Development Of The Novel Drug Releasing System Triggered By Hybridization With Target Sequence

We have already established the strategy of synchronous activation by hybridization, in which the highly reactive cross-linking agent, 2-amino-6-vinylpurine nucleoside analog, can be generated from its stable precursors, the phenylsulfide derivatives, by a hybridization-promoted activation process with selectivity to cytosine. In this study, this in situ activation system was applied to the method for the drug releasing system triggered by hybridization with the target sequence.     

Acid-Mediated Cleavage oF Oligonucleotide P3′ → N5′ Phosphoramidates Triggered by Sequence-Specific Triplex Formation

The P-N bond in oligonucleotide P3′ → N5′ phosphoramidates (5′ -amino-DNA) is known to be chemoselectively cleaved under mild acidic conditions. We prepared homopyrimidine oligonucleotides containing 5′ -amino-5′ -deoxythymidine (5′ -amino-DNA thymine monomer) or its conformationally locked congener, 5′ -amino-2′,4′ -BNA thymine monomer, at midpoint of the sequence. The effect of triplex formation with homopurineohomopyrimidine dsDNA targets on acid-mediated hydrolysis of the P3′ → N5′ phosphoramidate linkage was evaluated. Very interestingly, it was found that the triplex formation significantly accelerates the P-N bond cleavage.     

TWO EFFICIENT POLYMERIC CHEMICAL PLATFORMS FOR OLIGONUCLEOTIDE MICROARRAY PREPARATION

ABSTRACT

In this report we describe two robust procedures for oligonucleotide microarray preparation based on polymeric coatings. The proposed chemical approaches include: 1) a glass functionalisation step with appropriate silanes (γ-aminopropyltriethoxysilane-APTES or 3-glycid-oxypropyltrimethoxysilane-GOPS), 2) a coating step using polymers (poly-L-Lysine or poly(acrylic acid-co-acrylamide) copolymer) covalently bound to the modified glass and 3) a surface activation step to allow for the attachment of amino-modified oligonucleotides. Results obtained using these chemistries in oligo microarray preparation show: 1) an overall high loading capacity and availability to hybridisation against targets, 2) a good uniformity, 3) resistance to consecutive probing/stripping cycles, 4) stability to thermal cycles, 5) effectiveness in hybridisation-mediated mutation detection procedures and 6) the possibility to perform enzymatic reactions, such as ligation.     

计算机辅助设计联合斑点杂交筛选铜绿假单胞菌PAO1 motA基因反义寡核苷酸序列

为了筛选出能与铜绿假单胞菌PAO1 motA基因的mRNA结合紧密的反义寡核苷酸序列,采用全基因寻靶技术（full length gene targeting,FLGT）,运用计算机软件（Mfold和RNA Structure4.6）模拟铜绿假单胞菌PAO1 motA基因mRNA的二级结构,根据最小自由能原理设计出8条寡核苷酸探针序列;PCR扩增出全长motA基因,克隆motA基因并进行体外转录,同时用地高辛标记mRNA,以斑点杂交方法筛选出与motA基因mRNA结合紧密、杂交信号较强的寡核苷酸序列。斑点杂交结果显示8条寡核苷酸中的4条有较强的杂交信号,从而成功筛选到了能与motA mRNA牢固结合的反义序列,为进一步研究以motA基因为靶的反义技术抑制生物膜形成打下基础。     

