Oxidative stress-induced expression and modulation of Phosphatase of Regenerating Liver-1 (PRL-1) in mammalian retina

The phosphatase of regenerating liver-1, PRL-1, gene was detected in a screen for foveal cone photoreceptor-associated genes. It encodes a small protein tyrosine phosphatase that was previously immunolocalized to the photoreceptors in primate retina. Here we report that in cones and cone-derived cultured cells both PRL-1 activity and PRL-1 gene expression are modulated under oxidative stress. Oxidation reversibly inhibited the phosphatase activity of PRL-1 due to the formation of an intramolecular disulfide bridge between Cys104 within the active site and another conserved Cys, Cys49. This modulation was observed in vitro, in cell culture and in isolated retinas exposed to hydrogen peroxide. The same treatment caused a rapid increase in PRL-1 expression levels in cultured cells which could be blocked by the protein translation inhibitor, cycloheximide. Increased PRL-1 expression was also observed in living rats subjected to constant light exposure inducing photooxidative stress. We further demonstrated that both oxidation and overexpression of PRL-1 upon oxidative stress are greatly enhanced by inhibition of the glutathione system responsible for cellular redox regulation. These findings suggest that PRL-1 is a molecular component of the photoreceptor's response to oxidative stress acting upstream of the glutathione system.     

Incorporation of an EDTA-metal complex at a rationally selected site within a protein: application to EDTA-iron DNA affinity cleaving with catabolite gene activator protein (CAP) and Cro.

We have developed a simple procedure to incorporate an EDTA-metal complex at a rationally selected site within a full-length protein. Our procedure has two steps: In step 1, we use site-directed mutagenesis to introduce a unique solvent-accessible cysteine residue at the site of interest. In step 2, we derivatize the resulting protein with S-(2-pyridylthio)cysteaminyl-EDTA-metal, a novel aromatic disulfide derivative of EDTA-metal. We have used this procedure to incorporate an EDTA-iron complex at amino acid 2 of the helix-turn-helix motif of each of two helix-turn-helix motif sequence-specific DNA binding proteins, catabolite gene activator protein (CAP) and Cro, and we have analyzed EDTA-iron-mediated DNA affinity cleavage by the resulting protein derivatives. The CAP derivative cleaves DNA at base pair 2 of the DNA half-site in the protein-DNA complex, and the Cro derivative cleaves DNA at base pairs -3 to 5 of the DNA half-site in the protein-DNA complex. We infer that amino acid 2 of the helix-turn-helix motif of CAP is close to base pair 2 of the DNA half-site in the CAP-DNA complex in solution and that amino acid 2 of the helix-turn-helix motif of Cro is close to base pairs -3 to 5 of the DNA half-site in the Cro-DNA complex in solution.(ABSTRACT TRUNCATED AT 250 WORDS)     

Consensus DNA site for the Escherichia coli catabolite gene activator protein (CAP): CAP exhibits a 450-fold higher affinity for the consensus DNA site than for the E. coli lac DNA site.

We have synthesized two 40 base pair DNA fragments; one fragment contains the consensus DNA site for CAP (fragment 'ICAP'); the other fragment contains the E. coli lac promoter DNA site for CAP (fragment 'LCAP'). We have investigated the binding of CAP to the two DNA fragments using the nitrocellulose filter binding assay. Under standard conditions [( NaCl] = 200 mM, pH = 7.3), CAP exhibits a 450-fold higher affinity for ICAP than for LCAP. The salt dependence of the binding equilibrium indicates that CAP makes eight ion pairs with ICAP, but only six ion pairs with LCAP. Approximately half of the difference in binding free energy for interaction of CAP with ICAP vs. LCAP is attributable to this difference in ion-pair formation. The pH dependence of the binding equilibrium indicates that the eight CAP-ICAP ion pairs and the six CAP-LCAP ion pairs do not involve His residues of CAP.     

DNA sequence determinants for binding of the Escherichia coli catabolite gene activator protein.

The consensus DNA site for binding of the Escherichia coli catabolite gene activator protein (CAP) is 22 base pairs in length and is 2-fold symmetric: 5'-AAATGTGATCTAGATCACATTT-3'. Positions 4 to 8 of each half of the consensus DNA half-site are the most strongly conserved. In this report, we analyze the effects of substitution of DNA base pairs at positions 4 to 8, the effects of substitution of thymine by uracil and by 5-methylcytosine at positions 4, 6, and 8, and the effect of dam methylation of the 5'-GATC-3' sequence at positions 7 to 10. All DNA sites having substitutions of DNA base pairs at positions 4 to 8 exhibit lower affinities for CAP than does the consensus DNA site, consistent with the proposal that the consensus DNA site is the ideal DNA site for CAP. Specificity for T:A at position 4 appears to be determined solely by the thymine 5-methyl group. Specificity for T:A at position 6 and specificity for A:T at position 8 appear to be determined in part, but not solely, by the thymine 5-methyl group. dam methylation has little effect on CAP.DNA complex formation. The thermodynamically defined consensus DNA site spans 28 base pairs. All, or nearly all, DNA determinants required for maximal affinity for CAP and for maximal thermodynamically defined CAP.DNA ion pair formation are contained within a 28-base pair DNA fragment that has the 22-base pair consensus DNA site at its center. The quantitative data in this report provide base-line thermodynamic data required for detailed investigations of amino acid-base pair and amino acid-phosphate contacts in this protein-DNA complex.     

Structural organization of bacterial RNA polymerase holoenzyme and the RNA polymerase-promoter open complex

We have used systematic fluorescence resonance energy transfer and distance-constrained docking to define the three-dimensional structures of bacterial RNA polymerase holoenzyme and the bacterial RNA polymerase-promoter open complex in solution. The structures provide a framework for understanding sigma(70)-(RNA polymerase core), sigma(70)-DNA, and sigma(70)-RNA interactions. The positions of sigma(70) regions 1.2, 2, 3, and 4 are similar in holoenzyme and open complex. In contrast, the position of sigma(70) region 1.1 differs dramatically in holoenzyme and open complex. In holoenzyme, region 1.1 is located within the active-center cleft, apparently serving as a "molecular mimic" of DNA, but, in open complex, region 1.1 is located outside the active center cleft. The approach described here should be applicable to the analysis of other nanometer-scale complexes.