毛细管电泳结合电喷雾质谱分析人类癌基因c-myb四链体核酸与活性天然产物的相互作用

药物与靶点间的作用关系直接影响到药理和药效。药物-靶点结合能力、结合计量关系等信息是药物研发过程中必需的表征数据。人类癌基因c-myb在结直肠癌等多种癌症组织中存在过度表达,目前已成为结直肠癌、白血病等癌症疾病潜在的治疗靶点。位于癌基因c-myb启动子区的一段富含鸟嘌呤（G）的DNA序列,通过阳离子的诱导可自发折叠形成分子内G-四链体,而小分子的特异性识别可以稳定该G-四链体,进而调节基因的转录和表达过程。该文采用压力辅助毛细管电泳前沿分析（PACE-FA）结合电喷雾质谱（ESI-MS）研究人类癌基因c-myb启动子G-四链体（G4）与天然产物分子间的相互作用。PACE-FA法在毛细管电泳前沿分析（CE-FA）过程中施加一个与分析物迁移同向的压力,在保证结果准确度的前提下,能够大大加快分析速度。同时结合ESI-MS,可快速解析结合分子与靶点的亲合力和化学计量关系。首先,利用ESI-MS快速筛选出3种有亲合力的天然产物,亲合力大小依次为：土荆皮乙酸>丁溴东莨菪碱>荷叶碱。考虑到溶液相中存在特异性与非特异性结合,接着用PACE-FA法准确分析溶液相中结合的特异性和结合常数。结果发现：丁溴东莨菪碱能够特异性结合靶点G4 DNA,结合比为1：1,结合常数为1.18×10⁵ L/mol;荷叶碱属于非特异性结合,而土荆皮乙酸并未与靶点G4 DNA形成复合物。该组合方法不仅分析速度快,而且能够提高亲和分析的准确度和特异性,有望应用于靶向药物先导结构的发现和作用机制评价。     

电喷雾质谱法研究天然产物小分子识别人类端粒G-四链体及复合物的热稳定性

利用电喷雾质谱(ESI-MS)研究了12种天然产物小分子与人类端粒G-四链体结构的非共价相互作用和识别功能, 比较了不同小分子与人类端粒G-四链体的结合强弱, 发现了一种新的识别小分子——防己诺林碱对人类端粒G-四链体有很好的结合. 通过质谱升温实验比较了小分子结合对G-四链体热稳定性的影响, 防己诺林碱的结合使G-四链体的离子的解离温度(T1/2)上升到200 ℃. 利用分子模拟对G-四链体DNA与小分子结合的模式以及稳定性进行了探讨, 给出了防己诺林碱可能的结合位点和结合模式, Autodock计算出来的结合能约为-31.5 kJ·mol-1. 同原来的平面型分子不同, 防己诺林碱是一类新型结构的分子, 为设计合成新型G-四链体识别分子提供了新的结构模型.     

Specific recognition of human telomeric G-quadruplex DNA with small molecules and the conformational analysis by ESI mass spectrometry and circular dichroism spectropolarimetry

Electrospray ionization mass spectrometry (ESI-MS) was utilized to investigate the binding affinity and stoichiometry of small molecules with human telomeric G-quadruplex DNA. The binding-affinity order obtained for the (AGGGTT)(4) quadruplex was: Tel01>ImImImbetaDp>PyPyPygammaImImImbetaDp. The specific binding of Tel01 and PyPyPygammaImImImbetaDp in one system consisting of human telomeric G-quadruplex and duplex DNA was observed directly for the first time. This revealed that PyPyPygammaImImImbetaDp has a binding specificity for the duplex DNA, whereas Tel01 selectively recognizes the G-quadruplex DNA. Moreover, both ESI-MS and circular dichroism (CD) spectra indicated that Tel01 favored the formation and stabilization of the antiparallel G-quadruplex, and a structural transition of the (AGGGTT)(4) sequence from a coexistence of parallel and antiparallel G-quadruplexes to a parallel G-quadruplex induced by annealing.     

