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Molecular analysis of microdissected tissue samples is used for analyzing tissue heterogeneity of histological specimens. We have developed a rapid one-step microdissection technique, which was applied for the selective procurement of tissue areas down to a minimum of 10 cell profiles. The special features of our microdissection system consist of an ultrasonically oscillating needle and a piezo-driven micropipette. The validity of this technique is demonstrated in human lung large-cell carcinoma by real-time quantitative reverse transcriptase-polymerase chain reaction assays of vimentin, cyclin D1, and carcinoembryonic antigen after linear RNA amplification. mRNA expression values of microdissected samples scattered around those of bulk tumor tissue and showed differential mRNA expression between samples of tumor parenchyma and supportive stromal cells for vimentin and carcinoembryonic antigen as confirmed by immunohistochemistry. In conclusion, this procedure requires simple equipment, is easily performed, and delivers microdissected tissue samples of oligocellular clusters suitable for further molecular analysis.

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Glutaconyl-CoA decarboxylase from Acidaminococcus fermentans (clostridal cluster IX), a strict anaerobic inhabitant of animal intestines, uses the free energy of decarboxylation (delta G(o) approximately -30 kJ mol-1) in order to translocate Na+ from the inside through the cytoplasmic membrane. The proton, which is required for decarboxylation, most probably comes from the outside. The enzyme consists of four different subunits. The largest subunit, alpha or GcdA (65 kDa), catalyses the transfer of CO2 from glutaconyl-CoA to biotin covalently attached to the gamma-subunit, GcdC. The beta-subunit, GcdB, is responsible for the decarboxylation of carboxybiotin, which drives the Na+ translocation (approximate K(m) for Na+ 1 mM), whereas the function of the smallest subunit, delta or GcdD, is unclear. The gene gcdA is part of the 'hydroxyglutarate operon', which does not contain genes coding for the other three subunits. This paper describes that the genes, gcdDCB, are transcribed in this order from a distinct operon. The delta-subunit (GcdD, 12 kDa), with one potential transmembrane helix, probably serves as an anchor for GcdA. The biotin carrier (GcdC, 14 kDa) contains a flexible stretch of 50 amino acid residues (A26-A75), which consists of 34 alanines, 14 prolines, one valine and one lysine. The beta-subunit (GcdB, 39 kDa) comprising 11 putative transmembrane helices shares high amino acid sequence identities with corresponding deduced gene products from Veillonella parvula (80%, clostridial cluster IX), Archaeoglobus fulgidus (61%, Euryarchaeota), Propionigenium modestum (60%, clostridial cluster XIX), Salmonella typhimurium (51%, enterobacteria) and Klebsiella pneumoniae (50%, enterobacteria). Directly upstream of the promoter region of the gcdDCB operon, the 3' end of gctM was detected. It encodes a protein fragment with 73% sequence identity to the C-terminus of the alpha-subunit of methylmalonyl-CoA decarboxylase from V. parvula (MmdA). Hence, it appears that A. fermentans should be able to synthesize this enzyme by expression of gctM together with gdcDCB, but methylmalonyl-CoA decarboxylase activity could not be detected in cell-free extracts. Earlier observations of a second, lower affinity binding site for Na+ of glutaconyl-CoA decarboxylase (apparent K(m) 30 mM) were confirmed by identification of the cysteine residue 243 of GcdB between the putative hellces VII and VIII, which could be specifically protected from alkylation by Na+. The alpha-subunit was purified from an overproducing Escherichia coli strain and was characterized as a putative homotrimer able to catalyse the carboxylation of free biotin.

