The interaction of adriamycin and its beta anomer with DNA

Folic Acid-Decorated β-Cyclodextrin-Based Poly(ε-caprolactone)-dextran Star Polymer with Disulfide Bond-Linker as Theranostic Nanoparticle for Tumor-Targeted MRI and Chemotherapy

β-cyclodextrin(βCD)-based star polymers have attracted much interest because of their unique structures and potential biomedical and biological applications. Herein, a well-defined folic acid (FA)-conjugated and disulfide bond-linked star polymer ((FA-Dex-SS)-βCD-(PCL)₁₄) was synthesized via a couple reaction between βCD-based 14 arms poly(ε-caprolactone) (βCD-(PCL)₁₄) and disulfide-containing α-alkyne dextran (alkyne-SS-Dex), and acted as theranostic nanoparticles for tumor-targeted MRI and chemotherapy. Theranostic nanoparticles were obtained by loading doxorubicin (DOX), and superparamagnetic iron oxide (SPIO) particles were loaded into the star polymer nanoparticles to obtain ((FA-Dex-SS)-βCD-(PCL)₁₄@DOX-SPIO) theranostic nanoparticles. In vitro drug release studies showed that approximately 100% of the DOX was released from disulfide bond-linked theranostic nanoparticles within 24 h under a reducing environment in the presence of 10.0 mM GSH. DOX and SPIO could be delivered into HepG2 cells efficiently, owing to the folate receptor-mediated endocytosis process of the nanoparticles and glutathione (GSH), which triggered disulfide-bonds cleaving. Moreover, (FA-Dex-SS)-βCD-(PCL)₁₄@DOX-SPIO showed strong MRI contrast enhancement properties. In conclusion, folic acid-decorated reduction-sensitive star polymeric nanoparticles are a potential theranostic nanoparticle candidate for tumor-targeted MRI and chemotherapy.

Biologic Activity of Daunorubicin Linked to Proteins via the Methylketone Side Chain

New daunorubicin-protein conjugates were prepared by covalently linking the antitumor drug to various test proteins via its methylketone side chain. Attachment of daunorubicin to proteins was achieved by nucleophylic substitution reaction of the 14-bromo derivative of the drug, under mild coupling conditions. In contrast to conventional methods, this procedure did not involve reaction or modification of the amino sugar. As expected, the covalent linkage of the drug was generally associated with an appreciable reduction in the drug cytotoxicity to HeLa cells in vitro. The possible advantages of this method for coupling to specific protein carriers are discussed.

Microvesicles mediate transfer of P-glycoprotein to paclitaxel-sensitive A2780 human ovarian cancer cells, conferring paclitaxel-resistance

The overexpression of P-glycoprotein (P-gp) causes resistance to chemotherapy in human ovarian cancer. However, the underlying mechanism remains unclear. In the present study, we showed that, at membrane-bound protein level, P-gp was 'shared' between human ovarian cancer cells by the intercellular transfer of microvesicles (MVs). Paclitaxel-resistant human ovarian cancer cells (A2780/PTX) readily formed and released P-gp-containing MVs into the extracellular space compared with the wild-type parental line (A2780/WT). Shedding MVs bound to the chemosensitive A2780/WT cells in a time- and dose-dependent manner, transferring P-gp via the microenvironment. MV-mediated transfer of P-gp led to redistribution of the chemotherapeutic drug adriamycin in recipient cells (A2780/WT), which displayed 5- and 5-fold higher resistance to adriamycin and paclitaxel, respectively. Thus, these findings demonstrate a new mechanism of drug-resistance acquisition via MVs.

New insights into the mechanism of the DNA/doxorubicin interaction

Doxorubicin (DOX) is an important anthracycline antibiotic whose intricate features of binding to DNAs, not yet fully understood, have been the object of intense debate. The dimerization equilibrium has been studied at pH = 7.0, I = 2.5 mM, and T = 25 °C. A thermodynamic and kinetic study of the binding of doxorubicin to DNA, carried out by circular dichroism, viscometry, differential scanning calorimetry, fluorescence, isothermal titration calorimetry, and T-jump relaxation measurements, has enabled us to characterize for the first time two different types of calf thymus DNA (ctDNA)/DOX complexes: PD1 for C(DOX)/C(DNA) < 0.3, and PD2 for higher drug content. The nature of the PD1 complex is described better in light of the affinity of DOX with the synthetic copolymers [poly(dA-dT)]2 and [poly(dG-dC)]2. The formation of PD1 has been categorized kinetically as a two-step mechanism in which the fast step is the groove binding in the AT region, and the slow step is the intercalation into the GC region. This bifunctional nature provides a plausible explanation for the high PD1 constant obtained (K1 = 2.3 × 10(8) M(-1)). Moreover, the formation of an external aggregate complex ctDNA/DOX (PD2) at the expense of PD1, with K2 = 9.3 × 10(5) M(-1), has been evinced.

