A theoretical model for the binding of cis-Pt(NH3)2(+2) to DNA

The binding of cis-Pt(NH3)2B1B2 to the bases B1 and B2, i.e., guanine (G), cytosine (C), adenine (A), and thymine (T), of DNA is studied theoretically. The components of the binding are analyzed and a model structure is proposed for the intrastrand binding to the dB1pdB2 sequence of a kinked double helical DNA. Quantum mechanical calculations of the ligand binding energy indicates that cis-Pt(NH3)2(+2) (cis-PDA) binds to N7(G), N3(C), O2(C), O6(G), N3(A), N7(A), O4(T) and O2(T) in order of decreasing binding energy. Conformational analysis provides structures of kinked DNA in which adjacent bases chelate to cis-PDA. Only bending toward the major groove allows the construction of acceptable square planar complexes. Examples are presented for kinks of -70 degrees and -40 degrees at the receptor site to orient the base pairs for ligand binding to B1 and B2 to form a nearly square planar complex. The energies for complex formation of cis-PDA to the various intra-strand base sites in double stranded DNA are estimated. At least 32 kcal/mole separates the energetically favorable dGpdG.cis-PDA chelate from the dCpdG.cis-PDA chelate. All other possible chelate structures are much higher in energy which correlates with their lack of observation in competition with the preferred dGpdG chelate. The second most favorable ligand energy occurs with N3(C). A novel binding site involving dC(N3)pdG(N7) is examined. Denaturation can result in an anti----syn rotation of C about its glycosidic bond to place N3(C) in the major groove for intrastrand binding in duplex DNA. This novel intrastrand dCpdG complex and the most favored dGpdG structure are illustrated with stereographic projections.     

PtL3 X-ray absorption studies of Pt model compounds and [(NH3)2Pt(OH)2Pt(NH3)2]2+ bound to DNA

The Pt L₃ X-ray absorption spectra of a series of Pt compounds have been recorded and their extended fine structure (EXAFS) analysed to investigate the sensitivity of EXAFS to non-first-shell PtPt distances. The Pt L₃ EXAFS spectra of complexes formed between [(NH₃)₂Pt(OH)₂Pt(NH₃)₂]²⁺ and calf thymus DNA were also recorded. PtPt vectors could not be detected in these spectra. When combined with the model compound studies, this result rules out Pt dimer structures for the PtDNA complex which involve rigidly bridged, adjacent Pt atoms. Such structures, based on dimeric bonding of a hydroxo dimer intermediate to DNA, have been proposed as models for cisplatin antitumor activity. These types of models now seem unlikely.     

The interaction of [Ru(NH3)5Cl]2+ and [Ru(NH3)6]3+ ions with DNA

The interaction of [Ru(NH3)5Cl]2+ and [Ru(NH3)6]3+ complex ions with calf thymus DNA has been studied at various r values (r = [Mn+]/[DNA-P]). Electronic spectra of metal-DNA solutions have been recorded and compared to the spectra of metal, as well as of DNA, solutions. Melting curves have been taken for the determination of DNA melting temperature (Tm) in the presence of the above complex ions. The results showed a biphasic melting of the DNA strands for relatively high r values. The Tm for the first phase increased with increasing r values, indicating metal ion interaction with the phosphate moieties of the DNA. The appearance of a second-phase melting, in connection with electronic spectra, pH values, and conductivity measurements of metal ion solutions, is indicative of the initial complexes' transformation to [Ru(NH3)5OH]2+, which binds preferentially to double-stranded rather than single-stranded DNA, thus leading to a second melting curve at a higher temperature than the first one.     