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The protein mediator MIF has been identified as being released from immune cells by glucocorticoid stimulation and to counter-regulate glucocorticoid action. MIF also has been described recently to exhibit dopachrome tautomerase activity and to be structurally homologous to the bacterial enzymes 4-oxalocrotonate tautomerase (4-OT) and 5-carboxymethyl-2-hydroxymuconate isomerase (CHMI). We performed site-directed mutagenesis and biochemical analyses of mouse MIF in order to identify amino acid residues and protein domains that are essential for enzymatic reactivity. Mutant proteins which lacked a free N-terminal proline residue were enzymatically inactive, as was a preparation of native MIF modified covalently at its N terminus by 3-bromopyruvate, suggesting that this proline has a catalytic function. Substitutions of the internal histidine residues 42 and 63 did not affect enzymatic activity, indicating that these basic residues are not involved in dopachrome tautomerization. Carboxy-truncated forms of MIF (residues 1-110 and 1-104) also were inactive, affirming the role of the carboxy terminus in stable trimer formation and the importance of the trimer for enzymatic activity. Additional evidence for the homotrimeric structure of MIF under native solution conditions was obtained by SDS-PAGE analysis of MIF after chemical cross-linking at low protein concentrations. The enzymatic activity of MIF was found to be reversibly inhibited by micromolar concentrations of fatty acids with chain lengths of at least 16 carbon atoms. Of note, molecular modeling of the substrate L-dopachrome methyl ester into the active site of MIF suggests an acid-catalyzed enzymatic mechanism that is different from that deduced from studies of the enzymes 4-OT and CHMI. Finally, in vitro analysis of an enzymatically inactive MIF species (P2 --> S) indicates that the glucocorticoid counter-regulatory activity of MIF can be functionally dissociated from its tautomerization activity.

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Free hematin can be converted to a stable polymer both chemically, by heating hematin in acid suspensions, or biologically, in the food vacuoles of malaria. A high-performance liquid chromatographic assay has been developed which can separate and quantitate both free hematin and the polymer (beta-hematin), based on the differential solubility of the two compounds. Ion-pair reverse-phase chromatography, utilizing tetramethylammonium chloride and heptane sulfonate as the ion-pair agents in the presence of 40% acetonitrile, was performed on a polymeric-resin-based column with a phenyl bonded phase. Initiating the runs at pH 2.5 led to elution only of the free hematin, and a subsequent shift to pH 12.0 converted the beta-hematin back to hematin which then eluted separately. The method was found to have a linear range of detection from 78 pmol to 20 nmol injected hematin and intra- and interday variations of 9.71 and 12.46%, respectively. The assay was used to study several basic aspects of heme polymerization in vitro, including effects of hematin and beta-hematin concentration on the rate of polymerization.

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Glutaconate coenzyme A-transferase (Gct) from Acidaminococcus fermentans consists of two subunits (GctA, 35725 Da and GctB, 29168 Da). The N-termini sequences of both subunits were determined. DNA sequencing of a subgenomic fragment of A. fermentans revealed that the genes encoding glutaconate CoA-transferase (gctAB) are located upstream of a gene cluster formed by gcdA, hgdC, hgdA and hgdB in this order. Further upstream of gctA, a DNA sequence was detected showing significant similarities to sigma 70-type promoters from Escherichia coli. Primer-extension analysis revealed that this specific DNA sequence was indeed the location of transcription initiation in A. fermentans. The entire gene cluster, 7.3 kb in length, comprising gctAB, gcdA and hgdCAB, has tentatively been named the hydroxyglutarate operon, since the enzymes encoded by these genes are involved in the conversion of (R)-2-hydroxyglutarate to crotonyl-CoA in the pathway of glutamate fermentation by A. fermentans. The genes gctAB were expressed together in E. coli. Cell-free extracts of a transformant E. coli strain contained glutaconate CoA-transferase at a specific activity of up to 30 U/mg protein. The recombinant enzyme was purified to homogeneity with a specific activity of 130 U/mg protein by ammonium sulfate fractionation and crystallisation. The amino acid residue directly involved in catalysis was tentatively identified as E54 of the small subunit of the enzyme (GctB).

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(R)-2-Hydroxyglutaryl-CoA dehydratase (HGDA/B) from Acidaminococcus fermentans requires an activator protein for activity. This activator (HGDC) has not yet been purified from its natural source due to its low concentration combined with an extreme sensitivity towards oxygen. Gene expression in Escherichia coli identified an open reading frame (780 bp) as the gene encoding HGDC. Dehydratase activity was stimulated at least tenfold by cell-free extracts of E. coli cells transformed with a plasmid carrying hgdC. On the chromosome the hgdC gene is located just before hgdA and hgdB.

