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.     

The genome-wide sequence specificity of DNA cleavage by bleomycin analogues in human cells

Bleomycin (BLM) is a cancer chemotherapeutic agent that cleaves cellular DNA at specific sequences. Using next-generation Illumina sequencing, the genome-wide sequence specificity of DNA cleavage by two BLM analogues, 6′-deoxy-BLM Z and zorbamycin (ZBM), was determined in human HeLa cells and compared with BLM. Over 200 million double-strand breaks were examined for each sample, and the 50,000 highest intensity cleavage sites were analysed. It was found that the DNA sequence specificity of the BLM analogues in human cells was different to BLM, especially at the cleavage site (position “0”) and the “+1” position. In human cells, the 6′-deoxy-BLM Z had a preference for 5′-GTGY*MC (where * is the cleavage site, Y is C or T, M is A or C); it was 5′-GTGY*MCA for ZBM; and 5′-GTGT*AC for BLM. With cellular DNA, the highest ranked tetranucleotides were 5′-TGC*C and 5′-TGT*A for 6′-deoxy-BLM Z; 5′-TGC*C, 5′-TGT*A and 5′-TGC*A for ZBM; and 5′-TGT*A for BLM. In purified human genomic DNA, the DNA sequence preference was 5′-TGT*A for 6′-deoxy-BLM, 5′-RTGY*AYR (where R is G or A) for ZBM, and 5′-TGT*A for BLM. Thus, the sequence specificity of the BLM analogue, 6′-deoxy-BLM Z, was similar to BLM in purified human DNA, while ZBM was different.     

The specific cleavage of DNA with ultrasound

Cleavages of double-stranded DNA fragments of known base pair sequence upon ultrasound irradiation at 22 and 44 kHz were studied by gel electrophoresis. The cleavage rate is found to be strongly dependent on the DNA fragment length, pH, temperature and ionic strength of the solution under study. The cleavage of double-stranded DNA occurs predominantly at sites containing alternating 5'-CpG-3' sequences. The breakage of phosphatediester bond takes place between C and G in such a way that phosphate group at the 5'-end of the guanine residue remain intact. The cleavage rate at a given DNA site is found to depend on base pair sequences at adjacent sites. Distinctly different cleavage patterns are observed when free DNA and DNA complexes with cys-diammine-Pt-bridged bis-netropsin were irradiated by ultrasound. The observed effect can be attributed to local DNA conformation changes induced upon complex formation between ligand and DNA.     

UVA irradiation of BrU-substituted DNA in the presence of Hoechst 33258

Given that our knowledge of DNA repair is limited because of the complexity of the DNA system, a technique called UVA micro-irradiation has been developed that can be used to visualize the recruitment of DNA repair proteins at double-strand break (DSB) sites. Interestingly, Hoechst 33258 was used under micro-irradiation to sensitize 5-bromouracil (^BrU)-labelled DNA, causing efficient DSBs. However, the molecular basis of DSB formation under UVA micro-irradiation remains unknown. Herein, we investigated the mechanism of DSB formation under UVA micro-irradiation conditions. Our results suggest that the generation of a uracil-5-yl radical through electron transfer from Hoechst 33258 to ^BrU caused DNA cleavage preferentially at self-complementary 5′-AA^BrU^BrU-3′ sequences to induce DSB. We also investigated the DNA cleavage in the context of the nucleosome to gain a better understanding of UVA micro-irradiation in a cell-like model. We found that DNA cleavage occurred in both core and linker DNA regions although its efficiency reduced in core DNA.     

Sequence requirements for mammalian topoisomerase II mediated DNA cleavage stimulated by an ellipticine derivative.

