A method for the purification of DNA/protein complexes applied to DNA topoisomerase II cleavage sites.

The object of this study was to devise a purification method for DNA/topoisomerase II complexes, with which to examine the enzyme's cleavage site specificity in cellular differentiation. Retinoic acid-induced differentiation involves topoisomerase II-mediated transient changes in DNA supercoiling, but it is not known whether this occurs at specific sites in the genome. Topoisomerase II forms a covalent DNA enzyme complex as it acts, which can be recovered by the sodium dodecyl sulfate (SDS)/KCl precipitation method, but this method fails to recover significantly more DNA from cells induced to differentiate. This may in part reflect the low numbers of retinoic acid-induced protein-linked breaks in DNA and also the method's relative inefficiency for DNA with few attached topoisomerase molecules. This suggested that an additional purification method would be required to enrich sufficiently for cleavage site DNA to address the issue of site specificity. The principle of our method is to couple poly(ethylene glycol) (PEG) to topoisomerase while it is covalently attached to DNA and then to use phase partitioning in an aqueous two-phase system of PEG and phosphate to separate free DNA from DNA bound to PEG-modified topoisomerases (which have high affinities for the phosphate-rich and PEG-rich phases, respectively). The method can be used in conjunction with DNase protection and, unlike the SDS/KCl method, can fractionate short fragments of DNA to which single protein molecules are attached. Using the SDS/KCl precipitation and new method in series, we have recovered protein-linked DNA from HL60 cells induced to differentiate to the granulocyte lineage (by retinoic acid) or to the monocyte/macrophage lineage (by phorbol myristate acetate) and have demonstrated that specific sequences become protein linked, probably to topoisomerase II, during induced differentiation.     

Sliding window analyses for optimal selection of mini-barcodes, and application to 454-pyrosequencing for specimen identification from degraded DNA

DNA barcoding remains a challenge when applied to diet analyses, ancient DNA studies, environmental DNA samples and, more generally, in any cases where DNA samples have not been adequately preserved. Because the size of the commonly used barcoding marker (COI) is over 600 base pairs (bp), amplification fails when the DNA molecule is degraded into smaller fragments. However, relevant information for specimen identification may not be evenly distributed along the barcoding region, and a shorter target can be sufficient for identification purposes. This study proposes a new, widely applicable, method to compare the performance of all potential 'mini-barcodes' for a given molecular marker and to objectively select the shortest and most informative one. Our method is based on a sliding window analysis implemented in the new R package SPIDER (Species IDentity and Evolution in R). This method is applicable to any taxon and any molecular marker. Here, it was tested on earthworm DNA that had been degraded through digestion by carnivorous landsnails. A 100 bp region of 16 S rDNA was selected as the shortest informative fragment (mini-barcode) required for accurate specimen identification. Corresponding primers were designed and used to amplify degraded earthworm (prey) DNA from 46 landsnail (predator) faeces using 454-pyrosequencing. This led to the detection of 18 earthworm species in the diet of the snail. We encourage molecular ecologists to use this method to objectively select the most informative region of the gene they aim to amplify from degraded DNA. The method and tools provided here, can be particularly useful (1) when dealing with degraded DNA for which only small fragments can be amplified, (2) for cases where no consensus has yet been reached on the appropriate barcode gene, or (3) to allow direct analysis of short reads derived from massively parallel sequencing without the need for bioinformatic consolidation.     

一种快速提取细菌总DNA的方法研究

随着分子生物学技术应用于环境微生物研究的深入开展,占自然界微生物物种总数的90%以上的不能人工培养或培养困难的微生物已经可以借助分子生物学技术进行功能基因的开发和利用。而快速得到纯度较高,结构完整的细菌染色体DNA成为这一技术得以实现的前提。本文报道了利用高温处理和SDS的裂解作用相结合而建立的一种快速、简便的提取细菌染色体DNA的方法。经过脉冲电泳实验证明,利用本方法提取得到的几种革兰氏阳性和革兰氏阴性菌株的基因组DNA结构完整,并且无明显降解,无须经过纯化,可以直接进行PCR扩增和酶切等分子生物学操作,将此方法进一步应用于土壤环境DNA的提取方面,同样达到了快速得到大片段、高质量的环境微生物基因组的目的,为研究未培养的环境微生物多样性打下了坚实的基础,同时为环境基因组的提取提供了一个新的途径。     

