Solution structure of DNA/RNA hybrid duplex with C8-propynyl 2′-deoxyadenosine modifications: Implication of RNase H and DNA/RNA duplex interaction

Solution structures of DNA/RNA hybrid duplexes, d(GCGCA*AA*ACGCG): r(cgcguuuugcg)d(C) (designated PP57), containing two C8-propynyl 2′-deoxyadenosines (A*) and unmodified hybrid (designated U4A4) are solved. The C8-propynyl groups on 2′-deoxyadenosine perturb the local structure of the hybrid duplex, but overall the structure is similar to that of canonical DNA/RNA hybrid duplex except that Hoogsteen hydrogen bondings between A* and U result in lower thermal stability. RNase H is known to cleave RNA only in DNA/RNA hybrid duplexes. Minor groove widths of hybrid duplexes, sugar puckerings of DNA are reported to be responsible for RNase H mediated cleavage, but structural requirements for RNase H mediated cleavage still remain elusive. Despite the presence of bulky propynyl groups of PP57 in the minor groove and greater flexibility, the PP57 is an RNase H substrate. To provide an insight on the interactions between RNase H and substrates we have modeled Bacillus halodurans RNase H-PP57 complex, our NMR structure and modeling study suggest that the residue Gly(15) and Asn(16) of the loop residues between first β sheet and second β sheet of RNase HI of Escherichia coli might participate in substrate binding.     

Solution structure of actinomycin-DNA complexes: Drug intercalation at isolated G-C sites

Summary The actinomycin-D-d(A1-A2-A3-G4-C5-T6-T7-T8) complex (1 drug per duplex) has been generated in aqueous solution and its structure characterized by a combined application of two-dimensional NMR experiments and molecular dynamics calculations. We have assigned the exchangeable and nonexchangeable proton resonances of Act and d(A₃GCT₃) in the complex and identified the intermolecular proton-proton NOES that define the alignment of the antitumor agent at its binding site on duplex DNA. The molecular dynamics calculations were guided by 70 intermolecular distance constraints between Act and nucleic acid protons in the complex. The phenoxazone chromophore of Act intercalates at the (G-C)_I·(G-C)_II step in the d(A₃GCT₃) duplex with the phenoxazone ring stacking selectively with the G4_I and G4_II purine bases but not with C4_I and C4_II pyrimidine bases at the intercalation site. There is a pronounced unwinding between the A3·T6 and G4·C5 base pairs which are the next steps located in either direction from the intercalation site in the Act-d(A₃GCT₃) complex. The Act cyclic pentapeptide ring conformations in the complex are similar to those for free Act in the crystal except for a change in orientation of the ester linkage connecting meVal and Thr residues. The cyclic pentapeptide rings are positioned in the minor groove with the established G-C sequence specificity of binding associated with intermolecular hydrogen bonds between the Thr backbone CO and NH groups to the NH₂-2 and N3 positions of guanosine, respectively. Complex formation is also stabilized by van der Waals interactions between nonpolar groups on the cyclic pentapeptide rings and the sugar residues and base pair edges lining the widened minor groove of the (A3-G4-C5-T6)_I·(A3-G4-C5-T6)_II binding site segment of the DNA helix.Dedicated to the memory of Professor V.F. Bystrov     

A lysine residue in the fingers subdomain of T7 DNA polymerase modulates the miscoding potential of 8-oxo-7,8-dihydroguanosine

8-oxo-7,8-dihydroguanosine (8oG) is a highly mutagenic DNA lesion that stably pairs with adenosine, forming 8oG(syn).dA(anti) Hoogsteen base pairs. DNA polymerases show different propensities to insert dCMP or dAMP opposite 8oG, but the molecular mechanisms that determine faithful or mutagenic bypass are poorly understood. Here, we report kinetic and structural data providing evidence that, in T7 DNA polymerase, residue Lys536 is responsible for attenuating the miscoding potential of 8oG. The Lys536Ala polymerase shows a significant increase in mutagenic 8oG bypass versus wild-type polymerase, and a crystal structure of the Lys536Ala mutant reveals a closed complex with an 8oG(syn).dATP mismatch in the polymerase active site, in contrast to the unproductive, open complex previously obtained by using wild-type polymerase. We propose that Lys536 acts as a steric and/or electrostatic filter that attenuates the miscoding potential of 8oG by normally interfering with the binding of 8oG in a syn conformation that pairs with dATP.     

