DNA分析技术及其在植物研究中的应用

从DNA/DNA杂交、RFLP分析、DNA的限制酶图谱和核苷酸序列分析、PCR技术、DNA指纹技术、RAPD分析等六个方面详细描述DNA分析技术在植物学研究中的应用 ,并讨论了DNA分析技术与植物系统学的关系。     

DNA measurement and cell cycle analysis by flow cytometry

Measurement of cellular DNA content and the analysis of the cell cycle can be performed by flow cytometry. Protocols for DNA measurement have been developed including Bivariate cytokeratin/DNA analysis, Bivariate BrdU/DNA analysis, and multiparameter flow cytometry measurement of cellular DNA content. This review summarises the methods for measurement of cellular DNA and analysis of the cell cycle and discusses the commercial software available for these purposes.     

DNA分析与基因组序列和植物系统学研究

从DNA杂交、RFLP分析、DNA的限制酶图谱分析等方面描述DNA分析技术在植物学研究中的应用,讨论了DNA分析技术与植物系统学的关系及分子数据的分析方法。并以高等植物为对象,从核DNA、叶绿体DNA和线粒体DNA三方面对植物分子系统学进行了论述。     

Nucleotide Sequence Analysis of DNA

There are three major obstacles to the analysis of the nucleotide sequence in a DNA molecule starting from a known location in the DNA molecule. First, it is difficult to obtain large quantities of homogeneous DNA. Second, even the smallest DNA molecules contain several thousand nucleotides which make sequence analysis prohibitive. Third, there are no highly base-specific DNAases available for degrading DNA for sequence analysis. We have overcome some of these obstacles; first, by incorporating highly labelled deoxynucleotides into DNA in vitro, small amounts of material can be used for sequence analysis. Second, the nucleotide sequence of DNA molecules can now be determined from the 5′-terminal. Thus, two dodecanucleotide sequences corresponding to the two cohesive ends of λ DNA have been determined¹ and a nona-decanucleotide sequence corresponding to one cohesive end of phage 186 DNA has been completed². So far, our approach is limited to starting the analysis from the 5′-ends of a DNA molecule. A more general approach is being developed for starting the analysis from other selected parts of a DNA molecule with the use of specifically designed primers.     

Adsorptive transfer stripping voltammetry: Determination of nanogram quantities of DNA immobilized at the electrode surface

In adsorptive transfer stripping voltammetry (AdTSV), DNA is first adsorbed at the electrode, the electrode is washed and transferred (with the adsorbed layer) in the medium not containing DNA, and voltammetric analysis is performed in this medium. Adsorption can be performed from a drop of DNA solution, which makes it possible to reduce the volume of the analyzed sample by two orders of magnitude as compared to that of conventional voltammetry. With the hanging mercury drop electrode the limit of detection of single-stranded DNA is below 0.1 micrograms/ml; thus if the adsorption is performed from a 10-microliter drop of DNA solution subnanogram quantities of single-stranded DNA are sufficient for the analysis. In AdTSV the behavior of single- and double-stranded DNAs markedly differ from each other in a manner similar to that in the conventional voltammetric or polarographic analysis; AdTSV can thus be used in DNA structure analysis. In AdTSV the DNA transport and its adsorption at the electrode are separated from the electrode process; due to this fact it is possible (a) to perform the voltammetric analysis of DNA from media not suitable for voltammetric analysis of the conventional type, (b) to study the interaction of immobilized DNA with other substances in solution without the results of the voltammetric analysis being influenced by DNA interactions in the bulk of solution, and (c) to exploit the differences of adsorbability of DNA and other substances in order to separate them on the electrode.     

A significance of dual parameter flow cytometric DNA analysis using the anti-keratin antibody

Flow cytometric DNA analysis using the anti-cytokeratin antibody was carried out in order to estimate more reliable measurement in single cell suspension obtained from solid tumors. It was difficult to detect a DNA aneuploidy with DI of 2.0 by one parameter analysis of DNA. Whereas it could be detected easily by using dual parameter analysis of cytokeratin and DNA. And also, the pattern of DNA multiploidy could be selected for cytokeratin positive cell population by gate analysis.     