Various antitumor drugs stabilize DNA topoisomerase II-DNA transient covalent complexes. The complexes distribution along pBR322 DNA was shown previously to depend upon the nature of the drug (Tewey et al. (1984) Science 226, 466-468). The position in pBR322 of DNA cleavage by calf DNA topoisomerase II for 115 such sites stabilized by an ellipticine derivative and the relative frequency of cleavage at most of these sites were determined. The nucleotide sequence surrounding the 25 strongest sites was analyzed and the following ellipticine specific consensus sequence was deduced: 5'-ANCNT(A/G)T.NN(G/C)N(A/G)-3' where cleavage occurs at the indicated mark. A thymine is always present at the 3' end of at least one strand of the strong cleavage sites, and the dinucleotide AT or GT at the 3' end of the break plays a major role in the complex stabilisation. The predictive value of cleavage of the consensus was tested for two regions of SV40 DNA and cleavage was indeed detected at the majority of the sites matching the consensus. Some complexes stabilized by ellipticine are resistant to salt dissociation and this property seems to be correlated with the presence of symmetrical sequences in the cleavage site with a center of symmetry staggered relatively to the center of symmetry of cleavage.     

DNA Conjugates as Novel Functional Oligonucleotides

Abstract

Oligodeoxynucleotides with RNA cleavage activity 1) were conjugated with amines and peptides by solid phase fragment condensation (SPFC). It was found that 29 mer DNA enzyme conjugated with spermine at its 5′-end showed higher affinity to the target RNA sequence and 40 times higher activity of cleavage than native DNA enzyme. It is also to be noted that conjugate DNA enzymes showed increased resistance against nuclease digestion     

Partial characterization of DNA from five entomopoxviruses

Extensive genomic heterogeneity was detected in the restriction endonuclease cleavage patterns of DNA from five entomopoxvirus isolates and vaccinia virus, strain WR. An 8.2 kilobase pair extra-chromosomal element was detected in Amsacta moorei entomopoxvirus and a 22 kilobase pair extra-chromosomal DNA element was isolated from Choristoneura biennis EPV. The extent of DNA base sequence homology was determined by Southern hybridization of HindIII and BamHI DNA restriction fragments of C. biennis EPV DNA and A. moorei EPV DNA with (α³²P)-labeledA. moorei EPV DNA. Methylation of 5′-C^mCGG-3′ sequences was not detected in the DNA of A. moorei, C. biennis, E. auxiliaris, M. sanguinipes, and A. conspersa entomopoxviruses after cleavage of the viral DNAs with MspI and HpaII restriction endonucleases. Based upon the DNA base sequence homology data presented here, the five entomopoxviruses used in this study appear to be unrelated.     

Zorbamycin has a different DNA sequence selectivity compared with bleomycin and analogues

Bleomycin (BLM) is used clinically in combination with a number of other agents for the treatment of several types of tumours. Members of the BLM family of drugs include zorbamycin (ZBM), phleomycin D1, BLM A2 and BLM B2. By manipulating the BLM biosynthetic machinery, we have produced two new BLM analogues, BLM Z and 6′-deoxy-BLM Z, with the latter exhibiting significantly improved DNA cleavage activity. Here we determined the DNA sequence specificity of BLM Z, 6′-deoxy-BLM Z and ZBM, in comparison with BLM, with high precision using purified plasmid DNA and our recently developed technique. It was found that ZBM had a different DNA sequence specificity compared with BLM and the BLM analogues. While BLM and the BLM analogues showed a similar DNA sequence specificity, with TGTA sequences as the main site of cleavage, ZBM exhibited a distinct DNA sequence specificity, with both TGTA and TGTG as the predominant cleavage sites. These differences in DNA sequence specificity are discussed in relation to the structures of ZBM, BLM and the BLM analogues. Our findings support the strategy of manipulating the BLM biosynthetic machinery for the production of novel BLM analogues, difficult to prepare by total synthesis; some of which could have beneficial cancer chemotherapeutic properties.     

