Acceptor stem and anticodon RNA hairpin helix interactions with glutamine tRNA synthetase

The class I glutamine (Gln) tRNA synthetase interacts with the anticodon and acceptor stem of glutamine tRNA. RNA hairpin helices were designed to probe acceptor stem and anticodon stem-loop contacts. A seven-base pair RNA microhelix derived from the acceptor stem of tRNA^Gln was aminoacylated by Gln tRNA synthetase. Variants of the glutamine acceptor stem microhelix implicated the discriminator base as a major identity element for glutaminylation of the RNA helix. A second RNA microhelix representing the anticodon stem-loop competitively inhibited tRNA^Gln charging. However, the anticodon stem-loop microhelix did not enhance aminoacylation of the acceptor stem microhelix. Thus, transduction of the anticodon identity signal may require covalent continuity of the tRNA chain to trigger efficient aminoacylation.     

Purification and characterization of a mutant tRNA nucleotidyltransferase

tRNA nucleotidyltransferase has been extensively purified from a mutant strain of Escherichia coli which displays greatly decreased AMP incorporation, but normal CMP incorporation. The defect in AMP incorporation is retained throughout the purification of the mutant protein. The mutant protein behaves identically to the wild-type protein with regard to elution position on various chromatographic columns, and both have similar molecular weights of about 50000. The defect in the mutant protein is accentuated by the use of yeast tRNA rather than E. coli tRNA-C--C as substrate, by decreased pH, by increased ionic strength and by decreased divalent cation concentration. Substitution of MN2+ for Mg2+ greatly increases the relative activity of the mutant enzyme. In all these cases, CMP incorporation by the mutant enzyme remains the same as the wild-type enzyme. The Km values of the mutant enzyme for its tRNA and triphosphate substrates are unchanged, and the mutant protein is as stable as the wild type with respect to temperature inactivation. These results strongly suggest that the mutation is in the structural gene for tRNA nucleotidyltransferase, and that the mutation probably does not affect the overall structure of the mutant protein, but only a localized region near the AMP-incorporating site.     

Comparison of porcine liver tRNA preparations: Purification of tRNA and its separation from RNA-peptidyl complexes

Six fractions of soluble RNA were obtained from phenol extracts of porcine liver and were tested for their acceptance of 14 amino acids under aminoacylation conditions and for their effects on the aminoacylation of tRNA. Two of the fractions contained appreciable amounts of tRNA, and three of the fractions affected the aminoacylation of tRNA. Based on these observations a revised method of tRNA preparation was developed that includes essentially all the tRNA in one fraction but that excludes the RNA-peptidyl complexes. The revised method is rapid and convenient and provides better quality tRNA than three alternate methods to which it is compared.     

Purification and some properties of Escherichia coli tRNA nucleotidyltransferase.

Adenylyl (cytidylyl)-tRNA nucleotidyltransferase (ATP (CTP): tRNA adenylyl (cytidylyl)transferase, EC2.7.7.25) has been purified 11,800-fold from a crude extract of Escherichia coli B in an overall yield of 23%. The key step in this purification is the use of a tRNA-Sepharose affinity column. The purified enzyme has a specific activity of approximately 280 mumol of AMP incorporated/min/mg of protein at 37 degrees and has a molecular weight of 52,000 as determined by sodium dodecyl sulfate gel electrophoresis of Sephadex chromatography. The turnover number of the pure enzyme, under optimal assay conditions, is estimated as 21,000, and we believe it constitutes only o.oo6% of the total cellular protein. Both AMP- and CMP-incorporating activities have an identical isoelectric point of 5.85. The AMP-incorporating activity of the enzyme is inhibitied by some transition metal chelating agents but not by others.     