Simultaneously monitoring DNA binding and helicase-catalyzed DNA unwinding by fluorescence polarization

A new method for helicase-catalyzed DNA unwinding is described. This assay takes advantage of the substantial change in fluorescence polarization (FP) upon helicase binding and DNA unwinding. The low anisotropy value, due to the fast tumbling of the free oligonucleotide in solution, increases abruptly upon binding of helicase to the fluorescein-labeled oligonucleotide. The high anisotropy of the helicase– DNA complex decreases as the fluorescein-labeled oligonucleotide is released from the complex through helicase-catalyzed DNA unwinding. This FP signal can be measured in real time by fluorescent spectroscopy. This assay can simultaneously monitor DNA binding and helicase-catalyzed DNA unwinding. It can also be used to determine the polarity in DNA unwinding mediated by helicase. This FP assay should facilitate the study of the mechanism by which helicase unwinds duplex DNA, and also aid in screening for helicase inhibitors, which are of growing interest as potential anticancer agents.     

A mass spectrometry-based approach for identifying novel DNA polymerase substrates from a pool of dNTP analogues

There has been a long-standing interest in the discovery of unnatural nucleotides that can be incorporated into DNA by polymerases. However, it is difficult to predict which nucleotide analogs will prove to have biological relevance. Therefore, we have developed a new screening method to identify novel substrates for DNA polymerases. This technique uses the polymerase itself to select a dNTP from a pool of potential substrates via incorporation onto a short oligonucleotide. The unnatural nucleotide(s) is then identified by high-resolution mass spectrometry. By using a DNA polymerase as a selection tool, only the biologically relevant members of a small nucleotide library can be quickly determined. We have demonstrated that this method can be used to discover unnatural base pairs in DNA with a detection threshold of ≤10% incorporation.     

Recycling Isolation of Plant DNA,A Novel Method

DNA is one of the most basic and essential genetic materials in the field of molecular biology.To date,isolation of sufficient and good-quality DNA is still a challenge for many plant species,though various DNA extraction methods have been published.In the present paper,a recycling DNA extraction method was proposed.The key step of this method was that a single plant tissue sample was recycled for DNA extraction for up to four times,and correspondingly four DNA precipitations(termed as the 1st,2nd,3rd and 4th DNA sample, respectively) were conducted.This recycling step was integrated into the conventional CTAB DNA extraction method to establish a recycling CTAB method.This modified CTAB method was tested in eight plant species,wheat,sorghum,barley,corn,rice,Brachypodium distachyon,Miscanthus sinensis and tung tree.The results showed that high-yield and good-quality DNA samples could be obtained by using this new method in all the eight plant species.The DNA samples were good templates for PCR amplification of both ISSR and SSR markers.The recycling method can be used in multiple plant species and can be integrated with multiple conventional DNA isolation methods,and thus is an effective and universal DNA isolation method.     

Use of glucose-6-phosphate dehydrogenase as a new label for nucleic acid hybridization reactions

We describe here a sensitive new procedure for detecting DNA hybridization by dot blots. The method utilizes DNA or oligonucleotide probes labeled with biotin, sulfone, or haptens that can be detected by glucose-6-phosphate dehydrogenase (G6PDH) conjugates. Biotin labeling of DNA gave the best sensitivity. G6PDH activity was revealed by staining or by bioluminescence using an FMN oxidoreductase and a luciferase from Beneckea harveyi. Bioluminescent detection offered better sensitivity and faster revelation than the colorimetric assay and was found to be very useful in visualizing single mutations in human DNA after hybridization with an allele-specific biotinylated oligonucleotide probe. Revelation can be performed using a luminometer, photographic films, or a very sensitive video camera. The detection is limited by the nonspecific binding of the labeled reagent (streptavidin or antibodies). This limit is similar to that obtained with other nonisotopic labeling procedures, but our method is faster and several hybridization reactions can be performed on the same support.     

