Evidence for a regulatory action of vanadate on protein phosphorylation in brain microvessels

We investigated the action of vanadate on protein phosphorylation in microvessels isolated from rat brain. We found that a stimulation of protein phosphorylation from 32P-ATP occurs, in the presence of different concentrations of vanadate, 10(-3) M being the most effective dose. This action was time-dependent, and it was more evident after 60 s of treatment. The contribution of ATPase inhibition caused by vanadate appears to be negligible. In addition a stimulation of cAMP-dependent protein kinase activity was observed. The pattern of protein phosphorylation showed that exposure to 10(-3) M vanadate resulted in a nonspecific stimulation of protein phosphorylation concomitantly with a selective inhibition of the 55 KDa protein phosphorylation. The nature of this protein is also discussed.     

Sequence-selective DNA binding to the regulatory subunit of cAMP-dependent protein kinase

The fluorescence of Trp-226 in the regulatory subunit of bovine type II cAMP-dependent protein kinase is unaffected by the binding of cAMP, but is quenched by the binding of 2'-dansyl-cAMP (DNS-cAMP). Up to 67% of the fluorescence of Trp-226 can be quenched by resonant energy transfer to the DNS-cAMP bound to the first site, and 96% of the fluorescence can be quenched by saturating both sites with DNS-cAMP. The observed efficiencies of energy transfer gave a distance of 16 A between Trp-226 and the DNS-cAMP bound at the first site and a distance of 12.7 A between Trp-226 and the DNS-cAMP bound at second site. The fluorescence of Trp-226 was suppressed by incubation of RII with the self-complementary octanucleotide TGACGTCA (CRE) due to binding of the oligonucleotide to RII. A detailed study of the binding equilibrium showed that each RII(cAMP)2 molecule binds 1 molecule of CRE with Kd = 80 nM. The corresponding Kd value for cAMP-depleted RII was found to be 25-fold higher. RII was also found to bind randomly selected DNA fragments with an average Kd value much higher than that of CRE. These observations show for the first time that the binding of oligonucleotide to RII is cAMP-enhanced and sequence-selective.     

Characterization of RNA aptamer binding by the Wilms' tumor suppressor protein WT1

The interaction of the zinc finger protein WT1 with RNA aptamers has been investigated using a quantitative binding assay, and the results have been compared to those from a previous study of the DNA binding properties of this protein. A recombinant peptide containing the four zinc fingers of WT1 (WT1-ZFP) binds to representatives of three specific families of RNA aptamers with apparent dissociation constants ranging from 13.8 +/- 1.1 to 87.4 +/- 10.4 nM, somewhat higher than the dissociation constant of 4.12 +/- 0.4 nM for binding to DNA. An isoform that contains an insertion of three amino acids between the third and fourth zinc fingers (WT1[+KTS]-ZFP) also binds to these RNAs with slightly reduced affinity (the apparent dissociation constants ranging from 22.8 to 69.8 nM) but does not bind to DNA. The equilibrium binding of WT1-ZFP to the highest-affinity RNA molecule was compared to the equilibrium binding to a consensus DNA molecule as a function of temperature, pH, monovalent salt concentration, and divalent salt concentration. The interaction of WT1-ZFP with both nucleic acids is an entropy-driven process. Binding of WT1-ZFP to RNA has a pH optimum that is narrower than that observed for binding to DNA. Binding of WT1-ZFP to DNA is optimal at 5 mM MgCl(2), while the highest affinity for RNA was observed in the absence of MgCl(2). Binding of WT1 to both nucleic acid ligands is sensitive to increasing monovalent salt concentration, with a greater effect observed for DNA than for RNA. Point mutations in the zinc fingers associated with Denys-Drash syndrome have dramatically different effects on the interaction of WT1-ZFP with DNA, but a consistent and modest effect on the interaction with RNA. The role of RNA sequence and secondary structure in the binding of WT1-ZFP was probed by site-directed mutagenesis. Results indicate that a hairpin loop is a critical structural feature required for protein binding, and that some consensus nucleotides can be substituted provided proper base pairing of the stem of the hairpin loop is maintained.     

