Structural studies of a stable parallel-stranded DNA duplex incorporating isoguanine:cytosine and isocytosine:guanine basepairs by nuclear magnetic resonance spectroscopy

Isoguanine (2-hydroxyladenine) is a product of oxidative damage to DNA and has been shown to cause mutation. It is also a potent inducer of parallel-stranded DNA duplex structure. The structure of the parallel-stranded DNA duplex (PS-duplex) 5'-d(TiGiCAiCiGiGAiCT) + 5'-d(ACGTGCCTGA), containing the isoguanine (iG) and 5-methyl-isocytosine (iC) bases, has been determined by NMR refinement. All imino protons associated with the iG:C, G:iC, and A:T (except the two terminal A:T) basepairs are observed at 2 degrees C, consistent with the formation of a stable duplex suggested by the earlier Tm measurements [Sugiyama, H., S. Ikeda, and I. Saito. 1996. J. Am. Chem. Soc. 118:9994-9995]. All basepairs are in the reverse Watson-Crick configuration. The structural characteristics of the refined PS-duplex are different from those of B-DNA. The PS duplex has two grooves with similar width (7.0 A) and depth (7.7 A), in contrast to the two distinct grooves (major groove width 11.7 A, depth 8.5 A, and minor groove width 5.7 A, depth 7.5 A) of B-DNA. The resonances of the amino protons of iG and C are clearly resolved and observable, but those of the G and iC are very broad and difficult to observe. Several intercalators with different complexities, including ethidium, daunorubicin, and nogalamycin, have been used to probe the flexibility of the backbone of the (iG, iC)-containing PS-duplex. All of them produce drug-induced UV/vis spectra identical to their respective spectra when bound to B-DNA, suggesting that those drugs bind to the (iG, iC)-containing PS-duplex using similar intercalation processes. The results may be useful in the design of intercalator-conjugated oligonucleotides for antisense applications. The study presented in this paper augments our understanding of a growing number of parallel-stranded DNA structures, including the G-quartet, the i-motif, and the unusual homo basepaired parallel-stranded double helix. Their possible relevance is discussed.

Structural polymorphism and raman conformation markers of cyclic deoxytriadenylic acid

X-ray analysis of two different trigonal crystal forms (space groups R32 and P3 ) of cyclic deoxytriadenylic acid [c(dAp)3] indicates for each an asymmetric unit consisting of two conformationally similar c(dAp)3molecules. Raman spectroscopy supports the X-ray interpretation for the R32 crystal, but identifies another c(dAp)3conformation not revealed in the P3 X-ray structure. The results for the P3 crystal can be explained if an additional c(dAp)3conformer is present but not sufficiently ordered within the lattice to contribute to X-ray diffraction. The Raman signature of aqueous c(dAp)3, which differs from signatures of both the R32 and P3 crystals, exhibits backbone markers similar to those of thermally denatured DNA and indicates that c(dAp)3molecules in solution populate a wider range of phosphoester ring conformations than in R32 and P3 crystals. Thus, polymorphism is observed for both crystal and solution structures of c(dAp)3. The results imply a highly flexible phosphoester ring that may be relevant to the function of cyclic oligonucleotides as biological effectors. A novel Raman marker at 821 cm-1is demonstrated as diagnostic of phosphoester torsions alpha and zeta in the gauche+ range. Specific Raman markers are also identified for the S -type (C2'- endo) deoxyadenosine conformations that occur in R32 and P3 crystal structures of c(dAp)3.

Monofunctional platinum amine complexes destabilize DNA significantly

Both cis-[Pt(NH3)2(4-Me-Py)Cl]+ and trans-[Pt(NH3)2(4-Me-Py)Cl]+ bind DNA covalently at the N7 site of guanine residues forming mono-dentate adducts. However, like cisplatin and transplatin, only the cis isomer has anti-cancer activity, whereas the trans-isomer does not. In order to understand the molecular basis of the different activities associated with cis-[Pt(NH3)2(4-Me-Py)Cl]+ and trans-[Pt(NH3)2(4-Me-Py)Cl]+, the interactions of these two platinum compounds with the DNA heptamer CCTG*TCC:GGACAGG duplex (G* is the platinated guanine) have been examined. The reaction rate of cis-[Pt(NH3)2(4-Me-Py)Cl]+ with the single-stranded CCTGTCC is significantly faster than that of the trans isomer. The solution structure of the platinum-DNA adducts has been studied by two-dimensional NMR spectroscopy. Both the cis-platinum adducts and the trans-platinum adducts destabilize the DNA duplex significantly. The melting temperature (Tm) of the platinated heptamer duplex is estimated to be 10 degrees C lower than for the unplatinated duplex by NMR. At 2 degrees C, the base pairs located on the 5' side of the oligonucleotide, beyond the platinum lesion site, are disrupted. Over time, the platinum-DNA complex decomposes and the cis-[Pt(NH3)2(4-Me-Py)] platinum complex is gradually detached from DNA. No interstrand crosslinking is observed. The biological implications of the structural studies are discussed.

