Rapid High Quality RNA Preparation from Pine Seedlings

Conventional RNA extraction methods have been shown to produce poor quality RNA when applied to pine and other gymnosperms. We present a protocol for extracting highly pure RNA from pine. Modifications to conventional procedures include: 1) the use of seedlings, 2) the use of phenol and PVP to rapidly remove DNA, proteins and pigments, and 3) the use of salt precipitation to remove other contaminating compounds. The procedure can be completed in less than eight hours. Yield and purity were monitored by denaturing gel electrophoresis and by UV absorbance (A₂₆₀ /A₂₈₀ and A₂₆₀/A₂₃₀). These ratios were over 2, indicating an absence of contaminating metabolites. Additionally, a new absorbance ratio (A₂₆₀/A₂₁₀) was introduced to monitor the RNA purity in each step (it indicates the ratio of covalent links in the solution belonging to RNA). The yield was around 300 µg total RNA per gram of tissue of Pinus sylvestris and over 400 µg of total RNA per gram of P. pinaster tissue, which is a high recovery (more than 63%) for gymnosperms. The RNA was of sufficient quality for use in a RT-PCR reaction that amplified 1 kb of the pine GS gene. This protocol has been applied with success to other woody plants like Populus species.Abbreviations: DEPC, diethyl pyrocarbonate; AMV, avian myeloblastosis virus; FW, fresh weight.     

Control of in vivo protein synthesis and peroxidase formation by DNA-containing extracts of normal and crown gall tissues

Nucleic acids extracted from normal bean hypocotyl tissue (NE) and crown gall tumors (TE) affect amino acid incorporation into protein and the development of peroxidase activity when vacuum infiltrated into normal receptor tissues. TE enhances and NE inhibits both processes; NE from successively older tissues produces progressively greater inhibitions per unit of infiltrated nucleic acid. The active material has an absorption maximum at 257 nm with an A_260:280 ratio of more than 2·0. On acrylamide gel electrophoresis it shows a small DNA peak, four typical r-RNA peaks and a small low molecular weight RNA peak. Activity in such extracts is completely destroyed by hydrolysis with 0·3 N KOH or DNAase; RNAase is only slightly effective and pronase ineffective. It is deduced that the effective material contains DNA that may be complexed with RNA or other materials in the extract. Pretreatment of donor tissues with actinomycin d or 5-fluorouracil diminishes or annuls the activity of the extract. Pretreatment of receptor tissue with actinomycin d inhibits the action of TE but not of NE; pretreatment with cycloheximide prevents the action of both NE and TE.     

Rapid Colorimetric Assays to Qualitatively Distinguish RNA and DNA in Biomolecular Samples

Biochemical experimentation generally requires accurate knowledge, at an early stage, of the nucleic acid, protein, and other biomolecular components in potentially heterogeneous specimens. Nucleic acids can be detected via several established approaches, including analytical methods that are spectrophotometric (e.g., A₂₆₀), fluorometric (e.g., binding of fluorescent dyes), or colorimetric (nucleoside-specific chromogenic chemical reactions).¹ Though it cannot readily distinguish RNA from DNA, the A₂₆₀/A₂₈₀ ratio is commonly employed, as it offers a simple and rapid² assessment of the relative content of nucleic acid, which absorbs predominantly near 260 nm and protein, which absorbs primarily near 280 nm. Ratios < 0.8 are taken as indicative of ''pure'' protein specimens, while pure nucleic acid (NA) is characterized by ratios > 1.5³.However, there are scenarios in which the protein/NA content cannot be as clearly or reliably inferred from simple uv-vis spectrophotometric measurements. For instance, (i) samples may contain one or more proteins which are relatively devoid of the aromatic amino acids responsible for absorption at ≈280 nm (Trp, Tyr, Phe), as is the case with some small RNA-binding proteins, and (ii) samples can exhibit intermediate A₂₆₀/A₂₈₀ ratios (~0.8 < ~1.5), where the protein/NA content is far less clear and may even reflect some high-affinity association between the protein and NA components. For such scenarios, we describe herein a suite of colorimetric assays to rapidly distinguish RNA, DNA, and reducing sugars in a potentially mixed sample of biomolecules. The methods rely on the differential sensitivity of pentoses and other carbohydrates to Benedict''s, Bial''s (orcinol), and Dische''s (diphenylamine) reagents; the streamlined protocols can be completed in a matter of minutes, without any additional steps of having to isolate the components. The assays can be performed in parallel to differentiate between RNA and DNA, as well as indicate the presence of free reducing sugars such as glucose, fructose, and ribose (Figure 1).     