Discriminating coding, non-coding and regulatory regions using rescaled range and detrended fluctuation analysis

In this paper we analyse the efficiency of two methods, rescaled range analysis and detrended fluctuation analysis, in distinguishing between coding DNA, regulatory DNA and non-coding non-regulatory DNA of Drosophila melanogaster. Both methods were used to estimate the degree of sequential dependence (or persistence) among nucleotides. We found that these three types of DNA can be discriminated by both methods, although rescaled range analysis performs slightly better than detrended fluctuation analysis. On average, non-coding, non-regulatory DNA has the highest degree of sequential persistence. Coding DNA could be characterised as being anti-persistent, which is in line with earlier findings of latent periodicity. Regulatory regions are shown to possess intermediate sequential dependency. Together with other available methods, rescaled range and detrended fluctuation analysis on the basis of a combined purine/pyrimidine and weak/strong classification of the nucleotides are useful tools for refined structural and functional segmentation of DNA.     

PCR-DGGE研究微生物种群中多条带产生原因分析

鸡肠道微生物菌群经PCR-DGGE分析,回收PCR-DGGE分析胶上的一条DNA片段,回收的DNA片段再重复进行2次PCR-DGGE分析,以及分别用PCR反复循环扩增和PCR高保真酶扩增后再进行DGGE分析等方法研究PCR-DGGE分析中多条带产生原因。结果显示PCR-DGGE分析中多条带产生原因可能是作PCR扩增模板的DNA混杂有少量其他DNA片段,多条带现象不易被消除。DGGE分析胶上的DNA片段测序时,将该DNA片段回收、PCR扩增后克隆,提取多个阳性克隆菌的质粒DNA片段,分别与其原目的DNA片段进行DGGE分析,在DGGE分析胶上选取与原目的DNA片段处于同一电泳位置的质粒DNA测序,提高测序的准确性。     

粪便DNA分析技术在动物生态学中的应用

粪便DNA分析是一项新发展起来的从粪便中获取动物DNA并用于相关研究的技术,该技术有助于分子生态学研究中所遇到的取样难题。通过对粪便DNA分析的研究方法、研究内容以及研究进展情况的介绍,提供了该技术不仅能用于分子生态学的许多研究领域,而且还能够提供诸如种群数量估计、领域边界划定等生态生态学信息,这是对分子生态学的重要补充。     

Analysis and purification of nucleic acids by ion-pair reversed-phase high-performance liquid chromatography

Sizing of DNA fragments is a routine analysis traditionally performed on agarose or polyacrylamide gels. Electrophoretic analysis is labor-intensive with only limited potential for automation. Recovery of DNA fragments from gels is cumbersome. We present data on automated, size-based separation of DNA fragments by ion-pair reversed-phase high performance liquid chromatography (IP RP HPLC) - DNA chromatography - on the WAVE DNA Fragment Analysis System with the DNASep cartridge. This system is suitable for accurate and rapid sizing of double-stranded (ds) DNA fragments from 50 to ca. 2000 base pairs (bp). Fluorescently labeled DNA fragments are compatible with the technology. Length-dependent separation of dsDNA fragments is sequence independent and retention times are highly reproducible. The resolving capabilities of DNA chromatography are illustrated by the analysis of multiple DNA size markers. Resolved dsDNA fragments are easily collected and are suitable for downstream applications such as sequencing and cloning. DNA chromatography under denaturing conditions with fluorescently labeled DNA fragments offers a means for the separation and purification of individual strands of dsDNA. Analysis of DNA fragments on the WAVE System is highly automated and requires minimal manual intervention. DNA chromatography offers a reliable and automated alternative to gel electrophoresis for the analysis of DNA fragments.     

Development of large DNA methods for plants: molecular cloning of large segments of Arabidopsis and carrot DNA into yeast.

Procedures for the preparation, analysis and cloning of large DNA molecules from two different plant species are described. Arabidopsis and carrot protoplasts were used for the preparation of large DNA molecules in agarose "plugs" or in solution. Pulsed-field gel electrophoresis (PFGE) analysis of large plant DNA preparations using a contour-clamped homogeneous field (CHEF) apparatus indicated that the size of the DNA was at least 12 Mb. Large DNA preparations were shown to be useful for restriction enzyme analysis of the Arabidopsis genome using both frequent and infrequent cutting enzymes and for the molecular cloning of large segments of DNA into yeast using artificial chromosome (YAC) vectors. PFGE and blot hybridization analysis of Arabidopsis and carrot DNA-containing YACs indicated that both unique and highly repeated DNA sequences were represented in these libraries.     

