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。     

肽核酸—基因调控的利器

肽核酸(PNA)是具有类多肽骨架的DNA类似物,PNA的主链骨架是由N(2-氨基乙基)-甘氨酸与核酸碱基通过亚甲基羰基连接而成的。PNA可以特异性地与DNA或RNA杂交,形成稳定的复合体。PNA由于其自身的特点可以对DNA复制、基因转录、翻译等进行有针对的调控,同时作为杂交探针大大提高了遗传学检测和医疗诊断的效率和灵敏度。肽核酸（PNA）特异性地识别和结合互补核酸序列被引进用于医学和生物学的研究,展示了其独特的生化属性,成为了基因奥秘的探索者。     

PNA的合成及在基础医学中的应用

PNA是一类以多肽为骨架的核苷酸类似物,它不带电荷,杂交特异性强,能抵抗核酸酶及蛋白酶的降解,因此可作为杂交探针用于疾病诊断,或作为反义试剂进行基因治疗的探索。以下对PNA的合成及其在分子杂交诊断、基因治疗等基础医学领域的广泛用途做一综述。     

Solid-Phase synthesis of peptide nucleic acids

Peptide nucleic acids (PNA) were synthesized by a modified Merrifield method using several improvements. Activation by O-(benzotriazol-1-yl)-1,1,3,3-tetramethyluronium hexafluorophosphate in combination with in situ neutralization of the resin allowed efficient coupling of all four Boc-protected PNA monomers within 30 min. HPLC analysis of the crude product obtained from a fully automated synthesis of the model PNA oligomer H-CGGACTAAGTCCATTGC-Gly-NH₂, indicated an average yield per synthetic cycle of 97.1%. N¹-benzyloxycarbonyl-N6³-methylimidazole triflate substantially outperformed acetic anhydride as a capping reagent. The resin-bound PNAs were successfully cleaved by the ‘low–high’ trifluoromethanesulphonic acid procedure.     

Detection of a rare oligo(A) repeat tract mutation (8As-->7As) in the sequence encoding the La/SS-B autoantigen

Several diseases are characterized by the presence of point mutations, which are amenable to molecular detection using a number of methods such as PCR. However, certain mutations are particularly difficult to detect due to factors such as low abundance and the presence of special (e.g., oligonucleotide repeat) sequences. The mutation 7A in the oligoA sequence of exon 7 of the gene encoding the La autoantigen is difficult to detect at the DNA level, and even at the RNA level, due to both its estimated low abundance and its differentiation from the wild-type 8A sequence. This article describes a technique in which amplification of the excess wild-type 8A La sequence is suppressed by a peptide nucleic acid (PNA) during a nested PCR step. Detection of the amplified 7A mutant form was then performed by simple electrophoresis following a final primer extension step with an infrared dye-labeled primer. This technique allowed us to detect the mutation in 3 of 7 individuals harboring serum immunoglobulin G (IgG) antibodies reactive with a neo-B cell epitope in the 7A mutant protein product. We propose that this method is a viable screening test for mutations in regions containing simple polynucleotide repeats.     

A short PNA targeting coxsackievirus B3 5'-nontranslated region prevents virus-induced cytolysis.

Targeting regulatory RNA regions to interfere with the biosynthesis of a protein is an intriguing alternative to targeting a protein itself. Regulatory regions are often unique in sequence and/or structure and, thus, ideally suited for specific recognition with a low risk of undesired side effects. Targeting regulatory RNA elements, however, is complicated by their complex three-dimensional structure, which poses kinetic and thermodynamic constraints to the recognition by a complementary oligonucleotide. Oligonucleotide mimics, which shift the thermodynamic equilibrium towards complex formation and yield stable complexes with a target RNA, can overcome this problem. Peptide nucleic acids (PNA) represent such a promising class of molecules. PNA are very stable, non-ionic compounds and they are not sensitive to enzymatic degradation. Yet, PNA form specific base pairs with a target sequence. We have designed, synthesised and characterised PNA able to enter infected cells and to bind specifically to a control region of the genomic RNA of coxsackievirus B3 (CVB3), which is an important human pathogen. The results obtained by studying the interaction of such PNA with their RNA target, the entrance into the cell and the viral inhibition are herein presented.     

Light-directed synthesis of peptide nucleic acids (PNAs) chips

We report herein the light-directed synthesis of peptide nucleic acids (PNAs) microarray using PNA monomers protected by photolabile protecting groups and a maskless technique that uses a digital micromirror array system to form virtual masks. An ultraviolet image from the virtual mask was cast onto the active surface of a glass substrate, which was mounted in a flow cell reaction chamber connected to a peptide synthesizer. Light exposure was followed by automatic chemical coupling cycles and these steps were repeated with different virtual masks to grow the desired PNA probes in a selected pattern. In a preliminary experiment, an array of PNA probes with dimensions of 4.11 mm × 4.11 mm was generated on each slide. Each synthesis region in the final array measured 210 μm × 210 μm for a total of 256 sites. The center-to-center space was 260 μm. It was observed from the hybridization pattern of the fluorescently labeled oligonucleotide targets that the fluorescence intensities of the matched, and mismatched sequences showed substantial difference, demonstrating specificity in the identification of complementary sequences. This opens the way to exploit processes from the microelectronics industry for the fabrication of PNA microarrays with high densities.     

