DNA isolation protocol for the medicinal plant lemon balm (Melissa officinalis, Lamiaceae)

Lemon balm (Melissa officinalis) is a medicinal plant that is widely used as a sedative or calmant, spasmolytic and antibacterial agent and sleep aid. This has led to a high demand for lemon balm products, resulting in the extinction of this species in some of its natural habitats. Molecular techniques have increasingly been used in plant diversity conservation and isolation of PCR amplifiable genomic DNA is an important pre-requisite. Lemon balm contains high levels of polyphenols and polysaccharides, which pose a major challenge for the isolation of high-quality DNA. We compared different genomic DNA extraction protocols, including traditional phenol-chloroform DNA extraction protocols and two commercial kits for DNA purification for their ability to produce good-quality DNA from fresh leaves of five lemon balm genotypes. Quality and quantity of the DNA samples were determined using 0.8% agarose gel electrophoresis and a spectrophotometer. The DNA purity was further confirmed by PCR amplification using barley retrotransposon LTR base primers. The spectral quality of DNA as measured by the A(260)/A(280) ratio ranged from 1.46 to 2.37. The Fermentase genomic DNA purification kit and the CTAB extraction protocol using PVP and ammonium acetate to overcome the high levels of polyphenols and polysaccharides yielded high-quality DNA with a mean A(260)/A(280) ratio of 1.87. The quantity of DNA and its PCR purity were similar with all the protocols, but considering the time and cost required for extraction of DNA from a large number of samples, the CTAB protocol using PVP and ammonium acetate is suitable for lemon balm.     

A method for isolation and purification of peanut genomic DNA suitable for analytical applications

Numerous methods are available for isolation of plant genomic DNA, but in practice these procedures are empirical due to variability in plant tissue composition. Consistent isolation of quality DNA from peanut (Arachis hypogaea L.) is particularly problematic due to the presence of phenolic compounds and polysaccharides. Inconsistencies in extraction results can be attributed to the age and growth stage of the plant material analyzed. Mature leaves have higher quantities of polyphenols, tannins, and polysaccharides that can contaminate DNA during isolation. We show that four published protocols could not be used to isolate peanut DNA of sufficient quality for PCR amplification or Southern hybridization. We have devised a new protocol that uses DEAE-cellulose purification to isolate peanut DNA useful for downstream applications.     

An effective protocol to solve the problem in genomic DNA isolation of tung tree

Tung tree (Vernicia fordii) is a native and oil-producing woody plant in China. The oil is industrially important and promising biodiesel raw material. However, until recently the lack of effective protocols for the extraction of genomic DNA had made DNA-based molecular studies of tung tree difficult. Here, four conventional protocols and one novel protocol were compared for their capacity in isolating DNA from tung tree leaves of different age. Our results showed that all the four conventional protocols could isolate DNA from old leaves, two from matured leaves, but none from young leaves. However, the detectable DNA samples contained many contaminations, leading to overestimation of DNA concentration measured by ultraviolet spectrophotometer, also interfering with the downstream PCR reaction. The novel protocol could produce high-yield and good-quality DNA from tung tree leaves regardless of leaf age. Its key steps were that a single leaf tissue sample could be 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. All the four DNA samples of a single tissue were good template for PCR reaction. The novel protocol is an effective method for genomic DNA isolation of tung tree.     

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.     

A robust universal method for extraction of genomic DNA from bacterial species

The intactness of DNA is the keystone of genome-based clinical investigations, where rapid molecular detection of life-threatening bacteria is largely dependent on the isolation of high-quality DNA. Various protocols have been so far developed for genomic DNA isolation from bacteria, most of which have been claimed to be reproducible with relatively good yields of high-quality DNA. Nonetheless, they are not fully applicable to various types of bacteria, their processing cost is relatively high, and some toxic reagents are used. The routine protocols for DNA extraction appear to be sensitive to species diversity, and may fail to produce high-quality DNA from different species. Such protocols remain time-consuming and tedious, thus to resolve some of these impediments, we report development of a very simple, rapid, and high-throughput protocol for extracting of high-quality DNA from different bacterial species. Based upon our protocol, interfering phenolic compounds were removed from extraction using polyvinylpyrrolidone (PVP) and RNA contamination was precipitated using LiCl. The UV spectrophotometry and gel electrophoresis analysis resulted in high A ₂₆₀/A ₂₈₀ ratio (>1.8) with high intactness of DNA. Subsequent evaluations were performed using some quality-dependent techniques (e.g., RAPD marker and restriction digestions). The isolated DNA from 9 different bacterial species confirmed the accuracy of this protocol which requires no enzymatic processing and accordingly its low-cost making it an appropriate method for large-scale DNA isolation from various bacterial species.     

