We demonstrate non-degenerate down-conversion at 810 and 1550 nm for long-distance fiber based quantum communication using polarization entangled photon pairs. Measurements of the two-photon visibility, without dark count subtraction, have shown that the quantum correlations (raw visibility 89%) allow secure quantum cryptography after 100 km of non-zero dispersion shifted fiber using commercially available single photon detectors. In addition, quantum state tomography has revealed little degradation of state negativity, decreasing from 0.99 at the source to 0.93 after 100 km, indicating minimal loss in fidelity during the transmission.
We describe a modification of the tetracycline-inducible eukaryotic gene expression system with decreased basal levels of expression in HeLa cells. It employs the tetracycline-inducible transactivator and a tetracycline-regulated repressor fusion acting on the same promoter. To avoid heterodimerization or competition for the same DNA site, each was provided with different DNA recognition and/or protein dimerization specificities. We achieved active silencing in the uninduced state resulting in approximately 6-fold reduced levels of basal transcription and several hundred-fold activation of gene expression upon addition of tetracycline.
We examined the influence of substituents in tetracycline (tc) analogs modified at positions 2 and 4-9 and anhydrotetracycline (atc) on induction of the Tn10-encoded Tet repressor (TetR) by a quantitative in vitro induction assay. The equilibrium association constants of the modified tc to TetR were independently determined to distinguish effects on binding from those on induction. We found a correlation between the binding affinity and induction of TetR for most tc analogs. While a substitution at position 5 revealed only minor effects, changes at position 6 increased binding and induction efficiencies up to 20-fold. A chlorine at position 7 or 8 enhanced binding and induction about 4- and 9-fold, respectively. Substituents at position 9 decreased binding up to 5-fold. Epimerization of the dimethylamino function at position 4 in 4-epi-tc resulted in about 300-fold-reduced binding and 80-fold-reduced induction. Substitution of this grouping by hydrogen in 4-de(dimethylamino)-tc resulted in no binding and no induction. The respective atc analog failed to induce as well, although binding was still observed. The dimethylamino function may, thus, play a role in triggering the conformational change of TetR necessary for induction. Substitution of the 2-carboxamido by a nitrilo function did not influence binding and induction efficiencies. Atc showed about 30-fold increased binding and induction, being the most effective inducer tested in this study. The equilibrium association constants of most TetR-[Mg-tc]+ and TetR-([Mg-tc]+)2 analog complexes with tet operator are decreased about 10(2)- and 10(8)-fold, respectively, as compared to those of free TetR. This suggests that these tc analogs share the same molecular mechanism of TetR induction.
Various studies have linked alcohol dependence phenotypes to chromosome 4. One candidate gene is NACP (non-amyloid component of plaques), coding for alpha synuclein. Recently, it has been shown that alpha synuclein mRNA is increased in alcohol-dependent patients within withdrawal state. This increase is significantly associated with craving, especially obsessive craving. On the basis of these observations, the present study analysed two polymorphic repeats within the NACP gene. We found highly significant longer alleles of NACP-REP1 in alcohol-dependent patients compared with healthy controls (Kruskal-Wallis test, chi(2)=99.5; df=3, P<0.001). In addition, these lengths significantly correlate with levels of expressed alpha synuclein mRNA (chi(2)=8.83; df=2, P=0.012). The present results point to a novel approach for a genetic determination of craving, a key factor in the genesis and maintenance not only of alcoholism but also of addiction in general.
Tetracyclines coordinate metal(II) ions under physiological conditions forming chelate complexes with their ketoenolate moiety at rings B and C. These metal(II) complexes are the biologically relevant molecules conferring the antibiotic character of the drug by inhibiting ribosomal protein biosynthesis in prokaryotes. The Tet repressor, TetR, is the molecular switch for tetracycline resistance determinants in gram-negative bacteria. TetR controls transcription of a gene encoding the integral membrane protein TetA, which mediates active efflux of a tetracycline-metal(II) cation, [MeTc](+), by equimolar antiport with a proton. We evaluated distinct characteristics of the metal binding by crystal structure determination of TetR/[MeTc](+) complexes and of association equilibrium constants of [MeTc](+) and TetR/[MeTc](+) complexes. Various divalent metal ions bind to the same octahedral coordination site, defined by a histidine side chain of TetR, the tetracycline, and three water molecules. Whereas association constants for [MeTc](+) vary within 3 orders of magnitude, association of the [MeTc](+) cation to TetR is very similar for all measured divalent metals. Taking intracellular cation concentrations into account, it is evident that no other metal ion can compete with Mg(2+) for TetR/[MeTc](+) complex formation.
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