The consensus sequence for self-catalyzed site-specific G residue depurination in DNA

Fluorescently probing site-specific and self-catalyzed DNA depurination

Depurination occurs via hydrolysis of the purine-deoxyribose glycosyl bond and causes nucleic acid damage. In particular, the DNA sequences that can undergo a self-catalyzed depurination (SCD) will cause a great uncertainty in duplicating, separating, purifying, and storing the DNA samples. Therefore, there is a great demand to develop a rapid detection method for SCD events. Herein, the use of a convenient fluorescence method to follow the site-specific SCD was demonstrated. We found that the resultant apurine site (AP site) from depurination can be selectively recognized by a fluorescent probe of palmatine (PAL) with a turn-on fluorescence response. The dependence of SCD on the bases of the depurination site, pH, metal ions, and time shows that our method can be used to rapidly evaluate the depurination process. Furthermore, the depurination process can be photo-switched using a photoacid as an external initiator. Our work will find wide applications in preliminarily identifying the DNA depurination.

A Role for the Mutagenic DNA Self-Catalyzed Depurination Mechanism in the Evolution of 7SL-Derived RNAs

The Alu element, the most prevalent SINE (short interspersed element) in the human genome, is one of the many RNA-encoding genes that evolved from the 7SL RNA gene. During analysis of the evolution of 7SL-derived RNAs, two distinct evolutionary intermediates capable of self-catalyzed DNA depurination (SDP) were identified. These SDP sequences spontaneously create apurinic sites that can result in increased mutagenesis due to their error-prone repair. This DNA self-depurination mechanism has been shown both in vitro and in vivo to lead to substitution and short frameshift mutations at a frequency that far exceeds their occurrence due to random errors in DNA replication. In both evolutionary intermediates, the same self-depurination sequence overlaps motifs necessary for successful transcription and SRP9/14 (signal recognition particle) binding; hence, mutations in this region could disrupt RNA activity. Yet, the 7SL-derived RNAs that arose from the elements capable of SDP show significant diversity in this region, and every new sequence retains the transcription and SRP9/14-binding motifs, even as it has lost the SDP sequence. While some (but not all) of the mutagenesis can be alternatively attributed to CpG decay, the very fact that the self-depurinating sequences are selectively discarded in all cases suggests that this was evolutionarily motivated to prevent further destructive mutagenesis by the SDP mechanism.

Site-Specific Self-Catalyzed DNA Depurination: A Biological Mechanism That Leads to Mutations and Creates Sequence Diversity

Self-catalyzed DNA depurination is a sequence-specific physiological mechanism mediated by spontaneous extrusion of a stem-loop catalytic intermediate. Hydrolysis of the 5'G residue of the 5'GA/TGG loop and of the first 5'A residue of the 5'GAGA loop, together with particular first stem base pairs, specifies their hydrolysis without involving protein, cofactor, or cation. As such, this mechanism is the only known DNA catalytic activity exploited by nature. The consensus sequences for self-depurination of such G- and A-loop residues occur in all genomes examined across the phyla, averaging one site every 2,000-4,000 base pairs. Because apurinic sites are subject to error-prone repair, leading to substitution and short frameshift mutations, they are both a source of genome damage and a means for creating sequence diversity. Their marked overrepresentation in genomes, and largely unchanging density from the lowest to the highest organisms, indicate their selection over the course of evolution. The mutagenicity at such sites in many human genes is associated with loss of function of key proteins responsible for diverse diseases.

Why the DNA self-depurination mechanism operates in HB-β but not in β-globin paralogs HB-δ, HB-ɛ1, HB-γ1 and HB-γ2

The human β-globin, δ-globin and ɛ-globin genes contain almost identical coding strand sequences centered about codon 6 having potential to form a stem-loop with a 5'GAGG loop. Provided with a sufficiently stable stem, such a structure can self-catalyze depurination of the loop 5'G residue, leading to a potential mutation hotspot. Previously, we showed that such a hotspot exists about codon 6 of β-globin, with by far the highest incidence of mutations across the gene, including those responsible for 6 anemias (notably Sickle Cell Anemia) and β-thalassemias. In contrast, we show here that despite identical loop sequences, there is no mutational hotspot in the δ- or ɛ1-globin potential self-depurination sites, which differ by only one or two base pairs in the stem region from that of the β-globin gene. These differences result in either one or two additional mismatches in the potential 7-base pair-forming stem region, thereby weakening its stability, so that either DNA cruciform extrusion from the duplex is rendered ineffective or the lifetime of the stem-loop becomes too short to permit self-catalysis to occur. Having that same loop sequence, paralogs HB-γ1 and HB-γ2 totally lack stem-forming potential. Hence the absence in δ- and ɛ1-globin genes of a mutational hotspot in what must now be viewed as non-functional homologs of the self-depurination site in β-globin. Such stem-destabilizing variants appeared early among vertebrates and remained conserved among mammals and primates. Thus, this study has revealed conserved sequence determinants of self-catalytic DNA depurination associated with variability of mutation incidence among human β-globin paralogs.

