Hybridization kinetics between immobilized double-stranded DNA probes and targets containing embedded recognition segments

We have investigated the time-dependent strand displacement activity of several targets with double-stranded DNA probes (dsProbes) of varying affinity. Here, the relative affinity of various dsProbes is altered through choices in hybridization length (11-15 bases) and the selective inclusion of center mismatches in the duplexes. While the dsProbes are immobilized on microspheres, the soluble, 15 base-long complementary sequence is presented either alone as a short target strand or as a recognition segment embedded within a longer target strand. Compared to the short target, strand displacement activity of the longer targets is slower, but still successful. Additionally, the longer targets exhibit modest differences in the observed displacement rates, depending on the location of recognition segment within the long target. Overall, our study demonstrates that the kinetics of strand displacement activity can be tuned through dsProbe sequence design parameters and is only modestly affected by the location of the complementary segment within a longer target strand.     

Polycationic ligands of different chemical classes stimulate DNA strand displacement between short oligonucleotides in a protein‐free system

The ability of polycationic ligands to stimulate DNA strand displacement between short oligonucleotides in a protein‐free system is demonstrated. We show that two ligands, tetracationic aliphatic amine (spermine) and a dicationic intercalating drug (chloroquine), promote strand displacement in a concentration‐dependent manner. At low concentrations both ligands decelerate spontaneous strand displacement because of their impact on the stability of the DNA duplex. At elevated concentrations they accelerate strand displacement via formation of intermediate structures containing three DNA strands. The rate of the last process does not correlate with the thermal dissociation rate of the entire DNA duplex. It indicates that, possibly, the action of these agents cannot be explained by their influence on the stability of the DNA duplex. In general, our results suggest that the ability to stimulate DNA strand displacement appears to be a common feature of polycations of different chemical and structural classes. © 2016 Wiley Periodicals, Inc. Biopolymers 105: 633–641, 2016.     

A molecular model for RecA-promoted strand exchange via parallel triple-stranded helices.

A number of studies have concluded that strand exchange between a RecA-complexed DNA single strand and a homologous DNA duplex occurs via a single-strand invasion of the minor groove of the duplex. Using molecular modeling, we have previously demonstrated the possibility of forming a parallel triple helix in which the single strand interacts with the intact duplex in the minor groove, via novel base interactions (Bertucat et al., J. Biomol. Struct. Dynam. 16:535-546). This triplex is stabilized by the stretching and unwinding imposed by RecA. In the present study, we show that the bases within this triplex are appropriately placed to undergo strand exchange. Strand exchange is found to be exothermic and to result in a triple helix in which the new single strand occupies the major groove. This structure, which can be equated to so-called R-form DNA, can be further stabilized by compression and rewinding. We are consequently able to propose a detailed, atomic-scale model of RecA-promoted strand exchange. This model, which is supported by a variety of experimental data, suggests that the role of RecA is principally to prepare the single strand for its future interactions, to guide a minor groove attack on duplex DNA, and to stabilize the resulting, stretched triplex, which intrinsically favors strand exchange. We also discuss how this mechanism can incorporate homologous recognition.     

Quantitation of radiation-, chemical-, or enzyme-induced single strand breaks in nonradioactive DNA by alkaline gel electrophoresis: application to pyrimidine dimers

We have developed an alkaline agarose gel method for quantitating single strand breaks in nanogram quantities of nonradioactive DNA. After electrophoresis together with molecular length standards, the DNA is neutralized, stained with ethidium bromide, photographed, and the density profiles recorded with a computer controlled scanner. The median lengths, number average molecular lengths, and length average molecular lengths of the DNAs can be computed by using the mobilities of the molecular length standards. The frequency of single strand breaks can then be determined by comparison of the corresponding average molecular lengths of DNAs treated and not treated with single strand break-inducing agents (radiation, chemicals, or lesion-specific endonuclease). Single strand break yields (induced at pyrimidine dimer sites in uv-irradiated human fibroblasts DNA by the dimer-specific endonuclease from Micrococcus luteus) from our method agree with values obtained for the same DNAs from alkaline sucrose gradient analysis. The method has been used to determine pyrimidine dimer yields in DNA from biopsies of human skin irradiated in situ. It will be especially useful in determining the frequency of single strand breaks (or lesions convertible to single strand breaks by specific cleaving reagents or enzymes) in small quantities of DNA from cells or tissues not amenable to radioactive labeling.     

