Design,synthesis, and evaluation of novel N-1 fluoroquinolone derivatives: Probing for binding contact with the active site tyrosine of gyrase

Structural studies of topoisomerase-fluoroquinolone-DNA ternary complexes revealed a cavity between the quinolone N-1 position and the active site tyrosine. Fluoroquinolone derivatives having positively charged or aromatic moieties extended from the N-1 position were designed to probe for binding contacts with the phosphotyrosine residue in ternary complex. While alkylamine, alkylphthalimide, and alkylphenyl groups introduced at the N-1 position afforded derivatives that maintained modest inhibition of the supercoiling activity of DNA gyrase, none retained ability to poison DNA gyrase. Thus, the addition of a large and/or long moiety at the N-1 position disrupts ternary complex formation, and retained ability to inhibit supercoiling is likely through interference with the strand breakage reaction. Two derivatives were found to possess inhibitory effects on the decatenation activity of human topoisomerase II.     

Cisplatin-DNA adducts inhibit translocation of the Ku subunits of DNA-PK

We have determined the effect of cisplatin–DNA damage on the ability of the DNA-dependent protein kinase (DNA-PK) to interact with duplex DNA molecules in vitro. The Ku DNA binding subunits of DNA-PK display a reduced ability to translocate on duplex DNA containing cisplatin–DNA adducts compared to control, undamaged duplex DNA. The decreased rates of translocation resulted in a decrease in the association of the p460 catalytic subunit of DNA-PK (DNA-PKcs) with the Ku–DNA complex. In addition to a decrease in DNA-PKcs association, the DNA-PKcs that is bound with Ku at a DNA end containing cisplatin–DNA adducts has a reduced catalytic rate compared to heterotrimeric DNA-PK assembled on undamaged DNA. The position of the cisplatin–DNA lesion from the terminus also effects kinase activation, with maximal inhibition occurring when the lesion is closer to the terminus. These results are consistent with a model for DNA-PK activation where the Ku dimer translocates away from the DNA terminus and facilitates the association of DNA-PKcs which interacts with both Ku and DNA resulting in kinase activation. The presence of cisplatin adducts decreases the ability to translocate away from the terminus and results in the formation of inactive kinase complexes at the DNA terminus. The results are discussed with respect to the ability of cisplatin to sensitize cells to DNA damage induced by ionizing radiation and the ability to repair DNA double-strand breaks.     

Functional characterization of the Escherichia coli Fis-DNA binding sequence

The Escherichia coli protein Fis is remarkable for its ability to interact specifically with DNA sites of highly variable sequences. The mechanism of this sequence-flexible DNA recognition is not well understood. In a previous study, we examined the contributions of Fis residues to high-affinity binding at different DNA sequences using alanine-scanning mutagenesis and identified several key residues for Fis-DNA recognition. In this work, we investigated the contributions of the 15-bp core Fis binding sequence and its flanking regions to Fis-DNA interactions. Systematic base-pair replacements made in both half sites of a palindromic Fis binding sequence were examined for their effects on the relative Fis binding affinity. Missing contact assays were also used to examine the effects of base removal within the core binding site and its flanking regions on the Fis-DNA binding affinity. The results revealed that: (1) the − 7G and + 3Y bases in both DNA strands (relative to the central position of the core binding site) are major determinants for high-affinity binding; (2) the C⁵ methyl group of thymine, when present at the + 4 position, strongly hinders Fis binding; and (3) AT-rich sequences in the central and flanking DNA regions facilitate Fis-DNA interactions by altering the DNA structure and by increasing the local DNA flexibility. We infer that the degeneracy of specific Fis binding sites results from the numerous base-pair combinations that are possible at noncritical DNA positions (from − 6 to − 4, from − 2 to + 2, and from + 4 to + 6), with only moderate penalties on the binding affinity, the roughly similar contributions of − 3A or G and + 3T or C to the binding affinity, and the minimal requirement of three of the four critical base pairs to achieve considerably high binding affinities.     

Mapping of Escherichia coli RNA polymerase binding sites on 2-micrometers DNA from Saccharomyces cerevisiae. Heterogeneity within the inverted duplication and evidence for an eukaryotic invertible DNA sequence.

