Variables Influencing Extraction of Nucleic Acids from Microbial Plankton (Viruses,Bacteria, and Protists) Collected on Nanoporous Aluminum Oxide Filters

Anodic aluminum oxide (AAO) filters have high porosity and can be manufactured with a pore size that is small enough to quantitatively capture viruses. These properties make the filters potentially useful for harvesting total microbial communities from water samples for molecular analyses, but their performance for nucleic acid extraction has not been systematically or quantitatively evaluated. In this study, we characterized the flux of water through commercially produced nanoporous (0.02 μm) AAO filters (Anotop; Whatman) and used isolates (a virus, a bacterium, and a protist) and natural seawater samples to test variables that we expected would influence the efficiency with which nucleic acids are recovered from the filters. Extraction chemistry had a significant effect on DNA yield, and back flushing the filters during extraction was found to improve yields of high-molecular-weight DNA. Using the back-flush protocol, the mass of DNA recovered from microorganisms collected on AAO filters was ≥100% of that extracted from pellets of cells and viruses and 94% ± 9% of that obtained by direct extraction of a liquid bacterial culture. The latter is a minimum estimate of the relative recovery of microbial DNA, since liquid cultures include dissolved nucleic acids that are retained inefficiently by the filter. In conclusion, we demonstrate that nucleic acids can be extracted from microorganisms on AAO filters with an efficiency similar to that achievable by direct extraction of microbes in suspension or in pellets. These filters are therefore a convenient means by which to harvest total microbial communities from multiple aqueous samples in parallel for subsequent molecular analyses.     

An adaptation of the filter paper disk technique for the differential estimation of DNA and RNA of rat liver

A method is described for the differential estimation of DNA and RNA from rat liver on filter paper disks. To differentiate between DNA and RNA, samples are subjected to alkaline hydrolysis in microtitration plates prior to absorption on the disks. This procedure eliminates the loss of DNA which is observed if the disks are subjected to RNA hydrolysis after the sample has been absorbed on disks. The procedure is directly comparable to standard methods for the measurement of nucleic acids.     

Hydroxyapatite-mediated transfer of DNA from diluted solutions to nitrocellulose or nylon membranes

Transfer of DNA (from 0.1 to 10 micrograms) from diluted solutions of variable volumes (1-10 ml) and various composition (2 M NaCl; 4 M LiCl, 8 M urea; 4 M CsCl; 20% sucrose) to nitrocellulose or nylon membranes was achieved with the use of hydroxyapatite. This absorbent that binds nucleic acids effectively and independently of ionic strength and composition of solution (except for chelators and phosphate ions) easily dissolves in small volumes of acids (for example, in 10% TCA). This phenomenon provides the opportunity to deliver the acid-insoluble precipitates to membrane filters. After alkaline denaturation on the filter followed by a fixation step (baking or UV irradiation for nitrocellulose or nylon filters, respectively), DNA hybridizes effectively with nick-translated DNA probes. The method is simple, reproducible, sensitive, and useful for working with diluted DNA solutions containing interfering substances.     

Fractionation with ethanol of nucleic acids from viroid-infected plants

A combination of high salt and low ethanol concentration allowed the fractionation of nucleic acids extracted from viroid-infected leaves. By adding 0.4-0.5 vol of ethanol to 1 vol of a solution in 2 M LiCl of nucleic acids (containing mainly DNA, 4S, 5S, 7S, and viroid RNAs), 85% of the DNA and 75% of the 4S RNA remained in solution, from where they could be recovered by increasing the ethanol concentration, whereas almost all 5S, 7S, and viroid RNAs precipitated. When this process was repeated three times a 95% elimination of the initial DNA and 4S RNA was achieved. The method can be of special interest in viroid purification considering that DNA and 4S RNA are the most abundant contaminants in the starting solution of nucleic acids. It is suggested that the highly ordered secondary structure of viroid RNA may be responsible for its particular behavior in the ethanol fractionation of nucleic acids.     

Direct nanogram quantitation of nucleic acid and protein with a continuous-flow microcell

A simple method for rapid nanogram measurement of nucleic acids and proteins is described. It requires only 5 to 10 microliter of sample solution which is injected into the postcolumn flow stream of a high-performance liquid chromatograph. Samples are analyzed by uv detection at 260 nm for nucleic acids and 280 nm for proteins with a diode array detector. Analyzing speed is two samples per minute and the amount to be analyzed ranges from 3 ng to 80 micrograms for nucleic acids and 10 ng to 80 micrograms for bovine serum albumin, irrespective of the sample volume. The method is particularly useful for fast, accurate, and trace amount measurement of purified DNA, RNA, and protein samples in small volumes.     