DNA and protein content of mouse sperm: Implications regarding sperm chromatin structure

A variety of biochemical and histochemical techniques have been used to compare the composition of chromatin in sperm nuclei isolated from the epididymides of five mouse strains. The DNA content was determined by phosphorus analysis, deoxyribose analysis, absorption spectroscopy at 260 nm, and cytomorphometry following gallocyanine chrome alum staining. All four methods indicate that the mouse sperm nucleus contains approx. 3.3 pg DNA and that the DNA content does not vary significantly among the strains tested. Three different techniques, quantitative amino acid analysis, absorption spectroscopy at 230 nm, and sperm head density analysis in cesium chloride, were used to determine the protein content. Sperm nuclei from each strain of mouse were found to have a protein to DNA ratio of 0.9 and a chromatin protein content of 3 pg/nucleus. Comparisons of the basic proteins by disc gel electrophoresis demonstrate that the sperm nuclei contain only protamine and lack significant levels of somatic histones or transition proteins. The sperm from each strain contained both mouse protamine variants and the relative distribution of the two proteins did not appear to differ among strains. Using this information, we have been able to draw certain conclusions regarding DNA-protamine interactions and the mode of DNA packaging in the sperm nucleus. The most important of these is that the DNA in the mouse sperm nucleus cannot be packaged in nucleosomes. The protamines in sperm chromatin do not function as structural proteins, providing a subunit core around which the DNA is wrapped, but appear to completely neutralize the phosphodiester backbone of the DNA molecule, thereby minimizing the repulsion between neighboring segments of DNA and allowing it to be condensed into a biochemically inactive particle of genetic information.     

Genomic DNA extraction from<Emphasis Type="Italic">Victoria amazonica</Emphasis>

DNA extraction is difficult in many plants because of metabolites that interfere with DNA isolation procedures and subsequent applications such as DNA restriction, amplification, and cloning. We developed the first reliable and efficient method for isolatingVictoria amazonica genomic DNA that is free from polysaccharides and polyphenols. This protocol uses 1.5 M NaCl, 2% polyvinylpyrrolidone (PVP) (Mr 1000), 5% mercaptoethanol, 0.12% sodium sulfite, and an incubation at 65°C for 4 h. The purity of isolated genomic DNA was confirmed by means of high-performance liquid chromatography (HPLC) profile and spectrophotometric analyses (A_260/230 ratio of 1.836, A_260/280 of 1.842). DNA was obtained in the amount of 387 μg per gram of leaf material, and it proved amenable to restriction digestion.     

Revisiting absorbance at 230 nm as a protein unfolding probe

Thermodynamic stability and unfolding kinetics of proteins are typically determined by monitoring protein unfolding with spectroscopic probes, such as circular dichroism (CD) and fluorescence. UV absorbance at 230 nm (A₂₃₀) is also known to be sensitive to protein conformation. However, its feasibility for quantitative analysis of protein energetics has not been assessed. Here we evaluate A₂₃₀ as a structural probe to determine thermodynamic stability and unfolding kinetics of proteins. By using Escherichia coli maltose binding protein (MBP) and E. coli ribonuclease H (RNase H) as our model proteins, we monitored their unfolding in urea and guanidinium chloride with A₂₃₀. Significant changes in A₂₃₀ were observed with both proteins on unfolding in the chemical denaturants. The global stabilities were successfully determined by measuring the change in A₂₃₀ in varying concentrations of denaturants. Also, unfolding kinetics was investigated by monitoring the change in A₂₃₀ under denaturing conditions. The results were quite consistent with those determined by CD. Unlike CD, A₂₃₀ allowed us to monitor protein unfolding in a 96-well microtiter plate with a UV plate reader. Our finding suggests that A₂₃₀ is a valid and convenient structural probe to determine thermodynamic stability and unfolding kinetics of proteins with many potential applications.     

