Extraction of DNA from milligram amounts of fresh,herbarium and mummified plant tissues

Summary We have developed a DNA extraction procedure for milligram amounts of plant tissue. Yields ranged from 0.3–200 nanograms of DNA per milligram of tissue. The factors affecting yield are discussed. Fresh tissue, as well as herbarium specimens (22–118 years old) and mummified seeds and embryos (500 to greater than 44 600 years old) were used. All tissues attempted (57 types from 29 species) yielded measurable amounts of DNA. In no case tested was inhibition observed for restriction enzymes BamHI or EcoRI.     

Isolation of fungal DNA from plant tissues and removal of DNA amplification inhibitors

Specific primers and the polymerase chain reaction (PCR) are increasingly used for detection of fungi in plants. Detection depends on isolation of DNA that is free of compounds that inhibit amplification. We report on the significance of inhibition in soybean stems with a focus on studies of the vascular fungal pathogen Phialophora gregata. A simple DNA extraction procedure based on a FastDNA® kit is described that allows consistent detection of fungi in soybean stems using PCR. The addition of polyvinylpyrrolidone and supplemental DNA purification steps overcame inhibition in over 90% of samples. These methods should also facilitate studies with other plant and fungal species.     

Extraction of cellular DNA from human cells and tissues fixed in ethanol

DNA can be extracted from ethanol-fixed lymphoid cells and tissues. The fixation procedure is simple and rapid, and the DNA extraction itself is the same as that normally used for fresh tissue or cells. DNA extracted from ethanol-fixed material is indistinguishable from DNA extracted from fresh samples based on its purity, its ability to be digested with restriction endonucleases, and its ability to specifically hybridize to DNA probes. The capability to extract DNA from ethanol-fixed cells and tissues eliminates the need for stringent handling and storage requirements of fresh or frozen specimens.     

Analysis of cell wall material from plant tissues: Extraction and purification

The alcohol-insoluble residue (AIR) of immature and mature runner beans contains co-precipitated cytoplasmic proteins, nucleic acids, starch and polyphenols, which contaminate the isolated polysaccharide fractions and their binding is sufficiently tenacious to resist complete extraction with the usual protein solubilizing reagents. Therefore, a method was developed for preparation of “cell wall material” from plant tissues in which the contamination with cytoplasmic constituents was minimal. Alternative solvents for cell disruption and protein extraction have been compared. The method depended for its success on the selective removal of the contaminants from fresh ball-milled tissue by sequential treatments with 1% aq. Na deoxycholate, PhOH-HOAc-H₂O followed by α-amylase digestion. Ball-milling the tissue ensured almost complete rupture of the cells and organelles and allowed the solvents to penetrate the sample fully and dissolve the cytoplasmic constituents. The purified “cell wall material” has protein contents varying from 2.5 to 5.5% depending on the type and maturity of the tissue. The residual proteins are resistant to pronase, rich in hydroxyproline and have the amino acid composition of purified cell wall proteins, showing that the wall preparations are relatively pure.     

Extraction of PCR-quality plant and microbial DNA from total rumen contents

DNA from rumen digesta has several diagnostic applications such as studying microbial community dynamics, transgene/DNA stability, and population typing of various rumen bacteria. Several DNA extraction procedures are described in the literature for rumen digesta, which describe the removal of tannins, polysaccharides, and other PCR inhibitors. Some of these protocols are time-consuming and impractical when handling a large number of samples routinely. Here we describe a rapid method for the extraction of PCR-quality plant and microbial DNA from total rumen contents that is based on modifications in the cetyltrimethylammonium bromide procedure followed by cleanup using a Qiagen column. This procedure is highly reproducible and relatively short, once the initial grinding of the samples is performed, and it consistently yields PCR-quality DNA.     

Fluorescence in situ hybridization on vibratome sections of plant tissues

This protocol describes the application of fluorescence in situ hybridization (FISH) to three-dimensionally (3D) preserved tissue sections derived from intact plant structures such as roots or florets. The method is based on the combination of vibratome sectioning with confocal microscopy. The protocol provides an excellent tool to investigate chromosome organization in plant nuclei in all cell types and has been used on tissues of both monocot and dicot plant species. The visualization of 3D well-preserved tissues means that cell types can be confidently identified. For example, meiocytes can be clearly identified at all stages of meiosis and can be imaged in the context of their surrounding maternal tissue. FISH can be used to localize centromeres, telomeres, repetitive regions as well as unique regions, and total genomic DNAs can be used as probes to visualize chromosomes or chromosome segments. The method can be adapted to RNA FISH and can be combined with immunofluorescence labeling. Once the desired plant material is sectioned, which depends on the number of samples, the protocol that we present here can be carried out within 3 d.     

