Specific detection of residual CHO host cell DNA by real-time PCR.

Chinese hamster ovary cells have been widely used to manufacture recombinant proteins for human therapeutic use. A sensitive quantitative real-time polymerase chain reaction assay for the detection of residual Chinese hamster (Cricetulus griseus) DNA is presented in this paper. The assay is reasonably affordable and can be adapted for high-throughput screening using 96-well format. Real-time PCR primers were designed to amplify a 150bp region of a genomic fragment from hamster DNA. The specificity of the probe was evaluated in real-time PCR reactions using genomic DNA from mouse fibroblast, human kidney and hamster ovary cell lines as template. Sensitivity of real-time PCR was compared on genomic DNA from hamster cell line CHO DG44. These primers can be used in real-time PCR reactions to detect presence of contaminating hamster DNA in purified protein samples down to sensitivity of 300fg genomic DNA.     

Rapid zygosity determination in mice by SYBR Green real-time genomic PCR of a crude DNA solution

We examined whether crude DNA extracts prepared from gene-engineered mouse tissues are suitable as a template for zygosity determination by SYBR Green real-time genomic PCR. A crude DNA solution was prepared by brief incubation with lysis buffer containing ear, tail, or fetus of ROSA26 mouse, a gene-trapped strain carrying the β-galactosidase (β-gal) gene. Five serially diluted crude DNA samples (original, 2-, 4-, 8-, 16-diluted) were next prepared and then subjected to three-step (95°C, 60°C and 72°C) reactions of real-time PCR to detect the β-gal gene and the receptor-activity-modifying protein 3 (ramp3) gene (as an internal reference gene). The slopes of standard curves obtained from the real-time PCR indicated that amplification efficiency was approximately 99%, and the efficiencies of target and reference were almost equal. With this system, we next determined the zygosity of mice derived from mating heterozygous ROSA26 females and males, and found a sharp distinction in zygosity, wild-type, heterozygous and homozygous. Assessment of crude DNA samples from other gene-engineered mice including B6ZP3Cre-Tg, B6rAM-Tg, and Ramp2-gene-targeted strains revealed that our method was effective for determination of zygosity. The present method is more convenient and rapid than formerly published methods employing purified genomic DNA as a template. Our method will be particularly useful for experiments requiring rapid and accurate genotyping of gene-modified animals/fetuses.     

Noninvasive Method of DNA Isolation From Fecal Epithelial Tissue of Dairy Animals

A novel noninvasive genomic DNA isolation protocol from fecal tissue, by the proteinase K digestion and guanidine hydrochloride extraction method, was assessed for the genotyping of cattle and buffalo. The epithelial tissues present on the surface of the feces were used as source for isolation of genomic DNA. The DNA isolated from fecal tissue was found to be similar as those obtained from other body tissues such as skin, brain, liver, kidney, and muscle. The quality of DNA was checked by agarose gel electrophoresis and polymerase chain reaction (PCR). We successfully amplified a 320 bp MHC class II DRB gene and a 125 bp mt-DNA D-loop region from isolated genomic DNA of cattle. Thus, the DNA isolated using this method was suitable for common molecular biology methods, such as restriction enzyme digestion and genotyping of dairy animals through PCR.     

Quantitative analysis of total mitochondrial DNA: competitive polymerase chain reaction versus real-time polymerase chain reaction

An efficient and effective method for quantification of small amounts of nucleic acids contained within a sample specimen would be an important diagnostic tool for determining the content of mitochondrial DNA (mtDNA) in situations where the depletion thereof may be a contributing factor to the exhibited pathology phenotype. This study compares two quantification assays for calculating the total mtDNA molecule number per nanogram of total genomic DNA isolated from human blood, through the amplification of a 613-bp region on the mtDNA molecule. In one case, the mtDNA copy number was calculated by standard competitive polymerase chain reaction (PCR) technique that involves co-amplification of target DNA with various dilutions of a nonhomologous internal competitor that has the same primer binding sites as the target sequence, and subsequent determination of an equivalence point of target and competitor concentrations. In the second method, the calculation of copy number involved extrapolation from the fluorescence versus copy number standard curve generated by real-time PCR using various dilutions of the target amplicon sequence. While the mtDNA copy number was comparable using the two methods (4.92 +/- 1.01 x 10(4) molecules/ng total genomic DNA using competitive PCR vs 4.90 +/- 0.84 x 10(4) molecules/ng total genomic DNA using real-time PCR), both inter- and intraexperimental variance were significantly lower using the real-time PCR analysis. On the basis of reproducibility, assay complexity, and overall efficiency, including the time requirement and number of PCR reactions necessary for the analysis of a single sample, we recommend the real-time PCR quantification method described here, as its versatility and effectiveness will undoubtedly be of great use in various kinds of research related to mitochondrial DNA damage- and depletion-associated disorders.     

