DNA damage and repair in relation to cell killing in neocarzinostatin-treated HeLa cells

DNA double strand breaks but not interstrand crosslinks prevent progress through meiosis in fully grown mouse oocytes

There is some interest in how mammalian oocytes respond to different types of DNA damage because of the increasing expectation of fertility preservation in women undergoing chemotherapy. Double strand breaks (DSBs) induced by ionizing radiation and agents such as neocarzinostatin (NCS), and interstrand crosslinks (ICLs) induced by alkylating agents such as mitomycin C (MMC), are toxic DNA lesions that need to be repaired for cell survival. Here we examined the effects of NCS and MMC treatment on oocytes collected from antral follicles in mice, because potentially such oocytes are readily collected from ovaries and do not need to be in vitro grown to achieve meiotic competency. We found that oocytes were sensitive to NCS, such that this ionizing radiation mimetic blocked meiosis I and caused fragmented DNA. In contrast, MMC had no impact on the completion of either meiosis I or II, even at extremely high doses. However, oocytes treated with MMC did show γ-H2AX foci and following their in vitro maturation and parthenogenetic activation the development of the subsequent embryos was severely compromised. Addition of MMC to 1-cell embryos caused a similarly poor level of development, demonstrating oocytes have eventual sensitivity to this ICL-inducing agent but this does not occur during their meiotic division. In oocytes, the association of Fanconi Anemia protein, FANCD2, with sites of ICL lesions was not apparent until entry into the embryonic cell cycle. In conclusion, meiotic maturation of oocytes is sensitive to DSBs but not ICLs. The ability of oocytes to tolerate severe ICL damage and yet complete meiosis, means that this type of DNA lesion goes unrepaired in oocytes but impacts on subsequent embryo quality.

Neocarzinostatin as a probe for DNA protection activity--molecular interaction with caffeine

Neocarzinostatin (NCS), a potent mutagen and carcinogen, consists of an enediyne prodrug and a protein carrier. It has a unique double role in that it intercalates into DNA and imposes radical-mediated damage after thiol activation. Here we employed NCS as a probe to examine the DNA-protection capability of caffeine, one of common dietary phytochemicals with potential cancer-chemopreventive activity. NCS at the nanomolar concentration range could induce significant single- and double-strand lesions in DNA, but up to 75 ± 5% of such lesions were found to be efficiently inhibited by caffeine. The percentage of inhibition was caffeine-concentration dependent, but was not sensitive to the DNA-lesion types. The well-characterized activation reactions of NCS allowed us to explore the effect of caffeine on the enediyne-generated radicals. Postactivation analyses by chromatographic and mass spectroscopic methods identified a caffeine-quenched enediyne-radical adduct, but the yield was too small to fully account for the large inhibition effect on DNA lesions. The affinity between NCS chromophore and DNA was characterized by a fluorescence-based kinetic method. The drug-DNA intercalation was hampered by caffeine, and the caffeine-induced increases in DNA-drug dissociation constant was caffeine-concentration dependent, suggesting importance of binding affinity in the protection mechanism. Caffeine has been shown to be both an effective free radical scavenger and an intercalation inhibitor. Our results demonstrated that caffeine ingeniously protected DNA against the enediyne-induced damages mainly by inhibiting DNA intercalation beforehand. The direct scavenging of the DNA-bound NCS free radicals by caffeine played only a minor role.

The cellular response to DNA damage induced by the enediynes C-1027 and neocarzinostatin includes hyperphosphorylation and increased nuclear retention of replication protein a (RPA) and trans inhibition of DNA replication