大肠杆菌tRNA~(Leu)的提取、纯化及性质研究

采用高表达大肠杆菌ｔＲＮＡＬｅｕ菌株提取、纯化了亮氨酸等受体转移核糖核酸ｔＲＮＡＬｅｕ１和ｔＲＮＡＬｅｕ２．利用稳态动力学手段研究了ｔＲＮＡＬｅｕ１及脱镁ｔＲＮＡＬｅｕ１在不同稀土离子作用下与纯化亮氨酰－ｔＲＮＡ合成酶的氨酰化作用．ｔＲＮＡＬｅｕ１与亮氨酰－ｔＲＮＡ合成酶的结合及催化效率均受参与稀土离子的影响,表观Ｋｍ值有较明显的变化．结果表明,亮氨酰－ｔＲＮＡ合成酶催化的ｔＲＮＡＬｅｕ１氨酰化反应所需Ｍｇ２＋能够被稀土离子取代,但亲合性能不同．     

Purification Of Mouse and Human Interferons: Detection Of Subunit Structure

During the purification of mouse and human interferons, multiple active components have been detected. Mouse interferon was purified over 500-fold by differential precipitation, centrifugation, gel chromatography, and isoelectric focusing. On electrofocusing, two molecular forms (A and B) were noted. Form B (pI 7.35) had a molecular weight of about 38,000 and Form A (pI 7.15), which was equally active, a molecular weight of 19,000. Purified Form B was dissociable into Form A, but the reverse reaction occurred to a much lesser extent. Human interferon, purified about 1500-fold, is also composed of multiple molecular forms. Form B (pi 5.60) had a molecular weight of about 24,000 and Form A (pi 5.35), which may contain up to 85% of the total activity, a molecular weight of 12,000. Both forms appear to have equal specific activities. The dissociation of both human and mouse interferons into subunits appeared to take place during dialysis versus low salt (0.01 M tris pH 7.A). The data are consistent with the idea that the native molecule exists as a dimer of similar or identical subunits. Dimer formation, which probably occurs within the cells, does not seem to lead to a measurable cooperative effect between the subunits.     

Vitamin B12-dependent Methionine Synthetase in Photosynthetic Bacteria Partial Purification and Properties

Vitamin B₁₂-dependent methionine synthetase (N⁵-methyItetrahydrofolate-homocysteine Bi2-methyltransferase; EC 2.1.1.13) was partially purified from two different types of photo-synthetic bacteria, Chromatium D and Rhodospirillum rubrum.

Chromatium D, which does not produce vitamin B₁₂, possessed apomethionine synthetase when grown in the absence of the vitamin. Partially purified apoenzyme was converted to holoenzyme efficiently with CH₃B₁₂ or OHB₁₂. Holo-methionine synthetase was purified 244 fold with 56.4 % recovery from Chromatium D cells grown with vitamin B₁₂ added. The partially purified enzyme required reductants but was only partially dependent on S-adenosylmethionine.

On the other hand, Rsp. rubrum methionine synthetase which was always present as holoenzyme, in contrast with that of Chromatium D, was purified 40 fold with 2.8% recovery. The obtained preparation required S-adenosylmethionine and reductants for the enzyme activity. The optimal pH of Chromatium D enzyme and of Rsp. rubrum enzyme was in the range of 7.5~7.8 and 6.5~6.75, respectively.     

Purification and properties of tyrosyl tRNA synthetase of rat liver.

Purification of rat liver tyrosine tRNA synthetase yields two protein fractions A and B and both fractions are required for charging of tyrosine to tRNAtyr. Fraction B catalyzes the activation of tyrosine. Fractions A and B have been purified to near homogeneity and they are composed of single polypeptide chains of 62,000 daltons each. Gel filtration studies suggest a molecular weight of 120,000 for the synthetase.     

Purification and characterization of a tRNA methylase from Salmonella typhimurium.

