Salt drying: a low‐cost,simple and efficient method for storing plants in the field and preserving biological repositories for DNA diversity research

Although a variety of methods have been optimized for the collection and storage of plant specimens, most of these are not suited for field expeditions for a variety of logistic reasons. Drying specimens with silica gel in polyethylene bags is currently the standard for field‐sampling methods that are suitable for subsequent DNA extraction. However, silica‐gel repositories are not readily available in remote areas, and its use is not very cost‐effective for the long‐term storage of collections or in developing countries with limited research budgets. Salting is an ancient and traditional drying process that preserves food samples by dehydrating tissues and inhibiting water‐dependent cellular metabolism. We compared salt and silica‐gel drying methods with respect to dehydration rates overtime, DNA quality and polymerase chain reaction(PCR) success to assess whether dry salting can be used as an effective plant preservation method for DNA analysis. Specimens from eleven plant species covering a variety of leaf structures, leaf thicknesses and water contents were analysed. Experimental work indicated that (i) levels of dehydration in sodium chloride were usually comparable to those obtained when silica gel was used, (ii) no spoilage, fungal or bacterial growth was observed for any of the species with all drying treatments and (iii) good yields of quality genomic DNA suitable for PCR applications were obtained in the salt‐drying treatments. The preservation of plant tissues in commercial table salt appears to be a satisfactory, and versatile method that may be suitable in remote areas where cryogenic resources and silica repositories are not available.     

一种改良的植物基因组DNA通用提取方法

高质量的基因组DNA是分子生物学研究的基础,而从富含糖类和次生代谢物且异质性强的植物材料中分离DNA相对困难。本方法在CTAB法和商业DNA提取试剂盒的基础上,在裂解细胞之前,对植物材料进行预处理．去除干扰DNA提取的代谢物,并在后续步骤中进行了一些优化。该方法适于多种不同的植物种类,所提取的基因组DNA质量较好,能满足下一步基因操作的要求,是一种通用的植物基因组DNA提取方法。     

Species-specific PCR-DGGE markers to distinguish Pyrenophora species associated to cereal seeds

Pyrenophora species, toxigenic cereal pathogens, and causal agents of leaf and kernel diseases, bring about economic and food safety concerns. Traditionally, Pyrenophora taxa have been identified microscopically after a period of incubation on culture media. In this study, a simple nested PCR-denaturing gel electrophoresis (DGGE) method was developed to detect, differentiate and identify six Pyrenophora species in plant tissues. A primer, specific to Pyrenophora species and able to amplify a fragment of the ribosomal RNA (rRNA), following first round amplification with universal ITS primers, was designed by reviewing Pyrenophora ribosomal DNA sequences deposited in GenBank. The specificity of the primer was assessed by submitting its sequence to the GenBank Basic Local Alignment Search Tool (BLAST) algorithm, and was also tested with DNA extracted from several ascomycetous, basidiomycetous, and zygomycetous taxa. No PCR product was obtained from non-Pyrenophora species. PCR amplification of DNA extracted from pure cultures of the different Pyrenophora species generated amplicons of an approximate 350bp. DGGE effectively separated between all six Pyrenophora amplicons. Subsequently, amplicons of known Pyrenophora species were used as molecular markers when Pyrenophora infected wheat seed was analyzed by PCR-DGGE. The molecular-based approach described herein can be used to identify different Pyrenophora species directly from infected plant material.     

