Why do O-alkylguanine and O-alkylthymine miscode? The relationship between the structure of DNA containing O-alkylguanine and O-alkylthymine and the mutagenic properties of these bases

The carcinogenic and mutagenic N-nitroso compounds produce GC to AT and TA to GC transition mutations because they alkylate O⁶ of guanine and O⁴ of thymine. It has been generally assumed that these mutations occur because O⁶-alkylguanine forms a stable mispair with thymine and O⁴-alkylthymine forms a mispair with guanine. Recent studies have shown that this view is mistaken and that the alkylG·T and alkylT·G mispairs are not more stable than their alkylG·C or alkylT·A counterparts. Two possible explanations based on recent structural studies are put forward to account for the miscoding. The first possibility is that the DNA polymerase might mistake O⁶-alkylguanine for adenine, and O⁴-alkylthymine for cytosine, because of the physical similarity of these bases. O⁶-Methylguanine and adenine are similarly lipophilic and X-ray crystallography of the nucleosides has shown a close similarity in bond angles and lengths between O⁶-methylguanine and adenine, and between O⁴-methylthymine and cytosine. The second possible explanation is that the important factor in the miscoding is that the alkylG·T and alkylT·G mispairs retain the Watson-Crick alignment with N1 of the purine juxtaposed to N3 of the pyrimidine while the alkylG·C and alkylT·A pairs adopt a wobble conformation. ³¹P NMR of DNA duplexes show that the phosphodiester links both 3′ and 5′ to the C have to be distorted to accomodate the O⁶-ethylguanine:C pair, whereas there is less distortion of the phosphodiesters 3′ and 5′ to the T in an ethylG·T pair. Recent kinetic measurements show that the essential aspect of base selection in DNA synthesis is the ease of formation of the phosphodiester links on both the 3′ and 5′ side of the incoming base. The Watson-Crick alignment of the alkylG·T and alkylT·G mispairs may facilitate formation of these phosphodiester links, and this alignment rather than the strength of the base pairs and the extent of hydrogen bonding between them may be the crucial factor in the miscoding. If either hypothesis is correct it suggests that previously too much emphasis has been placed on the stability of the normal pairs in the replication of DNA.     

Loopstructures in synthetic oligonucleotides. Hairpin stability and structure studied as a function of loop elongation

The formation of hairpin structures in the homologous, (partly) self-complementary DNA fragments d(ATCCTAT_nTAGGAT), n = 0–7, was studied by means of nuclear magnetic resonance, T-jump and ultra-violet techniques. It is shown that all compounds in the series may adopt hairpin-like conformations, albeit for n < 3 this only occurs to a significant amount at relatively low concentrations (∼ 10μM). For the present series of oligonucleotides, hairpin formation is accompanied by an apparent loop enthalpy significantly different from zero. The stability of the DNA hairpins turns out to be at its maximum for loop lengths of four or five residues, whereas earlier experiments (Tinocoet al., 1973) indicated that loop lengths of six to seven residues are most favourable for RNA hairpins. This is explained by considering the difference in geometry of A-RNA and B-DNA helices.     

A convenient solid phase approach to obtain lipophilic 5′-phosphoramidate derivatives of DNA and RNA oligonucleotides

This paper explores the potential of a modified phosphotriester approach to the synthesis of 5′-phosphoramidate derivatives of DNA and RNA oligonucleotides. The modification of 5′-deprotected support-bound oligonucleotides is done in two steps: i) conversion of the 5′-OH group of an oligonucleotide into an activated phosphodiester, and ii) treatment of the activated phosphodiester with an aminocompound. The approach is efficient and compatible with conventional solid phase oligonucleotide synthesis. It can be used for the conjugation of therapeutically relevant oligonucleotides with functional moieties or carrier constructions, which are to be removed after endocytosis.     

反义c－fos和c－jun抑制IL－1诱导阿片肽分泌

白细胞介素-1(IL-1)及阿片肽作为神经调质参与了神经细胞兴奋性毒性作用.以大鼠大脑皮层神经细胞为研究对象,探讨了IL-1、阿片肽和c-fos、c-jun表达产物之间的关系.结果表明,IL-1β能诱导大脑皮层神经细胞c-fos、c-jun mRNA瞬时短暂表达,15min增高,30min达高峰,c-fos mKNA 2h回至基线水平,c-jun mRNA 8h回至基线水平;联合应用c-fos、c-jun反义寡核苷酸能部分抑制IL-1诱导的大脑皮层神经细胞脑啡肽及β-内啡肽分泌增加,呈一定量效关系,相应意义寡核苷酸无抑制作用.提示IL-1促进大脑皮层神经细胞脑啡肽及β-内啡肽分泌作用部分受Fos和Jun蛋白调控.     

