Technical note: improved ancient DNA purification for PCR using ion-exchange columns

A novel method of ancient DNA (aDNA) purification was developed using ion-exchange columns to improve PCR-amplifiable DNA extraction from ancient bone samples. Thirteen PCR-resistant ancient bone samples aged 500-3,300 years were tested to extract aDNA using a recently reported, silica-based aDNA extraction method and an ion-exchange column method for the further purification. The PCR success rates of the aDNA extracts were evaluated for the amplification ability of the fragments of mitochondrial DNA, a high-copy DNA, and amelogenin, a low-copy DNA. The results demonstrate that the further purification of silica-based aDNA extracts using ion-exchange columns considerably improved PCR amplification. We suggest that the ion-exchange column-based method will be useful for the improvement of PCR-amplifiable aDNA extraction, particularly from the poorly preserved, PCR-resistant, ancient samples.     

古DNA提取技术对比及概述

从古代原始材料中提取古DNA的方法多种多样,但是古DNA的研究受限于降解严重,内源性古DNA含量低,微生物和现生人群DNA污染严重等因素的影响。能否从古代人类遗骸中成功获取可靠且足量的内源性古DNA,一直是古DNA研究领域面临的实际困难和挑战。控制污染最直接且简便的策略就是在古DNA提取阶段的有效排除,本文整理了古DNA提取常用的去除污染的方法,对比分析了每种方法表现出来的优缺点。介绍了通常使用的骨粉裂解时间,并研究了在常温环境下,不同的裂解时间对古DNA回收效率的影响,提出了常温裂解过程中最佳孵育时间。同时对常用的古DNA纯化方法及其原理和在实际应用中的表现进行了概述与讨论。本文对古DNA提取技术的概述和实践经验,为古DNA相关领域的研究提供借鉴与参考。     

Technical note: PCR analysis of minimum target amount of ancient DNA

The study of ancient DNA plays an important role in archaeological and palaeontological research as well as in pathology and forensics. Here, we present a new tool for ancient DNA analysis, which overcomes contamination problems, DNA degradation, and the negative effects of PCR inhibitors while reducing the amount of starting target material in the picogram range. Ancient bone samples from four Egyptian mummies were examined by combining laser microdissection, conventional DNA extraction, and low‐volume PCR. Initially, several bone particles (osteons) in the micrometer range were extracted by laser microdissection. Subsequently, ancient DNA amplification was performed to verify our extraction method. Amelogenin and β‐actin gene specific fragments were amplified via low‐volume PCR in a total reaction volume of 1 μl. Results of microdissected mummy DNA samples were compared to mummy DNA, which was extracted using a standard DNA extraction method based on pulverization of bone material. Our results highlight the combination of laser microdissection and low‐volume PCR as a promising new technique in ancient DNA analysis. Am J Phys Anthropol, 2010. © 2010 Wiley‐Liss, Inc.     

Comparing the performance of three ancient DNA extraction methods for high‐throughput sequencing

The DNA molecules that can be extracted from archaeological and palaeontological remains are often degraded and massively contaminated with environmental microbial material. This reduces the efficacy of shotgun approaches for sequencing ancient genomes, despite the decreasing sequencing costs of high‐throughput sequencing (HTS). Improving the recovery of endogenous molecules from the DNA extraction and purification steps could, thus, help advance the characterization of ancient genomes. Here, we apply the three most commonly used DNA extraction methods to five ancient bone samples spanning a ~30 thousand year temporal range and originating from a diversity of environments, from South America to Alaska. We show that methods based on the purification of DNA fragments using silica columns are more advantageous than in solution methods and increase not only the total amount of DNA molecules retrieved but also the relative importance of endogenous DNA fragments and their molecular diversity. Therefore, these methods provide a cost‐effective solution for downstream applications, including DNA sequencing on HTS platforms.     