Binding of the transition metal ion [(H20)(NH3)5Ru(II)]2+ to nucleosomal core and internucleosomal DNA

The goal of this study is to establish the nature of pentammineruthenium(III) binding to DNA in intact mouse liver nuclei. Also, we wish to determine whether the nucleosomal organization of mouse chromatin has a substantial effect on the relative Ru(III) binding levels of internucleosomal and nucleosomal core DNA. These questions are important because ammineruthenium compounds share chemical and biological properties with the cis-dichlorodiammineplatinum(II) or cisplatin chemotherapeutic agent. Therefore, they represent a potential class of new chemotherapeutic agents. We find that in intact nuclei the predominant DNA binding site for pentammineruthenium(II), followed by air oxidation to pentammineruthenium(III), is N-7 guanine, as is the case with cisplatin. Also, the Ru(III) distribution between internucleosomal and nucleosomal core DNA was found to be nearly identical as probed with three non-specific deoxyribonucleases.     

On the Use of Chiral Compounds for Probing the DNA Handedness: Z to B Conversion in Poly(dGm5dC) Upon Binding of Fe(phen)3 2+ and Ru(phen)3 2+

Abstract

In order to examine whether chiral metal complexes can be used to discriminate between right- and left-handed DNA conformational states we have studied the enantioselective interactions of Fe(phen)₃ ²⁺ and Ru(phen)₃ ²⁺ (phen = 1,10-phenanthroline)with poly(dGm⁵dC) under B- and Z-form conditions. With the inversion-labile Fe(phen)₃ ²⁺, enantioselectivity leads to shifts in the diastereomeric binding equilibria. This effect, known as the “Pfeiffer effect” (1–4), is monitored as a slowly emerging circular dichroism of the solution, corresponding to a net excess of the favoured enantiomer. With Ru(phen)₃ ²⁺, which is stable to intramolecular inversion, the difference in DNA-binding strengths of the enantiomers results in an excess of the less favoured enantiomer in the bulk solution. This excess is detected in the dialysate of the DNA/metal complex solution. With both complexes we find that the Δ-enantiomer is favoured when the polynucleotide adopts the B-form, as previously shown, but also when it initially adopts the Z-form conformational state.

This observation, together with evidence from UV-circular dichroism and binding data, indicates that the binding of these metal complexes induces a Z- to B-form transition in Z- form poly(dGm⁵dC). Consequently, neither of the studied chiral DNA-binders can easily be used to discriminate the DNA handedness.     

Influence of counter-ions on the crystal structures of DNA decamers: binding of [Co(NH3)6]3+ and Ba2+ to A-DNA.

A-DNA is a stable alternative right-handed double helix that is favored by certain sequences (e.g., (dG)n.(dC)n) or under low humidity conditions. Earlier A-DNA structures of several DNA oligonucleotides and RNA.DNA chimeras have revealed some conformational variation that may be the result of sequence-dependent effects or crystal packing forces. In this study, four crystal structures of three decamer oligonucleotides, d(ACCGGCCGGT), d(ACCCGCGGGT), and r(GC)d(GTATACGC) in two crystal forms (either the P6(1)22 or the P2(1)2(1)2(1) space group) have been analyzed at high resolution to provide the molecular basis of the structural difference in an experimentally consistent manner. The study reveals that molecules crystallized in the same space group have a more similar A-DNA conformation, whereas the same molecule crystallized in different space groups has different (local) conformations. This suggests that even though the local structure is influenced by the crystal packing environments, the DNA molecule adjusts to adopt an overall conformation close to canonical A-DNA. For example, the six independent CpG steps in these four structures have different base-base stacking patterns, with their helical twist angles (omega) ranging from 28 degrees to 37 degrees. Our study further reveals the structural impact of different counter-ions on the A-DNA conformers. [Co(NH3)6]3+ has three unique A-DNA binding modes. One binds at the major groove side of a GpG step at the O6/N7 sites of guanine bases via hydrogen bonds. The other two modes involve the binding of ions to phosphates, either bridging across the narrow major groove or binding between two intra-strand adjacent phosphates. Those interactions may explain the recent spectroscopic and NMR observations that [Co(NH3)6]3+ is effective in inducing the B- to A-DNA transition for DNA with (G)n sequence. Interestingly, Ba2+ binds to the same O6/N7 sites on guanine by direct coordinations.     

