Biochemical and molecular analysis of carboxylesterase-mediated hydrolysis of cocaine and heroin.

BACKGROUND AND PURPOSE: Carboxylesterases (CEs) metabolize a wide range of xenobiotic substrates including heroin, cocaine, meperidine and the anticancer agent CPT-11. In this study, we have purified to homogeneity human liver and intestinal CEs and compared their ability with hydrolyse heroin, cocaine and CPT-11. EXPERIMENTAL APPROACH: The hydrolysis of heroin and cocaine by recombinant human CEs was evaluated and the kinetic parameters determined. In addition, microsomal samples prepared from these tissues were subjected to chromatographic separation, and substrate hydrolysis and amounts of different CEs were determined. KEY RESULTS: In contrast to previous reports, cocaine was not hydrolysed by the human liver CE, hCE1 (CES1), either as highly active recombinant protein or as CEs isolated from human liver or intestinal extracts. These results correlated well with computer-assisted molecular modelling studies that suggested that hydrolysis of cocaine by hCE1 (CES1), would be unlikely to occur. However, cocaine, heroin and CPT-11 were all substrates for the intestinal CE, hiCE (CES2), as determined using both the recombinant protein and the tissue fractions. Again, these data were in agreement with the modelling results. CONCLUSIONS AND IMPLICATIONS: These results indicate that the human liver CE is unlikely to play a role in the metabolism of cocaine and that hydrolysis of this substrate by this class of enzymes is via the human intestinal protein hiCE (CES2). In addition, because no enzyme inhibition is observed at high cocaine concentrations, potentially this route of hydrolysis is important in individuals who overdose on this agent.

Structural constraints affect the metabolism of 7-ethyl-10-[4-(1-piperidino)-1-piperidino]carbonyloxycamptothecin (CPT-11) by carboxylesterases.

7-Ethyl-10-[4-(1-piperidino)-1-piperidino]carbonyloxycamptothecin [CPT-11 (irinotecan)] is a water-soluble camptothecin-derived prodrug that is activated by esterases to yield the potent topoisomerase I poison SN-38. We identified a rabbit liver carboxylesterase (CE) that was very efficient at CPT-11 metabolism; however, a human homolog that was more than 81% identical to this protein activated the drug poorly. Recently, two other human CEs have been isolated that are efficient in the conversion of CPT-11 to SN-38, yet both demonstrate little homology to the rabbit protein. To understand this phenomenon, we have characterized a series of esterases from human and rabbit, including several chimeric proteins, for their ability to metabolize CPT-11. Computer predictive modeling indicated that the ability of each enzyme to activate CPT-11 was dependent on the size of the entrance to the active site. Kinetic studies with a series of nitrophenyl and naphthyl esters confirmed these predictions, indicating that activation of CPT-11 by a CE is constrained by size-limited access of the drug to the active site catalytic amino acid residues.

Targeting DNA secondary structures.

DNA secondary structures containing regions of single-stranded DNA have now been identified in the genomic DNA of a number of prokaryotic and eukaryotic species, including humans. Many of these secondary structures are associated with regions of DNA involved in regulation of transcription: promoters or upstream elements. The secondary structures involved appear likely to be hairpin or cruciform structures that may be recognition sites for binding of transcription factors. In the case of the coliphage N4 virion RNA polymerase, a defined hairpin in the polymerase promoter necessary for binding of the polymerase and regulation of transcription has been shown to be extruded under physiological conditions in plasmid DNA. The presence of single-stranded DNA in the promoters of several species suggests that regulatory hairpins may be involved in transcription of a number of genes. In support of this, hairpin- or cruciform-binding proteins have been identified from several species. These results imply that secondary structures in regulatory regions may be targets for drugs that bind and either block or enhance binding of proteins involved in transcription. In this review, we discuss the evidence for DNA secondary structures, particularly hairpins and cruciforms, in genomic DNA and review the studies to date of development of small molecules that can selectively bind these structures.

