X-ray crystallographic and NMR studies of the third KH domain of hnRNP K in complex with single-stranded nucleic acids

The heterogeneous nuclear ribonucleoprotein (hnRNP) K is implicated in multiple functions in the regulation of gene expression and acts as a hub at the intersection of signaling pathways and processes involving nucleic acids. Central to its function is its ability to bind both ssDNA and ssRNA via its KH (hnRNP K homology) domains. We determined crystal structures of hnRNP K KH3 domain complexed with 15-mer and 6-mer (CTC(4)) ssDNAs at 2.4 and 1.8 A resolution, respectively, and show that the KH3 domain binds specifically to both TCCC and CCCC sequences. In parallel, we used NMR to compare the binding affinity and mode of interaction of the KH3 domain with several ssRNA ligands and CTC(4) ssDNA. Based on a structure alignment of the KH3-CTC(4) complex with known structures of other KH domains in complex with ssRNA, we discuss recognition of tetranucleotide sequences by KH domains.     

Backbone dynamics and refined solution structure of the N-terminal domain of DNA polymerase beta. Correlation with DNA binding and dRP lyase activity

Mammalian DNA polymerase beta functions in the base excision DNA repair pathway filling in short patches (1-5 nt) in damaged DNA and removing deoxyribose 5'-phosphate from the 5'-side of damaged DNA. The backbone dynamics and the refined solution structure of the N-terminal domain of beta-Pol have been characterized in order to establish the potential contribution(s) of backbone motion to the DNA binding and deoxyribose 5'-phosphate lyase function of this domain. The N-terminal domain is formed from four helices packed as two antiparallel pairs with a 60 degrees crossing between the pairs. The RMSD of the NMR conformers (residues 13-80) is 0.37 A for the backbone heavy atoms and 0.78 A for all heavy atoms. NMR characterization of the binding site(s) for a ssDNA-5mer, ssDNA-8mer, ssDNA-9mer, and dsDNA-12mer shows a consensus surface for the binding of these various DNA oligomers, that surrounds and includes the deoxyribose 5'-phosphate lyase active site region. Connection segments between helices 1 and 2 and between helices 3 and 4 each contribute to DNA binding. Helix-3-turn-helix-4 forms a helix-hairpin-helix motif. The highly conserved hairpin sequence (LPGVG) displays a significant degree of picosecond time-scale motion within the backbone, that is possibly important for DNA binding at the phosphodiester backbone. An Omega-loop connecting helices 1 and 2 and helix-2 itself display significant exchange contributions (R(ex)) at the backbone amides due to apparent conformational type motion on a millisecond time-scale. This motion is likely important in allowing the Omega-loop and helix-2 to shift toward, and productively interact with, gapped DNA. The deoxyribose 5'-phosphate lyase catalytic residues that include K72 which forms the Schiff's base, Y39 which is postulated to promote proton transfer to the aldehyde, and K35 which assists in phosphate elimination, show highly restricted backbone motion. H34, which apparently participates in detection of the abasic site hole and assists in the opening of the hemiacetal, shows conformational exchange.     

Solution structure and small angle scattering analysis of TraI (381-569)

TraI, the F plasmid-encoded nickase, is a 1756 amino acid protein essential for conjugative transfer of plasmid DNA from one bacterium to another. Although crystal structures of N- and C-terminal domains of F TraI have been determined, central domains of the protein are structurally unexplored. The central region (between residues 306 and 1520) is known to both bind single-stranded DNA (ssDNA) and unwind DNA through a highly processive helicase activity. Here, we show that the ssDNA binding site is located between residues 381 and 858, and we also present the high-resolution solution structure of the N-terminus of this region (residues 381-569). This fragment folds into a four-strand parallel β sheet surrounded by α helices, and it resembles the structure of the N-terminus of helicases such as RecD and RecQ despite little sequence similarity. The structure supports the model that F TraI resulted from duplication of a RecD-like domain and subsequent specialization of domains into the more N-terminal ssDNA binding domain and the more C-terminal domain containing helicase motifs. In addition, we provide evidence that the nickase and ssDNA binding domains of TraI are held close together by an 80-residue linker sequence that connects the two domains. These results suggest a possible physical explanation for the apparent negative cooperativity between the nickase and ssDNA binding domain.     

