In situ fluorescent nick translation procedure for plant chromosomes

Pectinase and cellulase, which are used to macerate plant material, always show traces of DNase activities that result in DNA nicking. Moreover, the DNA polymerase I usually applied in the in situ nick translation techniques shows both 5' to 3' and 3' to 5' exonuclease activities. As a result, significant nonspecific labeling appears in control preparations that are not digested by a restriction endonuclease. Our procedure includes blocking nonspecific nick labeling before incubation with restriction enzymes (HpaII and HaeIII). This is achieved by incorporation of ddGTP into DNA by the Taq polymerase which lacks 3' to 5' exonuclease activity. This method gives satisfactory results because it eliminates nonspecific nick translation signals that are present after applying the methods described for animal material.     

Breakage of double-stranded DNA due to single-stranded nicking

Enzymes such as pancreatic deoxyribonuclease (DNase I) nick the single strands of double-stranded DNA. Two nicks sufficiently close on opposite strands will lead to breakage of the DNA molecule. This paper gives a mathematical model for the breakage of circular, supercoiled DNA under the action of an enzyme which nicks at random sites (or at preferred sites, these being in abundance and randomly positioned around the circle). After the first nick the DNA loses its supercoiled structure; after many nicks it breaks to become topologically linear; further nicks lead to fragmentation of this linear form. Formulae are given for the proportions of DNA molecules in each of the four classes: supercoiled; nicked but still circular; linear; fragmented. Formulae are also presented for the case when there is, in addition to nicking, simultaneous action of an endonuclease which produces direct double-stranded breaks in the DNA. Finally, a general theory is given for the case where a third type of enzyme, topoisomerase I, is operative, with all three DNA modifications taking place simultaneously.     

Arabinosylcytosine-induced accumulation of DNA nicks in myotube nuclei detected by in situ nick translation

This laboratory has recently reported the occurrence of DNA nicking at the onset of terminal skeletal myogenesis by using the technique of in situ nick translation (Dawson and Lough: Dev. Biol., 127:362-367, 1988). Because 1-beta-D-arabinofuranosylcytosine (araC), a cytocidal agent that is routinely used to removed dividing fibroblasts from myogenic cultures, inhibits DNA repair, it was of interest to determine whether araC treatment resulted in an accumulation of the endogenously created nicks. Thus, we have assessed the accumulation of DNA nicks in myotube cells during a 20 hour araC treatment period at the onset of terminal myogenesis (44-64 hours in vitro) by using three techniques: alkaline sucrose gradient density centrifugation, kinetic in situ nick translation, and cellular in situ nick translation. Although alkaline sucrose gradient centrifugation revealed no detectable nicking after 20 hours, kinetic in situ nick translation analysis revealed subtle but significant increases in DNA nicks caused by araC within 7 hours of drug application, and a 1.5-fold increase in DNA repair sites after 20 hours of drug treatment. That these observations reflected nicking specifically in myotube nuclei was determined by immunocytochemical localization of nicked sites after repair with a biotinylated nucleotide analog (biotin-11-dUTP). The effects of araC were only incompletely reversible, whether or not the drug was removed from the cultures, within 2 days of the treatment period.(ABSTRACT TRUNCATED AT 250 WORDS)     

Enrichment and depletion of Hela topoisomerase I recognition sites among specific types of DNA elements.

The SDS-induced nicking of DNA helix by Hela topoisomerase I in vitro has been studied by using 2.9 kb of cloned human DNA as the substrate. The frequency of nicking is increased from 1/23 (nick/nt) to 1/19 (nick/nt) when camptothecin is present in the nicking reaction. The cytotoxic drug also induces DNA nicks without the addition of SDS. Although the consensus built from DNA sequences from -20 to +20 of more than one hundred of the nicking sites only shows a preference for T at position -1, the distributions of the topoisomerae I-cleavable sites among different categories of specific DNA sequences are apparently non- random. Long stretches of tandem (CA), A, or T residues, and the GC-rich promoter region of alpha 1 globin gene are all refractory to the nicking reaction. However, the nicking frequencies of short direct repeats flanking different Alu type sequences are as high as 1/6 (nick/nt). Finally, several tandemly arranged minirepeats of the form (TxAy)z, that are usually found at the 3' ends of the primate Alu family or Kpnl family repeats, can be cleaved efficiently in a regular pattern by the enzyme. These data are discussed in terms of the mode of recognition of DNA sequences/structures by topoisomerase I, and its possible roles in the nonhomologous insertion of repetitive DNA sequences.     

