Werner Leupin

Interactions of antitumor drugs with natural DNA: 1H NMR study of binding mode and kinetics.

1H NMR has been used to study the interactions of over 70 clinical and experimental antitumor drugs with DNA. Spectra of the low-field (H-bonded imino proton) resonances of DNA were studied as a function of drug per base pair ratio. From the spectral changes observed, it was possible to distinguish three modes of drug binding (intercalation, groove binding, and nonspecific outside binding), to determine the kinetics of drug binding (approximate lifetime of the bound drug), and, in favorable cases, to determine the specificity of the drugs for A X T or G X C base pairs. This method is a useful assay for general drug-binding characteristics. For the intercalating compounds there appears to be a correlation between drug-binding kinetics and useful antitumor activity.

Isolation and sequence-specific DNA binding of the Antennapedia homeodomain.

The homeodomain encoded by the Antennapedia (Antp) gene of Drosophila was overproduced in a T7 expression vector in Escherichia coli. The corresponding polypeptide of 68 amino acids was purified to homogeneity. The homeodomain was analysed by ultracentrifugation and assayed for DNA binding. The secondary structure of the isolated homeodomain was determined by nuclear magnetic resonance spectroscopy. DNA‐binding studies indicate that the isolated homeodomain binds to DNA in vitro. It selectively binds to the same sites as a longer Antp polypeptide and a full‐length fushi tarazu (ftz) protein. Therefore, the homeodomain represents the DNA‐binding domain of the homeotic proteins.

1H nuclear magnetic resonance assignments for d-(GCATTAATGC))2 using experimental refinements of established procedures

Sequence-specific 1H nuclear magnetic resonance assignments are presented for d-(GCATTAATGC)2. Using omega 1-scaled double quantum-filtered correlated spectroscopy, two-quantum spectroscopy, relayed coherence transfer spectroscopy and detailed analysis of the fine structure in these phase-sensitive spectra, the spin system of the bases and deoxyribose rings were identified entirely via scalar proton-proton couplings. The sequential connectivities were established with two-dimensional nuclear Overhauser enhancement spectra recorded with a short mixing time of 60 milliseconds. These spectra contain only a small number of cross-peaks, corresponding to the shortest proton-proton distances prevailing in the DNA. They are thus easy to interpret, and therefore the presently proposed modifications of the established assignment procedures should enable studies of larger DNA duplexes with intrinsically more complex nuclear magnetic resonance spectra, and they also provided an improved basis for conformational studies of DNA fragments.

Distamycin-induced inhibition of homeodomain-DNA complexes.

The mobility shift assay was used to study the competition of the minor groove binder distamycin A with either an Antennapedia homeodomain (Antp HD) peptide or derivatives of a fushi tarazu homeodomain (ftz HD) peptide for their AT‐rich DNA binding site. The results show that distamycin and the homeodomain peptides compete under the conditions: (i) preincubation of DNA with distamycin and subsequent addition of HD peptide; (ii) simultaneous incubation of DNA with distamycin and HD peptide; and (iii) preincubation of DNA with HD peptide and subsequent addition of distamycin. There is also competition when using a peptide which lacks the N‐terminal arm of ftz HD that is involved in contacts in the minor groove. It is proposed that the proteins binding affinity is diminished by distamycin‐induced conformational changes of the DNA. The feasibility of the propagation of conformational changes upon binding in the minor groove is also shown for the inhibition of restriction endonucleases differing in the AT content of their recognition site and of their flanking DNA sequences. Thus, it is demonstrated that minor groove binders can compete with the binding of proteins in the major groove, providing an experimental indication for the influence of biological activities exerted by DNA ligands binding in the minor groove.

Determination of the NMR solution structure of the Hoechst 33258-d(GTGGAATTCCAC)2 complex and comparison with the X-ray crystal structure.