AP endonuclease 1 prevents the extension of a T/G mismatch by DNA polymerase β to prevent mutations in CpGs during base excision repair

Dynamics of DNA methylation and demethylation at CpG clusters are involved in gene regulation. CpG clusters have been identified as hot spots of mutagenesis because of their susceptibility to oxidative DNA damage. Damaged Cs and Gs at CpGs can disrupt a normal DNA methylation pattern through modulation of DNA methylation and demethylation, leading to mutations and deregulation of gene expression. DNA base excision repair (BER) plays a dual role of repairing oxidative DNA damage and mediating an active DNA demethylation pathway on CpG clusters through removal of a T/G mismatch resulting from deamination of a 5mC adjacent to a guanine that can be simultaneously damaged by oxidative stress. However, it remains unknown how BER processes clustered lesions in CpGs and what are the consequences from the repair of these lesions. In this study, we examined BER of an abasic lesion next to a DNA demethylation intermediate, the T/G mismatch in a CpG dinucleotide, and its effect on the integrity of CpGs. Surprisingly, we found that the abasic lesion completely abolished the activity of thymine DNA glycosylase (TDG) for removing the mismatched T. However, we found that APE1 could still efficiently incise the abasic lesion leaving a 3-terminus mismatched T, which was subsequently extended by pol β. This in turn resulted in a C to T transition mutation. Interestingly, we also found that APE1 3′–5′ exonuclease activity efficiently removed the mismatched T, thereby preventing pol β extension of the mismatched nucleotide and the resulting mutation. Our results demonstrate a crucial role of APE1 3′–5′ exonuclease activity in combating mutations in CpG clusters caused by an intermediate of DNA demethylation during BER.     

Hypothesis of initiation of DNA methylation de novo and allelic exclusion by small RNAs

We have established that 5′-CG-3′ dinucleotide and 5′-CNG-3′ trinucleotide are found in published sequences of small interfering RNA and microRNA more often than they should be in random DNA sequences. This circumstance indicates the important biological role played by 5′-CG-3′ dinucleotides and 5′-CNG-3′ trinucleotides in small RNA sequences. We suggest that small RNAs containing these di- and trinucleotides participate in the creation of chromatin marks of epigenetic information through a highly specific search for repressible DNA sequences and through the initiation of the methylation de novo of 5′-CG-3′ and 5′-CNG-3′ sites in DNA fragments appearing to be bound complementary to small RNAs. Several genes can be inactivated simultaneously if they contain the motif recognized by small RNA. Allelic exclusion appears, in our opinion, as a result of initiation by small RNAs of DNA methylation de novo of all but one of the alleles that exist in the cell. The predecessor of this small RNA is transcribed from the antiparallel allele chain. Alleles whose antiparallel chains are less actively read by RNA polymerase, which, as we suggest, in the process of transcribing, releases DNA from small RNA bound to it, are inactivated. However, the quantity of small RNA transcribed from only one allele is insufficient to overcome the level above which the repression process of this allele is initiated de novo.     

Double base lesions of DNA by a metabolite of carcinogenic benzo[a]pyrene.

Carcinogenic benzo[a]pyrene (BP) is generally considered to show genotoxicity by forming DNA adducts of its metabolite, BP-7,8-diol-9,10-epoxide. We investigated oxidative DNA damage and its sequence specificity induced by BP-7,8-dione, another metabolite of BP, using (32)P-5'-end-labeled DNA. Formamidopyrimidine-DNA glycosylase treatment induced cleavage sites mainly at G residues of 5'-TG-3' sequence and at poly(C) sequences, in DNA incubated with BP-7,8-dione in the presence of NADH and Cu(II), whereas piperidine treatment induced cleavage sites at T mainly of 5'-TG-3'. BP-7,8-dione strongly damaged the G and C of the ACG sequence complementary to codon 273 of the p53 gene. Catalase and a Cu(I)-specific chelator attenuated the DNA damage, indicating the involvement of H(2)O(2) and Cu(I). BP-7,8-dione with NADH and Cu(II) also increased 8-oxo-7,8-dihydro-2'-deoxyguanosine formation. We conclude that oxidative DNA damage, especially double base lesions, may participate in the expression of carcinogenicity of BP in addition to DNA adduct formation.     