New perspectives in diet analysis based on DNA barcoding and parallel pyrosequencing: the trnL approach

The development of DNA barcoding (species identification using a standardized DNA sequence), and the availability of recent DNA sequencing techniques offer new possibilities in diet analysis. DNA fragments shorter than 100-150 bp remain in a much higher proportion in degraded DNA samples and can be recovered from faeces. As a consequence, by using universal primers that amplify a very short but informative DNA fragment, it is possible to reliably identify the plant taxon that has been eaten. According to our experience and using this identification system, about 50% of the taxa can be identified to species using the trnL approach, that is, using the P6 loop of the chloroplast trnL (UAA) intron. We demonstrated that this new method is fast, simple to implement, and very robust. It can be applied for diet analyses of a wide range of phytophagous species at large scales. We also demonstrated that our approach is efficient for mammals, birds, insects and molluscs. This method opens new perspectives in ecology, not only by allowing large-scale studies on diet, but also by enhancing studies on resource partitioning among competing species, and describing food webs in ecosystems.     

Detection of hybrid formation between peptide nucleic acids and DNA by fluorescence polarization in the presence of polylysine.

A new method for the detection of PNA/DNA hybrids is presented. In this method, short PNA probes (9-13 mer) are labeled with a fluorescent dye and allowed to hybridize to target DNA molecules. A cationic polyamino acid, such as polylysine, is then added to the reaction mixture, whereupon the DNA molecules bind electrostatically to this polycation. The PNA probes, which are uncharged or may carry only a small charge due to the fluorescent dye, do not bind to polylysine unless hybridized to the negatively charged DNA target. The binding of the labeled PNA/DNA hybrid to the high-molecular-weight polymer leads to a significant change in the rotational correlation time of the fluorophore attached to the PNA. This can be conveniently detected by measuring the fluorescence polarization of the latter. The method is completely homogeneous because no separation of free from bound PNA probe is required. The hybridization and dehybridization reactions can be followed in real time. The method has been applied to the typing of single-nucleotide polymorphisms in PCR products.     

Real time quantitative PCR as a method to evaluate simian virus 40 removal during pharmaceutical protein purification.

Continuous cell lines used for pharmaceutical protein manufacturing have the potential to be contaminated by viruses. To ensure the safety of pharmaceutical proteins derived from continuous cell lines, validation of the ability of the manufacturing process to clear potential contaminating viruses is required for product registration. In this paper, a real time quantitative PCR method has been applied to the evaluation of simian virus 40 (SV40) removal during chromatography and filtration procedures. This method takes advantage of the 5'-3' exonuclease activity of Taq DNA polymerase and utilizes the PRISM 7700 sequence detection system of PE Applied Biosystems for automated SV40 DNA quantification through a dual-labeled fluorogenic probe. This method provides accurate and reproducible quantification of SV40 DNA. The SV40 clearance during chromatography and filtration procedures determined by this method is highly comparable with that determined by the cell-based infectivity assay. This method offers significant advantages over cell-based infectivity assays, such as higher sensitivity, greater reliability, higher sample throughput and lower cost. This method can be potentially used to evaluate the clearance of all model viruses during chromatography and filtration procedures. This method can be used to substitute cell-based infectivity assays for process validation of viral removal procedures and the availability of this method should greatly facilitate and reduce the cost of viral clearance evaluations required for new biologic product development.     

Preparation of plasmid DNA by sequential enzymatic digestion.

A new method for the preparation of plasmid DNA from Escherichia coli, sequential enzymatic digestion, is described. The method is based on sequential and selective enzymatic digestion of all components of E. coli except for the supercoiled plasmid DNA. The key enzymes are exonuclease I and exonuclease III that specifically hydrolyze linear chromosomal DNA and are unable to attack supercoiled plasmid DNA under controlled conditions. Isolated plasmid DNA can be sequenced and digested with restriction enzymes.     

