Differential effect of sample preservation methods on plant and arbuscular mycorrhizal fungal DNA

A wide range of methods are commonly used for preserving environmental samples prior to molecular analyses. However, the effect of these preservation methods on fungal DNA is not understood. The objective of this study was to test the effect of eight different preservation methods on the quality and yield of DNA extracted from Bromus inermis and Daucus carota roots colonized by the arbuscular mycorrhizal (AM) fungus, Glomus intraradices. The total DNA concentration in sample extracts was quantified using spectrophotometry. Samples that were frozen (− 80 ºC and − 20 ºC), stored in 95% ethanol, or silica gel dried yielded total (plant and fungal) DNA concentrations that were not significantly different from fresh samples. In contrast, samples stored in CTAB solution or freeze-dried resulted in significantly reduced DNA concentrations compared with fresh samples. The preservation methods had no effect on the purity of the sample extracts for both plant species. However, the DNA of the dried samples (silica gel dried, freeze-dried, heat dried) appeared to be slightly more degraded compared with samples that remained hydrated (frozen, stored in ethanol or CTAB solutions) during storage when visualized on a gel. The concentration of AM fungal DNA in sample extracts was quantified using TaqMan real time PCR. Methods that preserved samples in hydrated form had similar AM fungal DNA concentrations as fresh samples, except D. carota samples stored in ethanol. In contrast, preservation methods that involved drying the samples had very low concentrations of AM fungal DNA for B. inermis, and nearly undetectable for D. carota samples. The drying process appears to be a major factor in the degradation of AM fungal DNA while having less of an impact on plant DNA. Based on these results, samples that need to be preserved prior to molecular analysis of AM fungi should be kept frozen to minimize the degradation of plant and AM fungal DNA.     

Fecal collection, ambient preservation, and DNA extraction for PCR amplification of bacterial and human markers from human feces

Feces contain intestinal bacteria and exfoliated epithelial cells that may provide useful information concerning gastrointestinal tract health. Intestinal bacteria that synthesize or metabolize potential carcinogens and produce anti-tumorigenic products may have relevance to colorectal cancer, the second most common cause of cancer deaths in the USA. To facilitate epidemiological studies relating bacterial and epithelial cell DNA and RNA markers, preservative/extraction methods suitable for self-collection and shipping of fecal samples at room temperature were tested. Purification and PCR amplification of fecal DNA were compared after preservation of stool samples in RNAlater (R) or Paxgene (P), or after drying over silica gel (S) or on Whatman FTA cards (W). Comparisons were made to samples frozen in liquid nitrogen (N2). DNA purification methods included Whatman (accompanying FTA cards), Mo-Bio Fecal (MB), Qiagen Stool (QS), and others. Extraction methods were compared for amount of DNA extracted, DNA amplifiable in a real-time SYBR-Green quantitative PCR format, and the presence of PCR inhibitors. DNA can be extracted after room temperature storage for five days from W, R, S and P, and from N2 frozen samples. High amounts of total DNA and PCR-amplifiable Bacteroides spp. DNA (34%+/-9% of total DNA) with relatively little PCR inhibition were especially obtained with QS extraction applied to R preserved samples (method QS-R). DNA for human reduced folate carrier (SLC19A1) genomic sequence was also detected in 90% of the QS-R extracts. Thus, fecal DNA is well preserved by methods suitable for self-collection that may be useful in future molecular epidemiological studies of intestinal bacteria and human cancer markers.     

A new angiosperms molecular specimen treatment method for field use

Aims This study aims to identify a more convenient drying method for obtaining molecular specimen of angiosperms in the field than the conventional silica gel drying method. Methods The leaves of Prunus serrulata var. lannesiana and Liriope spicata were dried under temperatures of 150 °C, 80 °C, 40 °C as well as under natural conditions, and by the silica gel drying method, respectively. The DNA extracts of various specimens were then analyzed using techniques of spectrophotometer detection, electrophoresis and PCR to evaluate the impacts of different drying treatments to the genomic DNA of testing plants. Important findings The concentrations of total DNA were higher for the specimens dried at 40 °C treatment and by the silica gel drying method than other treatments when assessed by the techniques of spectrophotometer detection and electrophoresis. The concentration of PCR products was highest in the specimens dried at 40 °C. Based on the results, the 40 °C drying can be recommended for obtaining molecular specimens of angiosperms because of its minimum degree of degradation, for convenience of operation and avoiding carrying large amounts of silica gel in field investigations.     