Modulation of DNA and RNA by PNA

Peptide nucleic acid (PNA), a synthetic DNA mimic that is devoid of the (deoxy)ribose-phosphate backbone yet still perfectly retains the ability to recognize natural nucleic acids in a sequence-specific fashion, can be employed as a tool to modulate gene expressions via several different mechanisms. The unique strength of PNA compared to other oligonucleotide analogs is its ability to bind to nucleic acid targets with secondary structures such as double-stranded and quadruplex DNA as well as RNA. This digest aims to introduce general readers to the advancement in the area of modulation of DNA/RNA functions by PNA, its current status and future research opportunities, with emphasis on recent progress in new targeting modes of structured DNA/RNA by PNA and PNA-mediated gene editing.     

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.     

Fluorescence melting curve analysis using self-quenching dual-labeled peptide nucleic acid probes for simultaneously identifying multiple DNA sequences

Previous fluorescence melting curve analysis (FMCA) used intercalating dyes, and this method has restricted application. Therefore, FMCA methods such as probe-based FMCA and molecular beacons were studied. However, the usual dual-labeled probes do not possess adequate fluorescence quenching ability and sufficient specificity, and molecular beacons with the necessary stem structures are hard to design. Therefore, we have developed a peptide nucleic acid (PNA)-based FMCA method. PNA oligonucleotide can have a much higher melting temperature (T_m) value than DNA. Therefore, short PNA probes can have adequate T_m values for FMCA, and short probes can have higher specificity and accuracy in FMCA. Moreover, dual-labeled PNA probes have self-quenching ability via single-strand base stacking, which makes PNA more favorable. In addition, this method can facilitate simultaneous identification of multiple DNA templates. In conventional real-time polymerase chain reaction (PCR), one fluorescence channel can identify only one DNA template. However, this method uses two fluorescence channels to detect three types of DNA. Experiments were performed with one to three different DNA sequences mixed in a single tube. This method can be used to identify multiple DNA sequences in a single tube with high specificity and high clarity.     

The peptide nucleic acids (PNAs): a new generation of probes for genetic and cytogenetic analyses

Peptide nucleic acids (PNAs) are synthetic homologs of nucleic acids in which the phosphate-sugar polynucleotide backbone is replaced by a flexible pseudo-peptide polymer to which the nucleobases are linked. This structure gives PNAs the capacity to hybridize with high affinity and specificity to complementary sequences of DNA and RNA, and also confers remarkable resistance to DNAses and proteinases. The unique physico-chemical characteristics of PNAs have led to the development of a wide range of biological assays. Several exciting new applications of PNA technology have been published recently in genetics and cytogenetics. Also, PNA-based hybridization technology is developing rapidly within the field of in situ fluorescence hybridization, pointing out the great potential of PNA probes for chromosomal investigations.     

C3′-endo-puckered pyrrolidine containing PNA has favorable geometry for RNA binding: Novel ethano locked PNA (ethano-PNA)

A novel peptide nucleic acid (PNA) analogue is designed with a constraint in the aminoethyl segment of the aegPNA backbone so that the dihedral angle β is restricted within 60–80°, compatible to form PNA:RNA duplexes. The designed monomer is further functionalized with positively charged amino-/guanidino-groups. The appropriately protected monomers were synthesized and incorporated into aegPNA oligomers at predetermined positions and their binding abilities with cDNA and RNA were investigated. A single incorporation of the modified PNA monomer into a 12-mer PNA sequence resulted in stronger binding with complementary RNA over cDNA. No significant changes in the CD signatures of the derived duplexes of modified PNA with complementary RNA were observed.     

肽核酸对基因调节作用的研究进展

肽核酸(PNA)是一类人工合成的核酸类似物,PNA与核酸链以Waston-Crick碱基配对方式稳定互补结合,具有高度的亲合性、稳定性、特异性特征,PNA能调节基因的复制、转录（或逆转录）和翻译过程,有着广泛的分子生物学效应,显示出其作为基因调节药物的应用潜力。     

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。     

ANTIGENE PROPERTY OF PNA CONJUGATED TO THE NUCLEAR LOCALIZATION SIGNAL PEPTIDE

Peptide nucleic acid (PNA) is a DNA mimic with antigene properties. To enhance its capacity to enter in the cell and internalize in the nucleus, PNA has been conjugated to the nuclear localization signal (NLS) peptide, PKKKRKV. PNA-NLS conjugates form stable hybrids with complementary DNA strands and poorly tolerate mismatched base pairing. Employed against cancer-associated genes, PNA-NLS exhibited a potent and specific antigene activity, suggesting exciting therapeutic approaches to cancer.     

Peptide Conjugates of Oligonucleotides As Enhanced Antisense Agents

The use of synthetic oligonucleotides and their analogs to block gene expression by binding the complementary RNA sequences in cells, the antisense principle, has been limited by poor uptake of the agents by cells in culture. This review describes attempts to harness by chemical conjugation the ability of certain peptides that may cross membranes to enhance the cellular uptake of oligonucleotides. These include fusogenic and hydrophobic peptides, nuclear localization signals, receptor targeting and translocating peptides, and various combinations. We also outline briefly some popular methods of peptide–oligonucleotide conjugation. Finally, we review the use of noncovalent peptide additives and the recent studies of conjugates of peptide nucleic acid (PNA) with peptides.