Two new nuclear isolation buffers for plant DNA flow cytometry: a test with 37 species

Background and Aims: After the initial boom in the application of flow cytometryin plant sciences in the late 1980s and early 1990s, which wasaccompanied by development of many nuclear isolation buffers,only a few efforts were made to develop new buffer formulas.In this work, recent data on the performance of nuclear isolationbuffers are utilized in order to develop new buffers, generalpurpose buffer (GPB) and woody plant buffer (WPB), for plantDNA flow cytometry. Methods: GPB and WPB were used to prepare samples for flow cytometricanalysis of nuclear DNA content in a set of 37 plant speciesthat included herbaceous and woody taxa with leaf tissues differingin structure and chemical composition. The following parametersof isolated nuclei were assessed: forward and side light scatter,propidium iodide fluorescence, coefficient of variation of DNApeaks, quantity of debris background, and the number of particlesreleased from sample tissue. The nuclear genome size of 30 selectedspecies was also estimated using the buffer that performed betterfor a given species. Key Results: In unproblematic species, the use of both buffers resulted inhigh quality samples. The analysis of samples obtained withGPB usually resulted in histograms of DNA content with higheror similar resolution than those prepared with the WPB. In morerecalcitrant tissues, such as those from woody plants, WPB performedbetter and GPB failed to provide acceptable results in somecases. Improved resolution of DNA content histograms in comparisonwith previously published buffers was achieved in most of thespecies analysed. Conclusions: WPB is a reliable buffer which is also suitable for the analysisof problematic tissues/species. Although GPB failed with someplant species, it provided high-quality DNA histograms in speciesfrom which nuclear suspensions are easy to prepare. The resultsindicate that even with a broad range of species, either GPBor WPB is suitable for preparation of high-quality suspensionsof intact nuclei suitable for DNA flow cytometry.     

Optimal extraction methods for the simultaneous analysis of DNA from diverse organisms and sample types

Using environmental DNA (eDNA) to assess the distribution of micro‐ and macroorganisms is becoming increasingly popular. However, the comparability and reliability of these studies is not well understood as we lack evidence on how different DNA extraction methods affect the detection of different organisms, and how this varies among sample types. Our aim was to quantify biases associated with six DNA extraction methods and identify one which is optimal for eDNA research targeting multiple organisms and sample types. We assessed each methods’ ability to simultaneously extract bacterial, fungal, plant, animal and fish DNA from soil, leaf litter, stream water, stream sediment, stream biofilm and kick‐net samples, as well as from mock communities. Method choice affected alpha‐diversity for several combinations of taxon and sample type, with the majority of the differences occurring in the bacterial communities. While a single method performed optimally for the extraction of DNA from bacterial, fungal and plant mock communities, different methods performed best for invertebrate and fish mock communities. The consistency of methods, as measured by the similarity of community compositions resulting from replicate extractions, varied and was lowest for the animal communities. Collectively, these data provide the first comprehensive assessment of the biases associated with DNA extraction for both different sample types and taxa types, allowing us to identify DNeasy PowerSoil as a universal DNA extraction method. The adoption of standardized approaches for eDNA extraction will ensure that results can be more reliably compared, and biases quantified, thereby advancing eDNA as an ecological research tool.     

Effect of UV Radiation and Other Abiotic Stress Factors on DNA of Different Wild Plant Species Grown in Three Successive Seasons in Alpine and Subalpine Regions

Plants in natural ecosystems are exposed to a combination of UV radiation, ionizing radiation (IR) and other abiotic factors. These factors change with the altitude. We investigated DNA alterations of some wild plants of different plant families in natural ecosystems at three altitudes in Rila Mountain, Bulgaria (1500, 1782, and 2925 m above sea level (a.s.l.) exposed to UV radiation, IR and other abiotic stresses, to assess the tolerance of plant species to the changing environmental conditions in three successive growth seasons. For this purpose, physicochemical, cytogenetic, and molecular methods were applied. DNA damage was assessed by micronucleus test and molecular method comet assay adapted and applied by us to wild plant species from Onagraceae, Rosaceae, Boraginaceae, Saxifragaceae, Orobanchaceae, Asteraceae and Poaceae families, growing at three different altitudes. Variability in the DNA sensitivity and the level of tolerance was observed among the plant species in response to combined abiotic factors assessed by induced DNA damage and gross beta activity. The studied representatives of Poaceae were less susceptible than the other studied species at all three altitudes and showed close level of DNA injuries to that of unaffected control plant grown in laboratory conditions. The lower levels of DNA damage of these wild plant species corresponded to their lower ability to accumulate radionuclides. There was a particularly pronounced low level of DNA injuries in the plant species at the highest altitude. The level of DNA damage showed correlation with the values of some abiotic environmental factors. The results would contribute to the elucidation of the extent of adaptation of plant species to the continuously changing environment and would be useful in selecting sensitive herbaceous monitor species for environmental impact assessment at mountain and alpine sites.     