药用植物艾纳香基因组DNA提取方法研究

以药用植物艾纳香为研究对象,以-20℃保存、4℃保存、室温自然干燥和硅胶干燥四种样品保存方式,并采用SDS法、CTAB法、SDS-CTAB法和改良CTAB法4种不同的基因组DNA提取方法进行了对比试验,以期建立艾纳香的较好的样品保存方法和基因组DNA提取方法。结果表明,-20℃保存是艾纳香的较理想的样品保存方式;改良CTAB法是艾纳香基因组DNA提取较适宜的方法,该方法提取的DNA经紫外检测,其A_(260)/A_(280)为1.8左右,明显优于SDS法(1.1～1.5)、CTAB法(1.2～1.5)和SDS-CTAB法(1.4～1.6),琼脂糖凝胶电泳、酶切检测和PCR扩增也得出了同样的结论。     

Alternative methods for sampling and preservation of photosynthetic pigments and tocopherols in plant material from remote locations

Current methods for the study of pigments involve freezing in liquid nitrogen and storage at −80°C or lyophilization until HPLC analysis. These requirements greatly restrict ecophysiological research in remote areas where such resources are hardly available. We aimed to overcome such limitations by developing several techniques not requiring freezing or lyophilization. Two species with contrasting foliar characteristics (Olea europaea and Taraxacum officinale) were chosen. Seven preservation methods were designed, optimized and tested in a field trial. These protocols were compared with a control immediately frozen after collection. Pigments and tocopherols were analysed by HPLC. Main artefacts were chlorophyll epimerization or phaeophytinization, carotenoid isomerization, altered de-epoxidation index and tocopherol degradation. Among all methods, sample desiccation in silica gel provides robust samples (pigment composition was unaffected by storage time or temperature) and almost unaltered pigment profiles, except for a shift in epoxidation state. Although liquid nitrogen freezing and subsequent lyophilization or freezer storage were preferred, when these facilities are either not available or not suitable for long-distance transport, desiccation with silica gel, passive extraction in acetone and/or storage of fresh samples in water vapour saturated atmospheres enable a complete pigment characterization. Silica gel is advisable for long-term sample conservation.     

Factors affecting DNA preservation from museum-collected lepidopteran specimens

Recent innovations in molecular genetics made DNA an intriguing molecule not only in molecular biology, but also in ecology and evolutionary and conservation biology. Despite this general interest, several discrepancies have been reported in the literature regarding the techniques for preserving insects for DNA analysis, prompting us to analyse the effects of different storage conditions on lepidopteran DNA preservation. In particular, in the present paper, adults of the cabbage moth, Mamestra brassicae (L.) (Lepidoptera: Noctuidae), were stored under various conditions in order to verify which method is the most suitable to preserve lepidopteran specimens for DNA studies. Mamestra brassicae adults were stored by rapid desiccation with silica gel, by preservation in acetone, 2-propanol, Carnoy's or ethanol (both at 75 and 100% concentrations) solutions, and finally by storage in an ultracold freezer and liquid nitrogen. Adults preserved by each method were used to extract DNA at the aim of verifying the size of the extracted DNAs, the extraction yield and the possibility of using these samples to amplify both short and long DNA sequences by polymerase chain reaction. The results were compared with those obtained using fresh samples acting as controls. Acetone preservation appeared to be the most recommendable method for moth specimens as it proved to be a good storage medium for DNA analysis, it is cost-effective, and it is applicable not only to field surveys, but also to obtain efficient and low-cost storage of lepidopteran specimens in museum collections.     

Preservation of hymenopteran specimens for subsequent molecular and morphological study

Some guidelines are presented for long-term preservation of insects for non-traditional systematic studies such as DNA sequencing and internal anatomical research. The main criteria for good DNA preservation appear to be the rapidity with which the DNA is protected from enzymatic and chemical breakdown, and subsequent storage conditions. The immediate post mortem treatment of specimens appears particularly important to the preservation of amplifiable DNA. For storage we recommend 70–100% ethanol at low temperature, deep freezing, and critical point or chemical drying direct from alcohol. For internal anatomy, traditional fixatives, 70% ethanol in a refrigerator, critical point drying or chemical drying are recommended. Cold-storage in 70% ethanol with or without subsequent critical point drying or chemical drying using hexamethyldisilazane allow both molecular and morphological study.     