A useful protocol for in situ RT-PCR on plant tissues

This study describes an effective method of in situ RT-PCR (RT-ISPCR) that was developed to localize gene expression in plant tissues. This RT-PCR technique was performed on sectioned tissues of female buds of the cucumber GY3 inbred line. The CUS1 gene, encoding the MADS-box type (agamus-like) protein, the expression pattern of which was described earlier, was used as a marker gene for optimisation of steps in the in situ RT-PCR inside the cells. For the identification of RT-PCR products inside the cells of the female buds, they were fixed in FAA solution, embedded in Paraplast Plus and cut into 7 microm thick sections which were dewaxed by immersion in HistoClear and dehydrated with ethanol. They were washed in water, then in 0.02M HCl, 2xSSC and PBS buffer. In the next step of tissue pretreatment, the sections were digested with 1% pectinase. As shown, the pectinase treatment proved to be a crucial step in the tissue preparation procedure to get successful RT-PCR products. After washing in PBS buffer, the sections were digested with protease K followed by incubation with RNase-free DNase I, and subsequently washed in 2xSSC, 1xSSC and 0.5xSSC and finally in DEPC-treated water. Then the sections were covered with 50 microl of the RT-PCR reaction mixture supplemented with 0.5 microM digoxigenin dUTP and sealed with a coverslip. After amplification in situ the PCR products were identified with anti-digoxigenin antibody (Roche Molecular Biochemicals), conjugated with alkaline phosphatase. The data obtained showed that specific signals reflecting CUS1 gene expression were detected in the female flower buds of cucumber. The specificity of the in situ RT-PCR protocol was confirmed by dot blot hybridization of RT-PCR products with CUS1 cDNA probe.     

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.     

In situ detection of salicylic acid binding sites in plant tissues

The determination of hormone‐binding sites in plants is essential in understanding the mechanisms behind hormone function. Salicylic acid (SA) is an important plant hormone that regulates responses to biotic and abiotic stresses. In order to label SA‐binding sites in plant tissues, a quantum dots (QDs) probe functionalized with a SA moiety was successfully synthesized by coupling CdSe QDs capped with 3‐mercaptopropionic acid (MPA) to 4‐amino‐2‐hydroxybenzoic acid (PAS), using 1‐ethyl‐3‐(3‐dimethyllaminopropyl) carbodiimide (EDC) as the coupling agent. The probe was then characterized by dynamic light scattering and transmission electron microscopy, as well as UV/vis and fluorescence spectrophotometry. The results confirmed the successful conjugation of PAS to CdSe QDs and revealed that the conjugates maintained the properties of the original QDs, with small core diameters and adequate dispersal in solution. The PAS–CdSe QDs were used to detect SA‐binding sites in mung bean and Arabidopsis thaliana seedlings in vitro and in vivo. The PAS–CdSe QDs were effectively transported into plant tissues and specifically bound to SA receptors in vivo. In addition, the effects of the PAS–CdSe QDs on cytosolic Ca²⁺ levels in the tips of A. thaliana seedlings were investigated. Both SA and PAS–CdSe QDs had similar effects on the trend in cytosolic‐free Ca²⁺ concentrations, suggesting that the PAS–CdSe QDs maintained the bioactivity of SA. To summarize, PAS–CdSe QDs have high potential as a fluorescent probe for the in vitro/in vivo labeling and imaging of SA receptors in plants. Copyright © 2014 John Wiley & Sons, Ltd.     

Extraction of proteins for sodium dodecyl sulfate-polyacrylamide gel electrophoresis from protease-rich plant tissues

A method of extracting proteins for sodium dodecyl sulfate-polyacrylamide gel electrophoresis from plant tissues with high protease activity was described. It resolved protein bands in highmolecular-weight regions of the gel and replaced commonly used procedures which showed severe degradation of proteins, even in the presence of protease inhibitors.     

Safer DNA extraction from plant tissues using sucrose buffer and glass fiber filter

For some plant species, DNA extraction and downstream experiments are inhibited by various chemicals such as polysaccharides and polyphenols. This short communication proposed an organic-solvent free (except for ethanol) extraction method. This method consists of an initial washing step with STE buffer (0.25?M sucrose, 0.03?M Tris, 0.05?M EDTA), followed by DNA extraction using a piece of glass fiber filter. The advantages of this method are its safety and low cost. The purity of the DNA solution obtained using this method is not necessarily as high as that obtained using the STE/CTAB method, but it is sufficient for PCR experiments. These points were demonstrated empirically with two species, Japanese speedwell and common dandelion, for which DNA has proven difficult to amplify via PCR in past studies.     