Kinetic mechanisms of rat polymerase beta-ssDNA interactions. Quantitative fluorescence stopped-flow analysis of the formation of the (Pol beta)(16) and (Pol beta)(5) ssDNA binding mode.

Kinetics of rat polymerase beta (pol beta) binding to the single-stranded DNA (ssDNA) in the (pol beta)(16) and (pol beta)(5) binding modes has been examined, using the fluorescence stopped-flow technique. Binding of the enzyme to the ssDNA containing fluorescein is characterized by a strong increase of the DNA fluorescence, which provides an excellent signal to quantitatively study the complex mechanism of the ssDNA recognition process. The experiments were performed with a 20-mer ssDNA, which can engage the enzyme in the (pol beta)(16) binding mode, i.e. it encompasses the entire, total DNA-binding site of rat pol beta, and with a 10-mer which binds the enzyme exclusively in the (pol beta)(5) binding mode where only the 8 kDa domain of the enzyme is engaged in interactions with the DNA. The data indicate that the formation of the (pol beta)(16) binding mode occurs by a minimum three-step mechanism with the bimolecular binding step followed by two isomerizations: [formula-see text] A similar mechanism is observed in the formation of the (pol beta)(5) binding mode, although at low salt concentrations there is an additional, slow step in the reaction. The data analysis was performed using the matrix projection operator technique, a powerful method to address stopped-flow kinetics, particularly, amplitudes. The binding modes differ in the free energy changes of the partial reactions and ion effects on transitions between intermediates that reflect different participation of the two structural domains. The formation of both binding modes is initiated by the fast association with the ssDNA through the 8 kDa domain, followed by transitions induced by interactions at the interface of the 8 kDa domain and the DNA. In the (pol beta)(16) binding mode, the subsequent intermediates are stabilized by the DNA binding to the DNA-binding subsite on the 31 kDa domain. The data indicate that interactions of the ssDNA-binding subsite of the 8 kDa domain with the ssDNA, controlled by the ion binding, induce conformational transitions of the formed complexes in both binding modes. The sequential nature of the determined mechanisms indicates a lack of kinetically significant conformational equilibrium of rat pol beta, prior to ssDNA binding.     

Identification of an expanded binding surface on the FADD death domain responsible for interaction with CD95/Fas

The initiation of programmed cell death at CD95 (Fas, Apo-1) is achieved by forming a death-inducing signaling complex (DISC) at the cytoplasmic membrane surface. Assembly of the DISC has been proposed to occur via homotypic interactions between the death domain (DD) of FADD and the cytoplasmic domain of CD95. Previous analysis of the FADD/CD95 interaction led to the identification of a putative CD95 binding surface within FADD DD formed by alpha helices 2 and 3. More detailed analysis of the CD95/FADD DD interaction now demonstrates that a bimodal surface exists in the FADD DD for interaction with CD95. An expansive surface on one side of the domain is composed of elements in alpha helices 1, 2, 3, 5, and 6. This major surface is common to many proteins harboring this motif, whether or not they are associated with programmed cell death. A secondary surface resides on the opposite face of the domain and involves residues in helices 3 and 4. The major surface is topologically similar to the protein interaction surface identified in Drosophila Tube DD and the death effector domain of hamster PEA-15, two physiologically unrelated proteins which interact with structurally unrelated binding partners. These results demonstrate the presence of a structurally conserved surface within the DD which can mediate protein recognition with homo- and heterotypic binding partners, whereas a second surface may be responsible for stabilizing the higher order complex in the DISC.     

Single-stranded DNA binding of the cold-shock protein CspB from Bacillus subtilis: NMR mapping and mutational characterization

Cold-shock proteins (CSPs) bind to single-stranded nucleic acids, thereby acting as a "RNA chaperone." To gain deeper insights into the rather unspecific nature of ssDNA/RNA binding, we characterized the binding interface of CspB from Bacillus subtilis to a 25-mer of ssDNA (Y-Box25) using heteronuclear 2D NMR spectroscopy. Seventeen residues, including eight out of nine aromatic amino acids, are directly involved in the Y-Box25 interaction and were identified by extreme line broadening of their cross-peaks. Eight residues belong to the earlier proposed RNP binding motifs. A second set of seven backbone amides becomes evident by major chemical shift perturbations reporting remote conformational rearrangements upon binding. These residues are located in loop beta3-beta4 and loopbeta4-beta5, and include Ile18. The individual contributions of the so-identified residues were examined by fluorescence titration experiments of 15 CspB variants. Phenylalanine substitutions in- and outside the RNP motifs significantly reduce the binding affinity. Unrestricted possible backbone conformations of loop beta3-beta4 also markedly contribute to binding. Stopped-flow fluorescence kinetics revealed that the different binding affinities of CspB variants are determined by the dissociation rate, whereas the association rate remains unchanged. This might be of importance for the "RNA chaperone" activity of CspB.     