A comparison of different methods for preserving plant molecular materials and the effect of degraded DNA on ddRAD sequencing

Obtaining high-quality plant materials for experiments is challenging for many research projects. Therefore, it is of special importance to determine the best method for preserving biological macromolecules like DNA, which degrade over time. Although some research has demonstrated that DNA degradation has little effect on traditional molecular markers, the effects of DNA degradation on ddRADseq, a popular reduced-representation sequencing technology, have not been adequately investigated. In this study, we first chose six woody bamboo species (Bambusoideae, Poaceae) to explore appropriate methods for preserving molecular materials with two DNA extraction approaches. Then we sequenced twenty-one bamboos and examined the effects of DNA quality on data generation using the ddRAD-seq technique (MiddRAD-seq). Finally, we reconstructed phylogenies of twenty woody bamboo species. We found that the integrity of dry-powdered DNA was preserved longer than that of TE-dissolved DNA, regardless of whether the DNA was extracted by a modified CTAB protocol or DNAsecure plant kit. The ddRAD-seq data were robust, except when DNA was severely degraded. In addition, we resolved the phylogenetic positions of the sampled Phyllostachys spp. Our results suggest that dry-powdered DNA is the most appropriate preservation method for plant molecular materials. Furthermore, a moderate level of DNA degradation has little effect on reduced representation sequencing techniques represented by ddRAD-seq.     

A rapid method for tissue collection and high-throughput isolation of genomic DNA from mature trees

Collection of tissue and subsequent isolation of genomic DNA from mature tree species often proves difficult. DNA extraction from needles, leaves, or buds is recommended in many protocols. Collecting these tissues from mature trees generally requires the use of firearms or climbing if sampling is to be nondestructive. As a result, sample collection is a major expense of many tree-based projects. Tree (and plant) tissues generally contain large amounts of polysaccharides and phenolic compounds that are difficult to separate from DNA. Many methods aim to overcom these problems, with most involving extraction in buffers containing the nonionic detergent cetyltrimethyl-ammonium bromide (CTAB), followed by numerous steps to clean contaminants from the DNA, using organic solvents and differential salt precipitation. These steps are time-consuming, such that isolation of DNA becomes the bottleneck in many molecular studies. This paper presents a new, efficient, cambium collection method for tree species and a DNA extraction protocol based on that of Doyle and Doyle (1987), with follow-up purification using the Wizard nuclei lysis and protein precipitation solutions (Promega). Results show a significant improvement in yield and DNA purity compared with other published methods, with consistently high yields of pure genomic DNA and high sample throughput. The relatively low cost per extraction, no requirement for use of liquid nitrogen, no requirement for freezer storage, and long-term sample stability after collection are important additional benefits.     

A high-throughput protocol for extracting high-purity genomic DNA from plants and animals

DNA extraction techniques that employ the reversible binding of DNA to silica via chaotropic salts can deliver high-quality genomic DNA from plant and animal tissues, while avoiding the use of toxic organic solvents. Existing techniques that use this method are either prohibitively expensive, or are applicable to only a restricted set of taxa. Here we describe a cost-effective DNA extraction technique suitable for a wide range of plant and animal taxa that yields microgram quantities of high-molecular-weight genomic DNA at a throughput of 192 samples per day. Our technique is particularly robust for tissue samples that are insoluble or are rapidly discoloured or oxidized in standard DNA extraction buffers. We demonstrate the quality of DNA extracted using this method by applying the amplified fragment length polymorphism technique to plant species.     