Telomestatin, a potent telomerase inhibitor that interacts quite specifically with the human telomeric intramolecular g-quadruplex

Telomestatin is a natural product isolated from Streptomyces anulatus 3533-SV4 and has been shown to be a very potent telomerase inhibitor. The structural similarity between telomestatin and a G-tetrad suggested to us that the telomerase inhibition might be due to its ability either to facilitate the formation of or trap out preformed G-quadruplex structures, and thereby sequester single-stranded d[T(2)AG(3)](n) primer molecules required for telomerase activity. Significantly, telomestatin appears to be a more potent inhibitor of telomerase (5 nM) than any of the previously described G-quadruplex-interactive molecules. In this communication we provide the first experimental evidence that telomestatin selectively facilitates the formation of or stabilizes intramolecular G-quadruplexes, in particular, that produced from the human telomeric sequence d[T(2)AG(3)](4). A simulated annealing (SA) docking approach was used to study the binding interactions of telomestatin with the intramolecular antiparallel G-quadruplex structure. Each intramolecular G-quadruplex molecule was found to bind two telomestatin molecules (unpublished results). A 2:1 model for the telomestatin bound in the external stacking mode in an energy minimized complex with the human telomeric basket-type G-quadruplex was constructed. Our observation that a G-quadruplex-interactive molecule without significant groove interactions is able to reorient in a G-quadruplex structure proints to the importance of core interaction with an asymmetric G-quadruplex structure in producing selective binding. Furthermore, the G-quadruplex interactions of telomestatin are more selective for the intramolecular structure in contrast to other G-quadruplex-interactive agents, such as TMPyP4.     

Investigation of formation,recognition, stabilization,and conversion of dimeric G-quadruplexes of HIV-1 integrase inhibitors by electrospray ionization mass spectrometry

The dimeric G-quadruplex structures of d(GGGTGGGTGGGTGGGT) (S1) and d(GTGGTGGGTGGGTGGGT) (S2), the potent nanomolar HIV-1 integrase inhibitors, were detected by electrospray ionization mass spectrometry (ESI-MS) for the first time. The formation and conversion of the dimers were induced by NH(4)(+), DNA concentration, pH, and the binding molecules. We directly observed the specific binding of a perylene derivative (Tel03) and ImImImbetaDp in one system consisting of the intramolecular and the dimeric G-quadruplexes of the HIV-1 integrase inhibitor, which suggested that Tel03 could shift the equilibrium to the dimeric G-quadruplex formation, while ImImImbetaDp induces preferentially a structural change from the dimer to the intramolecular G-quadruplex. The results of this study indicated that Tel03 and ImImImbetaDp favor the stabilization of the dimeric G-quadruplex structures.     

Computational studies on G-quadruplex DNA-stabilizing property of novel Wittig-based Schiff-Base ligands and their copper(II) complexes

A series of mono imine (C=N) group that contained Wittig-based Schiff-Base ligands was optimized using the DFT-based computational method and Gaussian 09 program package. These optimized molecules were docked with Quadruplex DNA (PDB ID: 1KF1) and duplex DNA (PDB ID: 1BNA) using AutoDock Vina program along with the reference molecules. Schiff-Base ligands derived from fused aromatic rings contained amines and precursor aldehyde (PA-5 both Z and E isomers) showed lower binding energy for G-quadruplex DNA among all and N-5 category both Z and E isomer Schiff-Base ligands have shown high selectivity for G-quadruplex DNA over duplex DNA which is a very important phenomenon to develop the G-quadruplex DNA stabilizers. For a few Schiff-Base molecules like Ligand-6 (1-{[2-Hydroxy-5-(2-pyren-1-yl-vinyl)-benzylidene]-amino}-naphthalen-2-ol) of N-5 category both Z and E isomers with groove binding and end stacking modes, molecular dynamic calculations were carried out. The study revealed that Ligand-6 of N-5 category E isomer with groove binding mode has higher stabilizing effect on G-quadruplex DNA in spite of having the higher binding energy value. Among Schiff-Base copper(II) complexes, Complex-3 (E-(1-{[2-Hydroxy-5-(2-pyren-1-yl-vinyl)-benzylidene]-amino}-naphthalen-2-ol)Cu) is having high binding affinity for G-quadruplex DNA as compared to others.