Nucleic acid and protein elimination during the sugar manufacturing process of conventional and transgenic sugar beets

The fate of cellular DNA during the standard purification steps of the sugar manufacturing process from conventional and transgenic sugar beets was determined. Indigenous nucleases of sugar beet cells were found to be active during the first extraction step (raw juice production) which was carried out at 70°C. This and the consecutive steps of the manufacturing process were validated in terms of DNA degradation by competitive PCR of added external DNA. Each step of the process proved to be very efficient in the removal of nucleic acids. Taken together, the purification steps have the potential to reduce the amount of DNA by a factor of >10¹⁴, exceeding by far the total amount of DNA present in sugar beets. Furthermore, the gene products of the transgenes neomycin phosphotransferase and BNYVV (rhizomania virus) coat protein CP21 were shown to be removed during the purification steps, so that they could not be detected in the resulting white sugar. Thus, sugar obtained from conventional and transgenic beets is indistinguishable or substantially equivalent with respect to purity.     

Proboscidean DNA from Museum and Fossil Specimens: An Assessment of Ancient DNA Extraction and Amplification Techniques

Applications of reliable DNA extraction and amplification techniques to postmortem samples are critical to ancient DNA research. Commonly used methods for isolating DNA from ancient material were tested and compared using both soft tissue and bones from fossil and contemporary museum proboscideans. DNAs isolated using three principal methods served as templates in subsequent PCR amplifications, and the PCR products were directly sequenced. Authentication of the ancient origin of obtained nucleotide sequences was established by demonstrating reproducibility under a blind testing system and by phylogenetic analysis. Our results indicate that ancient samples may respond differently to extraction buffers or purification procedures, and no single method was universally successful. A CTAB buffer method, modified from plant DNA extraction protocols, was found to have the highest success rate. Nested PCR was shown to be a reliable approach to amplify ancient DNA templates that failed in primary amplification.     

A simple and efficient method for PCR amplifiable DNA extraction from ancient bones

A simple and effective modified ethanol precipitation-based protocol is described for the preparation of DNA from ancient human bones. This method is fast and requires neither hazardous chemicals nor special devices. After the powdering and incubating of the bone samples Dextran Blue was added as a carrier for removing the PCR inhibitors with selective ethanol precipitation. This method could eliminate the time-consuming separate decalcification step, dialysis, application of centrifugation-driven microconcentrators and the second consecutive PCR amplification. The efficiency of this procedure was demonstrated on ten 500–1200-year-old human bones from four different Hungarian burial sites. A mitochondrial specific primer pair was used to obtain sequence information from the purified ancient DNA. The PCR amplification, after our DNA extraction protocol, was successful from each of the 10 bone samples investigated. The results demonstrate that extraction of DNA from ancient bone samples with this new approach increases the success rate of PCR amplification.     

Comparison and optimization of ancient DNA extraction

Ancient DNA analyses rely on the extraction of the tiny amounts of DNA remaining in samples that are hundreds to tens of thousands of years old. Despite the critical role extraction efficiency plays in this field of research, no study has comprehensively compared ancient DNA extraction techniques to date. There are a wide range of methods currently in use, which rely on such disparate principles as spin columns, alcohol precipitation, or binding to silica. We have compared a number of these methods using quantitative PCR and then optimized each step of the most promising method. We found that most chemicals routinely added to ancient DNA extraction buffers do not increase, and sometimes even decrease, DNA yields. Consequently, our optimized method uses a buffer consisting solely of EDTA and proteinase K for bone digestion and binding DNA to silica via guanidinium thiocyanate for DNA purification. In a comparison with published methods, this minimalist approach, on average, outperforms all other methods in terms of DNA yields as measured using quantitative PCR. We also found that the addition of bovine serum albumin (BSA) to the PCR helps to overcome inhibitors in ancient DNA extracts. Finally, we observed a marked difference in the performance between different types of DNA polymerases, as measured by amplification success.     

