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The Escherichia coli RNA polymerase alpha-subunit binds through its carboxy-terminal domain (alpha CTD) to a recognition element, the upstream (UP) element, in certain promoters. We used genetic and biochemical techniques to identify the residues in alpha CTD important for UP-element-dependent transcription and DNA binding. These residues occur in two regions of alpha CTD, close to but distinct from, residues important for interactions with certain transcription activators. We used NMR spectroscopy to determine the secondary structure of alpha CTD, alpha CTD contains a nonstandard helix followed by four alpha-helices. The two regions of alpha CTD important for DNA binding correspond to the first alpha-helix and the loop between the third and fourth alpha-helices. The alpha CTD DNA-binding domain architecture is unlike any DNA-binding architecture identified to date, and we propose that alpha CTD has a novel mode of interaction with DNA. Our results suggest models for alpha CTD-DNA and alpha CTD-DNA-activator interactions during transcription initiation.

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Using limited proteolysis, we show that the Escherichia coli RNA polymerase alpha subunit consists of an N-terminal domain comprised of amino acids 8-241, a C-terminal domain comprised of amino acids 249-329, and an unstructured and/or flexible interdomain linker. We have carried out a detailed structural and functional analysis of an 85 amino acid proteolytic fragment corresponding to the C-terminal domain (alpha CTD-2). Our results establish that alpha CTD-2 has a defined secondary structure (approximately 40% alpha helix, approximately 0% beta sheet). Our results further establish that alpha CTD-2 is a dimer and that alpha CTD-2 exhibits sequence-specific DNA binding activity. Our results suggest a model for the mechanism of involvement of alpha in transcription activation by promoter upstream elements and upstream-binding activator proteins.

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Myc binds to a 6 bp 2-fold symmetric DNA site: 5'-C-3A-2C-1G+1T+2G+3-3'. Using site-specific 5-bromouracil mediated photocrosslinking, we show that His336 of Myc contacts, or is close to, the thymine 5-methyl group at 2-fold symmetry-related positions -2 and +2 of the DNA site in the Myc-DNA complex. Our results strongly suggest that homologous amino acids of Myc and Max make equivalent contacts in the respective protein-DNA complexes.

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Protein-protein interactions between transcription activator proteins and RNA polymerase or basal transcription factors have been suggested to be important for transcription activation. Interactions between catabolite gene activator protein (CAP) and RNA polymerase have been proposed based on face-of-helix-dependent transcription activation by CAP and based on face-of-helix-dependent cooperative binding of CAP and RNA polymerase to promoter DNA. Mutants of CAP specifically defective in transcription activation have been isolated (mutants defective in transcription activation, but not defective in DNA binding and DNA bending). All such mutants contain amino-acid substitutions within a surface loop consisting of amino acids 152 to 166 of CAP. Here we use the thermodynamically rigorous technique of fluorescence polarization to show that CAP interacts with RNA polymerase in solution in the absence of promoter DNA (KD,app = 2.8 x 10(-7) M), whereas [Ala158]CAP, a mutant of CAP specifically defective in transcription activation, does not.

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The bZIP DNA-binding proteins are characterized by a 50-amino-acid DNA binding and dimerization motif, consisting of a highly basic DNA-binding region ('b') followed by a leucine zipper dimerization region ('ZIP'). The best characterized bZIP DNA-binding protein is GCN4, a yeast transcriptional activator. GCN4 binds to a 9-base-pair two-fold-symmetric DNA site, 5'-A-4T-3G-2A-1C0T+1C+2A+3T+4-3' (refs 7-10). A detailed model known as the 'induced helical fork' model has been proposed for the structure of the GCN4-DNA complex. Using a site-specific bromouracil-mediated photocrosslinking method, we show here that the alanine at position 238 of GCN4 contacts, or is close to, the thymine 5-methyl of A.T at position +3 of the DNA site in the GCN4-DNA complex. Our results strongly support the induced helical fork model. Our site-specific bromouracil-mediated photocrosslinking method requires no prior information regarding the structure of the protein or the structure of the protein-DNA complex and should be generalizable to DNA-binding proteins that interact with the DNA major groove.