The actions of Neurospora endo-exonuclease on double strand DNAs

Neurospora crassa endo-exonuclease, an enzyme implicated in recombinational DNA repair, was found previously to have a distributive endonuclease activity with a high specificity for single strand DNA and a highly processive exonuclease activity. The activities of endo-exonuclease on double strand DNA substrates have been further explored. Endo-exonuclease was shown to have a low bona fide endonuclease activity with completely relaxed covalently closed circular DNA and made site-specific breaks in linear double strand DNA at a low frequency while simultaneously generating a relatively high level of single strand breaks (nicks) in the DNA. Sequencing at nicks induced by endo-exonuclease in pBR322 restriction fragments showed that the highest frequency of nicking occurred at the mid-points of two sites with the common sequence, p-AGCACT-OH. In addition, sequencing revealed less frequent nicking at identical or homologous hexanucleotide sequences in all other 54 cases examined where these sequences either straddled the break site itself or were within a few nucleotides on either side of the break site. The exonucleolytic action of endo-exonuclease on linear DNA showed about 100-fold preference for acting in the 5' to 3' direction. Removal of the 5'-terminal phosphates substantially reduced this activity, internal nicking, and the ability of endo-exonuclease to generate site-specific double strand breaks. On the other hand, nicking of the dephosphorylated double strand DNA with pancreatic DNase I stimulated the exonuclease activity by almost 5-fold, but no stimulation was observed when the DNA was nicked by Micrococcal nuclease. Thus, 5'-p termini either at double strand ends or at nicks in double strand DNA are entry points to the duplex from which endo-exonuclease diffuses linearly or "tracks" in the 5' to 3' direction to initiate its major endo- and exonucleolytic actions. The results are interpreted to show how it is possible for endo-exonuclease to generate single strand DNA for switching into a homologous duplex either at a nick or while remaining bound at a double strand break in the DNA. Such mechanisms are consistent with current models for recombinational double strand break repair in eukaryotes.     

DNA folding in the nucleosome

Digestion of chromatin with a number of nucleases shows that the DNA is regularly folded in the nucleosome. Particularly cleavage by pancreatic DNase (DNase I) in the 140 base-pair nucleosome has been examined. This nuclease nicks the DNA every ten bases on each strand as demonstrated by labeling the 5′-ends of the 140 base-pair nucleosome. Cleavage sites on opposite strands are staggered by two bases. This proves that the DNA is arranged on the outside of the histone core in a regular way. The probability distribution of nicking might indicate a 2-fold symmetry of the 140 base-pair nucleosome. In particular it is shown that the predominant band of 80 bases is derived from several regions within the 140 base-pairs and suggested to reflect the pitch of the DNA superhelix surrounding the histone core of the nucleosome. Its possible significance with respect to chromatin structure is discussed.     

Directly labeled DNA probes using fluorescent nucleotides with different length linkers.

Directly labeled fluorescent DNA probes have been made by nick translation and PCR using dUTP attached to the fluorescent label, Cy3, with different length linkers. With preparation of probes by PCR we find that linker length affects the efficiency of incorporation of Cy3-dUTP, the yield of labeled probe, and the signal intensity of labeled probes hybridized to chromosome target sequences. For nick translation and PCR, both the level of incorporation and the hybridization fluorescence signal increased in parallel when the length of the linker arm is increased. Under optimal conditions, PCR yielded more densely labeled probes, however, the yield of PCR labeled probe decreased with greater linear density of labeling. By using a Cy3-modified dUTP with the longest linker under optimal conditions it was possible to label up to 28% of the possible substitution sites on the target DNA with reasonable yield by PCR and 18% by nick translation. A mechanism involving steric interactions between the polymerase, cyanine-labeled sites on template and extending chains and the modified dUTP substrate is proposed to explain the inverse correlation between the labeling efficiency and the yield of DNA probe synthesis by PCR.     

Localization of DNase I-hypersensitive regions during rat spermatogenesis: stage-dependent patterns and unique sensitivity of elongating spermatids.

