Inhibiting transcription factor/DNA complexes using fluorescent microgonotropens (FMGTs)

Targeting Transcription Factors for Cancer Treatment

Transcription factors are involved in a large number of human diseases such as cancers for which they account for about 20% of all oncogenes identified so far. For long time, with the exception of ligand-inducible nuclear receptors, transcription factors were considered as “undruggable” targets. Advances knowledge of these transcription factors, in terms of structure, function (expression, degradation, interaction with co-factors and other proteins) and the dynamics of their mode of binding to DNA has changed this postulate and paved the way for new therapies targeted against transcription factors. Here, we discuss various ways to target transcription factors in cancer models: by modulating their expression or degradation, by blocking protein/protein interactions, by targeting the transcription factor itself to prevent its DNA binding either through a binding pocket or at the DNA-interacting site, some of these inhibitors being currently used or evaluated for cancer treatment. Such different targeting of transcription factors by small molecules is facilitated by modern chemistry developing a wide variety of original molecules designed to specifically abort transcription factor and by an increased knowledge of their pathological implication through the use of new technologies in order to make it possible to improve therapeutic control of transcription factor oncogenic functions.

DNA sequence recognition in the minor groove by hairpin microgonotropens

Two novel microgonotropens (MGTs) comprised of hairpin N-propylaminepyrrole polyamides linked to a Hoechst 33258 (Ht) analogue (3 and 4) were synthesized on solid phase by adopting an Fmoc technique using a series of HOBt mediated coupling reactions. The dsDNA-binding properties of MGTs 3 and 4 were determined by thermal denaturation experiments. Both MGTs were found to be selective for their nine-bp match dsDNA sequence 9 and were less tolerant of G/C bp substitutions in the binding region than linear progenitor MGT 1. MGT 3 was intolerant of a G/C substitution located in the middle of the binding region and did not bind to sequences 13 and 14. MGT 4 also did not bind to sequence 13, and its linker-bound Ht moiety was found to be more sensitive to a G/C substitution in the Ht-binding target, as demonstrated by the lack of binding to sequence 16.

DNA sequence recognition by Hoechst 33258 conjugates of hairpin pyrrole/imidazole polyamides

A series of hairpin pyrrole/imidazole polyamides linked to a Hoechst 33258 (Ht) analogue (5-7) were synthesized on solid-phase by adopting an Fmoc technique using a series of PyBOP/HOBt mediated coupling reactions. The dsDNA binding properties of Ht-polyamides 5-7 were determined by thermal denaturation experiments. Hairpin Ht-polyamides 5-7 bound to dsDNA sequences 16 and 18 show DeltaTm values that are 14-18 degrees higher than linear Ht-polyamides bound to the same sequences. All three Ht-polyamides were found to be selective for their 9-bp match dsDNA sequences, supporting a relative stronger interaction of an Im/Py anti-parallel dimer with an appropriately positioned G/Cbp rather than sequences containing only A/Tbps. In addition, Ht-polyamides 5 and 7 showed a 20-fold preference for a properly placed G/Cbp over a C/Gbp, while 6 showed a 10-fold preference.

Recognition of a 10 base pair sequence of DNA and stereochemical control of the binding affinity of chiral hairpin polyamide–Hoechst 33258 conjugates

Chiral hairpin polyamides linked to a Hoechst 33258 analogue at the alpha-position of the hairpin turn amino acid (1,2) were synthesized on solid phase by adopting Fmoc and ivDde techniques. The DNA-binding properties of enantiomeric conjugates 1 and 2, and N-terminal linked conjugate 3 for 8-14bp sequences were determined by spectrofluorometric and thermal melting studies. Conjugates 1 and 2 recognize a 10bp sequence, while conjugate 3 recognizes a 9bp sequence. Interestingly, R-enantiomer 1 exhibited 10- to 30-fold higher binding affinities than S-enantiomer 2 for the DNA sequences studied. These binding differences were accounted for by molecular modeling studies, which revealed that the amide proton nearest to the chiral center in R-conjugate 1 is better positioned to form hydrogen bonds to the DNA bases, while S-conjugate 2 does not.