The crystal structure of the hyperthermophile chromosomal protein Sso7d bound to DNA

Sso7d and Sac7d are two small (approximately 7,000 Mr), but abundant, chromosomal proteins from the hyperthermophilic archaeabacteria Sulfolobus solfataricus and S. acidocaldarius respectively. These proteins have high thermal, acid and chemical stability. They bind DNA without marked sequence preference and increase the Tm of DNA by approximately 40 degrees C. Sso7d in complex with GTAATTAC and GCGT(iU)CGC + GCGAACGC was crystallized in different crystal lattices and the crystal structures were solved at high resolution. Sso7d binds in the minor groove of DNA and causes a single-step sharp kink in DNA (approximately 60 degrees) by the intercalation of the hydrophobic side chains of Val 26 and Met 29. The intercalation sites are different in the two complexes. Observations of this novel DNA binding mode in three independent crystal lattices indicate that it is not a function of crystal packing.

2'-Deoxyisoguanosine adopts more than one tautomer to form base pairs with thymidine observed by high-resolution crystal structure analysis

The questions of whether different tautomeric forms of nucleic acid bases exist to any significant extent in DNA, or what their possible roles in mutation may be, are under intense scrutiny. 2'-Deoxyisoguanosine (iG) has been suggested to have a propensity to adopt the enol form. Isoguanine (also called 2-hydroxyadenine) can be found in oxidatively damaged DNA generated from treating DNA with a Fenton-type reactive oxygen-generating system and is known to cause mutation. We have analyzed the three-dimensional structure of the DNA dodecamer d(CGC[iG]AATTTGCG) (denoted iG-DODE) by X-ray crystallography and NMR. The crystal structure of the iG-DODE complexed with the minor groove binder Hoechst 33342, refined to 1.4 A resolution, showed that the two independent iG.T base pairs in the dodecamer duplex adopt different (one in Watson-Crick and the other in wobble) conformations. The high-resolution nature of the structure also affords unprecedented clear information about the conformation and interactions of the Hoechst drug. The Hoechst 33342 binds in the narrow minor groove at the iGAATT site, with the N-methylpiperazine ring near the iG4.T21 base pair. Three hydrogen bonds are found between the NH of the Hoechst ligand and T-O2 DNA atoms. In solution, the two iG.T base pairs in iG-DODE predominantly are in the wobble form at 2 degreesC. At higher temperatures, another duplex form (likely involving the enol form of iG) is in slow exchange with the keto form and becomes significantly populated, reaching approximately 40% at 40 degreesC. Our data support the conclusion that iG pairs with T in a Watson-Crick configuration to a significant extent at physiological temperature (37 degreesC), which may explain the facile incorporation rate of T across from an iG during in vitro DNA replication.

Molecular structure of two crystal forms of cyclic triadenylic acid at 1A resolution

The three dimensional structures of cyclic deoxytriadenylic acid, c-d(ApApAp), from two different trigonal crystal forms (space groups P3 and R32) have been determined by x-ray diffraction analysis at 1A resolution. Both structures were solved by direct methods and refined by anisotropic least squares refinement to R-factors of 0.109 and 0.137 for the P3 and R32 forms, respectively. In both crystal forms, each of the two independent c-d(ApApAp) molecules sits on the crystallographic 3-fold axis. All four independent c-d(ApApAp) molecules have similar backbone conformations. The deoxyriboses are in the S-type pucker with pseudorotation angles ranging from 156.7 degrees to 168.6 degrees and the bases have anti glycosyl torsion angles (chi falling in two ranges, one at -104.3 degrees and the other ranging from -141.0 degrees to -143.8 degrees). In the R32 form, a hexahydrated cobalt(II) ion is found to coordinate through bridging water molecules to N1, N3, and N7 atoms of three adjacent adenines and oxygen atoms of phosphates. Comparison with other structures of cyclic oligonucleotides indicates that the sugar adopts N-type pucker in cyclic dinucleotides and S-type pucker in cyclic trinucleotides, regardless whether the sugar is a ribose or a deoxyribose.

