Oxaliplatin-induced damage of cellular DNA.

Damage to cellular DNA is believed to determine the antiproliferative properties of platinum (Pt) drugs. This study characterized DNA damage by oxaliplatin, a diaminocyclohexane Pt drug with clinical antitumor activity. Compared with cisplatin, oxaliplatin formed significantly fewer Pt-DNA adducts (e.g., 0.86+/-0.04 versus 1.36+/- 0.01 adducts/10(6) base pairs/10 microM drug/1 h, respectively, in CEM cells, P<.01). Oxaliplatin was found to induce potentially lethal bifunctional lesions, such as interstrand DNA cross-links (ISC) and DNA-protein cross-links (DPC) in CEM cells. As with total adducts, however, oxaliplatin produced fewer (P<.05) bifunctional lesions than did cisplatin: 0.7+/-0.2 and 1.8+/-0.3 ISC and 0.8+/-0.1 and 1.5+/-0.3 DPC/10(6) base pairs/10 microM drug, respectively, after a 4-h treatment. Extended postincubation (up to 12 h) did not compensate the lower DPC and ISC levels by oxaliplatin. ISC and DPC determinations in isolated CEM nuclei unequivocally verified that oxaliplatin is inherently less able than cisplatin to form these lesions. Reactivation of drug-treated plasmids, observed in four cell lines, suggests that oxaliplatin adducts are repaired with similar kinetics as cisplatin adducts. Oxaliplatin, however, was more efficient than cisplatin per equal number of DNA adducts in inhibiting DNA chain elongation ( approximately 7-fold in CEM cells). Despite lower DNA reactivity, oxaliplatin exhibited similar or greater cytotoxicity in several other human tumor cell lines (50% growth inhibition in CEM cells at 1.1/1.2 microM, respectively). The results demonstrate that oxaliplatin-induced DNA lesions, including ISC and DPC, are likely to contribute to the drug's biological properties. However, oxaliplatin requires fewer DNA lesions than does cisplatin to achieve cell growth inhibition.

Region-specific DNA damage by AT-specific DNA-reactive drugs is predicted by drug binding specificity.

Bizelesin and adozelesin are DNA-reactive antitumor drugs that alkylate adenines at the 3' ends of their preferred binding sites [5'T(A/T)(4)A3'and 5'(A/T)(3)(-4)A3', respectively]. We used these drugs to examine the determinants for region-specific damage of human genomic DNA. The distribution of bizelesin binding motifs in several regions analyzed "in silico" correlated well with the experimentally determined lesions in these regions assessed by quantitative polymerase chain reaction (QPCR) stop assay. In contrast to the typically low motif density, clusters of potential bizelesin binding sites were found in the matrix-associated regions (MAR domains) of the c-myc and apolipoprotein B (apoB) genes. Accordingly, lesions induced by bizelesin in these domains (2.13 and 7.06 lesions kbp(-1) microM(-1), respectively) markedly exceeded lesions in bulk DNA (0.87 lesions kbp(-1) microM(-1)) or in regions with typically low motif density (e.g., 0.75 and 0.87 lesions kbp(-1) microM(-1) in a beta-globin gene and c-myc origin of replication regions, respectively). Consistent with the more frequent, less localized adozelesin motif, actual lesions induced by adozelesin exceeded by severalfold lesions by bizelesin in four selected regions (within the c-myc and HPRT loci). Whereas adozelesin is likely to affect similar regions as bizelesin, adozelesin's more promiscuous binding probably compromises its relative specificity for such targets. In contrast, findings for bizelesin provide for the first time a proof of principle that a small molecular weight drug can preferentially damage specific regions in cellular DNA. Targeting of critical repetitive sequences, such as AT-rich MAR domains, which allow for clustering of drug binding motif, can be the paradigm for region specificity of small molecular weight agents.

Tallimustine lesions in cellular DNA are AT sequence-specific but not region-specific.