Electrochemical investigations of platinum-methyluracil-blue and the related binuclear complex [(NH3)2Pt(MeU)2Pt(NH3)2](NO3)2

The redox behavior of the head-to-head bis(μ- (1-methyluracilato-N³,O²)-bis(cis-diammine platinum(II)) dinitrate, PtMeU, and platinum 1-methyluracil blue, PtMeUB, was studied by cyclic voltammetry (CV), rotating disk voltammetry (RDV), and controlled-potential coulometry (CPC). Redox titrimetry, electrochemistry/electron paramagnetic resonance spectroscopy (EPR), and liquid chromatography (LC) served as complementary techniques. The former reactant exhibits two-step electro-oxidation, consistent with the formation of a mixed-valence Pt(II, III) state en route to Pt(III, III). The latter also appears to oxidize to a uniform Pt(III) state. Although the oxidative-reductive electrochemistry of both reactants exhibits chemical reversibility, the heterogeneous electron-transfer kinetics are notably sluggish. The latter appears to be associated with the formation of an inhibiting film on the electrode surface. A slow conversion of PtMeU to a PtMeUB-like state was revealed by CV and LC. The complex, oligomeric nature of PtMeUB was revealed by means of gradient LC examination. Comparing oxidative and reductive electrolysis curves for PtMeUB yielded an average platinum oxidation state of 2.08. All observed behavior for PtMeUB, as well as for PtMeU, is accounted for by invoking +2 and +3 oxidation states for platinum; redox titrimetry using Ce(IV) revealed inconsequential oxidation of both of these systems beyond the III state. An estimate of molecular weight for the platinum blue was made by employing RDV in conjunction with the Einstein-Stokes equation.     

Selective DNA Binding of (N-alkylamine)-Substituted Naphthalene Imides and Diimides to G+C-rich DNA

Abstract

Alkylamine-substituted naphthalene imides and diimides bind DNA by intercalation and have applications as anticancer agents. The unique structures of these imides in which two adjacent carbonyl groups lie coplanar to an extended aromatic ring system allow the possibility of sequence-selective interactions between the intercalated chromophore and guanine amino groups situated in the DNA minor groove. The binding affinities of N-[3- (dimethylamino)propyl amine]-1,8-naphthalenedicarboxylic imide (N-DMPrNI) and N, N′- bis[3,3′-(dimethylamino)propylamine]-naphthalene-1,4,5,8-tetracarboxylic diimide (N- BDMPrNDI) for natural DNAs of differing base composition were determined spectroscopically and by equilibrium dialysis. In agreement with the above proposition, binding studies indicated that both the naphthalene imide and diimide strongly prefer to intercalate into steps containing at least one G:C base pair. The dependencies of association constants on DNA base composition are consistent with a requirement for one G:C pair in the binding site of the monoimide, and two G:C pairs in binding sites of the diimide. These selectivities are comparable to or exceed that of actinomycin D, a classic G:C-selective drug. Protection footprinting with DNase I confirmed that the naphthalene monoimide (N-DMPrNI) prefers to bind adjacent to G:C base pairs, with a most consistent preference for “mixed” steps containing both a G:C and an A:T pair, excepting GA:TC. Several 5-CG-3′ steps were also good binding sites as indicated by nuclease protection, but few GC:GC or GG:CC steps were protected. The naphthalene diimide inhibited DNase I digestion, but did not yield a footprint. The base recognition ability and versatile chemistry make naphthalene imides and diimides attractive building blocks for design of highly sequence-specific, DNA-directed drug candidates including conjugated oligonucleotides or oligopeptides.     