     

电喷雾质谱法研究防己诺林碱与G-四链体的相互作用

采用电喷雾质谱法研究了防己诺林碱与双链核酸及G-四链体的相互作用. 结果表明, 防己诺林碱可选择性地与G-四链体结合. 利用串联质谱技术对防己诺林碱与核酸的结合模式进行了研究, 结果表明, 防己诺林碱可能通过末端堆积作用与G-四链体结合, 而通过插入作用与双链核酸结合. 结合模式的差异导致防己诺林碱选择性地与G-四链体结合.     

New insights from molecular dynamic simulation studies of the multiple binding modes of a ligand with G-quadruplex DNA

G-quadruplexes are higher-order DNA and RNA structures formed from guanine-rich sequences. These structures have recently emerged as a new class of potential molecular targets for anticancer drugs. An understanding of the three-dimensional interactions between small molecular ligands and their G-quadruplex targets in solution is crucial for rational drug design and the effective optimization of G-quadruplex ligands. Thus far, rational ligand design has been focused mainly on the G-quartet platform. It should be noted that small molecules can also bind to loop nucleotides, as observed in crystallography studies. Hence, it would be interesting to elucidate the mechanism underlying how ligands in distinct binding modes influence the flexibility of G-quadruplex. In the present study, based on a crystal structure analysis, the models of a tetra-substituted naphthalene diimide ligand bound to a telomeric G-quadruplex with different modes were built and simulated with a molecular dynamics simulation method. Based on a series of computational analyses, the structures, dynamics, and interactions of ligand-quadruplex complexes were studied. Our results suggest that the binding of the ligand to the loop is viable in aqueous solutions but dependent on the particular arrangement of the loop. The binding of the ligand to the loop enhances the flexibility of the G-quadruplex, while the binding of the ligand simultaneously to both the quartet and the loop diminishes its flexibility. These results add to our understanding of the effect of a ligand with different binding modes on G-quadruplex flexibility. Such an understanding will aid in the rational design of more selective and effective G-quadruplex binding ligands.     

Evaluation of binding of perylene diimide and benzannulated perylene diimide ligands to dna by electrospray ionization mass spectrometry

Electrospray ionization mass spectrometry (ESI-MS) and spectroscopic studies in solution were used to evaluate the self-association, G-quadruplex DNA binding, and selectivity of a series of perylene diimides (PDIs) (PIPER, Tel01, Tel11, Tel12, and Tel18) or benzannulated perylene diimide ligands (Tel34 and Tel32). Fluorescence and resonance light scattering spectra of Tel01, Tel12, Tel32, and Tel34 reveal that these analogs undergo self-association in solution. UV-Vis and fluorescence titrations with G-quadruplex, duplex, or single-stranded DNA demonstrate that all the analogs, with the exception of Tel32, bind to G-quadruplex DNA, with those PDIs that are self-associated in solution showing the highest degree of selectivity for binding G-quadruplex DNA. Parallel ESI-MS analysis of the stoichiometries demonstrates the ability of the ligands, with the exception of Tel32, to bind to G-quadruplex DNA. While most ligands show major 1:1 and 2:1 binding stoichiometries as expected in the case of end-stacking, interestingly, three of the most quadruplex-selective ligands show a different behavior. Tel01 forms 3:1 complexes, while Tel12 and Tel32 only form 1:1 complexes. Collisional activation dissociation patterns are compatible with ligand binding to G-quadruplex DNA via stacking on the ends of the terminal G-tetrads. Experiments with duplex and single strand DNA were performed to assess the binding selectivities of the ligands. PIPER, Tel11, and Tel18 demonstrated extensive complexation with duplex DNA, while Tel11 and Tel18 bound to single strand DNA, confirming the lack of selectivity of these two ligands. Our results indicate that Tel01, Tel12, and Tel34 are the most selective for G-quadruplex DNA.     