Identification of microorganisms using random primed PCR

The polymerase chain reaction has facilitated the use of molecular approaches in microbiology including new strategies for the rapid identification of micro-organisms. Approaches based on the use of random primers and standard conditions, allows characteristic DNA fingerprints to be generated from any micro-organism even in the absence of information about its DNA sequence. Different primers can be used to produce genus-specific, species-specific, or even strain-specific DNA fingerprints. This article covers the background to this strategy, describes three different approaches to generating DNA fingerprints using random primers, and provides experimental detail for one method, RAPD.     

Engineering of large numbers of highly specific homing endonucleases that induce recombination on novel DNA targets

The last decade has seen the emergence of a universal method for precise and efficient genome engineering. This method relies on the use of sequence-specific endonucleases such as homing endonucleases. The structures of several of these proteins are known, allowing for site-directed mutagenesis of residues essential for DNA binding. Here, we show that a semi-rational approach can be used to derive hundreds of novel proteins from I-CreI, a homing endonuclease from the LAGLIDADG family. These novel endonucleases display a wide range of cleavage patterns in yeast and mammalian cells that in most cases are highly specific and distinct from I-CreI. Second, rules for protein/DNA interaction can be inferred from statistical analysis. Third, novel endonucleases can be combined to create heterodimeric protein species, thereby greatly enhancing the number of potential targets. These results describe a straightforward approach for engineering novel endonucleases with tailored specificities, while preserving the activity and specificity of natural homing endonucleases, and thereby deliver new tools for genome engineering.     

Flow cytometry DNA analysis on tumor cell subpopulation of human tumor specimens by exclusion of lymphohemopoietic cells

We describe a new flow cytometry procedure in which DNA analyses can be obtained selectively on pure, freshly obtained tumor cell subpopulations of human tumor specimens. This procedure is based on exclusion from analysis of the contaminating lymphohemopoietic cells mixed with tumor cells in tumor specimens. This exclusion is made possible by labeling all lymphohemopoietic cells with an antibody to HLe-1 (HLE), which is present on all lymphohemopoietic cells but on no other cells, and by gating against these labeled cells when analyzing for DNA. For the model system, a 1:1 mixture of normal human peripheral blood leukocytes and either of two human cancer cell lines, HEp-2 and MCF-7, normal leukocyte contamination can be reduced to 3.1% while retaining 94.7% of tumor cells for DNA analysis. Four examples of human tumor samples, two cases each of malignant effusions and lymph node metastases, were analyzed with this procedure. The results clearly indicate that this new method will improve ploidy analysis/aneuploidy detection and will make it possible to obtain more accurate cell-cycle analyses of tumor cells than have previously been possible. This new procedure will contribute to clinical and biological studies involving DNA of human tumors.     

An efficient method for DNA extraction from cyanobacteria isolated from hypersaline and marine environments

Cyanobacteria are ancient organisms surviving on the earth due to their simple nutritional requirements and ability to produce distinct secondary metabolites that can combat detrimental environmental impacts. In order to understand these abilities of cyanobacteria at the molecular level, it is necessary to extract high‐quality genomic DNA. However, the presence of secondary metabolites and exopolysaccharides hinders the DNA extraction from these organisms, especially from hypersaline environments. Here we have developed and compared a new method with two known methods of DNA extraction from environmental isolates. The results clearly indicate that the new optimized method yielded large amount of DNA with high purity. Additionally, the extracted DNA showed reduced degradation and excellent overall quality, which can be used directly for downstream purposes such as PCR and sequencing.     

DNA chip replication for a personalized DNA chip

We report the replication technology of DNA chip using by sequence specific localization of nucleic acids via hybridization and electric transfer of the nucleic acids onto a new substrate without losing their array information. The denatured DNA fragments are first spotted and UV-cross-linked on a nylon membrane. The membrane is then immersed and hybridized in a DNA mixture solution that contains all complementary sequences of the nucleic acids to be hybridized with the DNA fragments on the membrane. The hybridized DNA fragments are transferred to another membrane at the denatured condition. After separating two membranes, the transferred membrane contains a complementary array of DNA fragments. This method can be used for the replication of the same copy of DNA chip repeatedly and moreover could be applied for a personalized DNA chip fabrication, where specific information of each spot of DNA chip is originated from the genetic information of a personal sample.     