Ligand-modulated binding of a gene regulatory protein to DNA. Quantitative analysis of cyclic-AMP induced binding of CRP from Escherichia coli to non-specific and specific DNA targets

This paper describes a generally applicable method for quantitative investigation of ligand-dependent binding of a regulatory protein to its target DNA at equilibrium. It is used here to analyse the coupled binding equilibria of cAMP receptor protein from Escherichia coli K12 (CRP) with DNA and the physiological effector cAMP. In principle, the DNA binding parameters of CRP dimers with either one or two ligands bound are determinable in such an approach. The change of protein fluorescence was used to measure CRP binding to its recognition sequence in the lac control region and to non-specific DNA. Furthermore, the binding of cAMP to preformed CRP-DNA complexes was independently studied by equilibrium dialysis. The data were analysed using a simple interactive model for two intrinsically identical sites and site-site interactions. The intrinsic binding constant K and the co-operativity factor alpha for binding of cAMP to free CRP depend only slightly on salt concentration between 0.01 M and 0.2 M. In contrast, the affinity of cAMP for CRP pre-bound to non-specific DNA increases with the salt concentration and the co-operativity changes from positive to negative. This results from cation rebinding to the DNA lattice upon forming the cAMP-CRP-DNA complex from cAMP and the pre-formed CRP-DNA complex. The CRP-cAMP1 complex shows almost the same affinity for specific and non-specific DNA as the CRP-cAMP2 complex, and both displace the same number of cations. It is concluded that the allosteric activation of CRP is induced upon binding of the first cAMP. These results are used to estimate the occupation of the CRP site in the lac control region in relation to the cAMP concentration in vivo. Under physiological conditions the lac promoter is activated by the CRP dimer complexed with only one cAMP. Furthermore, a model for the differential activation of various genes expressed under catabolite repression is presented and discussed.     

Dihydroergotamine binding to rat brain membranes.

³H-dihydroergotamine, which is used clinically to treat orthostatic hypotension and migraine, binds saturably, reversibly and with high affinity (K_D = 0.2 nM) to rat brain membranes. The binding is time, temperature and pH dependent and is highest in the hippocampus and the corpus striatum. Serotonin was the only neurotransmitter tested capable of inhibiting ³H-DHE binding.     

Cooperative binding of the leucine-responsive regulatory protein (Lrp) to DNA

The leucine-responsive regulatory protein (Lrp) of Escherichia coli activates expression of a number of operons and represses expression of others. For some members of the Lrp regulon, exogenous leucine mitigates the effect of Lrp, for some it potentiates the effect of Lrp, and for others it has no effect on Lrp action. For the ilvIH operon that we study, Lrp activates expression in vivo and mediates the repression of the operon by exogenous leucine. We studied Lrp-1, a leucine-insensitive variant, to investigate mechanisms by which leucine alters Lrp action as an activator of ilvIH expression. The Asp114Glu change did not have much effect on the amount of total Lrp-1 in cells but decreased the amount of free Lrp-1 two- to threefold. Lrp monomers associate to form octamers and hexadecamers (hexadecamer form predominates at micromolar concentrations; Kd=5.27x10(-8) M), and leucine promotes the dissociation of Lrp hexadecamer to a leucine-bound octamer. By contrast, Lrp-1 exists primarily as an octamer in solution (equilibrium dissociation constant 6.5x10(-5) M) and leucine had little effect on the equilibrium. Thus, the hexadecameric form that Lrp assumes in the absence of DNA is not required for activation of the ilvIH operon. Both leucine and the lrp-1 mutation reduced the apparent affinity of Lrp binding to ilvIH DNA (contains two groups of binding sites separated by 136 bp) but they have different effects on intrinsic binding affinity and binding cooperativity. Whereas leucine reduced intrinsic binding affinities and interactions of Lrps bound at upstream and downstream regions of ilvIH DNA, it increased cooperative dimer-dimer interactions of Lrps bound to two adjacent sites. By contrast, the lrp-1 mutation did not have much effect on intrinsic binding affinities but it decreased cooperative adjacent dimer-dimer interactions and enhanced interactions of Lrps bound at upstream and downstream regions of ilvIH DNA. Our analysis is consistent with the idea that leucine enhances dimer-dimer interactions that contribute to octamer formation, concomitantly reducing dimer-dimer interactions that contribute to the longer range interactions of Lrps that are required for activation of the ilvIH promoter.     

