TraY DNA recognition of its two F factor binding sites

F factor TraY, a ribbon-helix-helix DNA-binding protein, performs two roles in bacterial conjugation. TraY binds the F origin of transfer (oriT) to promote nicking of plasmid DNA prior to conjugative transfer. TraY also binds the P(Y) promoter to up-regulate tra gene expression. The two plasmid regions bound by TraY share limited sequence identity, yet TraY binds them with similar affinities. TraY recognition of the two sites was first probed using in vitro footprinting methods. Hydroxyl radical footprinting at both oriT and P(Y) sites indicated that bound TraY protected the DNA backbone bordering three adjacent DNA subsites. Analytical ultracentrifugation results for TraY:oligonucleotide complexes were consistent with two of these subsites being bound cooperatively, and the third being occupied at higher TraY concentrations. Methylation protection and interference footprinting identified several guanine bases contacted by or proximal to bound TraY, most located within these subsites. TraY affinity for variant oriT sequences with base substitutions at or near these guanine bases suggested that two of the three subsites correspond to high-affinity, cooperatively bound imperfect inverted GA(G/T)A repeats. Altering the spacing or orientation of these sites reduced binding. TraY mutant R73A failed to protect two symmetry-related oriT guanine bases in these repeats from methylation, identifying possible direct TraY-DNA contacts. The third subsite appears to be oriented as an imperfect direct repeat with its adjacent subsite, although base substitutions at this subsite did not reduce binding. Although unusual for ribbon-helix-helix proteins, this binding site arrangement occurs at both F TraY sites, consistent with it being functionally relevant.     

Analysis of nuclear factor I binding to DNA using degenerate oligonucleotides.

Nuclear factor I (NFI) binds tightly to DNA containing the consensus sequence TGG(N)6-7GCCAA. To study the role of the spacing between the TGG and GCCAA motifs, oligonucleotides homologous to the NFI binding site FIB-2 were synthesized and used for binding assays in vitro. The wild-type site (FIB-2.6) has a 6bp spacer region and binds tightly to NFI. When the size of this spacer was altered by +/- 1 or 2bp the binding to NFI was abolished. To further assess the role of the spacer and bases flanking the motifs, two oligonucleotide libraries were synthesized. Each member of these libraries had intact TGG and GCCAA motifs, but the sequence of the spacer and the 3bp next to each motif was degenerate. The library with a 6bp spacer bound to NFI to 40-50% the level of FIB-2.6. The library with a 7bp spacer bound to NFI to only 4% the level of FIB-2.6 and some of this binding was weaker than that of FIB-2.6 DNA. This novel use of degenerate DNA libraries has shown that: 1) the structural requirements for FIB sites with a 7bp spacer are more stringent than for sites with a 6bp spacer and 2) a limited number of DNA structural features can prevent the binding of NFI to sites with intact motifs and a 6bp spacer region.     

Polymerase chain reaction of genes flanked by short noncontiguous sequence motifs

Short DNA sequence motifs have been demonstrated to interact with DNA binding proteins and regulate flanking genes. The short nature and the lack of continuity of many of these DNA binding sites make it difficult to develop an approach to characterize genes that have the same flanking sequences. We tested various oligonucleotide combinations using an immunoglobulin variable region gene family as a model amplification system. One successful amplification strategy used an oligonucleotide containing two known noncontiguous short sequences connected by random insertion of all four bases to maintain the appropriate spacing. A second approach used an oligonucleotide having a single short homologous sequence with the addition of all four bases randomly placed at the 5' end to increase the extent of homology. Both strategies will permit the priming of members of a specific gene family, with the two short sequences bridged by all four bases randomly added being more efficient in the amplification process.     