Binding of the modified daunorubicin WP401 adjacent to a T-G base pair induces the reverse Watson-Crick conformation: crystal structures of the WP401-TGGCCG and WP401-CGG[br5C]CG complexes

2'-Bromo-4'-epi-daunorubicin (alpha-manno configuration, denoted WP401) is a new anthracycline drug that exhibits promising activity toward multidrug-resistant cancer cells. We carried out X-ray diffraction analyses of the complexes formed in the presence of formaldehyde between WP401 and two DNA hexamers, TGGCCG and CGG[br5C]CG. The two complexes crystallized in different crystal lattices with respective crystal data of space group P4322, a = b = 37.20 A, c = 70.53 A and space group P43212, a = b = 37.23 A, c = 61. 96 A. These new crystal forms are different from the P41212 form of other daunorubicin/doxorubicin complexes studied previously. The refined crystal structures at approximately 2.0 A resolution revealed that the entire 2:1 drug-DNA complex is in the asymmetrical unit. Two WP401 drug molecules bind to the duplex, with the aglycones intercalated between the CpG or TpG steps and their modified daunosamines in the minor groove. As observed earlier, in the presence of formaldehyde, WP401 more readily forms a covalent adduct with (C/T)GG*:CCG than with (C/T)GC:G*CG (G* is the crosslink site), the opposite of what is seen for daunorubicin and doxorubicin. Surprisingly, the two T-G mismatched base pairs in the WP401-TGGCCG complex adopt the reverse Watson-Crick conformation, instead of the wobble conformation. The unusual T-G reverse Watson-Crick conformation may be required in order to maintain favorable stacking interactions between the base pair and the aglycone of WP401. Our results show that chemical modifications like bromo or iodo substitution on anthracycline drugs have significant effects on their DNA binding properties.

The hyperthermophile chromosomal protein Sac7d sharply kinks DNA

The proteins Sac7d and Sso7d belong to a class of small chromosomal proteins from the hyperthermophilic archaeon Sulfolobus acidocaldarius and S. solfactaricus, respectively. These proteins are extremely stable to heat, acid and chemical agents. Sac7d binds to DNA without any particular sequence preference and thereby increases its melting temperature by approximately 40 degrees C. We have now solved and refined the crystal structure of Sac7d in complex with two DNA sequences to high resolution. The structures are examples of a nonspecific DNA-binding protein bound to DNA, and reveal that Sac7d binds in the minor groove, causing a sharp kinking of the DNA helix that is more marked than that induced by any sequence-specific DNA-binding proteins. The kink results from the intercalation of specific hydrophobic side chains of Sac7d into the DNA structure, but without causing any significant distortion of the protein structure relative to the uncomplexed protein in solution.

Bridged cobalt amine complexes induce DNA conformational changes effectively

Cobalt(III) hexaamine ion [Co(NH3)6]3+ is known to facilitate the transition of B- to Z-DNA or B- to A-DNA depending on the DNA sequences. Specific interactions are found between the amines of [Co(NH3)6]3+ and DNA atoms of A-DNA or Z-DNA. Bridged Co(III)pentaamine complexes, with multiple amine groups arranged in a rigid framework, may enhance the effectiveness of the conformational transition by occupying simultaneously two of the Co(III) hexaamine binding sites. Therefore, the imidazole-bridged Co(III)pentaamine complexes have been synthesized and their interactions with DNA oligonucleotides investigated by circular dichroism (CD) and NMR spectroscopy. CD studies of the titrations of d(A2C15G15T2) with [(NH3)5Co(Im)Co(NH3)5]Br5 and [(NH3)5Co(Im)2Co(NH3)4]Br7 showed that the former metal compound indeed is more effective than [Co(NH3)6]3+ in inducing the transition from B- to A-DNA. The conversion of B- to A-DNA was also supported by one- and two-dimensional NMR studies. Similarly for the titrations of poly(dC-dG). poly(dC-dG) and d(m5C-G)15 with these two bridged Co(III) complexes, efficient induction of Z-DNA was observed. Our studies suggest that bridged Co(III)pentaamine complexes may be useful agents for studying nucleic acid structures.

