CYTOLOGICAL STUDIES ON THE ANTIMETABOLITE ACTION OF 2,6-DIAMINOPURINE IN VICIA FABA ROOTS

At a concentration of 9.6 x 10^–5 M, 2,6-diaminopurine (DAP) completely inhibited cell enlargement, cell division, and DNA synthesis (determined by microphotometric measurement of Feulgen dye) in Vicia faba roots. Inhibition of cell enlargement was partially reversed by adenine, guanine, xanthine, adenosine, and desoxyadenosine. Guanine and the nucleosides gave the greatest reversal, suggesting that one point of DAP action upon cell enlargement is a disruption of nucleoside or nucleotide metabolism, possibly during pentosenucleic acid synthesis. DAP inhibited cell division by preventing onset of prophase. At the concentrations used it had no significant effect on the rate or appearance of mitoses in progress. Inhibition of entrance into prophase was not directly due to inhibition of DNA synthesis since approximately half of the inhibited nuclei had the doubled (4C) amount of DNA. Adenine competitively reversed DAP inhibition of cell division, giving an inhibition index of about 0.5. Guanine gave a slight reversal while xanthine, hypoxanthine, adenosine, and desoxyadenosine were inactive. A basic need for free adenine for the onset of mitosis was suggested by this reversal pattern. Meristems treated with DAP contained almost no nuclei with intermediate amounts of DNA, indicating that DAP prevented the onset of DNA synthesis while allowing that underway to reach completion. The inhibition of DNA synthesis was reversed by adenine, adenosine, and desoxyadenosine although synthesis appeared to proceed at a slower rate in reversals than in controls. Inhibition of DNA synthesis by DAP is probably through nucleoside or nucleotide metabolism. A small general depression of DNA content of nuclei in the reversal treatments was observed. This deviation from DNA "constancy" cannot be adequately explained at present although it may be a result of direct incorporation of DAP into DNA. The possible purine precursor, 4-amino-5-imidazolecarboxamide gave no reversal of DAP inhibition of cell elongation and cell division and only a slight possible reversal of inhibition of DNA synthesis.     

Crystal Structure of A Z-DNA Fragment Containing Thymine/2-Aminoadenine Base Pairs

Abstract

The Z-DNA structure has been shown to form in two crystals made from self-complementary DNA hexamers d(CGTDCG) and d(CDCGTG) which contain thymine/2-ammoadenine (TD) base pairs. The latter structure has been solved and refined to 1.3 Å resolution and it shows only small conformational changes due to the introduction of the TD base pairs in comparison with the structure of d(CG)3. Spectroscopic studies with these compounds demonstrate that DNA molecules containing 2-aminoadenine residues form Z-DNA slightly more easily than do those containing adenine nucleotides, but not as readily as the parent sequence containing only guanine-cytosine base pairs.     

Nanomechanics of negatively supercoiled diaminopurine-substituted DNA

Single molecule experiments have demonstrated a progressive transition from a B- to an L-form helix as DNA is gently stretched and progressively unwound. The particular sequence of a DNA segment defines both base stacking and hydrogen bonding that affect the partitioning and conformations of the two phases. Naturally or artificially modified bases alter H-bonds and base stacking and DNA with diaminopurine (DAP) replacing adenine was synthesized to produce linear fragments with triply hydrogen-bonded DAP:T base pairs. Both unmodified and DAP-substituted DNA transitioned from a B- to an L-helix under physiological conditions of mild tension and unwinding. This transition avoids writhing and the ease of this transition may prevent cumbersome topological rearrangements in genomic DNA that would require topoisomerase activity to resolve. L-DNA displayed about tenfold lower persistence length than B-DNA. However, left-handed DAP-substituted DNA was twice as stiff as unmodified L-DNA. Unmodified DNA and DAP-substituted DNA have very distinct mechanical characteristics at physiological levels of negative supercoiling and tension.     