A simple method of DNA extraction from soil for detection of composite transgenic plants by PCR

This new and simple method of DNA extraction from composite soil allows the isolation of plant DNA with high efficiency, quality and reproductivity. The method is based on a simple CaCl₂-precipitation step and requires no additional purification steps to eliminate humic acids. The extracted DNA was obtained in sufficient purity and quantity to allow direct detection of transgenes by PCR. Furthermore, the simple procedure allows the assay of many samples at the same time.     

Comparison of three methods for DNA extraction from bone remains

Extraction of amplifiable DNA is a frequent problem when working with degraded specimens like bone samples. The possibility of obtaining as much information as possible from these samples has a particular significance in many forensic investigations. The present investigation was aimed to assess the efficiency of three organic extraction methods for purifying amplifiable DNA from bone samples. The amount of nucleic acids obtained, the success rate in the amplification of DNA microsatellite (STR) markers and amelogenin by PCR, the influence of PCR inhibitors and environmental conditions, and where the samples were found before their processing in the laboratory, were all evaluated in this investigation for the three methods. Results showed that method A (a modification of FBI method for DNA extraction) performed better in producing not a higher amount but a better quality amplifiable DNA, in comparison with the other two methods evaluated. It was also demonstrated that the quality of the DNA to be amplified by PCR was influenced by the presence of inhibitors and/or contaminants and the environmental conditions where the bone sample was taken from. The worst conditions were observed from aquatic environments. The results suggest that the implementation of some specific modifications in the method A (use of purification columns, reliable quantification methods and different dilutions) would help to obtain better DNA extracts intended to be used in different molecular identification tests.     

新石器时代人骨遗骸中古代DNA的提取及X—Y染色体同源基因片段的PCR扩增

从中国新石器时代人骨遗骸中提取出古代ＤＮＡ。通过聚合酶链式反应技术扩增得到Ｘ－Ｙ染色体上的单考贝同源基因片段。由于扩增的基因片段长度具有性别多态性,从而为古代人骨和牙齿提供了分子生物学的性别鉴定。     

一种实用可靠的古代 DNA 获取方法

古代DNA序列信息能够为物种演化研究提供最直接的分子证据,但获取古代DNA的技术仍存在诸多瓶颈,尤其是扩增中存在受损伤DNA模板的干扰、获取成本高和实验周期长等问题．改进了异丙醇沉淀提取法,并采用了尿嘧啶糖苷酶(UNG)去除受损伤DNA模板后进行扩增的方法,最终可以高效地获取真实的古代DNA序列．实验利用距今4 300～3 900年前的猪牙样本,将改进的古 DNA 获取方法与常规方法进行比较研究,结果表明,改进的异丙醇沉淀法提取结合UNG处理后进行PCR扩增的方法,可以在保证古代DNA获取成功率并提高获得的DNA序列可靠性的前提下,将经费投入和实验周期都各减少至常规方法的50%以下．这可以为开展大规模古代样本检测提供一种切实可行的 DNA 获取方法．     

两种外周血 DNA 提取方法的比较

目的:外周血DNA的提取是研究乙型肝炎病毒相关临床疾病的基础,所提取DNA的质与量直接关乎下游研究的成败,经济、高效、便捷的外周血DNA提取方法对于疾病分子水平的研究尤为重要,本实验旨在比较两种外周血DNA提取方法,从而为临床研究提供有力的参考。方法:以外周抗凝血为试验样本,分别采用改良盐析法和DNA提取试剂盒法(硅胶柱纯化)进行基因组DNA的提取,通过分光光度仪测量DNA浓度和纯度,并进行PCR扩增及电泳实验。比较改良盐析法与试剂盒提取法(硅胶柱纯化)的效果。结果:试剂盒提取法(硅胶柱纯化)标本用量甚微,省时,提取DNA纯度高,步骤繁琐,PCR条带单一、亮度差;改良盐析法操作步骤少,提取DNA浓度高,PCR条带亮度佳、杂带多,耗时长。结论:两组方法各有优缺点,试剂盒提取法(硅胶柱纯化)可靠、快速,但所获DNA量少、极易降解,改良盐析法耗时,但所获DNA浓度高、量多,可根据实验时间与经费,实验所需的DNA纯度与浓度,提供的样本体积等不同的临床研究需求及条件来综合选择适宜的提取方法。     

