New chromatographic and biochemical strategies for quick preparative isolation of tRNA.
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A combination of hydrophobic chromatography on phenyl-Sepharose and reversed phase HPLC was used to purify individual tRNAs with high specific activity. The efficiency of chromatographic separation was enhanced by biochemical manipulations of the tRNA molecule, such as aminoacylation, formylation of the aminoacyl moiety and enzymatic deacylation. Optimal combinations are presented for three different cases. (i) tRNA(Phe) from Escherichia coli. This species was isolated by a combination of low pressure phenyl-Sepharose hydrophobic chromatography with RP-HPLC. (ii) tRNA(Ile) from E. coli: Aminoacylation increases the retention time for this tRNA in RP-HPLC. The recovered acylated intermediate is deacylated by reversion of the aminoacylation reaction and submitted to a second RP-HPLC run, in which deacylated tRNA(Ile) is recovered with high specific activity. (iii) tRNA(i)(Met) from Saccharomyces cerevisiae. The aminoacylated form of this tRNA is unstable. To increase stability, the aminoacylated form was formylated using E.coli: enzymes and, after one RP-HPLC step, the formylated derivative was deacylated using peptidyl-tRNA hydrolase from E.COLI: The tRNA(i)(Met) recovered after a second RP-HPLC run exhibited electrophoretic homogeneity and high specific activity upon aminoacylation. These combinations of chromatographic separation and biochemical modification can be readily adapted to the large-scale isolation of any particular tRNA. (+info)
Evidence for specific and non-covalent binding of lipids to natural and recombinant Mycobacterium bovis BCG hsp60 proteins, and to the Escherichia coli homologue GroEL.
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Heat-shock proteins (Hsps) from various origins are known to share a conserved structure and are assumed to be key partners in the biogenesis of proteins. Fractionation of the mycobacterial Hsp60, a 65 kDa protein also called Cpn60, from Mycobacterium bovis BCG zinc-deficient culture filtrate on phenyl-Sepharose followed by Western blotting revealed the existence of four Hsp60-1 and Hsp60-2 forms, based on their hydrophobicity behaviour. Hsp60-2 species were further purified by ion-exchange chromatography and partial amino acid sequences of cyanogen bromide (CNBr) peptides of purified Hsp60-2 species showed identity with the amino acid sequence deduced from the hsp60-2 gene, indicating that the various Hsp60-2 forms are encoded by the same gene. In addition, the mycobacterial Hsp60-2 was overexpressed in E. coli using the pRR3Hsp60-2 plasmid and analysed on phenyl-Sepharose. The elution pattern of the recombinant Hsp60-2, as well as that of Escherichia coli GroEL, was similar to that of the native Hsp60-2 from the culture filtrate of M. bovis BCG and entirely different from that of the mycobacterial antigen 85. Extraction of mycobacterial Hsp60-2 forms, recombinant BCG Hsp60-2 and E. coli GroEL with organic solvents releases various amounts of non-covalently bound lipids. The presence of lipids on Hsp60-2 was confirmed by labelling M. bovis BCG with radioactive palmitate. The radioactivity was specifically associated with Hsp60 in the aqueous phase and the 19 and 38 kDa lipoproteins in the Triton X-114 phase. Analysis of the lipids extracted from purified Hsp60-2, recombinant BCG Hsp60-2 and E. coli GroEL by TLC showed the same pattern for all the samples. Acid methanolysis of the lipids followed by GC analysis led to the identification of C(16:0), C(18:0) and C(18:1) as the major fatty acyl constituents, and of methylglycoside in these proteins. Altogether, these data demonstrate that lipids are non-covalently bound to Hsp60-2 and homologous proteins. (+info)
Purification and partial characterization of the hydroxylase component of the methanesulfonic acid mono-oxygenase from methylosulfonomonas methylovora strain M2.