DNA binding property, nuclease activity and cytotoxicity of Zn(II) complexes of terpyridine derivatives

Two zinc(II) terpyridine complexes Zn(atpy)₂(PF₆)₂ (1) (atpy = 4′-p-N9′-adeninylmethylphenyl-2,2′:6,2′′-terpyridine) and Zn(ttpy)₂(PF₆)₂ (2) (ttpy = 4′-p-tolyl-2,2′:6,2′′-terpyridine) have been synthesized and characterized by elemental analysis, ¹H NMR and electrospray mass spectroscopy. The structure of complex 2 was also determined by X-ray crystallography, which revealed a ZnN₆ coordination in an octahedral geometry with two terpyridine acting as equatorial ligands. The circular dichroism data showed that complex 1 exhibited an ICD signal at around 300 nm and induced more evident disturbances on DNA base stacking than complex 2, reflecting the impact of the adenine moiety on DNA binding modes. Complex 1 exhibited higher cleavage activity to supercoiled pUC 19 DNA than complex 2 under aerobic conditions, suggesting a promotional effect of adenine moiety in DNA nuclease ability. Interestingly, both complexes demonstrated potent in vitro cytotoxicity against a series human tumor cell lines such as human cervix carcinoma cell line (HeLa), human liver carcinoma cell line (HepG2), human galactophore carcinoma cell line (MCF-7) and human prostate carcinoma cell line (pc-3). The cytotoxicity is averagely 10 times more active than the anticancer drug cisplatin. Electronic supplementary material  The online version of this article (doi:) contains supplementary material, which is available to authorized users.     

Perturbation of Hydrogen Bonds in the Adenine…Thymine Base Pair by Na+, Mg2+, Ca2+ and NH4 + Cations

Abstract

Perturbation of the hydrogen bonds in the adenine…thymine base pair by Na⁺, Mg²⁺, Ca²⁺ and NH₄ ⁺ cations has been investigated by means of ab initio SCF calculations with the STO-3G basis set. The geometry of adenine…thymine, as well as those of the perturbed pairs were optimized. Approach of any cation to thymine at 06 leads to destabilization of the adenine…thy mine pair; divalent cations (Mg²⁺, Ca²⁺) have a profound effect on the structure of the base pair. The approach of a cation to other available sites (thymine: O2, adenine N1 and N3) leads, on the other hand, to stabilization of the base pair. If a water molecule is placed between the cation and the base pair, the structure and stability of the base pair are changed only negligibly.     

Oligomers Containing 2′-Deoxyinosine Isosteres as Ambiguous Nucleoside or 1,3-Propanediol as Nucleoside Substitute

Abstract

Three new appropriately protected phosphoramidites have been synthesized. Two of them (1 and 2) are isosteric to that of inosine (3) [1], one is a derivative of 1′3-propanediol (4). Whereas the inosine isosteres contain an ambiguous base recognizing adenine, guanine as well as cytosine residues in double stranded DNA-fragments the 1,3-propanediol unit can be seen as a simple nucleoside substitute in a DNA chain. It contains only those structural elements necessary to form the sugar/phosphate backbone, without supplying the DNA with either a base [21 or a 2′-deoxyribofuranosyl moiety.     

Molecular-Mechanical studies of the mismatched base analogs of d(CGCGAATTCGCG)2:d(CGTGAATTCGCG)2, d(CGAGAATTCGCG)2, d(CGCGAATTCACG)2, d(CGCGAATTCTCG)2, and d(CGCAGAATTCGCG)·d(CGCGAATTCGCG)

