一种利用Taq酶快速标记DNA探针的方法

目的：探索低成本、高效、快速的DNA探针标记方法。方法：以特定引物和16nler的随机引物作为延伸引物,利用Taq酶标记DNA探针。以大肠杆菌Klenow片断随机引物延伸标记法作为对照。点杂交方法检测探针标记效果。结果与结论：Taq酶标记法和大肠杆菌Klenow片段随机引物延伸标记法同样有较好的标记效果,且随机引物或特定引物作为延伸引物均可以合成足够有效的探针。Taq酶标记法是一种低成本、高效、快速的DNA探针标记方法。     

Effect of CDP-choline on the biosynthesis of nucleic acids and proteins in brain regions during hypoxia

The effect of CDP-choline on the in vivo incorporation of labeled precursors into DNA, RNA, and proteins in cerebral hemispheres, cerebellum, and brainstem of guinea pigs after hypoxic treatment was studied. The labeling of macromolecules extracted from the various subcellular fractions of these brain regions was also determined. Hypoxic treatment affected macromolecular labeling to a different extent in the three brain regions examined. CDP-choline treatment was not able to reverse the effect of hypoxia on DNA labeling, but it was able to remove the effect of hypoxia on RNA and protein labeling. The action of CDP-choline was particularly evident on the labeling of RNA in nuclei and mitochondria of the cerebellum and on the labeling of proteins in microsomes of the three brain regions examined.     

Flow cytometric DNA content of fresh tumor specimens using keratin-antibody as second stain for two-parameter analysis.

Studies concerning flow cytometric assessed DNA content reveal problems in interpretating DNA histograms of tumor specimens. The main problems are histograms with a broad coefficient of variation in the G0/G1 fraction; a high G2M fraction and samples with a low percentage of tumor cells. Therefore, in the present study, 382 fresh tumor specimens of carcinomas were analysed routinely, double labeled with, on the one hand, propidium-iodide for assessing DNA content and, on the other, a monoclonal keratin-antibody for marking epithelial and tumor cells. Of the 311 tumor samples, using single parameter analysis 165 (54%) were classified as DNA aneuploid and 146 (46%) as DNA "euploid." By double parameter analysis, 224 (72%) samples were keratin positive and 87 (27%) keratin negative and, of the 224 keratin positive tumors, 175 (78%) were DNA aneuploid and 49 (22%) DNA euploid. The DNA histograms of single and double parameter analysis were compared and it was concluded that in 24 cases (11%) keratin labeling was necessary to recognize DNA aneuploidy. In another 23 (10%) cases, keratin labeling was helpful in assessing DNA aneuploidy. Finally when the results of the 311 samples were combined, 215 (68%) were scored as DNA aneuploid and 99 (32%) DNA euploid. Thus the overall gain in assessing DNA aneuploidy using the double labeling technique is 14%. In conclusion, it is shown that keratin labeling on fresh tumor cell suspensions of epithelial tumors is of additional value in establishing DNA content. Because single parameter DNA assessment is adequate in approximately 60% of the tested samples, the double labeling technique can be performed routinely, or after initial single parameter DNA assessment. Histograms having a broad CV and/or a high G2M are good candidates for the double labeling technique. Using this technique, DNA-content assessment becomes more reliable.     

ULS: a versatile method of labeling nucleic acids for FISH based on a monofunctional reaction of cisplatin derivatives with guanine moieties

The broad extension of an existing chemical DNA labeling technique for molecular cytogenetics is described. Called the Universal Linkage System (ULS(TM)), it is based on the capability of monoreactive cisplatin derivatives to react at the N7 position of guanine moieties in DNA. Simple repetitive probes, cosmids, PACs, and chromosome-specific painting probes were labeled by ULS and used in a series of multicolor fluorescence in situ hybridization experiments on interphase and metaphase cells. It is demonstrated that ULS-labeled probes, in general, perform as well as the more conventional enzymatically labeled probes. The advantage of ULS labeling over enzymatic labeling techniques is that it is a fast and simple procedure, and that the labeling can easily be scaled up for bulk probe synthesis. In addition, with ULS labeling it is possible to label degraded DNA, a situation in which enzymatic labeling is known to perform unsatisfactorily.     

Fluorescence properties,thermal duplex stability,and kinetics of formation of cyanin platinum DNAs

Fluorescent and haptenized, monofunctionally binding platinum compounds are increasingly used for chemically labeling nucleic acids for hybridization detection purposes. Here we analyze in detail the effect of labeling density of the cyanin-3 and -5 platinum DNA adducts on fluorescence and thermal stability. We also analyzed the kinetics of the reaction of the cyanin platinum compounds with DNA. The data provided are important for the design of optimal platinum DNA labeling and hybridization conditions for fluorescence hybridization applications.     