The 2-μm DNA plasmids from Saccharomyces cerevisiae strain H1 and strain HQ/5C were analyzed by electron microscopy for the presence of Escherichia coli RNA polymerase binding sites. On native 2-μm DNA isolated from strain HQ/5C five RNA polymerase binding sites were detected. One further site was mapped on cloned 2-μm DNA type 23 from S. cerevisiae strain H1. This additional site is located at a distance of 2.15 kilobases from EcoRI site B inside one of the inverted duplication (id) sequences. No such binding site could be detected in the other id sequence of the type 23 molecule, thus indicating that the two id sequences of strain H1 differ in at least one short region. The location of the id sequence carrying the RNA polymerase binding site was analyzed in native 2-μm DNA isolated from strain H1 and found to be present on HindIII fragment 2 and absent from HindIII fragment 5. This indicates that at least a part of the id sequences has a fixed position with respect to the unique S segment and further suggests a site specific recombination mechanism for the inversion of one of the unique segments. As a control for the specificity of RNA polymerase binding, we have mapped binding sites on vectors pBR313 and pBR322. The location of the E. coli RNA polymerase binding sites on 2-μm DNA is discussed in relation to the DNA regions expressed in E. coli minicells.     

Antisense inhibition of Flk-1 by oligonucleotides composed of 2'-deoxy-2'-fluoro-beta-D-arabino- and 2'-deoxy-nucleosides

The design of new antisense oligomers with improved binding affinity for targeted RNA, while still activating RNase H, is a major research area in medicinal chemistry. RNase H recognizes the RNA-DNA duplex and cleaves the complementary mRNA strand, providing the main mechanism by which antisense oligomers elicit their activities. It has been shown that configuration inversion at the C2' position of the DNA sugar moiety (arabinonucleic acid, ANA), combined with the substitution of the 2'OH group by a fluorine atom (2'F-ANA) increases the oligomer's binding affinity for targeted RNA. In the present study, we evaluated the antisense activity of mixed-backbone phosphorothioate oligomers composed of 2'-deoxy-2'-fluoro-beta-D-arabinose and 2'-deoxyribose sugars (S-2'F-ANA-DNA chimeras). We determined their abilities to inhibit the protein expression and phosphorylation of Flk-1, a vascular endothelial growth factor receptor (VEGF), and VEGF biological effects on endothelial cell proliferation, migration, and platelet-activating factor synthesis. Treatment of endothelial cells with chimeric oligonucleotides reduced Flk-1 protein expression and phosphorylation more efficiently than with phosphorothioate antisenses (S-DNA). Nonetheless, these two classes of antisenses inhibited VEGF activities equally. Herein, we also demonstrated the capacity of the chimeric oligomers to elicit RNase H activity and their improved binding affinity for complementary RNA as compared with S-DNA.     

Phase variation: genetic analysis of switching mutants

Site-specific inversion of a controlling element is responsible for flagellar phase transition in Salmonella. When a 900 bp DNA sequence is in one configuration, it allows the expression of the H2 gene, a structural gene which codes for the flagellar antigen. When it is in the opposite configuration, the H2 gene is not expressed. A hybrid λ phage containing the invertible control region and the adjacent H2 gene was constructed, and expression of the H2 gene was shown to be regulated by the orientation of the inversion region. Transposon Tn5 insertion derivatives of this hybrid phage were isolated and λH2::Tn5 mutants defective for inversion (H2 switching) were selected and characterized. Two classes of switching phenotypes were observed among the mutants—those which had slightly reduced frequencies of transition from expression of the H2 gene (H2 on) to nonexpression (H2 off) (intermediate class) and those in which the frequency of transition was reduced at least three orders of magnitude (null class). Physical mapping of the Tn5 insertion sites revealed that in all mutants the insertion was located inside the inversion region. Tn5 insertion sites in the null class of mutants defined a region of DNA including approximately 500 bp which was necessary for inversion. Genetic complementation tests showed that these λH2::Tn5 mutants could invert the H2 gene control element if the 500 bp region was introduced in the trans configuration. It is concluded that a gene is located inside the inversion segment and codes for a protein which is required for the inversion event. Furthermore, the two sites at which the crossover event occurred functioned in a cis configuration and were required for inversion. The presence of a gene which is involved in controlling site-specific recombination events may be a general feature of transposon-like elements.     

