Artificial Metalloenzymes with the Neocarzinostatin Scaffold: Toward a Biocatalyst for the Diels-Alder Reaction.

A copper(II) cofactor coupled to a testosterone anchor, copper(II)-(5-(Piperazin-1-yl)-1,10-phenanthroline)testosterone-17-hemisuccinamide (10) was synthesized and associated with a neocarzinostatin variant, NCS-3.24 (KD =3 µm), thus generating a new artificial metalloenzyme by following a "Trojan horse" strategy. Interestingly, the artificial enzyme was able to efficiently catalyze the Diels-Alder cyclization reaction of cyclopentadiene (1) with 2-azachalcone (2). In comparison with what was observed with cofactor 10 alone, the artificial enzymes favored formation of the exo products (endo/exo ratios of 84:16 and 62:38, respectively, after 12 h). Molecular modeling studies assigned the synergy between the copper complex and the testosterone (KD =13 µm) moieties in the binding of 10 to good van der Waals complementarity. Moreover, by pushing the modeling exercise to its limits, we hypothesize on the molecular grounds that are responsible for the observed selectivity.

Neocarzinostatin-based hybrid biocatalysts with a RNase like activity.

A new zinc(II)-cofactor coupled to a testosterone anchor, zinc(II)-N,N-bis(2-pyridylmethyl)-1,3-diamino-propa-2-ol-N'(17'-succinimidyltestosterone) (Zn-Testo-BisPyPol) 1-Zn has been synthesized and fully characterized. It has been further associated with a neocarzinostatin variant, NCS-3.24, to generate a new artificial metalloenzyme following the so-called 'Trojan horse' strategy. This new 1-Zn-NCS-3.24 biocatalyst showed an interesting catalytic activity as it was found able to catalyze the hydrolysis of the RNA model HPNP with a good catalytic efficiency (kcat/KM=13.6M(-1)s(-1) at pH 7) that places it among the best artificial catalysts for this reaction. Molecular modeling studies showed that a synergy between the binding of the steroid moiety and that of the BisPyPol into the protein binding site can explain the experimental results, indicating a better affinity of 1-Zn for the NCS-3.24 variant than testosterone and testosterone-hemisuccinate themselves. They also show that the artificial cofactor entirely fills the cavity, the testosterone part of 1-Zn being bound to one the two subdomains of the protein providing with good complementarities whereas its metal ion remains widely exposed to the solvent which made it a valuable tool for the catalysis of hydrolysis reactions, such as that of HPNP. Some possible improvements in the 'Trojan horse' strategy for obtaining better catalysts of selective reactions will be further studied.

Evaluating the use of Apo-neocarzinostatin as a cell penetrating protein.

Protein-ligand complex neocarzinostatin (NCS) is a small, thermostable protein-ligand complex that is able to deliver its ligand cargo into live mammalian cells where it induces DNA damage. Apo-NCS is able to functionally display complementarity determining regions loops, and has been hypothesised to act as a cell-penetrating protein, which would make it an ideal scaffold for cell targeting, and subsequent intracellular delivery of small-molecule drugs. In order to evaluate apo-NCS as a cell penetrating protein, we have evaluated the efficiency of its internalisation into live HeLa cells using matrix-assisted laser-desorption ionization-time-of-flight mass spectrometry and fluorescence microscopy. Following incubation of cells with apo-NCS, we observed no evidence of internalisation.

Thiols screened by the neocarzinostatin protein for preserving or detoxifying its bound enediyne antibiotic.

Neocarzinostatin is an antibiotic chromoprotein produced by Streptomyces carzinostaticus. Its enediyne-containing chromophore exhibits high DNA cleavage activity and belongs to one of the most potent categories of antitumor agents. The labile chromophore is readily inactivated by environmental thiols including the most abundant glutathione. How the microorganism preserves the secreted antibiotic and at the same time is immune to its toxicity are of interest. Site-directed mutagenesis studies of the neocarzinostatin protein have shown that residues D33 and D99 play primary and secondary roles, respectively, in preserving neocarzinostatin from acidic glutathione whereas D79 and other residues around the opening of the binding cleft have an insignificant effect. Biothiol analyses revealed that cells of S. carzinostaticus produced no glutathione, but instead neutral mycothiol, which is known to serve functions analogous to glutathione. Mycothiol was the only neutral-charged thiol produced by the organism; all other identified biothiols carried at least partial negative charges. When the bacteria were cultured under conditions that stimulated the biosynthesis of neocarzinostatin, the yield of mycothiol increased significantly, which suggests mycothiol-dependent cellular detoxification. Treating neocarzinostatin samples with the cell extract that retained active sulfhydryls led to efficient drug inactivation, which indicates that mycothiol is allowed to approach the protein-bound chromophore. The anionic side-chains of D33 and D99 in the neocarzinostatin protein played two critical roles in a single thiol-screening operation: Preserving the antibiotic for defense and survival by rejecting the ubiquitous glutathione through charge-charge repulsion in the outer-cell environment and detoxifying the toxin in the inner-cell body for self-resistance by accepting the cell-produced neutral mycothiol.

