The sequence specificity of bleomycin damage in three cloned DNA sequences that differ by a small number of base substitutions

The DNA sequence specificity of the cancer chemotherapeutic agent, bleomycin, has been investigated in three clones of human alpha RI-DNA. The three 340-base pair alpha RI-DNA sequences were almost identical in their nucleotide sequence enabling the study of subtle effects of base substitutions on bleomycin cleavage. By utilizing densitometer scanning and statistical analysis of the degree of bleomycin DNA cleavage, we found 17 significant differences between the three DNA sequences. Eleven of these differences could be attributed to base substitutions close to the dinucleotide cleavage site. However, six of the differences were at positions two or more base pairs from the base substitution sites. The significant differences were up to 12 base pairs from base substitutions. It is proposed that these long range effects are due to base substitutions causing microvariation in the DNA structure to which bleomycin cleavage is sensitive.     

The genome-wide DNA sequence specificity of the anti-tumour drug bleomycin in human cells

The cancer chemotherapeutic agent, bleomycin, cleaves DNA at specific sites. For the first time, the genome-wide DNA sequence specificity of bleomycin breakage was determined in human cells. Utilising Illumina next-generation DNA sequencing techniques, over 200 million bleomycin cleavage sites were examined to elucidate the bleomycin genome-wide DNA selectivity. The genome-wide bleomycin cleavage data were analysed by four different methods to determine the cellular DNA sequence specificity of bleomycin strand breakage. For the most highly cleaved DNA sequences, the preferred site of bleomycin breakage was at 5′-GT* dinucleotide sequences (where the asterisk indicates the bleomycin cleavage site), with lesser cleavage at 5′-GC* dinucleotides. This investigation also determined longer bleomycin cleavage sequences, with preferred cleavage at 5′-GT*A and 5′- TGT* trinucleotide sequences, and 5′-TGT*A tetranucleotides. For cellular DNA, the hexanucleotide DNA sequence 5′-RTGT*AY (where R is a purine and Y is a pyrimidine) was the most highly cleaved DNA sequence. It was striking that alternating purine–pyrimidine sequences were highly cleaved by bleomycin. The highest intensity cleavage sites in cellular and purified DNA were very similar although there were some minor differences. Statistical nucleotide frequency analysis indicated a G nucleotide was present at the ?3 position (relative to the cleavage site) in cellular DNA but was absent in purified DNA.     

Ultraviolet light-induced cleavage of DNA in the presence of iodoHoechst 33258: the sequence specificity of the reaction.

IodoHoechst 33258 sensitizes DNA to cleavage by near ultraviolet light (UV-A). Following an earlier study which showed that the UV-induced cleavage is at discrete locations corresponding to the ligand binding sites, this paper reports a more extensive analysis of the sequence specificity of cleavage. The experiments involved use of double-stranded DNA synthesised on primed M13 templates. Analysis of cleavage in a 280bp sequence in M13mp18 and a 310bp sequence in three M13mp9 clones ('alpha-32', 'alpha-82' and 'alpha-22') derived from human alpha-DNA, showed that for all of the twenty-nine strong and very strong damage sites, cleavage was at the 3' end of a run of three or more consecutive AT base pairs. The extent of cleavage was higher for sites with consecutive Ts than for consecutive As, and greatest for the sequence cTTTTca. Comparison of three closely-related alpha-DNA clones enabled assessment of single bp changes and essentially confirmed the results of detailed analysis of binding cleavage sites in mp18 and alpha-32. Decreasing the input ratio of iodoHoechst/per bp DNA from 0.13 to 0.013 altered the sequence specificity, and sites possessing only three consecutive AT bps were generally not cleaved. The contributions of both the strength of ligand binding and the efficiency of photolytic cleavage to the overall extent of cleavage by UV/iodoHoechst are discussed, in view of the potential utility of the ligand as a probe of DNA conformation.     