This study examined the cellular response to DNA damage induced by antitumor enediynes C-1027 and neocarzinostatin. Treatment of cells with either agent induced hyperphosphorylation of RPA32, the middle subunit of replication protein A, and increased nuclear retention of RPA. Nearly all of the RPA32 that was not readily extractable from the nucleus was hyperphosphorylated, compared to < or =50% of the soluble RPA. Enediyne concentrations that induced RPA32 hyperphosphorylation also decreased cell-free SV40 DNA replication competence in extracts of treated cells. This decrease did not result from damage to the DNA template, indicating trans-acting inhibition of DNA replication. Enediyne-induced RPA hyperphosphorylation was unaffected by the replication elongation inhibitor aphidicolin, suggesting that the cellular response to enediyne DNA damage was not dependent on elongation of replicating DNA. Neither recovery of replication competence nor reversal of RPA effects occurred when treated cells were further incubated in the absence of drug. C-1027 and neocarzinostatin doses that caused similar levels of DNA damage resulted in equivalent increases in RPA32 hyperphosphorylation and RPA nuclear retention and decreases in replication activity, suggesting a common response to enediyne-induced DNA damage. By contrast, DNA damage induced by C-1027 was at least 5-fold more cytotoxic than that induced by neocarzinostatin.

DNA damage and mutagenesis by radiomimetic DNA-cleaving agents: bleomycin, neocarzinostatin and other enediynes

Bleomycin and the enediyne antibiotics effect concerted, simultaneous site-specific free radical attack on sugar moieties in both strands of DNA, resulting in double-strand breaks of defined geometry and chemical structure, as well as abasic sites with closely opposed strand breaks. The hypersensitivity of several mammalian double-strand break repair-deficient mutants to these agents confirms the role of these double-strand breaks in mediating cytotoxicity. In bacteria, mutagenesis by both bleomycin and neocarzinostatin appears to result from replicative bypass of abasic sites, the repair of which is blocked by the presence of closely opposed strand breaks. However, in mammalian cells, such abasic sites decompose to form double-strand breaks, and mutagenesis consists primarily of small deletions, large deletions, and gene rearrangements, all of which probably result from errors in double-strand break repair by a nonhomologous end-joining mechanism. Studies with the radiomimetic antibiotics emphasize the importance of this end-joining repair pathway, and these agents provide useful probes of its mechanistic details, particularly the effects of chemically modified DNA termini on repair.

The binding modes of a rationally designed photoactivated DNA nuclease determined by NMR

The complex between the rationally designed synthetic DNA cleaving agent netropsin-diazene and the double-stranded DNA oligomer 5'-CGCAAAGGC-3'.5'-GCCTTTTGCG-3' was characterized by two-dimensional NMR spectroscopy in solution. Photolysis of netropsin-diazene bound to DNA generates a trimethylenemethane diradical intermediate that induces single-strand breaks in the DNA. The pi-diyl trimethylenemethane based compounds are a new class of DNA nucleases. We tested the following design criteria: (i) binding of the diazene and subsequent reactive diyl to the DNA, (ii) sequence selectivity in the ligand binding and (iii) prevention of diyl dimerization. Sixteen NOE derived ligand-DNA distance restraints were used to obtain the energy minimized model of the complex. The ligand is bound to the minor groove of the oligomer with the diazene at the 5' end of the A-tract in the predominant conformation of the complex. This form of the complex exchanges with a minor conformation in which the ligand is in the opposite orientation. The DNA maintains a B-form structure. Netropsin-diazene has fulfilled all of the design criteria, binding to the DNA duplex studied in the minor groove of the central AAAA tract in a 1:1 mode, preventing diyl dimerization and other side reactions from occurring.

Effects of the enediyne C-1027 on intracellular DNA targets

We examined DNA damage induced by the enediyne-containing antitumor antibiotic C-1027 in intracellular nuclear and mitochondrial DNA targets using the episome-containing cell line 935.1. Strand-scission activity of the C-1027 holoantibiotic was measured by the topological forms conversion assay in episomal and mitochondrial DNA, as well as in cell-free plasmid DNA. Genomic DNA damage was quantitated by filter elution analysis. Comparisons were made to the well-characterized enediyne neocarzinostatin. From these studies, mixed single- and double-strand breaks were observed not only in cell-free, plasmid DNA but also in intracellular episomal, mitochondrial, and genomic DNA at low nanomolar concentrations. C-1027 cleaved DNA 285-fold more efficiently in cells than in a cell-free environment, and displayed preference for intracellular DNA species in the following rank order: episome > mitochondrial DNA >> genomic. NCS also damaged the non-histone-associated mitochondrial DNA, but not the episome. Cleavage of the 935.1 cell episome by C-1027 occurred at specific sites including the BPV origin of replication and E6/E7 open reading frame regions, as well as the MMTV LTR promoter region.

