Zn2+ selectively stabilizes FdU-substituted DNA through a unique major groove binding motif

We report, based on semi-empirical calculations, that Zn(2+) binds duplex DNA containing consecutive FdU-dA base pairs in the major groove with distorted trigonal bipyramidal geometry. In this previously uncharacterized binding motif, O4 and F5 on consecutive FdU are axial ligands while three water molecules complete the coordination sphere. NMR spectroscopy confirmed Zn(2+) complexation occurred with maintenance of base pairing while a slight hypsochromic shift in circular dichroism (CD) spectra indicated moderate structural distortion relative to B-form DNA. Zn(2+) complexation inhibited ethidium bromide (EtBr) intercalation and stabilized FdU-substituted duplex DNA (ΔT(m) > 15 °C). Mg(2+) neither inhibited EtBr complexation nor had as strong of a stabilizing effect. DNA sequences that did not contain consecutive FdU were not stabilized by Zn(2+). A lipofectamine preparation of the Zn(2+)-DNA complex displayed enhanced cytotoxicity toward prostate cancer cells relative to the individual components prepared as lipofectamine complexes indicating the potential utility of Zn(2+)-DNA complexes for cancer treatment.     

DNA sequence preferences of GAL4 and PPR1: how a subset of Zn2 Cys6 binuclear cluster proteins recognizes DNA.

Biophysical and genetic experiments have defined how the Saccharomyces cerevisiae protein GAL4 and a subset of related proteins recognize specific DNA sequences. We assessed DNA sequence preferences of GAL4 and a related protein, PPR1, in an in vitro DNA binding assay. For GAL4, the palindromic CGG triplets at the ends of the 17-bp recognition site are essential for tight binding, whereas the identities of the internal 11 bp are much less important, results consistent with the GAL4-DNA crystal structure. Small reductions in affinity due to mutations at the center-most 5 bp are consistent with the idea that an observed constriction in the minor groove in the crystalline GAL4-DNA complex is sequence dependent. The crystal structure suggests that this sequence dependence is due to phosphate contacts mediated by arginine 51, as part of a network of hydrogen bonds. Here we show that the mutant protein GAL4(1-100)R51A fails to discriminate sites with alterations in the center of the site from the wild-type site. PPR1, a relative of GAL4, also recognizes palindromic CGG triplets at the ends of its 12-bp recognition sequence. The identities of the internal 6 bp do not influence the binding of PPR1. We also show that the PPR1 site consists of a 12-bp duplex rather than 16 bp as reported previously: the two T residues immediately 5' to the CGG sequence in each half site, although highly conserved, are not important for binding by PPR1. Thus, GAL4 and PPR1 share common CGG half sites, but they prefer DNA sequences with the palindromic CGG separated by the appropriate number of base pairs, 11 for GAL4 and 6 for PPR1.     

The regulator of streptomycin gene expression, StrR, of Streptomyces griseus is a DNA binding activator protein with multiple recognition sites

In Streptomyces griseus the expression of at least one streptomycin biosynthetic gene, strB1 , is dependent on the pathway-specific activator protein StrR. We show here that StrR is a DNA-binding protein which specifically interacts with the strB1 promoter fragment. Footprinting experiments demonstrate that the StrR protein binds to an inverted repeat located upstream of the strB1 promoter. Further StrR-binding sites having the consensus sequence GTTCGActG(N)₁₁CagTcGAAc were identified in the str—sts gene clusters of S. griseus and Streptomyces glaucescens by sequence comparison, gel retardation, and footprinting studies. The genetic and biochemical evidence strongly supports the model of the StrR protein activating the expression of streptomycin biosynthetic genes by interacting with multiple binding sites within the str—sts gene clusters of S. griseus and S. glaucescens .     

Covalent binding of Cys142 from SsoII methyltransferase with DNA duplexes, containing a phosphoryldisulfide internucleotide group

DNA duplexes containing a single phosphoryldisulfide link in place of the natural internucleotide phosphodiester bond were employed in affinity modification of Cys142 in cytosine-C5 DNA methyltransferase SsoII (M.SsoII). The possibility of duplex-M.SsoII conjugation as a result of disulfide exchange was demonstrated. The crosslinking efficiency proved to depend on the DNA primary structure, modification position, and the presence of S-adenosyl-L-homocysteine, a nonreactive analog of the methylation cofactor. The SH group of M.SsoII Cys142 was assumed to be close to the DNA sugar-phosphate backbone in the DNA-enzyme complex.     

Mitochondrial DNA quality control in the female germline requires a unique programmed mitophagy

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