Interactions of deglycosylated cobalt(III)-pepleomycin (green form) with DNA based on NMR structural studies,

Pepleomycin (PEP)1 is a metalloglycopeptide antitumor antibiotic that has improved pharmacological properties than does bleomycin (BLM). Both PEP and BLM bind to and degrade DNA in a sequence-selective manner. The binding interactions of HO2--Co(III)-CodPEP (CodPEP) with CGTACG have been studied by 2D NMR and molecular modeling. Inspection of the 2D-NMR data revealed 60 notable intermolecular NOEs between CodPEP and CGTACG which place the drug's metal binding domain and peptide linker in the minor groove of the DNA close to G8 and T9. On the basis of the NOEs, the drug's DNA binding domain is located close to the T9.A4 and A10.T3 base pairs. Intercalation of the bithiazole tail between these base pairs is indicated by the loss of DNA symmetry upon complexation with CodPEP, by a break in the sequential connectivity at the TpA steps, and by the upfield shift of the bithiazole H-H5 and H-H5' proton resonances. Intercalation of the bithiazole moiety unfolds the CodPEP molecule and exposes its hydroperoxide group to the DNA. The hydroperoxide group in the refined model of CodPEP-CGTACG is close to the C4' proton of T9, consistent with cleavage at this position. The NOE pattern between the pyrimidine ring of CodPEP and G8 of DNA suggests a specific pairing recognition via hydrogen bonds between these groups, thus establishing a 5'-GT-3' sequence preference. The structural elucidation of the free CodPEP and CoPEP [Caceres-Cortes et al. (1997) Eur. J. Biochem. 244, 818-828], and of the complex of CodPEP-CGTACG afford a plausible mechanism for the recognition and its subsequent cleaving of DNA by the drug. The process involves the unfolding of the compact CodPEP, recognition of a guanine base using the metal binding domain, threading of the bithiazole tail between base pairs, and finally positioning of the HO2- group close to the T or C found 3' to the specific G site.

Binding of two novel bisdaunorubicins to DNA studied by NMR spectroscopy

In the search for new generations of anthracycline drugs, lower cytotoxic side effects and higher activity against resistant cancer cells are two major goals. A new class of bis-intercalating anthracycline drugs has been designed, synthesized, and shown to have promising activity against multidrug-resistant cells. Two daunorubicins symmetrically linked together via a p-xylenyl group, either at their N3' (compound WP631) or N4' sites (compound WP652), exhibit extraordinary DNA binding affinities. We have used high-resolution NRM studies to understand the DNA binding mode of these two new bis-daunorubicin anticancer compounds. The structures of the WP631-d(ACGTACGT)2 and the WP652-d(TGTACA)2 complexes have been determined by NOE-restrained refinement. WP631 binds strongly to the 5'-CG(A/T)(A/T)CG hexanucleotide sequence, with the aglycons intercalated between the two CpG sites at both ends of the hexanucleotide sequence. The overall conformation of the WP631-d(CGTACG)2 part is remarkably similar to the crystal structure of the 2:1 complex of daunorubicin and d(CGTACG)2, as predicted previously [Gao, Y.-G., & Wang, A.H.H. (1996), J. Biomol. Struct. Dyn. 13, 103-117]. In contrast, the related bis-intercalator WP652 prefers the 5'-PyGTPu tetranucleotide sequence, with the aglycons intercalated between the PypG and TpPu sites. The binding of WP652 to DNA results in a severely distroted B-DNA duplex with the p-xylenyl tether moiety significantly protruded away from the bottom of the minor groove. While WP652 in some ways behaves similarly to other anticancer bis-intercalating antibiotics (e.g., triostine A and echinomycin), the detailed interactions between those two classes of bis-intercalators are quite different.

Structural analysis of Z-Z DNA junctions with A:A and T:T mismatched base pairs by NMR