Validation of a cheap and simple nondestructive method for obtaining AFLPs and DNA sequences (mitochondrial and nuclear) in amphibians

The use of nondestructive methods for obtaining DNA from amphibians (e.g. buccal swabs) allows genetic studies to be performed without affecting the survival of the studied individuals. In this study, we compared two methods of nondestructive DNA sampling, buccal swabs and interdigital membrane or toe‐clipping, in several amphibian species of different size: Rhinella spinulosa, R. atacamensis, six species of the genus Telmatobius and Pleurodema thaul. We evaluated the integrity of the DNA extracted by sequencing fragments of mitochondrial and nuclear genes and by generating amplified fragment length polymorphisms markers (AFLPs). In all cases, we obtained an adequate amount of DNA (mean range 55–298 ng/μL). We obtained identical DNA sequences from buccal swab and interdigital membrane/toe‐clip for all individuals. The differences in the coding of AFLP markers between the tissues were similar to those reported for replicas of the same type of sample in similar analyses in other species of amphibians. In conclusion, the use of buccal swabs is a trustworthy and inexpensive method to obtain DNA for mitochondrial and nuclear sequencing and AFLP analyses. Given the types of markers evaluated, buccal swabs may be used for phylogenetic, phylogeographic and population genetic studies, even in small amphibians (<33 mm).     

A Comparison of DNA Extraction Methods using Petunia hybrida Tissues

Extraction of DNA from plant tissue is often problematic, as many plants contain high levels of secondary metabolites that can interfere with downstream applications, such as the PCR. Removal of these secondary metabolites usually requires further purification of the DNA using organic solvents or other toxic substances. In this study, we have compared two methods of DNA purification: the cetyltrimethylammonium bromide (CTAB) method that uses the ionic detergent hexadecyltrimethylammonium bromide and chloroform-isoamyl alcohol and the Edwards method that uses the anionic detergent SDS and isopropyl alcohol. Our results show that the Edwards method works better than the CTAB method for extracting DNA from tissues of Petunia hybrida. For six of the eight tissues, the Edwards method yielded more DNA than the CTAB method. In four of the tissues, this difference was statistically significant, and the Edwards method yielded 27–80% more DNA than the CTAB method. Among the different tissues tested, we found that buds, 4 days before anthesis, had the highest DNA concentrations and that buds and reproductive tissue, in general, yielded higher DNA concentrations than other tissues. In addition, DNA extracted using the Edwards method was more consistently PCR-amplified than that of CTAB-extracted DNA. Based on these results, we recommend using the Edwards method to extract DNA from plant tissues and to use buds and reproductive structures for highest DNA yields.     

Comparison of conventional and molecular methods for the detection of bacterial pathogens in sputum samples from cystic fibrosis patients

The nature of the micro-flora present in sputa of six different cystic fibrosis (CF) patients was assessed using routine microbiological culture and molecular methods. Bacterial genes for the small subunit ribosomal RNA (ssu rDNA) were specifically amplified from DNA extracted from the sputum samples, cloned and characterised by hybridisation and DNA sequencing. A large number of clones from six sputa were screened. Initially, oligonucleotide hybridisation was performed with five probes, specific for Gram-positives and Gram-negatives in general and the main pathogens for the CF patient (Staphylococcus aureus, Pseudomonas aeruginosa and Haemophilus influenzae). For a single sputum sample, the results were fully congruent when culture and molecular methods were compared. In the other five sputa, discrepancies for S. aureus and/or H. influenzae were documented. Although S. aureus DNA and H. influenzae DNA was detected in three and four sputa, respectively, strains could not be cultured. Although the PCR approach is not capable of distinguishing viable from dead bacteria, all of the CF patients had a history of S. aureus infections, while one of the CF patients once had cultivable H. influenzae in the sputum as well. A number of clones for probe-unidentified Gram-negative or Gram-positive bacterial species were further analysed by sequencing and additional potential pathogens were identified. Although routine culture of sputum frequently points to mono-specific exacerbations, our molecular data indicate that the other CF-related pathogens appear to be persistently present as well. We conclude that routine culture for bacterial pathogens from CF sputa yields limited microbiological information since it frequently fails to identify a number of pathogenic bacterial species that are potentially present in a viable status in the lungs of these patients.     