Multiple-step kinetic mechanisms of the ssDNA recognition process by human polymerase beta in its different ssDNA binding modes

The kinetics of human polymerase beta (pol beta) binding to the single-stranded DNA, in the (pol beta)(16) and (pol beta)(5) binding modes, that differ in the number of occluded nucleotide residues in the protein-DNA complexes, have been examined, using the fluorescence stopped-flow technique. This is the first determination of the mechanism of ssDNA recognition by human pol beta. Binding of the enzyme to the ssDNA containing fluorescein in the place of one of the nucleotides is characterized by a strong DNA fluorescence increase, providing the required signal to quantitatively examine the complex mechanism of ssDNA recognition. The experiments were performed with the ssDNA 20-mer, which engages the polymerase in the (pol beta)(16) binding mode and encompasses the total DNA-binding site of the enzyme, and with the 10-mer, which exclusively forms the (pol beta)(5) binding mode engaging only the 8-kDa domain of the enzyme. The obtained data and analyses indicate that the (pol beta)(16) formation occurs by a minimum four-step, sequential mechanism: (reaction: see text). Formation of the (pol beta)(5) binding mode proceeds with the same mechanism; however, both binding modes differ in the energetics of the partial reactions and the structure of the intermediates. Quantitative amplitude analysis, using the matrix projection operator approach, allowed us to determine molar fluorescence intensities of all intermediates relative to the fluorescence of the free DNA. The results indicate that (pol beta)(16) binding mode formation, which is initiated by the association of the 8-kDa domain with the DNA, is followed by subsequent intermediates stabilized by DNA binding to the 31-kDa domain. Comparison with the (pol beta)(5) binding mode formation indicates that transitions of the enzyme-DNA complex in both modes are induced at the interface of the 8-kDa domain and the DNA. The sequential nature of the mechanism indicates the lack of a conformational preequilibrium of the enzyme prior to ssDNA binding.     

DNA-dependent protein kinase catalytic subunit. Structural requirements for kinase activation by DNA ends.

DNA-dependent protein kinase (DNA-PK) is a DNA end-activated protein kinase composed of a catalytic subunit, DNA-PKcs, and a DNA binding subunit, Ku, that is involved in repair of DNA double-stranded breaks (DSBs). We have previously shown that DNA-PKcs interacts with single-stranded DNA (ssDNA) ends with a separate ssDNA binding site to be activated for its kinase activity. Here, the properties of the ssDNA binding site were examined by using DNA fragments with modified ssDNA extensions. DNA fragments with a wide range of ssDNA modifictations activated DNA-PKcs, indicating a relaxed specificity for the chemical structure of terminal nucleotides of a DSB. Methyl substitution of the phosphate backbone impaired kinase activation but not binding, indicating that interaction with the DNA backbone was involved in kinase activation. Experiments with RNA and RNA/DNA hybrid fragments suggested that the discrimination between RNA and DNA ends resides in the double-stranded DNA binding function of DNA-PKcs. DNA fragments exposing only one ssDNA end activated DNA-PKcs poorly, suggesting that DNA-PKcs distinguishes between DSBs and ssDNA breaks by simultaneous interaction with two ssDNA ends. These properties potentially explain how DNA-PKcs can be specifically activated by DSBs but still recognize the diverse chemical structures exposed when DSBs are introduced by ionizing radiation.     

Mechanism of DNA binding by the DnaB helicase of Escherichia coli: analysis of the roles of domain gamma in DNA binding.

