DNA alkylation by pyrrole-imidazole seco-CBI conjugates with an indole linker: sequence-specific DNA alkylation with 10-base-pair recognition through heterodimer formation

The sequence-specific DNA alkylation by conjugates 4 and 5, which consist of N-methylpyrrole (Py)-N-methylimidazole (Im) polyamides and 1-(chloromethyl)-5-hydroxy-1,2-dihydro-3H-benz[e]indole (seco-CBI) linked with an indole linker, was investigated in the absence or presence of partner Py-Im polyamide 6. High-resolution denaturing polyacrylamide gel electrophoresis revealed that conjugate 4 alkylates DNA at the sequences 5'-(A/T)GCCTA-3' through hairpin formation, and alkylates 5'-GGAAAGAAAA-3' through an extended binding mode. However, in the presence of partner Py-Im polyamide 6, conjugate 4 alkylates DNA at a completely different sequence, 5'-AGGTTGTCCA-3'. Alkylation of 4 in the presence of 6 was effectively inhibited by a competitor 7. Surface plasmon resonance (SPR) results indicated that conjugate 4 does not bind to 5'-AGGTTGTCCA-3', whereas 6 binds tightly to this sequence. The results suggest that alkylation proceeds through heterodimer formation, indicating that this is a general way to expand the recognition sequence for DNA alkylation by Py-Im seco-CBI conjugates.     

Molecular design of a pyrrole-imidazole hairpin polyamides for effective DNA alkylation

New hairpin polyamide-CPI (CPI = cyclopropylpyrroloindole) conjugates, compounds 12-14, were synthesized and their DNA-alkylating activities compared with the previously prepared hairpin polyamide, compound 1, by high-resolution denaturing gel electrophoresis with 450 base pair (bp) DNA fragments and by HPLC product analysis of the synthetic decanucleotide. In accord with our previous results, alkylation by compound 1 occurred predominantly at the G moiety of the sequence 5'-AGTCAG-3' (site 3). However, compound 12, in which the structure of the alkylating moiety of compound 1 is replaced with segment A of duocarmycin A DU-86 (CPI), did not show any DNA alkylating activity. In clear contrast, the hairpin CPI conjugate 13, which differs from compound 1 in that it lacks one Py unit and possesses a vinyl linker, alkylated the A of 5'-AGTCAG-3' (site 3) efficiently at nanomolar concentrations. Alkylation by compound 14, which has a vinyl linker, occurred at the A of 5'-AGTCCA-3' (site 6) and at several minor alkylation sites, including mismatch alkylation at A of 5'-TCACAA-3' (site 2). The significantly different reactivity of the alkylating hairpin polyamides 1, 12, 13, and 14 was further confirmed by HPLC product analysis by using a synthetic decanucleotide. The results suggest that hairpin polyamide--CPI conjugate 13 alkylates effectively according to Dervan's pairing rule, and with a new mode of recognition in which the Im-vinyl linker (L) pair targets G-C base pairs. These results demonstrate that incorporation of the vinyl-linker pairing with Im dramatically improves the reactivity of hairpin polyamide--CPI conjugates.     

Specific adenine alkylation by pyrrole-imidazole CBI conjugates

We examined DNA alkylation by pyrrole (Py)-imidazole (Im) hairpin polyamides, which possess 1,2,9,9a-tetrahydrocyclopropa[1,2-c]benz[1,2-e]indol-4-one (CBI) or cyclopropapyrroloindole (CPI) as DNA alkylating moieties. High-resolution denaturing gel electrophoresis revealed that alkylation by CBI conjugates 2 and 4 occurred specifically at adenines (A) in matched sequences, whereas CPI conjugates 1 and 3 alkylated both A and guanines (G) in matched sequences. The origin of the different reactivity of CBI and CPI conjugates is discussed in relation to the electrophilicity of the cyclopropane moiety. The high selectivity of the CBI conjugate gives additional sequence specificity relative to CPI conjugates that would be useful for the biological applications.     