P1 partition complex assembly involves several modes of protein-DNA recognition

Assembly of P1 plasmid partition complexes at the partition site, parS, is nucleated by a dimer of P1 ParB and Escherichia coli integration host factor (IHF), which promotes loading of more ParB dimers and the pairing of plasmids during the cell cycle. ParB binds several copies of two distinct recognition motifs, known as A- and B-boxes, which flank a bend in parS created by IHF binding. The recent crystal structure of ParB bound to a partial parS site revealed two relatively independent DNA-binding domains and raised the question of how a dimer of ParB recognizes its complicated arrangement of recognition motifs when it loads onto the full parS site in the presence of IHF. In this study, we addressed this question by examining ParB binding activities to parS mutants containing different combinations of the A- and B-box motifs in parS. Binding was measured to linear and supercoiled DNA in electrophoretic and filter binding assays, respectively. ParB showed preferences for certain motifs that are dependent on position and on plasmid topology. In the simplest arrangement, one motif on either side of the bend was sufficient to form a complex, although affinity differed depending on the motifs. Therefore, a ParB dimer can load onto parS in different ways, so that the initial ParB-IHF-parS complex consists of a mixture of different orientations of ParB. This arrangement supports a model in which parS motifs are available for interas well as intramolecular parS recognition.     

The Arabidopsis TAG1 transposase has an N-terminal zinc finger DNA binding domain that recognizes distinct subterminal motifs

The in vitro DNA binding activity of the Arabidopsis Tag1 transposase (TAG1) was characterized to determine the mechanism of DNA recognition. In addition to terminal inverted repeats, the Tag1 element contains four different subterminal repeats that flank a transcribed region encoding a 729-amino acid protein. A single site-specific DNA binding domain is located near the N terminus of TAG1, between residues 21 and 133. This domain binds specifically to the AAACCC and TGACCC subterminal repeats, found near the 5' and 3' ends of the element, respectively. The ACCC sequence within these repeats is critical for recognition because mutations at positions 3, 5, and 6 abolished binding, yet the first two bases also are important because substitutions at these positions decreased binding by up to 90%. Weak interaction also occurs with the terminal inverted repeats, but no binding was observed to the other two 3' subterminal repeat regions. Sequence analysis of the TAG1 DNA binding domain revealed a C(2)HC zinc finger motif. Tests for metal dependence showed that DNA binding activity was inhibited by divalent metal chelators and greatly enhanced by zinc. Furthermore, mutation of each cysteine residue predicted to be a metal ligand in the C(2)HC motif abolished DNA binding. Together, these data show that the DNA binding domain of TAG1 specifically binds to distinct subterminal repeats and contains a zinc finger.     

Confirmation of a second natural preQ1 aptamer class in Streptococcaceae bacteria

Bioinformatics searches of eubacterial genomes have yielded many riboswitch candidates where the identity of the ligand is not immediately obvious on examination of associated genes. One of these motifs is found exclusively in the family Streptococcaceae within the 5' untranslated regions (UTRs) of genes encoding the hypothetical membrane protein classified as COG4708 or DUF988. While the function of this protein class is unproven, a riboswitch binding the queuosine biosynthetic intermediate pre-queuosine(1) (preQ(1)) has been identified in the 5' UTR of homologous genes in many Firmicute species of bacteria outside of Streptococcaceae. Here we show that a representative of the COG4708 RNA motif from Streptococcus pneumoniae R6 also binds preQ(1). Furthermore, representatives of this RNA have structural and molecular recognition characteristics that are distinct from those of the previously described preQ(1) riboswitch class. PreQ(1) is the second metabolite for which two or more distinct classes of natural aptamers exist, indicating that natural aptamers utilizing different structures to bind the same metabolite may be more common than is currently known. Additionally, the association of preQ(1) binding RNAs with most genes encoding proteins classified as COG4708 strongly suggests that these proteins function as transporters for preQ(1) or another queuosine biosynthetic intermediate.     

Specific interactions of distamycin with G-quadruplex DNA

Distamycin binds the minor groove of duplex DNA at AT-rich regions and has been a valuable probe of protein interactions with double-stranded DNA. We find that distamycin can also inhibit protein interactions with G-quadruplex (G4) DNA, a stable four-stranded structure in which the repeating unit is a G-quartet. Using NMR, we show that distamycin binds specifically to G4 DNA, stacking on the terminal G-quartets and contacting the flanking bases. These results demonstrate the utility of distamycin as a probe of G4 DNA–protein interactions and show that there are (at least) two distinct modes of protein–G4 DNA recognition which can be distinguished by sensitivity to distamycin.