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1. The primary sodium-ion pump glutaconyl-CoA decarboxylase (GCD) from Acidaminococcus fermentans is composed of four subunits: GCDA, the carboxytransferase (65 kDa), GCDB, the carboxylyase (36 kDa), GCDC, the biotin carrier (24 kDa) and GCDD (14 kDa) of unknown function. A genomic library of A. fermentans was screened with an antiserum raised against whole GCD. A clone giving the strongest reaction in an immunoassay contained a 12-kbp genomic fragment from A. fermentans and was analysed further. An oligonucleotide deduced from the N-terminus of GCDA was used for probing the corresponding gene gcdA. It is 1761 bp in length and encodes for a protein of 64.3 kDa. Both partial amino acid sequences obtained from GCDA, the N-terminus as well as an internal tryptic peptide, were detected in the open reading frame (ORF) of gcdA. 2. Sequencing of the flanking regions revealed three adjacent ORF (ORF1-3) which do not code for any of the peptide sequences known of the other GCD subunits. The ORF downstream of gcdA (ORF3) is followed by hgdA and hgdB coding for 2-hydroxyglutaryl-CoA dehydratase, the preceding enzyme of the pathway of glutamate fermentation. Our results suggest that at least these three genes of the hydroxyglutarate pathway are organised in an operon and that the genes of the other GCD subunits from which peptide sequences are known (GCDB and GCDC) are not located adjacent to gcdA. 3. gcdA was amplified from genomic DNA using the polymerase chain reaction and cloned into the expression vector pJF118HE. Active GCDA subunit (up to 2.8 nkat/mg protein), catalysing the biotin-dependent formation of crotonyl-CoA from glutaconyl-CoA, was obtained in cell-free extracts of Escherichia coli DH5 alpha by moderately inducing the tac promoter of pJF118HE with 25-100 microM isopropyl-1-thio-beta-D-galactoside. Strong induction (1 mM isopropyl-1-thio-beta-D-galactoside) led to the formation of inclusion bodies from which GCDA could not be reactivated. The apparent Km = 51 mM for free biotin of the expressed GCDA subunit with V = 1.9 nkat/mg protein is similar to that of butanol-treated GCD composed of GCDA and GCDC (apparent Km = 40 mM). Biocytin was found to be a somewhat better carboxy acceptor for the expressed GCDA subunit (apparent Km = 13 mM; V = 1.0 nkat/mg protein). 4. Native GCD and expressed GCDA were treated with 2 mM N-ethylmaleimide showing different kinetics of inactivation: GCD lost half of its activity within 6 min, whereas expressed GCDA required 21 min.

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[2'-13C]Biotin was incorporated into avidin (egg white), glutaconyl-CoA decarboxylase (EC 4.1.1.70) from Acidaminococcus fermentans and the biotin carrier of transcarboxylase from Propionibacterium freudenreichii (EC 2.1.3.1). 13C-NMR measurements showed an upfield shift of the carbonyl carbon of 3.1 and 2.0 ppm for both enzymes, whereas binding to avidin induced no significant change of the chemical shift as compared to free biotin. The data indicate that the enzymes provide an electronic environment for the covalently bound biotin which favours carboxylation. In addition it was demonstrated by NMR-measurements that glutaconyl-CoA decarboxylase, from which the hydrophobic carboxy-lyase subunit (beta) was removed, could carboxylate free biotin.

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Membrane preparations of Fusobacterium nucleatum grown on glutamate contain glutaconyl-CoA decarboxylase at a high specific activity (13.8 nkat/mg protein). The enzyme was solubilized with 2% Triton X-100 in 0.5 M NaCl and purified 63-fold to a specific activity of 870 nkat/mg by affinity chromatography on monomeric avidin-Sepharose. The activity of the decarboxylase was strictly dependent on Na+ (Km = 3 mM) and was stimulated up to 3-fold by phospholipids. The glutaconyl-CoA decarboxylases from the gram-positive bacteria Acidaminococcus fermentans and Clostridium symbiosum have a lower apparent Km for Na+ (1 mM) and were not stimulated by phospholipids. In addition only the fusobacterial decarboxylase required sodium ion for stability and was inactivated by potassium ion. By incorporation of this purified enzyme into phospholipids an electrogenic sodium ion pump was reconstituted. The enzyme consists of four subunits, alpha (m = 65 kDa), beta (33 kDa), gamma (19 kDa), and delta (16 kDa) with the functions of a carboxy transferase (alpha), a carboxy lyase (beta and probably delta) and a biotin carrier (gamma). The subunits are very similar to those of the glutaconyl-CoA decarboxylases from the gram-positive bacteria. With an antiserum directed against the decarboxylase from A. fermentans the alpha- and the biotin containing subunits of the three decarboxylases and that from Peptostreptococcus asaccharolyticus could be detected on Western blots.

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