Purification and Properties of the Geminivirus Euphorbia Mosaic Virus

Euphorbia mosaic virus was purified from infected plants of Nicotiana benthamiana. Highest concentrations of virus particles were found in infected plant tissue between 10–12 days after inoculation. The enzyme driselase assisted in purification of the virus particles from the infected tissue yielding about 600 μg/kg of plant material. Purified preparations showed a maximum absorption at 260–263 nm and the ratio of absorption at 260 and 280 nm was 1.4. The viral nucleic acid was digestedby DNase I and S₁ Nuclease but not RNase A. A single coat protein with a MW of 32,000 d and two DNA bands with a MW 0.96 × 10⁶ d (2870 nucleotides) and 0.90 × 10⁶ d (2700 nucleotides) were associated with the purified virus particles. Virus specific DNA was isolated from infected tissue between 7 and 15 days after inoculations.     

OPTIMIZATION OF DNA EXTRACTION FROM BROWN ALGAE (PHAEOPHYCEAE) BASED ON A COMMERCIAL KIT1

Large‐scale DNA molecular studies require reliable and efficient tools for DNA extractions. However, for some plant species and brown algae, isolation of high‐quality DNA is difficult. We developed a novel method for isolating high‐quality DNA from the polysaccharide‐rich and polyphenol‐rich brown algae based on a commercial kit and protocol (Qiagen) by optimizing the lysis step and including a chloroform/isoamyl alcohol supplementary purification step. DNAs from 24 brown algal species extracted using the original and the modified Qiagen protocol were compared for yield, quality, and effectiveness in PCR amplification. There was no significant difference in the yields between protocols. However, a statistically significant increase in DNA purity was obtained with the modified protocol, for which the A₂₆₀/A₂₈₀ and A₂₆₀/A₂₃₀ absorbance ratios averaged 1.66 ± 0.05 and 1.31 ± 0.01, respectively, compared to 1.37 ± 0.04 and 0.52 ± 0.04 with the original protocol. DNAs extracted by the modified procedure were more successfully amplified by PCR (nuclear, mitochondrial, and chloroplastic regions) than DNAs extracted using the original commercial kit and protocol. Importantly, the modified protocol can be applied in a high‐throughput (e.g., 96‐well plate) format, allowing a higher efficiency for downstream molecular analysis. In addition, improved DNA quality could increase its stability for long‐term storage.     

Evaluating genomic DNA extraction methods from human whole blood using endpoint and real-time PCR assays

The extraction of genomic DNA is the crucial first step in large-scale epidemiological studies. Though there are many popular DNA isolation methods from human whole blood, only a few reports have compared their efficiencies using both end-point and real-time PCR assays. Genomic DNA was extracted from coronary artery disease patients using solution-based conventional protocols such as the phenol–chloroform/proteinase-K method and a non-phenolic non-enzymatic Rapid-Method, which were evaluated and compared vis-a-vis a commercially available silica column-based Blood DNA isolation kit. The appropriate method for efficiently extracting relatively pure DNA was assessed based on the total DNA yield, concentration, purity ratios (A₂₆₀/A₂₈₀ and A₂₆₀/A₂₃₀), spectral profile and agarose gel electrophoresis analysis. The quality of the isolated DNA was further analysed for PCR inhibition using a murine specific ATP1A3 qPCR assay and mtDNA/Y-chromosome ratio determination assay. The suitability of the extracted DNA for downstream applications such as end-point SNP genotyping, was tested using PCR-RFLP analysis of the AGTR1-1166A>C variant, a mirSNP having pharmacogenetic relevance in cardiovascular diseases. Compared to the traditional phenol–chloroform/proteinase-K method, our results indicated the Rapid-Method to be a more suitable protocol for genomic DNA extraction from human whole blood in terms of DNA quantity, quality, safety, processing time and cost. The Rapid-Method, which is based on a simple salting-out procedure, is not only safe and cost-effective, but also has the added advantage of being scaled up to process variable sample volumes, thus enabling it to be applied in large-scale epidemiological studies.     