DNase I-hypersensitivity of rat spermatogenic cells was analyzed 1) to establish overall patterns of hypersensitivity in individual cell types, 2) to correlate these patterns with known changes in chromatin organization and function, and 3) to provide a foundation for further analyses examining DNase I-hypersensitivity and the localization of specific genes during spermatogenesis. Parameters for in situ nick translation, using radioactive and fluorescent probes to visualize DNase I-hypersensitive regions (DHR), were established for fixed and sectioned testicular preparations, permeabilized cells, and isolated germ cell nuclei. As anticipated, the pattern of DHR changed in a cell-type specific manner during the course of spermatogenesis, reflective of known stage-dependent alterations in the composition and structure of both the chromatin and the nuclear lamina/matrix as well as changes in gene expression. DHR in preleptotene spermatocytes were primarily peripheral, while in pachytene spermatocytes they were localized along the condensed chromosomes. The pattern of DHR changed from "checkerboard" in steps 7-8 round spermatid nuclei to "lamellar" in steps 10-11 elongating spermatids. In steps 12-13 elongating spermatids. DHR were localized throughout the nuclei or in a graded manner--increasing from anterior to posterior and mirroring the pattern of chromatin condensation. However, unlike the case in other stages, DNA of steps 12-13 elongating spermatids was exquisitely sensitive to nick translation even in the absence of exogenous DNase I. In contrast to the labeling of earlier stages, steps 16-19 spermatids and mature spermatozoa did not demonstrate DNase I-hypersensitivity under any conditions employed. A variety of agents that interact with topoisomerase II and DNA (teniposide, novobiocin, ethidium bromide, and adenosine triphosphate) were tested to determine the basis for the unique sensitivity to nick translation of steps 12-13 elongating spermatids. None of the agents tested, however, affected this unique labeling. The sensitivity of steps 12-13 elongating spermatids to nick translation in the absence of exogenous nuclease indicators the presence of endogenous nicks, which may relieve torsional stress and aid rearrangement as the chromatin is packaged into a form characteristic of the mature spermatozoon.     

Mapping of eukaryotic DNA topoisomerase I catalyzed cleavage without concomitant religation in the vicinity of DNA structural anomalies

Sensitive sites for covalent trapping of eukaryotic topoisomerase I at DNA structural anomalies were mapped by a new method using purified enzyme and defined DNA substrates. To insure that the obtained topoisomerase I trapping patterns were not influenced by DNA sequence variations, a single DNA imperfection was placed centrally within a homonucleotide track. Mapping of topoisomerase I-mediated irreversible cleavage sites on homopolymeric DNA substrates containing mismatches showed trapping of the enzyme in several positions in close vicinity of the DNA imperfection, with a strong preference for the 5' junction between the duplex DNA and the base-pairing anomaly. On homopolymeric DNA substrates containing a nick, sites of topoisomerase I-mediated cleavage on the intact strand were located just opposite to the nick and from one to ten nucleotides 5' to the nick. Sites of enzyme-mediated cleavage next to a nick and an immobile single-stranded branch were located 5' to the strand interruption in distances of two to six nucleotides and two to ten nucleotides, respectively. Taken together these findings suggest that covalent trapping of topoisomerase I proceeds at positions adjacent to mismatches, nicks and single-stranded branches, where the cleavage reaction is allowed and the ensuing ligation reaction prevented. In principle, the developed interference method might be of general utility to define topoisomerase-DNA interactions relative to different types of structural anomalies.     

Sensitive fluorescence in situ hybridization signal detection in maize using directly labeled probes produced by high concentration DNA polymerase nick translation.

The signal produced by fluorescence in situ hybridization (FISH) often is inconsistent among cells and sensitivity is low. Small DNA targets on the chromatin are difficult to detect. We report here an improved nick translation procedure for Texas red and Alexa Fluor 488 direct labeling of FISH probes. Brighter probes can be obtained by adding excess DNA polymerase I. Using such probes, a 30 kb yeast transgene, and the rp1, rp3 and zein multigene clusters were clearly detected.     

Characterization of the reaction product of the oriT nicking reaction catalyzed by Escherichia coli DNA helicase I.

