Microwave-assisted digestion combined with silica-based spin column for DNA isolation from human bones

A protocol for the extraction of DNA from ancient skeletal material was developed. Bone specimen samples (powder or slice), buffer, pretreatment, and extraction methodologies were compared to investigate the best conditions yielding the highest concentration of DNA. The degree of extract contamination by polymerase chain reaction (PCR) inhibitors was compared as well. Pretreatment was carried out using agitation in an incubator shaker and microwave digestion. Subsequently, DNA from bones was isolated by the classical organic phenol–chloroform extraction and silica-based spin columns. Decalcification buffer for total demineralization was required as well as lysis buffer for cell lysis to obtain DNA, whereas microwave-assisted digestion proved to be very rapid, with an incubation time of 2 min instead of 24 h at an incubator shaker without using lysis buffer. The correction of isolated DNA was detected using real-time PCR with melt curve analysis, which was 82.8 ± 0.2 °C for highly repetitive α-satellite gene region specific for human chromosome 17 (locus D17Z1). Consequently, microwave-based DNA digestion followed by silica column yielded a high-purity DNA with a concentration of 19.40 ng/μl and proved to be a superior alternative to the phenol–chloroform method, presenting an environmentally friendly and efficient technique for DNA extraction.     

Analysis of global DNA methylation by hydrophilic interaction ultra high-pressure liquid chromatography tandem mass spectrometry

We developed and validated a rapid, sensitive, and specific liquid chromatography tandem mass spectrometry (LC–MS/MS) method for determination of global DNA methylation in tissue. DNA was extracted by phenol–chloroform, hydrolyzed using 88% formic acid at 140 °C, spiked with cytosine-2,4-¹³C¹⁵N₂ as internal standard, evaporated under nitrogen, reconstituted in methanol, and analyzed by LC–MS/MS in multiple reaction monitoring mode to reflect the global DNA methylation of the tissue. The method was linear throughout the range of clinical interest and had good sensitivity, with a limit of quantification of 0.5 pg for both cytosine (Cyt) and 5-methylcytosine (5mCyt). The linear range of calibration curve was 1–50 and 1–100 ng/ml for 5mCyt and Cyt, respectively, with a correlation coefficient higher than 0.99. The relative standard deviation (RSD) was 0.70–4.09% and 0.60–4.81% for Cyt and 5mCyt, respectively. The intraday precision expressed as RSD ranged from 1.86% to 4.67%, whereas the interday values ranged from 3.72% to 4.68%. The recovery of the method varied from 86.52% to 105.14%. This yielded a simple and reliable LC–MS/MS assay for detection of Cyt and 5mCyt, thereby enabling the evaluation of global DNA methylation.     

Cost-effective and rapid (3 h) method for combined extraction of DNA,RNA and protein from a single tea leaf sample for genomic and proteomic analysis

This is the first report about the simultaneous extraction of nucleic acids and proteins from tea leaf tissue. Using the present protocol, the DNA, RNA and protein were simultaneously isolated from a single tea leaf sample. The method also maintained the quality and quantity of the isolated biomolecules. The method is cost-effective and takes only 3 h to isolate the starting molecules (DNA, RNA and protein) of central dogma of biology. It was also demonstrated that the isolated DNA, RNA and protein could be successfully used for genomics and proteomic analysis in tea plant which was verified by performing marker study, gene cloning, cDNA preparation, gene expression study and 2-DE.     

DNA extraction procedures meaningfully influence qPCR-based mtDNA copy number determination

Quantitative real time PCR (qPCR) is commonly used to determine cell mitochondrial DNA (mtDNA) copy number. This technique involves obtaining the ratio of an unknown variable (number of copies of an mtDNA gene) to a known parameter (number of copies of a nuclear DNA gene) within a genomic DNA sample. We considered the possibility that mtDNA:nuclear DNA (nDNA) ratio determinations could vary depending on the method of genomic DNA extraction used, and that these differences could substantively impact mtDNA copy number determination via qPCR. To test this we measured mtDNA:nDNA ratios in genomic DNA samples prepared using organic solvent (phenol–chloroform–isoamyl alcohol) extraction and two different silica-based column methods, and found mtDNA:nDNA ratio estimates were not uniform. We further evaluated whether different genomic DNA preparation methods could influence outcomes of experiments that use mtDNA:nDNA ratios as endpoints, and found the method of genomic DNA extraction can indeed alter experimental outcomes. We conclude genomic DNA sample preparation can meaningfully influence mtDNA copy number determination by qPCR.     