Molecular mechanism of inhibition of survivin transcription by the GC-rich sequence-selective DNA binding antitumor agent, hedamycin: evidence of survivin down-regulation associated with drug sensitivity

Expression of the antiapoptotic protein survivin is associated with cancer cell viability and drug resistance. Thus, control of its expression in cancer cells has significant consequences for cancer therapeutics. Here we have shown that hedamycin, a GC-rich DNA binding drug, down-regulated survivin expression. Using a series of survivin promoter-luciferase constructs, we have identified an 86-bp GC-rich DNA element (-124 to -39) that mediates the ability of hedamycin to down-regulate survivin expression. Furthermore, both in vivo foot-printing and in vitro gel mobility shift experiments revealed that hedamycin bound to a 21-bp GC-rich DNA element (-115 to -95) in the survivin promoter. This drug-DNA interaction abrogated the binding of Sp-1 or Sp1-like proteins to the 21-bp cis-acting DNA element, and mutagenesis of this region consistently diminished survivin promoter activity. Finally, down-regulation of survivin transcription by hedamycin modulated the viability of cancer cells. These data suggest that abrogation of Sp-1 or Sp1-like protein binding to the 21-bp DNA element in the survivin promoter contributes at least in part to the inhibitory effect of hedamycin on survivin gene transcription. Drug-induced modulation of survivin gene expression may provide novel approaches for cancer therapeutics.

DNA sequence recognition in the minor groove by hairpin pyrrole polyamide–Hoechst 33258 analogue conjugate

A hairpin pyrrole polyamide conjugated to a Hoechst 33258 (Ht) analogue, PyPyPy-gamma-PyPyPy-gamma-Ht, was synthesized on solid-phase by adaptation of an Fmoc technique using a series of PyBOP/HOBt mediated coupling reactions. Sequence selectivity and complex stabilities were characterized by spectrofluorometric titrations and thermal melting studies. The polyamide of the conjugate was observed to bind in a hairpin motif forming 1:1 conjugate:dsDNA complexes. The conjugate is able to recognize nine contiguous A/T bps, discriminating from the sequences containing fewer than nine contiguous A/T bps.

Solid-Phase Synthesis of Positively Charged Deoxynucleic Guanidine (DNG) Tethering a Hoechst 33258 Analogue: Triplex and Duplex Stabilization by Simultaneous Minor Groove Binding

Deoxynucleic guanidine (DNG), a DNA analogue in which positively charged guanidine replaces the phosphodiester linkages, tethering to Hoechst 33258 fluorophore by varying lengths has been synthesized. A pentameric thymidine DNG was synthesized on solid phase in the 3' --> 5' direction that allowed stepwise incorporation of straight chain amino acid linkers and a bis-benzimidazole (Hoechst 33258) ligand at the 5'-terminus using PyBOP/HOBt chemistry. The stability of (DNA)(2).DNG-H triplexes and DNA.DNG-H duplexes formed by DNG and DNG-Hoechst 33258 (DNG-H) conjugates with 30-mer double-strand (ds) DNA, d(CGCCGCGCGCGCGAAAAACCCGGCGCGCGC)/d(GCGGCGCGCGCGCTTTTTGGGCCGCGCGCG), and single-strand (ss) DNA, 5'-CGCCGCGCGCGCGAAAAACCCGGCGCGCGC-3', respectively, has been evaluated by thermal melting and fluorescence emission experiments. The presence of tethered Hoechst ligand in the 5'-terminus of the DNG enhances the (DNA)(2).DNG-H triplex stability by a DeltaT(m) of 13 degrees C. The fluorescence emission studies of (DNA)(2).DNG-H triplex complexes show that the DNG moiety of the conjugates bind in the major groove while the Hoechst ligand resides in the A:T rich minor groove of dsDNA. A single G:C base pair mismatch in the target site decreases the (DNA)(2).DNG triplex stability by 11 degrees C, whereas (DNA)(2).DNG-H triplex stability was decreased by 23 degrees C. Inversion of A:T base pair into T:A base pair in the center of the binding site, which provides a mismatch selectively for DNG moiety, decreases the triplex stability by only 5-6 degrees C. Upon hybridization of DNG-Hoechst conjugates with the 30-mer ssDNA, the DNA.DNG-H duplex exhibited significant increase in the fluorescence emission due to the binding of the tethered Hoechst ligand in the generated DNA.DNG minor groove, and the duplex stability was enhanced by DeltaT(m) of 7 degrees C. The stability of (DNA)(2).DNG triplexes and DNA.DNG duplexes is independent of pH, whereas the stability of (DNA)(2).DNG-H triplexes decreases with increase in pH.