Viability and genetic stability of the bacterium Escherichia coli HB101 with the recombinant plasmid during preservation by various methods.

The effects of various methods of preservation (freeze-drying and storage at 4 degrees C; low-temperature freezing on desiccated silica gel and storage at -70 and -150 degrees C; cryopreservation and storage at -196 degrees C) on viability and genetic stability of the bacterium Escherichia coli HB101 carrying the recombinant plasmid with the human DNA fragment were studied. Genetic stability was estimated by maintenance of the selective markers of antibiotic resistance and the stability of the restriction sites in recombinant DNA. Freezing on silica gel and cryopreservation were shown to be the optimal preservation methods providing a high level of survival and genetic stability.     

Is Shape of a Fresh and Dried Leaf the Same?

Plants kept as dried herbarium specimens share many characteristics with their living counterparts, but there are some substantial differences between them. Due to dehydration, leaves of herbarium specimens change not only their mass and colour, but in many cases change their dimensions, too. The present study aimed to determine whether leaf shape changes during the drying process. A total of 794 pairs of fresh and dried leaves or leaflets of 22 plant taxa were studied. The shape of the blades was quantified using elliptic Fourier analysis combined with principal component analysis. In addition, area and mass of the leaves were measured. Statistical tests were applied for comparing fresh and dried leaves. The results indicate that the preservation process of pressing and drying plants for herbarium purposes causes changes in leaf shape. In general, the shape changes were directional. As the shape of fresh and dried plants is different, it is strongly recommended that shape analyses should be performed on datasets containing either of the leaf types.     

Empirical evaluation of preservation methods for faecal DNA

We evaluate the relative effectiveness of four methods for preserving faecal samples for DNA analysis. PCR assays of fresh faecal samples collected from free-ranging baboons showed that amplification success was dependent on preservation method, PCR-product size, and whether nuclear or mitochondrial DNA was assayed. Storage in a DMSO/EDTA/Tris/salt solution (DETs) was most effective for preserving nuclear DNA, but storage in 70% ethanol, freezing at –20°C and drying performed approximately equally well for mitochondrial DNA and short (<200 bp) nuclear DNA fragments. Because faecal DNA is diluted and degraded, repeated extractions from faeces may be necessary and short nuclear markers should be employed for genotyping. A review of molecular scatology studies further suggests that three to six faeces per individual should be collected.     

Preservation of corals in salt-saturated DMSO buffer is superior to ethanol for PCR experiments

Specimen collection is time consuming and expensive, yet few laboratories test preservation methods before setting out on field expeditions. The most common preservation buffer used for coral specimens is >70% EtOH. However, alternatives exist that are less flammable, easier to ship, and are widely used in other taxa. Here, we compare the effects of salt-saturated DMSO (SSD) and EtOH preservation buffers on post-extraction DNA quantity and quality. We found that soft tissue integrity was better maintained and higher quantities of DNA were extracted from EtOH-preserved specimens; however, by all other measures, SSD was a superior preservative to EtOH. Extractions of SSD-preserved specimens resulted in higher molecular weight DNA, higher PCR success, and more efficient amplification than specimens preserved in EtOH. Our results show that SSD is generally a superior preservative to EtOH for specimens destined for PCR studies, but species-specific differences indicate that preservation comparisons should be undertaken before collection and storage of samples.     

Evaluation of six methods for extraction and purification of viral DNA from urine and serum samples

The sensitivity and reliability of PCR for diagnostic and research purposes require efficient unbiased procedures of extraction and purification of nucleic acids. One of the major limitations of PCR-based tests is the inhibition of the amplification process by substances present in clinical samples. This study used specimens spiked with a known amount of plasmid pBKV (ATCC 33-1) to compare six methods for extraction and purification of viral DNA from urine and serum samples based on recovery efficiency in terms of yield of DNA and percentage of plasmid pBKV recovered, purity of extracted DNA, and percentage of inhibition. The most effective extraction methods were the phenol/chloroform technique and the silica gel extraction procedure for urine and serum samples, respectively. Considering DNA purity, the silica gel extraction procedure and the phenol/chloroform method produced the most satisfactory results in urine and serum samples, respectively. The presence of inhibitors was overcome by all DNA extraction techniques in urine samples, as evidenced by semiquantitative PCR amplification. In serum samples, the lysis method and the proteinase K procedure did not completely overcome the presence of inhibitors.     

