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Vol. 294, Issue 1, 370-377, July 2000
Department of Biochemistry and Molecular Biology (R.G., C.R., N.B.,
C.M.) and Biotechnology Center (R.G., G.F.), Ferrara University,
Ferrara, Italy
DNA-binding drugs have been reported to be able to interfere with the
activity of transcription factors in a sequence-dependent manner,
leading to alteration of transcription. This and similar effects could
have important practical applications in the experimental therapy of
many human pathologies, including neoplastic diseases and viral
infections. The analysis of the biological activity of DNA-binding
drugs by footprinting, gel retardation, polymerase chain reaction, and
in vitro transcription studies does not allow a real time study of
binding to DNA and dissociation of the generated drugs/DNA complexes.
The recent development of biosensor technologies for biospecific
interaction analysis (BIA) enables monitoring of a variety of molecular
reactions in real-time by surface plasmon resonance (SPR). In this
study, we demonstrate that molecular interactions between DNA-binding
drugs (chromomycin, mithramycin, distamycin, and MEN 10567) and
biotinylated target DNA probes immobilized on sensor chips is
detectable by SPR technology using a commercially available biosensor.
The target DNA sequences were synthetic oligonucleotides mimicking the
Sp1, NF-kB, and TFIID binding sites of the long terminal repeat of the
human immunodeficiency type 1 virus. The results obtained demonstrate
that mithramycin/DNA complexes are less stable than chromomycin/DNA
complexes; distamycin binds to both NF-kB and TATA box
oligonucleotides, but distamycin/(NF-kB)DNA complexes are not stable;
the distamycin analog MEN 10567 binds to the NF-kB mer and the
generated drug/DNA complexes are stable. The experimental approach
described in this study allows fast analysis of molecular interactions
between DNA-binding drugs and selected target DNA sequences. Therefore,
this method could be used to identify new drugs exhibiting differential
binding activities to selected regions of viral and eukaryotic gene promoters.
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