DNA helicase I, encoded on the Escherichia coli F plasmid, catalyzes a site- and strand-specific nicking reaction within the F plasmid origin of transfer (oriT) to initiate conjugative DNA strand transfer. The product of the nicking reaction contains a single phosphodiester bond interruption as determined by single-nucleotide resolution mapping of both sides of the nick site. This analysis has demonstrated that the nick is located at precisely the same site previously shown to be nicked in vivo (T. L. Thompson, M. B. Centola, and R. C. Deonier, J. Mol. Biol. 207:505-512, 1989). In addition, studies with two oriT point mutants have confirmed the specificity of the in vitro reaction. Characterization of the nicked DNA product has revealed a modified 5' end and a 3' OH available for extension by E. coli DNA polymerase I. Precipitation of nicked DNA with cold KCl in the presence of sodium dodecyl sulfate suggests the existence of protein covalently attached to the nicked DNA molecule. The covalent nature of this interaction has been directly demonstrated by transfer of radiolabeled phosphate from DNA to protein. On the basis of these results, we propose that helicase I becomes covalently bound to the 5' end of the nicked DNA strand as part of the reaction mechanism for phosphodiester bond cleavage. A model is presented to suggest how helicase I could nick the F plasmid at oriT and subsequently unwind the duplex DNA to provide single-stranded DNA for strand transfer during bacterial conjugation.     

Transient generation of displaced single-stranded DNA during nick translation

We show that displaced single-stranded overhangs are transiently generated and destroyed during nick translation by E. coli DNA polymerase I. Evidence that hyper-rec mutants have an increased frequency of such overhang structures is discussed. The transient generation of overhangs may be significant for general recombination. The 5' leads to 3' exonuclease activity of polymerase I specifically hydrolyzes such overhangs to yield a nick. Overhangs are generated by polymerization, but after every polymerization step, either polymerase or exonuclease can act--55% of the time, polymerization occurred first. At this frequency overhangs of greater than or equal to 12 nucleotides are generated every 1300 nucleotides polymerized. We suggest that many DNA strand discontinuities are displaced single-stranded overhangs, rather than gaps or simple nicks.     

Excision repair and DNA synthesis with a combination of HeLa DNA polymerase beta and DNase V

The ability of HeLa DNA polymerases to carry out DNA synthesis from incisions made by various endodeoxyribonucleases which recognize or form baseless sites in DNA was examined. DNA polymerase beta carried out limited strand displacement synthesis from 3'-hydroxyl nucleotide termini made by HeLa apurinic/apyrimidinic (AP) endonuclease II at the 5'-side of apurinic sites. Escherichia coli endonuclease III incises at the 3'-side of apurinic sites to produce nicks with 3'-deoxyribose termini which did not efficiently support DNA synthesis with beta-polymerase. However, these nicks could be activated to support limited DNA synthesis by HeLa AP endonuclease II, an enzyme which removes the baseless sugar phosphate from the 3'-termini, thus creating a one-nucleotide gap. With dGTP as the only nucleoside triphosphate present, the beta-polymerase catalyzed one-nucleotide DNA repair synthesis from those gaps which lacked dGMP. In contrast, HeLa DNA polymerase alpha was unreactive with all of the above incised DNA substrates. Larger patches of DNA synthesis were produced by nick translation from one-nucleotide gaps with HeLa DNA polymerase beta and HeLa DNase V. Moreover, incisions made by E. coli endonuclease III were activated to support DNA synthesis by the DNase V which removed the 3'-deoxyribose termini. HeLa DNase V also stimulated both the rate and extent of DNA synthesis by DNA polymerase beta from AP endonuclease II incisions. In this case the baseless sugar phosphate was removed from the 5'-termini, and nick translational synthesis occurred. Complete DNA excision repair of pyrimidine dimers was achieved with the beta-polymerase, DNase V, and DNA ligase from incisions made in UV-irradiated DNA by T4 UV endonuclease and HeLa AP endonuclease II. Such incisions produce a one-nucleotide gap containing 3'-hydroxyl nucleotide and 5'-thymine: thymidylate cyclobutane dimer termini. DNase V removes pyrimidine dimers primarily as a dinucleotide and then promotes nick translational DNA synthesis.     

