Long-term T cell memory to human leucocyte antigen-A2 supertype epitopes in humans vaccinated against smallpox.

Identification of human leucocyte antigen (HLA) class I-restricted T cell epitopes is important to develop methods to track the evolution of T cell memory to new generation smallpox vaccines and allow comparison to older vaccinia virus preparations known to induce protection against smallpox. We evaluated the relative predictive values of four computational algorithms to identify candidate 9-mer HLA-A2 supertype epitopes that were confirmed to stimulate preferentially T cell interferon (IFN)-gamma responses by subjects last vaccinated with Dryvax 27-54 years previously. Six peptides encoded by I4L, G1L, A8R, I8R, D12L and H3L open reading frames that were identical for Vaccinia (Copenhagen), Variola major (Bangledesh 1975) and modified vaccinia Ankara strain preferentially stimulated IFN-gamma responses by healthy HLA-A2 supertype adults last given Dryvax 27-49 years earlier relative to remotely vaccinated non-HLA-A2 supertype and unvaccinated HLA-A2 supertype adults. Combining results from at least two computational algorithms that use different strategies to predict peptide binding to HLA-A2 supertype molecules was optimal for selection of candidate peptides that were confirmed to be epitopes by recall of T cell IFN-gamma responses. These data will facilitate evaluation of the immunogenicity of replication incompetent smallpox vaccines such as modified vaccinia Ankara and contribute to knowledge of poxvirus epitopes that are associated with long-lived T cell memory.

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.

Adozelesin triggers DNA damage response pathways and arrests SV40 DNA replication through replication protein A inactivation.

The cyclopropylpyrroloindole anti-cancer drug, adozelesin, binds to and alkylates DNA. Treatment of human cells with low levels of adozelesin results in potent inhibition of both cellular and simian virus 40 (SV40) DNA replication. Extracts were prepared from adozelesin-treated cells and shown to be deficient in their ability to support SV40 DNA replication in vitro. This effect on in vitro DNA replication was dependent on both the concentration of adozelesin used and the time of treatment but was not due to the presence of adozelesin in the in vitro assay. Adozelesin treatment of cells was shown to result in the following: induction of p53 protein levels, hyperphosphorylation of replication protein A (RPA), and disruption of the p53-RPA complex (but not disruption of the RPA-cdc2 complex), indicating that adozelesin treatment triggers cellular DNA damage response pathways. Interestingly, in vitro DNA replication could be rescued in extracts from adozelesin-treated cells by the addition of exogenous RPA. Therefore, whereas adozelesin and other anti-cancer therapeutics trigger common DNA damage response markers, adozelesin causes DNA replication arrest through a unique mechanism. The S phase checkpoint response triggered by adozelesin acts by inactivating RPA in some function essential for SV40 DNA replication.

Bizelesin, a bifunctional cyclopropylpyrroloindole alkylating agent, inhibits simian virus 40 replication in trans by induction of an inhibitor.

Bizelesin, a bifunctional DNA minor groove alkylating agent, inhibits both cellular and viral (SV40) DNA replication in whole cells. Bizelesin inhibition of SV40 DNA replication was analyzed in SV40-infected cells, using two-dimensional (2D) neutral agarose gel electrophoresis, and in a cell-free SV40 DNA replication assay. Within 1 h of bizelesin addition to infected cells, a similar rapid decrease in both the level of SV40 replication intermediates and replication activity was observed, indicating inhibition of initiation of SV40 DNA replication. However, prolonged bizelesin treatment (>/=2 h) was associated with a reduced extent of elongation of SV40 replicons, as well as the appearance on 2D gels of intense spots, suggestive of replication pause sites. Inhibition of elongation and induction of replication pause sites may result from the formation of bizelesin covalent bonds on replicating SV40 molecules. The level of in vitro replication of SV40 DNA also was reduced when extracts from bizelesin-treated HeLa cells were used. This effect was not dependent upon the formation of bizelesin covalent bonds with the template DNA. Mixing experiments, using extracts from control and bizelesin-treated cells, indicated that reduced DNA replication competence was due to the presence of a trans-acting DNA replication inhibitor, rather than to decreased levels or inactivation of essential replication factor(s).

C-1027-induced alterations in Epstein-Barr viral DNA replication in latently infected cultured human Raji cells: relationship to DNA damage.

