Molecular basis for the inhibition of HMGA1 proteins by distamycin A.

The molecular mechanism for the displacement of HMGA1 proteins from DNA is integral to disrupting their cellular function, which is linked to many metastatic cancers. Chemical shift and NOESY NMR experiments provide structural evidence for the displacement of an AT hook peptide (DNA binding motif of HMGA1 proteins) by both monomeric and dimeric distamycin. However, the displaced AT hook alters distamycin binding by weakening the distamycin:DNA complex, while slowing monomeric distamycin dissociation when AT hook is in excess. The central role of the AT hook was evaluated by monitoring full-length HMGA1a protein binding using fluorescence anisotropy. HMGA1a was effectively displaced by distamycin, but the cooperative binding exhibited by distamycin was eliminated by displaced HMGA1a. Additionally, these studies indicate that HMGA1a is displaced from the DNA by 1 equiv of distamycin, suggesting the ability to develop therapeutics that take advantage of the positively cooperative nature of HMGA1a binding.

Physical and structural basis for the strong interactions of the -ImPy- central pairing motif in the polyamide f-ImPyIm.

The polyamide f-ImPyIm has a higher affinity for its cognate DNA than either the parent analogue, distamycin A (10-fold), or the structural isomer, f-PyImIm (250-fold), has for its respective cognate DNA sequence. These findings have led to the formulation of a two-letter polyamide "language" in which the -ImPy- central pairings associate more strongly with Watson-Crick DNA than -PyPy-, -PyIm-, and -ImIm-. Herein, we further characterize f-ImPyIm and f-PyImIm, and we report thermodynamic and structural differences between -ImPy- (f-ImPyIm) and -PyIm- (f-PyImIm) central pairings. DNase I footprinting studies confirmed that f-ImPyIm is a stronger binder than distamycin A and f-PyImIm and that f-ImPyIm preferentially binds CGCG over multiple competing sequences. The difference in the binding of f-ImPyIm and f-PyImIm to their cognate sequences was supported by the Na(+)-dependent nature of DNA melting studies, in which significantly higher Na(+) concentrations were needed to match the ability of f-ImPyIm to stabilize CGCG with that of f-PyImIm stabilizing CCGG. The selectivity of f-ImPyIm beyond the four-base CGCG recognition site was tested by circular dichroism and isothermal titration microcalorimetry, which shows that f-ImPyIm has marginal selectivity for (A.T)CGCG(A.T) over (G.C)CGCG(G.C). In addition, changes adjacent to this 6 bp binding site do not affect f-ImPyIm affinity. Calorimetric studies revealed that binding of f-ImPyIm, f-PyImIm, and distamycin A to their respective hairpin cognate sequences is exothermic; however, changes in enthalpy, entropy, and heat capacity (DeltaC(p)) contribute differently to formation of the 2:1 complexes for each triamide. Experimental and theoretical determinations of DeltaC(p) for binding of f-ImPyIm to CGCG were in good agreement (-142 and -177 cal mol(-)(1) K(-)(1), respectively). (1)H NMR of f-ImPyIm and f-PyImIm complexed with their respective cognate DNAs confirmed positively cooperative formation of distinct 2:1 complexes. The NMR results also showed that these triamides bind in the DNA minor groove and that the oligonucleotide retains the B-form conformation. Using minimal distance restraints from the NMR experiments, molecular modeling and dynamics were used to illustrate the structural complementarity between f-ImPyIm and CGCG. Collectively, the NMR and ITC experiments show that formation of the 2:1 f-ImPyIm-CGCG complex achieves a structure more ordered and more thermodynamically favored than the structure of the 2:1 f-PyImIm-CCGG complex.

Synthesis and evaluation of an intercalator-polyamide hairpin designed to target the inverted CCAAT box 2 in the topoisomerase IIalpha promoter.