Transient receptor potential channel TRPC5 is essential for P-glycoprotein induction in drug-resistant cancer cells

An attractive strategy to overcome multidrug resistance in cancer chemotherapy is to suppress P-glycoprotein (P-gp), which is a pump overproduced in cancer cells to remove cytotoxic drugs from cells. In the present study, a Ca(2+)-permeable channel TRPC5 was found to be overproduced together with P-gp in adriamycin-resistant breast cancer cell line MCF-7/ADM. Suppressing TRPC5 activity/expression reduced the P-gp induction and caused a remarkable reversal of adriamycin resistance in MCF-7/ADM. In an athymic nude mouse model of adriamycin-resistant human breast tumor, suppressing TRPC5 decreased the growth of tumor xenografts. Nuclear factor of activated T cells isoform c3 (NFATc3) was the transcriptional factor that links the TRPC5 activity to P-gp production. Together, we demonstrated an essential role of TRPC5-NFATc3-P-gp signaling cascade in P-gp induction in drug-resistant cancer cells.

Mechanism of the ultrasonic activation of micellar drug delivery

The mechanism of the ultrasonic enhancement of the uptake of cytotoxic drugs, doxorubicin (DOX) and ruboxyl (Rb) by HL-60 cells from Pluronic micelles was studied. DOX and Rb sorption from either PBS or micellar Pluronic solutions is described by Langmuir-type isotherms characteristic of substrates with limited number of sorption centers. The sorption limits for Rb from PBS and Pluronic were considerably higher than those for DOX, presumably due to much higher Rb partitioning into cell membranes. The overall number of drug sorption centers for both drugs decreased in the presence of Pluronic implying the effect of Pluronic on the DNA conformation, which was confirmed by the electron paramagnetic resonance (EPR) experiments using Rb as a spin probe. Ultrasound increased drug uptake by the cells from PBS and Pluronic solutions. The fluorescence microscopy and flow cytometry experiments using fluorescently-labeled Pluronic showed that ultrasound enhanced both the intracellular uptake of Pluronic micelles and Pluronic trafficking into cell nuclei. A scheme is suggested that describes various equilibria controlling drug/cell interactions and effect of ultrasound on these equilibria. Under the action of ultrasound, the equilibrium between the micellar-encapsulated and free drug is shifted in the direction of free drug due to micelle perturbation; the equilibrium between extracellular and internalized drug is shifted to the intracellular drug due to the ultrasound-induced cellular changes that enhance the accessibility of various cellular structures to drug. An important advantage offered by ultrasound is that the same degree of the intracellular drug uptake may be achieved at a substantially lower drug concentration in the incubation medium.

Role of the sugar moiety in the pharmacological activity of anthracyclines: development of a novel series of disaccharide analogs

The sugar moiety is an essential component of anthracycline antibiotics for their topoisomerase poisoning activity and antitumor efficacy. Since the sugar interacts with the minor groove, modifications in this moiety could enhance the recognition potential of the drug at the target level. Based on this hypothesis, novel anthracyclines, disaccharides lacking the amino group in the first (aglycone-linked) sugar, were designed. The 3'-amino group in the first sugar was replaced by an hydroxyl group, and the second sugar residue was bound to the first sugar via an alpha (1-4) linkage. The cytotoxic and antitumor activities of disaccharide analogs of idarubicin were critically dependent on the optimal (axial) orientation of the second sugar residue. Although configurational requirements of the sugar moiety for optimal drug activity support a critical role of the external (non-intercalating) drug domains in the interaction of anthracyclines with the DNA-topoisomerase (ternary complex), the antitumor efficacy of disaccharide analogs is not fully explained by effects mediated by the nuclear enzyme target. The development of this novel disaccharide series may provide insights for a rational synthesis of anthracycline analogs with improved pharmacological profile.