Lipid bilayer-assisted release of an enediyne antibiotic from neocarzinostatin chromoprotein.

The nine-membered enediyne class has drawn extensive interest because of extremely high antitumor potency and intricate interactions with its carrier protein. While the drug-induced DNA cleavage reactions have been mostly elucidated, the critical release-transport process of the labile enediyne molecule in cellular environment remained obscure. Using neocarzinostatin chromoprotein as a model, we demonstrated a lipid bilayer-assisted release mechanism. The in vitro enediyne release rate under aqueous conditions was found to be too slow to account for its efficient DNA cleavage action. Via the presence of lipid bilayers, chaotropic agents, or organic solvents, we found the release was substantially enhanced. The increased rate was linearly dependent on the lipid bilayer concentration and the dielectric value of the binary organic solvent mixtures. While lipid bilayers provided a low surrounding dielectricity to assist in drug release, there were no major conformational changes in the apo and holo forms of the carrier protein. In addition, the lifespan of the released enediyne chromophore was markedly extended through partitioning of the chromophore in the hydrophobic bilayer phase, and the lipid bilayer-stabilized enediyne chromophore significantly enhanced DNA cleavage in vitro. Collectively, we depicted how a lipid bilayer membrane efficiently enhanced dissociation of the enediyne chromophore through a hydrophobic sensing release mechanism and then acted as a protector of the released enediyne molecule until its delivery to the target DNA. The proposed membrane-assisted antibiotic release-transport model might signify a new dimension to our understanding of the modus operandi of the antitumor enediyne drugs.

Insight into the strong inhibitory action of salt on activity of neocarzinostatin.

Enediyne anticancer drugs belong to one of the most potent category in inducing DNA damage. We report 85+/-5% inhibition on activity of neocarzinostatin by salt. As high sodium ion concentration is a known tumor cell feature, we explored the dynamic mechanism of inhibition. Using various analytical tools, we examined parameters involved in the four consecutive steps of the drug action, namely, drug releasing from carrier protein, drug-DNA binding, drug activating, and DNA damaging. Neither protein stability, nor drug release rate, was altered by salt. The salt inhibition level was similar in between the protein-bound and unbound enediyne chromophore. Salt did not quench the thiol-induced drug activation. The inhibition was independent of DNA lesion types and irrelevant with thiol structures. Collectively, no salt interaction was found in the releasing, activating, and DNA damaging step of the drug action. However, binding with DNA decreased linearly with salt and corresponded well with the salt-induced inhibition on the drug activity. Salt interference on the affinity of DNA binding was the main and sole cause of the severe salt inhibition. The inhibition factor should be carefully considered for all agents with similar DNA binding mode.

Molecular dynamics simulations investigation of neocarzinostatin chromophore-releasing pathways from the holo-NCS protein.

The enediyne ring chromophore with strong DNA cleavage activity of neocarzinostatin is labile and therefore stabilization by forming the complex (carrying protein+chromophore: holo-NCS). Holo-NCS has gained much attention in clinical use as well as for drug delivery systems, but the chromophore-releasing mechanism to trigger binding to the target DNA with high affinity and producing DNA damage remain unclear. Three possible pathways were initially determined by conventional MD, essential dynamics and essential dynamics sampling. One of the paths runs along the naphthoate moiety; another runs along the amino sugar moiety; the third along the enediyne ring. Further, calculated forces and time by FPMD (force-probe molecular dynamics) suggest that the opening of the naphthoate moiety is most favorable pathway and Leu45, Phe76 and Phe78 all are key residues for chromophore release. In addition, conformational analyses indicate that the chromophore release is only local motions for the protein.