Mechanism of mitochondrial DNA replication in mouse L-cells: kinetics of synthesis and turnover of the initiation sequence

Pulse-chase radioactive labeling experiments using thymidine kinase-plus mouse LA9 cells have shown that the 7 S mitochondrial DNA initiation sequence of mitochondrial DNA is synthesized and turned over at a faster rate than previously determined. These pulse-chase labeling experiments have also determined that the replication time of mouse LA9 cell mitochondrial DNA is one hour. The halflife of pulse-labeled 7 S mitochondrial DNA initiation sequences is approximately 70 minutes. This turnover is so rapid that at least 95% of the mitochondrial DNA initiation sequences synthesized are lost to turnover without acting as primers for expansion synthesis of the mitochondrial DNA heavy strand. The mechanism of 7 S mitochondrial DNA turnover does not lead to significant accumulation of free 7 S mitochondrial DNA single-strands within mitochondria. Resynthesis of the 7 S mitochondrial DNA initiation sequence is sufficiently rapid that the majority of mitochondrial DNA molecules are maintained as displacement loop molecules. Approximately 20% of all nucleotides polymerized into mitochondrial DNA are incorporated into the 7 S initiation sequences. The size of newly synthesized 7 S mitochondrial DNA strands varies from about 500 to 620 nucleotides. Several size classes are resolved by polyacrylamide/urea gel electrophoresis and each class has approximately the same turnover rate.Mouse LD cells maintain their mitochondrial DNA genomes as unicircular, head-to-tail dimers. Since a significant fraction of these unicircular dimers contain only one displacement loop, the size of the initiation sequence in such molecules should be twice as long if synthesis of the strand is limited by the free energy of superhelix formation. An identical array of size classes of 7 S strands is obtained from this cell line as compared to mouse LA9 cells. This indicates that the extent of 7 S mitochondrial DNA synthesis is most likely determined by a nucleotide sequence specific event.     

Characterization of strand displacement synthesis catalyzed by bacteriophage T7 DNA polymerase

The DNA polymerase induced after infection of Escherichia coli by bacteriophage T7 can exist in two forms. One distinguishing property of Form I, the elimination of nicks in double-stranded DNA templates, strongly suggests that this form of the polymerase catalyzes limited DNA synthesis at nicks, resulting in displacement of the downstream strand. In this paper, we document this reaction by a detailed characterization of the DNA product. DNA synthesis on circular, duplex DNA templates containing a single site-specific nick results in circular molecules bearing duplex branches. Analysis of newly synthesized DNA excised from the product shows that the majority of the branches are less than 500 base pairs in length and that they arise from a limited number of sites. The branches have fully base-paired termini but are attached by two noncomplementary DNA strands that have a combined length of less than 30 nucleotides. The product molecules are topologically constrained as a result of the duplex branch. DNA sequence analysis has provided an unequivocal structure of one such product molecule. We conclude that strand displacement synthesis catalyzed by Form I of T7 DNA polymerase is terminated by a template-switching reaction. We propose two distinct models for template-switching that we call primer relocation and rotational strand exchange. Strand displacement synthesis catalyzed by Form I of T7 DNA polymerase effectively converts T7 DNA circles that are held together by hydrogen bonds in their 160-nucleotide-long terminal redundancy to T7-length linear molecules. We suggest that strand displacement synthesis catalyzed by T7 DNA polymerase is essential in vivo to the processing of a T7 DNA concatemer to mature T7 genomes.     

