Recognition of Nucleic Acid Junctions Using Triptycene‐Based Molecules

The modulation of nucleic acids by small molecules is an essential process across the kingdoms of life. Targeting nucleic acids with small molecules represents a significant challenge at the forefront of chemical biology. Nucleic acid junctions are ubiquitous structural motifs in nature and in designed materials. Herein, we describe a new class of structure‐specific nucleic acid junction stabilizers based on a triptycene scaffold. Triptycenes provide significant stabilization of DNA and RNA three‐way junctions, providing a new scaffold for the development of nucleic acid junction binders with enhanced recognition properties. Additionally, we report cytotoxicity and cell uptake data in two human ovarian carcinoma cell lines.     

Microarrays of tagged combinatorial triazine libraries in the discovery of small-molecule ligands of human IgG

A novel and highly diverse tagged triazine library incorporating a triethylene glycol-based linker was synthesized using an orthogonal combinatorial approach on the solid phase and covalently immobilized on a glass substrate as a small molecule microarray (SMM). The SMM was screened with a fluorophore-conjugated human IgG, and 4 novel binders from a library of 2688 compounds were identified from the fully spatially addressable array without the need for compound decoding. Using surface plasmon resonance (SPR) analysis, binding seen on the array was confirmed, and a binding constant as low as Kd = 2.02 x10(-6) M was measured.     

Screening of Minimalist Noncanonical Sites in Duplex DNA and RNA Reveals Context and Motif-Selective Binding by Fluorogenic Base Probes

We hypothesize that programmable hybridization to noncanonical nucleic acid motifs may be achieved by macromolecular display of binders to individual noncanonical pairs (NCPs). As each recognition element may individually have weak binding to an NCP, we developed a semi-rational approach to detect low affinity interactions between selected nitrogenous bases and noncanonical sites in duplex DNA and RNA. A set of fluorogenic probes was synthesized by coupling abiotic (triazines, pyrimidines) and native RNA bases to thiazole orange (TO) dye. This probe library was screened against duplex nucleic acid substrates bearing single abasic, single NCP, and tandem NCP sites. Probe engagement with NCP sites was reported by 100–1000× fluorescence enhancement over background. Binding is strongly context-dependent, reflective of both molecular recognition and stability: less stable motifs are more likely to bind a synthetic probe. Further, DNA and RNA substrates exhibit entirely different abasic and single NCP binding profiles. While probe binding in the abasic and single NCP screens was monotonous, much richer binding profiles were observed with the screen of tandem NCP sites in RNA, in part due to increased steric accessibility. In addition to known binding interactions between the triazine melamine (M) and T/U sites, the NCP screens identified new targeting elements for pyrimidine-rich motifs in single NCPs and 2×2 internal bulges. We anticipate that semi-rational approaches of this type will lead to programmable noncanonical hybridization strategies at the macromolecular level.     

Strategies for the Design of Drugs Targeting RNA and RNA-Protein Complexes

In many steps of gene replication and expression, RNA molecules participate as key players, which renders them attractive targets for therapeutic intervention. While the function of nucleic acids as carriers of genetic material is based on their sequence, a number of important RNAs are involved in processes that depend on the defined three-dimensional structures of these molecules. As for proteins, numerous complex folds of RNA exist. The development of drugs that bind specifically to RNA folds opens exciting new ways to expand greatly the existing repertoire of protein-targeted therapeutics. Most functions of RNAs involve interactions with proteins that contain RNA-binding domains. Effector molecules targeted at RNA may either alter the functional three-dimensional structure of the nucleic acid, so the interaction with proteins is thereby inhibited or enhanced, or, as interface inhibitors, they may directly prevent the formation of competent RNA-protein complexes. While the same tools used for the design of protein-targeted drugs may be considered for studying effectors binding to nucleic acids, the differences between proteins and RNAs in the forces which dominate their three-dimensional folding call for novel drug design strategies. In the present review, I will outline how our rapidly expanding knowledge of RNA three-dimensional structure and function facilitates rational approaches to develop RNA-binding compounds. Putative RNA targets for therapeutic intervention will be discussed along with recent advances in understanding RNA-small molecule and RNA-protein interactions.     