Isolation and characterization of ribosomal ribonucleic acid

1. Ribosomal RNA has been prepared by extracting tissues with a phenol–cresol mixture, and ribosomal RNA can be selectively precipitated with m-cresol. No rapidly labelled RNA was associated with this material. 2. However, if RNA and DNA are extracted with 4-aminosalicylate and phenol–cresol mixture and the nucleic acids precipitated, DNA, glycogen and s-RNA (transfer RNA) can be extracted with 3m-sodium acetate and in this case rapidly labelled RNA remains associated with the ribosomal RNA. 3. The ribosomal RNA is stable in the presence of concentrated salt solution and, although the secondary structure is lost by heating at 70° in 10mm-sodium acetate, it can be re-formed in the presence of 200mm-sodium acetate. 4. The 28s and 18s components have been separated and their base compositions determined.     

Maxiprep genomic DNA extractions for molecular epidemiology studies and biorepositories

Molecular epidemiology and genomic characterisation studies require the screening of large numbers of individuals to achieve statistical significance. Although many of the novel DNA extraction methods offer convenient, high-throughput capabilities, their use for the processing of larger sample volumes becomes very expensive. We are currently compiling the Mexican Genomic DNA Collection in order to address specific health priorities through molecular techniques. Our approach employs a low-cost laundry detergent based DNA extraction technique that maximizes DNA yield and quality. We have optimised four different modalities (maxiprep, midiprep, miniprep and microprep) for two different sources (leukocyte concentrates and whole blood). Our optimised protocol produces 4.5 mg of DNA from 15 ml of blood-bank discarded leukocyte concentrates with spectrophotometric quality, genomic integrity and PCR suitability that rivals that of phenol–chloroform extracted samples. We present evidence of many PCR applications that we have carried out on samples extracted with this technique including Killer-cell Immunoglobulin-like Receptor genotyping, Short Tandem Repeat profiling as well as nucleic acid screening for hepatitis B and human immunodeficiency type-1 viruses. This paper highlights many of the advantages that this DNA extraction technique provides over existing methodologies, whether it is used to establish large genomic DNA collections (as was our main intention) or as a routine DNA extraction method for PCR applications.     

Ribonucleic acid from coffee beans

A method of extraction of RNA from coffee based on phenol treatment is described. Effectsf of various agents and pH of the extracting buffer on the efficiency of extraction were studied. The best extracting solution is 0·2 M Tris-HCl buffer at pH 7·4 with 1% sodium dodecyl sulphate and 0·05% EDTA. RNA (5–6%) is lost in the tissue residue and 4·6% in the interphase layer. No significant deviation of the spectral characteristics of the RNA solutions obtained from three samples of coffee from that for purified yeast RNA is observed. The purine-pyrimidine ratio for the RNA has been found to be in the range of 1·25–1·38.     

A robust,cost‐effective method for DNA,RNA and protein co‐extraction from soil,other complex microbiomes and pure cultures

The soil microbiome is inherently complex with high biological diversity, and spatial heterogeneity typically occurring on the submillimetre scale. To study the microbial ecology of soils, and other microbiomes, biomolecules, that is, nucleic acids and proteins, must be efficiently and reliably co‐recovered from the same biological samples. Commercial kits are currently available for the co‐extraction of DNA, RNA and proteins but none has been developed for soil samples. We present a new protocol drawing on existing phenol–chloroform‐based methods for nucleic acids co‐extraction but incorporating targeted precipitation of proteins from the phenol phase. The protocol is cost‐effective and robust, and easily implemented using reagents commonly available in laboratories. The method is estimated to be eight times cheaper than using disparate commercial kits for the isolation of DNA and/or RNA, and proteins, from soil. The method is effective, providing good quality biomolecules from a diverse range of soil types, with clay contents varying from 9.5% to 35.1%, which we successfully used for downstream, high‐throughput gene sequencing and metaproteomics. Additionally, we demonstrate that the protocol can also be easily implemented for biomolecule co‐extraction from other complex microbiome samples, including cattle slurry and microbial communities recovered from anaerobic bioreactors, as well as from Gram‐positive and Gram‐negative pure cultures.     

Fast chromatin immunoprecipitation assay

Chromatin immunoprecipitation (ChIP) is a widely used method to explore in vivo interactions between proteins and DNA. The ChIP assay takes several days to complete, involves several tube transfers and uses either phenol–chlorophorm or spin columns to purify DNA. The traditional ChIP method becomes a challenge when handling multiple samples. We have developed an efficient and rapid Chelex resin-based ChIP procedure that dramatically reduces time of the assay and uses only a single tube to isolate PCR-ready DNA. This method greatly facilitates the probing of chromatin changes over many time points with several antibodies in one experiment.     