Rapid and efficient extraction of genomic DNA from differentphytopathogenic fungi using DNAzol reagent

A modified procedure using the commercial DNAzol reagent was successfully applied to extract genomic DNA from 25 fungal species. The DNA yield varied from 306 to 1,927 g g^-1 dry mycelia and the A₂₆₀/A₂₈₀ ratio from 1.59 to 1.93. Compared with the method of J.L. Cenis (Nucleic Acids Res. 1992, 20: 2380) this procedure generated a higher DNA yield from 17 species and a higher A₂₆₀/A₂₈₀ ratio from 23 species. But for four species, Cenis (1992) method was more suitable. No inhibitor of polymerase chain reaction was evident for the DNA extracted by the modified procedure, whereas some inhibitors remained in DNA of eight species extracted by the previous method.Revisions requested 8 September 2004; Revisions received 1 November 2004     

RNA-free DNA Extraction Protocol from PinusTissues for Molecular Biology or HPCE/HPLC Analyses

A simple method for extracting DNA from various in vitro or ex vitro Pinus tissues is described. Good yield and high quality RNA-free DNA ready to use in molecular biology assays or analytical analysis was obtained. DNA quality was measured analyzing absorption spectra between 200 and 300 nm, A_260/280 ratio and HPCE. This protocol was tested with no modification in a wide range of Pinus tissues from recalcitrant in vitro callus to mature field scions improving the results obtained with previous protocols. As the protocol is simple, almost universal and inexpensive it may be used for routine isolation from Pinus tissues. An isolation troubleshooting table was included to facilitate the setting up of reported protocol to other plant species.     

Efficient isolation of high quality nucleic acids from different tissues of <Emphasis Type="Italic">Taxus baccata</Emphasis> L.

Improved and efficient methods were developed for isolating high quality DNA and RNA from different sources of Iranian Yew (Taxus baccata L.). The methods were based on CTAB extraction buffer added with high levels of polyvinylpyrrolidone (PVP) and β-mercaptoethanol to properly remove polysaccharides and prevent oxidation of phenolics. The pellets obtained by ethanol precipitation were washed only with Chloroform: isoamyl alcohol (24:1). So, we could successfully eliminate the dangerous phenol/chloroform extraction steps from the isolation procedure. Both spectrophotometric (A₂₆₀/A₂₈₀ and A₂₆₀/A₂₃₀ ratios) and agarose electrophoresis analysis of isolated nucleic acids (DNA and RNA) indicated good results. DNA with the average yield of 100–300 μg/g leaf and stem tissue and total RNA with an average yield of 20–30 μg/g cell culture and 80–100 μg/g leaf and stem tissue of Iranian yew could be obtained. Successful amplification of pam and pds by PCR and RT-PCR, showed the integrity of isolated DNA and RNA, respectively.     

Rapid,High Quality DNA Isolation from Cypress (Cupressus sempervirens L.) Needles and Optimization of the RAPD Marker Technique

A protocol for extracting high quality DNA from cypress (Cupressus sempervirens L.), a gymnosperm of economic and ecological importance to the Mediterranean, is presented using the commercially supplied DNeasy^TM Plant Mini Kit (QIAGEN GmbH, Germany). Additional steps were introduced in the QIAGEN protocol to significantly enhance DNA quantity and quality. For one sample, the procedure can be completed in less than one hour, and more than 10 samples can be processed in a day. DNA yield and purity were monitored by gel electrophoresis and by determining absorbance at UV (A₂₆₀/A₂₈₀ and A₂₆₀/A₂₃₀). Both ratios were between 1.7 and 2.0, indicating that the presence of contaminating metabolites was minimal. The average DNA yield obtained from 100 mg starting material was around 22 g, which compares very favorably with numbers indicated by the manufacturer. Additionally, restriction and PCR analyses of the extracted DNA showed its compatibility with downstream applications. Using this DNA, the parameters for the randomly amplified polymorphic DNA (RAPD) protocol were optimized based on the use of (1) an AmpliTaq^® DNA Polymerase, Stoffel fragment (Perkin-Elmer), and (2) a high initial denaturation temperature (97.5 °C). Reproducible amplification products were achieved in all PCR reactions. Seven to eight bands per primer were obtained with most individuals. This represents a number at the high end of published results with other plant species.     