Efficiency of doxorubicin handling by isolated hepatocytes is a valuable indicator for restored cell function

Pig liver is a possible source of hepatocytes for extracorporeal bio-artificial liver devices. In order to evaluate recovered hepatocyte function following enzymatic isolation, we developed a cytochemical method that is based on the capacity of hepatocytes to sequester the anthracycline antitumour drug doxorubicin within intracellular acidic compartments. Doxorubicin is a naturally fluorescent molecule. Thus, the process of drug concentration within hepatocytes can be visualized in living conditions by fluorescence microscopy. Porcine hepatocytes harvested from heart-beating donors were grown either as isolated cell suspensions or as tissue monolayers. Immediately after isolation and at fixed culture times, cells were incubated with 0.1 mM doxorubicin in Hanks' balanced salt solution for 10 min at 37 degrees C in 5% CO2-humidified atmosphere and observed by fluorescence microscopy. Parallel electron microscopy was performed to compare fluorescence data with general cell morphology. To monitor lysosomal acidification capacity, the fluorescent pH-sensitive vital dye LysoSensor-Blue was used. Doxorubicin fluorescence showed different patterns of nuclear and cytoplasmic staining, according to the time allowed for cell recovery and the culture method. In particular, cytoplasmic fluorescence changed from a diffuse staining, that could be observed after cell isolation and in hepatocyte suspensions, to a punctate perinuclear and pericanalicular fluorescence detectable in fully recovered hepatocyte monolayers. This study indicates that the 'doxorubicin-fluorescence test' may be considered a simple and rapid procedure for assessing hepatocyte functional condition. It may provide valuable and 'real time' guidelines for judging the correct way these cells are to be collected, preserved and utilized for clinical purposes.

Configurational requirements of the sugar moiety for the pharmacological activity of anthracycline disaccharides

The amino sugar is recognized to be a critical determinant of the activity of anthracycline monosaccharides related to doxorubicin and daunorubicin. In an attempt to improve the pharmacological properties of such agents, novel anthracycline disaccharides have been designed in which the amino sugar, daunosamine, is separated from the aglycone by another carbohydrate moiety. In the present study, we examined the influence of the orientation of the second sugar residue on drug biochemical and biological properties in a series of closely related analogs. This structure-activity relationship study showed that the substitution of the daunosamine for the disaccharide moiety dramatically reduced the cytotoxic potency of the drug in the 4-methoxy series (daunorubicin analogs). In contrast, in the 4-demethoxy series (idarubicin analogs), the C-4 axial, but not the equatorial, configuration conferred a cytotoxic potency and antitumor activity comparable to that of doxorubicin. The configuration also influenced the drug's ability to stimulate topoisomerase II alpha-mediated DNA cleavage. Indeed, the glycosides with the equatorial orientation were ineffective as topoisomerase II poisons, whereas the compounds with axial orientation were active, although the daunorubicin analog exhibited a lower activity than the idarubicin analog. It is conceivable that the axial orientation allows an optimal interaction of the drug with the DNA-enzyme complex only in the absence of the methoxy group. Our results are consistent with a critical role of the sugar moiety in drug interaction with the target enzyme in the ternary complex.

Defective acidification in human breast tumor cells and implications for chemotherapy

Multidrug resistance (MDR) is a significant problem in the treatment of cancer. Chemotherapeutic drugs distribute through the cyto- and nucleoplasm of drug-sensitive cells but are excluded from the nucleus in drug-resistant cells, concentrating in cytoplasmic organelles. Weak base chemotherapeutic drugs (e.g., anthracyclines and vinca alkaloids) should concentrate in acidic organelles. This report presents a quantification of the pH for identified compartments of the MCF-7 human breast tumor cell line and demonstrates that (a) the chemotherapeutic Adriamycin concentrates in acidified organelles of drug-resistant but not drug-sensitive cells; (b) the lysosomes and recycling endosomes are not acidified in drug-sensitive cells; (c) the cytosol of drug-sensitive cells is 0.4 pH units more acidic than the cytosol of resistant cells; and (d) disrupting the acidification of the organelles of resistant cells with monensin, bafilomycin A1, or concanamycin A is sufficient to change the Adriamycin distribution to that found in drug-sensitive cells, rendering the cell vulnerable once again to chemotherapy. These results suggest that acidification of organelles is causally related to drug resistance and is consistent with the hypothesis that sequestration of drugs in acidic organelles and subsequent extrusion from the cell through the secretory pathways contribute to chemotherapeutic resistance.

Relationship between lethal effects and topoisomerase II-mediated double-stranded DNA breaks produced by anthracyclines with different sequence specificity