Purification of 5S RNA from Plant Leaves

A simple and rapid method for large scale preparation of 5S RNA from plant leaves is described. To begin, all nucleic acids were extracted from the leaves with a mixture of phenol-chloroform-n-butyl alcohol and extracting buffer. After precipitation of the high-molecular-weight nucleic acids from the crude extract with 2 M LiCl, the low, molecular-weight RNA in the supernatant (containing about 6% 5S RNA) could be separated by eleetrophoresis on denatured polyaerylamide gels. The band of 5S RNA was excised from the preparatory slab gel under UV light and then purified by eleetrophoretie elution. In our experiments, several mg pure 5S RNA was obtained from 100 g leaves in a single run which takes about 4 days. The purified final produet was pure as showing a single hand on denatured polyaerylamide gel and a typical UV absorption peak of nucleic acid. The sedimentation coefficient (S20w) of the product was 4.6 as determined by ultracentrifugation.     

Rapid preparation of total nucleic acids from E. coli for multi-purpose applications

Separate protocols are commonly used to prepare plasmid DNA, chromosomal DNA, or total RNA from E. coli cells. Various methods for the rapid preparation of plasmid DNA have been developed previously, but the preparation of the chromosomal DNA and total RNA are usually laborious. We report here a simple, fast, reliable, and cost-effective method to extract total nucleic acids from E. coli by direct lysis of the cells with phenol. Five distinct and sharp bands, which correspond to chromosomal DNA, plasmid DNA, 23S rRNA, 16S rRNA, and a mixture of small RNA, were observed when analyzing the prepared total nucleic acids on a regular 1-2% agarose gel. The simple and high-quality preparation of the total nucleic acids in a single tube allowed us to rapidly screen the recombinant plasmid, as well as to simultaneously monitor the change of the plasmid copy number and rRNA levels during the growth of E. coli in the liquid medium.     

Nucleic acid hybridization: from research tool to routine diagnostic method

The nucleic acid hybridization reaction is extremely specific and thus a valuable tool for the identification of genes or organism of interest. The increasing use of nucleic acid hybridization in applied fields like diagnostic medicine has led to the development of more convenient hybridization assays than those originally used in basic research. In conventional nucleic acid hybridization methods immobilized nucleic acids are detected on a filter by a radiolabelled probe. Sandwich hybridization is a simple test format for the analysis of unpurified biological material, but has the disadvantage of a slow reaction rate. Solution hybridization methods are fast and easy to perform provided that a method to separate the formed hybrids from the reaction mixture is available. In non-isotopic detection the nucleic acid probe is modified with a chemical group, which is identified with a labelled detector molecule after hybridization. The low sensitivity of detection is the main problem in nucleic acid hybridization methods. Procedures to amplify the detectable signal or the amount of detectable nucleic acid sequences are potential solutions to this problem. The new hybridization methods have successfully been used for some applications, but still need to be combined into well performing tests to be applicable to any desired purpose.     

Extracting nucleic acids from activated sludge which reflect community population diversity

Critical to most studies in molecular microbial ecology is the application of DNA/RNA extraction methods which can reveal the true level of population biodiversity present in samples from the community under investigation. Activated sludge communities have been studied extensively using molecular methods, but rarely have the nucleic acid isolation methods applied been assessed for their ability to achieve this. This study compares eight published RNA and DNA extraction protocols and one commercially available DNA isolation kit for their capacity to provide high quality nucleic acids that reflect the community composition. Each method was assessed on the basis of nucleic acid yield, purity and integrity, and the ability to provide PCR amplifiable RNA and DNA from known marker populations that varied in their resistance to nucleic acid extraction. Only three consistently provided DNA from each of the marker populations known to be present in the samples from fluorescence in situ hybridisation analysis. The failure of the other methods emphasises the need to validate all DNA/RNA extraction protocols. It is recommended that several validated extraction methods be used and the extracts pooled to further minimise any risk of bias.     

Isotachophoresis of nucleic acids in agarose gel rods

A new method of electrophoresis (isotachophoresis in agarose gel rods) in which nucleic acid molecules are not separated but, oppositely, are brought together into one band, was elaborated. Heterogeneous in size DNA and RNA polymers present in a few milliliters of a solution at so low concentration that their isolation by other methods is hardly attainable and fraught with losses are brought together into one visible narrow band when put in a discontinuous electric field. Polynucleotides migrate in dilute (0.1%) semifluid agarose gel that permits easy quantitative isolation of the band of interest. Resulting DNA can be used directly in PCR. The suggested method for isolation of micro amounts of nucleic acids from dilute solutions can be applied to forensic and clinical research and cancer gene diagnostics by the analysis of fragmented circulating DNA from bodily fluids.     