Structural motives controlling the binding affinity of 9,10-bis(methylpyridinium)anthracenes towards DNA

In the search of new DNA groove binding agents a series of substituted 9,10-methylpyridiniumanthracenes have been synthesized and their interactions with DNA have been studied by UV/vis absorption, CD and fluorescence spectroscopy. A minor groove binding mode is confirmed by DNA melting studies, strong CD effects, the dependence of the binding affinity on ionic strength, and the differentiation between AT and GC base pairs. No binding occurs to GC sequences. Binding constants to calf thymus DNA (ct-DNA) and poly(dA:dT) in the range between 1 × 10⁴ and 3 × 10⁵ M⁻¹ have been determined. The binding strength decreases with the size of substituents attached at the anthracene site. Variation of the substitution pattern of the charged groups shows that methyl groups in meta position cause slightly stronger binding than methyl groups in para position. In contrast, with these groups in ortho position, no binding interaction has been observed. The strongest binding is achieved with an expansion of the peripheral heterocycle from pyridine to quinoline. Molecular modeling reveals the pivotal role of the substitution pattern: Anthracenes with para and meta pyridines align along the minor grooves. On the other hand, the ortho derivative adopts no groove-alignment.     

Molecular structural effects involved in the interaction of anthracyclines with DNA.

Changes in DNA binding ability of daunomycin following structural modifications in the aglycone moiety have been studied by the fluorescence quenching method and by thermal denaturation of the complex. Removal of the methoxyl group at position 4 leads to a slightly stronger binding. Changes in the position of the glycosidic linkage result in a markedly weaker binding. Removal of the hydroxyl group at position 9, with the concomitant formation of a 9,10-anhydro derivative, decreases the binding ability. Methylation of hydroxyl groups at C-6 and C-11 leads to an inactive derivative and makes the binding affinity disappear almost completely. Structure-activity correlations for the DNA binding reaction deduced from these studies are in agreement with earlier findings that relate to the biological activity and confirm the general picture of the binding mechanism.     

Synapsis and strand exchange in the resolution and DNA inversion reactions catalysed by the beta recombinase

In the presence of a sequence-independent chromatin-associated protein, such as Hbsu or HMGB, the β recombinase catalyses resolution between two directly oriented recombination sites (six sites) and both resolution and DNA inversion between two inversely oriented six sites. Assembly of the synaptic complex requires binding of the β recombinase to the six sites and the presence of Hbsu. Whether resolution or inversion will take place depends on the relative orientation of the two six sites, the level of DNA supercoiling and the amounts of Hbsu. In this work, the topologies of the products of the resolution and inversion reactions were analysed. The resolution reaction generated mainly singly catenated DNA circles, while DNA inversion gave rise to unknotted circles and small amounts of DNA molecules containing 3- or 5-noded knots. In spite of the distinctive features of the β system, the topology of synapsis and strand exchange during the resolution reaction is similar to that of Tn3 and γδ resolvases. The ability of the β recombinase to catalyse both inversion and resolution reactions probably reflects different possible architectures of the synaptic complex, which to a large extent depends on Hbsu.     

A genetic approach to the identification of functional amino acids in protein p6 of Bacillus subtilis phage ø29

Protein p6 of the Bacillus subtilis phage ø29 is essential for in vivo viral DNA replication. This protein activates the initiation of ø29 DNA replication in vitro by forming a multimeric nucleoprotein complex at the replication origins. The N-terminal region of protein p6 is involved in DNA binding, as shown by in vitro studies with p6 proteins altered by deletions or missense mutations. We report on the development of an in vivo functional assay for protein p6. This assay is based on the ability of protein p6-producing B. subtilis non-suppressor (su ^?) cells to support growth of a ø29 sus6 mutant phage. We have used this trans-complementation assay to investigate the effect on in vivo viral DNA synthesis of missense mutations introduced into the protein p6 N-terminal region. The alteration of lysine to alanine at position 2 resulted in a partially functional protein, whereas the replacement of arginine by alanine at position 6 gave rise to an inactive protein. These results indicate that arginine at position 6 is critical for the in vivo activity of protein p6. Our complementation system provides a useful genetic approach for the identification of functionally important amino acids in protein p6.     

