肽核酸探针技术及其在微生物检测中的应用

肽核酸(Peptide Nucleic Acid,PNA)是近十几年发展起来的以中性酰胺键为骨架的脱氧核糖核酸 (Deoxyribonucleic Acid,DNA)类似物,它能够与DNA和RNA特异性地结合从而可以制备PNA探针.与 DNA探针相比,其杂交的稳定性和特异性增加且能在低盐浓度下进行杂交.因此它能够大大提高微生物学检测和医疗诊断的效率和灵敏度.PNA独特的生化属性已逐渐为世人所瞩目,PNA探针技术也得到了迅速发展,尤其是其在微生物检测领域中的应用.     

肽核酸探针在微生物诊断领域的应用进展

肽核酸(Polyamide nucleic acid,PNA)是以中性酰胺键为骨架的脱氧核糖核酸(DNA)结构类似物,它可以特异性地与DNA杂交,且具有极高的生物稳定性.相比较传统的DNA探针技术,肽核酸探针以其特殊的结构和性质在食品、环境及临床等微生物快速诊断领域显示出独特的优势.就肽核酸探针在微生物诊断方面的应用进展做简要综述.     

肽核酸(peptide nucleic acid,PNA)阵列

肽核酸(PNA)以N—(2—氨基乙基)甘氨酸替代DNA分子中的磷酸戊糖骨架。它能特异性地识别与DNA、RNA所形成的杂交体。PNA—DNA、PNA—RNA的热稳定性要比相应的DNA—DNA、DNA—RNA高,而且PNA识别单碱基的能力强于DNA和RNA,使之在微阵列,尤其是SNP检测领域有着广泛的应用前景。本文简述了PNA阵列从探针设计、阵列合成、杂交和检测的全过程。     

γPNA一种新型高效的肽核酸

肽核酸(peptide nucleic acid,PNA)是一种人工合成的具有类多肽骨架的DNA类似物,具有与核酸结合特异性强、组织和细胞内生物稳定性好、半衰期长等优点。通过靶向结合DNA/RNA而抑制其复制、转录和翻译过程,进行基因调控。在PNA骨架结构中γ位点引入带手性的官能团,能形成右手螺旋结构,显著提高其与靶DNA/RNA的杂交特性,这种PNA衍生物称之为γPNA。γPNA的溶解性、热稳定性和特异性等化学与生物学特性明显改善,在基因编辑和作为探针检测等方面具有良好的应用前景。通过对γPNA结构、性质及其研究进展进行总结,以期为γPNA反义应用提供理论依据和参考。     

肽核酸在分子生物学技术中的应用

肽核酸(PNA)作为一种人工合成的核酸类似物,以中性的肽链酰胺2-氨基乙基甘氨酸键取代了DNA中的戊糖磷酸二酯键骨架,其余部分与DNA相同。PNA可通过Watson-Crick碱基配对的形式识别并结合DNA或RNA序列,形成稳定的双螺旋结构。与传统的DNA或RNA相比,PNA具有生物学稳定性高、杂交特异性强、杂合体的稳定性高和杂交速度快等明显优点,使PNA具有良好的物理化学性质和生物学特性,在检测目的核酸序列中单碱基突变、PCR基因分子诊断与检测、荧光原位杂交定量分析、基因芯片和生物传感器技术等调控水平和临床应用上有自己的特点。简要综述了近年来肽核酸在上述分子生物学技术中的运用以及应用前景的展望。     

肽核酸的特性及作用

肽核酸（peptide nucleic acid,PNA)是一类DNA结构类似物,能与DNA和RNA特异性杂交。它通过与DNA结合而抑制基因转录,通过与mRNA结合而阻止蛋白质的合成;同时,PNA不易被核酸酶和蛋白酶降解,所有这些显示出其作为反基因药物和反义药物的良好应用前景。     

肽核酸在抗肿瘤作用的研究进展

肽核酸(peptide nucleic acid,PNA)是一种人工合成DNA分子类似物,其与DNA分子结构的主要区别在于N-(2-氨基乙基)甘氨酸骨架代替糖-磷酸酯骨架作为重复结构单元。基于此分子结构,使得肽核酸具有独特的理化性质及众多的生物学功能。越来越多的研究表明,肽核酸以Waston-Crick碱基配对方式与肿瘤突变的序列特异性结合,从而调节突变基因的复制、转录及翻译过程,从基因水平上治疗肿瘤。肽核酸作为肿瘤基因治疗的重要介质,在抗肿瘤治疗中起着重要的作用。本文就肽核酸的理化性质及其生物学功能进行综述,重点阐述其在抗肿瘤作用机制方面的研究进展。     

修饰性肽核酸的细胞转运

肽核酸是人工合成的寡核苷酸类似物,以N-(2-氨乙基)甘氨酸结构单元替代DNA分子中的戊糖-磷酸结构。与天然核酸相比,肽核酸可以更高效地与DNA或RNA特异性杂交,在分子生物学和基因药物领域具有良好的应用前景。但是,肽核酸骨架呈电中性,难以高效穿过细胞膜,这成为工程应用的最大障碍。为了改善肽核酸的细胞转运性能,对肽核酸进行化学修饰是近年来的研究热点。结合近十年来文献报道和本实验室的工作,对肽核酸的骨架修饰和配合物结合修饰两类增强细胞转运的修饰方法进行综述,并对修饰性肽核酸细胞转运研究中存在的问题以及未来的研究趋势及其应用提出了见解。     

肽核酸的分子生物学效应及应用

肽核酸(PNA)是一类以酰胺键连接骨架替代核酸中核糖磷酸二酯键骨架构成的核酸类似物,其中N-乙基甘氨酸骨架PNA与核酸链以Waston-Crick碱基配对形式稳定互补结合,具有广泛生物学效应,包括调节DNA识别蛋白质的功能以及调节转录和翻译.在分子生物学研究中PNA作为新的工具在多方面得到应用.除它的DNA(RNA)结合特性外PNA在生物稳定性、细胞摄取、结构修饰多方面的研究进展显示出作为基因调节药物具有良好前景.     