Mini-scale Genomic DNA Extraction from Cotton

Large amounts of polyphenolics in cotton leaves make it difficult to obtain high-quality genomic DNA during extraction. A procedure to isolate nuclear DNA from local cotton leaves (gossypium hirsutum, MNH93, CIM443, FH672) was therefore developed. It consists of rapid isolation of stable nuclei, which hinders covalent interactions with phenolics, followed by DNA extraction. The yield and quality of the resulting DNA is satisfactory and the protocol can be scaled up or down according to sample size. It is suitable for PCR and the restriction enzyme digestion needed for Southern and RFLP analysis.     

Rapid Isolation of DNA from Dry and Fresh Samples of Plants Producing Large Amounts of Secondary Metabolites and Essential Oils

The presence of certain metabolites has been observed to interfere with DNA isolation procedures and downstream reactions such as DNA restriction, amplification and cloning. The chemotypic heterogeneity among species may not permit optimal DNA yields with a single protocol, and thus, even closely related species may require different isolation protocols. Here we describe the essential steps of a rapid DNA isolation protocol that can be used for diverse medicinal and aromatic plants, which produce essential oils and secondary metabolites such as alkaloids, flavanoids, phenols, gummy polysaccharides, terpenes and quinones. The procedure is applicable to dry as well as fresh plant tissues. This protocol, in our experiments, permitted isolation of DNA from tissues of diverse plant species and produced fairly good yields. The isolated DNA proved amenable to PCR amplification and restriction digestion.     

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.     

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.     

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.     

鳞翅目成虫乙醇保存标本基因组DNA的提取及在微卫星研究中的应用

高质量的基因组DNA样品是分子生态学研究的先决条件。本研究目的在于探索从东方粘虫Pseudaletia separata (Walker)成虫自然种群的乙醇保存标本中分离高质量基因组DNA的有效方案。在2 mL微型离心管中进行4种提取方案的实验比较,结果发现采用传统的苯酚抽提方法的2种方案提取腹部中段组织的基因组DNA,样品合格率只有7.69%~40%。但是,如果在苯酚抽提以前加入高浓度盐和十六烷基三甲基溴化铵（CTAB）,就会使DNA样品合格率达到68.42%~95.28%,而且DNA平均产量达到5.59~10.04 mg/g,明显高于前者的2.83~5.78 mg/g （统计检验表明,在不同种群中差异显著或不显著）。研究结果还证明腹部组织比胸部组织更适宜提取DNA。对来自一个自然种群的99头东方粘虫DNA合格样品的统计分析表明,DNA提取总量（μg）与组织样品用量（mg）之间存在弱的正相关关系,平均DNA提取量（mg/g）与组织样品用量（mg）之间存在中度负相关关系。总之,在2 mL微型离心管中,用10~20 mg腹部组织,利用CTAB+苯酚抽提方法可以获得高纯度和高含量的基因组DNA样品。用该方案提取的基因组DNA能够顺利地进行微卫星位点的分离和基因分型。     

Cloning genomic sequences using long-range PCR

Protocols are presented for preparing DNA from a genomic library in λ phage and for synthesizing genomic fragments using PCR with nested vector- and gene-specific primers and linker-primers. Library DNA, isolated fromE. coli liquid lysates by a simple protocol, is used as template in PCR following a commercial protocol. The method produces library DNA sufficient for several hundred PCRs, incorporates nested primers to reduce nonspecific product formation, and enables the synthesis of linker-containing DNA fragments containing selected restriction sites to simplify subsequent cloning. The isolation of 5′ upstream sequences of three different arabidopsis genes by this methodod is described.     