Studies on the structure—activity relationship among aliphatic and aromatic bisguanylhydrazones and some related compounds

A total of 18 compounds consisting of 7 aliphatic and 7 aromatic bis(guanylhydrazones), p-quinone-bis(guanylhydrazone), one monoguanylhydrazone, one diamidine and one diguanidine were studied spectrophotometrically to determine their ability to interact with native calf-thymus DNA and the possible correlation of binding with biological activity. In each case, the ability of a compound to bind to DNA correlated with its ability to inhibit the activity of DNA-dependent DNA polymerase (EC 2.7.7.7) extracted from mouse leukemia L1210 cells. For example, all the aromatic bis-guanylhydrazones and diamidine (hydroxystilbamidine), which were good inhibitors of the enzyme activity, showed a biphasic interaction with DNA. All the aliphatic compounds displayed no detectable interaction with DNA in the Tris buffer used, and were also poor inhibitors of the polymerase activity. Interaction of decamethylene diguanide (Synthalin) with DNA could not be determined because the compound does not absorb light in the UV-VIS region. However, in similarity with other aliphatic compounds, this agent was a poor inhibitor of DNA polymerase reaction. The p-quinone-bis(guanylhydrazone) and p-phenylbenzaldehyde-monoguanylhydrazone showed only a monophasic interaction with DNA and caused an intermediate inhibition of the enzyme activity. When tested for possible anti-leukemic activity against i.p. L1210 leukemia in syngeneic DBA/2J mice, all the aromatic bisguanylhydrazones as well as hydroxystilbamidine caused prolongation of survival of tumor-bearing mice. Among the aliphatic bisguanylhydrazones, all of which showed no binding to DNA and caused at the most only a very slight inhibition of DNA polymerase, only methylglyoxal-bis(guanylhydrazone) (CH₃-G) had antileukemic activity. Synthalin also inhibited leukemic growth. Evidences presented indicate that the mechanisms of action of aliphatic and aromatic bisguanylhydrazones may be quite different. Furthermore, the ability to bind to DNA may be a useful criterion to predict the antileukemic activity of aromatic guanylhydrazones and possibly other aromatic bis-cationic compounds, but not that of aliphatic congeners.     

DNA binding specificities of the long zinc-finger recombination protein PRDM9

Background

Meiotic recombination ensures proper segregation of homologous chromosomes and creates genetic variation. In many organisms, recombination occurs at limited sites, termed ''hotspots'', whose positions in mammals are determined by PR domain member 9 (PRDM9), a long-array zinc-finger and chromatin-modifier protein. Determining the rules governing the DNA binding of PRDM9 is a major issue in understanding how it functions.

Results

Mouse PRDM9 protein variants bind to hotspot DNA sequences in a manner that is specific for both PRDM9 and DNA haplotypes, and that in vitro binding parallels its in vivo biological activity. Examining four hotspots, three activated by Prdm9^Cst and one activated by Prdm9^Dom2, we found that all binding sites required the full array of 11 or 12 contiguous fingers, depending on the allele, and that there was little sequence similarity between the binding sites of the three Prdm9^Cst activated hotspots. The binding specificity of each position in the Hlx1 binding site, activated by Prdm9^Cst, was tested by mutating each nucleotide to its three alternatives. The 31 positions along the binding site varied considerably in the ability of alternative bases to support binding, which also implicates a role for additional binding to the DNA phosphate backbone.

Conclusions

These results, which provide the first detailed mapping of PRDM9 binding to DNA and, to our knowledge, the most detailed analysis yet of DNA binding by a long zinc-finger array, make clear that the binding specificities of PRDM9, and possibly other long-array zinc-finger proteins, are unusually complex.