Validation of an empirical RNA-ligand scoring function for fast flexible docking using RiboDock®

We report the design and validation of a fast empirical function for scoring RNA-ligand interactions, and describe its implementation within RiboDock, a virtual screening system for automated flexible docking. Building on well-known protein-ligand scoring function foundations, features were added to describe the interactions of common RNA-binding functional groups that were not handled adequately by conventional terms, to disfavour non-complementary polar contacts, and to control non-specific charged interactions. The results of validation experiments against known structures of RNA-ligand complexes compare favourably with previously reported methods. Binding modes were well predicted in most cases and good discrimination was achieved between native and non-native ligands for each binding site, and between native and non-native binding sites for each ligand. Further evidence of the ability of the method to identify true RNA binders is provided by compound selection ('enrichment factor') experiments based around a series of HIV-1 TAR RNA-binding ligands. Significant enrichment in true binders was achieved amongst high scoring docking hits, even when selection was from a library of structurally related, positively charged molecules. Coupled with a semi-automated cavity detection algorithm for identification of putative ligand binding sites, also described here, the method is suitable for the screening of very large databases of molecules against RNA and RNA-protein interfaces, such as those presented by the bacterial ribosome.     

Defining the RNA internal loops preferred by benzimidazole derivatives via 2D combinatorial screening and computational analysis

RNA is an important therapeutic target; however, RNA targets are generally underexploited due to a lack of understanding of the small molecules that bind RNA and the RNA motifs that bind small molecules. Herein, we describe the identification of the RNA internal loops derived from a 4096 member 3 × 3 nucleotide loop library that are the most specific and highest affinity binders to a series of four designer, druglike benzimidazoles. These studies establish a potentially general protocol to define the highest affinity and most specific RNA motif targets for heterocyclic small molecules. Such information could be used to target functionally important RNAs in genomic sequence.     

In Vitro Selection of Specific Ligand-binding Nucleic Acids

In vitro selection is a method that allows the simultaneous screening of very large numbers of nucleic acid molecules for a wide range of properties from binding characteristics to catalytic properties; moreover, the isolation of the very rare functional molecules becomes possible. Binding sites between proteins and nucleic acids, for example, have been evaluated by this methodology in order to gain information about protein/nucleic acid interactions. Structure and function of catalytic RNA (“ribozymes”) has been studied by in vitro selection and has led to new ribozymes with improved catalytic function. Substrate specificity of catalytic RNA has been changed and has led to a ribozyme that cleaves DNA. Other applications include the isolation of nucleic acids that bind specifically to small organic molecules and of RNA molecules that form triple helices with double-stranded DNA. In this article we discuss the background, design, and results of in vitro genetic experiments, which bridge biochemical/molecular biological and organic chemical approaches to molecular recognition.     

Quantitative inhibitor fingerprinting of metalloproteases using small molecule microarrays

Current methods to identify interactions on small molecule microarrays (SMMs) introduce false positives that are difficult to dissect from the "real" binding events without tedious downstream re-evaluation. To specifically elucidate only activity-dependent ligand binding interactions, we have developed a technique that can be universally applied to present SMM systems. Our method makes use of a dual-color application strategy and is based on the simultaneous application of differentially treated samples. Overcoming the limitations of slide-to-slide variation, this method directly revealed activity-dependent interactions through a one-step application of protein samples on SMMs. Besides providing lead molecules for further development, the high-throughput screening results confer activity-dependent fingerprints for quantitative characterization and differentiation of proteins. The procedure was tested using a synthetic hydroxamate peptide library with 1400 discrete sequences permuted combinatorially across P1', P2', and P3' positions. Functional profiling across a panel of metalloproteases provided 44,800 datapoints within just eight SMM slides. These data were globally analyzed for activities, specificity, potency, and hierarchical clustering providing unique insights into inhibitor design and preference within this group of enzymes. Quantitative K(D) measurements performed on SMMs using one of the enzymes in the panel, Anthrax Lethal Factor, the toxic component of a notorious bioterror agent, unraveled several lead micromolar binders for further development. Overall, the effectiveness of the SMM platform is shown to be enhanced and extended using the strategy presented in this work.     