Improved high-throughput sunflower and cotton genomic DNA extraction and PCR fidelity

The extraction of high-quality genomic DNA for PCR amplification from sunflower (Helianthus annuus) and cotton (Gossypium spp.) is challenging because of the presence of polysaccharides, secondary metabolites, and polyphenolics in the tissues. A high-throughput DNA extraction protocol was needed in our laboratory for simple sequence repeats (SSR)-marker screening and other molecular analyses that do not require organic extraction steps of phenol or chloroform. Here we describe 2 improved highthroughput protocols for DNA extraction and in-PCR modification that result in successful PCR amplification of sunflower and cotton. While the sunflower DNA extraction protocol uses reducing agents such as sodium metabisulfite and dithiothreitol (DTT), the cotton protocol uses polyvinylpyrrolidone (PVP) in PCR reactions and reducing agents in the DNA extraction procedure.     

Comparison of Metagenomic DNA Extraction Methods for Soil Sediments of High Elevation Puga Hot Spring in Ladakh,India to Explore Bacterial Diversity

Extraction of good-quality metagenomic DNA from extreme environments is quite challenging, particularly from high elevation hot spring sediments. Low microbial load, high humic acid content and other contaminants complicate the process of extraction of metagenomic DNA from hot spring sediments. In the present study, efficacy of five manual DNA extraction protocols with modifications has been evaluated for metagenomic DNA extraction from boron–sulfur rich high elevation Puga hot spring sediments. Best suited protocol was identified based on the cell lysis efficiency, DNA yield, humic acid content, PCR reproducibility and representation of bacterial diversity. Quantity as well as quality of crude metagenomic DNA differed remarkably between various protocols used and were not pure enough to give PCR amplification using 16S rRNA bacterial and archaeal primers. Crude metagenomic DNA extracted using five different DNA extraction protocols was purified using spin column based purification method. Even after purification, only three protocols C, D and E yielded metagenomic DNA that could be amplified using both archaeal and bacterial primers. To evaluate the degree of microbial diversity represented by protocols C, D and E, phylogenetic genes amplified were subjected to amplified ribosomal DNA restriction analysis (ARDRA) and denaturing gradient gel electrophoresis analysis (DGGE) analysis. ARDRA banding pattern of amplicons generated for all the three extraction protocols, i.e., C, D and E were found to be similar. DGGE of protocol E derived amplicons resulted in the similar number of dominant bands but a greater number of non-dominant bands, i.e., the highest microbial diversity in comparison to protocols C and D, respectively. In the present study, protocol E developed from Yeates et al. protocol has been found to be best in terms of DNA yield, DNA purity and bacterial diversity depiction associated with boron–sulfur rich sediment of high elevation hot springs.     

Assessment of various methods for extraction of metagenomic DNA from saline habitats of coastal Gujarat (India) to explore molecular diversity

Aims:  To develop total DNA extraction protocol from saline soil for further metagenomic applications.
Methods and Results:  The protocols combine the application of mechanical (Beads and Sonicator) and Soft Lysis (SDS and enzymes) method for the isolation of total DNA from saline soil of coastal Gujarat followed by its quantification and purity assessment. The quality and purity of metagenomic DNA was quite consistent and reliable, although it contained residual concentartions of humic acid. The extracted DNA was used to successfully amplify 16S rRNA region. The amplicons were suitable for further applications such as diversity-based analysis by denaturing gradient gel electrophoresis (DGGE).
Conclusions:  The methods appear to have wide applicability in investigating molecular diversity and exploring functional genes from the total DNA.
Significance and Impact of the Study:  The protocol is simple, short and facilitates rapid isolation of PCR amplifiable total genomic DNA from saline soil. The method yielded good quality of the DNA suitable for metagenomic studies. The results are also significant as only few extreme environments, particularly saline habitats, are explored for their metagenomic potential.     