The role of the site selectivity of topoisomerase II poisoning in the cytotoxic activity of anthracyclines has not been established. In this article, we have thus studied the levels and persistence of double-stranded DNA breaks (DSB) along with the cytotoxic activity in human leukemic HL60 cells of seven anthracyclines, including doxorubicin, daunorubicin, and idarubicin, as well as sugar-modified analogues characterized by an altered sequence specificity. Epimerization at the 3' position of the sugar moiety markedly affected the biological activity; indeed, a dramatic reduction of drug effects was evident for 3'-deamino-3'-epi-hydroxy-4'-deoxy-4'-amino-daunorubicin. The studied analogues could be gathered into three groups based on the DSB/cytotoxicity ratio. At equitoxic concentrations: (a) parent drugs and 3'-deamino-3'-epi-hydroxy-4'-deoxy-4'-amino-daunorubicin endowed with the same sequence specificity stimulated low DSB levels; (b) 3'-epi-daunorubicin and 3'-deamino-4'-deoxy-4'-epi-amino-idarubicin, which have a different sequence specificity, and teniposide (a structurally unrelated poison) stimulated higher amounts of DSB; and (c) 4-demethoxy-3'-deamino-3'-hydroxy-4'-epi-doxorubicin stimulated the highest DSB levels. For the last agent, a faster rate of cleavage resealing, which is consistent with a reduced DNA binding affinity, could account for the increased DSB/cytotoxicity ratio compared with parent drugs. However, for other analogues, the observed differences in DSB persistence/resealing could not completely explain the different DSB/cytotoxicity ratios. The results thus suggest that the cytotoxic potency of anthracyclines may be the result of an interplay of the level, the persistence, and the genomic localization of topoisomerase II-mediated DNA cleavage.

Cell biological mechanisms of multidrug resistance in tumors

Multidrug resistance (MDR) is a generic term for the variety of strategies tumor cells use to evade the cytotoxic effects of anticancer drugs. MDR is characterized by a decreased sensitivity of tumor cells not only to the drug employed for chemotherapy but also to a broad spectrum of drugs with neither obvious structural homology nor common targets. This pleiotropic resistance is one of the major obstacles to the successful treatment of tumors. MDR may result from structural or functional changes at the plasma membrane or within the cytoplasm, cellular compartments, or nucleus. Molecular mechanisms of MDR are discussed in terms of modifications in detoxification and DNA repair pathways, changes in cellular sites of drug sequestration, decreases in drug-target affinity, synthesis of specific drug inhibitors within cells, altered or inappropriate targeting of proteins, and accelerated removal or secretion of drugs.

Intracellular pH and the control of multidrug resistance

Many anticancer drugs are classified as either weak bases or molecules whose binding to cellular structures is pH dependent. Accumulation of these drugs within tumor cells should be affected by transmembrane pH gradients. Indeed, development of multidrug resistance (MDR) in tumor cells has been correlated with an alkaline shift of cytosolic pH. To examine the role of pH in drug partitioning, the distribution of two drugs, doxorubicin and daunomycin, was monitored in fibroblasts and myeloma cells. In both cell types the drugs rapidly accumulated within the cells. The highest concentrations were measured in the most acidic compartments--e.g., lysosomes. Modifying the cellular pH in drug-sensitive cells to mimic reported shifts in MDR caused an immediate change in the cellular drug concentration. Drug accumulation was enhanced by acidic shifts and reversed by alkaline shifts. All of these effects were rapid and reversible. These results demonstrate that the alkaline shift observed in MDR is sufficient to prevent the accumulation of chemotherapeutic drugs independent of active drug efflux.

Doxorubicin resistance in P388 leukemia--evidence for reduced drug influx

Multi-drug resistance (MDR) in cancer cells is associated with reduced drug accumulation. Although intensively studied, the mechanism of this process remains ill-defined. We have now developed a new, rapid and quantitative method of measuring uptake of doxorubicin by these cells, in which the fluorescence of accumulated drug is rapidly quenched by DNA in the cell nucleus. Pre-treatment of cells with deoxyribonuclease eliminates DNA from non-viable, permeable cells, and this obviates the spurious fluorescence quenching that made previous application of this technique useless. Our data strongly suggest that the drug passively diffuses into cells. The rate of this diffusion into drug-resistant cells is considerably lower than that found in drug-sensitive cells. The ratio of the rates of drug entry in these cell types could fully account for the differences between the cell lines in doxorubicin growth-inhibitory activity. In these experiments no evidence for the previously proposed active efflux mechanism was found in either cell line.

Equilibrium binding of daunomycin and adriamycin to calf thymus DNA. Temperature and ionic strength dependence of thermodynamic parameters