Molecular-mechanical simulations have been carried out on “mismatched base” analogs of the DNA double-helical structure d(CGCGAATTCGCG)₂, in which the base pairs CG at the 3 and 10 positions have been replaced by CA, AG, TC, and TG base pairs, as well as an insertion analog in which an extra adenine has been incorporated into one strand of the above structure between bases 3 and 4. The results of these simulations (calculated relative stabilities, structures, and nmr ring-current shifts) have been compared with calorimetric and nmr data. The calculated relative stabilities of the double-helical parent dodecamer and the various “wobble” base pairs qualitatively correlate with the experimental melting temperatures. The base-pairing structure for the GT wobble pair is in agreement with that previously determined from nmr experiments. For the GA base pair, the structure with both bases anti has a slightly more favorable energy from base pairing and stacking than a structure with non-Watson-Crick H-bonding with adenine syn, in agreement with nmr experiments. The CA wobble base is calculated to favor an adenine 6NH₂ …? cytosine N3 H-bond over cytosine 4NH₂ …? adenine N1, again, in agreement with nmr experiments. There is no definitive experimental data on the TC base pair, but the existence of (somewhat long and weak) H-bonds involving cytosine 4NH₂ …? thymine 4CO and cytosine N3 …? thymine HN3 seems reasonable. We find a structure in which the extra adenine base of the insertion analogs sits “inside” the double helix.     

Mutagenic specificity of N-acetoxy-3-aminobenzanthrone, a major metabolically activated form of 3-nitrobenzanthrone, in shuttle vector plasmids propagated in human cells

3-Nitrobenzanthrone (3-NBA) is a potent environmental mutagen and a potential human carcinogen present in diesel exhaust and airborne particulates. N-acetoxy-3-aminobenzanthrone (N-Aco-ABA) has been shown to be a major reactive metabolite of 3-NBA, which mainly produces adducts with guanine and adenine in cellular DNA. Here we analyzed mutations induced by N-Aco-ABA using supF shuttle vector plasmids to elucidate the mutagenic specificity of 3-NBA in human cells. Base sequence analysis of more than 100 plasmids with supF mutations induced in wildtype and DNA repair-deficient XP cells revealed that the major mutation was base substitutions of which the majority (42 and 38%, respectively) were G:C to T:A transversions. The next major mutation was G:C to A:T and A:T to G:C base substitutions in wildtype and XP cells, respectively. The DNA polymerase stop assay using N-Aco-ABA-treated plasmids as a template showed that most stop signals, i.e., adducted sites, appeared at G:C sites. These results suggest that N-Aco-ABA binds preferably to guanine rather than adenine, and adducted adenine is repaired more efficiently by the nucleotide excision repair. Error-prone DNA polymerases could insert adenine at sites opposite to N-Aco-ABA-adducted guanine, which leads to G:C to T:A transversion. These findings could be very important to evaluate the human lung cancer risk of environmental 3-NBA.     

Cytological studies on the antimetabolite action of 2, 6-diaminopurine in Vicia faba roots

At a concentration of 9.6 x 10(-5)M, 2,6-diaminopurine (DAP) completely inhibited cell enlargement, cell division, and DNA synthesis (determined by microphotometric measurement of Feulgen dye) in Vicia faba roots. Inhibition of cell enlargement was partially reversed by adenine, guanine, xanthine, adenosine, and desoxyadenosine. Guanine and the nucleosides gave the greatest reversal, suggesting that one point of DAP action upon cell enlargement is a disruption of nucleoside or nucleotide metabolism, possibly during pentosenucleic acid synthesis. DAP inhibited cell division by preventing onset of prophase. At the concentrations used it had no significant effect on the rate or appearance of mitoses in progress. Inhibition of entrance into prophase was not directly due to inhibition of DNA synthesis since approximately half of the inhibited nuclei had the doubled (4C) amount of DNA. Adenine competitively reversed DAP inhibition of cell division, giving an inhibition index of about 0.5. Guanine gave a slight reversal while xanthine, hypoxanthine, adenosine, and desoxyadenosine were inactive. A basic need for free adenine for the onset of mitosis was suggested by this reversal pattern. Meristems treated with DAP contained almost no nuclei with intermediate amounts of DNA, indicating that DAP prevented the onset of DNA synthesis while allowing that underway to reach completion. The inhibition of DNA synthesis was reversed by adenine, adenosine, and desoxyadenosine although synthesis appeared to proceed at a slower rate in reversals than in controls. Inhibition of DNA synthesis by DAP is probably through nucleoside or nucleotide metabolism. A small general depression of DNA content of nuclei in the reversal treatments was observed. This deviation from DNA "constancy" cannot be adequately explained at present although it may be a result of direct incorporation of DAP into DNA. The possible purine precursor, 4-amino-5-imidazolecarboxamide gave no reversal of DAP inhibition of cell elongation and cell division and only a slight possible reversal of inhibition of DNA synthesis.     