A modified protocol for rapid DNA isolation from plant tissues using cetyltrimethylammonium bromide

We describe a modification of the DNA extraction method, in which cetyltrimethylammonium bromide (CTAB) is used to extract nucleic acids from plant tissues. In contrast to the original method, the modified CTAB procedure is faster, omits the selective precipitation and CsCl gradient steps, uses less expensive and toxic reagents, requires only inexpensive laboratory equipment and is more readily adapted to high-throughput DNA extraction. This protocol yields approximately 5-30 microg of total DNA from 200 mg of tissue fresh weight, depending on plant species and tissue source. It can be completed in as little as 5-6 h.     

A fully automatable enzymatic method for DNA extraction from plant tissues

Background  

DNA extraction from plant tissues, unlike DNA isolation from mammalian tissues, remains difficult due to the presence of a rigid cell wall around the plant cells. Currently used methods inevitably require a laborious mechanical grinding step, necessary to disrupt the cell wall for the release of DNA.     

Molecular and Immunohistochemical Characterization of Historical Long-Term Preserved Fixed Tissues from Different Human Organs

University and museum collections are very important sources of biological samples that can be used to asses the past and present genetic diversity of many species. Modern genetic and immunohistochemical techniques can be used on long-term preserved fixed tissues from museum specimens to answer epidemiological questions. A proof of principle was established to apply modern molecular genetics and immunohistochemical methods to these old specimens and to verify the original diagnosis. We analysed 19 specimens from our university collection including human organs that had been in fixative for more than 80 years. The tissues originated from lung, colon, brain, heart, adrenal gland, uterus and skin. We isolated amplifiable DNA from these wet preparations and performed mutational analysis of BRAF, KRAS and EGFR. The tissues were also embedded in paraffin and used for modern histology and immunohistochemistry. Our data show that amplifiable DNA is extractable and ranged from 0.25 to 22.77 μg of total DNA. In three specimens BRAF^V600E or KRAS^G12D mutations were found. Additionally, expression of different proteins like vimentin and GFAP was detected immunohistochemical in six investigated specimens. On the basis of our results the original diagnosis was altered in three specimens. Our work showed that it is possible to extract amplifiable DNA suitable for sequence analysis from long-term fixed tissue. Furthermore, histology and immunohistochemistry is feasible in specimens fixed long time ago. We conclude that these old preparations are suitable for further epidemiological research and that our methods open up new opportunities for future studies.     

Comparison of five DNA extraction methods for molecular analysis of Jerusalem artichoke (Helianthus tuberosus)

DNA extraction is an essential step for molecular analysis of an organism, but it is difficult to acquire a sufficient amount of pure DNA from plant tissue with high levels of phenolic compounds, carbohydrates, proteins, and secondary metabolites. Jerusalem artichoke (Helianthus tuberosus) has high levels of such substances. We compared five commonly used methods of extracting genomic DNA in tests made with leaves and seed of four Jerusalem artichoke genotypes: 1) modified method of Tai and Tanksley, 2) method of Doyle and Doyle, 3) method of Porebski, 4) modified method of ?torchová, and 5) Plant DNA Kit of Omega Bio-tek. The quality and quantity of extracted DNAs were assessed by photometric assay, electrophoresis on 1% agarose gel and a PCR-based technique. The modified method of Tai and Tanksley was found to be superior for both young leaves and seed. The quality of the extracted DNA was confirmed by sequence-related amplified polymorphism. This information will be useful for molecular analyses of Jerusalem artichoke and other related Helianthus species.     