Labeling of unique sequences in double-stranded DNA at sites of vicinal nicks generated by nicking endonucleases

We describe a new approach for labeling of unique sequences within dsDNA under nondenaturing conditions. The method is based on the site-specific formation of vicinal nicks, which are created by nicking endonucleases (NEases) at specified DNA sites on the same strand within dsDNA. The oligomeric segment flanked by both nicks is then substituted, in a strand displacement reaction, by an oligonucleotide probe that becomes covalently attached to the target site upon subsequent ligation. Monitoring probe hybridization and ligation reactions by electrophoretic mobility retardation assay, we show that selected target sites can be quantitatively labeled with excellent sequence specificity. In these experiments, predominantly probes carrying a target-independent 3′ terminal sequence were employed. At target labeling, thus a branched DNA structure known as 3′-flap DNA is obtained. The single-stranded terminus in 3′-flap DNA is then utilized to prime the replication of an externally supplied ssDNA circle in a rolling circle amplification (RCA) reaction. In model experiments with samples comprised of genomic λ-DNA and human herpes virus 6 type B (HHV-6B) DNA, we have used our labeling method in combination with surface RCA as reporter system to achieve both high sequence specificity of dsDNA targeting and high sensitivity of detection. The method can find applications in sensitive and specific detection of viral duplex DNA.     

Roles of DNA ligase III and XRCC1 in regulating the switch between short patch and long patch BER

Damaged DNA bases are repaired by base excision repair (BER), which can proceed via two pathways: short patch and long patch BER. During the latter, a stretch of several nucleotides is replaced by strand displacement DNA synthesis. We recently demonstrated that the ATP concentration may govern the decision between these BER sub-pathways. Employing a reconstituted BER complex containing among others DNA polymerase beta (Pol beta), DNA ligase III (Lig III) and XRCC1, here we show that Lig III and XRCC1 are essential mediators of this regulation. XRCC1 stimulates Pol beta strand displacement activity and releases inhibition of Pol beta by DNA-bound Lig III if ligation is prevented. XRCC1 is thus able to strongly promote strand displacement and long patch BER under conditions of ATP shortage. If sufficient ATP is available, ligation by Lig III prevents strand displacement, leading to short patch BER. Ligation-inactive mutants of Lig III do not prevent strand displacement by Pol beta under the same conditions. Consequently, the preferred use of short patch BER depends on the ligation competence of Lig III. Accordingly, lowering the levels of the XRCC1/Lig III complex in HeLa cells using siRNA decreases ligation capacity but enhances Pol beta-dependent DNA synthesis.     

Multiplexed and reiterative fluorescence labeling via DNA circuitry

A class of reactive DNA circuits was adapted as erasable molecular imaging probes that allow fluorescent reporting complexes to be assembled and disassembled on a biological specimen. Circuit reactions are sequence-dependent and therefore facilitate multiplexed (multicolor) detection. Yet, the ability to disassemble reporting complexes also allows fluorophores to be removed and new circuit complexes to be used to label additional markers. Thus, these probes present opportunities to increase the total number of molecular targets that can be visualized on a biological sample by allowing multiple rounds of fluorescence microscopy to be performed.     

SIMPLE: A Sequential Immunoperoxidase Labeling and Erasing Method

The ability to simultaneously visualize expression of multiple antigens in cells and tissues can provide powerful insights into cellular and organismal biology. However, standard methods are limited to the use of just two or three simultaneous probes and have not been widely adopted for routine use in paraffin-embedded tissue. We have developed a novel approach called sequential immunoperoxidase labeling and erasing (SIMPLE) that enables the simultaneous visualization of at least five markers within a single tissue section. Utilizing the alcohol-soluble peroxidase substrate 3-amino-9-ethylcarbazole, combined with a rapid non-destructive method for antibody–antigen dissociation, we demonstrate the ability to erase the results of a single immunohistochemical stain while preserving tissue antigenicity for repeated rounds of labeling. SIMPLE is greatly facilitated by the use of a whole-slide scanner, which can capture the results of each sequential stain without any information loss. (J Histochem Cytochem 57:899–905, 2009)     

Fine structural in situ analysis of nascent DNA movement following DNA replication