Tallimustine (FCE 24517) is an AT-specific alkylating antitumor derivative of distamycin. This study examined levels of tallimustine lesions in intracellular DNA, their sequence- and region-specificity, and the long-range distribution of the drug binding motif. Tallimustine adducts in DNA converted to strand breaks by heating allowed the quantitation of drug lesions. In bulk DNA of intact human leukemia CEM cells, tallimustine formed 0.15 +/- 0.04 and 0.64 +/- 0.18 lesions/kbp at 5 and 50 microM, respectively. These lesions represent monoadducts as no interstrand cross-links or DNA-protein cross-links were detected. Tallimustine adducts in intracellularly treated DNA showed a general preference for sequences with T-tracts, suggesting a propensity for intrinsically bent motifs. Major drug-adducted sites identified by repetitive primer extension, included 5'-TTTTGPu-3' and 5'-TTTTGC-3' motif. Despite the high specificity at the nucleotide level, tallimustine did not differentiate among bulk DNA and three discrete AT-rich regions of genomic DNA examined by quantitative PCR stop assay with lesion frequencies ranging from 0.23 to 0.39 lesions/kbp at 25 microM drug. In comparisons of lesion frequencies and cytotoxicity, tallimustine adducts are approximately 50 times more lethal than relatively nonsequence specific cisplatin adducts but are >100 times less lethal than lesions by an unrelated AT-specific drug, bizelesin. However, the 5'-TTTTGPu-3' motifs targeted by tallimustine are relatively infrequent and scattered throughout the genome. In contrast, the motifs 5'-T(A/T)(4)A-3' motifs targeted by bizelesin, while also infrequent, cluster in defined AT-rich islands. The lack of region-specificity may be the reason tallimustine adducts, despite high AT-specificity at the nucleotide level, are less lethal than region-specific bizelesin adducts.

Drug uptake and cellular targets of hydroxymethylacylfulvene (HMAF).

Hydroxymethylacylfulvene (HMAF, MGI 114) is a novel antitumor drug and a potent pro-apoptotic agent that has the potential to alkylate cellular nucleophiles. The objective of these studies was to characterize drug uptake and cellular targets for drug binding in human leukemia CEM cells. The uptake of [14C]HMAF had two components: a rapid phase (0-10 min) and a slow phase. At 10 microM drug (37 degrees), the rapid and slower phase amounted to 0.86 and 0.13 pmol/min/10(6)cells, respectively. HMAF uptake was inhibited 82% by low temperature (4 degrees) at 4 hr. Cell-associated HMAF localized to nuclear (50%), cytoplasmic (37%), and membrane fractions (10%). Continued drug uptake appeared to be driven by covalent binding to cellular macromolecules. Approximately 1/4 and 2/3 of cell-associated HMAF formed covalent adducts after 10 min and 4 hr, respectively, as found by perchloric acid precipitation. Drug adducts were not readily reversible; 77% of the covalently bound radiolabel was retained by the cells 20 hr after drug treatment. Combinations of DNase, RNase, and proteinase K with perchloric acid precipitation showed that approximately 60, 30, and 10% of the covalently bound drug was associated with the protein, DNA, and RNA fractions, respectively. Incubation of 100 microM [14C]HMAF (24 hr) with purified DNA, serum albumin, thioredoxin, and thioredoxin reductase resulted in 6, 22, 14, and 11 pmol [14C]HMAF/microg DNA or protein, respectively. Results indicate that multiple targets for HMAF binding may contribute to the pro-apoptotic and antiproliferative action of the drug.

Feeding stimulants activate an identified dopaminergic interneuron that induces the feeding motor program in Helisoma.

The neurotransmitter dopamine is shown to play a fundamental role in the generation of the feeding motor pattern and resultant feeding behavior in Helisoma. Application of exogenous dopamine triggered the fictive feeding motor pattern in the isolated CNS and triggered feeding movements in semi-intact preparations. Application of feeding stimulants to the oral cavity excited the putatively dopaminergic buccal interneuron N1a, and depolarization of interneuron N1a triggered the production of the fictive feeding motor pattern. The ability of dopamine superfusion and of interneuron N1a stimulation to activate the fictive feeding motor pattern was blocked by the dopamine antagonist sulpiride. The phase of the fictive feeding motor pattern was reset by brief hyperpolarization of interneuron N1a, demonstrating that interneuron N1a is an integral component of the buccal central pattern generator (CPG). During spontaneous fictive feeding patterns, prolonged hyperpolarizations of interneuron N1a inhibited the production of patterned activity. Exogenous dopamine maintained the fictive feeding motor pattern in the absence of interneuron N1a activity. Interneuron N1a was labeled by the formaldehyde-glutaraldehyde histochemical technique, which is indicative of the presence of dopamine in mollusks. These data suggest that interneuron N1a is an endogenous source of the neuromodulator dopamine, intrinsic to the buccal CPG, and that interneuron N1a has a prominent role in the sensory-motor integration triggering the consummatory response.

Effect of atropine sulfate on tear production in the cat when used with ketamine hydrochloride and acetylpromazine maleate.

Schirmer I tear tests were done on 10 cats before and during anesthesia induced with ketamine hydrochloride in combination with acetylpromazine maleate, with and without atropine sulfate as a preanesthetic agent. Use of atropine sulfate alone decreased tear production from a mean base-line value of 16.9 +/- 3.7 mm/min to 8.2 +/- 4.9 mm/min, 10 minutes after its subcutaneous administration. Tear production continued to decrease from 8.2 +/- 4.9 mm/min to a mean of 2.3 +/- 2.5 mm/min at 30 minutes after the administration of the ketamine hydrochloride and acetylpromazine maleate combination.