Acetyl-boswellic acids are novel catalytic inhibitors of human topoisomerases I and IIalpha.

Acetyl-boswellic acids (acetyl-BA) are pentacyclic triterpenes derived from the gum resin of frankincense. We have previously shown that these compounds are effective cytotoxic agents, acting through a mechanism that appears to involve the inhibition of topoisomerase activity. We have now investigated the mechanism of action of acetyl-BA and show that these compounds are more potent inhibitors of human topoisomerases I and IIalpha than camptothecin, and amsacrine or etoposide, respectively. Our data demonstrate that acetyl-BA and, to a lesser extent, some other pentacyclic triterpenes, such as betulinic acid, ursolic acid, and oleanolic acid, inhibit topoisomerases I and IIalpha through a mechanism that does not involve stabilization of the cleavable complex or the intercalation of DNA. Surface plasmon resonance analysis revealed that topoisomerases I and IIalpha bind directly to an immobilized derivative of acetyl-BA. This acetyl-BA derivative interacts with human topoisomerases through high-affinity binding sites yielding K(D) values of 70.6 nM for topoisomerase I and 7.6 nM for topoisomerase IIalpha. Based on our data, we propose that acetyl-BA inhibit topoisomerases I and IIalpha through competition with DNA for binding to the enzyme. Thus, acetyl-BA are a unique class of dual catalytic inhibitors of human topoisomerases I and IIalpha.

Sensing biological effectors through the response of bridged nucleic acids and polynucleotides fixed in liquid-crystalline dispersions.

The formation of three-dimensional structures of double-stranded nucleic acid and polynucleotide molecules, fixed in the structure of liquid-crystalline dispersions and bridged by polymeric chelate complexes is described. The bridging elements consist of alternating daunomycin molecules and copper ions. It is shown that these bridges between nucleic acid molecules stabilize cholesteric structures of the DNA liquid-crystalline dispersion. The formation of polymeric chelate bridges is accompanied by a remarkable increase of the intense circular dichroism (CD) band characteristic of the DNA-daunomycin cholesterics. These bridges are destabilized by a number of biologically relevant compounds and macromolecules, such as ascorbic acid, homocarnosine, bovine serum albumin and lysozyme. The dramatic change in the optical activity of the liquid-crystalline dispersions upon addition of these compounds makes them easily detectable. The sensitivity of the method, in the range of analytic concentration 10(-4)-10(-8) M, depends on the nature of the compound being tested. The response of bridged DNA structures to biological effectors observed here foresees their further development as biosensor devices for detecting the presence of biologically and pharmacologically relevant compounds.

Liquid-crystalline structure of nucleic acids: effect of antracycline drugs and copper ions.

The formation of liquid-crystalline dispersions (L.C.D.) from double-stranded DNA and polynucleotide (NA) molecules complexed with a number of anthracycline derivatives was investigated. These drugs form two types of complexes (complex I and complex II) with NA, which differ in the mode of drug orientation in respect to the NA helical axis. When complex II forms, addition of copper ions causes bridging of neighboring NA molecules through polymeric copper-anthracycline links (Figure 1). This results in an extra-increase in the amplitude of the intense CD band, characteristic for complex II, in the drug absorption region. Comparison of data obtained for different analogs and derivatives of daunomycin, has shown that the presence of 4 coordinating oxygen atoms at positions 5,6 and 11,12 (or 1,12) of the anthracycline ring system represents the basic prerequisite for the formation of a long polymeric chelate bridge after addition of copper ions. A second requirement relates to the chemical and stereochemical properties of sugar residues at position 7. These are important for proper positioning of the neighboring anthracycline aglycones in the polymeric chelate bridges and for spatial fixation of Cu2+ ions. Base sequence of double-stranded polynucleotides plays, if any, a minor role in polymeric chelate bridge formation. The question concerning the sterical orientation of two neighbouring antracyclines in the linking bridges, formed between NA molecules fixed in the liquid-crystalline structure, remains open.

Formation of polymeric chelate bridges between double-stranded DNA molecules fixed in spatial structure of liquid-crystalline dispersions.

The formation of cholesteric liquid-crystalline dispersions from DNA-daunomycin complexes in water-salt polyethyleneglycol-containing solutions was investigated. In the case of nonclassical complex formation between DNA and daunomycin (DAU), reactive groups of DAU were used for the formation of polymeric chelate complex with divalent copper ions (-DAU-Cu-...-Cu-DAU-), located between neighboring double-stranded DNA molecules, fixed in spatial structure of liquid-crystalline dispersions. The formation of polymeric chelate complex does not depend upon the sense of helicoidal twist of DNA cholesterics. A many-fold increase in the CD band in the DAU absorption region is specific to this process. A reduction of the divalent copper ions as a result of a redox-process is accompanied by destroying of structure of polymeric chelate complex between DNA molecules and by disappearance of the abnormal CD band in daunomycin absorption region.