Left-handed Z-DNA structure is favored by the alternating (dC-dG)n sequence. Many Z-potentiating sequences are found in genome and they often do not have a perfect alternating (dC-dG)n sequence. When a single base pair is removed from the alternating (dC-dG)n sequence, a Z-Z junction is created. A Z-Z junction is energetically less favorable by 3.5 kcal/mol than a perfect Z-DNA sequence. We designed special sequences to probe the structural perturbation at the Z-Z junction. Four DNA oligomers, d(*CG*CGT*CG*CG) and d(*CG*CGA*CG*CG) (*C = C or br5C), have been synthesized and analyzed by NMR. The two br5C-modified DNA nonamers are in the Z-DNA conformation in 50% methanol solution. The T and the A nucleotides are in the anti and syn conformation, respectively, in the two br5C nonamers. The NOE-restrained molecular dynamics refinement demonstrated that T-T and A-A bases in the two Z-DNA duplexes are dynamic and adopt a range of conformations. Mixing the br5C-d(*CG*CGT*CG*CG) and br5C-d(*CG*CGA*CG*CG) nonamers together converts a fraction of the two nonamer populations into a hetero duplex as evident from the presence of the imino proton (at 13.70 ppm) of an A:T base pair. A model has been generated for the br5C-d(*CG*CGT*CG*CG)+br5C-d(*CG*CGA*CG*CG) duplex which incorporates a Z-Z junction. Previous biophysical and biochemical data associated with the Z-Z junction are discussed in the context of the present model.

Analyses of the stability and function of three surface mutants (R82C, K69H, and L32R) of the gene V protein from Ff phage by X-ray crystallography

The high-resolution crystal structure of the gene V protein (GVP) from the Ff filamentous phages (M13, fl, fd) has been solved recently for the wild-type and two surface mutant (Y41F and Y41H) proteins, leading to a plausible model for the polymeric GVP-ssDNA complex (Guan Y, Zhang H, Wang AHJ, 1995, Protein Sci 4:187-197). The model of the complex shows extensive contacts between neighboring dimer GVPs involving electrostatic interactions between the K69 from one and the D79 and R82 from the next dimer. In addition, hydrophobic interactions between the amino acids L32 and L44 from one and G23 from the next dimer also contribute to the dimer-dimer interactions. Mutations at the L32, K69, and R82 amino acid sites generally destabilize the protein and many of these affect the function of the phage. We have studied the structural effects of three mutant proteins involving those sites, i.e., L32R, K69H, and R82C, by X-ray crystallographic analysis at 2.0 A resolution. In L32R GVP, the structural perturbation is localized, whereas in K69H and R82C GVPs, some long-range effects are also detected in addition to the local perturbation. We have interpreted the protein stability and the functional properties associated with those mutations in terms of the observed structural perturbations.

Structures of cobalt(III)-pepleomycin and cobalt(III)-deglycopepleomycin (green forms) determined by NMR studies

Pepleomycin (PEP) is a metalloglycopeptide that has stronger anticancer activity and less pulmonary toxicity than bleomycin (BLM). PEP, like BLM, exerts its action by binding to and degrading DNA in the presence of oxygen and certain metals. Obtaining detailed structural information of PEP and PEP-DNA complexes is crucial to understanding its anticancer activity. The structures of two green forms of cobalt-PEP species, HO2-Co(III)-PEP (denoted CoPEP) and deglycosylated HO2-Co(III)-PEP (denoted CodPEP) have been obtained by NOE restrained refinements. Earlier studies of the related HO2-Co(III)-BLM A2 proposed that two chiral conformers (form A or B) could exist with either the beta-aminoalanine primary amine (A,NH2) or the mannose carbamoyl nitrogen (M,NH2) as the axial ligand. Analysis of our NOESY data shows convincingly that form A is the most probable conformer with the mannose carbamoyl M,NH2 and the beta-aminoalanine primary amine A,NH2 as the axial ligands in CoPEP and CodPEP, respectively. The NOE cross-peaks resulting from the interactions between the N-terminus (i.e., the metal-binding domain) and the C-terminus of CoPEP and CodPEP have similar patterns, suggesting that they both adopt compact structures with the bithiazole group folded back over the N-terminus.

Distamycin A modulates the sequence specificity of DNA alkylation by duocarmycin A

Duocarmycin A (Duo) normally alkylates adenine N3 at the 3' end of A + T-rich sequences in DNA. The efficient adenine alkylation by Duo is achieved by its monomeric binding to the DNA minor groove. The addition of another minor groove binder, distamycin A (Dist), dramatically modulates the site of DNA alkylation by Duo, and the alkylation switches preferentially to G residues in G + C-rich sequences. HPLC product analysis using oligonucleotides revealed a highly efficient G-N3 alkylation via the cooperative binding of a heterodimer between Duo and Dist to the minor groove. The three-dimensional structure of the ternary alkylated complex of Duo/Dist/d(CAGGTGGT).d(ACCACCTG) has been determined by nuclear Overhauser effect (NOE)-restrained refinement using 750 MHz two-dimensional NOE spectroscopy data. The refined NMR structure fully explains the sequence requirement of such modulated alkylations. This is the first demonstration of Duo DNA alkylation through cooperative binding with another structurally different natural product, and it suggests a promising new way to alter or modify the DNA alkylation selectivity in a predictable manner.