Repetitive DNA of Candida albicans: nuclear and mitochondrial components

We report the isolation and analysis of the rapidly reassociating DNA of the pathogenic, dimorphic fungus Candida albicans. Minicot analysis of whole-cell repetitive DNA suggested that a significant portion of this component was mitochondrial DNA. Genomic blot hybridizations in which radioactive whole-cell repetitive DNA was used as a probe revealed eight major EcoRI bands in the molecular weight range resolved by the gel system used. Isolation and analysis of high-purity mitochondrial DNA have shown that five of these bands are of mitochondrial origin. The remaining three bands are of nuclear origin and represent repetitive sequences that are found in the nuclear genome. Attempts to isolate nuclear DNA that was completely free of mitochondrial DNA contamination were unsuccessful.     

Archived Guthrie blood spots as a novel source for quantitative DNA methylation analysis

Sodium bisulfite treatment followed by PCR and DNA sequencing is widely considered the gold standard for the analysis of DNA methylation patterns. However, this technique generally requires substantial quantities of genomic DNA as starting material and is often associated with degradation of DNA. Here, we assess the feasibility of performing bisulfite sequencing on DNA isolated from 3-mm diameter punches of dried blood Guthrie spots. We demonstrate that it is possible to perform bisulfite sequencing from both freshly prepared and archived dried blood spots, using a combination of high purity DNA extraction and efficient bisulfite conversion. With the number of new technologies available for DNA methylation studies, we have extended this analysis and have successfully used a high-throughput mass spectrometry method for DNA methylation analysis on these samples. This provides a new source of material for epigenetic analysis of birth samples and provides an invaluable reference point to track temporal change in epigenetic profiles possibly linked with health and disease.     

Serial analysis of mutation spectra (SAMS): a new approach for the determination of mutation spectra of site-specific DNA damage and their sequence dependence

Many mutations occur as a result of DNA synthesis past the site of DNA damage by DNA damage bypass polymerases. The frequency and types of mutations not only depend on the nature of the damage, but also on the sequence context, as revealed from analysis of mutation spectra of DNA exposed to mutagens. Herein we report a new method for the rapid determination of the effect of sequence context on mutagenesis called SAMS for serial analysis of mutation spectra. This technique makes use of the methodology that underlies serial analysis of gene expression (SAGE) to analyze mutations that result from DNA synthesis past a DNA lesion site-specifically embedded in a library of DNA sequences. To illustrate our technique we determined the effect of sequence context on mutations generated by DNA synthesis past a tetrahydrofuran abasic site model by the DNA damage bypass polymerase yeast polymerase eta.     

Comparative mitochondrial and nuclear quantitative PCR of historical marine mammal tissue,bone, baleen,and tooth samples

The use of historical and ancient tissue samples for genetic analysis is increasing, with ever greater numbers of samples proving to contain sufficient mitochondrial and even nuclear DNA for multilocus analysis. DNA yield, however, remains highly variable and largely unpredictable based solely on sample morphology or age. Quantification of DNA from historical and degraded samples can greatly improve efficiency of screening DNA extracts prior to attempting sequencing or genotyping, but requires sequence‐specific quantitative polymerase chain reaction (qPCR) based assays to detect such minute quantities of degraded DNA. We present two qPCR assays for marine mammal DNA quantification, and results from analysis of DNA extracted from preserved soft tissues, bone, baleen, and tooth from several cetacean species. These two assays have been shown to amplify DNA from 26 marine mammal species representing 12 families of pinnipeds and cetaceans. Our results indicate that different tissues retain different ratios of mitochondrial to nuclear DNA, and may be more or less suitable for analysis of nuclear loci. Specifically, historical bone and tooth samples average 60‐fold higher ratio of mitochondrial DNA to nuclear DNA than preserved fresh soft tissue, and the ratio is almost 8000‐fold higher in baleen.     

Rapid analysis of amplified double-stranded DNA by capillary electrophoresis with laser-induced fluorescence detection

DNA amplification technology has been applied to clinical diagnosis of infectious disease, genetic disorder, and cancer. After in vitro amplification of a particular DNA region, the methods of analysis for these amplified samples play a pivotal role in clinical diagnosis. Conventional gel electrophoresis has been routinely used in the lab for checking DNA. The whole procedure is time consuming and requires more than 1 ng of DNA for detection. To achieve greater performance in DNA diagnosis, we demonstrated capillary electrophoresis with laser induced fluorescence detection for analysis of amplified DNA. The analysis of DNA could be completed within 3 min and the data is directly entered into the computer. Considering the automatic and rapid process, we believe that this method could be routinely utilized for the clinical diagnosis of amplified DNA products.     