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4-trans-(NN-Dimethylamino)cinnamaldehyde (an aldehyde, DACA) and 4-trans-(NN-dimethylamino)cinnamoylimidazole (an amide, DACI) have been shown to be substrates for human aldehyde dehydrogenase (EC 1.2.1.3) which form chromophoric covalent intermediates. The spectra of covalent intermediates from both the cytoplasmic (E1) and mitochondrial (E2) isoenzymes derived from DACA and DACI were compared. The spectra were similar when either substrate was used, and also when the two isoenzymes were compared, and resembled that obtained for 4-trnas-(NN-dimethylamino)cinnamoyl-N-acetylcysteine, but differed from the spectrum of 4-trans-(NN-dimethylamino)cinnamoyl ethyl ester. After extensive digestion of the covalent intermediates from both 3H-labelled DACA and DACI with Pronase and purification, the labelled amino acid was identified as cysteine. Covalent intermediates from both DACA and DACI were also digested with trypsin, and labelled peptides were purified by ion-exchange and reverse-phase chromatography. Amino acid sequence analysis showed that the peptide comprising residues 273-307 was labelled by both DACA and DACI. The radioactive label at cysteine residues 301-303 of the primary structure could be unequivocally identified by employing the DACA derivative. Assignment of label to cysteine-302 was achieved by employing iodoacetamide-labelled E1 isoenzyme (iodoacetamide specifically labels cysteine-302), in which case there was no formation of the covalent intermediate from either DACA or DACI. In addition, cysteine-302 is the only cysteine residue conserved in all aldehyde dehydrogenases sequenced. Thus cysteine-302 is the amino acid residue that forms a covalent intermediate with both aldehyde and ester substrates.

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A major component of the sex pheromone from the tobacco budworm moth Heliothis virescens is a C16 straight-chain aldehyde with a single unsaturation at the eleventh position. The sex pheromones are inactivated when metabolized to their corresponding acids by insect aldehyde dehydrogenase. During this investigation it was demonstrated that the C16 aldehyde is a good substrate for human aldehyde dehydrogenase (EC 1.2.1.3) isoenzymes E1 and E2 with Km and Kcat. values at pH 7.0 of 2 microM and 0.4 mumol of NADH/min per mg and of 0.6 microM and 0.24 mumol of NADH/min per mg respectively. A vinyl ketone analogue of the pheromone inhibited insect pheromone metabolism; it also inactivated human aldehyde dehydrogenase. Total inactivation of both isoenzymes was achieved at stoichiometric (equal or less than the subunit number) concentrations of vinyl ketone, incorporating 2.1-2.6 molecules/molecule of enzyme. Substrate protection was observed in the presence of the parent aldehyde and 5'-AMP. Peptide maps of tryptic digests of the E2 isoenzyme modified with 3H-labelled vinyl ketone showed that incorporation occurred into a single peptide peak. The labelled peptide of E2 isoenzyme was further purified on h.p.l.c. and sequenced. The label was incorporated into cysteine-302 in the primary structure of E2 isoenzyme, thus indicating that cysteine-302 is located in the aldehyde substrate area of the active site of aldehyde dehydrogenase. Affinity labelling of aldehyde dehydrogenase with vinyl ketones may prove to be of general utility in biochemical studies of these enzymes.

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Michaelis constants and maximal velocities for phenylacetaldehyde (a metabolite of phenylethylamine), 3,4-dihydroxyphenylacetaldehyde (a metabolite of dopamine), 5-hydroxyindole acetaldehyde (a metabolite of serotonin), and 3,4-dihydroxyphenylglycolaldehyde (a metabolite of epinephrine and norepinephrine) have been determined for both cytoplasmic (E1) and mitochondrial (E2) isozymes of human liver aldehyde dehydrogenase (EC 1.2.1.3). Kinetic constants with biogenic aldehydes have never been previously determined for individual homogeneous isozymes of aldehyde dehydrogenase from any species. Mathematical treatment of these constants suggests that competition with acetaldehyde during alcohol metabolism would severely inhibit dehydrogenation of biogenic aldehydes with the mitochondrial and not the cytoplasmic isozyme of human liver aldehyde dehydrogenase.

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The ability of two platinum(IV) antitumor agents, cis,cis,trans-PtIV[(CH3)2CHNH2]2Cl2(OH)2 (2) and cis,cis,trans-PtIV(NH3)2Cl2(OH)2 (4), to interact with PM2 DNA was examined. Analysis using gel electrophoresis showed that neither compound is able to alter the electrophoretic mobilities of the three forms of PM2 DNA in the gel. However, incubation of 2 and 4 with 2 equiv of Fe(ClO4)2 X 6H2O or 1 equiv of ascorbic acid results in reduction to yield the divalent complexes cis-PtII(NH3)2Cl2 (1) and cis-PtII-[(CH3)2CHNH2]2Cl2 (3). The structures of the reduction products were characterized by using elemental analysis as well as infrared and 195Pt NMR spectroscopies. Both 1 and 3 were found to bind to and unwind supercoiled form I PM2 DNA. The aforementioned observations support the suggestion that reduction is a means of activating the antitumor properties of 2 and 4.

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