Solid-phase synthesis and evaluation of TAR RNA targeted beta-carboline-nucleoside conjugates

Four types of beta-carboline-nucleoside conjugates were synthesized. The binding affinities of these beta-carboline-nucleoside conjugates , and to TAR RNA were evaluated by affinity capillary electrophoresis. The data of binding affinities to TAR RNA show that conjugates and are stronger binders than the parent compound . Computer modeling indicates that the beta-carboline-nucleoside conjugate can fit to the UCU three-nucleotide bulge region of TAR RNA.     

Sequence‐Specific DNA Alkylation by Tandem Py–Im Polyamide Conjugates

Tandem N‐methylpyrrole? N‐methylimidazole (Py? Im) polyamides with good sequence‐specific DNA‐alkylating activities have been designed and synthesized. Three alkylating tandem Py? Im polyamides with different linkers, which each contained the same moiety for the recognition of a 10 bp DNA sequence, were evaluated for their reactivity and selectivity by DNA alkylation, using high‐resolution denaturing gel electrophoresis. All three conjugates displayed high reactivities for the target sequence. In particular, polyamide 1 , which contained a β‐alanine linker, displayed the most‐selective sequence‐specific alkylation towards the target 10 bp DNA sequence. The tandem Py? Im polyamide conjugates displayed greater sequence‐specific DNA alkylation than conventional hairpin Py? Im polyamide conjugates ( 4 and 5 ). For further research, the design of tandem Py? Im polyamide conjugates could play an important role in targeting specific gene sequences.     

Quantitative experimental determination of primer-dimer formation risk by free-solution conjugate electrophoresis

DNA barcodes are short, unique ssDNA primers that "mark" individual biomolecules. To gain better understanding of biophysical parameters constraining primer-dimer formation between primers that incorporate barcode sequences, we have developed a capillary electrophoresis method that utilizes drag-tag-DNA conjugates to quantify dimerization risk between primer-barcode pairs. Results obtained with this unique free-solution conjugate electrophoresis approach are useful as quantitatively precise input data to parameterize computation models of dimerization risk. A set of fluorescently labeled, model primer-barcode conjugates were designed with complementary regions of differing lengths to quantify heterodimerization as a function of temperature. Primer-dimer cases comprised two 30-mer primers, one of which was covalently conjugated to a lab-made, chemically synthesized poly-N-methoxyethylglycine drag-tag, which reduced electrophoretic mobility of ssDNA to distinguish it from ds primer-dimers. The drag-tags also provided a shift in mobility for the dsDNA species, which allowed us to quantitate primer-dimer formation. In the experimental studies, pairs of oligonucleotide primer barcodes with fully or partially complementary sequences were annealed, and then separated by free-solution conjugate CE at different temperatures, to assess effects on primer-dimer formation. When less than 30 out of 30 base-pairs were bonded, dimerization was inversely correlated to temperature. Dimerization occurred when more than 15 consecutive base-pairs formed, yet non-consecutive base-pairs did not create stable dimers even when 20 out of 30 possible base-pairs bonded. The use of free-solution electrophoresis in combination with a peptoid drag-tag and different fluorophores enabled precise separation of short DNA fragments to establish a new mobility shift assay for detection of primer-dimer formation.     

C-H to N substitution dramatically alters the sequence-specific DNA alkylation, cytotoxicity, and expression of human cancer cell lines

We designed and synthesized sequence-specific alkylating conjugates 1 and 2, which selectively alkylate matched sequences at nanomolar concentrations. Conjugates 1 and 2 differ only in that the C-H is substituted by an N in the second ring, which precisely recognizes and effectively alkylates DNA according to the recognition rule of Py-Im polyamides. We investigated sequence-specific DNA alkylation, cytotoxicity in 39 human cancer cell lines, and the effect on expression levels in cancer cell lines by Py-Im conjugates 1 and 2. The COMPARE analysis of the mean graphs showed that conjugates 1 and 2 did not correlate well with each other (r = 0.65) despite having a common DNA alkylating mechanism (purine N3 alkylation). Array-based gene expression analysis demonstrated that there are several oppositely regulated genes. The results suggest the intriguing possibility that DNA alkylating agents recognizing longer base-pair sequences may provide a promising approach for developing new types of antigene agents.     