Enrichment of specific genes from genomic DNA or from clone library DNA, using R-looping

We have developed a procedure for enriching DNA for specific sequences that is based on R-looping (Thomas et al., 1976). R-loops are formed with the DNA using mRNAs containing the sequence of interest and then isolated on poly(U)-sepharose via the poly(A) tail of the mRNA. Model experiments showed that plasmid DNA containing a cDNA copy of an immunoglobulin kappa chain mRNA could be selectively retrieved using this procedure. Approx. 5-10% of the kappa sequences in mouse embryo DNA could be recovered by R-looping, while non-specific binding of mouse DNA to the poly(U)-sepharose column was 0.03-0.04%. This represents a 100-200-fold enrichment of mouse genomic kappa sequences. We have also used the procedure to rapidly screen a mouse clone library for immunoglobulin heavy chain genes. DNA from the clone library was enriched 100-200-fold using immunoglobulin heavy chain mRNAs, and the enriched DNA repackaged in vitro to recover the phage.     

Non-invasive genotyping of transgenic animals using fecal DNA

For genotyping of transgenic animals, many IACUC guidelines recommend the use of fecal DNA when possible because this approach is non-invasive. Existing methods for extracting fecal DNA may be costly or involve the use of toxic organic solvents. Furthermore, feces contain an abundance of PCR inhibitors that may hinder DNA amplification when they are co-purified with fecal DNA. Here the authors describe a cost-effective, non-toxic method for genotyping transgenic animals by using the reagent AquaStool to extract fecal DNA and remove PCR inhibitors. Genotyping results obtained from fecal DNA samples extracted using AquaStool were reliably accurate when compared with results obtained from tail DNA samples. Because it is non-invasive, the authors believe that use of this method for genotyping transgenic animals using fecal DNA samples may improve animal welfare.     

Efficient DNA Extraction from Nail Clippings Using the Protease Solution from <Emphasis Type="Italic">Cucumis melo</Emphasis>

Owing to the increasing importance of genomic information, obtaining genomic DNA easily from biological specimens has become more and more important. This article proposes an efficient method for obtaining genomic DNA from nail clippings. Nail clippings can be easily obtained, are thermostable and easy to transport, and have low infectivity. The drawback of their use, however, has been the difficulty of extracting genomic material from them. We have overcome this obstacle using the protease solution obtained from Cucumis melo. The keratinolytic activity of the protease solution was 1.78-fold higher than that of proteinase K, which is commonly used to degrade keratin. With the protease solution, three times more DNA was extracted than when proteinase K was used. In order to verify the integrity of the extracted DNA, genotype analysis on 170 subjects was performed by both PCR–RFLP and Real Time PCR. The results of the genotyping showed that the extracted DNA was suitable for genotyping analysis. In conclusion, we have developed an efficient extraction method for using nail clippings as a genome source and a research tool in molecular epidemiology, medical diagnostics, and forensic science.     

三种提取柱状黄杆菌基因组DNA方法的比较

采用酚氯仿抽提法、CTAB法和SDS-蛋白酶K法分别对鱼类病原菌柱状黄杆菌提取基因组DNA。使用超微量紫外分光光度计和琼脂糖凝胶电泳检测所提取的基因组DNA的产量和质量,并用PCR扩增对DNA进行了评价。结果显示,3种方法均可提取到柱状黄杆菌的基因组DNA,并能有效扩增细菌16S rDNA序列,但CTAB法提取的DNA产量和质量最高,CTAB法可以作为柱状黄杆菌DNA提取以开展分子生物学研究的首选方法。     

Rapid isolation of terminal sequences from cloned plant DNA fragments

The isolation of DNA clone termini is an important step in the development of DNA contigs utilized for a range of applications, including physical mapping, genetic map-based cloning, insertion mutagenesis cloning, and isolation of complete gene sequences. We describe a rapid PCR-based method for the isolation of vector-insert junctions, or insert terminal sequences, of cloned plant DNA fragments. PCR amplification is performed using a vector-specific primer and a nonspecific primer, originally designed for use in animal systems, containing degenerative bases that we have shown can also anneal to plant insert DNA. Using this method we have successfully isolated end-terminal sequences from plant genomic clones harbored in YAC, BAC, and bacteriophage λ vectors. Termini of genomic clones from both tomato andArabidopsis were isolated demonstrating the utility of this technique among a range of plant species.     