SELEX and dynamic combinatorial chemistry interplay for the selection of conjugated RNA aptamers

SELEX (for Systematic Evolution of Ligands by Exponential enrichment) has proven to be extraordinarily powerful for the isolation of DNA or RNA aptamers that bind with high affinity and specificity to a wide range of molecular targets. However, the modest chemical functionality of nucleic acids poses some limits on the versatility of aptamers as binders and catalysts. To further improve the properties of aptamers, additional chemical diversity must be introduced. The design of chemical modifications is not a trivial task. Recently, dynamic combinatorial chemistry (DCC) has been introduced as an alternative to traditional combinatorial chemistry. DCC employs equilibrium shifting to effect molecular evolution of a dynamic combinatorial library of molecules. Herein, we describe an original process that combines DCC and SELEX for the in vitro selection of modified aptamers which are conjugated to chemically diverse small-molecules. Its successful application for the selection of small-molecule conjugated RNA aptamers that bind tightly to the transactivation-response (TAR) element of HIV-1 is presented.     

小分子靶标的核酸适配体筛选的研究进展

核酸适配体(aptamer)是通过指数富集配体系统进化(SELEX)技术筛选得到的核糖核酸(RNA)或单链脱氧核糖核酸(ssDNA)。核酸适配体通过高亲和力特异性地识别小分子、蛋白质、细胞、微生物等多种靶标,在生物、医药、食品和环境检测等领域的应用日渐增多。但目前实际可用的核酸适配体有限,其筛选过程复杂,筛选难度大,制约了其应用。与生物大分子、细胞和微生物等靶标不同,小分子靶标与核酸分子的结合位点少、亲和力弱,且靶标通常需要固定在载体上。此外,小分子靶标结合核酸形成的复合物与核酸自身的大小、质量、电荷性质等方面差异较小,二者的分离难度大。故小分子靶标的核酸适配体筛选过程与大分子和细胞等复合靶标相比有明显差异,筛选难度更大。因此需要根据其自身结构特点和核酸适配体的应用目的选定靶标或核酸库的固定方法,优化靶标核酸复合物的分离方法。本文介绍了不同类型小分子(具有基团差异的单分子、含相同基团分子和手性分子等)靶标的选择及其核酸适配体的筛选方法,并对核酸库的设计、与靶标结合的核酸的分离方法和亲和作用表征方法进行了介绍,列出了自2008年以来报道的40余种小分子靶标的核酸适配体序列和复合物的平衡解离常数(K_d)。     

Synthesis of Naphthyridine Dimers with Conformational Restriction and Binding to DNA and RNA

One of the important determinants in the efficiency of a molecular interaction is the necessity for conformational changes in host and/or guest molecules upon binding. In small‐molecule interactions with nucleic acids, conformational changes on both molecules are often involved, especially in intercalating binding. Mismatch binding ligands (MBLs) we described here consist of two heterocycles that predominantly exist in one conformation, so it is of interest to determine if such molecules can bind to any DNA and RNA structures. One molecule, 1 ‐NHR, which predominantly exists as the unstacked conformation in aqueous solvent, has been successfully synthesized and characterized. Compound 1 ‐NHR did not efficiently bind to GX/Y DNA and RNA sequences, but the binding pattern is different from that of authentic MBL naphthyridine carbamate dimer. In vitro selection of RNA that specifically binds to 1 ‐NHR was performed from pre‐miR‐29a loop library RNA, and one RNA, to which 1 ‐NHR bound with high affinity, has been successfully identified. Although it was anticipated that 1 ‐NHR, with a predominantly unstacked conformation, would show entropy‐driven binding, isothermal titration calorimetry analysis suggested that the binding of 1 ‐NHR to RNA was enthalpy driven with an apparent K _d of about 100 nm .     