Structure and function of a novel endonuclease acting on branched DNA substrates

We show that Pyrococcus abyssi PAB2263 (dubbed NucS (nuc lease for s s DNA) is a novel archaeal endonuclease that interacts with the replication clamp PCNA. Structural determination of P. abyssi NucS revealed a two‐domain dumbbell‐like structure that in overall does not resemble any known protein structure. Biochemical and structural studies indicate that NucS orthologues use a non‐catalytic ssDNA‐binding domain to regulate the cleavage activity at another site, thus resulting into the specific cleavage at double‐stranded DNA (dsDNA)/ssDNA junctions on branched DNA substrates. Both 3′ and 5′ extremities of the ssDNA can be cleaved at the nuclease channel that is too narrow to accommodate duplex DNA. Altogether, our data suggest that NucS proteins constitute a new family of structure‐specific DNA endonucleases that are widely distributed in archaea and in bacteria, including Mycobacterium tuberculosis.     

Trimming of damaged 3′ overhangs of DNA double-strand breaks by the Metnase and Artemis endonucleases

Both Metnase and Artemis possess endonuclease activities that trim 3′ overhangs of duplex DNA. To assess the potential of these enzymes for facilitating resolution of damaged ends during double-strand break rejoining, substrates bearing a variety of normal and structurally modified 3′ overhangs were constructed, and treated either with Metnase or with Artemis plus DNA-dependent protein kinase (DNA-PK). Unlike Artemis, which trims long overhangs to 4–5 bases, cleavage by Metnase was more evenly distributed over the length of the overhang, but with significant sequence dependence. In many substrates, Metnase also induced marked cleavage in the double-stranded region within a few bases of the overhang. Like Artemis, Metnase efficiently trimmed overhangs terminated in 3′-phosphoglycolates (PGs), and in some cases the presence of 3′-PG stimulated cleavage and altered its specificity. The nonplanar base thymine glycol in a 3′ overhang severely inhibited cleavage by Metnase in the vicinity of the modified base, while Artemis was less affected. Nevertheless, thymine glycol moieties could be removed by Metnase- or Artemis-mediated cleavage at sites farther from the terminus than the lesion itself. In in vitro end-joining systems based on human cell extracts, addition of Artemis, but not Metnase, effected robust trimming of an unligatable 3′-PG overhang, resulting in a dramatic stimulation of ligase IV- and XLF-dependent end joining. Thus, while both Metnase and Artemis are biochemically capable of resolving a variety of damaged DNA ends for the repair of complex double-strand breaks, Artemis appears to act more efficiently in the context of other nonhomologous end joining proteins.     

Sequence-specific DNA cleavage by dipeptides disubstituted with chlorambucil and 2,6-dimethoxyhydroquinone-3-mercaptoacetic acid.