Random DNA fragmentation with endonuclease V: application to DNA shuffling

The enzyme endonuclease V nicks uracil-containing DNA at the second or third phosphodiester bond 3′ to uracil sites. I applied the enzyme to random fragmentation of DNA to revise the complex DNA shuffling protocol. The merit of using endonuclease V is that cleavage occurs at random sites and the length of the fragments can easily be adjusted by varying the concentration of dUTP in the polymerase chain reaction. Unlike the conventional method using DNase I, no partial digestion or gel separation of fragments is required. Therefore, labor is dramatically reduced and reproducibility ensured. I applied this method to recombine two truncated green fluorescent protein (GFP) genes and demonstrated successful DNA shuffling by the appearance of the fluorescent full-length GFP genes.     

Gamma rays and bleomycin nick DNA and reverse the DNase I sensitivity of beta-globin gene chromatin in vivo.

The active beta-globin genes in chicken erythrocytes, like all active genes, reside in large chromatin domains which are preferentially sensitive to digestion by DNase I. We have recently proposed that the special structure of chromatin in active domains is maintained by torsional stress in the DNA (Villeponteau et al., Cell 39:469-478, 1984). This hypothesis predicts that nicking of the DNA within any such chromosomal domain in vivo will relax the DNA and lead to loss of the special DNase I-sensitive state. Here we have tested this prediction by using gamma irradiation and bleomycin treatment to cleave DNA within intact chicken embryo erythrocytes. Both treatments cause reversal of DNase I sensitivity. Moreover, reversal occurs at approximately one nick per 150 kilobase pairs for both agents despite their entirely unrelated modes of cell penetration and DNA attack. These results suggest that the domain of DNase I sensitivity surrounding the beta-globin genes comprises 150 kilobase pairs of chromatin under torsional stress and that a single DNA nick in this region is sufficient to reverse the DNase I sensitivity throughout the entire domain.     

Translocation of nicked but not gapped DNA by the packaging motor of bacteriophage phi29

The biomolecular mechanism that the double-stranded DNA viruses employ to insert and package their genomic DNA into a preformed procapsid is still elusive. To better characterize this process, we investigated packaging of bacteriophage phi29 DNA with structural alterations. phi29 DNA was modified in vitro by nicking at random sites with DNase I, or at specific sites with nicking enzyme N.BbvC IA. Single-strand gaps were created by expanding site-specific nicks with T4 DNA polymerase. Packaging of modified phi29 DNA was studied in a completely defined in vitro system. Nicked DNA was packaged at full genome length and with the same efficiency as untreated DNA. Nicks were not repaired during packaging. Gapped DNA was packaged only as a fragment corresponding to the DNA between the genome terminus and gap. Thus the phi29 DNA packaging machinery tolerated nicks, but stopped at gaps. The packaging motor did not require a nick-free DNA backbone, but the presence of both DNA strands, for uninterrupted packaging.     

Sperm decondensation during fertilisation in the mouse: presence of DNase I hypersensitive sites in situ and a putative role for topoisomerase II

In this study our aim was to characterise the presence and the role of DNA alterations during sperm decondensation in the mouse. To visualise the changes during decondensation we investigated for the presence of DNase I hypersensitive sites in situ and for a putative role for topoisomerase II by examining the effect of teniposide, a topoisomerase II inhibitor, during fertilisation. In situ nick translation without the previous addition of DNase I failed to reveal the presence of endogenous nicks in decondensing sperm and pronuclei whereas preincubation of fixed oocytes with DNase I indicated that decondensing sperm were sensitive to this enzyme. Addition of 100 microM teniposide did not completely inhibit pronuclei formation but its addition to the fertilisation medium did lead to the presence of endogenous DNA nicks in decondensing sperm. These observations suggest that DNase I hypersensitivity during sperm decondensation is related to the dramatic conformational changes that the chromatin undergoes during the decondensation process, in which topoisomerase II may be implicated.     

Sensitive fluorescence in situ hybridization signal detection in maize using directly labeled probes produced by high concentration DNA polymerase nick translation

The signal produced by fluorescence in situ hybridization (FISH) often is inconsistent among cells and sensitivity is low. Small DNA targets on the chromatin are difficult to detect. We report here an improved nick translation procedure for Texas red and Alexa Fluor 488 direct labeling of FISH probes. Brighter probes can be obtained by adding excess DNA polymerase I. Using such probes, a 30 kb yeast transgene, and the rp1, rp3 and zein multigene clusters were clearly detected.