7- and 10-substituted camptothecins: dependence of topoisomerase I-DNA cleavable complex formation and stability on the 7- and 10-substituents.

7-Alkyl, 7-alkyl-10-hydroxy, 7-alkyl-10-methoxy, and 7-alkyl-10, 11-methylenedioxy analogs of camptothecin have been synthesized and evaluated for their ability to trap human DNA topoisomerase I in cleavable complexes. The 7-alkyl chain lengths varied linearly from methyl to butyl. The concentration required to produce cleavable complexes with purified topoisomerase I in 50% of the plasmid DNA (EC(50)) was reduced by 1 order of magnitude by the introduction of a 10-methoxy or 7-alkyl group compared with camptothecin. The EC(50) values were reduced by 2 orders of magnitude with a 10-hydroxy or 10, 11-methylenedioxy moiety compared with camptothecin. The steady-state EC(50) concentrations for all of the analogs tested were slightly dependent on substitution at the 7-position, but this dependence was least with the 10-methoxy series. The kinetics of the reversibility of the complexes formed with all analogs was only slightly influenced by the length of the 7-substitution, with the trend that ethyl or greater lengths led to slightly reduced rate constants for cleavable complex reversal. These results were also observed for DNA-protein cross-link formation by the analogs in isolated CEM cell nuclei. Our data indicate that in vitro cleavable complex stability, as determined by the apparent rate constants for complex dissociation, does not reflect the in vitro biological activity of these camptothecin analogs. However, complex stability in vivo may be important for the antitumor activity of the compounds.

The role of the loop in binding of an actinomycin D analog to hairpins formed by single-stranded DNA.

Our recent work has indicated that the potent antibiotic and antitumor agent actinomycin D has the ability to selectively bind and stabilize single-stranded DNA that is capable of adopting a hairpin conformation. This mechanism of DNA binding has been implicated in the drug's ability to inhibit transcription by HIV reverse transcriptase from single-stranded DNA templates. In this report, we studied the importance of the hairpin loop on the ability of the 7-amino analog of actinomycin D to selectively bind DNA hairpins. Binding dissociation constant (Kd) values were determined to be 0.22 +/- 0.11 microM for the hairpin formed from the single-stranded DNA 5'-AAAAAAATAGTTTTAAATATTTTTTT-3' (dubbed HP1). The hairpin stem without the loop resulted in binding with Kd = 2.6 +/- 0.9 microM. The drug showed low affinity for the HP1 strand fully duplexed to its complementary sequence (estimated to be at least Kd > 21 microM). Evaluation of 7-aminoactinomycin D binding to a library of thermodynamically characterized DNA hairpins revealed an affinity for the hairpin-forming sequence 5'-GGATACCCCCGTATCC-3' (dubbed ACC4) of Kd = 6.8 +/- 2.2 microM. Replacement of the terminal guanines of this sequence to generate 5'-ATATACCCCCGTATAT-3' resulted in a 10-fold increase in affinity for this hairpin compared to ACC4, to Kd = 0.74 +/- 0.06 microM. A molecular model of the ACC4actinomycin D complex reveals that significant interactions between the hairpin loop and the pentapeptide rings of the drug must occur during drug binding. Taken together, our data indicate that the composition of the stem-loop interface is critical for the selectivity of actinomycin D and its 7-amino analog for DNA hairpins and suggests that novel drugs may be designed based on selection for the desired hairpin composition.

Water soluble 20(S)-glycinate esters of 10,11-methylenedioxycamptothecins are highly active against human breast cancer xenografts.