Differential Nuclear and Mitochondrial DNA Preservation in Post-Mortem Teeth with Implications for Forensic and Ancient DNA Studies

Major advances in genetic analysis of skeletal remains have been made over the last decade, primarily due to improvements in post-DNA-extraction techniques. Despite this, a key challenge for DNA analysis of skeletal remains is the limited yield of DNA recovered from these poorly preserved samples. Enhanced DNA recovery by improved sampling and extraction techniques would allow further advancements. However, little is known about the post-mortem kinetics of DNA degradation and whether the rate of degradation varies between nuclear and mitochondrial DNA or across different skeletal tissues. This knowledge, along with information regarding ante-mortem DNA distribution within skeletal elements, would inform sampling protocols facilitating development of improved extraction processes. Here we present a combined genetic and histological examination of DNA content and rates of DNA degradation in the different tooth tissues of 150 human molars over short-medium post-mortem intervals. DNA was extracted from coronal dentine, root dentine, cementum and pulp of 114 teeth via a silica column method and the remaining 36 teeth were examined histologically. Real time quantification assays based on two nuclear DNA fragments (67 bp and 156 bp) and one mitochondrial DNA fragment (77 bp) showed nuclear and mitochondrial DNA degraded exponentially, but at different rates, depending on post-mortem interval and soil temperature. In contrast to previous studies, we identified differential survival of nuclear and mtDNA in different tooth tissues. Futhermore histological examination showed pulp and dentine were rapidly affected by loss of structural integrity, and pulp was completely destroyed in a relatively short time period. Conversely, cementum showed little structural change over the same time period. Finally, we confirm that targeted sampling of cementum from teeth buried for up to 16 months can provide a reliable source of nuclear DNA for STR-based genotyping using standard extraction methods, without the need for specialised equipment or large-volume demineralisation steps.     

Direct extraction of DNA from soils for studies in microbial ecology

Molecular analyses for the study of soil microbial communities often depend on the extraction of DNA directly from soils. These extractions are by no means trivial, being complicated by humic substances that are inhibitory to PCR and restriction enzymes or being too highly colored for blot hybridization protocols. Many different published protocols exist, but none have been found to be suitable enough to be generally accepted as a standard. Most direct extraction protocols start with relatively harsh cell breakage steps such as bead-beating and freeze-thaw cycles, followed by the addition of detergents and high salt buffers and/or enzymic digestion with lysozyme and proteases. After typical organic extraction and alcohol precipitation, further purification is usually needed to remove inhibitory substances from the extract. The purification steps include size-exclusion chromatography, ion-exchange chromatography, silica gel spin columns, and cesium chloride gradients, among others. A direct DNA extraction protocol is described that has been shown to be effective in a wide variety of soil types. This protocol is experimentally compared to several published protocols.     

Optimization of microbial DNA extraction and purification from raw wastewater samples for downstream pathogen detection by microarrays

Numerous waterborne pathogens are difficult to detect and enumerate with accuracy due to methodological limitations and high costs of direct culturing. The purity of DNA extracted from wastewater samples is an important issue in the sensitivity and the usefulness of molecular methods such as polymerase chain reaction (PCR) and hybridizations on DNA microarrays. Ten different DNA extraction procedures, including physical and chemical extraction and purification steps, were examined to ascertain their relative effectiveness for extracting bacterial DNA from wastewater samples. The quality of the differentially extracted DNAs was subsequently assessed by PCR amplification and microarray hybridization. Our results showed that great differences existed among the ten procedures and only a few of the methods gave satisfactory results when applied to bacterial pathogens. This observation suggested that the extraction method needed to be carefully selected to produce significant and confident results in the detection of pathogens from environmental samples.     