We have analyzed the mechanism of single-stranded DNA (ssDNA) binding mediated by the C-terminal domain gamma of the DnaB helicase of Escherichia coli. Sequence analysis of this domain indicated a specific basic region, "RSRARR", and a leucine zipper motif that are likely involved in ssDNA binding. We have carried out deletion as well as in vitro mutagenesis of specific amino acid residues in this region in order to determine their function(s) in DNA binding. The functions of the RSRARR domain in DNA binding were analyzed by site-directed mutagenesis. DnaBMut1, with mutations R(328)A and R(329)A, had a significant decrease in the DNA dependence of ATPase activity and lost its DNA helicase activity completely, indicating the important roles of these residues in DNA binding and helicase activities. DnaBMut2, with mutations R(324)A and R(326)A, had significantly attenuated DNA binding as well as DNA-dependent ATPase and DNA helicase activities, indicating that these residues also play a role in DNA binding and helicase activities. The role(s) of the leucine zipper dimerization motif was (were) determined by deletion analysis. The DnaB Delta 1 mutant with a 55 amino acid C-terminal deletion, which left the leucine zipper and basic DNA binding regions intact, retained DNA binding as well as DNA helicase activities. However, the DnaB Delta 2 mutant with a 113 amino acid C-terminal deletion that included the leucine zipper dimerization motif, but not the RSRARR sequence, lost DNA binding, DNA helicase activities, and hexamer formation. The major findings of this study are (i) the leucine zipper dimerization domain, I(361)-L(389), is absolutely required for (a) dimerization and (b) ssDNA binding; (ii) the base-rich RSRARR sequence is required for DNA binding; (iii) three regions of domain gamma (gamma I, gamma II, and gamma III) differentially regulate the ATPase activity; (iv) there are likely three ssDNA binding sites per hexamer; and (v) a working model of DNA unwinding by the DnaB hexamer is proposed.     

Backbone <Superscript>1</Superscript>H, <Superscript>13</Superscript>C and <Superscript>15</Superscript>N resonance assignments of the OB domain of the single stranded DNA-binding protein hSSB1 (NABP2/OBFC2B) and chemical shift mapping of the DNA-binding interface

Single-stranded DNA-binding proteins (SSBs) are highly important in DNA metabolism and play an essential role in all major DNA repair pathways. SSBs are generally characterised by the presence of an oligonucleotide binding (OB) fold which is able to recognise single-stranded DNA (ssDNA) with high affinity. We discovered two news SSBs in humans (hSSB1 and hSSB2) that both contain a single OB domain followed by a divergent spacer region and a charged C-terminus. We have extensively characterised one of these, hSSB1 (NABP2/OBFC2B), in numerous important DNA processing events such as, in DNA double-stranded break repair and in the response to oxidative DNA damage. Although the structure of hSSB1 bound to ssDNA has recently been determined using X-ray crystallography, the detailed atomic level mechanism of the interaction of hSSB1 with ssDNA in solution has not been established. In this study we report the solution-state backbone chemical shift assignments of the OB domain of hSSB1. In addition, we have utilized NMR to map the DNA-binding interface of hSSB1, revealing major differences between recognition of ssDNA under physiological conditions and in the recently determined crystal structure. Our NMR data in combination with further biophysical and biochemical experiments will allow us to address these discrepancies and shed light onto the structural basis of DNA-binding by hSSB1 in solution.     

Phosphorylation of replication protein A by S-phase checkpoint kinases

The major eukaryotic single-stranded DNA (ssDNA) binding protein, replication protein A (RPA), is a heterotrimer with subunits of 70, 32 and 14 kDa (RPA70, RPA32 and RPA14). RPA-coated ssDNA has been implicated as one of the triggers for intra-S-phase checkpoint activation. Phosphorylation of RPA occurs in cells with damaged DNA or stalled replication forks. Here we show that human RPA70 and RPA32 can be phosphorylated by purified S-phase checkpoint kinases, ATR and Chk1. While ATR phosphorylates the N-terminus of RPA70, Chk1 preferentially phosphorylates RPA's major ssDNA binding domain. Chk1 phosphorylated RPA70 shows reduced ssDNA binding activity, and binding of RPA to ssDNA blocks Chk1 phosphorylation, suggesting that Chk1 and ssDNA compete for RPA's major ssDNA binding domain. ssDNA stimulates RPA32 phosphorylation by ATR in a length dependent manner. Furthermore, 3'-, but not 5'-, recessed single strand/double strand DNA junctions produce an even stronger stimulatory effect on RPA32 phosphorylation by ATR. This stimulation occurs for both RNA and DNA recessed ends. RPA's DNA binding polarity and its interaction to 3'-primer-template junctions contribute to efficient RPA32 phosphorylation. Progression of DNA polymerase is able to block the accessibility of the 3'-recessed ends and prevent the stimulatory effects of primer-template junctions on RPA phosphorylation by ATR. We propose models for the role of RPA phosphorylation by Chk1 in S-phase checkpoint pathways, and the possible regulation of ATR activity by different nucleic acid structures.     