Absorbance and fluorescence quenching monitoring of the binding of the anthracyclines adriamycin (ADM) and daunomycin (DNM) to calf thymus DNA, provides reproducible binding data only when moderate drug/DNA molar ratios are used in the assays. Under these conditions, the fraction of DNA-bound drug, in equilibrium with free anthracycline, which can be reliably detected, ranged from 40-60% to 80-95% of the total added drug, depending upon ionic strength and temperature. Use of the neighbour exclusion model adequately fits such data and predicts that (i) the affinity of ADM for binding to the DNA is always higher than that corresponding to DNM, under similar experimental conditions, (ii) the binding constant for both drugs exhibits a strong salt and temperature dependence, and (iii) the exclusion parameter, indicative of the size of the anthracycline binding sites on the DNA, equals 3.1 +/- 0.4 and 3.3 +/- 0.4 base pairs for ADM and DNM, respectively, and is independent of salt concentration. The salt and temperature dependence of the binding constant is used to estimate the thermodynamic parameters involved in the interaction of the drugs with the DNA. Binding of the drugs is an exothermic process and the binding free energy arises primarily from a large negative enthalpy which, as the entropy, strongly depends upon ionic strength, and is much larger than predicted by polyelectrolyte theory. The enthalpy and entropy changes observed, appear to compensate each other over the entire range of salt concentrations used, and may arise from a complex variety of contributions, including salt-induced changes in secondary structure of the DNA, as indicated by circular dichroism techniques.

Plasmid pKM101 muc(-)- and muc(+)-mediated anthracycline mutagenicity and cytotoxicity in Salmonella typhimurium

Muc (mutagenesis: UV: chemical) genes of plasmid pKM101, along with the chromosomal gene recA are known to be important constituents for full expression of inducible error-prone DNA repair in Salmonella typhimurium. This study investigates the affects of muc+ pKM101 and three of its derivatives bearing muc- point mutations (pGW1, pGW16, and pGW21) on spontaneous as well as anthracycline-induced back mutation to histidine independence. Different base-substitution and frameshift his- tester strains of S typhimurium were treated with the anthracyclines daunomycin, Adriamycin, carminomycin, and 4-demethoxy-doxorubicin. In many cases the muc- plasmids did mediate dose-dependent anthracycline mutagenicity as measured by His+ reversion. In many of the his- strains, the presence of muc+ pKM101 or muc- plasmids also resulted in a concomitant elevation of spontaneous reversion patterns over those seen with the plasmid-free parent strains. As a result, the sensitivity of most strains to anthracycline mutagenicity (based on His+ revertants/spontaneous background/microgram anthracycline) was not enhanced by muc+ pKM101 or its muc- mutant derivatives. In contrast, the low incidence of spontaneous His+ reversion in strains of the hisD3052 series, along with the inherently greater sensitivities of these strains to anthracycline-induced reversion, demonstrate most dramatically the mutagenesis-enhancing effects of muc+ pKM101 and muc- plasmids. In these and other cases in which muc- plasmid effects on enhancement of strain sensitivity to mutagenesis or cytotoxicity are observed, the overall spectrum of enhancement is the following, in decreasing order: pKM101 greater than pGW16 greater than pGW1 greater than no plasmid approximately equal to pGW21. Possible correlations are drawn between muc- plasmid effects on anthracycline-induced mutagenesis and cytotoxicity.

Interaction of anthracyclines with nucleotides and related compounds studied by spectroscopy

Interaction of the antitumour anthracyclines with mononucleotides and related compounds can be assessed through the perturbation of the spectral properties of the drugs. Purine-derived compounds induce spectral changes more efficiently than pyrimidine derivatives. No marked differences are observed when mono-, di- or triphosphate derivatives, deoxy forms, nucleosides or free nitrogen bases are used for the experiments. Visible absorbance data indicate the existence of a drug/purine nucleotide complex in solution. Assuming a simple equilibrium, this complex would be of low affinity (Keq 100 M-1). Circular dichroism spectra of daunomycin in the presence of ATP suggest that the resulting daunomycin/ATP complexes are not comparable to those formed by intercalation of the anthracycline into DNA. 31P-NMR of ATP in the presence of daunomycin does not support the notion that anthracycline/nucleotide complex formation involves interaction through the phosphate group(s) of the nucleotide. Analysis of the quenching of the drug's intrinsic fluorescence in the presence of nucleotides indicates a predominantly collisional, dynamic quenching mechanism. Values in the 2-6 mM and 85-100 mM range, respectively, are estimated for the reciprocal of the Stern-Volmer quenching constant for a variety of purine and pyrimidine derivatives. This indicates that purine derivatives are highly efficient quenchers of the fluorescence of anthracyclines, while pyrimidine derivatives are not. The fluorescence lifetime of daunomycin in the absence of quencher and the Stern-Volmer quenching constants obtained for different nucleotides are used to calculate the apparent bimolecular rate constants for collisions between fluorophore and quencher to occur. Values of (2-3) X 10(11) and 1 X 10(10) M-1 X s-1 are obtained, respectively, for purine and pyrimidine derivatives. This suggests a combination of static and dynamic quenching processes for purine compounds, which is consistent with the drug/purine nucleotide complex formation detected by visible absorbance. Because of the high intracellular concentration of certain nucleotides, particularly ATP, the above processes are predicted to be highly significant 'in vivo'.