Real-time monitoring of nucleic acid ligation in homogenous solutions using molecular beacons

Nucleic acids ligation is a vital process in the repair, replication and recombination of nucleic acids. Traditionally, it is assayed by denatured gel electrophoresis and autoradiography, which are not sensitive, and are complex and discontinuous. Here we report a new approach for ligation monitoring using molecular beacon DNA probes. The molecular beacon, designed in such a way that its sequence is complementary with the product of the ligation process, is used to monitor the nucleic acid ligation in a homogeneous solution and in real-time. Our method is fast and simple. We are able to study nucleic acids ligation kinetics conveniently and to determine the activity of DNA ligase accurately. We have studied different factors that influence DNA ligation catalyzed by T4 DNA ligase. The major advantages of our method are its ultrasensitivity, excellent specificity, convenience and real-time monitoring in homogeneous solution. This method will be widely useful for studying nucleic acids ligation process and other nucleic acid interactions.     

内参基因加标法定量土壤微生物目标基因绝对拷贝数

【目的】通过荧光定量PCR技术对土壤微生物目标基因进行绝对定量,其定量结果的准确性容易受到DNA提取得率以及腐殖酸抑制性的影响。【方法】采用内参基因加标法,利用构建的突变质粒DNA,对供试水稻土壤样品中的微生物16S r RNA目标基因的绝对拷贝数进行荧光定量PCR检测,用来表征该样品中细菌群落总体丰度。在定量前通过双向引物扩增方法验证突变质粒中的内参基因对供试土壤的特异性。【结果】不同水稻土壤样品的DNA提取量在样品间差异较大。通过内参基因加标法对DNA提取量进行校正,显著提高了16S r RNA基因绝对定量的精确度。不同水稻土壤样品间的变异系数为17.8,与未加标处理相比降低了66.7%。在此基础上,进一步通过内参基因加标法对土壤有机质和含水率均呈现典型空间特征差异的6处亚热带湿地土壤样品中的16S r RNA基因进行绝对定量。16S r RNA基因绝对拷贝数与土壤微生物生物量碳具有显著的线性相关性(R2=0.694,P0.001),表明内参校正后的16S r RNA基因绝对拷贝数可以准确反映单位质量土壤中微生物的丰度。【结论】内参基因加标法可以对DNA提取得率以及腐殖酸对PCR扩增的抑制性进行校正,从而提高绝对定量的准确性。基于内参基因加标法的目标基因绝对定量PCR检测,可作为土壤微生物生物量测量,以及微生物功能基因绝对丰度定量的一种核酸检测方法。     

Concentration and isolation of DNA from biological fluids by agarose gel isotachophoresis

Isotachophoresis is an electrophoretic method of separation of charged substances. The method is characterized by a discontinuous buffer system, constant velocity of separated molecules, and the distribution of separated components in the form of narrow concentrated bands located one right after another. As a rule, isotachophoresis is not used for the separation of nucleic acids because the mobility of polynucleotides in this system does not depend on their size. However, this circumstance proved to be very useful for the quantitative isolation of heterogeneous DNA fragments from biological fluids, for gene diagnostics of cancer in particular. The proposed method of agarose gel isotachophoresis of DNA has been used for the isolation of blood DNA and its successful PCR analysis.     

Size-dependent chromatographic separation of nucleic acids

Chromatographic procedures currently used for the size-dependent fractionation of nucleic acids are reviewed. First, an attempt is made to clarify the concept of “size” of nucleic acids and then various aspects of the chromatography of nucleic acids are considered. It is emphasized that consideration of the dynamic three-dimensional structure of large polynucleotides in a rapidly flowing eluent is essential for both the better understanding of mechanism and the development of sophisticated procedures. Of the practical chromatographic techniques that are not based on true size fractionation, ion-exchange chromatography on non-porous column packings appears to be the most efficient. Other methods, such as hydrophobic interaction, are unlikely to become popular. As for truly size-dependent modes, there are gel permeation and slalom chromatography. Although media with extremely large pores become available, the efficiency of gel permeation is still low as a practical separation procedure for large nucleic acid molecules. Its best use seems to be in the field of physicochemical research into nucleic acids in solution. The newly discovered slalom chromatography is based on a principle completely different from all other chromatographic modes. It enables the efficient separation of large double-stranded DNA fragments of 5–50 kilo base pairs by discriminating their length. It has proved not only to be useful as a tool for nucleic acid research but also to have great significance in other fields, e.g. the hydrodynamics of polymer solutions, the search for new chromatographic modes, etc.