Comparison of Eleven Methods for Genomic DNA Extraction Suitable for Large-Scale Whole-Genome Genotyping and Long-Term DNA Banking Using Blood Samples

Over the recent years, next generation sequencing and microarray technologies have revolutionized scientific research with their applications to high-throughput analysis of biological systems. Isolation of high quantities of pure, intact, double stranded, highly concentrated, not contaminated genomic DNA is prerequisite for successful and reliable large scale genotyping analysis. High quantities of pure DNA are also required for the creation of DNA-banks. In the present study, eleven different DNA extraction procedures, including phenol-chloroform, silica and magnetic beads based extractions, were examined to ascertain their relative effectiveness for extracting DNA from ovine blood samples. The quality and quantity of the differentially extracted DNA was subsequently assessed by spectrophotometric measurements, Qubit measurements, real-time PCR amplifications and gel electrophoresis. Processing time, intensity of labor and cost for each method were also evaluated. Results revealed significant differences among the eleven procedures and only four of the methods yielded satisfactory outputs. These four methods, comprising three modified silica based commercial kits (Modified Blood, Modified Tissue, Modified Dx kits) and an in-house developed magnetic beads based protocol, were most appropriate for extracting high quality and quantity DNA suitable for large-scale microarray genotyping and also for long-term DNA storage as demonstrated by their successful application to 600 individuals.     

Post Mortem DNA Degradation of Human Tissue Experimentally Mummified in Salt

Mummified human tissues are of great interest in forensics and biomolecular archaeology. The aim of this study was to analyse post mortem DNA alterations in soft tissues in order to improve our knowledge of the patterns of DNA degradation that occur during salt mummification. In this study, the lower limb of a female human donor was amputated within 24 h post mortem and mummified using a process designed to simulate the salt dehydration phase of natural or artificial mummification. Skin and skeletal muscle were sampled at multiple time points over a period of 322 days and subjected to genetic analysis. Patterns of genomic fragmentation, miscoding lesions, and overall DNA degradation in both nuclear and mitochondrial DNA was assessed by different methods: gel electrophoresis, multiplex comparative autosomal STR length amplification, cloning and sequence analysis, and PCR amplification of different fragment sizes using a damage sensitive recombinant polymerase. The study outcome reveals a very good level of DNA preservation in salt mummified tissues over the course of the experiment, with an overall slower rate of DNA fragmentation in skin compared to muscle.     

Plant DNA extraction using silica

Described here is a method that uses silicon dioxide (silica) to extract whole genomic plant DNA of high molecular weight. The protocol is presented in a microcentrifuge format, and yields were approximately 2–4 μg per 200 mg of plant leaf tissue. The method involves fewer steps than many previous extraction protocols and, as shown here for 4 taxonomically distant angiosperms, produces DNA suitable for digestion with restriction endonucleases. The use of commercial kits is not required; the silica costs are comparatively inexpensive (<$0.03 per tube); and CTAB, rather than the more expensive guanidine thiocyanate salt, is used.     

Preservation of comet assay slides: comparison with fresh slides.

The single cell gel electrophoresis assay (comet assay) is an inexpensive, rapid and highly sensitive method for the determination of DNA damage, crosslinks, and alkaline-labile lesions in individual cells. A limitation of the procedure is that the microelectrophoretic gels must be scored rapidly as the comet configuration deteriorates on storage due to dehydration of the agarose and diffusion of DNA. The objectives of this study were firstly to evaluate drying regimes as rapid and simple methods of preservation of the microgels as close to their original fresh state as possible, and secondly to examine the effects of storage of the slides. Human hepatoma (HepG2) cells challenged for 30 min with hydrogen peroxide (H(2)O(2)) were used in the study. Microgel slides were prepared and evaluated immediately, or after drying with or without a methanol fixation step. Microgels that were dried at a variety of temperatures (22-50 degrees C) and re-hydrated did not differ in the values obtained for H(2)O(2)-induced DNA damage when compared to fresh samples. Samples could also be continually dried and re-hydrated over a period of up to 3 months with no obvious loss of information. In conclusion, drying of microgels represents a simple and inexpensive method of preserving comet assay slides.     