吖啶-多胺类缀合物的合成、 抗肿瘤活性及与DNA键合作用

设计合成了系列吖啶-多胺类衍生物(ACP1~ACP6), 并通过四甲基偶氮唑蓝(MTT)染色法研究了化合物对K562(人白血病细胞)、 A549(人肺癌细胞)和Hela(人宫颈癌细胞)细胞株的体外抗肿瘤活性. 结果显示, 化合物对肿瘤细胞具有一定的抑制作用, 尤其是化合物ACP2的抗肿瘤活性优于阳性对照顺铂. 通过UV-Vis光谱、 荧光光谱、 圆二色谱和热变性实验研究了合成化合物与小牛胸腺DNA(Ct-DNA)的键合作用. 结果表明, 三乙烯四胺修饰的化合物ACP2具有较好的抗肿瘤活性, 与DNA分子具有较强的结合能力.     

HPLC analysis of functionalized poly(amidoamine) dendrimers and the interaction between a folate-dendrimer conjugate and folate binding protein

Poly(amidoamine) (PAMAM) dendrimers of different generations with carboxyl, acetyl, and hydroxyl terminal groups and a folic acid (FA)-dendrimer conjugate were separated and analyzed using reverse-phase high performance liquid chromatography (HPLC). Analysis of both the individual PAMAM derivatives and the separation of mixed generations can be achieved using a linear gradient 0-50% acetonitrile (ACN) (balance water) within 40 min. We also show that PAMAMs with defined acetylation and carboxylation degrees can be analyzed using HPLC. Furthermore, a generation 5 dendrimer-FA conjugate (G5.75Ac-FA4; Ac denotes acetyl) was analyzed and its specific binding with a bovine folic acid binding protein (FBP) was monitored. The HPLC and sodium dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE) results indicate the formation of three complexes after the binding of G5.75Ac-FA4 with FBP. Dendrimers with FA moieties show much higher specific binding capability with FBP than those without FA moieties. Findings from this study indicate that HPLC is an effective technique not only for characterization and separation of functionalized PAMAM dendrimers and conjugates but also for investigation of the interaction between dendrimers and biomolecules.     

新型生物黏附性材料巯基壳聚糖的合成与表征

巯基聚合物利用二硫键的形成, 以共价键黏附于黏膜表面, 可以延长药物在黏膜上的滞留时间, 有利于药物分子的吸收. 本文合成了一种新型巯基聚合物——N-乙酰基-L-半胱氨酸-g-壳聚糖(CS-NAC), 并进行了表征, 同时对材料的溶胀度、黏附性和细胞毒性进行了测试. 结果表明, 这种巯基聚合物具有较高的巯基含量, 最高可达到589.3 μmol/g; 具有快速的溶胀性能; 黏附性显著增强, 黏附时间和黏附力分别是壳聚糖的30和3倍; 无明显的细胞毒性. 因此, CS-NAC是一种很有应用前景的生物黏附性材料.     

Sequence-specific alkylation by Y-shaped and tandem hairpin pyrrole-imidazole polyamides

To extend the target DNA sequence length of the hairpin pyrrole-imidazole (Py-Im) polyamide 1, we designed and synthesized Y-shaped and tandem hairpin Py-Im polyamides 2 and 3, which possess 1-(chloromethyl)-5-hydroxy-1,2-dihydro-3H-benz[e]indole (seco-CBI) as DNA-alkylating moieties. High-resolution denaturing polyacrylamide gel electrophoresis by using 5'-Texas-Red-labeled 465 base pair (bp) DNA fragments revealed that conjugates 2 and 3 alkylated the adenine of the target DNA sequences at nanomolar concentrations. Conjugate 2 alkylated adenine N3 at the 3' end of two 8 bp match sequences, 5'-AATAACCA-3' (site A) and 5'-AAATTCCA-3' (site C), while conjugate 3 recognized one 10 bp match sequence, 5'-AGAATAACCA-3' (site A) in the 465 bp DNA fragments. These results demonstrate that seco-CBI conjugates of Y-shaped and tandem hairpin polyamides have extended their target alkylation sequences.     

