A robust universal method for extraction of genomic DNA from bacterial species

The intactness of DNA is the keystone of genome-based clinical investigations, where rapid molecular detection of life-threatening bacteria is largely dependent on the isolation of high-quality DNA. Various protocols have been so far developed for genomic DNA isolation from bacteria, most of which have been claimed to be reproducible with relatively good yields of high-quality DNA. Nonetheless, they are not fully applicable to various types of bacteria, their processing cost is relatively high, and some toxic reagents are used. The routine protocols for DNA extraction appear to be sensitive to species diversity, and may fail to produce high-quality DNA from different species. Such protocols remain time-consuming and tedious, thus to resolve some of these impediments, we report development of a very simple, rapid, and high-throughput protocol for extracting of high-quality DNA from different bacterial species. Based upon our protocol, interfering phenolic compounds were removed from extraction using polyvinylpyrrolidone (PVP) and RNA contamination was precipitated using LiCl. The UV spectrophotometry and gel electrophoresis analysis resulted in high A ₂₆₀/A ₂₈₀ ratio (>1.8) with high intactness of DNA. Subsequent evaluations were performed using some quality-dependent techniques (e.g., RAPD marker and restriction digestions). The isolated DNA from 9 different bacterial species confirmed the accuracy of this protocol which requires no enzymatic processing and accordingly its low-cost making it an appropriate method for large-scale DNA isolation from various bacterial species.     

Rapid and reliable extraction of genomic DNA from various wild-type and transgenic plants

Background  

DNA extraction methods for PCR-quality DNA from calluses and plants are not time efficient, since they require that the tissues be ground in liquid nitrogen, followed by precipitation of the DNA pellet in ethanol, washing and drying the pellet, etc. The need for a rapid and simple procedure is urgent, especially when hundreds of samples need to be analyzed. Here, we describe a simple and efficient method of isolating high-quality genomic DNA for PCR amplification and enzyme digestion from calluses, various wild-type and transgenic plants.     

Extraction of adenine nucleotides from cultured endothelial cells

The goal of this work was to find a method suitable for the extraction of adenine nucleotides from cultured vascular endothelial cells. Extraction of cell monolayers with 80% methanol in water yielded extracts with a higher content of ATP than did extraction of cells with perchloric acid, trichloroacetic acid, or boiling water. The optimal extraction solution was 80% methanol with 0.5 mM ethylene glycol bis(beta-aminoethyl ether) N,N'-tetraacetic acid (EGTA) or EDTA, heated to 70 degrees C immediately before use. Extraction of nucleotides by this solution was rapid and the recovery of exogenous ATP added during the extraction process was generally greater than 90%. An aqueous methanol or ethanol solution may be applicable for the extraction of nucleotides and other metabolites from cultured animal cells, dispersed cells, and frozen, powdered tissues.     

Methacarn fixation for genomic DNA analysis in microdissected, paraffin-embedded tissue specimens.

We recently found methacarn to be a versatile fixative for analysis of RNA and protein applicable for microdissected specimens from paraffin-embedded tissue (PET). In this study we investigated the performance of methacarn for genomic DNA analysis using microdissected rat tissues. We found that extensive portions of DNA up to 2.8 kb could be amplified by nested PCR using DNA templates extracted by a simple and rapid extraction procedure from a 1 x 1-mm area of cerebral cortex of a 10-microm-thick section. By nested PCR, a 522-bp fragment from a single cell could be amplified in 20% of cresyl violet-stained Purkinje cells, and the minimal number of cells required, as estimated using hippocampal neurons, was on the order of 10-20. Although tissue staining with hematoxylin and eosin affected the PCR, amplification of a 522-bp fragment was successful, with 150-270 cells by 35 cycles of single-step PCR. Immunostaining resulted in a substantial decrease of yield and degradation of extracted DNA. However, even after immunostaining, a 184-bp DNA fragment could be amplified with 150-270 cells by 35 cycles of PCR. The results thus demonstrate the superior performance of methacarn to that reported with formalin in genomic DNA analysis using microdissected PET specimens.     

High-efficiency transformation of Saccharomyces cerevisiae cells by bacterial minicell protoplast fusion.