A Novel and Enantioselective Approach to the Synthesis of Cyclohexane Carbocyclic Nucleosides Starting from (-)-Carvone

Abstract

3,5-dihydroxy-4-(hydroxymethyl)-1-cyclohexanyl adenine has been synthesized starting from (-)-carvone. The adenine base was introduced via Mitsunobu reaction. Conformational analysis showed that the base still adopts the equatorial position at the expence of three axial substituents.     

Interactions of Quinoxaline Antibiotic and DNA.: The Molecular Structure of a Triostin A—d(GCGTACGC) Complex

Abstract

The crystal structure of a DNA. octamer d(GCGTA.CGC) complexed to an antitumor antibiotic, triostin A, has been solved and refined to 2.2 Å resolution by x-ray diffraction analysis. The antibiotic molecule acts as a true bis intercalator surrouding the d(CpG) sequence at either end of the unwound right-handed DNA. double helix. A.s previously observed in the structure of triostin A.—d(CGTA.CG) complex (A.H.-J. Wang, et. al., Science, 225,1115–1121 (1984)), the alanine amino acid residues of the drug molecule form sequence-specific hydrogen bonds to guanines in the minor groove. The two central A · T base pairs are in Hoogsteen configuration with adenine in the syn conformation. In addition, the two terminal G · C base pairs flanking the quinoxaline rings are also held together by Hoogsteen base pairing. This is the first observation in an oligonucleotide of. Hoogsteen G · C base pairs where the cytosine is protonated. The principal functional components of a bis-intercalative compound are discussed.     

Distamycin and Penta-N-Methylpyrrolecarboxamide Binding Sites on Native DNA A Comparison of Methidiumproyl-EDTA-Fe(II) Footprinting and DNA Affinity Cleaving

Abstract

Using two direct methods we have studied the binding locations and site sizes of distamycin and penta-N-methylpyrrolecarboxamide on three DNA restriction fragments from pBR322 plasmid. We find that methidiumpropyl-EDTA·Fe(II) footprinting and DNA affinity cleaving methods report common binding locations and site sizes for the tri- and pentapeptides bound to heterogeneous DNA. The tripeptide distamycin binds 5-base-pair sites with a preference for poly(dA)·poly(dT) regions. The pentapeptide binds 6–7-base-pair sites with a preference for poly(dA)·poly(dT) regions. These results are consistent with distamycin binding as an isogeometric helix to the minor groove of DNA with the four carboxamide N-H's hydrogen bonding five A+T base pairs. The data supports a model where each of the carboxamide N-H's can hydrogen bond to two bases, either O(2) of thymine or N(3) of adenine, located on adjacent base pairs on opposite strands of the helix. In most (but not all) cases the tri- and pentapeptide can adopt two orientations at each A+T rich binding site.     

Changing the target base specificity of the EcoRV DNA methyltransferase by rational de novo protein-design

The EcoRV DNA-(adenine-N⁶)-methyltransferase (M.EcoRV) specifically modifies the first adenine residue within GATATC sequences. During catalysis, the enzyme flips its target base out of the DNA helix and binds it into a target base binding pocket which is formed in part by Lys16 and Tyr196. A cytosine residue is accepted by wild-type M.EcoRV as a substrate at a 31-fold reduced efficiency with respect to the k_cat/K_M values if it is located in a CT mismatch substrate (GCTATC/GATATC). Cytosine residues positioned in a CG base pair (GCTATC/GATAGC) are modified at much more reduced rates, because flipping out the target base is much more difficult in this case. We intended to change the target base specificity of M.EcoRV from adenine-N⁶ to cytosine-N⁴. To this end we generated, purified and characterized 15 variants of the enzyme, containing single, double and triple amino acid exchanges following different design approaches. One concept was to reduce the size of the target base binding pocket by site-directed mutagenesis. The K16R variant showed an altered specificity, with a 22-fold preference for cytosine as the target base in a mismatch substrate. This corresponds to a 680-fold change in specificity, which was accompanied by only a small loss in catalytic activity with the cytosine substrate. The K16R/Y196W variant no longer methylated adenine residues at all and its activity towards cytosine was reduced only 17-fold. Therefore, we have changed the target base specificity of M.EcoRV from adenine to cytosine by rational protein design. Because there are no natural paragons for the variants described here, a change of the target base specificity of a DNA interacting enzyme was possible by rational de novo design of its active site.     