Model for the Porphyrin-DNA Binding Site: ENDOR Investigations of Cu-Porphyrins Binding to DNA

Abstract

Proton ENDOR has been observed from frozen solutions (ca. 38K°) of copper meso-(4-N-tetra-methylpyridyl)porphyrin (CuTMpyP(4)) complexed with Salmon sperm DNA in water and D₂O. Lines from exchangeable protons of the DNA bases have been observed in these ENDOR spectra. Analyses of these ENDOR data show that the separations of these DNA protons from the copper atom are between 3.76 and 3.84 A with angles of 19.5 to 22.5 degrees between the Cu-H vectors and the g_z axis. A distant ENDOR response has also been observed from phosphorous nuclei in the DNA backbone. We estimate that the phosphorous atoms producing this ENDOR signal are 7.5–10 Å from the copper center of the porphyrin. These ENDOR data combined with results from an earlier NMR investigation (1) have been used to construct a computer simulated model of the binding site in which the porphyrin is partially intercalated and extends into the major groove of DNA. The two GC base pairs at this site are slightly inequivalent. For each, the G imino proton and one of the C amino protons are at appropriate positions to account for the ENDOR signals arising from exchangeable protons. It is unlikely that this inequivalence would persist at room temperature where dynamic processes would give an apparently symmetric interaction. Although the model accounts for all reported experimental data involving tetracationic porphyrin species which have been suggested to be intercalators, it is not a unique solution.     

H3K36me2/3 Binding and DNA Binding of the DNA Methyltransferase DNMT3A PWWP Domain Both Contribute to its Chromatin Interaction

The PWWP domain of DNMT3 DNA methyltransferases binds to histone H3 tails containing methylated K36, and this activity is important for heterochromatic targeting. Here, we show that the PWWP domain of mouse DNMT3A binds to H3K36me2 and H3K36me3 with a slight preference for H3K36me2. PWWP domains have also been reported to bind to DNA, and the close proximity of H3K36 and nucleosomal DNA suggests a combined binding to H3K36me2/3 and DNA. We show here that the DNMT3A PWWP domain binds to DNA with a weak preference for AT-rich sequences and that the designed charge reversal R362E mutation disrupts DNA binding. The K295E mutation, as well as K295I recently identified in paraganglioma, a rare neuroendocrine neoplasm, disrupts both DNA and H3K36me2/3 binding, which is in agreement with the proximity of K295 to residues involved in K36me2/3 methyllysine binding. Nucleosome pulldown experiments show that DNA binding and H3K36me2/3 binding are important for the interaction of the DNMT3A PWWP domain with nucleosomes. Localization studies of transiently transfected fluorescently-tagged wild-type and PWWP-mutated full-length DNMT3A indicate that both interactions contribute to the subnuclear localization of DNMT3A in mouse cells. In summary, our data demonstrate that the combined binding of the DNMT3A PWWP domain to the H3 tail containing K36me2/3 and to the nucleosomal or linker DNA is important for its chromatin interaction and subnuclear targeting of DNMT3A in living cells.     

Binding of Eu3+ to cardiac sarcoplasmic reticulum (Ca2+ + Mg2+)-ATPase-laser excited Eu3+ spectroscopic studies.

The binding of Eu3+ with Ca2+-stimulated, Mg2+-dependent adenosine triphosphatase ([Ca2+ + Mg2+]-ATPase) of cardiac sarcoplasmic reticulum (SR) has been investigated using direct laser excited Eu3+ luminescence. Eu3+ is found to inhibit both Ca2+-dependent ATPase activity and Ca2+-uptake in a parallel manner. This is attributed to the binding of Eu3+ to the high affinity Ca2+-binding sites. The Ki for Ca2+-dependent ATPase is approximately 50 nM. The 7F0----5D0 excitation spectrum of Eu3+ in cardiac SR shows a peak at 579.3 nm, as compared to 578.8 nm in potassium-morpholino propane sulfonic acid (K-MOPS) pH 6.8. Upon binding with cardiac SR, Eu3+ shows an increase in fluorescence intensity as well as in lifetime values. The fluorescence decay of bound Eu3+ exhibits a double-exponential curve. The apparent number of water molecules in the first coordination sphere of Eu3+ in SR is 2.8 for the short component and 1.0 for the long component. In the presence of ATP, a further increase in fluorescence lifetimes is observed, and the number of water molecules in the first coordination sphere of Eu3+ is reduced further to 1.3 and 0.5. The double exponential nature of the decay curve and the different number of water molecules coordinated to Eu3+ for both decay components suggest that Eu3+ binds to two sites and that these are heterogeneous. The reduction in the number of H2O ligands in the presence of ATP shows a change in the molecular environment of the Eu3+-binding sites upon phosphoenzyme formation, with a movement of Eu3+ to an occluded site on the enzyme.     