The determination of the DNA sequence specificity of bleomycin-induced abasic sites

The DNA sequence specificity of the cancer chemotherapeutic agent, bleomycin, was determined with high precision in purified plasmid DNA using an improved technique. This improved technique involved the labelling of the 5′- and 3′-ends of DNA with different fluorescent tags, followed by simultaneous cleavage by bleomycin and capillary electrophoresis with laser-induced fluorescence. This permitted the determination of bleomycin cleavage specificity with high accuracy since end-label bias was greatly reduced. Bleomycin produces single- and double-strand breaks, abasic sites and other base damage in DNA. This high-precision method was utilised to elucidate, for the first time, the DNA sequence specificity of bleomycin-induced DNA damage at abasic sites. This was accomplished using endonuclease IV that cleaves DNA at abasic sites after bleomycin damage. It was found that bleomycin-induced abasic sites formed at 5′-GC and 5′-GT sites while bleomycin-induced phosphodiester strand breaks formed mainly at 5′-GT dinucleotides. Since bleomycin-induced abasic sites are produced in the absence of molecular oxygen, this difference in DNA sequence specificity could be important in hypoxic tumour cells.     

The DNA sequence specificity of bleomycin cleavage in telomeric sequences in human cells

Bleomycin is an antibiotic drug that is widely used in cancer chemotherapy. Telomeres are located at the ends of chromosomes and comprise the tandemly repeated DNA sequence (GGGTTA) _n in humans. Since bleomycin cleaves DNA at 5??-GT dinucleotide sequences, telomeres are expected to be a major target for bleomycin cleavage. In this work, we determined the DNA sequence specificity of bleomycin cleavage in telomeric sequences in human cells. This was accomplished using a linear amplification procedure, a fluorescently labelled oligonucleotide primer and capillary gel electrophoresis with laser-induced fluorescence detection. This represents the first occasion that the DNA sequence specificity of bleomycin cleavage in telomeric DNA sequences in human cells has been reported. The bleomycin DNA sequence selectivity was mainly at 5??-GT dinucleotides, with lesser amounts at 5??-GG dinucleotides. The cellular bleomycin telomeric DNA damage was also compared with bleomycin telomeric damage in purified human genomic DNA and was found to be very similar. The implications of these results for the understanding of bleomycin??s mechanism of action in human cells are discussed.     

Differences between sites of binding to DNA and strand cleavage for complexes of bleomycin with iron or cobalt

The sequence specificity of bleomycin A5 and of its light-activated cobalt complex were compared by examining the relative cleavage of each strand of two DNA fragments by either species. Significant differences between the two metallobleomycins were observed. The iron-bleomycin (Fe-BLM) complex cleaved the DNA molecules preferentially at dinucleotides GpT and GpC, whereas the light-activated cobalt-bleomycin complex (Co-BLM) showed a preference for cutting at the dinucleotide GpA in addition to cleavage at every GpT dinucleotide. Further, new sites of preferential cleavage were noted for Co-BLM in regions of the DNA where enhanced reaction with DNAaseI can be observed in the presence of the antibiotic. No differences in the cutting behaviour of the Fe-BLM were evident upon irradiation of the reaction mixture. A reduction in the relative efficiency of cutting at GpC sequences by Co-BLM is responsible for the previously observed diminution of double-strand breaks under conditions of photoactivated cleavage. The results are discussed in terms of the likely production of highly reactive, diffusible cutting elements in the light activated reaction which cause cleavage of the DNA in regions where the antibiotic is not bound.     

Human telomeric DNA sequences are a major target for the antitumour drug bleomycin

The DNA sequence specificity of the cancer chemotherapeutic agent bleomycin was examined in a human telomeric DNA sequence and compared with that of non-telomeric sequences. The target DNA sequence contained 17 repeats of the human telomeric sequence and other primary sites of bleomycin cleavage. The 377-base-pair target DNA was fluorescently labelled at the 3′-end, damaged with bleomycin and electrophoresed in an ABI 3730 automated capillary sequencer to determine the intensity and sequence specificity of bleomycin damage. The results revealed that bleomycin cleaved primarily at 5′-GT in the telomeric sequence 5′-GGGTTA. Maxam–Gilbert chemical sequencing reactions were utilised as DNA size markers to determine the precise sites of bleomycin cleavage. The telomeric region contained strong sites of bleomycin cleavage and constituted 57% of the 30 most intense bleomycin damage sites in the DNA sequence examined. These data indicated that telomeric DNA sequences are a major site for bleomycin damage.     