Rapid and simple methodology for isolation of high quality genomic DNA from coniferous tissues (<Emphasis Type="Italic">Taxus baccata</Emphasis>)

Various investigations have been so far performed for extraction of genomic DNA from plant tissues, in which the extracted intact DNA can be exploited for a diverse range of biological studies. Extraction of high quality DNA from leathery plant tissues (e.g., coniferous organs) appears to be a critical stage. Moreover, for some species such as Taxus trees, bioprocess engineering and biosynthesis of secondary metabolites (e.g., paclitaxel) is a crucial step due to the restrictions associated with extinction of these species. However, extraction of intact genomic DNA from these plants still demands a rapid, easy and efficient protocol. To pursue such aim, in the current work, we report on the development of a simple and highly efficient method for the extraction of DNA from Taxus baccata. Based upon our protocol, interfering phenolic compounds were removed from extraction using polyvinylpyrrolidone and RNA contamination was resolved using LiCl. By employing this method, high quality genomic DNA was successfully extracted from leaves of T. baccata. The quality of extracted DNA was validated by various techniques such as RAPD marker, restriction digestions and pre-AFLP. Upon our findings, we propose this simple method to be considered for extraction of DNA from leathery plant tissues.     

A CRISPR-based strategy for targeted sequencing in biodiversity science

Many applications in molecular ecology require the ability to match specific DNA sequences from single- or mixed-species samples with a diagnostic reference library. Widely used methods for DNA barcoding and metabarcoding employ PCR and amplicon sequencing to identify taxa based on target sequences, but the target-specific enrichment capabilities of CRISPR-Cas systems may offer advantages in some applications. We identified 54,837 CRISPR-Cas guide RNAs that may be useful for enriching chloroplast DNA across phylogenetically diverse plant species. We tested a subset of 17 guide RNAs in vitro to enrich plant DNA strands ranging in size from diagnostic DNA barcodes of 1,428 bp to entire chloroplast genomes of 121,284 bp. We used an Oxford Nanopore sequencer to evaluate sequencing success based on both single- and mixed-species samples, which yielded mean chloroplast sequence lengths of 2,530–11,367 bp, depending on the experiment. In comparison to mixed-species experiments, single-species experiments yielded more on-target sequence reads and greater mean pairwise identity between contigs and the plant species' reference genomes. But nevertheless, these mixed-species experiments yielded sufficient data to provide ≥48-fold increase in sequence length and better estimates of relative abundance for a commercially prepared mixture of plant species compared to DNA metabarcoding based on the chloroplast trnL-P6 marker. Prior work developed CRISPR-based enrichment protocols for long-read sequencing and our experiments pioneered its use for plant DNA barcoding and chloroplast assemblies that may have advantages over workflows that require PCR and short-read sequencing. Future work would benefit from continuing to develop in vitro and in silico methods for CRISPR-based analyses of mixed-species samples, especially when the appropriate reference genomes for contig assembly cannot be known a priori.     

A Simple and Non-destructive Method of Direct-PCR for Plant Systems

To date, PCR is a fundamental tool for most of the research concerning plant diversity analysis, marker-assisted selection, genetic purity testing, disease diagnostics, and transgene analysis. In all of these analyses, good-quality DNA serves as a template for amplification of target sequences. Extraction of good-quality DNA requires many steps, making the whole process time consuming, tedious, labor intensive, and expensive due to costlier and toxic chemicals. To overcome these preparatory steps from PCR-based DNA amplification, we have developed a direct-PCR amplification method for plants without isolating DNA. The method is unique and beneficial over some previously described methods of direct-PCR which fail due to inefficient amplification of target DNA in the presence of PCR inhibitors and crop specificity. Moreover, such methods are non-specific and, being destructive, cannot be replicated; one cannot completely rely on them due to lack of reproducibility. This method was streamlined from our earlier observation that alcohol-desiccated tissues maintain intact DNA for a long time. This method is specific, rapid, and, being non-destructive, allows replication, giving advantages over existing methods. The method was tested over a wide range of plant species and found very effective and quick in generating data. The method was successfully used to test the genetic purity of pearl millet hybrid (RHB-127) and its restorer (RIB 3135-18) and CMS line (ICMA 93333A). Our method is especially important for developing inexpensive and high-throughput non-invasive genetic analyses.