New insights from old bones: DNA preservation and degradation in permafrost preserved mammoth remains

Despite being plagued by heavily degraded DNA in palaeontological remains, most studies addressing the state of DNA degradation have been limited to types of damage which do not pose a hindrance to Taq polymerase during PCR. Application of serial qPCR to the two fractions obtained during extraction (demineralization and protein digest) from six permafrost mammoth bones and one partially degraded modern elephant bone has enabled further insight into the changes which endogenous DNA is subjected to during diagenesis. We show here that both fractions exhibit individual qualities in terms of the prevailing type of DNA (i.e. mitochondrial versus nuclear DNA) as well as the extent of damage, and in addition observed a highly variable ratio of mitochondrial to nuclear DNA among the six mammoth samples. While there is evidence suggesting that mitochondrial DNA is better preserved than nuclear DNA in ancient permafrost samples, we find the initial DNA concentration in the bone tissue to be as relevant for the total accessible mitochondrial DNA as the extent of DNA degradation post-mortem. We also evaluate the general applicability of indirect measures of preservation such as amino-acid racemization, bone crystallinity index and thermal age to these exceptionally well-preserved samples.     

A quantitative analysis of DNA extraction and purification from compost

We quantified both DNA and humic acid concentrations during the extraction and purification of DNA from compost. The DNA extraction method consisted of bead-beating with SDS for cell lysis, poly(ethylene glycol)-8000 precipitation for preliminary DNA purification, and chromatography on a 10-ml Sephadex G-200 column for final DNA purification. Direct microscopic observation of pre- and post-lysis samples revealed that 95.3+/-2.3% of native cells was lysed. Sixty-three percent of the original DNA was lost during purification, resulting in a final DNA yield of 18.2+/-3.8 microg DNA/g of wet compost. The humic acid content was reduced by 97% during the purification steps resulting in a final humic acid concentration of 27+/-4.7 ng humic acid/microl. The purified DNA fragments were up to 14 kbp in size and were sufficiently free of contaminants to allow both restriction enzyme digestion by four different enzymes and PCR amplification of 16S rDNA.     

A vector for purification-free cloning of polymerase chain reaction products

Conventional cloning requires the purification of restriction-enzyme-digested vectors prior to the ligation reaction. The purification often involves the separation of restriction fragments via electrophoresis, the cutting out of a piece of gel, and the gel extraction of the linearized vector. In addition to the loss of significant amounts of DNA, reduced cloning efficiency, time, and cost, these steps are also mutagenic to DNA and hazardous to humans. We developed a purification-free cloning vector pGT3 with a bright green fluorescent protein indicator that is suitable for TA cloning of polymerase chain reaction (PCR) products. PCR products were cloned into pGT3 efficiently without the gel purification steps.     

Technical note: Bone DNA extraction and purification using silica-coated paramagnetic beads

The goal of this study was to develop a simple method to improve DNA recovery from challenging bone samples. To this end, an optimized procedure was developed that combined the demineralization and DNA extraction into a single step, followed by DNA purification using an automated silica-coated paramagnetic bead procedure. This method replaced a previous silica-membrane-based procedure, which was able to recover sufficient DNA to obtain full autosomal and Y chromosome STR profiles from greater than 90% of the samples, including samples greater than 20 years old. The development process began with the evaluation of buffer and demineralization systems to determine the best reagent combination. During the developmental process, we observed that the addition of EDTA and DTT affected silica-based DNA purification methods by raising the pH of the digest buffer. The protocols with buffer ATL, PK, EDTA, and DTT followed by lowering the pH with sodium acetate just before purification resulted in the best yields. The method reduced the extraction volume from 10 to 1.5 ml and used commercially available reagents already being utilized in forensic DNA casework. Because of the simplicity and small volume needed for the procedure, many steps where contamination could be introduced have been eliminated or minimized. This study demonstrated a new method of recovering DNA from bone samples capable of extracting trace quantities of DNA, removing potential inhibitors, and minimizing the potential for exogenous DNA contamination.