Sequence specificity of 125I-labelled Hoechst 33258 damage in six closely related DNA sequences

The sequence selectivity of [125I]Hoechst 33258 in six 340 base-pair DNA sequences has been investigated. [125I]Hoechst 33258, which is a bis-benzimidazole and binds to the minor groove of B-DNA, preferentially binds to A + T-rich regions of DNA. Six out of nine strong binding sites contained four or more consecutive A.T base-pairs, while the other three strong binding sites were AAGGATT, TATAGAAA (the peak of damage was in the run of 3 A residues) and AAA. One of the six weak binding sites had five consecutive A.T base-pairs, two of the weak binding sites had three, and three did not have any. In addition to genomic 340 base-pair alpha RI-DNA (which is a tandem repeat in human cells), five 340 base-pair alpha RI-DNA clones were generated that differed from the genomic "consensus" sequence by a number of random base alterations. The effect of these base changes on the sequence specificity of [125I]Hoechst 33258 damage indicated that of the base changes that interrupted 14 binding sites, six decreased and eight did not change the extent of damage, while two sites changed position. Of the base alterations that augmented 17 binding sites, five increased, two decreased and ten did not alter the degree of cleavage, while ten sites changed position. It was concluded from the data that, while runs of consecutive A.T base-pairs was the most important parameter that determines [125I]Hoechst 33258 binding, other factors including position in the DNA sequence, nearest neighbour and long-range interactions were also important.     

A protein binds to a satellite DNA repeat at three specific sites that would be brought into mutual proximity by DNA folding in the nucleosome

Using a generally applicable assay for specific DNA-binding proteins in crude extracts, we have detected and purified an HMG-like nuclear protein from African green monkey cells that preferentially binds to the 172 bp repeat of alpha-satellite DNA (alpha-DNA). DNAase I footprinting with the purified protein detects three specific binding sites (I-III) per alpha-DNA repeat. Site II is 145 bp (one core nucleosome length) from site III on the adjacent alpha-DNA repeat, while site I lies midway between sites II and III. In the alpha-nucleosome phasing frame corresponding with this arrangement, sites I-III would be brought into mutual proximity by DNA folding in the nucleosome. This phasing frame is identical with the preferred frame detected previously in isolated chromatin. Our results suggest that this new and abundant protein recognizes a family of short, related nucleotide sequences found not only in alpha-DNA but also throughout the genome, and that functions of this protein are mediated through its nucleosome-positioning activity. Such nucleosome-positioning proteins may underlie the sequence specificity of both nucleosome arrangements and higher order chromatin structures.     

Strand scission of deoxyribonucleic acid by neocarzinostatin, auromomycin, and bleomycin: studies on base release and nucleotide sequence specificity

The nucleotide sequence specificity of neocarzinostatin (NCS), auromomycin (AUR), bleomycin (Blm), phleomycin (Phlm), and tallysomycin (Tlm) has been determined by using these antibiotics and their associated chromophores to create strand scissions in end-labeled restriction fragments of DNA and then determining the base sequence of the oligonucleotides formed. NCS and the NCS chromophore induce similar patterns of cleavage in DNA fragments labeled at the 5' terminus. The pattern produced by the AUR chromophore also resembles that of its holoantibiotic. Dithiothreitol enhances the rate of cleavage of DNA by the AUR chromophore but does not alter the sequence specificity. The results suggest that the polypeptide component of AUR and NCS serves primarily as a carrier for the chromophore. When tested with a fragment labeled at the 3' terminus, the products of NCS and AUR cleavage do not display the patterns of chemically produced oligonucleotides cleaved at phosphodiester bonds, suggesting that the 5' terminus is modified by a sugar fragment. NCS primarily attacks thymine (75% of the total bases attacked) and, to a lesser extent, adenine (19%) and cytosine (6%). AUR preferentially attacks guanine (67% of total bases), while attacking less often thymine (24%) and adenine (9%). Bleomycin and its analogues preferentially cleave purine--pyrimidine (5' leads to 3') and pyrimidine--pyrimidine (3' leads to 5') sequences. All (5' leads to 3') GT and GC sequences were cleaved. Phlm G and Phlm-Pep are less active than bleomycin toward purines while Tlm was more active. The patterns of cleavage produced by Blm A2 and Blm B6 are similar, while those produced by Phlm-Pep, Phlm G, Blm-B1', and Blm-Pep resemble one another. The cleavage pattern of Tlm shows quantitative differences from the other analogues tested. Differences between bleomycin and its analogues may be related to structural differences in these molecules.     