Nascent DNA (newly replicated DNA) was visualized in situ with regard to the position of the previously replicated DNA and to chromatin structure. Localization of nascent DNA at the replication sites can be achieved through pulse labeling of cells with labeled DNA precursors during very short periods of time. We were able to label V79 Chinese Hamster cells for as shortly as 2 min with BrdU; Br-DNA, detected by immunoelectron microscopy, occurs at the periphery of dense chromatin, at individual dispersed chromatin fibers, and within dispersed chromatin areas. In these regions DNA polymerase alpha was also visualized. After a 5-min BrdU pulse, condensed chromatin also became labeled. When the pulse was followed by a chase, a larger number of gold particles occurred on condensed chromatin. Double-labeling experiments, consisting in first incubating cells with IdU for 20 min, chased for 10 min and then labeled for 5 min with CldU, reveal CldU-labeled nascent DNA on the periphery of condensed chromatin, while previously replicated IdU-labeled DNA has been internalized into condensed chromatin. Altogether, these results show that the sites of DNA replication correspond essentially to perichromatin regions and that the newly replicated DNA moves rapidly from replication sites toward the interior of condensed chromatin areas.     

The segregation of DNA in epithelial stem cells

It has recently been suggested that stem cells may invariably keep, from one division to the next, the daughter DNA molecules that contain the older of the two parental strands—that is, they may retain a complete set of “immortal strands,” through successive cell divisions (Cairns, 1975). We can test this hypothesis by labeling either the old immortal strands at the time the stem cells are created or the newly synthesized strands during subsequent divisions of the stem cells. In the former case, the stem cells should become permanently labeled; in the latter case, they should eliminate their label on their second division.Experiments of this sort have been conducted with the tongue papilla under steady state conditions and with the regenerating small intestinal crypts. The results clearly show that by far most of the multiplying cells in tongue and intestinal epithelium segregate their DNA “randomly” at mitosis. Nevertheless, the results, though far from conclusive, suggest that there are a small number of cells (1–5 in the stem cell region of each crypt and one at the base of each column of cells in the tongue) that selectively segregate their old and new DNA strands in the expected way. Thus in the immortal strand labeling experiments, there are a few labeled cells that retain their label for up to 4 weeks; conversely, in the new strand labeling experiments, a few cells appear to rid themselves of label after intervals equivalent to approximately two cell cycles.     

Fine Structural in Situ Analysis of Nascent DNA Movement Following DNA Replication

Nascent DNA (newly replicated DNA) was visualized in situ with regard to the position of the previously replicated DNA and to chromatin structure. Localization of nascent DNA at the replication sites can be achieved through pulse labeling of cells with labeled DNA precursors during very short periods of time. We were able to label V79 Chinese Hamster cells for as shortly as 2 min with BrdU; Br-DNA, detected by immunoelectron microscopy, occurs at the periphery of dense chromatin, at individual dispersed chromatin fibers, and within dispersed chromatin areas. In these regions DNA polymerase α was also visualized. After a 5-min BrdU pulse, condensed chromatin also became labeled. When the pulse was followed by a chase, a larger number of gold particles occurred on condensed chromatin. Double-labeling experiments, consisting in first incubating cells with IdU for 20 min, chased for 10 min and then labeled for 5 min with CldU, reveal CldU-labeled nascent DNA on the periphery of condensed chromatin, while previously replicated IdU-labeled DNA has been internalized into condensed chromatin. Altogether, these results show that the sites of DNA replication correspond essentially to perichromatin regions and that the newly replicated DNA moves rapidly from replication sites toward the interior of condensed chromatin areas.     

Nitric oxide fully protects against UVA-induced apoptosis in tight correlation with Bcl-2 up-regulation