Studies on the possible influence of the so-calledwound healing reaction on DNA synthesis in organ culture

Tissue sectioning is a necessary preliminary step in the preparation of organ culture explants. The real extent of tissue damage in the "wound healing reaction" can be assessed by DNA isotopic labeling. The differential count of labeling indices between epithelial structures located at the margin of the explants and similar structures near the center was used to study the influence of tissue damage on DNA synthesis. Our results suggest a time-related influence of wound healing on labeling indices. This reaction has to be taken into account when DNA synthesis is used as an indicator of hormonedependency in vitro.     

CHROMOSOMAL DNA SYNTHESIS IN DROSOPHILA MELANOGASTER

Analysis of labeling patterns in three chromosome segments of Drosophila melanogaster has shown that the replicative activity within chromosomes is temporally ordered. Moreover, specific labeling patterns on one chromosome occur with specific patterns on another chromosome with a very high degree of correlation. This circumstance leads to the conclusion that DNA synthesis among all the regions in the three chromosome segments studied is coordinated. The various labeling patterns observed in any one chromosome and the combinations of labeling patterns observed in all three chromosome segments can be arranged in ordered arrays, if one assumes that the DNA synthesis in each chromosome region will go to completion without stopping once it has started. Such arrays can serve as models for the temporal order of DNA synthesis among chromosome regions. They predict that in any one chromosome DNA replication begins and ends at very few loci and that synthesis at a larger number of points occurs at an intermediate time.     

Preparation of labeled nucleic acids (nick translation and iodination) for DNA homology and rRNA hybridization experiments

Nick-translated DNA preparations may contain very short fragments, causing inconsistent DNA homology results. This appears to be due to extensive fragmentation of the high molecular weight DNA used in the labeling procedure. DNA preparations from organisms containing DNA of low mol% G+C content appear to be the most fragmented. The problem was circumvented by labeling these DNA preparations with¹²⁵I. Sample preparation protocols have been developed for the routine¹²⁵I labeling of DNA and rRNA from a wide range of organisms.     

Labeling During Cleavage of Nucleic Acids for Their Detection on DNA Chips

Abstract

A new and efficient strategy for labeling of nucleic acids prior to their hybridization on high density DNA chip has been developed. Our approach which combines the fragmentation and the labeling is based on the reactivity of the terminal phosphates of cleaved DNA and RNA fragments with a reporter molecule bearing aryldiazomethane group.     

Chemical methods of DNA and RNA fluorescent labeling.

Several procedures have been described for fluorescent labeling of DNA and RNA. They are based on the introduction of aldehyde groups by partial depurination of DNA or oxidation of the 3'-terminal ribonucleoside in RNA by sodium periodate. Fluorescent labels with an attached hydrazine group are efficiently coupled with the aldehyde groups and the hydrazone bonds are stabilized by reduction with sodium cyanoborohydride. Alternatively, DNA can be quantitatively split at the depurinated sites with ethylenediamine. The aldimine bond between the aldehyde group in depurinated DNA or oxidized RNA and ethylenediamine is stabilized by reduction with sodium cyanoborohydride and the primary amine group introduced at these sites is used for attachment of isothiocyanate or succinimide derivatives of fluorescent dyes. The fluorescent DNA labeling can be carried out either in solution or on a reverse phase column. These procedures provide simple, inexpensive methods of multiple DNA labeling and of introducing one fluorescent dye molecule per RNA, as well as quantitative DNA fragmentation and incorporation of one label per fragment. These methods of fluorophore attachment were shown to be efficient for use in the hybridization of labeled RNA, DNA and DNA fragments with oligonucleotide microchips.     

Nanostructured luminescently labeled nucleic acids

Important and emerging trends at the interface of luminescence, nucleic acids and nanotechnology are: (i) the conventional luminescence labeling of nucleic acid nanostructures (e.g. DNA tetrahedron); (ii) the labeling of bulk nucleic acids (e.g. single‐stranded DNA, double‐stranded DNA) with nanostructured luminescent labels (e.g. copper nanoclusters); and (iii) the labeling of nucleic acid nanostructures (e.g. origami DNA) with nanostructured luminescent labels (e.g. silver nanoclusters). This review surveys recent advances in these three different approaches to the generation of nanostructured luminescently labeled nucleic acids, and includes both direct and indirect labeling methods.     

Conjugated polyelectrolytes for label-free DNA microarrays

Classical strategies for gene microarrays require labeling of probes or target nucleic acids with signaling molecules, a process that is expensive, time consuming and not always reliable. Bazan and colleagues showed that a nucleic acid-binding cationic conjugated polyelectrolyte can be used in label-free DNA microarrays based on surfaces modified with neutral peptide nucleic acid (PNA) probes. This technique provides a simple and sensitive method for DNA detection without the need for covalent labeling of target DNA.     