Studying aminoglycoside antibiotic binding to HIV-1 TAR RNA by electrospray ionization mass spectrometry

The recognition of the aminoglycosides neomycin and streptomycin by HIV-1 TAR RNA was studied by electrospray ionization mass spectrometry (ESI-MS). Members of the aminoglycoside family of antibiotics are known to target a wide variety of RNA molecules. Neomycin and streptomycin inhibit the formation of the Tat protein–TAR RNA complex, an assembly that is believed to be necessary for HIV replication. The noncovalent complexes formed by the binding of aminoglycosides to TAR RNA and the Tat–TAR complex were detected by ESI-MS. Neomycin has a maximum binding stoichiometry of three and two to TAR RNA and to the Tat–TAR complex, respectively. Data from the ESI-MS experiments suggest that a high affinity binding site of neomycin is located near the three-nucleotide bulge region of TAR RNA. This is consistent with previous solution phase footprinting measurements [H.-Y. Mei et al., Biochemistry 37 (1998) 14204]. Neomycin has a higher affinity toward TAR RNA than streptomycin, as measured by ESI-MS competition binding experiments. A noncovalent complex formed between a small molecule inhibitor of TAR RNA, which has a similar solution binding affinity as the aminoglycosides, and TAR RNA is much less stable than the RNA–aminoglycoside complexes to collisional dissociation in the gas phase. It is believed that the small molecule inhibitor interacts with TAR RNA via hydrophobic interactions, whereas the aminoglycosides bind to RNAs through electrostatic forces. This difference in gas phase stabilities may prove useful for discerning the types of noncovalent forces holding complexes together.     

Characterization of noncovalent complexes formed between minor groove binding molecules and duplex DNA by electrospray ionization-mass spectrometry

The noncovalent complex formed in solution between minor groove binding molecules and an oligonucleotide duplex was investigated by electrospray ionization-mass spectrometry (ESI-MS). The oligonucleotide duplex formed between two sequence-specific 14-base pair oligonucleotides was observed intact by ESI-MS and in relatively high abundance compared to the individual single-stranded components. Only sequence-specific A:B duplexes were observed, with no evidence of random nonspecific aggregation (i.e., A:A or B:B) occurring under the conditions utilized. Due to the different molecular weights of the two 14-base pair oligonucleotides, unambiguous determination of each oligonucleotide and the sequence-specific duplex was confirmed through their detection at unique mass-to-charge ratios. The noncovalent complexes formed between the self-complementary 5′-dCGCAAATTTGCG-3′ oligonucleotide and three minor groove binding molecules (distamycin A, pentamidine, and Hoechst 33258) were also observed. Variation of several electrospray ionization interface parameters as well as collision-induced dissociation methods were utilized to characterize the nature and stability of the noncovalent complexes. The noncovalent complexes upon collisional activation dissociated into single-stranded oligonucleotides and single-stranded oligonucleotides associated with a minor groove binding molecule. ESI-MS shows potential for the study of small molecule-oligonucleotide duplex interactions and determination of small molecule binding stoichiometry.     

A novel small molecule that alters shelterin integrity and triggers a DNA-damage response at telomeres

We describe a novel synthetic small molecule which shows an unprecedented stabilization of the human telomeric G-quadruplex with high selectivity relative to double-stranded DNA. We report that this compound can be used in vitro to inhibit telomerase activity and to uncap human POT1 (protection of telomeres 1) from the telomeric G-overhang. We also show that the small molecule G-quadruplex binder induces a partial alteration of shelterin through POT1 uncapping from telomeres in human HT1080 cancer cells and the presence of gammaH2AX foci colocalized at telomeres.     