Molecular basis of substrate promiscuity for the SAM-dependent O-methyltransferase NcsB1, involved in the biosynthesis of the enediyne antitumor antibiotic neocarzinostatin.

The small molecule component of chromoprotein enediyne antitumor antibiotics is biosynthesized through a convergent route, incorporating amino acid, polyketide, and carbohydrate building blocks around a central enediyne hydrocarbon core. The naphthoic acid moiety of the enediyne neocarzinostatin plays key roles in the biological activity of the natural product by interacting with both the carrier protein and duplex DNA at the site of action. We have previously described the in vitro characterization of an S-adenosylmethionine-dependent O-methyltransferase (NcsB1) in the neocarzinostatin biosynthetic pathway [Luo, Y., Lin, S., Zhang, J., Cooke, H. A., Bruner, S. D., and Shen, B. (2008) J. Biol. Chem. 283, 14694-14702]. Here we provide a structural basis for NcsB1 activity, illustrating that the enzyme shares an overall architecture with a large family of S-adenosylmethionine-dependent proteins. In addition, NcsB1 represents the first enzyme to be structurally characterized in the biosynthetic pathway of neocarzinostatin. By cocrystallizing the enzyme with various combinations of the cofactor and substrate analogues, details of the active site structure have been established. Changes in subdomain orientation were observed via comparison of structures in the presence and absence of substrate, suggesting that reorientation of the enzyme is involved in binding of the substrate. In addition, residues important for substrate discrimination were predicted and probed through site-directed mutagenesis and in vitro biochemical characterization.

Disulfide bond substitution by directed evolution in an engineered binding protein.

Breaking ties: The antitumour protein, neocarzinostatin (NCS), is one of the few drug-carrying proteins used in human therapeutics. However, the presence of disulfide bonds limits this protein's potential development for many applications. This study describes a generic directed-evolution approach starting from NCS-3.24 (shown in the figure complexed with two testosterone molecules) to engineer stable disulfide-free NCS variants suitable for a variety of purposes, including intracellular applications.The chromoprotein neocarzinostatin (NCS) has been intensively studied for its antitumour properties. It has recently been redesigned as a potential drug-carrying scaffold. A potential limit of this protein scaffold, especially for intracellular applications, is the presence of disulfide bonds. The objective of this work was to create a disulfide-free NCS-derived scaffold. A generic targeted approach was developed by using directed evolution methods. As a starting point we used a previously engineered NCS variant in which a hapten binding site had been created. A library was then generated in which cysteine Cys88 and Cys93 and neighbouring residues were randomly substituted. Variants that preserved the hapten binding function were selected by phage display and further screened by colony filtration methods. Several sequences with common features emerged from this process. The corresponding proteins were expressed, purified and their biophysical properties characterised. How these selected sequences rescued folding ability and stability of the disulfide-free protein was carefully examined by using calorimetry and the results were interpreted with molecular simulation techniques.

Is association of labile enediyne chromophore a mutually assured protection for carrier protein?

Most conjugate proteins undergo both conformational and stability changes on ligand removal. When architecture remains unchanged in the protein holo and apo forms, it is uncertain whether the protein stability also remains unaltered in both of the forms. Neocarzinostatin (NCS), a chromoprotein possessing a potent enediyne chromophore stands for such an instance. Protein-chromophore interaction has not been thoroughly explored previously due to a lack of strategies to independently and simultaneously monitor changes in the NCS conjugates. Here we report a method by which one can detect the signal exclusively from only one of the NCS conjugates without the spectral interference from the other. Stability of the NCS protein is significantly correlated to the protein-bound chromophore, irrespective of denaturation by heat, pH, urea, or ethanol. Despite the similarity in protein backbone conformation, protein stability of the NCS holo form diminishes and equalizes to that of the apo form when the chromophore is released and degraded. Although the enediyne chromophore is highly unstable, it intriguingly protects the protein by which it is protected. Significant mutual reliance between the carrier protein and its naturally associated ligand unveils important information on the NCS drug stability.

The radiomimetic enediyne C-1027 induces unusual DNA damage responses to double-strand breaks.