Water-soluble 20(S)-glycinate esters of two highly potent 10,11-methylenedioxy analogues of camptothecin (CPT) have been synthesized and evaluated for their ability to eradicate human breast cancer tumor xenografts. The glycinate ester moiety increases the water solubility of the 10,11-methylenedioxy analogues 4-16-fold. However, in contrast to CPT-11, a water-soluble CPT analogue that was recently approved for second line treatment of colorectal cancer, the 20(S)-glycinate esters do not require carboxylesterase for conversion to their active forms. The glycinate esters are hydrolyzed to their parent, free 20(S)-hydroxyl active analogues in phosphate buffer (pH 7.5) and in mouse and human plasma. The glycinate esters are also 20-40-fold less potent than CPT-11 in inhibiting human acetylcholinesterase. In vivo, we examined 20(S)-glycinate-10,11-methylenedioxycamptothecin, 20(S)-glycinate-7-chloromethyl-10,11-methylenedioxycamptothecin, and CPT-11. We found that the two 10,11-methylenedioxy analogues had antitumor activity against breast cancer xenografts that was comparable to that of CPT-11. Our results indicate that water-soluble 20(S)-glycinate esters of highly potent CPT analogues provide compounds that maintain biological activity, do not require interactions with carboxylesterases, and do not inhibit human acetylcholinesterase.

The anticancer prodrug CPT-11 is a potent inhibitor of acetylcholinesterase but is rapidly catalyzed to SN-38 by butyrylcholinesterase.

Patients treated with high doses of CPT-11 rapidly develop a cholinergic syndrome that can be alleviated by atropine. Although CPT-11 was not a substrate for acetylcholinesterase (AcChE), in vitro assays confirmed that CPT-11 inhibited both human and electric eel AcChE with apparent K(i)s of 415 and 194 nM, respectively. In contrast, human or equine butyryl-cholinesterase (BuChE) converted CPT-11 to SN-38 with K(m)s of 42.4 and 44.2 microM for the human and horse BuChE, respectively. Modeling of CPT-11 within the predicted active site of AcChE and BuChE corroborated experimental results indicating that, although the drug was oriented correctly for activation, the constraints dictated by the active site gorge were such that CPT-11 would be unlikely to be activated by AcChE.

Actinomycin D binds to metastable hairpins in single-stranded DNA.

We have examined the role of DNA composition in the binding of actinomycin D to single-stranded DNA. By using the fluorescent analogue 7-aminoactinomycin D, we were able to monitor binding of the drug to ssDNA with single base changes distant from the 5'-TAGT-3' site previously determined to be a high-affinity site for actinomycin D binding (Wadkins et al. (1996) J. Mol. Biol. 262, 53-68). Our binding studies indicated that secondary structures in the ssDNA were likely to be responsible for binding the drug. A series of six low-melting DNA hairpins containing all or part of the 5'-TAGT-3' binding site were synthesized. The highest Tm observed for the melting of these hairpins was 34.2 +/- 0.3 degrees C, and it depended on the length of the stem region. These metastable hairpins were stabilized by 7-aminoactinomycin D, with the drug shifting the Tm for the drug-hairpin complex to approximately 45 degrees C. The hairpins showed very high affinity (Kd approximately 0.1 microM) for 7-aminoactinomycin D, with some dependence on stem length. Digestion of the hairpins in the presence and absence of drug using mung bean nuclease, which specifically interacts with the loop region of hairpin DNA, revealed that the stable hairpins (i) contain a number of non-Watson-Crick base pairs, and (ii) undergo a conformational change in the loop region upon binding 7-aminoactinomycin D. Our results suggest that stabilization of unusual hairpins by actinomycin D may be an important aspect of the potent transcription inhibition activity of this drug.

Detection of multiple toxic agents using a planar array immunosensor.