The synthesis and DNA-binding properties of a novel naphthalimide-polyamide hairpin (3) designed to target the inverted CCAAT box 2 (ICB2) site on the topoisomerase IIalpha (topoIIalpha) promoter are described. The polyamide component of 3 was derived from the minor-groove binder, 2, and tailored to bind to the 5'-TTGGT sequence found in and flanking ICB2. The propensity of mitonafide 4 to intercalate between G-C base pairs was exploited by the incorporation of a naphthalimide moiety at the N terminus of 2. Hybrid 3 targeted 5'-CGATTGGT and covered eight contiguous base pairs, which included the underlined ICB2 site. DNase I footprinting analysis with the topoIIalpha promoter sequence demonstrated that 3 bound selectively to the ICB2 and ICB3 sites. Thermal-denaturation studies confirmed these results, and the highest degree of stabilization was found for ICB2 and -3 in preference to ICB1 (4.1, 4.6, and 0.6 degrees C, respectively). CD studies confirmed minor-groove binding and suggested a 1:1 binding stoichiometry. Emission-titration experiments established intercalative binding. Surface plasmon resonance results showed strong binding to ICB2 (2.5x10(7) M(-1)) with no observable binding to ICB1. Furthermore, the binding constant of 3 to ICB2 was larger than that of the parent polyamide 2. The increased binding affinity was primarily due to a reduction in the dissociation-rate constant of the polyamide-DNA complex, which can be attributed to the N-terminal naphthalimide moiety. In addition, the binding site of 3 was larger than that of 2, which innately improved sequence selectivity. We conclude that the polyamide-naphthalimide 3 selectively binds to the ICB2 site by simultaneous intercalation and minor-groove binding, and warrants further investigation as a model compound for the regulation of topoIIalpha gene expression.

Design of a hairpin polyamide, ZT65B, for targeting the inverted CCAAT box (ICB) site in the multidrug resistant (MDR1) gene.

A novel hairpin polyamide, ZT65B, containing a 3-methylpicolinate moiety was designed to target the inverted CCAAT box (ICB) of the human multidrug resistance 1 gene (MDR1) promoter. Binding of nuclear factor-Y (NF-Y) to the ICB site upregulates MDR1 gene expression and is, therefore, a good target for anticancer therapeutic agents. However, it is important to distinguish amongst different promoter ICB sites so that only specific genes will be affected. All ICB sites have the same sequence but they differ in the sequence of the flanking base pairs, which can be exploited in the design of sequence-specific polyamides. To test this hypothesis, ten ICB-containing DNA hairpins were designed with different flanking base pairs; the sequences ICBa and ICBb were similar to the 3'-ICB site of MDR1 (TGGCT). Thermal-denaturation studies showed that ZT65B effectively targeted ICBa and ICBb (DeltaTM=6.5 and 7.0 degrees C) in preference to the other DNA hairpins (<3.5 degrees C), with the exception of ICBc (5.0 degrees C). DNase I-footprinting assays were carried out with the topoisomerase IIalpha-promoter sequence, which contains five ICB sites; of these, ICB1 and ICB5 are similar to the ICB site of MDR1. ZT65B was found to selectively bind ICB1 and ICB5; footprints were not observed with ICB2, ICB3, or ICB4. A strong, positive induced ligand band at 325 nm in CD studies confirmed that ZT65B binds in the DNA minor groove. The selectivity of ZT65B binding to hairpins that contained the MDR1 ICB site compared to one that did not (ICBd) was confirmed by surface-plasmon studies, and equilibrium constants of 5x10(6)-1x10(7) and 4.6x10(5) M-1 were obtained with ICB1, ICB5,and ICB2 respectively. ZT65B and the previously published JH37 (J. A. Henry, et al. Biochemistry 2004, 43, 12 249-12 257) serve as prototypes for the design of novel polyamides. These can be used to specifically target the subset of ubiquitous gene elements known as ICBs, and thereby affect the expression of one or a few proteins.

Molecular recognition of DNA base pairs by the formamido/pyrrole and formamido/imidazole pairings in stacked polyamides.