A variety of toxic and modulating events induced by UVA exposure are described to cause cell death via apoptosis. Recently, we found that UV irradiation of human skin leads to inducible nitric-oxide synthase (iNOS) expression in keratinocytes and endothelial cells (ECs). We have now searched for the role of iNOS expression and nitric oxide (NO) synthesis in UVA-induced apoptosis as detected by DNA-specific fluorochrome labeling and in DNA fragmentation visualized by in situ nick translation in ECs. Activation with proinflammatory cytokines 24 h before UVA exposure leading to iNOS expression and endogenous NO synthesis fully protects ECs from the onset of apoptosis. This protection was completely abolished in the presence of the iNOS inhibitor L-N5-(1-iminoethyl)-ornithine (0.25 mM). Additionally, preincubation of cells with the NO donor (Z)-1-[N(2-aminoethyl)-N-(2-ammonioethyl)amino]diazen-1-i um-1, 2-diolate at concentrations from 10 to 1000 microM as an exogenous NO-generating source before UVA irradiation led to a dose-dependent inhibition of both DNA strand breaks and apoptosis. In search of the molecular mechanism responsible for the protective effect, we find that protection from UVA-induced apoptosis is tightly correlated with NO-mediated increases in Bcl-2 expression and a concomitant inhibition of UVA-induced overexpression of Bax protein. In conclusion, we present evidence for a protective role of iNOS-derived NO in skin biology, because NO either endogenously produced or exogenously applied fully protects against UVA-induced cell damage and death. We also show that the NO-mediated expression modulation of proteins of the Bcl-2 family, an event upstream of caspase activation, appears to be the molecular mechanism underlying this protection.     

DNA hairpins: fuel for autonomous DNA devices

We present a study of the hybridization of complementary DNA hairpin loops, with particular reference to their use as fuel for autonomous DNA devices. The rate of spontaneous hybridization between complementary hairpins can be reduced by increasing the neck length or decreasing the loop length. Hairpins with larger loops rapidly form long-lived kissed complexes. Hairpin loops may be opened by strand displacement using an opening strand that contains the same sequence as half of the neck and a "toehold" complementary to a single-stranded domain adjacent to the neck. We find loop opening via an external toehold to be 10-100 times faster than via an internal toehold. We measure rates of loop opening by opening strands that are at least 1000 times faster than the spontaneous interaction between hairpins. We discuss suitable choices for loop, neck, and toehold length for hairpin loops to be used as fuel for autonomous DNA devices.     

In vitro repair of DNA hairpins containing various numbers of CAG/CTG trinucleotide repeats

Expansion of CAG/CTG trinucleotide repeats (TNRs) in humans is associated with a number of neurological and neurodegenerative disorders including Huntington's disease. Increasing evidence suggests that formation of a stable DNA hairpin within CAG/CTG repeats during DNA metabolism leads to TNR instability. However, the molecular mechanism by which cells recognize and repair CAG/CTG hairpins is largely unknown. Recent studies have identified a novel DNA repair pathway specifically removing (CAG)(n)/(CTG)(n) hairpins, which is considered a major mechanism responsible for TNR instability. The hairpin repair (HPR) system targets the repeat tracts for incisions in the nicked strand in an error-free manner. To determine the substrate spectrum of the HPR system and its ability to process smaller hairpins, which may be the intermediates for CAG/CTG expansions, we constructed a series of CAG/CTG hairpin heteroduplexes containing different numbers of repeats (from 5 to 25) and examined their repair in human nuclear extracts. We show here that although repair efficiencies differ slightly among these substrates, removal of the individual hairpin structures all involve endonucleolytic incisions within the repeat tracts in the nicked DNA strand. Analysis of the repair intermediates defined specific incision sites for each substrate, which were all located within the repeat regions. Mismatch repair proteins are not required for, nor do they inhibit, the processing of smaller hairpin structures. These results suggest that the HPR system ensures CAG/CTG stability primarily by removing various sizes of (CAG)(n)/(CTG)(n) hairpin structures during DNA metabolism.     

DNA double strand break responses and chromatin alterations within the aging cell

Cellular senescence is a state of permanent replicative arrest that allows cells to stay viable and metabolically active but resistant to apoptotic and mitogenic stimuli. Specific, validated markers can identify senescent cells, including senescence-associated β galactosidase activity, chromatin alterations, cell morphology changes, activated p16- and p53-dependent signaling and permanent cell cycle arrest. Senescence is a natural consequence of DNA replication-associated telomere erosion, but can also be induced prematurely by telomere-independent events such as failure to repair DNA double strand breaks. Here, we review the molecular pathways of senescence onset, focussing on the changes in chromatin organization that are associated with cellular senescence, particularly senescence-associated heterochromatin foci formation. We also discuss the altered dynamics of the DNA double strand break response within the context of aging cells. Appreciating how, mechanistically, cellular senescence is induced, and how changes to chromatin organization and DNA repair contributes to this, is fundamental to our understanding of the normal and premature human aging processes associated with loss of organ and tissue function in humans.     