A planar array immunosensor, equipped with a charge-coupled device (CCD) as a detector, was used to simultaneously detect 3 toxic analytes. Wells approximately 2 mm in diameter were formed on glass slides using a photoactivated optical adhesive. Antibodies against staphylococcal enterotoxin B (SEB), ricin, and Yersinia pestis were covalently attached to the bottoms of the circular wells to form the sensing surface. Rectangular wells containing chicken immunoglobulin were used as alignment markers and to generate control signals. After removing the optical adhesive, the slides were mounted over a scientific grade CCD operating at ambient temperature in inverted (multipin phasing) mode. A two-dimensional graded index of refraction lens array was used to focus the sensing surface onto the CCD. Solutions of toxins were then placed on the slide. After rinsing, Cy5-labeled antibodies were introduced. The identity and amount of toxin bound at each location on the slide were determined by quantitative image analysis. Concentrations as low as 25 ng/mL of ricin, 15 ng/mL of pestis F1 antigen, and 5 ng/mL of SEB could be routinely measured.

Characterization of topotecan-mediated redistribution of DNA topoisomerase I by digital imaging microscopy.

Topographical image measures have been used to characterize the subnuclear distribution of DNA topoisomerase I in human tumor cell lines. This topographical analysis allowed a mathematical description of staining patterns to be produced that did not depend on subjective grading. The redistribution of topoisomerase I in response to increasing concentrations of topotecan was then monitored by this method. The cell lines were stained for topoisomerase I by indirect immunofluorescence methods. Digital imaging microscopy and image analysis were used to extract the nucleus from each cell, and nine parameters describing the topography of the distribution of topoisomerase I within the nucleus were computed for each. Use of multivariate analysis of variance enabled this nine-parameter set to be reduced to a single canonical variable, representing 60-90% of the observed internuclear variance. Plotting the canonical variable vs drug concentration resulted in dose-response curves that could be fitted well by a simple Emax model. From these curve fits, EC50 and Emax values for drug-induced redistribution of topoisomerase I were determined. Our results indicate that neither the maximum extent of topoisomerase I redistribution (Emax) nor the EC50 for drug-induced redistribution correlated well with the growth inhibition produced by continuous exposure to topotecan in these cell lines. However, the EC50 determined for the 1-h high-concentration exposure did reflect the growth inhibition produced in cells exposed to the drug for 1 h. The methodology described may also be generally applied to any antigen of interest.

Biophysical aspects of P-glycoprotein-mediated multidrug resistance.

In the 45 years since Burchenal's observation of chemotherapeutic drug resistance in tumor cells, many investigators have studied the molecular basis of tumor drug resistance and the phenomenon of tumor multidrug resistance (tumor MDR). Examples of MDR in microorganisms have also become topics of intensive study (e.g., Plasmodium falciparum MDR and various types of bacterial MDR) and these emerging fields have, in some cases, borrowed language, techniques, and theories from the tumor MDR field. Serendipitously, the cloning of MDR genes overexpressed in MDR tumor cells has led to elucidation of a large family of membrane proteins [the ATP-binding cassette (ABC) proteins], an important subset of which confer drug resistance in many different cells and microorganisms. In trying to decipher how ABC proteins confer various forms of drug resistance, studies on the structure and function of both murine and human MDR1 protein (also called P-glycoprotein or P-gp) have often led the way. Although various theories of P-gp function have become popular, there is still no precise molecular-level description for how P-gp overexpression lowers intracellular accumulation of chemotherapeutic drugs. In recent years, controversy has developed over whether the protein protects cells by translocating drugs directly (as some type of drug pump) or indirectly (through modulating biophysical parameters of the cell). In this ongoing debate over P-gp function, detailed consideration of biophysical issues is critical but has often been neglected in considering cell biological and pharmacological issues. In particular, P-gp overexpression also changes plasma membrane electrical potential (delta psi zero) and intracellular pH (pHi), and these changes will greatly affect the cellular flux of a large number of compounds to which P-gp overexpression confers resistance. In this chapter, we highlight these biophysical issues and describe how delta psi zero and pHi may in fact be responsible for many MDR-related phenomena that have often been hypothesized to be due to direct drug translocation (e.g., drug pumping) by P-gp.

Actinomycin D binding to single-stranded DNA: sequence specificity and hemi-intercalation model from fluorescence and 1H NMR spectroscopy.