Two dipeptides, each containing a lysyl residue, were disubstituted with chlorambucil (CLB) and 2,6-dimethoxyhydroquinone-3-mercaptoacetic acid (DMQ-MA): DMQ-MA-Lys(CLB)-Gly-NH2 (DM-KCG) and DMQ-MA-beta-Ala-Lys(CLB)-NH2 (DM-BKC). These peptide-drug conjugates were designed to investigate sequence-specificity of DNA cleavage directed by the proximity effect of the DNA cleavage chromophore (DMQ-MA) situated close to the alkylating agent (CLB) inside a dipeptide moiety. Agarose electrophoresis studies showed that DM-KCG and DM-BKC possess significant DNA nicking activity toward supercoiled DNA whereas CLB and its dipeptide conjugate Boc-Lys(CLB)-Gly-NH2 display little DNA nicking activity. ESR studies of DMQ-MA and DM-KCG both showed five hyperfine signals centered at g = 2.0052 and are assigned to four radical forms at equilibrium, which may give rise to a semiquinone radical responsible for DNA cleavage. Thermal cleavage studies at 90 degrees C on a 265-mer test DNA fragment showed that besides alkylation and cleavage at G residues, reactions with DM-KCG and DM-BKC show a preference for A residues with the sequence pattern: 5'-G-(A)n-Pur-3' > 5'-Pyr-(A)n-Pyr-3' (where n = 2-4). By contrast, DNA alkylation and cleavage by CLB occurs at most G and A residues with less sequence selectivity than seen with DM-KCG and DM-BKC. Thermal cleavage studies using N7-deazaG and N7-deazaA-substituted DNA showed that strong alkylation and cleavage at A residues by DM-KCG and DM-BKC is usually flanked on the 3' side by a G residue whereas strong cleavage at G residues is flanked by at least one purine residue on either the 5' or 3' side. At 65 degrees C, it is notable that the preferred DNA cleavage by DM-KCG and DM-BKC at A residues is significantly more marked than for G residues in the 265-mer DNA; the strongest sites of A-specific reaction occur within the sequences 5'-Pyr-(A)n-Pyr-3'; 5'-Pur-(A)n-G-3' and 5'-Pyr-(A)n-G-3'. In pG4 DNA, cleavage by DM-KCG and DM-BKC is much greater than that by CLB at room temperature and at 65 degrees C. It was also observed that DM-KCG and DM-BKC cleaved at certain pyrimidine residues: C40, T66, C32, T34, and C36. These cleavages were also sequence selective since the susceptible pyrimidine residues were flanked by two purine residues on both the 5' and 3' sides or by a guanine residue on the 5' side. These findings strongly support the proposal that once the drug molecule is positioned so as to permit alkylation by the CLB moiety, the DMQ-MA moiety is held close to the alkylation site, resulting in markedly enhanced sequence-specific cleavage.     

DNA sequence selectivity of human topoisomerase I‐mediated DNA cleavage induced by camptothecin

In probing the mechanism of inhibition of hypoxia inducible factor (HIF-1) by campothecins, we investigated the ability of human topoisomerase I to bind and cleave HIF-1 response element (HRE), which contains the known camptothecin-mediated topoisomerase I cleavage site 5′-TG. We observed that the selection of 5′-TG by human topoisomerase I and topotecan depends to a large extent on the specific flanking sequences, and that the presence of a G at the −2 position (where cleavage occurs between −1 and +1) prevents the HRE site from being a preferred site for such cleavage. Furthermore, the presence of −2 T/A can induce the cleavage at a less preferred TC or TA site. However, in the absence of a more preferred site, the HRE site is shown to be cleaved by human topoisomerase I in the presence of topotecan. Thus, it is implied that the −2 base has a significant influence on the selection of the camptothecin-mediated Topo I cleavage site, which can overcome the preference for +1G. While the cleavage site recognition has been known to be based on the concerted effect of several bases spanning the cleavage site, such a determining effect of an individual base has not been previously recognized. A possible base-specific interaction between DNA and topoisomerase I may be responsible for this sequence selectivity.     

Enhancement and alteration of bleomycin-catalyzed site-specific DNA cleavage by distamycin A and some minor groove binders.

The effects of compounds which bind in the DNA minor groove of A.T rich sequences, on bleomycin-catalyzed site-specific DNA cleavage were investigated by a DNA sequencing technique. Distamycin A enhanced bleomycin-catalyzed DNA cleavage in G.C rich sequences such as 5'-GGGGC-3' (under scoring; the cleaved nucleotide). The cleavage in such a sequence in the presence of distamycin A was greater than that in the absence of distamycin A by as much as about 100 times. Neither Hoechst 33258, 4',6-diamidino-2-phenylindole (DAPI) nor berenil caused extensive enhancement. The results suggest that the distamycin-induced conformational changes of DNA through interactions other than the DNA minor groove binding in A.T-rich sequences are specifically suitable for the bleomycin action.