Crystal structures of Nova-1 and Nova-2 K-homology RNA-binding domains.

BACKGROUND: Nova-1 and Nova-2 are related neuronal proteins that were initially cloned using antisera obtained from patients with the autoimmune neurological disease paraneoplastic opsoclonus-myoclonus ataxia (POMA). Both of these disease gene products contain three RNA-binding motifs known as K-homology or KH domains, and their RNA ligands have been identified via binding-site selection experiments. The KH motif structure has been determined previously using NMR spectroscopy, but not using X-ray crystallography. Many proteins contain more than one KH domain, yet there is no published structural information regarding the behavior of such multimers. RESULTS: We have obtained the first X-ray crystallographic structures of KH-domain-containing proteins. Structures of the third KH domains (KH3) of Nova-1 and Nova-2 were determined by multiple isomorphous replacement and molecular replacement at 2.6 A and 2.0 A, respectively. These highly similar RNA-binding motifs form a compact protease-resistant domain resembling an open-faced sandwich, consisting of a three-stranded antiparallel beta sheet topped by three alpha helices. In both Nova crystals, the lattice is composed of symmetric tetramers of KH3 domains that are created by two dimer interfaces. CONCLUSIONS: The crystal structures of both Nova KH3 domains are similar to the previously determined NMR structures. The most significant differences among the KH domains involve changes in the positioning of one or more of the alpha helices with respect to the betasheet, particularly in the NMR structure of the KH1 domain of the Fragile X disease protein FMR-1. Loop regions in the KH domains are clearly visible in the crystal structure, unlike the NMR structures, revealing the conformation of the invariant Gly-X-X-Gly segment that is thought to participate in RNA-binding and of the variable region. The tetrameric arrangements of the Nova KH3 domains provide insights into how KH domains may interact with each other in proteins containing multiple KH motifs.     

Specific recognition of the C-rich strand of human telomeric DNA and the RNA template of human telomerase by the first KH domain of human poly(C)-binding protein-2

Poly(C)-binding proteins (PCBPs) constitute a family of nucleic acid-binding proteins that play important roles in a wide spectrum of regulatory mechanisms. The diverse functions of PCBPs are dependent on the ability of the PCBPs to recognize poly(C) sequences with high affinity and specificity. PCBPs contain three copies of KH (hnRNP K homology) domains, which are responsible for binding nucleic acids. We have determined the NMR structure of the first KH domain (KH1) from PCBP2. The PCBP2 KH1 domain adopts a structure with three alpha-helices packed against one side of a three-stranded antiparallel beta-sheet. Specific binding of PCBP2 KH1 to a number of poly(C) RNA and DNA sequences, including the C-rich strand of the human telomeric DNA repeat, the RNA template region of human telomerase, and regulatory recognition motifs in the poliovirus-1 5'-untranslated region, was established by monitoring chemical shift changes in protein (15)N-HSQC spectra. The nucleic acid binding groove was further mapped by chemical shift perturbation upon binding to a six-nucleotide human telomeric DNA. The binding groove is an alpha/beta platform formed by the juxtaposition of two alpha-helices, one beta-strand, and two flanking loops. Whereas there is a groove in common with all of the DNA and RNA binders with a hydrophobic floor accommodating a three-residue stretch of C residues, nuances in recognizing flanking residues are provided by hydrogen bonding partners in the KH domain. Specific interactions of PCBP2 KH1 with telomeric DNA and telomerase RNA suggest that PCBPs may participate in mechanisms involved in the regulation of telomere/telomerase functions.     