Neutral filter elution detects differences in chromatin organization which can influence cellular radiosensitivity.

We have shown previously that the neutral filter elution assay is dependent not only on the number of DNA double-strand breaks present in a mammalian cell but also on the way in which DNA expands on the filter following lysis. Results in this study indicate that the rate of DNA elution appears to be dependent upon the proximity of the DNA in relation to the replication complex. The rate of elution for DNA analyzed immediately after a 30-min labeling period with [14C]thymidine was about five times slower than the rate of elution for bulk-labeled DNA. However, the rate was increased a few hours later when the recently replicated DNA had matured and was likely to be farther from replication-associated attachment sites on the nuclear protein matrix. About one cell cycle after pulse labeling, when the labeled DNA was replicated again, DNA underwent similar changes in elution rate. For the four cell lines examined here, the elution rate 3-4 h after pulse labeling correlated with cellular radiosensitivity. Changes in rate of elution caused by altering EDTA concentration or pH may also be explained by DNA structural changes which occur during lysis. We conclude that the neutral filter elution method is sensitive to differences in chromatin organization which may also play a role in cell sensitivity to ionizing radiation.     

Enzymatic labeling of nucleic acids

Enzymatic labeling of nucleic acids is a fundamental tool in molecular biology with virtually every aspect of nucleic acid hybridization technique involving the use of labeled probes. Different methods for enzymatic labeling of DNA, RNA and oligonucleotide probes are available today. In this review, we will describe both radioactive and nonradioactive labeling methods, yet the choice of system for labeling the probe depends on the application under study.     

Nonradioactive labeling of probe with digoxigenin by polymerase chain reaction

Probes nonradioactively labeled with the steroid hapten digoxigenin have several intriguing properties, including a high sensitivity equivalent to that of radioactive probes, speed in detection, low hazard potential in handling, and possibility of long-term storage. The use of polymerase chain reaction for labeling probe has been demonstrated to offer various advantages including efficient labeling of fragments as small as 100 bp, direct labeling of genomic DNA, and labeling with subnanogram amounts of input DNA. We therefore investigated whether this technique could be adapted for labeling with a relatively large molecule such as digoxigenin. In this report, we show that the polymerase chain reaction is a very efficient technique for synthesis of digoxigenin-labeled DNA and we present an extremely simple procedure for purification of the non-isotopically labeled fragments.     

Multiple topological labeling for imaging single plasmids

Sequence-specific labeling methods for double-stranded DNA are required for mapping protein binding sites or specific DNA structures on circular DNA molecules by high-resolution imaging techniques such as electron and atomic force microscopies. Site-specific labeling can be achieved by ligating a DNA fragment to a stem-loop-triplex-forming oligonucleotide, thereby forming a topologically linked complex. The superhelicity of the plasmid is not altered and the process can be applied to two different target sites simultaneously, using DNA fragments of different sizes. Observation of the labeled plasmids by electron microscopy revealed that, under conditions where the triple helices were stable, the two labels were located at 339+/-34 bp from one another, in agreement with the distance between the two target sequences for triple helix formation (350 bp). Under conditions where the triple helices were not stable, the short DNA fragments could slide away from their target site. The concomitant attachment of two different stable labels makes it possible, for the first time to our knowledge, to label a circular DNA molecule and obtain information on its direction. In addition to its potential applications as a tool for structural investigations of single DNA molecules and their interactions with proteins, this DNA labeling method may also prove useful in biotechnology and gene therapy.     

Cytochemical characterization of two types of nuclear bodies in Cicer arietinum L.

The present study was carried out to characterize two distinct types of nuclear bodies, the nucleolus-associated bodies (NABs) and the satellites (SATs) using some specific staining, enzyme and immunogold labeling techniques in Cicer arietinum L. These bodies are of interest as the functional components of plant nucleus. DNA-specific staining and labeling with anti-DNA, a monoclonal antibody, were employed to verify the presence of DNA in NABs as well as in SATs. The enzyme-gold labeling technique was used to compare the relative amounts of RNase-gold and protease-gold labeling over the NABs. In NABs, RNase-gold labeling was relatively low compared to the protease-gold labeling. Ag-NOR staining revealed a similar content of NOR-silver proteins in both NABs and granular zone of the nucleolus. The NABs do not contain any DNA as they show negative response to DNA-specific stains and also when incubated with anti-DNA, only few gold particles are found over these structures. The SATs, on the other hand, react positively with DNA-specific stains, and high labeling is recorded with anti-DNA along with the dense chromatin masses.