Easy and efficient protocol for oomycete DNA extraction suitable for population genetic analysis

Purpose of work  

A simple and rapid DNA extraction protocol capable of obtaining high-quality and quantity DNA from a large number of individuals is essential for assaying population and phylogenetic studies of plant pathogens. Most DNA extraction protocols used with oomycetes are relatively lengthy and cumbersome for high throughput analysis. Commercial kits are widely used, but low quantities of DNA are usually obtained, and with large scale analysis multiple isolations are required.     

Evaluation of an automated protocol for efficient and reliable DNA extraction of dietary samples

Molecular techniques have become an important tool to empirically assess feeding interactions. The increased usage of next‐generation sequencing approaches has stressed the need of fast DNA extraction that does not compromise DNA quality. Dietary samples here pose a particular challenge, as these demand high‐quality DNA extraction procedures for obtaining the minute quantities of short‐fragmented food DNA. Automatic high‐throughput procedures significantly decrease time and costs and allow for standardization of extracting total DNA. However, these approaches have not yet been evaluated for dietary samples. We tested the efficiency of an automatic DNA extraction platform and a traditional CTAB protocol, employing a variety of dietary samples including invertebrate whole‐body extracts as well as invertebrate and vertebrate gut content samples and feces. Extraction efficacy was quantified using the proportions of successful PCR amplifications of both total and prey DNA, and cost was estimated in terms of time and material expense. For extraction of total DNA, the automated platform performed better for both invertebrate and vertebrate samples. This was also true for prey detection in vertebrate samples. For the dietary analysis in invertebrates, there is still room for improvement when using the high‐throughput system for optimal DNA yields. Overall, the automated DNA extraction system turned out as a promising alternative to labor‐intensive, low‐throughput manual extraction methods such as CTAB. It is opening up the opportunity for an extensive use of this cost‐efficient and innovative methodology at low contamination risk also in trophic ecology.     

Rapid and efficient protocol for DNA extraction and molecular identification of the basidiomycete Crinipellis perniciosa

DNA isolation from some fungal organisms is difficult because they have cell walls or capsules that are relatively unsusceptible to lysis. Beginning with a yeast Saccharomyces cerevisiae genomic DNA isolation method, we developed a 30-min DNA isolation protocol for filamentous fungi by combining cell wall digestion with cell disruption by glass beads. High-quality DNA was isolated with good yield from the hyphae of Crinipellis perniciosa, which causes witches' broom disease in cacao, from three other filamentous fungi, Lentinus edodes, Agaricus blazei, Trichoderma stromaticum, and from the yeast S. cerevisiae. Genomic DNA was suitable for PCR of specific actin primers of C. perniciosa, allowing it to be differentiated from fungal contaminants, including its natural competitor, T. stromaticum.     

Successful extraction of DNA from archived alcohol-fixed white-eye fish specimens using an ancient DNA protocol

A protocol used routinely for rapid ancient DNA extraction was applied to fish tissue archived over 80 years ago. The method proved successful, whereas other extraction protocols failed. Researchers working on DNA from older archived fish samples are encouraged to continue to concentrate their efforts on 'white-eye' specimens, which indicate an alcohol-based fixative and are thus likely to yield viable DNA.     

New protocol for DNA extraction of stool

Present methods for DNA isolation of stool have various limitations such as the amount of stool used, the requirement of lavage fluids or the use of fresh stool. In this paper, a new method is described for the isolation of human nucleic acids from stool, which is independent from the moment of collection. Fecal samples as dry as possible were collected from 75 patients; two grams of stool were mixed with a lysis buffer containing phenol. DNA yields of crude stool were variable and ranged from 9-1686 micrograms/g of feces. With dot blots in 9 of the 75 cases, the human DNA was identified and ranged from 0.06%-46%. In the remaining 66 cases, human genomic DNA was detected by nested PCR, using human K-ras gene amplification as an example. Amplification products were confirmed for human K-ras with the exonuclease-amplification coupled capture technique (EXACCT). In conclusion, the developed DNA isolation method can be used for the study of large numbers of stool samples, is independent of the age or method of stool collection and is suitable for large-scale screening studies.     

Simple and efficient genomic DNA extraction protocol for molecular characterisation of Phytophthora colocasiae causing taro leaf blight

Genomic DNA extraction protocol with relatively high quantity and purity is prerequisite for the successful molecular identification and characterisation of plant pathogens. Conventional DNA extraction methods are often time-consuming and yield only very poor quantity of genomic DNA for samples with higher mycelial age. In our laboratory, we have aimed at establishing an efficient DNA isolation procedure, exclusively for the oomycete pathogen Phytophthora colocasiae causing serious leaf blight disease in taro. For this a phenol free protocol was adopted, which involves SDS/Proteinase K-based inactivation of protein contaminants, extraction of nucleic acids using chloroform: isoamyl alcohol and later precipitation of genomic DNA using isopropanol and sodium acetate. The purity of the isolated DNA was analysed by A_260/280 and A_260/230 spectrophotometric readings and confirmed by restriction digestion with restriction enzyme Eco RI. In this study, a comparative assessment was done with CTAB method and the commercial genomic DNA purification kit (Thermo Fisher Scientific, Fermentas, EU). The extracted DNA was found to be suitable for further downstream applications like ITS amplification of the rDNA ITS region and PCR amplification with species-specific primers.     