Mutational specificities of brominated DNA adducts catalyzed by human DNA polymerases

Chronic inflammation is known to lead to an increased risk for the development of cancer. Under inflammatory condition, cellular DNA is damaged by hypobromous acid, which is generated by myeloperoxidase and eosinophil peroxidase. The reactive brominating species induced brominated DNA adducts such as 8-bromo-2′-deoxyguanosine (8-Br-dG), 8-bromo-2′-deoxyadenosine (8-Br-dA), and 5-bromo-2′-deoxycytidine (5-Br-dC). These DNA lesions may be implicated in carcinogenesis. In this study, we analyzed the miscoding properties of the brominated DNA adducts generated by human DNA polymerases (pols). Site-specifically modified oligodeoxynucleotides containing a single 8-Br-dG, 8-Br-dA, or 5-Br-dC were used as a template in primer extension reactions catalyzed by human pols α, κ, and η. When 8-Br-dG-modified template was used, pol α primarily incorporated dCMP, the correct base, opposite the lesion, along with a small amount of one-base deletion (4.8%). Pol κ also promoted one-base deletion (14.2%), accompanied by misincorporation of dGMP (9.5%), dAMP (8.0%), and dTMP (6.1%) opposite the lesion. Pol η, on the other hand, readily bypassed the 8-Br-dG lesion in an error-free manner. As for 8-Br-dA and 5-Br-dC, all the pols bypassed the lesions and no miscoding events were observed. These results indicate that only 8-Br-dG, and not 5-Br-dC and 8-Br-dA, is a mutagenic lesion; the miscoding frequency and specificity vary depending on the DNA pol used. Thus, hypobromous acid-induced 8-Br-dG adduct may increase mutagenic potential at the site of inflammation.     

Folding Topology of a Bimolecular DNA Quadruplex Containing a Stable Mini-hairpin Motif within the Diagonal Loop

We describe the NMR structural characterisation of a bimolecular anti-parallel DNA quadruplex d(G₃ACGTAGTG₃)₂ containing an autonomously stable mini-hairpin motif inserted within the diagonal loop. A folding topology is identified that is different from that observed for the analogous d(G₃T₄G₃)₂ dimer with the two structures differing in the relative orientation of the diagonal loops. This appears to reflect specific base stacking interactions at the quadruplex-duplex interface that are not present in the structure with the T₄-loop sequence. A truncated version of the bimolecular quadruplex d(G₂ACGTAGTG₂)₂, with only two core G-tetrads, is less stable and forms a heterogeneous mixture of three 2-fold symmetric quadruplexes with different loop arrangements. We demonstrate that the nature of the loop sequence, its ability to form autonomously stable structure, the relative stabilities of the hairpin loop and core quadruplex, and the ability to form favourable stacking interactions between these two motifs are important factors in controlling DNA G-quadruplex topology.     

Structural basis for molecular recognition in an affibody:affibody complex

Affibody molecules constitute a class of engineered binding proteins based on the 58-residue three-helix bundle Z domain derived from staphylococcal protein A (SPA). Affibody proteins are selected as binders to target proteins by phage display of combinatorial libraries in which typically 13 side-chains on the surface of helices 1 and 2 in the Z domain have been randomized. The Z(Taq):anti-Z(Taq) affibody-affibody complex, consisting of Z(Taq), originally selected as a binder to Taq DNA polymerase, and anti-Z(Taq), selected as binder to Z(Taq), is formed with a dissociation constant K(d) approximately 100 nM. We have determined high-precision solution structures of free Z(Taq) and anti-Z(Taq), and the Z(Taq):anti-Z(Taq) complex under identical experimental conditions (25 degrees C in 50 mM NaCl with 20 mM potassium phosphate buffer at pH 6.4). The complex is formed with helices 1 and 2 of anti-Z(Taq) in perpendicular contact with helices 1 and 2 of Z(Taq). The interaction surface is large ( approximately 1670 A(2)) and unusually non-polar (70 %) compared to other protein-protein complexes. It involves all varied residues on anti-Z(Taq), most corresponding (Taq DNA polymerase binding) side-chains on Z(Taq), and several additional side-chain and backbone contacts. Other notable features include a substantial rearrangement (induced fit) of aromatic side-chains in Z(Taq) upon binding, a close contact between glycine residues in the two subunits that might involve aliphatic glycine Halpha to backbone carbonyl hydrogen bonds, and four hydrogen bonds made by the two guanidinium N(eta)H(2) groups of an arginine side-chain. Comparisons of the present structure with other data for affibody proteins and the Z domain suggest that intrinsic binding properties of the originating SPA surface might be inherited by the affibody binders. A thermodynamic characterization of Z(Taq) and anti-Z(Taq) is presented in an accompanying paper.     