Human myocardial histologic characteristics in congestive heart failure

The purpose of this study was to identify the histologic characteristics of human myocardium in congestive heart failure (CHF) by cellular hypertrophy, nuclear area, endocardial thickness, and percentage of fibrosis and to correlate histologic findings to cause, severity, and duration of disease. Right ventricular endomyocardial biopsies from 109 patients were quantitatively analyzed. Ten patients with normal cardiac history, physical examination results, and cardiac function served as the control group. The remaining patients were divided into the following groups: those treated with doxorubicin (n = 18), and those with chest pain with normal coronary arteries (n = 8), familial CHF (n = 3), CHF associated with myotonic dystrophy (n = 3), peripartal CHF (n = 2), valvular CHF (n = 9), alcohol-induced CHF (n = 13), postviral CHF (n = 6), or idiopathic CHF (n = 36). Linear regression analyses showed a strong correlation between cell diameter and nuclear area (r = .70, p less than .001) and weaker correlations between amount of fibrosis and cell diameter (r = .30, p less than .005) and fibrosis and nuclear area (r = .29, p less than .005). Results of function studies and histologic measurements (e.g., echocardiographically measured change in the minor-axis dimension of the left ventricle with systole and cell diameter) correlated poorly (r = -.33, p less than .005). Duration of dyspnea did not correlate with any histologic factor. Within the normal group there was a direct correlation of cell diameter with age (r = .67, p less than .05).(ABSTRACT TRUNCATED AT 250 WORDS)

Interaction between a 3-nitrobenzothiazolo (3,2-a) quinolinium antitumour drug and deoxyribonucleic acid

The interaction of 3-nitrobenzothiazolo (3,2-a) quinolinium (NBQ) perchlorate with DNA was studied by u.v.-visible and fluorescence spectrophotometry as well as by hydrodynamic methods. On binding to DNA, the absorption spectrum underwent bathochromic and hypochromic shifts, and the fluorescence was quenched. Binding parameters, determined from spectrophotometric measurements by Scatchard analysis according to an excluded-site model, indicated a binding constant of 2.4 X 10(5)M-1 for calf thymus DNA at ionic strength 0.01. The interaction was markedly suppressed by increasing the salt concentration. Binding to the GC-rich DNA of Micrococcus lysodeikticus was weaker than the binding to calf thymus DNA at ionic strength 0.01 NBQ increased the viscosity of sonicated rod-like DNA fragments, producing a calculated increment in length of 2.4 A/bound drug molecule. It removed and reversed the supercoiling of closed circular duplex plasmid pBR322 DNA by virtue of a helix-unwinding angle estimated as approximately 13 degrees/bound ligand molecule. We conclude that the binding of NBQ to DNA occurs by a mechanism of intercalation, which probably accounts for its reported antitumor activity.

Anti-tumor activity of daunorubicin linked to poly-L-aspartic acid

Daunorubicin was bound to poly-L-aspartic acid via the methylketone side chain of the drug to avoid reaction of the sugar amino group believed to be essential for optimal drug activity. Attachment of the drug to the polyamino acid by an ester linkage was achieved by nucleophylic substitution reaction of 14-bromo-daunorubicin. Compared with free daunorubicin, the polymeric derivative was less cytotoxic to HeLa cells in vitro, but more effective against all tumor models tested (P388 leukemia, Gross leukemia, MS-2 sarcoma). The binding to the polypeptide markedly reduced drug toxicity but only slightly decreased drug potency. The daunorubicin-poly-L-aspartic acid conjugate demonstrated antitumor activity comparable to that of doxorubicin in leukemia models, but superior to that of doxorubicin in a solid tumor model (MS-2 sarcoma).

Adriamycin-induced changes in the surface membrane of sarcoma 180 ascites cells

Adriamycin increases (a) the rate of agglutination of Sarcoma 180 cells by concanavalin A after brief exposure of 2-3 h and (b) membrane fluidity as measured by ESR within 30 min of exposure at concentrations of the anthracycline of 10(-7)-10(-5) M. The effect of adriamycin on agglutination is not due to an increase in the number of surface receptors for concanavalin A, since the extent of binding of the lectin is not altered by adriamycin and no change occurs in the rate of occupancy of the concanavalin A binding sites by the lectin in cells treated with the antibiotic. The order parameter, a measurement of membrane fluidity, decreases in cells exposed to adriamycin and is dose-related. The results indicate that adriamycin can induce changes in the surface membrane of Sarcoma 180 cells within a brief period of exposure to a low but cytotoxic level of this agent.