An effective DNA extraction protocol for brown algae

Successful extraction of total DNA from brown algae, which are generally polysaccharide and polyphenol rich, is often problematic using current methods. Persistent polysaccharide and polyphenolic compounds can hinder further application of modern molecular techniques requisite to molecular‐based evolutionary studies. Our broad and long‐term research goals with fucalean taxa, especially Sargassum, and problems with existing DNA extraction methods were an impetus to develop a reliable DNA extraction method. Initial research established hexadecyltrimethylammonium bromide (CTAB) based total‐DNA methods as the most viable for further empirical development. Several constituents effective at either complexing secondary compounds or creating a reductive extraction environment were increased in concentration or added to the extraction buffer. These seemingly minor changes resulted in the creation of a highly reductive extraction buffer and effective total‐ DNA harvesting technique. We detail these modifications and demonstrate the reliability of the modified protocol with a variety of brown algae and tissue preservation methods. Such DNA is shown to be suitable for a variety of molecular techniques.     

Nondestructive DNA extraction method for mitochondrial DNA analyses of museum specimens

Museum specimens have provided the material for a large proportion of ancient DNA studies conducted during the last 20 years. However, a major drawback of the genetic analyses is that the specimens investigated are usually damaged, as parts of skin, bone, or a tooth have to be removed for DNA extraction. To get around these limitations, we have developed a nondestructive extraction method for bone, tooth, and skin samples. We found that it is possible to amplify mitochondrial DNA (mtDNA) sequences up to at least 414 bp long from samples up to 164 years old. Using this method, almost 90% (35 of 40) of the investigated samples yielded amplifiable mtDNA. Moreover, we found that repeated extractions of the same samples allowed amplifications of the expected length for all samples at least three times and for some samples up to at least five times. Thus this method opens up the possibility to repeatedly use museum collections for mtDNA analyses without damaging the specimens and thus without reducing the value of irreplaceable collections for morphological analyses.     

堆肥中微生物总DNA的高效提取

采用化学裂解和酶解相结合的方法,选择加入PVPP的高盐缓冲液作为细胞裂解的反应体系,并以PEG-8000进行DNA沉淀,从高有机含量的堆肥样品中进行微生物总DNA的提取。结果表明,从4种性质不同的堆肥中均获得了高质量的微生物总DNA,所得的DNA分子片段在23kb左右;每克干重堆肥的总DNA提取量为63.54±12.08μg~106.50±28.36μg,A260/A280大于1.6,A260/A230大于1.8,不用经过纯化可以直接进行PCR扩增和限制性酶切;以该DNA为模板进行微生物区系的DGGE分析,显示了丰富的微生物多样性。该方法减少了通常环境样品DNA提取过程中的纯化步骤,减少了DNA的损失,为从事微生物分子生态学,尤其是那些针对高有机含量以及获取极为不易的环境样品的研究而言是十分有益的。     

A protocol for DNA fragment extraction from polyacrylamide gels

A simple and efficient method of purifying linear plasmid DNA from contaminating DNA fragments is described. Both vector and insert containing plasmids may be used without extensive purification, in particular without cesium chloride centrifugation. Careful deproteinization with phenol-chloroform allows efficient restriction enzyme digestion. Fragment separation can be performed immediately after restriction endonuclease digestion in a single 6% polyacrylamide gel. Extraction of DNA fragments from the gel is easy and gives a good yield. The DNA may be used for ligation and transformation without further purification.     

金丝小枣基因组DNA的优化提取方法

采用SDS和CTAB两种方法分离提取金丝小枣基因组DNA,并比较其提取效果。结果表明,改进后的CTAB法可获得高质量、高得率的基因组DNA,可用于金丝小枣的各种分子生物学研究。     

An efficient and non-destructive DNA extraction method for oribatid mites

Molecular methods play an important role in systematic acarology and DNA extraction is the first step in this ground. Nowadays, the varieties of methods are being used for extraction of DNA, but most of them destroy the important external characters that are essential for morphological identification. In order to overcome the problem of associating molecular and morphological information, we have developed a simple, efficient and non-destructive DNA extraction method for oribatid mites. The non-destructive method was tested on three different species [Oppia nitens C.L. Koch, 1836 (Oppiidae), Acrotritia ardua C.L. Koch, 1841 (Euphthiracaridae), and Amerus polonicus Kulczynski, 1902 (Ameridae)] and exoskeleton of specimens were preserved in Hoyer’s medium on glass microscopic slides for further identification via morphological studies. This method is more time consuming than commercial kits, but is easier and cheaper, meanwhile, allows systematic analysis with linking the morphological and genetic traits from a single mite. The most important advantage of TNES method is that after using this non-destructive method, specimens preserve all of their morphological features.     