Solution Structure of Human ζ-COP: Direct Evidences for Structural Similarity between COP I and Clathrin-Adaptor Coats

COP-I-coated vesicles are protein and lipid carriers that mediate intra-Golgi transport and transport from the cis-Golgi complex to the endoplasmic reticulum in cells. The coatomer of the vesicles coat is comprised of seven subunits: α-COP, ?-COP, β′-COP, β-COP, γ-COP, δ-COP, and ζ-COP. Here we report the solution structure of a truncated form (residues 1-149; ζ-COP149) of human ζ-COP (total 177 residues). It is the first three-dimensional structure of a “core” subunit of the COP I F-subcomplex. The structure of ζ-COP149 mainly consists of a disordered N-terminal tail, a five-stranded antiparallel β-sheet, a two-stranded antiparallel β-sheet, and five α-helices. The global folding of ζ-COP149 is very similar to the crystal structures of AP1-σ1 and AP2-σ2, directly demonstrating the structural similarity between the “core” subunits of the COP I F-subcomplex and adaptor protein complexes. Through structural comparison and mutagenesis study, we have also demonstrated that the heterodimers of ζ-COP149 and γ-COP have packing interfaces and relative subunit orientations similar to those of AP2-σ2 and AP2-α heterodimers. These results provide direct evidence supporting the previous proposal that the COP I F-subcomplex and adaptor protein complexes have similar tertiary and quaternary structures.     

A crystallographic study of the role of sequence context in thymine glycol bypass by a replicative DNA polymerase serendipitously sheds light on the exonuclease complex

Thymine glycol (Tg) is the most common oxidation product of thymine and is known to be a strong block to replicative DNA polymerases. A previously solved structure of the bacteriophage RB69 DNA polymerase (RB69 gp43) in complex with Tg in the sequence context 5′-G-Tg-G shed light on how Tg blocks primer elongation: The protruding methyl group of the oxidized thymine displaces the adjacent 5′-G, which can no longer serve as a template for primer elongation [Aller, P., Rould, M. A., Hogg, M, Wallace, S. S. & Doublié S. (2007). A structural rationale for stalling of a replicative DNA polymerase at the most common oxidative thymine lesion, thymine glycol. Proc. Natl. Acad. Sci. USA, 104, 814-818.].Several studies showed that in the sequence context 5′-C-Tg-purine, Tg is more likely to be bypassed by Klenow fragment, an A-family DNA polymerase. We set out to investigate the role of sequence context in Tg bypass in a B-family polymerase and to solve the crystal structures of the bacteriophage RB69 DNA polymerase in complex with Tg-containing DNA in the three remaining sequence contexts: 5′-A-Tg-G, 5′-T-Tg-G, and 5′-C-Tg-G. A combination of several factors—including the associated exonuclease activity, the nature of the 3′ and 5′ bases surrounding Tg, and the cis-trans interconversion of Tg—influences Tg bypass. We also visualized for the first time the structure of a well-ordered exonuclease complex, allowing us to identify and confirm the role of key residues (Phe123, Met256, and Tyr257) in strand separation and in the stabilization of the primer strand in the exonuclease site.     