Effect of loop orientation on quadruplex-TMPyP4 interaction

G-quadruplexes are believed to be potential targets for therapeutic intervention and this has resulted in designing of various quadruplex interacting ligands. Moreover, reports about existence of quadruplex forming sequences across the genome have propelled greater interest in understanding their interaction with small molecules. An intramolecular quadruplex sequence can adopt different conformations, owing to different orientation of loops in the structure. The differences in the loop orientation can affect their molecular recognition. Herein, we have studied the interaction of 5,10,15,20-tetrakis(1-methyl-4-pyridyl)-21H, 23H-porphine (TMPyP4), a well-known G quadruplex binding ligand with three DNA quadruplexes differing in loop orientations. Results obtained from UV, ITC, and SPR studies have coherently revealed that the TMPyP4 molecule shows preferential binding to parallel G-quadruplex ( c-myc and c-kit) over its antiparallel counterpart (human telomeric). The binding affinity for parallel quadruplex was (10(7)) 1 order of magnitude higher than that for antiparallel DNA quadruplex (10 ). The study shows two binding modes, stronger binding (10(7)) of TMPyP4 involving end stacking and a weaker external binding (10 ), while TMPyP4 shows only one binding mode with duplex with a binding affinity of the order of 10(6). Overall, the study emphasizes that differences in the loop orientation give rise to different conformations of quadruplex, which in turn govern its binding to small molecules, and thereby play a pivotal role in molecular recognition.     

Solution phase enantioselective recognition and discrimination by electrospray ionization--mass spectrometry: state-of-the-art, methods, and an eye towards increased throughput measurements

A review is given from the stand-point of applying methods utilizing electrospray ionization - mass spectrometry (ESI-MS) for quantitative binding (affinity and selectivity) determinations in small molecule host-guest (receptor-ligand, selector-selectand, etc.) systems. Advantages over more commonly utilized and traditional solution phase approaches, both in the context of developing new chiral selector molecules for separation and purification of enantiomers and in drug discovery applications, are presented. Although the majority of studies employing methods such as host-guest screening, competitive binding, and titrations have focused on large protein-ligand, DNA-ligand, and RNA-ligand systems, the use of ESI-MS for studying small molecule and chiral recognition systems is growing. For the latter case, greater care must be given to considering the effects of the ESI process on the ionization of the species involved in equilibria of interest. Some basic mechanistic and practical concerns for performing solution-phase-targeting quantitative measurements by ESI-MS are given in this light. Finally, an account of the application of these methods in a high throughput format is given, highlighting the potential of traditional and novel screening and titration approaches which allow scientists to screen the performance of hundreds, if not thousands, of compounds in a single day.     

Immunoglobulin cross-reactivity examined by library screening, crystallography and docking studies

Antibodies are extremely diverse with respect to their specificities and affinities for target molecules. Despite rigorous selection, some antibodies are cross-reactive whereby they recognize their natural antigens along with other molecules. In this review, we discuss our efforts toward understanding the cross-reactivity of selected immunoglobulins. Investigations that are discussed employed screens of combinatorial peptide libraries, crystallography of ligand-protein complexes, and computer-based peptide docking simulations. In the first example, two different antibodies (NC6.8 and NC10.14) bound the same trisubstituted guanidine (NC174) with similar affinities, but utilized predominantly dissimilar binding strategies. However, there was one common binding strategy, in which the cyanophenyl portion of NC174 was inserted end-on into the binding crevices of the NC6.8 and NC10.14 antibodies. In the second example, scanning of peptide libraries and X-ray crystallography were used to design and test synthetic peptides for binding to the Mcg L chain dimer. Again, end-on insertion was favored for all peptides larger than dipeptides in the voluminous Mcg binding cavity. Finally, automated docking was used for rapid predictions of complexes for the Fv molecule from a broadly cross-reactive human IgM (Mez) and nearly two thousand peptides. Certain amino acids, including the aromatic residues Trp and Phe, functioned as anchoring groups in automated docking. Anchoring groups acted in most of the peptides that were otherwise accommodated by a variety of binding strategies in the docked complexes. We suggest that anchoring of at least a portion of a ligand in a binding site is a common mechanism for antibody recognition.     