Mechanical Transmission, Purification and Properties of an Isolate of Maize Stripe Virus from Venezuela

A Venezuelan isolate of maize stripe virus (MStpV) was successfully transmitted mechanically and by the leafhopper Peregrinus maidis from field infected plants to sweet cv. Iochief. After purification of maize infected with MStpV, fine spiral filamentous particles about 4 nm in diameter and with variable lengths were consistently associated with a nucleoprotein band present in CsCl or Cs₂SO₄ isopycnic gradients. Purified preparations exhibited a typical nucleoprotein absorption spectrum with a maximum at 260–263 nm and a minimum at 240–243 nm and a 260–280 ratio of 1.38. The density of the nucleoprotein in CsCl gradients was estimated at 1.29 g/ml. The sedimentation coefficient was calculated at 62 S. The nucleoprotein consisted of 5 % single stranded RNA and a capsid protein of molecular weight 33.500 daltons. Large quantities of non-capsid proteins were isolated from infected tissue with a molecular weight of 17.500 and 16.500 daltons. Peregrinus maidis, injected with purified MStpV preparation failed to transmit the disease to healthy plants. However, they were infectious when injected with clarified infected plant sap. Antisera against capsid and non-capsid proteins from MStpV-Florida strain reacted positively with the Venezuelan antigens.     

Comparisons of direct extraction methods of microbial DNA from different paddy soils

Molecular analyses for the study of soil microbial communities often depend on the direct extraction of DNA from soils. The present work compares the effectiveness of three different methods of extracting microbial DNA from seven different paddy soils. Comparison among different DNA extraction methods against different paddy soil samples revealed a marked variation in DNA yields from 3.18–20.17 μg DNA/g of dry soil. However, irrespective of the soil samples and extraction methods the DNA fragment size was >10 kb. Among the methods evaluated, method-C (chemical–enzymatic–mechanical) had better cell lysis efficiency and DNA yield. After purification of crude DNA by Purification Kit, A₂₆₀/A₂₃₀ and A₂₆₀/A₂₈₀ ratios of the DNA obtained by method-C reached up to 2.27 and 1.89, respectively, sustaining the efficacy of this technique in removing humic acid, protein and other contaminants. Results of the comprehensive evaluation of DNA extraction methods suggest that method-C is superior to other two methods (chemical–enzymatic and chemical–mechanical), and was the best choice for extraction of total DNA from soil samples. Since soil type and microbial community characteristics influence DNA recovery, this study provides guidance for choosing appropriate extraction and purification methods according to experimental goals.     

Use of the diaminobenzoic acid fluorescence assay in conjunction with uv absorbance as a means of quantifying and ascertaining the purity of a DNA preparation

In the course of a study conducted to determine the correlation between covalently bound DNA-ethyl adducts and specific locus mutation induction in maize (W. E. Schy and M. J. Plewa Mutat. Res., 211, 231-241), it was necessary to accurately quantify and ascertain the purity of small amounts of DNA isolated from germinating maize kernels. DNA was purified from leaf primordial tissue that was dissected from germinating maize kernels and quantified by measuring its absorbance at 260 nm. Its absorbance at 260 nm relative to its absorbance at 280 nm (A260/A280 ratio) fell within the range of values that indicated a pure preparation. An attempt to verify the quantity of DNA using a second independent method specific for DNA, the diaminobenzoic acid dihydrochloride fluorescence assay, revealed a significant discrepancy between the two methods. The difference appeared to result from impurities present within the DNA preparation, despite a A260/A280 ratio that indicated otherwise. We found the A260/A280 ratio to be a poor indicator of the purity of DNA preparations, and determined that significant error may result from quantifying DNA using spectrophotometric methods alone. We propose as an alternative, quantifying DNA using the diaminobenzoic acid dihydrochloride assay in conjunction with uv absorbance at 260 nm and using a FLUOR/A260 ratio as an indicator of DNA purity.