Quantitative and qualitative analysis of amplified DNA sequences by a competitive hybridization assay.

The presence of allelic sequence variations in DNA fragments can be easily detected by measuring the extent of DNA strand exchange between test double-stranded PCR products (target) and labeled standard double-stranded PCR products (probe). Under selected hybridization conditions, sequences identical to the probe decreased the formation of double-labeled hybrid, whereas differing sequences were not efficient enough to compete with the regeneration of the probe. A single base substitution in the target DNA increased the percentage of remaining double-labeled probe. A general procedure involving denaturation and hybridization in solution under different temperature conditions or using different probes enabled sequence identification. The degree of regeneration of double-labeled probe was determined using a bioluminescent assay. We evaluated the specificity of this method with two probes (108 and 131 bp) and several targets with different base substitutions.     

Detection of heavy methylation in human repetitive DNA subsets by a monoclonal antibody against 5-methylcytosine

A monoclonal antibody (IgM) against 5-methylcytosine (mC) was isolated and characterized. It showed a high specificity for mC with a cross-reactivity of less than 1% with cytosine and 0.1% with thymidine. An improved immunohybridization method, originally developed with polyclonal antibodies (Sano et al. (1980) Proc. Natl. Acad. Sci. USA 77, 3581), was applied to detect mC in immobilized DNA using the new monoclonal preparation. Human genomic DNA was cleaved with the restriction enzyme EcoRI and successively fractionated by malachite-green affinity chromatography and agarose gel electrophoresis. The fractionated DNA was transferred to nitrocellulose paper and treated with the anti-mC monoclonal antibody. Heavy methylation was observed in EcoRI-ladders of repetitive sequences of 1360, 1750, 2200 and 3400 bp, while 340, 660 and 2700 bp fragments were less methylated. The results show that methylation occurs in limited subsets of satellite II and III repetitive DNAs that contain high amounts of methylatable CpG dinucleotides, or CpG clusters.     

The use of Taq DNA polymerase to determine the sequence specificity of DNA damage caused by cis-diamminedichloroplatinum(II), acridine-tethered platinum(II) diammine complexes or two analogues.

cis-Diamminedichloroplatinum(II) (cisplatin) forms adducts with DNA. The sequence specificity of formation of cisplatin adducts with plasmid DNA was investigated using Taq DNA polymerase. This procedure involved the extension of an oligonucleotide primer by Taq DNA polymerase up to the cisplatin adduct. Using thermal cycling, this process is repeated many times in order to amplify the signal. The products of this linear amplification can then be examined on DNA sequencing gels, and the sequence specificity of cisplatin adduct formation can be determined to the exact base pair. In the pUC8 plasmid, the sequences that produced the most intense damage sites (as determined by densitometry) were runs of two or more Gs. Adducts could also be detected at GA, AG, and GC dinucleotides. Four other cisplatin analogues were also tested in the system. Two of these analogues contained an attached intercalating chromophore, and the strong damage with these compounds was similar to that found for cisplatin, but the medium and weak damage tended to be different. Weak damage was also detected with trans-diamminedichloroplatinum(II). With this compound, a large number of the damage sites were at the CG dinucleotide. This technique represents a simple, accurate, and quick method for determining the sequence specificity of damage for a cisplatin analogue in any DNA sequence.     

