosphatide-aqueous system, obtained by the metod of Bungenberg de Jong, activation of aldolase is gradually replaced by its inactivation.     

Properties and active center of the thermostable branching enzyme from Bacillus stearothermophilus.

Although the branching enzyme (EC 2.4.1.18) is a member of the alpha-amylase family, the characteristics are not understood. The thermostable branching enzyme gene from Bacillus stearothermophilus TRBE14 was cloned and expressed in Escherichia coli. The branching enzyme was purified to homogeneity, and various enzymatic properties were analyzed by our improved assay method. About 80% of activity was retained when the enzyme was heated at 60 degrees C for 30 min, and the optimum temperature for activity was around 50 degrees C. The enzyme was stable in the range of pH 7.5 to 9.5, and the optimum pH was 7.5. The nucleotide sequence of the gene was determined, and the active center of the enzyme was analyzed by means of site-directed mutagenesis. The catalytic residues were tentatively identified as two Asp residues and a Glu residue by comparison of the amino acid sequences of various branching enzymes from different sources and enzymes of the alpha-amylase family. When the Asp residues and Glu were replaced by Asn and Gln, respectively, the branching enzyme activities disappeared. The results suggested that these three residues are the catalytic residues and that the catalytic mechanism of the branching enzyme is basically identical to that of alpha-amylase. On the basis of these results, four conserved regions including catalytic residues and most of the substrate-binding residues of various branching enzymes are proposed.     

Limited proteolysis of branching enzyme from Escherichia coli

Branching enzyme is involved in determining the structure of starch and glycogen. It catalyzes the formation of branch points by cleavage and transfer of alpha-1,4-glucan chains to alpha-1,6 branch points. Branching enzyme belongs to the amylolytic family of enzymes containing four conserved regions in a central (alpha/beta)8-barrel. Limited proteolysis of the branching enzyme from Escherichia coli (84 kDa) by proteinase K produced a truncated protein of 70-kDa, which still retained 40-60% of branching activity, depending on the type of assay used. Amino acid sequencing showed that the 70-kDa protein lacked 111 or 113 residues at the amino terminal, whereas the carboxy terminal was still intact. We purified this truncated enzyme to homogeneity and analyzed its properties. The enzyme had a three- to fourfold lower catalytic efficiency than the native enzyme, whereas the substrate specificity was unaltered. Furthermore, a branching enzyme with 112 residues deleted at the amino terminal was constructed by recombinant technology and found to have properties identical to those of the proteolyzed enzyme.