The use of diaminopurine to investigate structural properties of nucleic acids and molecular recognition between ligands and DNA.

2,6-Diaminopurine (DAP) is an analogue of adenine which can be converted to nucleotides that serve as substrates for incorporation into nucleic acids by polymerases in place of (d)AMP. It pairs with thymidine (or uracil), engaging in three hydrogen bonds of the Watson-Crick type. The result of DAP incorporation is to add considerable stability to the double helix and to impart other structural features, such as an altered groove width and disruption of the normal spine of hydration. DNA containing DAP may or may not be recognized by restriction endonucleases; RNA containing DAP may not engage in normal splicing. The DAP.T pair affects the local flexibility of DNA and impedes the interaction with helix bending proteins. By providing a non-canonical hydrogen bond donor in the minor groove and/or blocking access to the floor of that groove it strongly affects interactions with small molecules such as antibiotics and anticancer drugs. Examples which illustrate altered recognition of nucleotide sequences in DAP-containing DNA are presented: changed sites of cutting by bleomycin, photocleavage by uranyl nitrate and footprinting with mithramycin. Using DNA in which both A-->DAP and G-->Inosine substitutions have been made it is possible to assess precisely the role of the purine 2-amino group in ligand-DNA recognition.     

Structures of Oligonucleotides Containing 5-(methoxymethyl)-2′-deoxyuridine Determined by NMR Spectroscopy

Abstract

Base pairing of 5-(methoxymethyl)-2′-deoxyuridine (MMdU) opposite either adenine or guanine in a seven base pair oligonucleotide duplex has been studied by NMR spectroscopy. When paired with A, we observe that the MMdU. Abase pair adopts Watson-Crick geometry. The methoxymethyl substituent is not held in a fixed conformation and may rotate around the C5-CH₂ and CH₂?O bonds. Examination of the potential energy as a function of rotation around these bonds indicates the presence of four low energy conformations. No hydrogen bonding is indicated for the methoxymethyl substituent, and the four potential minima result from reduced steric clash. For the MMdU. G base pair, the two bases adopt a wobble geometry which does not change with increasing solvent pH. Similarly, we find four low energy conformations for the methoxymethyl substituent in the major groove of the DNA helix.     

15N-Enriched 5-Fluorocytosine as a Probe for Examining Unusual DNA Structures

Abstract

A new method is presented for the synthesis of oligonucleotides containing ¹⁵N-enriched 5- fluorocytosine (FC). Due to the reduced pK of FC, the amino protons of an unpaired FC residue may be observed at lower values of solution pH. The labeled FC residue has been placed as a template base at a model DNA replication fork. The amino protons of the FC residue have been identified in isotope-edited NMR spectra. Data is presented for a template FC residue unpaired, paired with guanine, and mispaired with adenine. These studies demonstrate the utility of labeled FC in examining unusual DNA structures.     

Enantioselective Synthesis and Conformational Analysis of Cyclohexene Carbocyclic Nucleosides

Abstract

An enantioselective approach towards the synthesis of optically pure cyclohexene nucleosides 3 has been developed starting from (R)-carvone. The key steps are the regio- and stereoselective hydroboration of an exo double bond, the selective reduction of an enone intermediate and introduction of a base moiety by Mitsunobu reaction. Conformational analysis showed that the adenine base adopts predominantly in a pseudo-axial position.     