raldh2基因阻抑导致斑马鱼心脏发育畸形的机制

目的通过显微注射吗啡啉修饰的反义寡核苷酸(MO)阻抑视黄醛脱氢酶2(raldh2)基因表达,探讨raldh2基因阻抑对斑马鱼胚胎心脏发育的影响及可能的分子机制。方法根据斑马鱼raldh2基因起始密码区域序列设计合成吗啡啉修饰的反义寡核苷酸,采用显微注射方法阻抑斑马鱼胚胎raldh2基因表达。构建raldh2-EG-FP重组质粒进一步验证MO的特异性和有效性。分析raldh2基因阻抑后对胚胎发育,尤其心脏表型和功能的影响。通过胚胎整体原位杂交,分析心脏相关nppa和tbx20基因表达模式以及raldh2阻抑后对其表达的影响。结果显微注射raldh2-MO能有效地特异地阻抑斑马鱼胚胎raldh2基因表达,raldh2-MO对胚胎发育影响呈剂量依赖性。raldh2基因阻抑可导致胚胎心脏发育畸形,干扰正常的房室分化和向右环化,导致房室瓣血液反流。与野生型胚胎比较,raldh2基因阻抑组胚胎心率和心室收缩分数降低(P<0.05),心功能受损。整体原位杂交结果显示raldh2基因阻抑后nppa基因表达改变,心室部位nppa表达清晰,而心房部位表达减弱。tbx20基因在心脏、运动神经元、顶盖及视网膜表达,raldh2基因阻抑后,tbx20表达下调,在心脏表达减弱,以心房和流出道部位更显著。结论 raldh2基因在心脏早期发育的多个环节发挥重要作用,影响房室分化、心管环化和心肌收缩等。在心脏发育过程中nppa和tbx20基因表达受到raldh2基因调控,可能参与RA信号缺乏导致心脏畸形的潜在分子机制。     

A simple,universal, efficient PCR-based gene synthesis method: Sequential OE-PCR gene synthesis

Herein we present a simple, universal, efficient gene synthesis method based on sequential overlap extension polymerase chain reactions (OE-PCRs). This method involves four key steps: (i) the design of paired complementary 54-mer oligonucleotides with 18 bp overlaps, (ii) the utilisation of sequential OE-PCR to synthesise full-length genes, (iii) the cloning and sequencing of four positive T-clones of the synthesised genes and (iv) the resynthesis of target genes by OE-PCR with correct templates. Mispriming and secondary structure were found to be the principal obstacles preventing successful gene synthesis and were easily identified and solved in this method. Compensating for the disadvantages of being laborious and time-consuming, this method has many attractive advantages, such as the ability to guarantee successful gene synthesis in most cases and good allowance for Taq polymerase, oligonucleotides, PCR conditions and a high error rate. Thus, this method provides an alternative tool for individual gene synthesis without strict needs of the high-specialised experience.     

Structure of eukaryotic DNA binding sites for steroid hormone-apolipoprotein A-I complexes

High affinity for DNA and synthetic oligonucleotides was detected for apolipoprotein A-I (ApoA-I) by affinity chromatography, affinity modification, and enzymatic analysis. Competitive inhibition and Southern hybridization showed that the tetrahydrocortisol (THC)-ApoA-I complex specifically bound to high-molecular-weight DNA in regions containing GCC/CGG sequences. The CC(GCC)₃ · GG(CGG)₃ duplex was found to be sensitive to nuclease S1 under the action of the THC-ApoA-I complex. The eukaryotic DNA binding sites for steroid (THC, androsterone)-ApoA-I complexes were found to be involved in the initiation of DNA copying in vitro.     

Kinetic study of the binding of triplex-forming oligonucleotides containing partial cationic modifications to double-stranded DNA

Several triplex-forming oligonucleotides (TFOs) partially modified with 2′-O-(2-aminoethyl)- or 2′-O-(2-guanidinoethyl)-nucleotides were synthesized and their association rate constants (k_on) with double-stranded DNA were estimated by UV spectrophotometry. Introduction of cationic modifications in the 5′-region of the TFOs significantly increased the k_on values compared to that of natural TFO, while no enhancement in the rate of triplex DNA formation was observed when the modifications were in the middle and at the 3′-region. The k_on value of a TFO with three adjacent cationic modifications at the 5′-region was found to be 3.4 times larger than that of a natural one. These results provide useful information for overcoming the inherent sluggishness of triplex DNA formation.