肽核酸在基因诊断和治疗中的研究进展

肽核酸是一种以多肽为骨架,类似核苷酸的物质。它不带电荷,能抵抗核酸酶和蛋白酶的降解;它与DNA或RNA杂交特异性很强,可与靶基因形成稳定的三螺旋结构。肽核酸能够抑制基因的复制、转录、逆转录和翻译过程,在基因诊断及治疗方面有着广泛的用途。     

An introduction to peptide nucleic acid

Peptide Nucleic Acid (PNA) is a powerful new biomolecular tool with a wide range of important applications. PNA mimics the behaviour of DNA and binds complementary nucleic acid strands. The unique chemical, physical and biological properties of PNA have been exploited to produce powerful biomolecular tools, antisense and antigene agents, molecular probes and biosensors.     

Identification of single base-pair mutation on uidA gene of Escherichia coli O157:H7 by Peptide Nucleic Acids (PNA) mediated PCR clamping

Peptide Nucleic Acids (PNA) is a new type of DNA analogue with a peptide backbone. We developed a rapid identification system of Escherichia. coli O157:H7 using PNA mediated PCR clamping. Firstly, we confirmed a single nucleotide alteration in the uidA gene (T93G), which is specific to E. coli O157: H7. We designed forward mutant DNA primer, wild type PNA, and a reverse DNA primer corresponding to the uidA sequence. PCR cycle consisted of four steps including dual annealing temperatures, 57 degrees C and 45 degrees C. Among 20 E. coli strains with various serotypes and 4 neighboring strains, the amplified bands (517 bp) were detected only in E. coli O157:H7 strains. PNA has specifically inhibited the PCR amplification from a wild type uidA gene. We successfully developed a multiplex PCR system, which detects both shigatoxin (stx) and uidA genes at once, to get reliable results by easier and rapid operation. We also analyzed kinetic parameters of PNA/DNA association using surface plasmon resonance and melting temperature using fluorescence resonance energy transfer (FRET). We discussed a selection mechanism of PCR clamping from these results.     

Real time RNA transcription monitoring by Thiazole Orange (TO)-conjugated Peptide Nucleic Acid (PNA) probes: norovirus detection

Thiazole Orange (TO)-conjugated Peptide Nucleic Acid (PNA) probes have been reported as a valuable strategy for DNA analysis; however, no investigations targeting RNA molecules and no comparisons between different derivatization approaches have been reported so far. In this work, two TO-conjugated PNAs for genogroup II noroviruses (NoV GII) detection were designed and synthesized. Both the probes target the most conserved stretch of nucleotides identified in the open reading frame 1-2 (ORF1-ORF2) junction region and differ for the dye conjugation strategy: one PNA is end-labelled with the TO molecule tethered by a linker; the other probe bears the TO molecule directly linked to the PNA backbone, replacing a conventional nucleobase. The spectroscopic properties of the two PNA probes were studied and their applicability to NoVs detection, using an isothermal assay, was investigated. Both probes showed good specificity and high fluorescence enhancement upon hybridization, especially targeting RNA molecules. Moreover, the two probes were successfully employed for NoVs detection from stool specimens in an isothermal-based amplification assay targeting RNA 'amplicons'. The probes showed to be specific even in the presence of high concentrations of non-target RNA.     

肽核酸相关技术在杂交检测中的应用

肽核酸是一种寡核苷酸的类似物,它是由丹麦哥本哈根大学的Ｎｉｅｌｓｅｎ、Ｅｇｈｏｌｍ等人首先发明合成的。肽核酸与传统的寡核苷酸相比,骨架结构发生了根要变化。肽核酸的电中性骨架有许多ＤＮＡ所不具备的性质,例舅高灵敏度、高特异性、非盐依赖性等,从而使它成为一种优良的寡核苷酸的取代物,尤其是杂交检测领域。     

DNA detection using nanostructured SERS substrates with Rhodamine B as Raman label

A technique is demonstrated to detect DNA hybridization at low concentrations, based on Surface-Enhanced Raman Scattering (SERS) using silicon nanostructures coated with gold-silver as substrate. Standard silicon process technologies were employed to fabricate the SERS substrates featuring nanogaps with a characteristic distance of 15+/-10nm. Target DNA was hybridized with cysteine-modified Peptide Nucleic Acids (PNA), which was previously fixed into the nanogaps as the capture sites. After hybridization, the introduced phosphate groups from the backbone of the target DNA showed strong affinity to an inorganic linker, Zr(4+), so that resulting in the assembly substrate-PNA-DNA-Zr. Since PNA does not possess phosphate groups, the linker is avoided when there is no hybridization from the complimentary DNA. Subsequently, the assembly of substrate-PNA-DNA-Zr was incubated with a Raman label, Rhodamine B (RB). The carboxylic acid group in RB reacted with the linker Zr(4+) allowing this Raman Label to be attached to the assembly substrate-PNA-DNA-Zr. The Raman peaks corresponding to RB were selected to detect the target DNA, with a detection limit of 1x10(-12)M.