Interaction between left-handed Z-DNA and polyamine - 3. The crystal structure of the d(CG)3 and thermospermine complex

The DNA fragment, d(CG)3, was co-crystallized with N-(3-amino-propyl)-N-(5-aminopropyl)-l,4 -diaminobutane (thermospermine; PA(334)), a polyamine metabolized from the nucleic acid. By using a good crystal with dimensions of 0.5 x 0.5 x 0.5 mm3, X-ray intensity data were collected up to 1.0 A resolution. Two thermospermine molecules and a magnesium cation were bound to the left-handed double-helical d(CG)3 molecule. The d(CG)3 molecule adopted the left-handed Z-conformation and two thermospermine molecules and a magnesium cation neutralized the negative charges of the phosphate groups of the d(CG)3 molecule. Furthermore, the binding modes between d(CG)3 and thermospermine were different from those of d(CG)3 complexes with PA(24), spermidine and spermine. This is the first case in which it was determined by X-ray crystallographic analysis that one of two thermospermine molecules bound three d(CG)3 duplexes which were symmetrically related to each other, and the other formed two hydrogen bonds at the N(5) and N(9) atoms with two adjacent nucleotide phosphate groups of a single d(CG)3 strand at the minor groove. Furthermore, no direct coordination bond was found between the d(CG)3 molecule and the magnesium cation.

Single-stranded DNA binding protein from bacteriophage cf: characterization, gene localization and protein-ssDNA complex

The single-stranded DNA binding protein from the filamentous bacteriophage cf has been purified and characterized. The first 12 amino acids, resulting from the N-terminal amino acid sequencing analysis of the protein, agree with an open reading frame (ORF) on the cf genome. The ORF contains 294 bp and codes for a 98 a.a. protein of molecular weight 10.8 kDa, consistent with the result from the denaturing protein gel analysis. The protein appears to be a homodimer as evident from the apparent molecular weight of about 22 kDa obtained from native protein gel analysis. The gene location of the protein has been identified as gene V of the cf single stranded genome, same as that from the M13 phage. The GVP of cf shows a strong sequence homology to the ssDNA binding proteins of Ff, IKe and Pf3 filamentous phages. The DNA binding wing of GVP, conserved among the filamentous phages, has been predicted for cf. To further characterize the protein, the GVP-ssDNA complex of cf has been purified from the infected host (Xanthomonas campestris pv. citri) by density gradient centrifugation. Transmission electron microscopy (TEM) images of the complex showed that it is about 1200 nm in length and 9 nm in diameter and it has a highly regular morphology with a central groove shadow running along the entire structure, but without any apparent helical pattern seen in the M13 complex. The GVP-ssDNA complex of cf seems more rigid than that of M13. Our computer modeling study suggested that this difference between the two complexes may be due to the additional 11 or 12 amino acids at the C-terminal end of the cf-GVP.

Substitutions at C2' of daunosamine in the anticancer drug daunorubicin alter its DNA-binding sequence specificity

In the search for new generations of anthracycline drugs, lower cytotoxic side effect and higher activity toward resistant cancer cells are two major goals. A new anthracycline drug, WP401 (2'-bromo-4'-epidaunorubicin, alpha-manno configuration), exhibits promising activity toward multidrug-resistant cells. In contrast, the related compound WP400 (2'-bromo-4'-epidaunorubicin, alpha-gluco configuration), is significantly less cytotoxic. To establish the structural and molecular bases of this observation, we performed X-ray diffraction analyses of the complexes between WP401 and four DNA hexamers CGTACG, CGATCG, CGCGCG, and CGGCCG. Their crystal data (space group P4(1)2(1)2, a = b approximately 2.8 nm, c approximately 5.3 nm) are similar to those of other daunorubicin/doxorubicin complexes. The refined crystal structures at 0.18-nm resolution revealed that two WP401 drug molecules bind to the duplex, with the aglycons intercalated between the CpG steps and their modified daunosamines in the minor groove. The bulky bromine atom at the C2' position caused the daunosamine of the bound WP401 to adopt a different conformation from that of the bound daunorubicin. In the presence of formaldehyde, WP401 formed a covalent adduct with CGGCCG more readily than with CGCGCG. This is the opposite of what is seen for daunorubicin and doxorubicin. Thus modifications at the C2' position of daunosamine modulate the sequence specificity of the formaldehyde-crosslinking reactions between anthracyclines and DNA.