Multiple gene detection by in situ RT-PCR in isolated plant cells and tissues

With the number of functional genomic approaches in plant biology increasing daily, the demand for rapid and reliable RNA localization techniques for gene characterization is being felt. We present herein a novel, liquid phase in situ RT-PCR (IS-RT-PCR) protocol using a combination of gene-specific fluorescent primers and spectral confocal microscopy to localize target RNA in epicotyl sections and xylogenic suspension cultures of Zinnia elegans. Potential sources of artefacts from fixation to gene detection were systematically eliminated using both fluorescent primers and nucleotides for 18S rRNA gene detection, resulting in a set of optimal parameters for IS-RT-PCR that may be readily adapted to any target gene. By judiciously choosing fluorescent primers with non-overlapping fluorochromes, we have shown that our technique is readily adapted to multiplex IS-RT-PCR, enabling the simultaneous localization of more than one gene within a complex tissue or heterogeneous cell population. A 6-carboxy-2',4,4',5',7,7'-hexachlorofluorescein (6-HEX)-labelled primer and a tetrachloro-6-carboxy-fluorescein (TET)-labelled primer were designed for two marker genes associated with programmed cell death in tracheary elements (TEs): an endonuclease (Zen1) and a cysteine protease (ZcP4), respectively. An additional Cyan5 (Cy5)-labelled primer was used to monitor 18SrRNA expression. As expected, the 18S signal was constitutively expressed throughout epicotyls sections and living cells in xylogenic in vitro cultures, whereas Zen1 and ZcP4 were co-localized in forming TEs both in planta and in vitro. Analogous to clustering analysis of gene expression using microarrays to elucidate common metabolic pathways and developmental processes, this novel technique is perfectly adapted to gaining a better understanding of gene function via the coordinated expression of genes in specific cell types of complex tissues and cell populations.     

Fluorescence in situ hybridization for phytoplasma and endophytic bacteria localization in plant tissues

In the present study, we developed a rapid and efficient fluorescence in situ hybridization assay (FISH) in non-embedded tissues of the model plant Catharanthus roseus for co-localizing phytoplasmas and endophytic bacteria, opening new perspectives for studying the interaction between these microorganisms.     

Distinguishing plant and fungal sequences in ESTs from infected plant tissues

Expressed sequence tags (ESTs) from fungal-infected plant tissues are composed of a mixture of plant and fungal sequences. Using freely available software and tools, a novel procedure is described for distinguishing plant and fungal DNA sequences. Although the GenBank non-redundant (NR) database is larger and therefore one would presume that BLASTX analysis of it would be more accurate, superior resolution of 700 randomly selected fungal ESTs was found with Standalone TBLASTX analyses with a local matching database composed of a plant and a fungal genome. Standalone TBLASTX analyses of 3,983 ESTs from nine different fungal-infected plant EST libraries also proved to be superior in identifying the origin of sequences as either plant or fungal compared to GenBank BLASTX analysis. Standalone TBLASTX with a matching database comprised of a single plant and a single fungal genome appears to be a faster and more accurate method than BLASTX searches of the GenBank non-redundant database to distinguish fungal and plant sequences in mixed EST collections.     

RNA extraction from plant tissues

Several protocols and commercial kits are used for the extraction of nucleic acids from different plant tissues. Although there are several procedures available to remove sugars, which hinder the extraction of clean genomic DNA, there are few to assist with extraction of RNA. Those presently used include precipitations with ethylene glycol monobutyl ether or lithium chloride (LiCl), or centrifugation in cesium chloride (CsCl) gradients, but these generally either do not allow high recovery of RNA, are time consuming, rely on hazardous chemicals or need special equipment. Here we present the use of the simple cation, Ca²⁺, which has been tested and shown to be very efficient for the precipitation of high molecular weight pectic sugars during RNA extraction. Results are presented for different plant tissues, especially tissues of peach and apple fruits at varying ripening stages.     

Dichloromethane as an economic alternative to chloroform in the extraction of DNA from plant tissues

Processing of large numbers smaples of plant tissue samples for molecular mapping and gene tagging requires methods that are quick, simple, and cheap, and that eventually can be automated. Organic solvents used for DNA extraction can represent a significant proportion of the overall cost. In this study we examined dichloromethane as a replacement for chloroform to be used in combination with phenol.