How human IgGs against DNA recognize oligonucleotides and DNA

In the literature, there are no available data on how anti‐DNA antibodies recognize DNA. In the present work, to study the molecular mechanism of DNA recognition by antibodies, we have used anti‐DNA IgGs from blood sera of patients with multiple sclerosis. A stepwise increase in ligand complexity approach was used to estimate the relative contributions of virtually every nucleotide unit of different single‐ (ss) and double‐stranded (ds) oligonucleotides to their affinity for IgG fraction having high affinity to DNA‐cellulose. DNA‐binding site disposed on the heavy chain demonstrates higher affinity to different dNMPs (K_d = 0.63μM‐3.8μM) than the site located on the light chain (28μM‐170μM). The heavy and light chains interact independently forming relatively strong contacts with 2 to 4 nucleotides of short homo‐ and hetero‐d(pN)_2‐9. Then the increase in the affinity of different d(pN)_n became minimal, and at n ≥ 8 to 9, all dependencies reached plateaus: approximately 3.2nM to 20nM and approximately 200nM to 460nM for the heavy and light chains, respectively. A similar situation was observed for different ribooligonucleotides, in which their affinity is 6‐fold to 100‐fold lower than that for d(pN)_n. Transition from ss to ds d(pN)_n leads to a moderate increase in affinity of ligands to DNA‐binding site of heavy chains, while light chains demonstrate the same affinity for ss and ds d(pN)_n. Long supercoiled DNA interacts with both heavy and light chains with affinity of approximately 10‐fold higher than that for short oligonucleotides. The thermodynamic models were constructed to describe the interactions of IgGs light and heavy chains with DNA.     

An alternative to ITS, a hypervariable, single-copy nuclear intron in corals, and its use in detecting cryptic species within the octocoral genus Carijoa

Here we report a highly variable nuclear marker that can be used for both soft and stony corals. Primers that amplify a ∼177 bp fragment from the nuclear gene encoding the 54 kDa subunit of the signal recognition particle (SRP54) were developed for the octocoral genus Carijoa. Cloning results from 141 individuals suggest that this hypervariable nuclear locus is a single-copy gene. Sequencing revealed a potential cryptic species previously thought to be Carijoa riisei. Results from an Analysis of Molecular Variance (AMOVA) based on mitochondrial DNA (mtDNA) explained <10% of the variation between Atlantic and Pacific samples of C. riisei (F _st = 0.47), whereas the same comparison with SRP54 explained >33% of the variation (F _st = 0.54). Using previously reported degenerate primers for SRP54, high levels of sequence variation were found at this locus across both scleractinian and octocorals. For example, pairwise sequence divergence within octocorals was ∼8–13 times greater with SRP54 than with mtDNA, and, up to 2.8% pairwise sequence divergence was found in SRP54 among individuals of Pocillopora whereas no variation at all was found in mtDNA markers. This case study with the octocoral C. riisei shows that variation in SRP54 appears sufficient to address questions of phylogeography as well as systematics of closely related species.     

Studying the Influence of the Pyrene Intercalator TINA on the Stability of DNA i-Motifs

Certain cytosine-rich (C-rich) DNA sequences can fold into secondary structures as four-stranded i-motifs with hemiprotonated base pairs. Here we synthesized C-rich TINA-intercalating oligonucleotides by inserting a nonnucleotide pyrene moiety between two C-rich regions. The stability of their i-motif structures was studied by using UV melting temperature measurements and circular dichroism spectra at different pH values under noncrowding and crowding conditions (20% poly(ethylene glycol)). When TINA ((R)-3-((4-(1-pyrenylethynyl)benzyl)oxy) propane-1,2-diol) is inserted, the oligonucleotides could form an i-motif at a higher pH than observed for the corresponding wildtype oligonucleotide.     

Stereoselective Nucleoside Deuteration for NMR Studies of DNA

A procedure has been elaborated for stereoselective deuterium substitution of one of the diastereotopic 5′-protons in 2′-deoxynucleotides. The synthetic scheme uses the reduction of the 5-oxosugar derivative with deuterated Alpine-Borane. The resulting deuterosugar is converted into pyrimidine nucleosides and incorporated into DNA using standard protocols. Comparison of two-dimensional NMR spectra of the fully protonated and partially deuterated duplexes allowed us to assign diastereotopic 5′ protons, increasing the number of experimental restraints used for structure determination.     

Further Optimization of Detritylation in Solid-Phase Oligodeoxyribonucleotide Synthesis

Various conditions for optimum detritylation (i.e., the removal of 5′-O-trityl protecting groups) during solid-phase synthesis of oligodeoxyribonucleotides were investigated. Di- and tri-chloroacetic acids of variable concentrations were used to study the removal of the 4,4′-dimethoxytrityl (DMTr) group. It was found that the DMTr group could be completely removed under much milder acidic conditions than what are currently used for automated solid-phase synthesis. The 2,7-dimethylpixyl (DMPx) is proposed as an alternative and more readily removable group for the protection of the 5′-OH functions both in solid- and solution-phase synthesis. The improved detritylation conditions are expected to minimize the waste and offer a protocol for incorporation of acid sensitive building-blocks in oligonucleotides.