This study is the first detailing drug-induced changes in EBV DNA replication intermediates (RIs). Both EBV replication inhibition and damage induction were studied in latently infected human Raji cells treated with the enediyne DNA strand-scission agent C-1027. Analysis of RIs on two-dimensional agarose gels revealed a rapid loss in the EBV bubble arc. When elongation of nascent chains was blocked by aphidicolin, this loss was inhibited, suggesting that C-1027-induced disappearance of RIs was related to maturation of preformed replication molecules in the absence of initiation of new RIs. C-1027 damage to EBV DNA was limited at concentrations where loss of the bubble arc was nearly complete, and none was detected within the replicating origin (ori P)-containing fragment, indicating that replication inhibition occurred in trans. By contrast, the non-nuclear mitochondrial genome was insensitive to replication inhibition but highly sensitive to damage induced by C-1027. C-1027-induced trans inhibition of nuclear but not mitochondrial DNA replication is consistent with a cell cycle checkpoint response to a DNA-damaging agent. EBV replication and Raji cell growth were inhibited at equivalent C-1027 doses.

DNA-damaging enediyne C-1027 inhibits initiation of intracellular SV40 DNA replication in trans.

This study used 2-D agarose gel techniques to examine the effects of the DNA-strand scission enediyne C-1027 on DNA replication in SV40-infected BSC-1 cells. Replication of SV40 DNA was inhibited by C-1027 to a greater extent than was BSC-1 genomic DNA replication in infected cells. Low nanomolar concentrations (0.2-10 nM) of C-1027 affected a rapid, progressive decrease in SV40 replication activity and replication intermediates (RIs) within 15 min after drug addition. A concurrent decrease in the signal of both the SV40 bubble arc and replication activity with increasing concentrations of C-1027 suggested that C-1027 inhibited initiation of new RIs. Additionally, the reduction in bubble arc signal observed with C-1027 was prevented when elongation of nascent chains was blocked by aphidicolin. Thus, the C-1027-induced disappearance of RIs probably is related to the maturation of preformed replication molecules in the absence of initiation of new RIs. Strand damage to SV40 DNA was barely detectable at concentrations where inhibition of replication activity was nearly complete, indicating that C-1027 replication inhibition occurs in trans.

Effects of bizelesin (U-77779), a bifunctional alkylating minor groove agent, on genomic and simian virus 40 DNA.

Bizelesin is a bifunctional covalent minor groove binding agent which forms adducts with 3'-adenines on opposite DNA strands. DNA lesions induced by bizelesin in genomic DNA of BSC-1 cells, as well as intracellular and purified simian virus 40 (SV40) DNA, were examined. Alkaline sucrose sedimentation analysis indicated a nonrandom distribution of heat-labile damage in BSC-1 cell genomic DNA with frequencies of 1-60 lesions/10(6) base pairs (bp) for bizelesin concentrations from 10 to 400 nM, respectively. Extrapolation of these data suggested that, at 0.15 nM bizelesin, approximately 10(2) adducts per cell may be sufficient to inhibit cell growth by 90% (D10). While the frequency of bizelesin adducts in intracellular SV40 DNA was comparable to that in genomic DNA, higher levels of lesion formation are observed with purified SV40 DNA. Chromatin structure has little effect on localization of bizelesin adducts since treatment of either infected cells or purified SV40 DNA reveals a similar pattern of drug-induced damage. Bizelesin adduction sites (mapped on the SV40 genome as thermally-induced strand breaks at 50-100 bp resolution) are found in regions centered at 4200, 3900, 4700, and approximately 5200. The location of these regions of intense bizelesin bonding coincides with the sites of potential cross-links predicted using the 5'-T-(A/T)4-A-3' sequence. The analysis of bizelesin adducts at the sequence level in the 3943-4451 SV40 DNA fragment indicated that 40% of total damage was in potential cross-linking sites and an additional 35% in the 5'-A-(A/T)4-A-3' monoalkylating sites.(ABSTRACT TRUNCATED AT 250 WORDS)

Effects of the DNA-damaging enediyne C-1027 on intracellular SV40 and genomic DNA in green monkey kidney BSC-1 cells.

This study describes the selective ability of C-1027 to induce limited double-strand damage in a viral DNA target. The effect of the cellular environment on C-1027 activity was examined by assaying the extent, as well as the specificity, of damage to simian virus 40 (SV40) DNA in lytically infected mammalian BSC-1 cells and in purified SV40 DNA preparations. C-1027 damage to intracellular SV40 DNA was quantitated by topological forms conversion analysis. A gradual decrease in intracellular supercoiled form I accompanied by an increase in form III was observed with C-1027 concentrations from 2 to 100 nM, with a 50% reduction in form I observed at 50 nM. Damage to purified SV40 DNA also was most pronounced between 10 and 100 nM C-1027. When concentrations were expressed as r values (drug/DNA molar ratio), the amount of C-1027 necessary to effect a 50% reduction in form I was lower for intracellular (r = 0.002) than for purified SV40 DNA (r = 0.0035). Double-strand damage was more likely to occur with C-1027 treatment of intracellular compared to purified SV40 DNA. However, with both purified and intracellular DNA, restriction enzyme digestion analysis revealed double-strand damage at a number of specific sites throughout the genome, particularly within the early region of the SV40 genome (e.g., within the coding sequence for large T-antigen). No significant damage was observed in either the origin (ORI) or the termination (TER) regions of SV40 replication. The extent of C-1027 damage to uninfected BSC-1 cell DNA was also quantitated using pulsed-field gel electrophoresis. At 0.1 nM (r = 2.8 x 10(-5), where incorporation of [3H]thymidine was reduced by 80%, 600 rad equiv of damage was detected in uninfected BSC-1 cells. At C-1027 r values from 1 x 10(-4) to 40 x 10(-4), double-strand breaks were from 80- to 40-fold more frequent in SV40 than in BSC-1 cell genomic DNA. By contrast, 50-fold more drug was necessary to inhibit intracellular SV40 DNA accumulation compared to [3H]thymidine incorporation into uninfected BSC-1 cells. Thus, SV40 DNA synthesis appeared to be less sensitive to C-1027-induced lesions than replication in uninfected BSC-1 cells.