Separation of single-stranded DNAs using DNA conjugates having different migration properties in capillary electrophoresis

A probe-regulated simultaneous separation (PRESS) using capillary electrophoresis (CE) was developed for separating single-stranded (ss) DNAs. We synthesized two DNA conjugate probes, -(5'-TGTGTGTGT-3')p-AAm(q)- and -(5'-GCCACCAGC-3')m-AAm(n)-, by copolymerizing 5'-methacryloyl-modified ssDNA with acrylamide (AAm), and characterized them in detail. The two probes showed lower electrophoretic mobilities than 5'-methacryloyl-modified ssDNAs. Furthermore, -(5'-TGTGTGTGT-3')p-AAm(q)- showed slightly faster electrophoretic mobility toward the anode than -(5'-GCCACCAGC-3')m-AAm(n)- due to its higher molar fraction of negatively-charged ssDNA. We successfully separated target ssDNAs having the same chain length by using two ssDNA conjugate probes that showed different electrophoretic mobilities, although the separation of these ssDNAs was difficult in conventional capillary electrophoresis systems.     

Sequence‐Specific DNA Alkylation Targeting for Kras Codon 13 Mutation by Pyrrole–Imidazole Polyamide seco‐CBI Conjugates

Hairpin N‐methylpyrrole‐N‐methylimidazole polyamide seco‐CBI conjugates 2 – 6 were designed for synthesis by Fmoc solid‐phase synthesis, and their DNA‐alkylating activities against the Kras codon 13 mutation were compared by high‐resolution denaturing gel electrophoresis with 225 base pair (bp) DNA fragments. Conjugate 5 had high reactivity towards the Kras codon 13 mutation site, with alkylation occurring at the A of the sequence 5′‐ACGTCACC A ‐3′ (site 2), including minor 1 bp‐mismatch alkylation against wild type 5′‐ACG C CACC A ‐3′ (site 3). Conjugate 6 , which differs from conjugate 5 by exchanging one Py unit with a β unit, showed high selectivity but only weakly alkylated the A of 5′‐ACGTCACC A ‐3′ (site 2). The hairpin polyamide seco‐CBI conjugate 5 thus alkylates according to Dervan′s pairing rule with the pairing recognition which β/β pair targets T–A and A–T pairs. SPR and a computer‐minimized model suggest that 5 binds to the target sequence with high affinity in a hairpin conformation, allowing for efficient DNA alkylation.     

Site-directed cleavage of DNA by an oligonucleotide conjugate with o-bromobenzoic acid in the presence of copper ions

Site-directed cleavage of single- and double-stranded DNAs by an oligonucleotide conjugate with 5-[N-(3-aminopropyl)sulfamoyl]-2-bromobenzoic acid was investigated. When forming duplex complexes with a single-stranded DNA and triplex complexes with a double-stranded DNA, this conjugate cleaves DNA near the binding site in the presence of copper ions and free o-bromobenzoic acid. The efficacy and specificity of DNA cleavage by this conjugate and other oligonucleotide conjugates bearing tetracarboxyphthalocyanine Co^II and bleomycin A5 as reactive groups were compared.     

Photophysical and Duplex‐DNA‐Binding Properties of Distamycin Dimers Based on 4,4′‐ and 2,2′‐Dialkoxyazobenzenes as the Core

Distamycin‐based tetrapeptide ( 1 ) was covalently tethered to both ends of the central dihydroxyazobenzene moiety at either the 2,2′ or 4,4′ positions. This afforded two isomeric, distamycin–azobenzene–distamycin systems, 2 (para) and 3 (ortho), both of them being photoisomerizable. Illumination of these conjugates in solution at approximately 360 nm induced photoisomerization and the time course of the process was followed by UV/Vis and ¹H NMR spectroscopy. The kinetics of the thermal reversion at various temperatures of cis to trans isomers of the conjugates obtained after photoillumination were also examined. This afforded the respective thermal‐activation parameters. Both the molecular architecture and the location of the substituent around the core azobenzene determined the rate and activation‐energy barrier for the cis‐to‐trans back‐isomerization of these conjugates in solution. Duplex–DNA binding of the conjugates and the changes in DNA‐binding efficiency upon photoisomerization was also examined by CD spectroscopy, thermal denaturation studies, and a Hoechst displacement assay. The conjugate 2 showed higher DNA‐binding affinity and a greater change in the DNA‐binding efficiency upon photoisomerization compared with its 2,2′‐disubstituted counterpart. The experimental findings were substantiated by using molecular‐docking studies involving each conjugate with a model duplex d[(GC(AT)₁₀CG)]₂ DNA molecule.     