We have studied the sequence specificity in the binding of the potent antitumor drug actinomycin D (AMD) to single-stranded DNA (ssDNA) by fluorescence and NMR spectroscopy and by molecular modeling. The significant absorption and emission changes accompanying the interaction of the fluorescent derivative 7-amino-AMD with DNAs varying in length and base composition were used to calculate affinity constants for the drug-DNA complexes. The guanine-containing trinucleotide sequences AGT, AGA, and TGT embedded within 25-base oligonucleotides, constituted favorable binding sites. In contrast, the sequence TGA did not bind the drug appreciably. Among the DNAs studied, the highest affinity was for the tetranucleotide sequence TAGT. The binding was length dependent, an oligonucleotide of at least 14 bases being required for effective complex formation (Ka > 10(4) M1=). AMD also bound to poly(d(AGT)). Gel electrophoresis confirmed that the complex was formed between the drug and individual unstructured DNA strands. The 1H NMR spectra of oligonucleotides containing the TAGT site and their complexes with AMD provided further insight into the mode(s) of interaction. A comparison of the measured chemical shifts with those estimated from ring-current calculations provided strong evidence for a hemi-intercalation of AMD between the A and G purine bases with a preference for one of two possible relative orientations. The latter were modeled as complexes with the sequence T3AGT3 and refined by force field calculations with the AMBER program. The biological implications for this novel form of interaction of AMD with single-stranded DNA are discussed.

Calibration of biosensor response using simultaneous evanescent wave excitation of cyanine-labeled capture antibodies and antigens.

Fiber optic biosensors have proven their ability to detect antigens rapidly in a variety of environmental and clinical samples. These biosensors are based on the technique of covalently linking antibodies to the core of an optical fiber and detecting antigen binding via measurement of fluorescence induced in the evanescent wave. One problem associated with these biosensors is the fiber-to-fiber variability in measured signal. We have addressed this problem by labeling a portion of the immobilized capture antibody with the fluorescent cyanine dye Cy5.5 (emission lambda max = 696 nm). The antigen was then labeled with fluorescent Cy5 (emission lambda max = 668 nm). Both fluorophores were excited by 635-nm light, and their emission was collected using both a fiber optic spectrometer and a biosensor optimized to collect fluorescence at two wave-lengths. The fluorescence from the Cy5.5-labeled capture antibody served as a calibration signal for each fiber and corrected for differences in optics, fiber defects, and varying amounts of capture antibody present on the fiber. Our data show that normalizing the signal measured from Cy5-labeled antigen binding to the Cy5.5 signal provides a standardization process for greatly reducing signal variance among individual fibers.

Kinetics of transport of dialkyloxacarbocyanines in multidrug-resistant cell lines overexpressing P-glycoprotein: interrelationship of dye alkyl chain length, cellular flux, and drug resistance.

The membrane transport properties of a series of dialkyloxacarbocyanine [DiOCn(3)] dyes in multidrug-resistant KB cell lines were investigated to determine the influence of alkyl chain length on the ability of p-glycoprotein (i) to protect cells from the toxicity of the dyes and (ii) to affect the plasma membrane flux of the dyes. Cytotoxicity assays revealed that increased levels of p-glycoprotein led to increased resistance to the toxicity of the DiOCn(3) relative to the sensitive KB-3-1 parent line. This resistance could be fully or partially reversed by 10 microM verapamil. Monitoring of DiOCn(3) fluorescence changes allowed the measurement of accumulation and efflux rates for the dyes in the parent and two resistant cell lines at 1.5-s resolution. The flux of DiOCn(3) into and out of the KB85 and KBV1 cell lines was shown to be dramatically different from the parental KB-3-1 line when n < 5, while the transport properties of n = 7 were identical in the three cell lines examined. The membrane transport properties were shown not to be correlated with the 7-day toxicity of DiOCn(3). Verapamil affected the kinetic processes of DiOC2-5(3) involving redistribution of the dyes within the cells once they had initially passed the plasma membrane. Fluorescence microscopy was used to show no alteration in the subcellular distribution of the DiOCn(3), in response to neither chain length nor cell line. Our results indicate that an alkyl chain length of 5 carbons is the critical length necessary for p-glycoprotein to affect membrane transport of DiOCn(3) but not to protect the cells from the cytotoxicity of the dyes.