TECHNICAL REPORT: Rapid confirmation of gene targeting in embryonic stem cells using two long-range PCR techniques

Gene targeting in mouse embryonic stem (ES) cells generally includes the analysis of numerous colonies to identify a few with mutations resulting from homologous recombination with a targeting vector. Thus, simple and efficient screening methods are needed to identify targeted clones. Optimal screening approaches require probes from outside of the region included in the targeting vector to avoid detection of the more common random insertions. However, the use of large genomic fragments in targeting vectors can limit the availability of cloned DNA, thus necessitating a strategy to obtain unique flanking sequences. We describe a rapid method to identify sequences adjacent to cloned DNA using long-range polymerase chain reaction (PCR) amplification from a genomic DNA library, followed by direct nucleotide sequencing of the amplified fragment. We have used this technique in two independent gene targeting experiments to obtain genomic DNA sequences flanking the mouse cholecystokinin (CCK) and gastrin genes. The sequences were then used to design primers to characterize ES cell lines with CCK or gastrin targeted gene mutations, employing a second long-range PCR approach. Our results show that these two long-range PCR methods are generally useful to rapidly and accurately characterize allele structures in ES cells     

A one-step method for quantitative determination of uracil in DNA by real-time PCR

Uracil may occur in DNA due to either cytosine deamination or thymine replacing incorporation. Its quantitative characterization is important in assessing DNA damages in cells with perturbed thymidylate metabolism or within different DNA segments involved in immunoglobulin gene diversification. The archaeal DNA polymerase from Pyrococcus furiosus binds strongly to the deaminated base uracil and stalls on uracil-containing templates. Here, we present a straightforward method for quantitative assessment of uracil in DNA within specific genomic segments. We use wild-type P. furiosus polymerase in parallel with its point mutant version which lacks the uracil-binding specificity on synthetic and genomic DNA samples to quantify the uracil content in a single-step real-time PCR assay. Quantification of the PCR results is based on an approach analogous to template copy number determination in comparing different samples. Data obtained on synthetic uracil-containing templates are verified by direct isotopic measurements. The method is also tested on physiological DNA samples from Escherichia coli and mouse cell lines with perturbed thymidylate biosynthesis. The present PCR-based method is easy to use and measures the uracil content within a genomic segment defined by the primers. Using distinct sets of primers, the method allows the analysis of heterogeneity of uracil distribution within the genome.     

Fingerprinting genomes by use of PCR with primers that encode protein motifs or contain sequences that regulate gene expression

PCR primers of arbitrary nucleotide sequence have identified DNA polymorphisms useful for genetic mapping in a large variety of organisms. Although technically very powerful, the use of arbitrary primers for genome mapping has the disadvantage of characterizing DNA sequences of unknown function. Thus, there is no reason to anticipate that DNA fragments amplified by use of arbitrary primers will be enriched for either transcribed or promoter sequences that may be conserved in evolution. For these reasons, we modified the arbitrarily primed PCR method by using oligonucleotide primers derived from conserved promoter elements and protein motifs. Twenty-nine of these primers were tested individually and in pairwise combinations for their ability to amplify genomic DNA from a variety of species including various inbred strains of laboratory mice and Mus spretus. Using recombinant inbred strains of mice, we determined the chromosomal location of 27 polymorphic fragments in the mouse genome. The results demonstrated that motif sequence-tagged PCR products are reliable markers for mapping the mouse genome and that motif primers can also be used for genomic fingerprinting of many divergent species.     

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.     

Evaluation of a Quantitative DNA Methylation Analysis Technique using Methylation-Sensitive/Dependent Restriction Enzymes and Real-Time PCR

DNA methylation in mammals has been shown to play many important roles in diverse biological phenomena. Several methods have been developed for the measurement of region-specific levels of DNA methylation. We sought a technique that could be used to quantitatively evaluate multiple independent loci in several tissues in a quick and cost-effective manner. Recently, a few quantitative techniques have been developed by employing the use of real-time PCR, though they require the additional step of sodium bisulfite conversion. Here we evaluate a technique that involves the digestion of non-sodium bisulfite-treated genomic DNA using methylation-sensitive and methylation-dependent restriction enzymes followed by real-time PCR. The utility of this method is tested by analyzing seventeen genomic regions of known tissue-specific levels of DNA methylation including three imprinted genes. We find that this approach generates rapid, reproducible and accurate results (range= ±5%) without the additional time required for bisulfite conversion. This approach is also adaptable for use with smaller amounts of starting material. We propose this method as a rapid, quantitative method for the analysis of DNA methylation at single sites or within small regions of DNA.      