CC-1065 bonding to intracellular and purified SV40 DNA: site specificity and functional effects.

CC-1065 is a minor-groove bonding agent capable of forming covalent adducts with the N-3 position of adenines within A-T-rich regions of duplex DNA. By examining the formation and location of CC-1065 adducts within the simian virus 40 (SV40) DNA molecule, the present study marks the first time that the precise sites of CC-1065 lesions have been identified at the level of eukaryotic genomic DNA. In naked DNA preparations, r values (moles of drug/mole of nucleotide base pair) > or = 0.0015 effected, after thermal treatment, a measurable decrease in intact supercoiled form I, as well as increases in forms II and III, indicating that both single-strand and apparent double-strand damage had occurred. A similar pattern of damage was observed in SV40-infected cells, albeit at higher CC-1065 levels. The amount of CC-1065 required to produce a 50% loss in form I was > 2-fold higher in infected cells (r = 0.029) than with purified DNA samples (r = 0.013). The appearance of double-strand damage at low drug levels suggested a high specificity of CC-1065 bonding to localized regions of the genome. The precise location of these CC-1065 adduction sites was examined by three methods: sequence analysis of the entire genome (GenBank), DNA polymerase termination assay of specific fragments of SV40, and restriction enzyme digestion analysis of the entire SV40 molecule. When sequence analysis of the entire genome was performed by examining both strands for the presence of the consensus CC-1065 binding sequence 5'-A/T-A/T-A/T-A/T-A*-3'[Reynolds et al. (1985) Biochemistry 24, 6228-6247], 294 single-strand adduction sites were predicted, compared to 20 sites where CC-1065 should bond to both strands within a 30-base-pair window and at which, when heated, a double-strand break should occur. DNA polymerase termination assay of actual adduction sites was performed on restriction fragments of SV40 DNA pretreated with CC-1065 in infected cells or in purified supercoiled DNA preparations and selected on the basis of the sequence analysis (i.e., regions 2510-2730, 3701-3920, 4400-4659, 4020-4320, and 5163-65). In general, double-strand lesions were detected in similar regions of the genome by the DNA termination assay and by sequence analysis. When restriction enzyme digestion and the DNA polymerase termination assay were compared throughout the genome, nearly identical patterns of adduct formation were observed. Interestingly, similar alkylation patterns were observed with either naked or infected cell DNA.(ABSTRACT TRUNCATED AT 400 WORDS)

Effects of analogs of the DNA minor groove binder Hoechst 33258 on topoisomerase II and I mediated activities.

By contrast with other DNA minor groove binders, Hoechst 33258 inhibited topoisomerase-mediated activity in intact cells. To determine whether specific structural alterations could modify the topoisomerase reactivity of this drug, a series of analogs of Hoechst 33258 (compound 1) was examined. When the relative DNA binding affinities (Ka) of these agents were determined, compound 1 had the highest Ka while agents with substitutions in either of the benzimidazole moieties showed reduced affinity. Whether these changes in DNA binding correlated with topoisomerase inhibitory potency was next examined. In isolated nuclei, 25 microM of agents 1, 5 and 7 reduced VM-26 induced cross-links by 64, 65 and 83%, compared with 15 to 25% reductions by agents 2, 3, 4 and 6, respectively. The structural modification common to the less active compounds was the substitution of an oxygen for nitrogen at either position 1 or 2. On the basis of these results, agents 1, 2, 3 and 7, representing a range of inhibitory potency, were chosen for further analyses. Cross-link induction by m-AMSA and camptothecin in isolated nuclei, as well as by VM-26 in intact cells, was inhibited to a greater extent by agents 1 and 7 than 2 or 3. Additionally, all four drugs inhibited relaxation of pBR 322 DNA induced by both topoisomerases, although topoisomerase I was 2 to 5-fold more sensitive than topoisomerase II. A linear correlation was observed between the logarithms of the Ka value of compounds 1, 2 and 3 and their IC25 values for both topoisomerases, suggesting a strong dependence on DNA binding affinity for enzyme inhibition. Nevertheless, agent 7, despite having less affinity for calf thymus DNA than 1, was the most potent topoisomerase inhibitor tested in intact cells and in isolated enzyme systems. Thus, retention of nitrogen at positions 1 and 2 as well as the addition of nitrogen at position 16 was associated with increased topoisomerase inhibitory potency.