Interaction between the left-handed Z-DNA and polyamine-2. The crystal structure of the d(CG)3 and spermidine complex

This paper deals with the crystal structure of d(CG)3-spermidine complex. The DNA fragment, d(CG)3, was crystallized with N-(2-amino-propyl)-1,4-diamino-butane, PA(34), spermidine. The results of its X-ray crystallographic analysis showed many intermolecular contacts between d(CG)3 and spermidine, but the binding mode of spermidine to the d(CG)3 molecule is different from that of the d(CG)3 and N-(2-amino-ethyl)-1,4-diamino-butane [PA(24)] complex: a spermidine molecule bound to the d(CG)3 and its symmetrically related neighboring d(CG)3 molecules through the water molecules with hydrogen bonds, while one PA(24) molecule connected directly to one d(CG)3 molecule, but not to its neighboring d(CG)3 molecule. In the crystal, the d(CG)3 molecule was the left-handed Z-form, and three magnesium cations and a sodium cation were observed around the d(CG)3 moiety with different binding modes from the case of the d(CG)3-PA(24) complex.

Structural effect of intra-strand cisplatin-crosslink on palindromic DNA sequences

Three self-complementary DNA oligonucleotides, each having a single GpG site, have been reacted with the anticancer platinum compound cis-Pt(NH3)2Cl2 (cisplatin). Their covalent intra-strand didentate adducts have been purified and studied by NMR. In d(GAC-CATATG*G*TC), the two G*G* sites (G*G* denoting the cisplatin crosslinked lesion site) are separated by four base pairs and capped by two base pairs at the ends of the helix and the dodecamer forms a doubly-kinked duplex structure. Multi-stranded aggregate of the dodecamer was formed over time in the presence of chloride. This is due to the meta-stable property of the intra-strand Pt-G*pG* crosslink in dsDNA, similar to that first seen recently in another duplex (Yang et al., Biochemistry (1995) 34, 12912-12920). In d([c7A]CC[c7G][c7G]CCG*G*T), the CG*G*T segment of the decamer is essentially single-stranded with the G*8 in the syn conformation. In d([c7G]CC[c7G]CG*G*C), two possible structures, a full duplex and a staggered partial duplex, were formed. Therefore, the structural consequence of the incorporation of the G*G* lesion site into palindromic sequences is dependent on the location of the lesion sites in the sequence. The destabilizing effect of G*G* in dsDNA may facilitate the formation of a hairpin structure as shown recently (Iwamoto et al., J. Amer. Chem. Soc. (1994) 116, 6238-6244). Such alternative structural distortions may be relevant in understanding the protein recognition of the lesions induced by cisplatin.

Context dependence of mutational effects in a protein: the crystal structures of the V35I, I47V and V35I/I47V gene V protein core mutants

The basis for the context dependence of the effects of core mutations on protein stability was investigated by comparing the structures of three gene V protein mutants with that of the wild-type protein. We previously examined a "swapped" mutant in which core residues Val35 and Ile47 were simply reversed so that the mutant had no hydrophobicity change from the native protein. The swapped mutant was destabilized by 3 kcal/mol per gene V protein dimer relative to the wild-type protein, demonstrating that factors other than hydrophobicity must make substantial contributions to the effects of mutations on the stability of the protein. Here we have determined the structure of this swapped mutant (V35I/I47V) as well as those of the two constituent mutants (V35I and I47V). We find that the structures of the mutant proteins are very similar to that of the wild-type protein except for the necessary addition or deletion of methylene groups and for slight positional shifts of atoms around each mutated residue. The structure of the double mutant is a composite of the structures of the two single mutants. In the mutant structures, the V35I mutation fills a cavity that exists in the wild-type protein and the I47V mutation creates a new cavity. The structures of the mutants indicate further that the reason the V35I and I47V mutations do not have opposite effects on stability is that the cavity in the wild-type protein filled by the V35I mutation is not optimally shaped for accommodating the additional methylene group of the isoleucine. These results support the concepts that the details of core packing have substantial influence on the effects of core mutations on protein stability and that these packing effects are major determinants of the context dependence of core mutation effects on stability.