Second-generation DNA-encoded multiple display on a constant macrocyclic scaffold enabled by an orthogonal protecting group strategy

DNA-encoded chemical library(DEL) represents an emerging drug discovery technology to construct compound libraries with abundant chemical combinations. While drug-like small molecule DELs facilitate the discovery of binders against targets with defined pockets, macrocyclic DELs harboring extended scaffolds enable targeting of the protein–protein interaction(PPI) interface. We previously demonstrated the design of the first-generation DNA-encoded multiple display based on a constant macrocyclic s...     

CHEMOENZYMATIC FUNCTIONALIZATION OF RIBONUCLEIC ACID WITH AZOBENZENE CHROMOPHORES

In recent years, biological molecules have brought about a renaissance in the development of novel responsive materials. An example of this is the development of new photoresponsive materials for the artificial regulation of chemical and biological systems. Towards this we have developed a novel enzymatic synthetic approach for covalent attachment of photoresponsive units into the RNA backbone. This involves a lipase catalyzed acylation of the 2' hydroxyl group in the ribose sugars in the RNA molecule to incorporate photo-isomerizable azobenzene groups into the RNA strands. A reverse micellar approach was used for this RNA functionalization to maintain the solubility of the nucleic acid as well as to limit the preferred hydrolysis reaction in aqueous media. The azobenzene groups incorporated in the RNA molecule show photo-isomerization behavior and can serve as optical ‘handles’ for the manipulation of the conformation of RNA. This modification of RNA using covalently attached chromophores or fluorophores is a generic approach that can be extended to other biomacromolecular matrices leading to new opportunities for biophotonic device applications.

     

Erythropoietin mimetics derived from solution phase combinatorial libraries.

The erythropoietin receptor (EPOr) is activated by ligand-induced homodimerization, which leads to the proliferation and differentiation of erythroid progenitors. Through the screening of combinatorial libraries of dimeric iminodiacetic acid diamides, novel small molecule binders of EPOr were identified in a protein binding assay. Evaluation of a series of analogues led to optimization of binding subunits, and these were utilized in the synthesis of higher order dimer, trimer, and tetramer libraries. Several of the most active EPOr binders were found to be partial agonists and induced concentration-dependent proliferation of an EPO-dependent cell line (UT-7/EPO) while having no effect on a cell line lacking the EPOr (FDC-P1). An additional compound library, based on a symmetrical isoindoline-5,6-dicarboxylic acid template and including the optimized binding subunits, was synthesized and screened leading to the identification of additional EPO mimetics.     

Single molecule magnets: from thin films to nano-patterns

Single molecule magnets (SMM) are a class of molecules exhibiting magnetic properties similar to those observed in conventional bulk magnets, but of molecular origin. SMMs have been proposed as potential candidates for several technological applications that require highly controlled thin films and patterns. Here we present an overview of the most important approaches for thin film growth and micro(nano)-patterning of SMM, giving special attention to Mn(12) based molecules. We present both conventional approaches to thin film growth (Langmuir-Blodgett, chemical approach, dip and dry, laser evaporation), patterning (micro-contact printing, deposition on patterned surface, moulding of homogeneous films) and new methods specifically developed for SMM (lithographically controlled wetting, lithographically controlled de-mixing).     