Single molecule linear analysis of DNA in nano-channel labeled with sequence specific fluorescent probes

An array of nano-channels was fabricated from silicon based semiconductor materials to stretch long, native dsDNA. Here we present a labeling scheme in which it is possible to identify the location of specific sequences along the stretched DNA molecules. The scheme proceeds by first using the strand displacement activity of the Vent (exo-) polymerase to generate single strand flaps on nicked dsDNA. These single strand flaps are hybridized with sequence specific fluorophore-labeled probes. Subsequent imaging of the DNA molecules inside a nano-channel array device allows for quantitative identification of the location of probes. The highly efficient DNA hybridization on the ss-DNA flaps is an excellent method to identify the sequence motifs of dsDNA as it gives us unique ability to control the length of the probe sequence and thus the frequency of hybridization sites on the DNA. We have also shown that this technique can be extended to a multi color labeling scheme by using different dye labeled probes or by combining with a DNA- polymerase-mediated incorporation of fluorophore-labeled nucleotides on nicking sites. Thus this labeling chemistry in conjunction with the nano-channel platform can be a powerful tool to solve complex structural variations in DNA which is of importance for both research and clinical diagnostics of genetic diseases.     

A role for single-stranded templates in cell-free adeno-associated virus DNA replication

Assays have been described in which duplex adeno-associated virus (AAV) DNA can be replicated in HeLa cell extracts with exogenous AAV Rep protein. These assays appear to mimic the AAV DNA replication that occurs in the cell, including the ability of extracts from adenovirus (Ad)-infected cells to replicate duplex AAV DNA templates more efficiently than extracts from uninfected cells can. We showed previously that the Ad-infected extract was able to support a more processive replication than the uninfected extract. When the Ad single-stranded DNA binding protein (Ad-DBP) was added to an uninfected extract, DNA replication became processive. Based on a strand displacement replication model, we hypothesized that the Ad-DBP was stabilizing the displaced single-stranded DNA during strand displacement replication. In this report, we show that in Ad-infected extracts most of the newly replicated duplex DNA is converted into a single-stranded form shortly after synthesis. Using the results of assays for the replication of single-stranded AAV DNA, we show that these single-stranded molecules serve as templates for additional replication. In addition, we identify a class of molecules which are likely to be intermediates of replication on single-stranded templates. We discuss a possible role for replication of single-stranded molecules in the infected cell.     

Visualization of irreparable ischemic damage in brain by selective labeling of double strand blunt-ended DNA breaks

BACKGROUND: Double-strand DNA breaks with blunt ends represent the most serious type of DNA damage, and cannot be efficiently repaired by cells. They are generated in apoptosis or necrosis and are absent in normal or transiently damaged cells. Consequently, they can be used as a molecular marker of irreparable cellular damage. We evaluated the effects of focal brain ischemia using selective labeling of blunt-ended DNA breaks as a marker of irreversible tissue damage. A new approach permitting such analysis in situ is introduced. MATERIALS AND METHODS: Rat brain sections taken 6, 24, 48 and 72 hr after the onset of focal brain ischemia were used. Double-strand DNA breaks were detected directly in the tissue sections via ligation of blunt-ended hairpin-shaped oligonucleotide probes. The probes were attached to the ends of the breaks by T4 DNA ligase. Conventional cresyl violet co-staining and terminal transferase based labeling (TUNEL) were employed to analyze the distribution of labeled cells. RESULTS: Double-strand blunt-ended DNA breaks rapidly accumulate in brain cells after focal brain ischemia. At 24 hr, they concentrate in the peripheral areas of stroke, which are prone to ischemia-reoxygenation. By 48-72 hr, this type of DNA damage spreads inward, covering the internal areas of the ischemic zone. CONCLUSIONS: Selective labeling of blunt-ended DNA breaks delineates the dynamics of stroke-induced irreversible DNA damage and provides highly specific detection of brain cells with irreparable DNA injury. It can be used for comparing the efficiency of various anti-ischemic drugs, particularly those that target DNA damage, as well as for monitoring stroke-induced damage.