Studies of the topoisomerase II-mediated cleavage and religation reactions by use of a suicidal double-stranded DNA substrate.

The cleavage and religation reactions of eukaryotic topoisomerase II were studied by use of a 5'-recessed DNA substrate containing a strong recognition sequence for the enzyme. Cleavage of the DNA substrate was suicidal, that is the enzyme was unable to religate the cleaved DNA due to a release of DNA 5' to the cleavage position. With this substrate cleavage products accumulated with time in the absence of protein-denaturing agents, and the cleavage reaction was not reversible with salt. The suicide cleavage complexes contained a kinetically competent topoisomerase II enzyme as determined by the enzyme's ability to perform intermolecular ligation of the cleaved DNA to a free 3'-hydroxyl end on another DNA strand. The efficiency of the religation reaction depended on the ability of the religation substrate to base pair to the DNA in the cleaved enzyme-DNA complex. Higher levels of religation were obtained with dinucleotides than with long DNA substrates. Mononucleotides also were efficiently religated, indicating an ability of the enzyme to mediate religation without making contacts to a long stretch of nucleotides 5' to the cleavage position.     

A role for the metal binding domain in determining the DNA sequence selectivity of Fe-bleomycin.

Previous studies of Fe-bleomycin-mediated DNA cleavage have established that the bithiazole moiety + C-terminal substituent of bleomycin are required for DNA binding, while the metal binding domain is responsible for O2 activation. Although recent studies have indicated that the metal binding domain also participates in DNA unwinding, and in determining the sequence and strand selectivity of DNA cleavage, no study has defined the structural domain that bears primary responsibility for the observed pattern of bleomycin-mediated DNA degradation. Presently, by the use of four synthetic analogs of bleomycin demethyl A2 having the functional domains connected by rigid spacers of varying lengths, the source of DNA cleavage specificity has been determined. When the four analogs cleaved 242- and 127-base pair 5'-32P-end-labeled DNA restriction fragments containing isolated Fe-bleomycin cleavage sites, all four produced cleavage at the same preferred sites. Because the (oligo)glycine spacers altered the distance between the domains by as much as 14 A, the identical cleavage patterns argue that the primary determinant of sequence specificity for these analogs is the metal binding domain.     

Effects of hypoxanthine substitution on bleomycin-mediated DNA strand degradation in DNA-RNA hybrids.

We have reported on the differences in site-specific cleavage between DNA and DNA-RNA hybrids by various prototypic DNA cleavers (accompanying paper). In the case of bleomycin (BLM), degradation at 5'-GC-3'sites was suppressed relative to the same sequence in double-stranded DNA, while 5'-GT-3' damage remained constant. We now present results of our further investigation on the chemical and conformational factors that contribute to BLM-mediated DNA strand cleavage of DNA-RNA hybrids. Substitution of guanine by hypoxanthine on the RNA strand of hybrids resulted in a significant enhancement of 5'-GC-3' site damage on the DNA strand relative to double-stranded DNA, thus reversing the suppression noted at these sites. Additionally, 5'-AT-3' sites, which are damaged significantly more in the hybrid than in DNA, exhibit decreased product formation when hypoxanthine is present on the RNA strand of hybrids. However, when hypoxanthine is substituted for guanine on the DNA strand (a GC cleavage site becomes IC), 5'-IT-3' and 5'-IC-3' site cleavage is almost completely suppressed, whereas AT site cleavage is dramatically enhanced. The priority in metallobleomycin site-specific cleavage of hybrids changes with hypoxanthine substitution: the cleavage priority is AT > GT > GC in native hybrid; GC > GT > AT in hybrids substituted with hypoxanthine in the RNA strand; AT >> GT approximately GC in hybrids substituted with hypoxanthine in the DNA strand. The results of kinetic isotope effect studies on BLM cleavage are presented and, in most cases, the values are larger for the hypoxanthine-substituted hybrid. The results suggest that the 2-amino groups of guanine residues on both strands of the nucleic acid play an important role in modulation of the binding and cleavage specificity of BLM.     