C1027 chromophore, a potent new enediyne antitumor antibiotic, induces sequence-specific double-strand DNA cleavage

C1027, a new macromolecular antitumor antibiotic produced by a Streptomyces strain, shows highly potent cytotoxicity to cultured cancer cells and marked DNA cleaving ability. The structure of its chromophore, responsible for most of the biological activities of the antibiotic, was recently determined and found to contain a nine-membered enediyne. In contrast to other enediyne antibiotics, such as neocarzinostatin, calicheamicin, esperamicin, and recently found kedarcidin, C1027 damages duplex DNA even in the absence of thiols. The DNA damage caused by C1027 includes double-strand breaks, single-strand breaks, and abasic sites. Experiments with plasmid DNA and 32P-end-labeled restriction fragments demonstrated that the chromophore, extracted from the protein-containing holoantibiotic, interacts in the DNA minor groove and cleaves double-helical DNA with a remarkable sequence-selectivity causing direct double-strand breaks. The double-strand cleavage sites, occurring predominantly at CTTTT/AAAAG, ATAAT/ATTAT, CTTTA/TAAAG, CTCTT/AAGAG, and especially GTTAT/ATAAC, consist of five nucleotide sequences with a two-nucleotide 3'-stagger of the cleaved residues (cutting sites are underlined). The chemical structures of the damaged residues at the GTTAT/ATAAC cleavage site suggest a model in which a C1027-induced double-strand break results from abstraction, by a single molecule of the diradical form of the chromophore, of a C4' hydrogen atom from the A residue of GTTAT and a C5' hydrogen atom from the A of ATAAC on the opposite strand. Single-strand breaks, which are mainly produced at adenylate and thymidylate residues, appear to be separate events presumably resulting from different binding modes of the drug to DNA.(ABSTRACT TRUNCATED AT 250 WORDS)

Spontaneous cleavage of bleomycin-induced abasic sites in chromatin and their mutagenicity in mammalian shuttle vectors

The stability of oxidized abasic sites induced by bleomycin and neocarzinostatin was examined in chromatin reconstituted from a supercoiled plasmid and core histones. Most of the drug-induced abasic sites were found to undergo spontaneous cleavage in chromatin, probably by reaction with histone amine groups. However, there was considerable heterogeneity in the rate of spontaneous cleavage, with some sites being cleaved almost immediately and some remaining intact even after 7 h. Bleomycin-induced abasic sites with closely opposed strand breaks were more unstable than lone abasic sites. Neocarzinostatin-induced abasic sites, which have a different chemical structure, were cleaved somewhat more slowly than those induced by bleomycin. To assess the mutagenic potential of bleomycin-induced abasic sites, bleomycin-treated shuttle vectors were transfected into mammalian cells, and mutations in progeny plasmids were sequenced. Bleomycin treatment resulted primarily in deletions of various sizes in the shuttle vectors, including a number of one-base deletions occurring at potential bleomycin damage sites. However, under certain conditions, substitutions occurring at expected sites of bleomycin attack were also observed. The results suggest that bleomycin-induced abasic sites have only a slight potential to produce base substitutions in mammalian cells and that a substantial fraction of the double-strand breaks induced by bleomycin and most of the double-strand breaks induced by neocarzinostatin are the result of spontaneous cleavage of abasic sites with closely opposed strand breaks. Inaccurate repair of these double-strand breaks may account for the large deletions, and perhaps the one-base deletions, induced by bleomycin.