Cell cycle analysis of amount and distribution of nuclear DNA topoisomerase I as determined by fluorescence digital imaging microscopy.

Fluorescence digital imaging microscopy (FDIM) has been used to perform a cell cycle analysis of both the amount and the distribution of nuclear DNA topoisomerase I in individual CEM human leukemia cells. Cells were stained by indirect immunofluorescence methods using a polyclonal antiserum generated with a 21-amino-acid peptide representing amino acids 219-239 of human topoisomerase I. Immunohistochemical staining was followed by staining with Hoechst dye 33342, allowing DNA content to be determined in each cell. Cell cycle analysis showed that nuclear topoisomerase I content doubled (2.2-fold increase) as the cells progressed from G1 to G2/M phases of the cell cycle. However, when normalized for nuclear size, topoisomerase I content per nuclear area remained almost constant (1.3-fold increase). For comparison, we measured the amount of proliferating cell nuclear antigen (PCNA), a protein whose expression fluctuates during the cell cycle. Nuclear PCNA content increased 2.7-fold from G1 to S phase, then declined in G2/M- phases, whereas PCNA content per nuclear area increased 1.7-fold from G1 to S phase. We also measured topoisomerase I content in leucine-deprived cells to determine if altered growth conditions affect topoisomerase I protein expression. Compared to CEM cells in logarithmic growth, leucine-deprived CEM cells had 1.8-fold less topoisomerase I content per nuclear area. Subnuclear distribution studies of proliferating CEM cells showed topoisomerase I to be localized predominantly in the nucleoli throughout the cell cycle. In contrast, leucine-deprived cells exhibited a perinuclear distribution of topoisomerase I. Our results show that FDIM is a useful technique in determining the cell cycle position and both the content and the distribution of topoisomerase I as well as other nuclear proteins in individual cells.

The role of drug-lipid interactions in the biological activity of modulators of multi-drug resistance.

Of the compounds that have now been shown to circumvent acquired cellular multidrug resistance, little or no structure-activity relationship has been found, although their proposed mechanism of action is through modulation of function of p-glycoprotein. While it has been suggested that this inhibition is a direct binding to p-glycoprotein, we show here that such a model seriously neglects the effects many of these compounds have on lipid physical properties. We have characterized the interactions between 16 structurally diverse pharmacological agents (nine of which are known to reverse multidrug resistance) and a variety of lipids. Potent modulators inhibit the membrane binding of rhodamine 6G, and we have observed a correlation of the measured Ki values with the effectiveness of the compounds in situ. We have determined the effects of the compounds on detergent micellization, and have shown substantial changes on the critical micelle concentration of detergents in the presence of modulators. Finally, we have examined the changes in model membrane 'viscosity' induced by the compounds. These results indicate that both direct p-glycoprotein and indirect lipid interactions of modulators should be considered in the mechanism by which these compounds reverse multidrug resistance.

Kinetics of cellular permeability of phenoxazine and its dependence on P-glycoprotein expression.

We present here the initial characterization of the mechanism of reversal of cellular resistance to Vinca alkaloids by phenoxazine (PZ). Changes in fluorescence upon cellular accumulation of PZ allowed measurement of the membrane transport kinetics in a sensitive KB-3-1 cell line and two multi-drug resistant (MDR) counterparts. The accumulation of PZ is characterized by two uptake routes, with pseudo-first order rate constants of 0.3 s-1 and 0.07 s-1, while efflux of PZ from cells revealed rate constants of 0.2 s-1. PZ rapidly reaches steady-state concentrations within cells, which may make it more clinically useful than modulators that accumulate more slowly (e.g. verapamil).