Non-invasive transgenic mouse genotyping using stool analysis

Commonly applied genotyping of transgenic mice involves using tail or ear biopsies which may cause discomfort to the animal. We tested the possibility of polymerase chain reaction (PCR)-based mouse genotyping using stool specimens from three transgenic mouse lines that overexpress 10-18 transgene copies of human keratin polypeptide 18, as compared to genotyping using tail biopsies. Stool specimens were obtained with ease and provided easy detection of the human transgene product. The method was also able to detect endogenous mouse actin and keratin genes which presumably are present at two copies each. Nested PCR was not necessary for genotyping using stool-derived genomic material but did increase the relative magnitude of the signal obtained. The non-invasive genotyping method described herein offers a reproducible, sensitive and effective modality that could replace invasive tissue sampling procedures currently used to test thousands of genetically altered mice.     

Easy and rapid method of zygosity determination in transgenic mice by SYBR<Superscript>®</Superscript> Green real-time quantitative PCR with a simple data analysis

Establishment and maintenance of transgenic mouse strains require being able to distinguish homozygous from heterozygous animals. To date, the developed real-time quantitative PCR techniques are often complicated, time-consuming and expensive. Here, we propose a very easy and rapid method with a simple data analysis to determine zygosity in transgenic mice. We show that the real-time quantitative PCR using SYBR Green fluorescent dye can be applied to discriminate two-fold differences in copy numbers of the transgene. Our procedure has to fit only three simple requirements: (1) to design primers capable of detecting one Ct difference for two-fold differences in DNA amounts (2) to measure genomic DNA concentrations accurately and (3) to have a reference animal of known zygosity in each run. Then, if the Ct values for the control gene are similar in all samples, we are able to compare directly the Ct values for the transgene in every sample, and so, to deduce the zygosity status of each mouse relative to the reference animal. This method is really simple and reliable, and it may be valuable as a rapid screening tool for zygosity status in transgenic animals.     

A PCR-based method for isolation of genomic DNA flanking a known DNA sequence

We describe a simple PCR-based method for the isolation of genomic DNA that lies adjacent to a known DNA sequence. The method is based on the directional cloning of digested genomic DNA into the multiple cloning site of a pUC-based plasmid to generate a limited genomic library. The library is plated onto a number of selective LA plates which are incubated overnight, and recombinant plasmid DNA is then isolated from resistant colonies pooled from each plate. PCR amplification is performed on the pooled recombinant plasmid DNAs using primers specific for the pUC vector and the known genomic sequence. The combination of efficient directional cloning and bacterial transformation gives relative enrichment for the genomic sequence of interest and generates a simple DNA template, enabling easy amplification by PCR.     

High-resolution melt analysis of DNA methylation to discriminate semen in biological stains

The goal of this study was to develop a method for the detection of semen in biological stains using high-resolution melt (HRM) analysis and DNA methylation. To perform this task, we used an epigenetic locus that targets a tissue-specific differentially methylated region for semen. This specific locus, ZC3H12D, contains methylated CpG sites that are hypomethylated in semen and hypermethylated in blood and saliva. Using this procedure, DNA from forensic stains can be isolated, processed using bisulfite-modified polymerase chain reaction (PCR), and detected by real-time PCR with HRM capability. The method described in this article is robust; we were able to obtain results from samples with as little as 1 ng of genomic DNA. Samples inhibited by humic acid still produced reliable results. Furthermore, the procedure is specific and will not amplify non-bisulfite-modified DNA. Because this process can be performed using real-time PCR and is quantitative, it fits nicely within the workflow of current forensic DNA laboratories. As a result, it should prove to be a useful technique for processing trace evidence samples for serological analysis.     

An efficient method for the extraction of DNA from formalin-fixed, paraffin-embedded tissue by sonication

A method was developed for fast and efficient isolation of DNA from formalin-fixed, paraffin-embedded tissue sections for subsequent use in PCRs and DNA hybridization assays. The method relies on the use of a sonicating water bath to disrupt tissue samples to which a small amount of micro-sized glass beads have been added. The sonicating glass beads provide fast and efficient physical shearing of fixed tissue sections, allowing for quick release and solubilization of the DNA. The extraction process from paraffin section to amplifiable target DNA takes 30 minutes. The method eliminates the need for repetitive solvent extractions and exhaustive proteinase K digestion. PCR amplification of human genomic and viral target sequences was successfully carried out on DNA isolated from a number of different types of normal and infected tissues.