Characterization of a mitochondrial protein binding to single-stranded DNA.

A DNA-binding protein from Xenopus laevis oocyte mitochondria which has been found associated with the D-loop also shows a strong preference for single-stranded DNA. The binding to polynucleotides is dependent on the base composition, but no sequence specificity was found. This protein, called mtSSB, binds tightly and cooperatively to single-stranded DNA. By its amino-acid composition and its binding properties it appears to be similar to the single-stranded DNA-binding proteins found in prokaryotes.     

Influence of DNA aptamer structure on the specificity of binding to Taq DNA polymerase

The secondary structure of DNA aptamer to Taq DNA polymerase was established as a hairpin. Both stem and loop structures of DNA ligand were shown to be involved in the interaction with Taq DNA polymerase. Moreover, the structure and sequence of DNA aptamer that was the most effective inhibitor of DNA polymerase activity were established. This crucial structure was evaluated as a GC-rich stem longer than 17 bp, and a loop consisting of 12 bases with strictly determined nucleotide sequence. It was demonstrated that nucleotide in position 23 counting from the 5"-end of DNA ligand was involved in direct contact with Taq DNA polymerase. The ability of optimized DNA aptamer TQ21-11 to form a complex with the enzyme was increased 5-fold in comparison to the initial aptamer.     

Sequence selective binding of bis-daunorubicin WP631 to DNA.

We have used footprinting techniques on a wide range of natural and synthetic footprinting substrates to examine the sequence-selective interaction of the bis-daunorubicin antibiotic WP631 with DNA. The ligand produces clear DNase I footprints that are very different from those seen with other anthracycline antibiotics such as daunorubicin and nogalamycin. Footprints are found in a diverse range of sequences, many of which are rich in GT (AC) or GA (TC) residues. As expected, the ligand binds well to the sequences CGTACG and CGATCG, but clear footprints are also found at hexanucleotide sequences such GCATGC and GCTAGC. The various footprints do not contain any particular unique di-, tri- or tetranucleotide sequences, but are frequently contain the sequence (G/C)(A/T)(A/T)(G/C). All sequences with this composition are protected by the ligand, though it can also bind to some sites that differ from this consensus by one base pair.     

Selection of DNA binding sites by regulatory proteins. II. The binding specificity of cyclic AMP receptor protein to recognition sites

The statistics of base-pair usage within known recognition sites for a particular DNA-binding protein can be used to estimate the relative protein binding affinities to these sites, as well as to sites containing any other combinations of base-pairs. As has been described elsewhere, the connection between base-pair statistics and binding free energy is made by an equal probability selection assumption; i.e. that all base-pair sequences that provide appropriate binding strength are equally likely to have been chosen as recognition sites in the course of evolution. This is analogous to a statistical-mechanical system where all configurations with the same energy are equally likely to occur. In this communication, we apply the statistical-mechanical selection theory to analyze the base-pair statistics of the known recognition sequences for the cyclic AMP receptor protein (CRP). The theoretical predictions are found to be in reasonable agreement with binding data for those sequences for which experimental binding information is available, thus lending support to the basic assumptions of the selection theory. On the basis of this agreement, we can predict the affinity for CRP binding to any base-pair sequence, albeit with a large statistical uncertainty. When the known recognition sites for CRP are ranked according to predicted binding affinities, we find that the ranking is consistent with the hypothesis that the level of function of these sites parallels their fractional saturation with CRP-cAMP under in-vivo conditions. When applied to the entire genome, the theory predicts the existence of a large number of randomly occurring "pseudosites" with strong binding affinity for CRP. It appears that most CRP molecules are engaged in non-productive binding at non-specific or pseudospecific sites under in-vivo conditions. In this sense, the specificity of the CRP binding site is very low. Relative specificity requirements for polymerases, repressors and activators are compared in light of the results of this and the first paper in this series.     