Two modes of longe-range orientation of DNA bases realized upon compaction

Formation of compact particles from linear DNA-anthracycline complexes is accompanied by appearance of intense bands in the CD spectra in the region of absorption of DNA bases (UV-region) and in the region of absorption of anthracycline chromophores (visible region). The intense (positive or negative) bands in the region of anthracycline absorption demonstrate an ordered helical location of anthracycline molecules on the DNA template. This fact, in its turn, is related to formation of the DNA superstructure in PEG-containing water-salt solutions with a long-range orientation of nitrogen bases. Possible types of DNA superstructures and the relation between the local- and the long-range order of bases in the DNA superstructure are discussed.

The interaction of daunorubicin and doxorubicin with DNA and chromatin

Isotherms that describe the binding of anthracycline antibiotics (including daunorubicin and doxorubicin (adriamycin)) to calf thymus DNA and chromatin have been obtained by means of fluorescence measurements. As expected for charged ligands, the association constants for the interaction of all drugs examined with DNA were found to be dependent on the ionic strength. However, in the case of the daunorubicin-DNA interaction, a marked decrease in the number of binding sites was also observed when the ionic strength was increased. It is suggested that the effect of salt concentration on the number of potential binding sites of daunorubicin molecules to DNA may be the result of some salt-induced alterations in the DNA conformation. This interpretation is also supported by binding data obtained with calf thymus chromatin; Whereas at low salt concentration the binding parameters for the doxorubicin-chromatin interaction are similar to those expected by neutralization of the phosphate groups by histones, modifications of the DNA structure in chromatin are invoked to account for the reduction and heterogeneity of daunorubicin binding sites. The side chain at C-9 could play an important role in determining the strength and specificity of the anthracycline-DNA interaction.

The interaction of adriamycin and adriamycin analogues with nucleic acids in the B and A conformations

The reinforced intercalative binding to DNA typical of adriamycin and daunomycin can still occur if there is epimerisation at C4' or if the O-methyl group is lost or if the 9-substituents are deleted or if the 4'-hydroxyl group is lost. In the latter two cases however, there is a reduction in affinity for the DNA, supporting the suggested role of the 9-hydroxyl and 4'-hydroxyl groups in secondary stabilization of the complex. Epimerisation at C-1' or at C-3' alters but does not abolish the intercalative mode of binding to DNA whereas epimerisation at C-7 precludes intercalation of the chromophore into the helix of DNA. In contrast to the interaction with the B-form found in DNA, the parent drugs do not intercalate into nucleic acids possessing the A-conformation and none of the above-mentioned structural changes will allow intercalation into A-form nucleic acids.

Studies on the interaction between steffimycins and DNA

The complexes formed between steffimycins and DNA were studied using various physicochemical techniques. The binding process has been followed spectrophotometrically or fluorimetrically. The binding parameters n and K, evaluated according to McGhee and Von Hippel, show a good affinity of these antibiotics for the macromolecule. Flow dichroism measurements showed that in the complex with DNA, the antracycline moiety of the steffimycins is intercalated between two base pairs of the macromolecule. The binding experiments with various polydeoxyribonucleotides and with various DNA samples, having different base pair compositions, suggest that an alternate sequence of A-T, such as that of poly[d(A-T)] . poly[d(A-T)], represents a good receptor site for the binding of steffimycins to DNA. The lack of in vivo activity of these antibiotics is discussed.

Molecular structural effects involved in the interaction of anthracyclines with DNA

Changes in DNA binding ability of daunomycin following structural modifications in the aglycone moiety have been studied by the fluorescence quenching method and by thermal denaturation of the complex. Removal of the methoxyl group at position 4 leads to a slightly stronger binding. Changes in the position of the glycosidic linkage result in a markedly weaker binding. Removal of the hydroxyl group at position 9, with the concomitant formation of a 9,10-anhydro derivative, decreases the binding ability. Methylation of hydroxyl groups at C-6 and C-11 leads to an inactive derivative and makes the binding affinity disappear almost completely. Structure-activity correlations for the DNA binding reaction deduced from these studies are in agreement with earlier findings that relate to the biological activity and confirm the general picture of the binding mechanism.