Evaluation of The Interaction Between Netropsin and Double Stranded DNA by Capillary Zone Electrophoresis

DNAmoleculesarepolymorphic,andexistinavarietyofstructuralformsthatmightprovideuniquebindingsitesforsmallmolecules1.ManysmallmoleculesthatinteractwithDNAhavepotentialtherapeuticapplicationsininhibitingtumorgrowth,andviral,bacterial,fungalandparasiticinfections.Thesedrugscanbedividedintotwocategories:intercalatorandminorgroovebinder2-3.SoDNA-druginteractionsareaparticularlyimportantclassofintermolecularinteractions.ManymethodshavebeenperformedtostudythebasisofDNA-druginteractions4.However,i…     

Synthesis of DNA conjugate by mechanochemical solid-state polymerization and its affinity separation of oligonucleotides having single-base difference by capillary electrophoresis

In this communication, we discuss the characterization of DNA conjugate synthesized by mechanochemical polymerization, Con-M, on the separation of model oligo-DNA and its single nucleotide polymorphisms (SNPs) by affinity capillary electrophoresis, compared with that prepared by radical-initiated solution polymerization, Con-RL. The average molecular weight of Con-M was similar to that of Con-RL, although the molecular weight distribution of Con-M was narrower than that of Con-RL. Capillary electrophoresis of oligo-DNA was performed using the capillary filled with DNA conjugate. The resolution of the capillary filled with Con-M was apparently higher than with Con-RL. It is considered that higher resolution using the capillary filled with Con-M could be ascribed not only to the narrow molecular weight distribution but also to the difference of copolymer structure.     

Bifunctional rhodium intercalator conjugates as mismatch-directing DNA alkylating agents

A conjugate of a DNA mismatch-specific rhodium intercalator, containing the bulky chrysenediimine ligand, and an aniline mustard has been prepared, and targeting of mismatches in DNA by this conjugate has been examined. The preferential alkylation of mismatched over fully matched DNA is found by a mobility shift assay at concentrations where untethered organic mustards show little reaction. The binding site of the Rh intercalator was determined by DNA photocleavage, and the position of covalent modification was established on the basis of the enhanced depurination associated with N-alkylation. The site-selective alkylation at mismatched DNA renders these conjugates useful tools for the covalent tagging of DNA base pair mismatches and new chemotherapeutic design.     

Probing of effective pyrazolone based metallonucleases: Molecular docking and in vitro biological critiques

Four novel tryptophan based metal (II) complexes of the type [ML (Try)₂] were prepared by using pyrazolone derived Schiff base ligand. The proposed structure was confirmed by physicochemical methods which reveal octahedral coordination environment around the metal center. Intercalative binding mode of the complexes with CT DNA was confirmed by electronic absorption titration, viscosity measurements and fluorescence spectroscopy. Efficiency of DNA cleavage ability of the metal complexes was explored by the gel electrophoresis technique. The antimicrobial activities of the metal complexes showed potent biocidal activity. The percentage of free radical scavenging activity shows that the complexes are very reactive towards DPPH. Moreover, their cytotoxicity was tested against the two cancer cell lines (MCF‐7 and HepG2) and one normal cell line (NHDF) respectively. The MTT assay shows that the complexes have the anticancer efficacy. Moreover, the complexes exhibit a limited cytotoxicity effect on normal cell line NHDF. The morphological changes of apoptosis cell death were investigated by using Hoechst 33258 staining method. In addition, the Molecular docking studies was executed to consider the nature of binding and binding affinity of the synthesized compounds with DNA (PDB: 1BNA) and protein (PDB: 3hb5).     

Use of Capillary Electrophoresis in the Study of Interaction between dsDNA and Drug Molecules

The advantages of berberine such as the anticancer1, antiinflammatory2 and no side effects of camptothecin1, have promoted the research in the mechanism of berberine with macrobiomolecules. In general, three different points of view have been presented on…