Exploratory Study on the RNA‐Binding Structural Motifs by Library Screening Targeting pre‐miRNA‐29 a

The metabolic stream of microRNA (miRNA) production, the so‐called maturation process of miRNAs, became one of important metabolic paths for drug‐targeting to modulate the expression of genes related to a number of diseases. We carried out discovery studies on small molecules binding to the precursor of miR‐29a (pre‐miR‐29a) from a chemical library containing 41 119 compounds (AQ library) by the fluorescent indicator displacement (FID) assay using the xanthone derivative X2SdiMe as a fluorescent indicator. The FID assay provided 1075 compounds, which showed an increase of fluorescence. These compounds were subsequently submitted to a binding analysis in a surface plasmon resonance (SPR) assay on a pre‐miR‐29a immobilized surface. 21 hit compounds were identified with a good reproducibility in the binding. These compounds have not been reported to bind to RNA until now and can be classified into two groups on the basis of the kinetics in the binding. To gain more information on the motif structures that could be necessary for the binding to pre‐miR‐29a, 19 substructures were selected from the hit compounds. The substructure library (SS library) which consisted of 362 compounds was prepared from the AQ library. An SPR assay of the SS library on pre‐miR‐29a‐immobilized surface suggested that five substructures could potentially be important structural motifs to bind to pre‐miR‐29a. These studies demonstrate that the combination of FID‐based screening of chemical library and subsequent SPR assay would be one way for obtaining practical solutions for the discovery of molecules which bind to the target pre‐miRNAs.     

Molecular docking of intercalators and groove-binders to nucleic acids using Autodock and Surflex

The molecular docking tools Autodock and Surflex accurately reproduce the crystallographic structures of a collection of small molecule ligands that have been shown to bind nucleic acids. Docking studies were performed with the intercalators daunorubicin and ellipticine and the minor groove binders distamycin and pentamidine. Autodock and Surflex dock daunorubicin and distamycin to their nucleic acid targets within a resolution of approximately 2 A, which is similar to the limit of the crystal structure resolution. However, for the top ranked poses, Autodock and Surflex both dock ellipticine into the correct site but in a different orientation compared to the crystal structure. This appears not only to be partly related to the symmetry of the target nucleic acid, as ellipticine is able to dock from either side of the intercalation site, but also due to the shape of the ligand and docking accuracy. Surflex docks pentamidine in a symmetrically equivalent orientation relative to the crystal structure, while Autodock was able to dock this molecule in the original orientation. In the case of the Surflex docking of pentamidine, the initial rmsd is misleading, given the symmetrical structure of pentamidine. Importantly, the ranking functions of both of these programs are able to return a top pose within approximately 2 A rmsd for daunorubicin, distamycin, and pentamidine and approximately 3 A rmsd for ellipticine compared to their respective crystal structures. Some docking challenges and potential pitfalls are explored, such as the importance of hydrogen treatment on ligands as well as the scoring functions of Autodock and Surflex. Overall for this set of complexes, Surflex is preferred over Autodock for virtual screening, as although the results are comparable, Surflex has significantly faster performance and ease of use under the optimal software conditions tested. These experiments show that molecular docking techniques can be successfully extended to include nucleic acid targets, a finding which has important implications for virtual screening applications and in the design of new small molecules to target therapeutically relevant morphologies of nucleic acids.     

Application and analysis of structure-switching aptamers for small molecule quantification

Modern tools for the analysis of cellular function aim for the quantitative measurement of all members of a given class of biological molecules. Of the analyte classes, nucleic acid measurements are typically the most tractable, both on an individual analyte basis and in parallel. Thus, tools are being sought to enable measurement of other cellular molecules using nucleic acid biosensors. Of the variety of potential nucleic acid biosensor strategies, structure-switching aptamers (SSAs) present a unique opportunity to couple sensing and readout of the target molecule. However, little has been characterized about the parameters that determine the fidelity of the signal from SSA biosensors. In this study, a small molecule biosensor based on a SSA was engineered to detect the model small molecule, theophylline, in solution. Quantitative theophylline detection over nearly three orders-of-magnitude was achieved by scintillation counting and quantitative PCR. Further analysis showed that the biosensor fidelity is primarily controlled by the relative stability of the two conformations of the SSA.