Ancient DNA analysis of human populations

The use of ancient DNA (aDNA) in the reconstruction of population origins and evolution is becoming increasingly common. The resultant increase in number of samples and polymorphic sites assayed and the number of studies published may give the impression that all technological hurdles associated with aDNA technology have been overcome. However, analysis of aDNA is still plagued by two issues that emerged at the advent of aDNA technology, namely the inability to amplify a significant number of samples and the contamination of samples with modern DNA. Herein, we analyze five well-preserved skeletal specimens from the western United States dating from 800-1600 A.D. These specimens yielded DNA samples with levels of contamination ranging from 0-100%, as determined by the presence or absence of New World-specific mitochondrial markers. All samples were analyzed by a variety of protocols intended to assay genetic variability and detect contamination, including amplification of variously sized DNA targets, direct DNA sequence analysis of amplification products and sequence analysis of cloned amplification products, analysis of restriction fragment length polymorphisms, quantitation of target DNA, amino acid racemization, and amino acid quantitation. Only the determination of DNA sequence from a cloned amplification product clearly revealed the presence of both ancient DNA and contaminating DNA in the same extract. Our results demonstrate that the analysis of aDNA is still an excruciatingly slow and meticulous process. All experiments, including stringent quality and contamination controls, must be performed in an environment as free as possible of potential sources of contaminating DNA, including modern DNA extracts. Careful selection of polymorphic markers capable of discriminating between ancient DNA and probable DNA contaminants is critical. Research strategies must be designed with a goal of identifying all DNA contaminants in order to differentiate convincingly between contamination and endogenous DNA.     

方兴未艾的古代DNA的研究

保留在古代生物遗骸中的遗传物质DNA是一种重要的遗传资源。古代DNA的研究对于了解包括人类在内的各种生物的起源、进化和迁徙有重要意义。古代DNA的研究有其自身的特点,并且已经取得一系列重要成就。本文综述古代DNA研究的历史、方法和进展。 Abstract：DNA present in ancient samples can be recovered,amplified and analysed.It opens a new window for genetic analysis in many different disciplines,such as anthropology,archaeology,human population genetics,animal and plant evolutionary taxonomy and forensic science.In general,ancient DNA is rare in quantity,damaged in quality.To ensure the reproducibility and reliability of the results,great cares should be taken,such as various measurements against contamination and phylogenetic analysis of ancient DNA sequences.In this paper we review recovery,amplification and analysis of ancient DNA,also discuss the guidelines to ensure the authenticity of ancient DNA and the recent advances in ancient DNA study.     

Use of molecular DNA probes in the diagnosis of mucoviscidosis-- analysis of restriction fragment length polymorphisms (RFLP) in 22 high-risk families]

The results of DNA analysis with the aid of specific molecular probes are discussed. DNA analysis involved 22 families of a high risk of cystic fibrosis. A significance of the obtained results in genetic counselling is also discussed. DNA analysis enabled detection or exclusion of cystic fibrosis gene carrier state in patient's relatives. DNA analysis proved fully informative in case of 17 families being a base to offer these families prenatal diagnosis of the disease in the I trimester of pregnancy, if such a family plans conception, and to accept this diagnostic technique.     

Accurate quantification of DNA methylation using combined bisulfite restriction analysis coupled with the Agilent 2100 Bioanalyzer platform

DNA methylation is the best-studied epigenetic modification and describes the conversion of cytosine to 5-methylcytosine. The importance of this phenomenon is that aberrant promoter hypermethylation is a common occurrence in cancer and is frequently associated with gene silencing. Various techniques are currently available for the analysis of DNA methylation. However, accurate and reproducible quantification of DNA methylation remains challenging. In this report, we describe Bio-COBRA (combined bisulfite restriction analysis coupled with the Agilent 2100 Bioanalyzer platform), as a novel approach to quantitative DNA methylation analysis. The combination of a well-established method, COBRA, which interrogates DNA methylation via the restriction enzyme analysis of PCR-amplified bisulfite treated DNAs, with the Bioanalyzer platform allows for the rapid and quantitative assessment of DNA methylation patterns in large sample sets. The sensitivity and reproducibility of Bio-COBRA make it a valuable tool for the analysis of DNA methylation in clinical samples, which could aid in the development of diagnostic and prognostic parameters with respect to disease detection and management.