Monomers of the Escherichia coli SSB-1 mutant protein bind single-stranded DNA

The Escherichia coli wild-type single strand binding (SSB) protein is a stable tetramer that binds to single-stranded (ss) DNA in its role in DNA replication, recombination and repair. The ssb-1 mutation, a substitution of tyrosine for histidine-55 within the SSB-1 protein, destabilizes the tetramer with respect to monomers, resulting in a temperature-sensitive defect in a variety of DNA metabolic processes, including replication. Using quenching of the intrinsic SSB-1 tryptophan fluorescence, we have examined the equilibrium binding of the oligonucleotide, dT(pT)15, to the SSB-1 protein in order to determine whether a ssDNA binding site exists within individual SSB-1 monomers or whether the formation of the SSB tetramer is necessary for ssDNA binding. At high SSB-1 protein concentrations, such that the tetramer is stable, we find that four molecules of dT(pT)15 bind per tetramer in a manner similar to that observed for the wild-type SSB tetramer; i.e. negative co-operativity is observed for ssDNA binding to the SSB-1 protomers. As a consequence of this negative co-operativity, binding is biphasic, with two molecules of dT(pT)15 binding to the tetramer in each phase. However, the intrinsic binding constant, K16, for the SSB-1 protomer-dT(pT)15 interaction is a factor of 3 lower than for the wild-type protomer interaction and the negative co-operativity parameter, sigma 16, is larger in the case of the SSB-1 tetramer, indicating a lower degree of negative co-operativity. At lower SSB-1 concentrations, SSB-1 monomers bind dT(pT)15 without negative co-operativity; however, the intrinsic affinity of dT(pT)15 for the monomer is a factor of approximately 10 lower than for the protomer (50 mM-NaCl, pH 8.1, 25 degrees C). Therefore, an individual SSB-1 monomer does possess an independent ssDNA binding site; hence formation of the tetramer is not required for ssDNA binding, although tetramer formation does increase the binding affinity significantly. These data also show that the negative co-operativity among ssDNA binding sites within an SSB tetramer is an intrinsic property of the tetramer. On the basis of these studies, we discuss a modified explanation for the temperature-sensitivity of the ssb-1 phenotype.     

Amino acid sequences within the alpha subunit of integrin alpha M beta 2 (Mac-1) critical for specific recognition of C3bi.

Phagocytosis of opsonized particles by neutrophils and monocytes plays a central role in host defense mechanisms against foreign pathogens. This process depends on the interaction between C3bi, a degradation product derived from activation of the complement system, and the alpha M beta 2 (CD11b/CD18, Mac-1) receptor, the major integrin on neutrophils. Previous studies had established a central role for the I domain, a stretch of approximately 200 amino acids within the alpha M subunit in the binding of C3bi, as well as many other alpha M beta 2 ligands. The present study was undertaken to establish the molecular basis of C3bi recognition by alpha M beta 2. The strategy employed the use of a series of mutant receptors in which short segments of the I domain of alpha M were switched to the corresponding segments of alpha L, which is structurally very similar but does not bind C3bi. We report three major findings: (1) The C3bi binding pocket is composed of three regions, P147-R152, P201-K217, and K245-R261 of alpha M, which surround the cation binding site within the MIDAS motif of the I domain. (2) Within the latter segment, K245 plays a critical role in mediating C3bi binding to alpha M beta 2. Mutation of K245 to Ala significantly reduced C3bi binding but had no effect on binding of another alpha M beta 2 I domain ligand, NIF. (3) Blocking of C3bi binding to alpha M beta 2 by monoclonal antibodies is achieved through two different mechanisms: direct competition for the ligand binding site or induction of conformational changes. Overall, these studies support the hypothesis that many of the ligands of alpha M beta 2 bind to overlapping but not identical sites within the I domain. Although the same short structural segments within the I domain may be involved in binding, different amino acids within these segments may contact different ligands.     

Elucidating the mechanism of DNA-dependent ATP hydrolysis mediated by DNA-dependent ATPase A, a member of the SWI2/SNF2 protein family

The active DNA-dependent ATPase A domain (ADAAD), a member of the SWI2/SNF2 family, has been shown to bind DNA in a structure-specific manner, recognizing DNA molecules possessing double-stranded to single-stranded transition regions leading to ATP hydrolysis. Extending these studies we have delineated the structural requirements of the DNA effector for ADAAD and have shown that the single-stranded and double-stranded regions both contribute to binding affinity while the double-stranded region additionally plays a role in determining the rate of ATP hydrolysis. We have also investigated the mechanism of interaction of DNA and ATP with ADAAD and shown that each can interact independently with ADAAD in the absence of the other. Furthermore, the protein can bind to dsDNA as well as ssDNA molecules. However, the conformation change induced by the ssDNA is different from the conformational change induced by stem-loop DNA (slDNA), thereby providing an explanation for the observed ATP hydrolysis only in the presence of the double-stranded:single-stranded transition (i.e. slDNA).