Synthesis and Hybridization Properties of Oligonucleotides Containing (2 S ,3 R )-9-(2,3,4-Trihydroxybutyl)Adenine

The synthesis and properties of oligonucleotides (ONs) containing 9-(2,3,4-trihydroxybutyl)adenine, A ^C2 and A ^C3, are described. The ON containing A ^C2 involves the 3′ → 4′ and 3′ → 5′ phosphodiester linkages in the strand, whereas that containing A ^C3 possesses the 3′ → 4′ and 2′ → 5′ phosphodiester linkages. It was found that incorporation of the analogs, A ^C2 or A ^C3, into ONs significantly reduces the thermal and thermodynamic stabilities of the ON/DNA duplexes, but does not largely decrease the thermal and thermodynamic stabilities of the ON/RNA duplexes as compared with the case of the ON/DNA duplexes. It was revealed that the base recognition ability of A ^C2 is greater than that of A ^C3 in the ON/RNA duplexes.     

Theoretical Design,Chemical Synthesis and Footprinting Analysis of a Novel Peptide Derivative of the Intercalator 7-H Pyridocarbazole Targeted Towards the Major Groove of DNA

Abstract

In order to target the major groove of DNA, we have designed novel peptide derivatives of 7-H pyridocarbazole, which is the chromophoric ring of ditercalinium, a potent antitumor bisin- tercalator. We will present here the results obtained with a compound that has a D-Asn tethered to the pyridinium nitrogen of the ring by a protonated β-alanyl-ethyl chain. We have investigated two alternative means of intercalation of the chromophore: first, into the (pur-pur) sequences, d(CpG)₂ and d(CpA)·d(TpG); second, into the (pur-pyr) sequences, d(GpC)₂and d(GpT)·d(ApC). For the first intercalative mode, the best bound triplet sequences are d(ACG)·d(CGT) and d(ACA) d(TGT), namely with an adenine immediately upstream from the intercalation site. In these complexes, the chromophore has its concave side in the major groove, its long axis nearly colinear with the mean long axis of the two base pairs of the intercalation site, and a bidentate H-bonded configuration occurs which involves the C=0 and NH groups of the D-Asn side chain and HN₆ and N₇ (resp.) of the adenine base upstream. One alkylammonium proton is H-bonded to N₇ of the guanine of the intercalation site, on the strand opposite to the one bearing the adenine. In the second intercalative mode, the chromophore's concave site now faces one DNA strand, and both alkylammonium protons are involved in H-bonds with N₇ and O₆ of the 3′ guanine on the same strand. The peptide's complexes with sequences having A, G, or C upstream of this guanine were computed to be energetically competitive with those with the best (pyr-pur) triplets. This provides a rare example of energetically favourable drug intercalation in-between (pur-pyr) sequences as compared to the standard (pyr-pur) ones. The synthesis of this compound was performed, and a series of footprinting experiments undertaken on a total of approximately 300 nucleotides. These experiments were consistent with the inferences from the theoretical computations.     

Theoretical study on the binding mechanism between N6-methyladenine and natural DNA bases

N6-methyladenine (m⁶A) is a rare base naturally occurring in DNA. It is different from the base adenine due to its N-CH₃. Therefore, the base not only pairs with thymine, but also with other DNA bases (cytosine, adenine and guanine). In this work, Møller-Plesset second-order (MP2) method has been used to investigate the binding mechanism between m⁶A and natural DNA bases in gas phase and in aqueous solution. The results show that N-CH₃ changed the way of N6-methyladenine binding to natural DNA bases. The binding style significantly influences the stability of base pairs. The trans-m⁶A:G and trans-m⁶A:C conformers are the most stable among all the base pairs. The existence of solvent can remarkably reduce the stability of the base pairs, and the DNA bases prefer pairing with trans-m⁶A to cis-m⁶A. Besides, the properties of these hydrogen bonds have been analyzed by atom in molecules (AIM) theory, natural bond orbital (NBO) analysis and Wiberg bond indexes (WBI). In addition, pairing with m⁶A decreases the binding energies compared to the normal Watson-Crick base pairs, it may explain the instability of the N6 site methylated DNA in theory.