Solution NMR Studies of Chlorella Virus DNA Ligase-adenylate

DNA ligases are essential guardians of genome integrity by virtue of their ability to recognize and seal 3′-OH/5′-phosphate nicks in duplex DNA. The substrate binding and three chemical steps of the ligation pathway are coupled to global and local changes in ligase structure, involving both massive protein domain movements and subtle remodeling of atomic contacts in the active site. Here we applied solution NMR spectroscopy to study the conformational dynamics of the Chlorella virus DNA ligase (ChVLig), a minimized eukaryal ATP-dependent ligase consisting of nucleotidyltransferase, OB, and latch domains. Our analysis of backbone ¹⁵N spin relaxation and ¹⁵N,¹H residual dipolar couplings of the covalent ChVLig-AMP intermediate revealed conformational sampling on fast (picosecond to nanosecond) and slow timescales (microsecond to millisecond), indicative of interdomain and intradomain flexibility. We identified local and global changes in ChVLig-AMP structure and dynamics induced by phosphate. In particular, the chemical shift perturbations elicited by phosphate were clustered in the peptide motifs that comprise the active site. We hypothesize that phosphate anion mimics some of the conformational transitions that occur when ligase-adenylate interacts with the nick 5′-phosphate.     

Structure, folding and stability of FimA, the main structural subunit of type 1 pili from uropathogenic Escherichia coli strains

Filamentous type 1 pili are responsible for attachment of uropathogenic Escherichia coli strains to host cells. They consist of a linear tip fibrillum and a helical rod formed by up to 3000 copies of the main structural pilus subunit FimA. The subunits in the pilus interact via donor strand complementation, where the incomplete, immunoglobulin-like fold of each subunit is complemented by an N-terminal donor strand of the subsequent subunit. Here, we show that folding of FimA occurs at an extremely slow rate (half-life: 1.6 h) and is catalyzed more than 400-fold by the pilus chaperone FimC. Moreover, FimA is capable of intramolecular self-complementation via its own donor strand, as evidenced by the loss of folding competence upon donor strand deletion. Folded FimA is an assembly-incompetent monomer of low thermodynamic stability (− 10.1 kJ mol^− 1) that can be rescued for pilus assembly at 37 °C because FimC selectively pulls the fraction of unfolded FimA molecules from the FimA folding equilibrium and allows FimA refolding on its surface. Elongation of FimA at the C-terminus by its own donor strand generated a self-complemented variant (FimAa) with alternative folding possibilities that spontaneously adopts the more stable conformation (− 85.0 kJ mol^− 1) in which the C-terminal donor strand is inserted in the opposite orientation relative to that in FimA. The solved NMR structure of FimAa revealed extensive β-sheet hydrogen bonding between the FimA pilin domain and the C-terminal donor strand and provides the basis for reconstruction of an atomic model of the pilus rod.     

Solution Structure of RCL, a Novel 2′-Deoxyribonucleoside 5′-Monophosphate N-glycosidase

RCL is an enzyme that catalyzes the N-glycosidic bond cleavage of purine 2′-deoxyribonucleoside 5′-monophosphates, a novel enzymatic reaction reported only recently. In this work, we determined the solution structure by multidimensional NMR and provide a structural framework to elucidate its mechanism with computational simulation. RCL is a symmetric homodimer, with each monomer consisting of a five-stranded parallel β-sheet sandwiched between five α-helices. Three of the helices form the dimer interface, allowing two monomers to pack side by side. The overall architecture featuring a Rossmann fold is topologically similar to that of deoxyribosyltransferases, with major differences observed in the putative substrate binding pocket and the C-terminal tail. The latter is seemingly flexible and projecting away from the core structure in RCL, but loops back and is positioned at the bottom of the neighboring active site in the transferases. This difference may bear functional implications in the context of nucleobase recognition involving the C-terminal carboxyl group, which is only required in the reverse reaction by the transferases. It was also noticed that residues around the putative active site show significant conformational variation, suggesting that protein dynamics may play an important role in the enzymatic function of apo-RCL. Overall, the work provides invaluable insight into the mechanism of a novel N-glycosidase from the structural point of view, which in turn will allow rational anti-tumor and anti-angiogenesis drug design.     

NMR structural characterization of the penta-peptide calpain inhibitor

Calpains are ubiquitous intracellular calcium- and thiol-dependent proteases. Their over activation, resulting in the degradation of various substrates, has been implicated in a number of cardiovascular and neurological disorders. Here, we present the first structural characterization of LSEAL penta-peptide, a potent calpain inhibitor, bound to the calmodulin-like domain of calpain. Our in vitro binding data supports the idea that domains other than calpain’s active site may be suitable targets for future development of therapeutic agents to be used to treat heart attack, traumatic brain injuries or a variety of neurodegenerative conditions, such as ischemic stroke.