Neocarzinostatin-mediated DNA damage in a model AGT.ACT site: mechanistic studies of thiol-sensitive partitioning of C4' DNA damage products

Double-strand (DS) DNA damage caused by neocarzinostatin (NCS) has been studied in the trinucleotide AGT-ACT sequence in an AP-1 transcription factor binding site. There are strong similarities between bistranded lesions produced at AGT.ACT and AGC-GCT, including the fact that DS lesions outnumber SS lesions on the AGT and AGC strands, while SS exceed DS on the ACT and GCT strands. Structure-function studies revealed that a variety of different thiols produced bistranded lesions in this model by predominantly C4'-hydrogen atom abstraction (84-93%) at the T of AGT and C5'-hydrogen atom abstraction (87-91%) at the T of ACT. Single-strand (SS) lesions were found to represent a variable mixture of C4' and C5' chemistry. The C4'-hydroxylated abasic site occurred in both SS and DS lesions at both sites and accounted for most of the DS damage at AGT (60-83%); the remaining damage consisted of 3'-phosphoglycolate- and 3'-phosphate-ended fragments. The nature of the thiol was found to affect the partitioning of the breakdown products arising from C4' and, to a lesser extent, C5' hydrogen atom abstraction. Production of 3'-phosphoglycolate residues, restricted mainly to the T of AGT in bistranded lesions, correlated with the incidence of direct DS breaks in the AGT.ACT model and in plasmid DNA and appeared to be influenced by the reducing power of the thiol activator. Furthermore, hydrazine and sodium borohydride both inhibited the formation of glycolate, an effect that was exploited to determine the rate constant for 3'-phosphoglycolate formation: 0.06 min-1 at 0 degree C, pH 7.4. Under anaerobic conditions, the nitroaromatic radiation sensitizer misonidazole caused a large increase in glycolate production in both SS and DS lesions formed by NCS, which suggests that the formation of 3'-phosphoglycolate, like 3'-formylphosphate generated by C5' chemistry, involves an oxyradical intermediate. The pathways for DNA damage involving C4' and C5' hydrogen atom abstraction thus share many common features, several of which are consistent with a mechanism for the production of NCS-mediated bistranded lesions at AGT.ACT that involves a tetraoxide bridge joining the lesions on opposite strands of DNA.

Molecular models of neocarzinostatin damage of DNA: analysis of sequence dependence in 5'GAGCG:5'CGCTC

Model building and molecular mechanics and dynamics calculations have been performed on a number of complexes of the post-activated form of the neocarzinostatin chromophore (NCS) with the B-DNA oligomer 5'GAGCG:5'CGCTC. Stable structures with the naphthoic acid moiety intercalated at all base pairs can be constructed. The observed bistranded lesions consisting of an abasic site at the Cyt residue in AGC and a direct break at the Thy residue on the complementary strand can be explained by assuming that NCS in the (R,R) form intercalates between the Ade2-Thy9/Gua3-Cyt8 base step with its 'diradical' core oriented towards the 3'-end of the (+) strand. Sites at C5', C4' and C1' in the minor groove are within a short enough distance from the two radical centers on NCS to permit hydrogen atom abstraction and the formation of the bistranded lesions. Strand cleavage at Thy9 may occur as a single lesion if NCS is intercalated into the Gua3-Cyt8/Cyt4-Gua7 base step with its active core towards the 3'-end of the (-) strand. The results are analyzed, and the utility and limitations of this type of model building are discussed.

Combined effect of radiation and YM-881 (SMANCS) on murine tumors and bone marrow

The combined effect of radiation and YM-881 (SMANCS) was studied in vitro and in vivo. When 0.25 microgram/ml of YM-881 was simultaneously combined with radiation, during and after irradiation for 30 min in total, Dq decreased from 3.3 Gy to 1.4 Gy without changing D0 in the dose-survival curve of exponentially growing SCC VII tumor cells. Five or ten times administrations of 0.1 mg/kg YM-881 at an interval of 24 h did not inhibit tumor growth. However, administration of 0.1 mg/kg YM-881 just before every irradiation which was repeated five times at an interval of 24 h yielded dose modifying factors (DMFs) of 1.8-1.2 when the tumor response to treatment was evaluated by the time for the tumors to regrow to three times the original volume. Administration of YM-881 ten times just before every irradiation yielded DMFs of 1.3-1.2. Adverse effects of the combination on bone marrow were examined by spleen colony assay. After five injections of 0.1 mg/kg YM-881, the mean number of CFU-S per femur decreased to 77% of the pretreatment level, but this was not significant statistically (0.1 greater than p greater than 0.05). The slope of radiation response curve for CFU-S per femur was not affected by the combination.