Extraction of DNA from soil using nanoparticles by magnetic bioseparation

Aims: To develop a simple, rapid and inexpensive soil DNA extraction protocol. Methods and Results: The protocol relies on the use of superparamagnetic silica‐magnetite nanoparticles for the isolation and purification of DNA from soil samples. DNA suitable for use in molecular biology applications was obtained from a number of soil samples. Conclusions: The DNA extracted using the tested method successfully permitted the PCR amplification of a fragment of the bacterial 16S rDNA gene. The extracted DNA could also be restriction endonuclease digested. Significance and Impact of the Study: The protocol reported here is simple and permits rapid isolation of PCR‐ready soil DNA. The method requires only small quantities of soil sample, is scalable and suitable for automation.     

DNA isolation from dry and fresh samples of polysaccharide-rich plants

DNA extraction is difficult in a variety of plants because of the presence of metabolites that interfere with DNA isolation procedures and downstream applications such as DNA restriction, amplification, and cloning. The chemotypic heterogeneity among species may not permit optimal DNA yield with a single protocol; thus, even closely related species may require different isolating protocols. Here we describe a modified procedure based on the hexadecyltrimethylammonium bromide (CTAB) method to isolate DNA from tissues containing high levels of polysaccharides. The procedure is applicable to both dry and fresh tissues and was tested on chickpea seeds, soybean, and wheat leaves. This method solved the problems of DNA degradation, contamination, and low yield due to binding and/or coprecipitation with starches and polysaccharides. The isolated DNA proved amenable to PCR amplification and restriction digestion.     

Evaluating genomic DNA extraction methods from human whole blood using endpoint and real-time PCR assays

The extraction of genomic DNA is the crucial first step in large-scale epidemiological studies. Though there are many popular DNA isolation methods from human whole blood, only a few reports have compared their efficiencies using both end-point and real-time PCR assays. Genomic DNA was extracted from coronary artery disease patients using solution-based conventional protocols such as the phenol–chloroform/proteinase-K method and a non-phenolic non-enzymatic Rapid-Method, which were evaluated and compared vis-a-vis a commercially available silica column-based Blood DNA isolation kit. The appropriate method for efficiently extracting relatively pure DNA was assessed based on the total DNA yield, concentration, purity ratios (A₂₆₀/A₂₈₀ and A₂₆₀/A₂₃₀), spectral profile and agarose gel electrophoresis analysis. The quality of the isolated DNA was further analysed for PCR inhibition using a murine specific ATP1A3 qPCR assay and mtDNA/Y-chromosome ratio determination assay. The suitability of the extracted DNA for downstream applications such as end-point SNP genotyping, was tested using PCR-RFLP analysis of the AGTR1-1166A>C variant, a mirSNP having pharmacogenetic relevance in cardiovascular diseases. Compared to the traditional phenol–chloroform/proteinase-K method, our results indicated the Rapid-Method to be a more suitable protocol for genomic DNA extraction from human whole blood in terms of DNA quantity, quality, safety, processing time and cost. The Rapid-Method, which is based on a simple salting-out procedure, is not only safe and cost-effective, but also has the added advantage of being scaled up to process variable sample volumes, thus enabling it to be applied in large-scale epidemiological studies.     

A simplified protocol for preparing DNA from filamentous cyanobacteria

The preparation of good quality genomic DNA from microalgae and plants is often time-consuming because of the need to remove contaminants that may interfere with the downstream enzymatic manipulation of the DNA. Simpler protocols have been reported but these are applicable only to a few species and in many cases are not effective for removing trace contaminants. In this report, we describe a modification of existing protocols that significantly simplified the preparation of genomic DNA from cyanobacteria and plants. A key step in our protocol is the precipitation of DNA in a high concentration of salt (2–2.5 M NaCl) in the presence of isopropanol, immediately following phenol and chloroform extractions. The preparation and enzymatic digestion of the DNA can be performed in a single day. The DNA was easily digested in 2 h at normal restriction enzyme concentrations, and is highly suitable for PCR and Southern hybridization. We successfully used this simplified protocol to prepare genomic DNA from several filamentous cyanobacteria, such asAnabaena sp. PCC 7120,Anabaena siamensis, andSpirulina strains M2 and Kenya. This protocol may also be useful for preparing genomic DNA from other algae and from higher plants.