A convenient protocol for extraction and purification of DNA from Fragaria

Summary In this paper we describe a simple and efficient DNA extraction protocol for Fragaria species, a highly recalcitrant genus due to the large amount of polyphenols and polymeric carbohydrates present in strawberry tissues. The protocol yields a high quality DNA that can be amplified by polymerase chain reaction and digested with restriction endonucleases.     

A simplified universal genomic DNA extraction protocol suitable for PCR

Conventional genomic DNA extraction protocols need expensive and hazardous reagents for decontamination of phenolic compounds from the extracts and are only suited for certain types of tissue. We developed a simple, time-saving and cost-efficient method for genomic DNA extraction from various types of organisms, using relatively innocuous reagents. The protocol employs a single purification step to remove contaminating compounds, using a silica column and a non-hazardous buffer, and a chaotropic-detergent lysing solution that hydrolyzes RNA and allows the selective precipitation of DNA from cell lysates. We used this system to extract genomic DNA from different tissues of various organisms, including algae (Dunaliella salina), human peripheral blood, mouse liver, Escherichia coli, and Chinese hamster ovary cells. Mean DNA yields were 20-30 μg/cm(3) from fresh tissues (comparable to yields given by commercial extraction kits), and the 260/280 nm absorbance ratio was 1.8-2.0, demonstrating a good degree of purity. The extracted DNA was successfully used in PCR, restriction enzyme digestion and for recombinant selection studies.     

DNA extraction protocol for rapid PCR detection of pathogenic bacteria

Twelve reagents were evaluated to develop a direct DNA extraction method suitable for PCR detection of foodborne bacterial pathogens. Many reagents exhibited strong PCR inhibition, requiring significant dilution of the extract with a corresponding reduction in sensitivity. Most reagents also exhibited much lower recovery of DNA from the gram-positive test organism (Listeria monocytogenes) than from the gram-negative organism (Escherichia coli O157:H7), preventing unbiased detection and quantitation of both organisms. The 5× HotSHOT + Tween reagent exhibited minimal inhibition and high extraction efficiency for both test organisms, providing a 15-min single-tube DNA-extraction protocol suitable for highly sensitive quantitative PCR assays.     

A protocol for high-throughput extraction of DNA from rice leaves

Current DNA isolation methods have limitations between speed and purity in high-throughput molecular genetic analysis such as gene mapping and marker-assisted selection programs. We have optimized a simple and rapid method for isolating high-quality genomic DNA from rice that significantly minimizes time and the use of laboratory materials. One person can process as many as 384 samples in 2 h. The isolated DNA is suitable for polymerase chain reaction-based techniques and is stable for no less than 6 mo of storage at 4°C.     

A high-throughput DNA extraction protocol for tropical molecular breeding programs

Liquid handling robotics and capillary electrophoresis genetic analyzers now offer high-throughput solutions for 2 of the 4 key steps in PCR-based DNA marker-assisted fingerprinting (DNA extraction, PCR amplification, electrophoresis, data analysis). Thus, DNA extraction remains the most significant bottleneck at the bench for large-scale applications in plant breeding and germplasm characterization. We report on a rapid and low-cost method for relatively high-throughput extraction of high-quality DNA from young and mature leaves of sorghum, pearl millet, chickpea, groundnut, and pigeonpea. The procedure uses a modified CTAB/β-mercaptoethanol method for DNA extraction in a 96-well plate. The quantity and quality of the DNA extracted per sample is adequate for more than 1000 PCR reactions. A relatively high throughput of 96–384 samples per person per day can be achieved, depending on the crop. A major timesaving aspect of the protocol is the absence of a manual sample-grinding step. Finally, the cost is a magnitude lower than commercial plate-based kits, and, as such, is likely to have substantial application in tropical molecular breeding programs.     

An electroporation protocol for efficient DNA transfection in PC12 cells

A wide variety of mammalian cell types is used in gene transfection studies. Establishing transfection methods that enable highly efficient DNA uptake has become increasingly important. PC12 is an established rat pheochromocytoma cell line, which responds to exposure to NGF with cessation of growth, expression of cytoplasmic processes, and differentiation into cells resembling sympathetic neurons. Although PC12 cells represent an important model system to study a variety of neuronal functions, they proved relatively difficult to transfect. We have compared the efficiency of three different chemical transfection reagents (Lipofectamine 2000, Lipofectamine LTX and TransIT-LT1) and of two electroporation systems (Neon and Gene Pulser Xcell) in transiently transfecting undifferentiated PC12 cells. By comparing efficiencies from replicate experiments we proved electroporation (in particular Neon) to be the method of choice. By optimizing different parameters (voltage, pulse width and number of pulses) we reached high efficiency of transfection (90 %) and viability (99 %). We also demonstrated that, upon electroporation, cells are not altered by the transfection and maintain their ability to differentiate.