Free radical mechanisms in neocarzinostatin-induced DNA damage

The molecular mechanisms by which the antitumor protein antibiotic, neocarzinostatin, interacts with DNA and causes DNA sugar damage is discussed. Physical binding of the nonprotein chromophore of neocarzinostatin to DNA, involving an intercalative process and dependent on the microheterogeneity of DNA structure, is followed by thiol activation of the drug to a probable radical species. The latter attacks the deoxyribose, especially at thymidylate residues, by abstracting a hydrogen atom from C-5' to generate a carbon-centered radical on the DNA. This nascent form of DNA damage either reacts with dioxygen to form a peroxyl radical derivative, which eventuates in a strand break with a nucleoside 5'-aldehyde at the 5'-end or reacts with the bound drug to form a novel drug-deoxyribose covalent adduct. Nitroaromatic radiation sensitizers can substitute for dioxygen, but the DNA damage products are different. Similarities between the various biological effects of neocarzinostatin and ionizing radiation are reviewed.

Poly(deoxyadenylic-deoxythymidylic acid) damage by radiolytically activated neocarzinostatin

The anaerobic reaction of poly(deoxyadenylic-deoxythymidylic acid) with neocarzinostatin activated by the carboxyl radical CO2-, an electron donor generated from gamma-ray radiolysis of nitrous oxide saturated formate buffer, has been characterized. DNA damage includes base release and strand breaks. Few strand breaks are formed prior to alkaline treatment; they bear 3'-phosphoryl termini. In contrast, most (66%) of the base release occurs spontaneously. DNA damage is highly (95%) specific for thymidine sites. Neither DNA-drug covalent adduct nor nucleoside 5'-aldehyde, which are major products in the DNA-nicking reaction initiated by mercaptans and oxygen, is formed in this reaction. Data are presented to show that the CO2(-)-activated neocarzinostatin intermediate is a short-lived free radical able to abstract hydrogen atoms from the C-1' and C-5' positions of deoxyribose. Attack occurs mostly (68%) at the C-1' position, producing a lesion whose properties are consistent with those of (oxidized) apyrimidinic sites.

Characterization of intracellular DNA strand breaks induced by neocarzinostatin in Escherichia coli cells

DNA strand breaks induced by Neocarzinostatin in Escherichia coli cells have been characterized. Radioactively labeled phage lambda DNA was introduced into lysogenic host bacteria allowing the phage DNA to circularize into superhelical molecules. After drug treatment DNA single- and double-strand breaks were measured independently after neutral sucrose gradient sedimentation. The presence of alkali-labile lesions was measured in parallel in alkaline sucrose gradients. The cell envelope provided an efficient protection towards the drug, since no strand breaks were detected unless the cells were made permeable with toluene or with hypotonic Tris buffer. In permeable cells, no double strand breaks could be detected, even at high NCS concentration (100 micrograms/ml). Induction of single-strand breaks leveled off after 15 min at 20 degrees C in the presence of 2 mM mercaptoethanol. Exposure to 0.3N NaOH doubled the number of strand breaks. No enzymatic repair of the breaks could be observed.