Impact of planarity of unfused aromatic molecules on G-quadruplex binding: learning from isaindigotone derivatives

G-quadruplex structures are a new class of attractive targets for DNA-interactive anticancer agents. The primary building block of this structure is the G-quartet, which is composed of four coplanar guanines and serves as the major binding site for small molecules. NMR studies and molecular dynamics simulations have suggested that the planarity of G-quartet surface has been highly dynamic in solution. To better investigate how the planarity of unfused aromatic ligand impacts on its quadruplex binding properties, a variety of planarity controllable isaindigotone derivatives were designed and synthesized. The interaction of G-quadruplex DNA with these designed ligands was systematically explored using a series of biophysical studies. The FRET-melting, SPR, and CD spectroscopy results showed that reducing the planarity of their unfused aromatic core resulted in their decreased binding affinity and stabilization ability for G-quadruplex. NMR studies also suggested that these compounds could stack on the G-quartet surface. Such results are in parallel with subsequent molecular modeling studies. A detailed binding energy analysis indicated that van der Waals energy (ΔE(vdw)) and entropy (TΔS) are responsible for their decreased quadruplex binding and stabilization effect. All these results provided insight information about how quadruplex recognition could be controlled by adjusting the planarity of ligands, which shed light on further development of unfused aromatic molecules as optimal G-quadruplex binding ligands.     

Formation and stability of G-quadruplexes self-assembled from guanine-rich strands

Electrospray ionization mass spectrometry (ESI-MS) was utilized to investigate the formation and stability of G-quadruplexes. For the 15 6-nt oligonucleotides tested, ESI-MS indicated that formation of a parallel tetramer quadruplex requires at least four continuous guanines in the 6-nt sequence. In addition, the G-rich strands prefer to employ "self-association" in the formation of the G-quadruplex rather than hybridized integration, and the thermodynamic-stability order of these three G-quadruplexes is Q(2)>Q(1)>Q(3).     

Study of interactions between actinomycin D and oligonucleotides by microchip electrophoresis and ESI-MS

In the present study, the interactions between actinomycin D (ActD) and single stranded DNA (ssDNA) 5′-CGTAACCAACTGCAACGT-3′ and a duplex stranded DNA (dsDNA) with this sequence were investigated by microchip-based non-gel sieving electrophoresis and electrospray ionization mass spectrometry (ESI-MS). The ssDNA was designed according to the conserved regions of open reading frame 1b (replicase 1B) following the Tor 2 SARS genome sequence of 15611-15593. The binding constants of the interactions between ActD and ssDNA/dsDNA were (8.3 ± 0.32) × 10⁶ M⁻¹ (ssDNA) and (2.8 ± 0.02) × 10⁵ M⁻¹ (dsDNA), respectively, calculated from microchip electrophoresis via Scatchard plot. The binding stoichiometries were 1:1 (single/1ActD molecule) and 1:2 (duplex/2ActD molecules) calculated from microchip electrophoresis, and the results were further verified by ESI-MS. The results obtained by these two methods indicated that ActD bound much more tightly to ssDNA used in this work than dsDNA. Furthermore, this is shown that the microchip-based non-gel sieving electrophoresis method is a rapid, highly sensitive and convenient method for the studies of interactions between DNA and small molecule drugs.     

高效液相色谱-荧光检测BMVC对核酸酶的抑制作用

本文利用荧光标记代替传统的同位素标记,用高效液相色谱法(HPLC)研究了端粒酶抑制剂BMVC浓度依赖的酶切抑制作用,得到了和聚丙烯酰胺(PAGE)凝胶电泳一致的结果.说明了该方法的可行性,也为高通量筛选提供了可能性.