Synthesis, structure and thermodynamic properties of 8-methylguanine-containing oligonucleotides: Z-DNA under physiological salt conditions

Various oligonucleotides containing 8-methylguanine (m8G) have been synthesized and their structures and thermodynamic properties investigated. Introduction Of M8G into DNA sequences markedly stabilizes the Z conformation under low salt conditions. The hexamer d(CGC[M8G]CG)2 exhibits a CD spectrum characteristic of the Z conformation under physiological salt conditions. The NOE-restrained refinement unequivocally demonstrated that d(CGC[m8G]CG)2 adopts a Z structure with all guanines in the syn conformation. The refined NMR structure is very similar to the Z form crystal structure of d(CGCGCG)2, with a root mean square deviation of 0.6 between the two structures. The contribution of m8G to the stabilization of Z-DNA has been estimated from the mid-point NaCl concentrations for the B-Z transition of various m8G-containing oligomers. The presence of m8G in d(CGC[m8G]CG)2 stabilizes the Z conformation by at least deltaG = -0.8 kcal/mol relative to the unmodified hexamer. The Z conformation was further stabilized by increasing the number of m8Gs incorporated and destabilized by incorporating syn-A or syn-T, found respectively in the (A,T)-containing alternating and non-alternating pyrimidine-purine sequences. The results suggest that the chemically less reactive m8G base is a useful agent for studying molecular interactions of Z-DNA or other DNA structures that incorporate syn-G conformation.

Neomycin, spermine and hexaamminecobalt (III) share common structural motifs in converting B- to A-DNA

The (dG)n.(dC)n-containing 34mer DNA duplex [d(A2G15C15T2)]2 can be effectively converted from the B-DNA to the A-DNA conformation by neomycin, spermine and Co(NH3)6(3+). Conversion is demonstrated by a characteristic red shift in the circular dichroism spectra and dramatic NMR spectral changes in chemical shifts. Additional support comes from the substantially stronger CH6/GH8-H3'NOE intensities of the ligand-DNA complexes than those from the native DNA duplex. Such changes are consistent with a deoxyribose pucker transition from the predominate C2'-endo (S-type) to the C3'-endo (N-type). The changes for all three ligand-DNA complexes are identical, suggesting that those three complex cations share common structural motifs for the B- to A-DNA conversion. The A-DNA structure of the 4:1 complex of Co(NH3)6(3+)/d(ACCCGCGGGT) has been analyzed by NOE-restrained refinement. The structural basis of the transition may be related to the closeness of the two negatively charged sugar-phosphate backbones along the major groove in A-DNA, which can be effectively neutralized by the multivalent positively charged amine functions of these ligands. In addition, ligands like spermine or Co(NH3)6(3+) can adhere to guanine bases in the deep major groove of the double helix, as is evident from the significant direct NOE cross-peaks from the protons of Co(NH3)6(3+) to GH8, GH1 (imino) and CH4 (amino) protons. Our results point to future directions in preparing more potent derivatives of Co(NH3)6(3+) for RNA binding or the induction of A-DNA.

Binding of the antitumor drug nogalamycin to bulged DNA structures

Defects in DNA, e.g., unpaired/bulged nucleotides, are repaired by specific repair enzymes. Understanding the dynamics and structure of DNA defects is important. Two DNA heptamers, CTb-GTACG and CGTACTbG, each containing a bulged T nucleotide embedded in the CpG step, have been studied by NMR. Both duplexes are significantly destabilized, and the bulged T remains intrahelical. Binding of the anthracycline antitumor antibiotic nogalamycin (Ng) to these two heptamers stabilizes the duplex structure. The solution structures of the 2:1 complexes of Ng-d(CTbGTACG) and Ng-d(CGTACTbG) have been determined by the NOE-restrained refinement procedure. In both structures the elongated aglycon of Ng is intercalated between base pairs, and the nogalose and aminoglucose lie in the minor and major grooves, respectively. The bulged T behaves differently upon the binding of Ng. In Ng-CTbGTACG wobble G6:Tb base pairs are formed, leaving two dangling 5'-C1 nucleotides; whereas in Ng-CGTACTbG weak C1:Tb base pairs are formed, leaving two dangling 3'-G6 nucleotides. Thus Ng induces the bulged T and the opposing base in the duplex to stack on the aglycon and causes the base next to Tb to unpair, mimicking a "frame-shift". Such structural rearrangement of a bulged DNA site due to the binding of an intercalator drug may perturb the recognition of DNA defects by repair enzymes or may cause mutation during replication.