Gamma-radiolysis study of the reductive activation of neocarzinostatin by the carboxyl radical

The activation of the antitumor protein antibiotic neocarzinostatin (NCS) by the carboxyl radical CO-2, a one-electron donor obtained selectively from gamma-ray irradiation of nitrous oxide-saturated formate buffer, has been investigated in the presence and in the absence of DNA at pH 4.7 and pH 7.0. The reaction of NCS with CO-2 in the absence of DNA is followed by a marked red shift (420----441 nm) and a pronounced increase (X 8.8) of the fluorescence emission corresponding to the naphthalene moiety of the NCS chromophore. The light absorption spectrum shows in parallel a hypochromic change with considerable fine structure throughout the 250-400 nm wavelength range. When DNA is present, the fluorescence intensity at completion of the reaction is slightly reduced (by 5 to 15 per cent) and the maximum emission wavelength shifted to 436-438 nm. However, the bulk rate of reaction is not altered by DNA and is independent of the pH, of the temperature and of the concentration of NCS. The NCS concentration-independence of the reaction rate is consistent with a high intrinsic rate (k greater than 10(8)M-1 . s-1) for the reaction of CO-2 with the NCS chromophore. Complete reduction of the NCS chromophore involves a total of three electron-equivalents. The final product does not react with oxygen, shows no odd electron spin, and is unable to induce DNA strand scission. Its molecular state, however, is fundamentally different when gamma-ray irradiations are performed with DNA. This bears evidence of short-lived one electron or two-electrons reduced intermediates decaying via non-identical routes depending on the presence of the acceptor DNA. Actually, dose-related strand breaks appear in DNA exposed to the action of NCS and CO-2. Some NCS chromophore-DNA covalent adducts are also found. DNA strand breakage by CO-2-activated NCS is correlated with thymine release and is inhibited by a redox-stable intercalating agent. The DNA-nicking process thus bears resemblance to that reported by other authors using mercaptans to initiate reductive activation of the NCS chromophore. However, some spectral differences are observed between the CO-2-reacted and the thiol-treated chromophores. Moreover, thymine release and strand scission in DNA incubated with CO-2 and NCS proceed under anaerobic conditions. It is proposed that the strict oxygen requirement for DNA damage by NCS in the presence of mercaptans is due, at least partly, to competition between oxygen and thiols for reaction with the same primary deoxyribose radical resulting from DNA attack by the reductively activated NCS chromophore.

Mode of inhibition of DNA replication in neocarzinostatin-treated HeLa cells

The effect of antitumor antibiotic neocarzinostatin on DNA replication in HeLa cells was studied by pulse-labeling of DNA with [3H]thymidine and sedimentation analysis of the DNA with alkaline sucrose gradients. The drug, which produced DNA damage, primarily inhibited the replicon initiation in the cells at low doses (less than or equal to 0.1 microgram/ml), and at high doses (greater than or equal to 0.5 microgram/ml) inhibited the DNA chain elongation. An analysis of the number of single-strand breaks of parental DNA, induced by neocarzinostatin, indicated that inhibition of the initiation occurred with introduction of single-strand breaks of less than 1.5 . 10(4)/cell, while inhibition of the elongation occurred with introduction of single-strand breaks of more than 7.5 . 10(4)/cell. Assuming that the relative molecular mass of DNA/HeLa cell was about 10(13) Da, the target size of DNA for inhibition of replicon initiation was calculated to be about 10(9) Da, such being close to an average size of loop DNA in the cell and for inhibition of chain elongation, 1-2 . 10(8) Da which was of the same order of magnitude as the size of replicons. Recovery of inhibited DNA replication by neocarzinostatin occurred during post-incubation of the cells and seemed to correlate with the degree of rejoining of the single-strand breaks of parental DNA. Caffeine and theophylline enhanced the recovery of the inhibited replicon initiation, but did not aid in the repair of the breaks in parental DNA.

On the mechanism of reductive activation in the mode of action of some anticancer drugs

Bioactivation of a number of DNA-specific antitumor drugs depends on oxidoreduction. Bleomycin, neocarzinostatin and anthracycline glycosides are the best known among such drugs in terms of reductive activation processes. Their reduction results in short-lived radical or electrophilic intermediates attacking DNA stereospecifically. The physico-chemical properties of these drugs and the nature of DNA damage are reviewed. Models for DNA-intercalation, electron-donor systems involved in drug metabolisation, and the role of oxygen in radical reactions, are discussed in the light of recent reports.