Effects of minor groove binding drugs on camptothecin-induced DNA lesions in L1210 nuclei.

Topoisomerase I inhibition detected in mammalian cells can be correlated with reduced tumor growth. Camptothecin specifically inhibits topoisomerase I by stabilization of a covalently linked DNA-enzyme complex and associated DNA single-strand breaks. Whether perturbations in nuclear DNA structure can alter camptothecin-induced DNA damage was examined using the non-intercalative DNA minor groove binders distamycin, Hoechst 33258 and DAPI (4',6-diamidino-2-phenylindole). L1210 nuclei were treated with camptothecin alone or in the presence of single minor groove binders. DNA-protein crosslinks and single-strand breaks were determined using potassium-sodium dodecyl sulfate precipitation and alkaline elution respectively. Distamycin produced a dose-dependent decrease in DNA-protein crosslinks and strand breaks. This effect was reduced if nuclei were treated with camptothecin prior to distamycin addition. Distamycin was unable to reverse lesions once induced or to prevent repair of damage upon camptothecin removal. Hoechst 33258 and DAPI also decreased camptothecin-induced DNA damage. The order of inhibitory potency was: distamycin greater than Hoechst greater than DAPI. This order corresponded to the molecular weights as well as to the size of the nucleotide binding sites of the drugs. Identifying agents which alter such DNA lesions should provide better understanding of the chemotherapeutic activity of camptothecin as well as help elucidate new leads for drug combinations of improved therapeutic benefit.

Effect of minor groove binding drugs on mammalian topoisomerase I activity.

Three minor groove binding drugs, distamycin A, bisbenzimide (Hoechst 33258) and 4',6-diamidino-2-phenylindole (DAPI), were examined for their abilities to modulate the activity of topoisomerase I purified from L1210 cells. At 0.5 and 1.0 microM, distamycin stimulated topoisomerase I relaxation of supercoiled DNA by 38 and 13%, respectively, while increasing the drug concentration above 2.0 microM resulted in inhibition. Inhibition was reversible. Complete relaxation could be achieved even in the presence of inhibitory concentrations of distamycin if the incubation time with topoisomerase I was increased from 7.5 to 120 min. The velocity of topoisomerase I mediated relaxation was reduced by 2 microM distamycin at DNA levels ranging from 350 to 2000 ng/reaction. Hoechst 33258 and DAPI inhibited topoisomerase I relaxation in a concentration-dependent manner. Hoechst 33258 and distamycin were equivalent in their abilities to inhibit topoisomerase I, whereas DAPI had a lesser effect (e.g. relaxation was reduced by 50% with 2.7 microM distamycin and 2.8 microM Hoechst 33258 compared to 5 microM DAPI). This study suggests that ligand binding in the minor groove can be a factor in the regulation of topoisomerase I activity.

Assessment of preferential cleavage of an actively transcribed retroviral hybrid gene in murine cells by deoxyribonuclease I, bleomycin, neocarzinostatin, or ionizing radiation.

Preferential cleavage induced by bleomycin, neocarzinostatin, or ionizing radiation in a transcribed cellular gene was evaluated through comparisons with deoxyribonuclease I. The glucocorticoid-inducible LTL gene (a hybrid viral gene derived from mouse mammary tumor virus DNA) previously described [Zaret, K. S., & Yamamoto, K. R. (1984) Cell (Cambridge, Mass.) 38, 29-38] served as the specific DNA target. A Southern blot analysis was used to specifically assess cleavage of the LTL gene in nuclei isolated from cells either treated or untreated with the synthetic glucocorticoid dexamethasone. Hypersensitivity of the gene to bleomycin or neocarzinostatin, which paralleled deoxyribonuclease I hypersensitivity, was evident only in nuclei isolated from dexamethasone-treated cells. Like deoxyribonuclease I, sites of dexamethasone-inducible drug hypersensitivity were coincident with the binding region for the glucocorticoid receptor found within the regulatory sequences of the LTL gene. In contrast, no hypersensitivity to ionizing radiation was evident. Although bleomycin and neocarzinostatin showed qualitatively similar preferences for the transcribed LTL gene, quantitative evaluations of damage to total cellular DNA by filter elution showed that the relative specificity of bleomycin for the hypersensitive region was much less than that of either deoxyribonuclease I or neocarzinostatin.

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.