Absence of anthracycline-induced degradation of nuclear DNA in Ehrlich ascites tumour cells

The in vivo effects of anthracycline antibiotics on the integrity of Ehrlich ascites tumour cell DNA have been studied by sedimentation analysis of nuclear structures containing superhelical DNA in neutral sucrose gradients. These fast-sedimenting protein-DNA complexes may be released by gently lysing cells in solution containing non-ionic detergents and high NaCl concentrations (1.95 M). The supercoiled structure of DNA in these protein-DNA complexes is suggested by the characteristic sedimentation in the presence of intercalating agents. Apparently, no DNA damage could be detected in Ehrlich cells from 7-day-old tumours within 3 h after various doses of daunomycin (0.5--10 mg/kg of body wt.) were administered i.p. to mice. Sedimentation anomalies could not be observed even 15 or 30 h after administration of rtherapeutic doses of daunomycin or adriamycin. In contrast, at 30 min after administration to mice, therapeutic doses of bleomycin (2--8 mg/kg) caused extensive fragmentation of tumour cell DNA, which could be monitored as slowly sedimenting DNA structures (compared with the the control). Similarly, DNA damage could be induced by procarbazine at therapeutic doses. Exposure to bleomycin or procarbazine abolished the characteristic biphasic response to ethidium bromide. The absence of anthracycline-induced degradation of Ehrlich ascites tumour cell DNA is apparently in contrast with the DNA damage observed in L1210 tumour cells. These observations suggest that DNA damage is not a necessary condition for antitumour activity.

Anthracycline antitumor antibiotic nucleic-acid interactions. Structural aspects of the daunomycin poly(dA-dT) complex in solution

The helix-to-coil transition of the synthetic DNA poly(dA-dT) in the presence of the anthracycline antitumor antibiotic daunomycin has been investigated by high-resolution proton nuclear magnetic resonance (NMR) spectrocopy in 1 M salt solution. The dissociation of the complex, containing molar ratios of phosphate to daunomycin (Pi/drug) of 50, 25, 9 and 5, with increasing temperature can be monitored independently at the nucleic acid and the antibiotic resonances under conditions of fast exchange. The antibiotic complex formation shifts suggest that either ring B and/or C of the intercalated anthracycline chromophore of daunomycin overlaps with adjacent nucleic acid base pairs. Ultraviolet/visible melting studies of daunomycin complexes with a series of synthetic DNAs substituted with halogen atoms (Br, I) at position 5 of the pyrimidine ring suggest that intercalation of the antibiotic into poly(dA-dU) is not perturbed by bulky substituents at this position. A comparison of the melting curves for the daunomycin . poly(dA-dT) complex with an analog of the antibiotic where the NH3 + group is replaced by dimethylglycine demonstrates the important contributions of electrostatic interactions between the amino sugar and backbone phosphates to the stability of the complex in low salt solution. The ultraviolet/visible and NMR studies monitor biphasic melting transitions at the nucleic acid markers in the daunomycin . poly(dA-dT) complexes, Pi/drug = 50--9, so that antibiotic-free base-pair regions and those centered about bound daunomycin can be independently studied at the synthetic DNA level in solution.

Nucleic acid binding drugs. Part IV. The crystal structure of the anti-cancer agent daunomycin

The crystal structure has been determined of the anti-cancer drug daunomycin, as the hydrochloride monohydrate pyridine salt. The overall structure, previously determined by X-ray analysis of an N-bromoacetyl derivative (Anguili, R., Foresti, E., Riva Di Sanserverino, L., Isaacs, N.W., Kennard, O., Motherwell, W.D.S., Wampler, D.L. and Arcamone, F. (1971) Nat. New Biol. 234, 78-80) has been confirmed, although substantial conformational differences are observed. The conformation described here is very similar to that found for the related drug carminomycin I (Wani, M.C., Taylor, H.L., Wall, M.E., McPhaill, A.T. and Onan, K.D. (1975) J. Am. Chem. Soc. 97, 5955-5956; Pettit, G.R., Einck, J.J., Herald, C.L., Ode, R.H. Von Dreele, R.B., Brown, P., Brazhnikova, M.G. and Gause, G.F. (1975) J. Am. Chem. Soc. 97, 7387-7388); it is suggested that this represents a significantly stable molecular conformation; an intramolecular C(7)...O(9) hydrogen bond is invoked to account for this. This conformation is likely to be at least close to that of daunomycin when bound to DNA.

Changes of activity of daunorubicin, adriamycin and stereoisomers following the introduction or removal of hydroxyl groups in the amino sugar moiety

The results of a study of the effects of hydroxyl groups at positions, 2, 4 and 6 of the amino sugar on the activity of daunorubicin, adriamycin, and stereoisomers are presented. While the 4'-deoxy derivatives showed a slightly increased biological activity as compared with the parent compounds, the derivatives containing an additional hydroxyl group were less active. It is suggested that the changes in the polarity and in the DNA binding ability of these derivatives are the main factors accounting for the difference in the in vivo activity. The possible relations among the pKa values, the DNA binding properties, and the cellular uptake of the compounds are discussed with particular reference to their therapeutic effectiveness.