Postreplication repair in Neurospora crassa

Changes in the molecular weight of nascent DNA made after ultraviolet (UV) irradiation have been studied in the excision-defective Neurospora mutant uvs-2 using isotopic pulse labeling, alkaline gradient centrifugation and alkaline filter elution. Both the size of nascent DNA and the rate of incorporation of label into DNA was reduced by UV light in a dose dependent manner. However, this DNA repair mutant did recover the ability to synthesize control-like high molecular weight DNA 3 hours after UV treatment, although the rate of DNA synthesis remained depressed after the temporary block to elongation (or ligation) had been overcome. Photoreactivation partially eliminated the depression of DNA synthesis rate and UV light killing of cells, providing strong evidence that the effects on DNA synthesis and killing were caused by pyrimidine cyclobutane dimers. The caffeine inhibition repair studies performed were difficult to quantitate but did suggest either partial inhibition of a single repair pathway or alternate postreplication DNA repair pathways in Neurospora. No enhancement in killing was detected after UV irradiation when cells were grown on caffeine containing plates.

Degradation of HeLa cell chromatin by neocarzinostatin and its chromophore

Chromatin is the in vivo target site for neocarzinostatin, a DNA strand scission antitumor drug. The effect of neocarzinostatin and its active chromophore component on HeLa cell chromatin is described here. Chromatin consisting of a mixture of mono-, di-, tri- and larger nucleosome fragments is prepared by micrococcal nuclease digestion of HeLa cell nuclei. Drug-induced conversion of chromatin to smaller sized fragments is measured by electrophoresis of the DNA on non-denaturing 4% polyacrylamide gels. Chromatin breakdown measured under these conditions is double-stranded in nature. In the presence of 2 mM dithiothreitol, neocarzinostatin causes degradation of large chromatin fragments and a loss of distinct nucleosome peaks. Detection of chromatin breakdown by neocarzinostatin is dependent upon the concentration of chromatin in the assay. When chromatin is increased from 14 to 70 micrograms/ml, changes in the larger fragments caused by 100 micrograms/ml neocarzinostatin become less obvious are are almost undetectable at 140 micrograms/ml chromatin. No change is observed when chromatin is treated with either neocarzinostatin or its chromophore in the absence of dithiothreitol. For detectable levels of chromatin degradation, 10 micrograms/ml neocarzinostatin is required compared to only 2.5 microgram/ml chromosome (expressed in microgram equivalent neocarzinostatin). Such degradation also occurs more rapidly with chromophore than with neocarzinostatin. Digestion of chromatin with neocarzinostatin continues for at least 30 min at 37 degrees C, while similar degradation caused by chromophore is complete in 1 min. Neocarzinostatin levels which actively degrade isolated chromatin can also effect release of soluble chromatin from intact nuclei. The released chromatin can serve as a substrate for micrococcal nuclease digestion. Such chromatin studies should prove useful in characterizing the mechanism of action of DNA reactive drugs such as neocarzinostatin.

Contrasts in the actions of protein antibiotics on deoxyribonucleic acid structure and function

The protein antibiotics neocarzinostain (NCS), macromomycin (MCR), and auromomycin (AUR), which is closely related to MCR, have been compared for their in vitro and in vivo actions on deoxyribonucleic acid (DNA). NCS, markedly stimulated by 2-mercaptoethanol, is much more active in inducing strand scissions in superhelical pMB9 and linear duplex lambda DNA than AUR, which is slightly inhibited by 2-mercaptoethanol. Purified MCR, even at very high levels, does not give any significant amount of cutting with either DNA substrate. 2-Propanol stimulates the activity of NCS but inhibits that of AUR. On the other hand, the antioxidant alpha-tocopherol strongly inhibits DNA breakage by both drugs. The intercalating drugs ethidium bromide, daunorubicin, proflavin, and actinomycin D at low concentrations inhibit DNA scission by AUR. The levels of intercalators required to inhibit NCS activity to comparable levels are about 10 times higher than those for AUR. Although MCR has virtually no in vitro DNA cutting activity, it is, like AUR and NCS, cytotoxic, as measured by the inhibition of DNA synthesis and induction of DNA strand breakage in HeLa cells.