Field preservation of marine invertebrate tissue for DNA analyses

Successful preservation of tissue samples is a prerequisite for long field studies in remote areas. However, there is little published information concerning field preservation of marine invertebrate tissues for DNA analyses. This omission is significant because marine biodiversity is centered in the Indo-Pacific, where immediate DNA analysis is often impossible. Consequently, we used an assay based on polymerase chain reaction (PCR) to examine the effect of five storage solutions and three temperature regimens on the degradation of DNA from four common classes of marine invertebrates (Anthozoa, Gastropoda, Polychaeta, and Scyphozoa). Control samples were cryopreserved. Storage solution and the type of tissue preserved were the best predictors of preservation success. The length of time in storage and the storage temperature also affected the preservation of DNA. A field test demonstrates that a solution of dimethylsulfoxide and sodium chloride (DMSO-NaCl) preserves a wide range of tissues for DNA analyses and is very simple to use in remote field locations.     

An improved semiautomated rapid method of extracting genomic DNA for molecular marker analysis in cocoa,<Emphasis Type="Italic">Theobroma cacao</Emphasis> L

DNA extraction is a time-consuming and expensive component of molecular marker analysis, constituting about 30–60% of the total time required for sample processing. Furthermore, the procedure for extracting high-quality DNA from tree species such as cocoa differs from extraction protocols suitable for other crop plants. This is accompanied by problems in collecting leaf tissues from field-grown cocoa trees, where storage facilities are not available and where transporting samples to laboratory for immediate refrigeration is usually impossible. We preserved cocoa leaf tissues in the field in an NaCl-CTAB-azide solution (as described in Rogstad, 1992), which did not require immediate refrigeration. This method also allowed preservation of leaf tissues for a few days during transportation and protected leaf tissues from bacterial and fungal attacks. Once transported to the laboratory, the samples were stored at 4°C for almost 1 y. To isolate good-quality DNA from stored leaf tissues, a rapid semiautomated and relatively high-throughput protocol was established. The procedure followed a modified CTAB/β-mercaptoethanol method of DNA extraction in a 96-well plate, and an automated system (i.e., GenoGrinder 2000) was used to grind the leaf tissues. The quality of DNA was not affected by long storage, and the quantity obtained per sample was adequate for about 1000 PCR reactions. Thus, this method allowed isolation of about 200 samples per day at a cost of $0.60 per sample and is a relatively high-throughput, low-cost extraction compared with conventional methods that use manual grinding and/or expensive kits.     

A cheap,reliable and rapid method of extracting high‐quality DNA from plants

Here we describe a rapid method for extracting DNA from plant material using a microtitre plate system. This extraction procedure has been tested using three species, Brassica napus, Brassica napus/rapa hybrids and Arum maculatum, stored frozen, in silica gel or used fresh. The length of storage was between 7 days and 2 years, and in all cases high molecular weight DNA was reliably purified. Polymerase chain reaction (PCR) testing, using multiplex and single product amplification, inter simple sequence repeats (ISSRs) and microsatellites, was always reliable. This method combines the speed of commercial 96‐well plate methods with the economies associated with readily available laboratory chemicals.     

The effect of culture preservation techniques on patulin and citrinin production by Penicillium expansum Link

AIMS: To study the influence of culture preservation methods and culture conditions on the production of the mycotoxins patulin and citrinin by Penicillium expansum. METHODS AND RESULTS: Ten strains of Penicillium expansum were preserved using subculture and maintenance at 4 degrees C, mineral oil, drying on silica gel and freeze-drying. Patulin and citrinin production was assessed on yeast extract sucrose agar (YES) and grape juice agar (GJ), using TLC before and after 0.5, 2-3, 6 and 12 months preservation. Citrinin was detected in all cultures for all preservation techniques on YES. The patulin profiles obtained differed with strain and culture media used. CONCLUSIONS: Citrinin production seems to be a stable character for the tested strains. There is a tendency for patulin detection with time apparently more consistent for silica gel storage and freeze-drying, especially when the strains are grown on GJ. SIGNIFICANCE AND IMPACT OF THE STUDY: Variability in the profiles of the mycotoxins tested seems to be more strain-specific than dependent on the preservation technique used.