Non-enzymatic depurination of nucleic acids: factors and mechanisms

Depurination has attracted considerable attention since a long time for it is closely related to the damage and repair of nucleic acids. In the present study, depurination using a pool of 30-nt short DNA pieces with various sequences at diverse pH values was analyzed by High Performance Liquid Chromatography (HPLC). Kinetic analysis results showed that non-enzymatic depurination of oligodeoxynucleotides exhibited typical first-order kinetics, and its temperature dependence obeyed Arrhenius’ law very well. Our results also clearly showed that the linear relationship between the logarithms of rate constants and pH values had a salient point around pH 2.5. Interestingly and unexpectedly, depurination depended greatly on the DNA sequences. The depurination of poly (dA) was found to be extremely slow, and thymine rich sequences depurinated faster than other sequences. These results could be explained to some extent by the protonation of nucleotide bases. Moreover, two equations were obtained based on our data for predicting the rate of depurination under various conditions. These results provide basic data for gene mutagenesis and nucleic acids metabolism in acidic gastric juice and some acidic organelles, and may also help to rectify some misconceptions about depurination.

Polyvinyl pyrrolidone promotes DNA cleavage by a ROS-independent and depurination mechanism

Polyvinyl pyrrolidone polymer (PVP) has been widely applied in biological and medical fields. A few in vitro studies indicated that PVP might cause toxicity. However, the underlying mechanism is poorly understood. In this work, we found that PVP directly induced strand breakages of various DNA molecules, implicating a cleavage activity. Moreover, reactive oxygen species (ROS) scavenging analysis shows that DNA cleavage activity of PVP is not related to ROS-induced oxidation. As revealed by gel electrophoresis and liquid chromatography/mass spectrometry analysis, the major cleavage products of DNA were identified as two purine bases, guanine and adenine, suggesting that PVPs have a novel depurination activity. The selective depurination and DNA cleavage activity of PVPs were further confirmed by studying the interaction of PVP with four nucleosides and four well-designed oligodeoxynucleotides probes containing specific nucleotides. This study may provide insights into PVP-DNA interactions and resultant genotoxicity and may also open a new way for DNA study.

Self-catalytic DNA depurination underlies human β-globin gene mutations at codon 6 that cause anemias and thalassemias

The human β-globin gene contains an 18-nucleotide coding strand sequence centered at codon 6 and capable of forming a stem-loop structure that can self-catalyze depurination of the 5'G residue of that codon. The resultant apurinic lesion is subject to error-prone repair, consistent with the occurrence about this codon of mutations responsible for 6 anemias and β-thalassemias and additional substitutions without clinical consequences. The 4-residue loop of this stem-loop-forming sequence shows the highest incidence of mutation across the gene. The loop and first stem base pair-forming residues appeared early in the mammalian clade. The other stem-forming segments evolved more recently among primates, thereby conferring self-depurination capacity at codon 6. These observations indicate a conserved molecular mechanism leading to β-globin variants underlying phenotypic diversity and disease.

Self-catalyzed site-specific depurination of G residues mediated by cruciform extrusion in closed circular DNA plasmids

A major variety of "spontaneous" genomic damage is endogenous generation of apurinic sites. Depurination rates vary widely across genomes, occurring with higher frequency at "depurination hot spots." Recently, we discovered a site-specific self-catalyzed depurinating activity in short (14-18 nucleotides) DNA stem-loop-forming sequences with a 5'-G(T/A)GG-3' loop and T·A or G·C as the first base pair at the base of the loop; the 5'-G residue of the loop self-depurinates at least 10(5)-fold faster than random "spontaneous" depurination at pH 5. Formation of the catalytic intermediate for self-depurination in double-stranded DNA requires a stem-loop to extrude as part of a cruciform. In this study, evidence is presented for self-catalyzed depurination mediated by cruciform formation in plasmid DNA in vitro. Cruciform extrusion was confirmed, and its extent was quantitated by digestion of the plasmid with single strand-specific mung bean endonuclease, followed by restriction digestion and sequencing of resulting mung bean-generated fragments. Appearance of the apurinic site in the self-depurinating stem-loop was confirmed by digestion of plasmid DNA with apurinic endonuclease IV, followed by primer extension and/or PCR amplification to detect the endonuclease-generated strand break and identify its location. Self-catalyzed depurination was contingent on the plasmid being supercoiled and was not observed in linearized plasmids, consistent with the presence of the extruded cruciform in the supercoiled plasmid and not in the linear one. These results indicate that self-catalyzed depurination is not unique to single-stranded DNA; rather, it can occur in stem-loop structures extruding from double-stranded DNA and therefore could, in principle, occur in vivo.