Cells lacking the protein kinase ataxia telangiectasia mutated (ATM) have defective responses to DNA double-strand breaks (DSBs), including an inability to activate damage response proteins such as p53. However, we previously showed that cells lacking ATM robustly activate p53 in response to DNA strand breaks induced by the radiomimetic enediyne C-1027. To gain insight into the nature of C-1027-induced ATM-independent damage responses to DNA DSBs, we further examined the molecular mechanisms underlying the cellular response to this unique radiomimetic agent. Like ionizing radiation (IR) and other radiomimetics, breaks induced by C-1027 efficiently activate ATM by phosphorylation at Ser1981, yet unlike other radiomimetics and IR, DNA breaks induced by C-1027 result in normal phosphorylation of p53 and the cell cycle checkpoint kinases (Chk1 and Chk2) in the absence of ATM. In the presence of ATM, but under ATM and Rad3-related kinase (ATR) deficient conditions, C-1027 treatment resulted in a decrease in the level of Chk1 phosphorylation but not in the level of p53 and Chk2 phosphorylation. Only when cells were deficient in both ATM and ATR was there a reduction in the level of phosphorylation of each of these DNA damage response proteins. This reduction was also accompanied by an increased level of cell death in comparison to that of wild-type cells or cells lacking either ATM or ATR. Our findings demonstrate a unique cellular response to C-1027-induced DNA DSBs in that DNA damage response proteins are unaffected by the absence of ATM, as long as ATR is present.

Structures of in vitro evolved binding sites on neocarzinostatin scaffold reveal unanticipated evolutionary pathways.

We have recently applied in vitro evolution methods to create in Neocarzinostatin a new binding site for a target molecule unrelated to its natural ligand. The main objective of this work was to solve the structure of some of the selected binders in complex with the target molecule: testosterone. Three proteins (1a.15, 3.24 and 4.1) were chosen as representative members of sequence families that came out of the selection process within different randomization schemes. In order to evaluate ligand-induced conformational adaptation, we also determined the structure of one of the proteins (3.24) in the free and complexed forms. Surprisingly, all these mutants bind not one but two molecules of testosterone in two very different ways. The 3.24 structure revealed that the protein spontaneously evolved in the system to bind two ligand molecules in one single binding crevice. These two binding sites are formed by substituted as well as by non-variable side-chains. The comparison with the free structure shows that only limited structural changes are observed upon ligand binding. The X-ray structures of the complex formed by 1a.15 and 4.1 Neocarzinostatin mutants revealed that the two variants form very similar dimers. These dimers were observed neither for the uncomplexed variants nor for wild-type Neocarzinostatin but were shown here to be induced by ligand binding. Comparison of the three complexed forms clearly suggests that these unanticipated structural responses resulted from the molecular arrangement used for the selection experiments.

Synthetic ligands for apo-neocarzinostatin.

Neocarzinostatin (NCS) is a 1:1 complex of an enediyne chromophore (NCSChrom), non-covalently bound to an 11 kDa protein (apoNCS). We are exploring apoNCS as a generic protein system for sequestering small molecules for therapeutic applications. Here, we disclose a new flavone ligand 1 for apoNCS and present a high-resolution NMR structure of this ligand bound to apoNCS. This is the first high-resolution structure of a completely non-cognate ligand bound to the apoNCS protein. This work provides unambiguous evidence that a completely new class of ligand can bind specifically to apoNCS. Furthermore, the mode of binding is different than that of the naphthoate-based ligands, and for such a simple hydrophobic compound, the new ligand surprisingly binds specifically. This work indicates that apo-Neocarzinostatin has multiple selective and distinct binding modes for small-molecule cargo.

Interaction of bulged DNA with leucine-containing mimics of NCS-chrom.

Synthesis of chiral spirocyclic helical compounds containing leucine that mimic the molecular architecture of the potent DNA bulge binder obtained from the natural product metabolite NCSi-gb has been accomplished. The interaction between the compounds and DNA was studied by circular dichroism (CD) method. The results suggested that the two synthetic diastereoisomers specifically targeted the bulge site of DNA and induced conformational change of bulged DNA greatly.

Affinity transfer by CDR grafting on a nonimmunoglobulin scaffold.