After a new transformation procedure, 10% of Saccharomyces cerevisiae cells were found to contain transforming DNA sequences. We used direct transfer of plasmid molecules by fusing bacterial minicell protoplasts to yeast protoplasts. Since the procedure significantly reduces the toxic effect of procaryotic protoplasm on the eucaryotic organism, it might be generally applicable in other systems in which transformation is inefficient or impossible.     

基于PCR DGGE的小鼠肠道菌群基因组提取方法的建立

通过比较4种小鼠粪便细菌总DNA提取方法对基于PCR-DGGE检测的肠道菌群多样性分析的影响,旨在建立适于PCR—DGGE的小鼠肠道微生物宏基因组提取的稳定、经济、快捷的方法。采用SDS裂解法、某国产市售粪便DNA提取试剂盒、改进的化学裂解法、改进的溶菌酶法4种方法提取小鼠粪便细菌总DNA,通过琼脂糖凝胶电泳、紫外分光光度法、细菌16S rRNAV3区PCR扩增结合DGGE对提取结果进行比较分析。SDS裂解法和国产市售试剂盒2种方法提取粪便细菌总DNA均未得到理想结果,另2种方法均能够检测到粪便中20种左右的细菌。改进的化学裂解法和改进的溶菌酶提取法的建立为基于PCR—DGGE进行肠道菌群结构的定量及定性分析提供了可靠的前提基础和实验保障。     

An improved method for extracting bacteria from soil for high molecular weight DNA recovery and BAC library construction

Separation of bacterial cells from soil is a key step in the construction of metagenomic BAC libraries with large DNA inserts. Our results showed that when combined with sodium pyro-phosphate and homogenization for soil dispersion, sucrose density gradient centrifugation (SDGC) was more effective at separating bacteria from soil than was low speed centrifugation (LSC). More than 70% of the cells, along with some soil colloids, were recovered with one round of centrifugation. A solution of 0.8% NaCl was used to resuspend these cell and soil pellets for purification with nycodenz density gradient centrifugation (NDGC). After purification, more than 30% of the bacterial cells in the primary soil were extracted. This procedure effectively removed soil contamination and yielded sufficient cells for high molecular weight (HMW) DNA isolation. Ribosomal intergenic spacer analysis (RISA) showed that the microbial community structure of the extracted cells was similar to that of the primary soil, suggesting that this extraction procedure did not significantly change the the soil bacteria community structure. HMW DNA was isolated from bacterial cells extracted from red soil for metagenomic BAC library construction. This library contained DNA inserts of more than 200 Mb with an average size of 75 kb.     

Mini-scale Genomic DNA Extraction from Cotton

Large amounts of polyphenolics in cotton leaves make it difficult to obtain high-quality genomic DNA during extraction. A procedure to isolate nuclear DNA from local cotton leaves (gossypium hirsutum, MNH93, CIM443, FH672) was therefore developed. It consists of rapid isolation of stable nuclei, which hinders covalent interactions with phenolics, followed by DNA extraction. The yield and quality of the resulting DNA is satisfactory and the protocol can be scaled up or down according to sample size. It is suitable for PCR and the restriction enzyme digestion needed for Southern and RFLP analysis.     

临床标本细菌基因组DNA提取方法探讨

目的优化细菌基因组DNA提取方法,使其适合临床细菌分子生物学检测需要。方法分别采用专用DNA提取液法、热裂解法、溶菌酶法、热裂解法与碱性裂解法组合改良法,对纯培养细菌和临床标本中细菌基因组DNA进行提取。结果专用DNA提取液法、溶菌酶法提取成功率为100%,热裂解法革兰阳性菌提取成功率为0%,革兰阴性菌成功率为100%,碱性裂解液法在NaOH浓度大于4 mmol时提取成功,临床标本在NaOH溶液超过20 mmol/L并含2%SDS时细菌基因组DNA的提取成功率为100%。结论热裂解法与碱性裂解法组合改良法提取细菌基因组DNA方便快速、简单实用,适用临床标本检测。     

Genomic DNA extraction from medicinal plants available in Malaysia using a TriOmic(TM) improved extraction kit