Efficient removal of detergents from proteins and peptides in a spin column format

Detergents are commonly used in protein–chemistry protocols and may be necessary for protein extraction, solubilization, and denaturation; however, their presence interferes with many downstream analysis techniques, including mass spectrometry (MS). To enable downstream analysis, it is critical to remove unbound detergents from protein and peptide samples. In this study, we describe a high-performance resin that offers exceptional detergent removal for proteins and peptides. When used in a spin column format, this resin dramatically improves protein and peptide MS results by more than 95% removal of 1–5% detergents, including sodium dodecyl sulfate (SDS), sodium deoxycholate, Chaps, Triton X-100, Triton X-114, NP-40, Brij-35, octyl glucoside, octyl thioglucoside, and lauryl maltoside, with high recovery of proteins and peptides. Postcolumn liquid chromatography–tandem MS (LC–MS/MS) analysis of trypsin digests of bovine serum albumin (BSA) and HeLa cell lysate revealed excellent sequence coverage, indicating successful removal of detergent from the peptides. Matrix-assisted laser desorption/ionization (MALDI)–MS analysis of unprocessed and processed samples further confirmed efficient removal of detergents. The advantages of this method include speed (<15 min), efficient detergent removal, and high recovery of proteins and peptides.     

Optimized lymphocyte protein extraction performed simultaneously with DNA and RNA isolation: application to the study of factors affecting DNA, RNA, and protein recovery from lymphocytes of the oldest individuals.

We describe an optimized procedure for protein extraction performed simultaneously with that of DNA and RNA from a single tissue sample that is, unlike the original protocol, suitable for quantitative studies. This optimized protocol is particularly well adapted to studies where gene regulation at DNA, RNA, and protein levels must be examined simultaneously, and when the amount of starting biological material is limited. We applied this procedure to the study of factors affecting both qualitatively and quantitatively the extraction of DNA, RNA, and proteins from lymphocytes of very old individuals, since we observed variability in the recovery of these molecular species with advanced age. Therefore, we investigated the combined effects of age and time delay between blood collection and lymphocyte isolation on the recovery of DNA, RNA, and proteins simultaneously extracted from Danish nonagenarians and centenarians versus younger adult samples. Our results suggest that neither RNA nor DNA nor protein contents of lymphocytes are altered with aging. However, the quantity of RNA and protein recovery is affected by a 24-h delay in blood processing. This effect is more pronounced in the oldest, particularly for RNA, and may affect data interpretation of age-dependent gene expression studies.     

Evaluation and optimization of nucleic acid extraction methods for the molecular analysis of bacterial communities associated with corroded carbon steel

Different DNA and RNA extraction approaches were evaluated and protocols optimized on in situ corrosion products from carbon steel in marine environments. Protocols adapted from the PowerSoil DNA/RNA Isolation methods resulted in the best nucleic acid (NA) extraction performances (ie combining high NA yield, quality, purity, representativeness of microbial community and processing time efficiency). The PowerSoil RNA Isolation Kit was the only method which resulted in amplifiable RNA of good quality (ie intact 16S/23S rRNA). Sample homogenization and hot chemical (SDS) cell lysis combined with mechanical (bead-beating) lysis in presence of a DNA competitor (skim milk) contributed to improving substantially (around 23 times) the DNA yield of the PowerSoil DNA Isolation Kit. Apart from presenting NA extraction strategies for optimizing extraction parameters with corrosion samples from carbon steel, this study proposes DNA and RNA extraction procedures suited for comparative molecular analysis of total and active fractions of bacterial communities associated with carbon steel corrosion events, thereby contributing to improved MIC diagnosis and control.     

Evaluation of commercial kits for extraction of DNA and RNA from Clostridium difficile

Commercial nucleic acid extraction kits are a cost effective, efficient and convenient way to isolate DNA and RNA from bacteria. Despite the increasing importance of the gastrointestinal pathogen, Clostridium difficile, and the increased use of nucleic acids in its identification, characterization, and investigation of virulence factors, no standardized or recommended methods for nucleic acid isolation exist. Here, we sought to evaluate 4 commercial DNA extraction kits and 3 commercial RNA extraction kits assessing cost, labor intensity, purity, quantity and quality of nucleic acid preparations. The DNA extraction kits produced a range of concentrations (20.9–546 ng/ml) and A_260/280 ratios (1.92–2.11). All kits were suitable for DNA extraction with the exception of the Roche MagNA pure LC DNA isolation kit III which produced DNA of high yield but with substantial shearing, but that did not affect downstream PCR amplifications. For RNA extraction, the Qiagen RNeasy mini kit stood out producing preparations of consistently higher concentrations and higher RNA integrity numbers (RIN). The Roche MagNA pure LC RNA isolation kit produced preparations that could not be properly assigned RINs due to a failure to remove small RNAs which were interpreted as degradation. Good DNA and RNA yield are critical but methods are often overlooked. This study highlights the potential for critical variation between established commercial systems and the need for assessment of any extraction methods that are used.