Neocarzinostatin (NCS) is a small "all beta" protein displaying the same overall fold as immunoglobulins. This protein possesses a well-defined hydrophobic core and two loops structurally equivalent to the CDR1 and CDR3 of immunoglobulins. NCS is the most studied member of the enediynechromoprotein family, and is clinically used as an antitumoral agent. NCS has promise as a drug delivery vehicle if new binding specificities could be conferred on its protein scaffold. Previous studies have shown that the binding specificity of the crevasse can be extended to compounds completely unrelated to the natural enediyne chromophore family. We show here that it is possible to introduce new interaction capacities to obtain a protein useful for drug targeting by modifying the immunoglobulin CDR-like loops. We transferred the CDR3 of the VHH chain of camel antilysozyme immunoglobulin to the equivalent site in the corresponding loop of neocarzinostatin. We then evaluated the stability of the resulting structure and its affinity for lysozyme. The engineered NCS-CDR3 presents a structure similar to that of the wild-type NCS, and is stable and efficiently produced. ELISA, ITC, and SPR measurements demonstrated that the new NCS-CDR3 specifically bound lysozyme.

Role of the tyrosine corner motif in the stability of neocarzinostatin.

Although the immunoglobulin-like beta-sandwich fold has no specifically conserved function, some common structural features have been observed, in particular a structural motif, the tyrosine corner. Such a motif was described in neocarzinostatin (NCS), a bacterial protein the structure of which is very similar to that of the immunoglobulin domain. Compared with the other beta-sheet proteins, the NCS 'tyrosine corner' presents non-standard structural features. To investigate the role of this motif in the NCS structure and stability, we studied the properties of a mutant where the H bond interaction had been eliminated by replacing the tyrosine with a phenylalanine. This mutation costs 4.0 kcal/mol showing that the NCS 'tyrosine corner' is involved in protein stability as in the other Greek key proteins. This destabilization is accompanied by remote structural effects, including modification of the binding properties, suggesting an increase in the internal flexibility of the protein. With a view to using this protein for drug targeting, these results along with those obtained previously allow us to define clearly the limitations of the modifications that can be performed on this scaffold.

In vitro evolution of the binding specificity of neocarzinostatin, an enediyne-binding chromoprotein.

Neocarzinostatin is the most studied member of the enediyne-chromoprotein family, and is clinically used as an antitumoral agent. Neocarzinostatin could be a promising drug delivery vehicle if new binding specificities could be conferred to its protein scaffold. We used in vitro evolution methods to demonstrate that this approach is feasible. We created large libraries containing between 1.7 x 10(8) and 1.4 x 10(9) independent clones, where up to 13 side chains pointing toward the binding crevice were randomly substituted. We then used phage display to select variants that bind to a model ligand (testosterone) which is unrelated to the natural ligand of neocarzinostatin. Several different binders were selected from each library. The corresponding proteins were expressed in Escherichia coli and their affinities and specificities were characterized in detail. K(D) values of about 20 nM were obtained for streptavidin-bound testosterone. The K(D) of selected proteins for free soluble testosterone are between 7 and 55 microM and therefore higher than the K(D) for streptavidin-bound testosterone. The spacer and streptavidin used during selection contributed to the high affinity of the selected binders for the target. Binding studies of 15 different steroids related to testosterone allowed us to determine that C3, 4, 5, 6, and 7 on cycles A and B and the conjugated 3 oxo group of the steroid molecule were essential for molecular recognition. Other testosterone analogues substituted on C1, 2, 9, 11, 15, and 17 were not discriminated from testosterone. These results demonstrate that the binding specificity of this protein family can be extended to compounds that are completely unrelated to the natural enediyne chromophore family. This type of highly expressed, stable proteins with tailored binding properties have a wide potential range of applications.

Design, production, and characterization of recombinant neocarzinostatin apoprotein in Escherichia coli.