Mutation detection by electrocatalysis at DNA-modified electrodes

Detection of mutations and damaged DNA bases is important for the early diagnosis of genetic disease. Here we describe an electrocatalytic method for the detection of single-base mismatches as well as DNA base lesions in fully hybridized duplexes, based on charge transport through DNA films. Gold electrodes modified with preassembled DNA duplexes are used to monitor the electrocatalytic signal of methylene blue, a redox-active DNA intercalator, coupled to [Fe(CN)6]3-. The presence of mismatched or damaged DNA bases substantially diminishes the electrocatalytic signal. Because this assay is not a measure of differential hybridization, all single-base mismatches, including thermodynamically stable GT and GA mismatches, can be detected without stringent hybridization conditions. Furthermore, many common DNA lesions and "hot spot" mutations in the human p53 genome can be distinguished from perfect duplexes. Finally, we have demonstrated the application of this technology in a chip-based format. This system provides a sensitive method for probing the integrity of DNA sequences and a completely new approach to single-base mismatch detection.     

Rapid isolation of DNA from Dioscorea species suitable for PCR,restriction digestion and pathogen screening

The methods employed for DNA extraction from many plants is difficult because of the metabolites that interfere with DNA isolation procedures. We have developed a reliable and efficient method for isolating genomic DNA free from polysaccharide, polyphenols and protein contaminants from Dioscorea spp. The method involves inactivation of contaminant proteins by using CTAB/Proteinase K and precipitation of polysaccharides in the presence of high concentration of salt. The purity of genomic DNA was confirmed by A260/280 and A260/230 ratios calculated from the spectrophotometric readings and further by restriction analysis of the isolated DNA using restriction enzymes Eco RI. The total genomic DNA extracted by the new protocol was used for polymerase chain reaction amplification, RAPD analysis, restriction digestion and pathogen screening. The new protocol can be successfully used for both small- and large-scale preparation of genomic DNA from different tissues of Dioscorea spp. The quarantine of seed tubers and use of pathogen-free tubers for planting is a prerequisite for integrated disease management strategy. The protocol can be used for the isolation of genomic DNA from other crop plants too.     

Intracellular viral processing, not single-stranded DNA accumulation, is crucial for recombinant adeno-associated virus transduction

Adeno-associated virus (AAV) is a unique gene transfer vector which takes approximately 4 to 6 weeks to reach its expression plateau. The mechanism for this slow-rise expression profile was proposed to be inefficient second-strand DNA synthesis from the input single-stranded (ss) DNA viral genome. In order to clarify the status of ss AAV genomes, we generated AAV vectors labeled with bromodeoxyuridine (BrdU), a nucleotide analog that can be incorporated into the AAV genome and packaged into infectious virions. Since BrdU-DNA can be detected only by an anti-BrdU antibody when DNA is in an ss form, not in a double-stranded (ds) form, ss AAV genomes with BrdU can be readily tracked in situ. Although ss AAV DNA was abundant by Southern blot analysis, free ss AAV genomes were not detectable after AAV transduction by this new detection method. Further Southern blot analysis of viral DNA and virions revealed that ss AAV DNA was protected within virions. Extracted cellular fractions demonstrated that viral particles in host cells remained infectious. In addition, a significant amount of AAV genomes was degraded after AAV transduction. Therefore, we conclude that the amount of free ss DNA is not abundant during AAV transduction. AAV transduction is limited by the steps that affect AAV ss DNA release (i.e., uncoating) before second-strand DNA synthesis can occur. AAV ss DNA released from viral uncoating is either converted into ds DNA efficiently or degraded by cellular DNA repair mechanisms as damaged DNA. This study elucidates a mechanism that can be exploited to develop new strategies to improve AAV vector transduction efficiency.