Actinomycin D and 7-aminoactinomycin D binding to single-stranded DNA.

The potent RNA polymerase inhibitors actinomycin D and 7-aminoactinomycin D are shown to bind to single-stranded DNAs. The binding occurs with particular DNA sequences containing guanine residues and is characterized by hypochromic UV absorption changes similar to those observed in interactions of the drugs with double-stranded duplex DNAs. The most striking feature of the binding is the dramatic (ca. 37-fold) enhancement in fluorescence that occurs when the 7-aminoactinomycin is bound to certain single-stranded DNAs. This fluorescence of the complex is also characterized by a 40-nm hypsochromic shift in the emission spectrum of the drug and an increase in the emission anisotropy relative to the free drug or the drug bound to calf thymus DNA. The fluorescence lifetimes change in the presence of the single-stranded DNA in a manner compatible with the intensity difference. Thus, there is an increase in the fraction of the emission corresponding to a 2-ns lifetime component compared to the predominant approximately 0.5-ns lifetime of the free drug. The 7-aminoactinomycin D comigrates in polyacrylamide gels with the single-stranded DNAs, and the fluorescence of the bound drug can be visualized by excitation with 540-nm light. The binding interactions are characterized by association constants of 2.0 x 10(6) to 1.1 x 10(7) M-1.

Interactions of anilinoacridines with nucleic acids: effects of substituent modifications on DNA-binding properties.

Spectroscopic methods are used to probe the interactions of several anilinoacridine analogues with calf thymus DNA over a wide range of temperatures and sodium chloride concentrations. The structurally similar compounds m-AMSA, AMSA (both active as antitumor agents), and o-AMSA (inactive as an antitumor agent) have been widely studied in their abilities to bind DNA in an intercalative manner. Recent studies from this laboratory reveal distinct differences in the thermodynamic binding mechanisms between m-AMSA and o-AMSA (Wadkins & Graves, 1989), with the m-AMSA-DNA interaction being an enthalpy-driven process while the binding of o-AMSA to DNA is characterized by more positive entropy values. To further examine the physical chemical properties associated with these compounds and their correlation with antitumor activities, an in-depth investigation into the thermodynamic parameters of these compounds and structurally related anilinoacridine analogues was performed. These studies demonstrate that substituent type and position on the aniline ring of the anilinoacridines greatly influences both the affinities of these drugs in binding to DNA and dictates whether the DNA binding is an enthalpy- or entropy-driven process. The differences in thermodynamic mechanisms of binding between the two isomers along with molecular modeling studies reveal the electronic and/or steric factors resulting from the positioning of the methoxy substituent group on the anilino ring directs the DNA-binding properties through orientation of the methanesulfonamido group at the 1' position of the aniline ring. The orientation of this substituent group may result in favorable contacts through hydrogen bonding with neighboring base pairs and ultimately influence the biological effectiveness as an antitumor agent.

Thermodynamics of the interactions of m-AMSA and o-AMSA with nucleic acids: influence of ionic strength and DNA base composition.

The equilibrium binding of the antitumor agent m-AMSA and its biologically inactive analog o-AMSA to native and synthetic DNAs are compared over a wide range of ionic strengths and temperatures. Although o-AMSA binds DNA with a higher affinity than m-AMSA it is not effective as an antitumor agent. Both m-AMSA and o-AMSA bind DNA in an intercalative manner. Indepth investigations into the thermodynamic parameters of these interactions reveal the interaction of m-AMSA with DNA to be an enthalpy driven process. In contrast, the structurally similar but biologically inactive o-AMSA binds DNA through an entropy driven process. The differences in thermodynamic mechanisms of binding between the two isomers reveal that the electronic and/or steric factors resulting from the position of the methoxy substituent group on the anilino ring directs the DNA binding properties of these compounds and ultimately the biological effectiveness as an antitumor agent.