Reaction of DNA oligonucleotides with [Pt(dien)GSMe]2+ (GSMe =S-methylated glutathione) and cis-[Pt(NH3)2(GSMe)2]2+: evidence of oligonucleotide platination via sulfur-coordinated platinum intermediates

To study the possibility of DNA platination via platinum-sulfur coordinated intermediates, the reactions of the complexes [Pt(dien)GSMe]2+ (GSMe=S-methylated glutathione) and cis-[Pt(NH3)2(GSMe)2]2+ with the synthetic oligonucleotides d(ATATGCATAT), d(ATTACCGGTAAT), and d(ATCCTATTTTTTTTAGGAT) have been investigated. The reactions were studied using FPLC, NMR, and mass spectrometry. It was found that the sulfur atom of the platinum-thioether adduct is substituted by these oligonucleotides. For the reactions with [Pt(dien)GSMe]2+ at 310 K, half-lives were determined to be t 1/2 =147+/-7 h for d(ATATGCATAT), t 1/2 =84+/-4 h) for d(ATTACCGGTAAT), and t 1/2 = 21+/-1 h for d(ATCCTATTTTTTTTAGGAT. This study clearly shows that it is indeed possible for oligonucleotides to be platinated via Pt-thioether coordinated intermediates. The rates at which such substitutions occur, however, makes it improbable that such a mechanism contributes significantly to the antitumor activity of cisplatin.     

Binding of 2-acetylaminofluorene to DNA

2-Acetylaminofluorene (2-AAF) is a carcinogenic and mutagenic derivative of fluorene. It is used as a biochemical tool in the study of carcinogenesis. Studies have shown that it induces tumors in a number of species in the liver, bladder, and kidney. It is thought that 2-AAF-DNA adduct formation leads to mutation, and eventually tumor formation. The aim of this study was to examine the interactions of AAF with calf-thymus DNA in aqueous solution at physiological conditions, using constant DNA concentration (12.5 mM) and various AAF/polynucleotide (phosphate) ratios of 1/120, 1/80, 1/40, 1/20, 1/10, 1/5, 1/2, and 1/1. Fourier transform infrared and UV-visible spectroscopic methods and molecular modeling were used to determine the ligand binding mode, the binding constant, and the stability of AAF-DNA complexes in aqueous solution. Spectroscopic evidence showed both intercalation and external binding of AAF to DNA with an overall binding constant of K(AAF-DNA) = 2.33 × 10(7) M(-1). 2-AAF induced a partial B to A-DNA transition and DNA aggregation was observed at high AAF content.     

A Conserved Na+ Binding Site of the Sodium-coupled Neutral Amino Acid Transporter 2 (SNAT2)