BACKGROUND The chromosomal stain, Hoechst 33258, binds to the minor groove of the DNA double helix and specifically recognizes a run of four A-T base pairs. Extensive biochemical and biophysical studies have been aimed at understanding the binding of the dye to DNA at the atomic level. Among these studies there have been several crystal structure determinations and some preliminary structural studies by NMR. RESULTS On the basis of our own previously reported NMR data, we have now determined the three-dimensional solution structure of the 1:1 complex between Hoechst 33258 and the self-complementary DNA duplex d(GTGGAATTCCAC)2. Two coexisting families of con formers, which exhibit differences in their intermolecular hydrogen bonding pattern, were found and the two terminal rings of the dye displayed greater internal mobility than the rest of the molecule. CONCLUSIONS The observed multiple ligand-binding modes in the complex between Hoechst 33258 and DNA and differential internal mobility along the bound ligand provide a novel, dynamic picture of the specific inter actions between ligands that bind in the minor groove and DNA. The dynamic state revealed by these studies may account for some of the significant differences previously observed between different crystal structures of Hoechst 33258 complexed with a different DNA duplex, d(CGCGAATTCGCG)2.

Assignment of the 13C nuclear magnetic resonance spectrum of a short DNA-duplex with 1H-detected two-dimensional heteronuclear correlation spectroscopy

Proton-detected 1H-13C heteronuclear correlated spectroscopy [( 1H,13C]-COSY) was used to establish relations between the carbon-13 and proton nuclear magnetic resonance chemical shifts in the hexadeoxynucleoside pentaphosphate d-(GCATGC)2. Using the previously established sequence-specific proton NMR assignments, sequence-specific assignments were thus obtained for nearly all proton-bearing carbons. This approach offers a new criterion for distinguishing between the proton NMR lines of purines and pyrimidines, based on the different proton-carbon-13 coupling constants. Furthermore, the adenine ring carbon 2 has a unique carbon-13 chemical shift, which enables a straightforward identification of the adenine C2H resonances by [1H,13C]-COSY.

Proton NMR study of the binding of bis(acridines) to d(AT)5.cntdot.d(AT)5. 2. Dynamic aspects

Measurements of the 1H NMR spectra and relaxation rates were used to study the dynamic properties of 9-aminoacridine (9AA) and four bis(acridine) complexes with d(AT)5.d(AT)5. The behavior of the 9AA (monointercalator) and that of C8 (bisintercalator containing an eight-carbon atom linker chain) are entirely similar. For both compounds, the lifetime of the drug in a particular binding site is 2-3 ms at approximately 20 degrees C, and neither affects the A.T base pair opening rates. The complex with C10 (bisintercalator containing a 10-carbon atom linker chain) is slightly more stable than the C8 complex since its estimated binding site lifetime is 5-10 ms at 29 degrees C. Base pairs adjacent to the bound C10 are destabilized, relative to free d(AT)5.d(AT)5, but other base pairs in the C10 complex are little affected. Bis(acridine) pyrazole (BAPY) and bis(acridine) spermine (BAS) considerably stabilize those base pairs that are sandwiched between the two acridine chromophores, but in the BAS complex proton exchange from the two flanking base pairs appears to be accelerated, relative to free d(AT)5.d(AT)5. The lifetime of these drugs in specific binding sites is too long (>10 ms) to be manifested in increased line widths, at least up to 41 degrees C. An important conclusion from this study is that certain bisintercalators rapidly migrate along DNA, despite having large binding constants (K>10(6) M-1). For C8 and C10 complexes, migration rates are little different from those deduced for 9AA. The rigid linker chain in BAPY and the charge interactions in BAS retard migration of these two bisintercalators. These results provide new parameters that are useful in understanding the biochemical and biological properties of these and other bisintercalating drugs.

Synthesis of pyrene—acridine bis-intercalators and effects of binding to DNA

Abstract A bis-intercalating compound containing pyrene and 9-aminoacridine chromophores ( N -(5-(1-pyrenyl)-pentyl)-6-(9-acridinylamino) hexylamide, I ), was prepared and its interaction with double-stranded DNA was investigated. Homologous compounds in which the two chromophores were connected by a linear carbon chain (pentamethylene ( II ), tetramethylene ( III ) and methylene ( IV )) were also prepared. In acetonitrile solutions of the free ligands, the presence of the proximal pyrene results in reduced acridine fluorescence relative to 9methylaminoacridine (9-MAA), and the degree of quenching increases with decreasing chain length. The quenching process is assigned to exothermic electron transfer from pyrene to the excited 9-aminoacridine (9-AA) chromophore. In the presence of DNA, the relative quenching order is reversed, and I and IV are quenched more strongly than II and III . From linear dichroism experiments, it is concluded that I binds by bis-intercalation of the pyrene and acridine moieties, III and IV undergo intercalation of the acridine chromophore and II binds by partial bis-intercalation at two contiguous sites.