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The reductase enzyme and the hydroxylase enzyme of the three-component methanesulfonic acid mono-oxygenase (MSAMO) from Methylosulfonomonas methylovora were purified. Purification of the reductase from M. methylovora using a range of chromatographic techniques was accompanied by complete loss of activity. Expression of the reductase as a glutathionine S-transferase fusion protein in Escherichia coli cells was successful as judged from the size of the polypeptide band obtained on induction with isopropyl thio-beta-D-galactoside. Subsequent affinity purification of the fusion protein, however, led to a protein extract containing only glutathionine S-transferase protein, indicating that the fusion protein was unstable in vitro. The hydroxylase component of the MSAMO was purified from M. methylovora to near electrophoretic homogeneity using Q-Sepharose, hydroxyapatite and Mono Q chromatography. SDS/PAGE of the purified hydroxylase showed a single band at approximately 43.7 kDa for the alpha-subunit and a double band at approximately 23 kDa for the beta-subunit. MS scans obtained with matrix-assisted laser desorption/ionization and electrospray ionization showed single peaks for both subunits, with a mass of 48 145.4 Da for alpha, 20 479.1 Da for beta, and 68 624.5 for the alphabeta-monomer. Gel filtration revealed a mass of 209 kDa, suggesting an alpha3beta3 structure for the native enzyme. Purified hydroxylase enzyme exhibited absorbance maxima at 330 nm, 460 nm and 570 nm, indicating the presence of iron-sulfur centres. The protein preparations contained 1 mol sulfide and 3-4 mol iron per mol alphabeta-monomer. Chromium, cobalt, copper, lead, nickel, molybdenum, tungsten and vanadium were not found. Flavins were also absent. Antibodies raised against the native hydroxylase enzyme cross-reacted with cell-free extract from M. methylovora cells grown with methanesulfonate, but not with extract from cells grown with methanol, confirming that MSAMO was specifically induced during growth on methanesulfonate. (+info)
A novel action of human apurinic/apyrimidinic endonuclease: excision of L-configuration deoxyribonucleoside analogs from the 3' termini of DNA.
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beta-l-Dioxolane-cytidine (l-OddC, BCH-4556, Troxacitabine) is a novel unnatural stereochemical nucleoside analog that is under phase II clinical study for cancer treatment. This nucleoside analog could be phosphorylated and subsequently incorporated into the 3' terminus of DNA. The cytotoxicity of l-OddC was correlated with the amount of l-OddCMP in DNA, which depends on the incorporation by DNA polymerases and the removal by exonucleases. Here we reported the purification and identification of the major enzyme that could preferentially remove l-OddCMP compared with dCMP from the 3' termini of DNA in human cells. Surprisingly, this enzyme was found to be apurinic/apyrimidinic endonuclease (APE1) (), a well characterized DNA base excision repair protein. APE1 preferred to remove l- over d-configuration nucleosides from 3' termini of DNA. The efficiency of removal of these deoxycytidine analogs were as follows: l-OddC > beta-l-2',3'-dideoxy-2', 3'-didehydro-5-fluorocytidine > beta-l-2',3'-dideoxycytidine > beta-l-2',3'-dideoxy-3'-thiocytidine > beta-d-2',3'-dideoxycytidine > beta-d-2',2'-difluorodeoxycytidine > beta-d-2'-deoxycytidine >/= beta-d-arabinofuranosylcytosine. This report is the first demonstration that an exonuclease can preferentially excise l-configuration nucleoside analogs. This discovery suggests that APE1 could be critical for the activity of l-OddC or other l-nucleoside analogs and may play additional important roles in cells that were not previously known. (+info)
Fractionation of antibodies to L-cell colony-stimulating factor by affinity chromatography.
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Purified L-cell colony-stimulating factor (CSF) was coupled to cyanogen-bromide-activated Sepharose and used to selectively fractionate antibodies to this factor. With the use of a simplified two-step washing and elution technique, there was 50%--70% binding of the anti-CSF, with recovery of 60%--100% of the bound material. Both the native antiserum and purified anti-CSF fractions were inhibitory to murine granulocyte-macrophage colony formation. The purified antibodies contained only IgG and were reduced in protein concentration to 0.1% of the serum IgG values. These fractions should prove useful tools for the study of granulocyte and macrophage differentiation. (+info)
The eukaryotic mRNA decapping protein Dcp1 interacts physically and functionally with the eIF4F translation initiation complex.