Single-strand DNA binding protein from rat liver: interactions with supercoiled DNA.

As shown by competition experiments, the single-strand DNA binding protein from normal rat liver (S25) interacts preferentially with supercoiled DNA compared to relaxed DNA duplexes. When followed both by sedimentation analysis and by nitrocellulose filter assay, the binding of S25 to SV40 supercoiled DNA (FI) appears to be non-cooperative. Saturation is reached at a protein to DNA weight ratio of about 2. The S25-DNA complexes prefixed with glutaraldehyde appear as beaded structures having an average of 14 to 16 beads per SV40 DNA molecules. Cross-linking of S25 bound to SV40 DNA by dimethyl suberimidate allows to detect oligomeric structures containing a maximum of twenty monomers of S25. When complexes are treated by glutaraldehyde, 10% of the genome become resistant against micrococcal nuclease. Moreover, S25 affects the DNA helical structure. Superhelical forms are generated by the association of S25 with SV40 DNA, in the presence of nicking-closing enzyme.     

The salt dependence of the interferon regulatory factor 1 DNA binding domain binding to DNA reveals ions are localized around protein and DNA

The equilibrium dissociation constant of the DNA binding domain of interferon regulatory factor 1 (IRF1 DBD) for its DNA binding site depends strongly on salt concentration and salt type. These dependencies are consistent with IRF1 DBD binding to DNA, resulting in the release of cations from the DNA and both release of anions from the protein and uptake of a cation by the protein. We demonstrated this by utilizing the fact that the release of fluoride from protein upon complex formation does not contribute to the salt concentration dependence of binding and by studying mutants in which charged residues in IRF1 DBD that form salt bridges with DNA phosphates are changed to alanine. The salt concentration dependencies of the dissociation constants of wild-type IRF1 DBD and the mutants R64A, D73A, K75A, and D73A/K75A were measured in buffer containing NaF, NaCl, or NaBr. The salt concentration and type dependencies of the mutants relative to wild-type IRF1 DBD provide evidence of charge neutralization by solution ions for R64 and by a salt bridge between D73 and K75 in buffer containing chloride or bromide salts. These data also allowed us to determine the number, type, and localization of condensed ions around both IRF1 DBD and its DNA binding site.     

Factor D is a selective single-stranded oligodeoxythymidine binding protein.

Factor D, a protein purified from rabbit liver that selectively enhances traversal of template oligodeoxythymidine tracts by diverse DNA polymerases, was examined for the sequence specificity of its binding to DNA. Terminally [32P]-labeled oligomers with the sequence 5'-d[AATTC(N)16G]-3', N being dT, dA, dG, or dC, were interacted with purified factor D and examined for the formation of protein-DNA complexes that exhibit retarded electrophoretic mobility under nondenaturing conditions. Whereas significant binding of factor D to 5'-d[AATTC(T)16G]-3' is detected, there is no discernable association between this protein and oligomers that contain 16 contiguous moieties of dG, dA, or dC. Furthermore, factor D does not form detectable complexes with the duplexes oligo(dA).oligo(dT) or poly(dA).poly(dT). The preferential interaction of factor D with single-stranded poly(dT) is confirmed by experiments in which the polymerase-enhancing activity of this protein is protected by poly(dT) against heat inactivation two- and four-fold more efficiently than by poly(dA) or poly(dA).poly(dT), respectively.