Sequence heterogeneity of the human alphoid satellite DNA and thermal stability of mismatched alphoid DNA duplexes

1. 340 bp (dimer) and 680 bp (tetramer) fractions of the human alphoid satellite DNA (h alpha RI DNA) were isolated after complete cleavage of total human DNA with EcoR I and cloned in pBR 32.5. 2. Ten clones containing 340 bp inserts and one clone containing 680 bp insert were sequenced in order to investigate the sequence heterogeneity of this satellite DNA and the sequence data were compared with the consensus h alpha RI DNA sequence of Wu and Manuelidis (1980). 3. It was shown that in all clones studied the mutations are nonrandomly distributed along the human alphoid monomers forming distinct conservative and variable regions. 4. This mutation distribution pattern was compared with the nucleotide variations between the consensus sequences of different primate alphoid DNAs and it was found that the interspecies nucleotide divergency of this satellite DNA is quite similar to the intragenomic one. 5. The sequenced h alpha RI DNA clones were used for preparation of DNA-DNA hybrids with a known percentage of base pair mismatching. 6. These hybrids were melted on hydroxyapatite (HAP) and the results obtained were used to determine the relationship between the thermal stability (Tm) and the extent of base pair mismatching for naturally diverged DNA sequences. 7. A value of 0.7 degrees C decrease in Tm per 1% base pair mismatching was found.     

Ca/Mg-dependent endonuclease from porcine liver. Purification, properties, and sequence specificity

A rapid and reproducible method for the purification of the Ca/Mg-endonuclease from porcine and rat liver and for the stabilization of the enzyme activity is presented. The optimum conditions for enzyme activity were determined. The enzyme degrades double-stranded DNA endonucleolytically. In the course of digestion of form I closed circular SV 40 DNA, the form II nicked circular DNA is the prominent intermediate product. Digestion of hen erythrocyte nuclei with added endonuclease produces a ladder of mono- and oligonucleosomal fragments similar to that generated by micrococcal nuclease digestion. Determination of the 5'-terminal nucleotides indicates the absence of a significant base specificity. Analyzing the cleavage pattern of end-labeled pBR322 restriction fragments on sequencing gels shows that the enzyme exhibits a weak preference for dinucleotides with A in the 5'-position; dinucleotides with 5%-C are less readily cleaved. Digestion of end-labeled pBR322 DNA, followed by electrophoresis in agarose gels produces a "smear"-like fragmentation pattern with weak superimposed bands, while micrococcal nuclease generates a different and much more distinct pattern. These data show that the sequence specificity of the enzyme is less pronounced than that of micrococcal nuclease and that the sites preferentially cleaved are not the same.     

Influence of neighboring base sequence on mutagenesis induced by in vitro misincorporation in the lacI gene of Escherichia coli.

Genetic and electrophoretic assays of misincorporation were used to assess the effect of DNA sequence on mutagenesis arising from in vitro DNA synthesis within the lacI gene of Escherichia coli. The viral strand of a derivative of phage M13 containing the entire lacI gene was annealed with a series of synthetic oligonucleotides complementary to the N-terminal region of the lacI gene. Each primer-template was incubated with E. coli DNA polymerase I (Klenow fragment) under conditions favoring misincorporation, wherein one of the 4 dNTPs was lacking ('minus' reaction) or present at very low concentration ('micro' reaction). The extent of elongation of each primer was assessed by gel electrophoresis, and lacI mutants arising during the misincorporation reactions were detected by a transfection assay in which i- base substitutions within the in vitro synthesized strand were selectively recovered by the use of uracil-containing templates. Direct dideoxy sequencing of the '-A' reaction products and sequence analysis of i- mutant progeny revealed a vast predominance of single and non-tandem multiple base transitions. The addition of small quantities of dATP to a '-A' reaction increased the mutation yield and broadened the distribution of base substitutions along the template. We detected a general bias towards increased base substitution at template positions flanked by G.C base pairs or 5'-pyrimidine, 3'-purine nearest neighbors, although considerable site-to-site variation in the occurrence of base substitutions was seen, even within identical nearest neighbor contexts.