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Dcp1 plays a key role in the mRNA decay process in Saccharomyces cerevisiae, cleaving off the 5' cap to leave an end susceptible to exonucleolytic degradation. The eukaryotic initiation factor complex eIF4F, which in yeast contains the core components eIF4E and eIF4G, uses the cap as a binding site, serving as an initial point of assembly for the translation apparatus, and also binds the poly(A) binding protein Pab1. We show that Dcp1 binds to eIF4G and Pab1 as free proteins, as well as to the complex eIF4E-eIF4G-Pab1. Dcp1 interacts with the N-terminal region of eIF4G but does not compete significantly with eIF4E or Pab1 for binding to eIF4G. Most importantly, eIF4G acts as a function-enhancing recruitment factor for Dcp1. However, eIF4E blocks this effect as a component of the high affinity cap-binding complex eIF4E-eIF4G. Indeed, cooperative enhancement of the eIF4E-cap interaction stabilizes yeast mRNAs in vivo. These data on interactions at the interface between translation and mRNA decay suggest how events at the 5' cap and 3' poly(A) tail might be coupled. (+info)
One-step single-chain Fv recombinant antibody-based purification of gp96 for vaccine development.
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Heat shock proteins such as gp96 (grp94) isolated from tumor or infected cells are able to induce specific cytotoxic T-cell responses and protective immunity. To facilitate rapid and efficient isolation, we generated gp96-specific recombinant single-chain Fv (scFv) antibodies from a semisynthetic phage display library. When immobilized on Sepharose beads, these antibodies allow a high-yield, one-step purification of native gp96 molecules from both mouse and human tumor cell lysates. gp96 molecules eluted from these affinity columns under mild conditions are still capable of generating antigen-specific CTL responses in mice. Thus, scFv-purified gp96 is still associated with peptides; however, in contrast to conventionally purified gp96, scFv-isolated gp96 is free of contaminating material such as mitogenic concanavalin A and proteolytic cathepsins. With the help of these high-yield antibody columns, it is now possible to rapidly isolate immunogenic gp96-peptide complexes from small amounts of tumor material to a purity that allows their use in cancer immunotherapy protocols. (+info)
Polymorphism of the glutathione transferase subunit 3 in Sprague-Dawley rats involves a reactive cysteine residue.
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Comparison of Hirosaki hairless rat (HHR) and Sprague-Dawley (SD) rat liver glutathione transferase (GST) subunits by HPLC revealed differences in subunit 3; a new peak was detected in HHR GSTs and this was tentatively named X. By chromatofocusing, the HHR GST form composed of peak X and SD rat GST 3-3 were eluted at pH 8.8 and 9.1 respectively. The former was more sensitive to the SH reagent N-ethylmaleimide (NEM) than the latter. GSSG treatment of peak X resulted in a shift of retention time (peak Y) by HPLC analysis. However, such conversion was not observed for the SD rat GST 3-3 following GSSG or dithiothreitol (DTT) treatment. Peak Y exhibited m/z values of 26091.9 and 26125.4 by matrix-assisted laser-desorption ionization-time-of-flight MS, higher than those of peak X by 304-307, equivalent to the molecular-mass value of GSH. On treatment with DTT, peak Y was converted into peak X, with release of a substance with HPLC-characteristics of GSH. This substance was confirmed to be GSH by liquid chromatography/MS. These results thus indicated peak Y to be a glutathionylated form of peak X. Quantification revealed the release of 4 nmol of GSH from 0.12 mg of the peak Y protein, corresponding to 4.8 nmol (M(r) 25000). The nucleotide sequence of HHR GST subunit 3 cDNA proved identical to that reported for pGTA/C44, possessing asparagine and cysteine as the 198th and 199th amino acid residues, respectively, corresponding to lysine and serine in subunit 3 of the SD rat. Thus peak X appeared to be the product of HHR GST subunit 3 cDNA. Treatment with N-(4-dimethylamino-3,5-dinitrophenyl)maleimide, a coloured analogue of NEM, followed by trypsin-treatment and sequencing of labelled peptides, identified the reactive cysteine residue of HHR GST subunit 3 to be located at position 199. Unlike SD rat GST 3-3, HHR GST 3-3 was not activated by treatment with xanthine and xanthine oxidase. These results suggest polymorphism of the rat GST subunit 3 gene with individual gene product variation in sensitivity to oxidative stress. (+info)