A tRNA methylase, in which supK strains of Salmonella typhimurium are deficient, was purified from strain LT2 and characterized. Column chromatography of protein extracts from wild-type cells on phosphocellulose, diethylaminoethyl-Sephadex A-50, and hydroxlapatite resulted in an enzyme that was estimated to be about 50% pure. tRNA from S. typhimurium which had been incubated at pH 9.0 served as a substrate for this methylase. The enzyme has a molecular weight of about 50,000 as estimated by gel chromatography and by electrophoresis on sodium dodecyl sulfate-polyacrylamide gels. The optimal assay conditions, as well as the kinetics and stability of the enzyme, were studied. As with other tRNA-methylating enzymes, S-adenosylhomocysteine is a potent inhibitor.     

Gene Cloning, Overproduction and Purification of Escherichia coli tRNA_2~(Arg)

合成的编码大肠杆菌ｔＲＮＡＡｒｇ２的基因,嵌入受ＩＰＴＧ诱导启动子控制的质粒ｐＴｒｃ９９Ｂ中。用上述含目的基因的质粒转化大肠杆菌ＭＴ１０２,得到ｔＲＮＡＡｒｇ２基因序列正确的克隆。诱导表达后,与受体菌相比,转化子中的ｔＲＮＡＡｒｇ的含量高出１０倍,ｔＲＮＡＡｒｇ２的含量高出３０倍,占总ｔＲＮＡ的７０％。ＤＥＡＥＳｅｐｈａｃｅｌ柱层析后,ｔＲＮＡＡｒｇ２的纯度即可达到８８％。再用ｂｅｎｚｙｌＤＥＡＥｃｅｌｕｌｏｓｅ柱层析可得到纯度为９９％、精氨酸接受活力为１６００ｐｍｏｌｅ／Ａ２６０单位的ｔＲＮＡＡｒｇ２。从４升过夜培养液中得到的４０ｍｇ总ｔＲＮＡ。从中可得到１８ｍｇ纯ｔＲＮＡＡｒｇ２,产率为６２％。首次精确地测定了精氨酰ｔＲＮＡ合成酶催化ｔＲＮＡＡｒｇ２时的动力学常数。     

Purification and Characterization of Methionine:Glyoxylate Aminotransferase from Brassica carinata and Brassica napus

The first step in the biosynthesis of allylglucosinolate from methionine in Brassica is thought to be the transamination of methionine to 2-keto-4-methylthiobutyrate. By using Q-Sepharose and Red Agarose, followed by high resolution anion exchange chromatography and chromatofocussing, a methionine:glyoxylate aminotransferase (MGAT) was purified to homogeneity from leaves of Brassica carinata var R-4218, and approximately 5000-fold from leaves of Brassica napus var Topas. The final purification was accomplished using nondenaturing polyacrylamide gel electrophoresis. The enzyme has a pl of 4.3, a native molecular mass of 230 to 290 kilodaltons, and a subunit molecular mass of approximately 50 kilodaltons. Four isozymes of the enzyme were identified in the six species of Brassica commonly cultivated. Nonglucosinolate producing species had only low levels of MGAT or an MGAT isozyme which was distinctly different from that in Brassica.     

Purification of potential 3'' processing nucleases using synthetic tRNA precursors.

The synthetic tRNA precursors, tRNA-C-114C]U and tRNA-C-C-A-[14C]C-C, as well as poly (a) and diesterase-treated tRNA, have been used to identify and purify potential 3'processing nucleases. Four activities have been separated by this analysis; and three of them have been characterized. Two of the enzymes, which are well-separated on hydroxylapatite columns, act on poly(A), require K+ and Mg2+ for activity, and have molecular weights of about 90,000. These activities have properties previously ascribed to RNase II. The third enzyme does not act on poly(A), requires Mg2+ for activity, and has a molecular weight of about 60,000. It is identical to RNase D, previously characterized as an exonuclease acting on tRNAs with altered structure. Each of the enzymes can remove nucleotides from the tRNA precursor containing extra nucleotides beyond the 3'terminus, whereas they are relatively inactive with intact tRNA or tRNA-C-U. The greatest specificity was displayed by RNase D. The possibility that RNase D is a 3'processing nuclease is discussed.