Neocarzinostatin (NCS) is the first discovered anti-tumor antibiotic having an enediyne-containing chromophore and an apoprotein with a 1:1 complex. An artificial gene library for NCS apoprotein (apo-NCS) production in Escherichia coli was designed and constructed on a phage-display vector, pJuFo. The recombinant phages expressing pre-apo-NCS protein were enriched with a mouse anti-apo-NCS monoclonal antibody, 1C7D4. The apo-NCS gene (encsA) for E. coli was successfully cloned, and then re-cloned into the pRSET A vector. After the his-tagged apo-NCS protein had been purified and cleaved with enterokinase, the binding properties of the recombinant protein as to ethidium bromide (EtBr) were studied by monitoring of total fluorescence intensity and fluorescence polarization with a BEACON 2000 system and GraphPad Prism software. A dissociation constant of 4.4 +/- 0.3 microM was obtained for recombinant apo-NCS in the fluorescence polarization study. This suggests that fluorescence polarization monitoring with EtBr as a chromophore mimic may be a simplified method for the characterization of recombinant apo-NCS binding to the NCS chromophore. When Phe78 on apo-NCS was substituted with Trp78 by site-directed mutagenesis using a two stage megaprimer polymerase chain reaction, the association of the apo-NCS mutant and EtBr observed on fluorescence polarization analysis was of the same degree as in the case of the wild type, although the calculated maximum change (DeltaIT(max)) in total fluorescence intensity decreased from 113.9 to 31.3. It was suggested that an environmental change of the bound EtBr molecule on F78W might have dramatically occurred as compared with in the case of wild type apo-NCS. This combination of monitoring of fluorescence polarization and total fluorescence intensity will be applicable for determination and prediction of the ligand state bound or associated with the target protein. The histone-specific proteolytic activity was also re-investigated using this recombinant apo-NCS preparation, and calf thymus histone H1, H2A, H2B, H3, and H4. The recombinant apo-NCS does not act as a histone protease because a noticeable difference was not observed between the incubation mixtures with and without apo-NCS under our experimental conditions.

Induced formation of a DNA bulge structure by a molecular wedge ligand-postactivated neocarzinostatin chromophore.

Our previous structure elucidation of the complexes of DNA and postactivated neocarzinostatin chromophore (NCS-chrom) compounds revealed two distinctly different binding modes of this antitumor molecule. A thorough understanding of these results will provide the molecular basis for the binding and DNA chain cleavage properties of NCS-chrom. NCSi-gb is one of the postactivated mimics of NCS-chrom which is formed under thiol-free conditions and is able to bind to DNA. This report describes the structure refinement of the NCSi-gb-bulge-DNA complex [Stassinopoulos, A., Jie, J., Gao, X., and Goldberg, I. H. (1996) Science 272, 1943-1946] and the NMR characterization of the free bulge-DNA and free NCSi-gb. These results reveal that the formation of the complex involves conformational changes in both the DNA and the ligand molecule. Of mechanistic importance for the NCS-chrom-DNA interaction, the two ring systems of the drug are brought closer to each other in the complex. This conformation correlates well with the previously observed marked enhancement of the formation of a DNA bulge cleaving species in the presence of bulge-DNA sequences, due to the promotion of the intramolecular radical quenching of the activated NCS-chrom. Interestingly, the binding of NCSi-gb promotes the formation of a bulge binding pocket; this was not found in the unbound DNA. NCS-chrom is unique among the enediyne antibiotics in its ability to undergo two different mechanisms of activation to form two different DNA binding and cleaving species. The two corresponding DNA complexes are compared. One, the bulge-DNA binder NCSi-gb, involves the major groove, and the second, the duplex binder NCSi-glu which is generated by glutathione-induced activation, involves the minor groove. Since the two NCS-chrom-related ligand molecules contain some common chemical structural elements, such as the carbohydrate ring, the striking differences in their DNA recognition and chain cleavage specificity provide insights into the fundamental principles of DNA recognition and ligand design.

Recognition of bulged DNA by a neocarzinostatin product via an induced fit mechanism.

The binding of the wedge-shaped isostructural analogue of the biradical species of the chromphore of antitumor antibiotic neocarzinostatin to sequence-specific bulged DNAs results in alterations in ellipticity of the DNAs. Circular dichroism (CD) spectroscopic results suggest that the drug specifically recognizes bulges of DNA via a combination of conformational selection and induced fit, not by binding to a preorganized site. Analysis of circular dichroism spectra indicates that the degree of induced fit observed is primarily a consequence of optimising van der Waals contacts with the walls of the bulge cavity. The effective recognition of the bulge site on duplex DNA appears to depend to a significant extent on the bent groove space being flexible enough to be able to adopt the geometrically optimal conformation compatible with the wedge-shaped drug molecule, rather than involving 'lock and key' recognition. The spectroscopic results indicate a change of DNA conformation, consistent with an allosteric binding model. Spectroscopic studies with various bulged DNAs also reveal that the binding strength directly correlates with the stability of the bulge structures.