Polyamides containing an N-terminal formamido (f) group bind to the minor groove of DNA as staggered, antiparallel dimers in a sequence-specific manner. The formamido group increases the affinity and binding site size, and it promotes the molecules to stack in a staggered fashion thereby pairing itself with either a pyrrole (Py) or an imidazole (Im). There has not been a systematic study on the DNA recognition properties of the f/Py and f/Im terminal pairings. These pairings were analyzed here in the context of f-ImPyPy, f-ImPyIm, f-PyPyPy and f-PyPyIm, which contain the central pairing modes, -ImPy- and -PyPy-. The specificity of these triamides towards symmetrical recognition sites allowed for the f/Py and f/Im terminal pairings to be directly compared by SPR, CD and DeltaT (M) experiments. The f/Py pairing, when placed next to the -ImPy- or -PyPy- central pairings, prefers A/T and T/A base pairs to G/C base pairs, suggesting that f/Py has similar DNA recognition specificity to Py/Py. With -ImPy- central pairings, f/Im prefers C/G base pairs (>10 times) to the other Watson-Crick base pairs; therefore, f/Im behaves like the Py/Im pair. However, the f/Im pairing is not selective for the C/G base pair when placed next to the -PyPy- central pairings.

Extending the language of DNA molecular recognition by polyamides: unexpected influence of imidazole and pyrrole arrangement on binding affinity and specificity.

Pyrrole (Py) and imidazole (Im) polyamides can be designed to target specific DNA sequences. The effect that the pyrrole and imidazole arrangement, plus DNA sequence, have on sequence specificity and binding affinity has been investigated using DNA melting (DeltaT(M)), circular dichroism (CD), and surface plasmon resonance (SPR) studies. SPR results obtained from a complete set of triheterocyclic polyamides show a dramatic difference in the affinity of f-ImPyIm for its cognate DNA (K(eq) = 1.9 x 10(8) M(-1)) and f-PyPyIm for its cognate DNA (K(eq) = 5.9 x 10(5) M(-1)), which could not have been anticipated prior to characterization of these compounds. Moreover, f-ImPyIm has a 10-fold greater affinity for CGCG than distamycin A has for its cognate, AATT. To understand this difference, the triamide dimers are divided into two structural groupings: central and terminal pairings. The four possible central pairings show decreasing selectivity and affinity for their respective cognate sequences: -ImPy > -PyPy- >> -PyIm- approximately -ImIm-. These results extend the language of current design motifs for polyamide sequence recognition to include the use of "words" for recognizing two adjacent base pairs, rather than "letters" for binding to single base pairs. Thus, polyamides designed to target Watson-Crick base pairs should utilize the strength of -ImPy- and -PyPy- central pairings. The f/Im and f/Py terminal groups yielded no advantage for their respective C/G or T/A base pairs. The exception is with the -ImPy- central pairing, for which f/Im has a 10-fold greater affinity for C/G than f/Py has for T/A.

Tris-borate is a poor counterion for RNA: a cautionary tale for RNA folding studies.

Native polyacrylamide gel electrophoresis is a powerful approach for visualizing RNA folding states and folding intermediates. Tris-borate has a high-buffering capacity and is therefore widely used in electrophoresis-based investigations of RNA structure and folding. However, the effectiveness of Tris-borate as a counterion for RNA has not been systematically investigated. In a recirculated Hepes/KCl buffer, the catalytic core of the bI5 group I intron RNA undergoes a conformational collapse characterized by a bulk transition midpoint, or Mg1/2, of approximately 3 mM, consistent with extensive independent biochemical experiments. In contrast, in Tris-borate, RNA collapse has a much smaller apparent Mg1/2, equal to 0.1 mM, because in this buffer the RNA undergoes a different, large amplitude, folding transition at low Mg2+ concentrations. Analysis of structural neighbors using a short-lived, RNA-tethered, photocrosslinker indicates that the global RNA structure eventually converges in the two buffer systems, as the divalent ion concentration approaches approximately 1 mM Mg2+. The weak capacity of Tris-borate to stabilize RNA folding may reflect relatively unfavorable interactions between the bulky Tris-borate ion and RNA or partial coordination of RNA functional groups by borate. Under some conditions, Tris-borate is a poor counterion for RNA and its use merits careful evaluation in RNA folding studies.

Targeting the inverted CCAAT box 2 in the topoisomerase IIalpha promoter by JH-37, an imidazole-pyrrole polyamide hairpin: design, synthesis, molecular biology, and biophysical studies.