The SLC38 family of solute transporters mediates the coupled transport of amino acids and Na⁺ into or out of cells. The structural basis for this coupled transport process is not known. Here, a profile-based sequence analysis approach was used, predicting a distant relationship with the SLC5/6 transporter families. Homology models using the LeuT_Aa and Mhp1 transporters of known structure as templates were established, predicting the location of a conserved Na⁺ binding site in the center of membrane helices 1 and 8. This homology model was tested experimentally in the SLC38 member SNAT2 by analyzing the effect of a mutation to Thr-384, which is predicted to be part of this Na⁺ binding site. The results show that the T384A mutation not only inhibits the anion leak current, which requires Na⁺ binding to SNAT2, but also dramatically lowers the Na⁺ affinity of the transporter. This result is consistent with a previous analysis of the N82A mutant transporter, which has a similar effect on anion leak current and Na⁺ binding and which is also expected to form part of the Na⁺ binding site. In contrast, random mutations to other sites in the transporter had little or no effect on Na⁺ affinity. Our results are consistent with a cation binding site formed by transmembrane helices 1 and 8 that is conserved among the SLC38 transporters as well as among many other bacterial and plant transporter families of unknown structure, which are homologous to SLC38.The sodium-coupled neutral amino acid transporter, SNAT2,² belongs to the SLC38 gene family of solute carrier proteins (1). Together with SNAT1 and -4 (2), it is believed to mediate Na⁺-dependent amino acid transport activity that was classically assigned to System A transporters (3–8). In addition to SNAT1 and -2, the SLC38 family has four other known members, two of which predominantly mediate glutamine transport (SNAT3 and -5, System N (9–11)). SNAT2 is widely expressed in mammalian tissue (1, 7), but it may play a particularly critical role in the brain (12), where it may help shuttle glutamine from astrocytes to neurons via the glutamate-glutamine cycle (1). This process is essential for recycling the neurotransmitter glutamate (13). However, the exact contribution of SNAT2 to the glutamate-glutamine cycle is still controversially discussed (14).Despite this physiological importance, surprisingly little is known about the functional properties and the structural basis of amino acid transport by the SLC38 proteins. Although hydropathy analysis predicts 11 transmembrane helices (TMs), with an intracellular N terminus and an extracellular C terminus (1), it is not clear whether the transporters belong to a large superfamily of transporters, of which members have been characterized structurally through x-ray crystallography. At present, sequence homology has only been established with transporters of the mammalian SLC32 and SLC36 families as well as with the more distantly related plant auxin carriers and the bacterial amino acid-polyamine-organocation (APC) family (15, 16). High resolution crystal structures are not available for any of the transporters from these families, although low resolution projection structures were recently reported for the APC family members AdiC (17) and SteT (18). However, these structures do not allow the assignment of transmembrane helices. Thus, it remains unknown whether the SLC38 fold is similar to established transport protein folds, although homology to the major facilitator superfamily seems unlikely.We have recently identified a conserved amino acid residue in SNAT2, Asn-82, which is involved in controlling the Na⁺ affinity of the transporter (19). Interestingly, Asn-82 is localized in the predicted TM1 of SNAT2. This first transmembrane helix was recently found to contribute ligands to a Na⁺ binding site in several bacterial transporters, which are related to the SLC5 (sodium glucose symporter) and SLC6 (sodium- and chloride-dependent neurotransmitter transporter) family members (20–22), which also comprises bacterial members (23, 24). Although sequence similarity with SLC5 and -6 is not detectable, SLC38 may be a member of a possibly very large superfamily with the same general fold, which also contains many amino acid transport proteins.Here, we used a homology modeling approach based on profile-based sequence alignment (25, 26). A search against sequences deposited in the Protein Data Bank (PDB (27)) revealed that the transporters with the highest likelihood to share an analogous fold are a leucine transporter from Aquifex aeolicus, LeuT_Aa, and a homologous hydantoin transporter from Microbacterium liquefaciens, Mhp1. We established a homology model based on these structures, which predicts Asn-82 to be part of a Na⁺ binding site. Furthermore, another conserved hydrophilic amino acid residue in TM8, Thr-384, was predicted to be near this cation binding site. When Thr-384 was mutated to alanine, a dramatic loss of the affinity of SNAT2 for Na⁺ was observed, whereas mutations to other sites that were spatially removed from the predicted Na⁺ binding site had little or no effect on Na⁺ affinity. We hypothesize that the SLC38 family is a member of a large superfamily of cation/organic substrate transporters which includes the mammalian SLC5 and -6 proteins and which has a conserved cation binding site formed by TMs 1 and 8.     

Binding of protein uH2A and histone H2A to DNA

The binding properties of protein uH2A and histone H2A to DNA were investigated by filter binding assays. Both proteins revealed similar affinity for native and denatured DNA. Competition with increasing amounts of repetitive and nonrepetitive DNA has shown that protein uH2A binds selectively to nonrepetitive sequences. When poly d(A-T) was used as a competitor, uH2A bound to this polynucleotide with much greater affinity than histone H2A. These findings suggest a selective binding to regulatory A-T rich intergenic sequences in native DNA.