The topoisomerase IIalpha promoter is regulated through transcription factor interactions with five inverted CCAAT boxes (ICBs). In confluent cancer cells, binding of nuclear factor Y to ICB2 represses the expression of this gene, contributing to resistance to topoisomerase II poisons. The ICB sites within the topoisomerase IIalpha promoter are, therefore, potential targets for the design of anticancer drugs and gene control agents. The synthesis and DNA binding properties of a hairpin polyamide molecule (JH-37) that targets 5'-TTGGT-3' found in ICB2 and ICB3 sites are described. Gel shift and DNase I footprinting studies on the topoisomerase IIalpha promoter showed JH-37 to preferentially bind to ICB2,3 and ICB1 sites. The larger DeltaT(M) values for ICB2,3 (8-9 degrees C) over ICB1,4,5 (4-5 degrees C) indicated a preference of JH-37 for ICB2,3. CD titration studies confirmed the binding of JH-37 to the minor groove, with a 1:1 binding stoichiometry. Results from SPR studies showed JH-37 to bind most strongly to ICB2 (K = 3 x 10(7) M(-1)), followed by ICB1, the non-ICB sequence (TGCA), and finally the ICB mutant (ICB2m). The improved binding to ICB2 is largely due to a lower dissociation rate of the compound at the preferred site. To our knowledge, this is the first example on the use of SPR for studying the interactions of hairpin polyamides with DNA. Binding of JH-37 to ICB2 was corroborated by ITC studies, in which the DeltaG degrees of binding is driven by both enthalpy and entropy. With knowledge of the fundamental thermodynamic and kinetic properties that govern the molecular recognition of polyamides with DNA, we are poised to systematically edit the structure of JH-37 in order to further enhance its binding affinity and selectivity for ICB2,3. Our strategy for designing molecules that control gene expression is to target shorter, but multiple, binding sites that are in close array within the promoter. Binding of JH-37 to multiple ICB sites in the topoisomerase IIalpha promoter is an ideal test for this strategy. This approach is in contrast to the traditional strategy of targeting 15-16 base pairs, which has not been successful in actual biological systems due to poor cell uptake and distribution.

Near native structure in an RNA collapsed state.

Many large RNAs form conformationally collapsed, but non-native, states prior to folding to the native state or assembling with protein cofactors. Although RNA collapsed states play fundamental roles in RNA folding and ribonucleoprotein assembly processes, their structures have been poorly understood. We obtained 12 high-quality structural constraints for the collapsed state formed by the catalytic core of the bI5 intron RNA using site-specific cross-linking mediated by a short-lived reactant. RNA tertiary structures in the collapsed and native states are indistinguishable, even though only the native state forms a solvent-inaccessible core. Thus, structural neighbors in the collapsed state, including several long-range tertiary interactions, are approximately as close in space as in the native state, but RNA packing is sufficiently loose or dynamic to allow access by solvent. Binding by the obligate CBP2 protein cofactor has almost no effect on structural neighbors reported by cross-linking, even though protein binding chases the RNA from the collapsed state to the native state. Protein binding thus appears to promote only the final few angstroms of RNA folding rather than mediate global conformational rearrangements in the catalytic core. The bI5 RNA collapsed state functions to self-chaperone ribonucleoprotein assembly because this conformationally restrained structure lies very near that of the native state and excludes structures that otherwise misassemble efficiently.

RNA-tethered phenyl azide photocrosslinking via a short-lived indiscriminant electrophile.

Arylazide mediated photocrosslinking has been widely used to obtain structural constraints in biological systems, even though the reactive species generated upon photolysis in aqueous solution have not been well characterized. We establish a mechanistic framework for formation of adducts between photoactivated 3-hydroxyphenyl azide and RNA. Tethered to an internal site in an RNA duplex via a 2'-amido linkage, photolysis of the aryl azide yields a cross-strand cross-link. Analysis of the ability of reagents with diagnostic reactivities to intercept formation of this cross-strand cross-link supports the assignment that the photoactivated intermediate is the ketenimine or a ketenimine-derived ring expansion product. Neither the initially produced singlet nitrene nor the subsequently formed triplet nitrene contribute to cross-link formation. Argon matrix and time-resolved solution experiments show that photolysis of free 3-hydroxyphenyl azide releases (in