DNA extraction was carried out on 32 medicinal plant samples available in Malaysia using the TriOmic(TM) extraction kit. Amounts of 0.1 g flowers or young leaves were ground with liquid nitrogen, lysed at 65°C in RY1(plus) buffer and followed by RNAse treatment. Then, RY2 buffer was added to the samples and mixed completely by vortexing before removal of cell debris by centrifugation. Supernatants were transferred to fresh microcentrifuge tubes and 0.1 volume RY3 buffer was added to each of the transferred supernatant. The mixtures were applied to spin columns followed by a centrifugation step to remove buffers and other residues. Washing step was carried out twice by applying 70% ethanol to the spin columns. Genomic DNA of the samples was recovered by applying 50 μL TE buffer to the membrane of each spin column, followed by a centrifugation step at room temperature. A modification of the TriOmic(TM) extraction procedure was carried out by adding chloroform:isoamyl alcohol (24:1) steps in the extraction procedure. The genomic DNA extracted from most of the 32 samples showed an increase of total yield when chloroform:isoamyl alcohol (24:1) steps were applied in the TriOmicTM extraction procedure. This preliminary study is very important for molecular studies of medicinal plants available in Malaysia since the DNA extraction can be completed in a shorter period of time (within 1 h) compared to manual extraction, which entails applying phenol, chloroform and ethanol precipitation, and requires 1-2 days to complete.     

Long-term room temperature storage of high-quality embryonic stem cell genomic DNA extracted with a simple and rapid procedure.

A very simple procedure for the isolation of high-quality, high-molecular-weight genomic DNA from embryonic stem cells is described. The DNA is very stable once dried and can be stored for long periods of time without refrigeration. Living cells are lysed in a sodium dodecyl sulfate and EDTA buffer containing proteinase K and then air-dried. Samples can be processed in bulk, and an individual can easily process thousands of samples for extraction and shipment on a daily basis using only common laboratory materials such as plastic ware and a multichannel pipetteman.     

Simultaneous and rapid isolation of bacterial and eukaryotic DNA and RNA: a new approach for isolating DNA.

A very simple procedure for the simultaneous preparation of genomic DNA and total RNA is described. The procedure is essentially the same for eukaryotes and prokaryotes except for the lysis buffer and can be used for small or large numbers of cells. Mammalian cells are lysed in sodium dodecyl sulfate and bacterial cells are lysed in Triton X-100, both in the presence of EDTA. RNA is obtained in the aqueous phase after phenol (acidic pH):chloroform:isoamyl alcohol extraction. DNA is eluted out of the organic phase (and the interface) into the aqueous phase by increasing the pH with highly basic 1 M Tris solution. The method is extremely rapid for small or large numbers of cells, and several large samples can be processed in one day. The qualities of both nucleic acids are excellent and the yield is high.     

A rapid microscale technique for isolation of recombinant plasmid DNA suitable for restriction enzyme analysis

A simple and rapid microscale technique is described for the isolation of plasmid DNA which involves cell lysis with phenol, centrifugation, phenol extraction, ethanol precipitation, and RNase digestion. The plasmid DNA is of suitable purity and quantity for multiple restriction endonuclease digestions and bacterial transformations. This “miniprep” procedure is applicable for a variety of types of plasmids ranging in size from 2900 to 18,400 base pairs (bp) and for a number of Escherichia coli strains. The plasmids are rapidly cleaved by all restriction enzymes (total of 14) tested to date. Recombinant clones have been screened for insertions as small as 10 bp and as large as 5000 bp. The procedure takes ~3 h and has been routinely used to simultaneously analyze 24 candidate clones. This procedure is reliable and useful for rapid screening of recombinant DNA candidates where analysis by restriction endonuclease digestion is necessary.     

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.     

Electroporation-mediated transfection of mammalian cells with crude plasmid DNA preparations

We designed a simple and reproducible electroporation-mediated transfection procedure with which to screen mammalian expression vector-constructed cDNA libraries. Using a specific chamber composed of five parallel electrodes, the recipient cells can be electroporated separately with 40 plasmid DNA preparations in a single experiment. Over 300 crude plasmids prepared from E. coli (DH-5) carrying a pcD2neo-vector-derived cDNA library were tested. The efficiency of stable transfection by electroporation with crude plasmid DNA preparations was 10-times higher than with the CsCl-purified plasmid DNA. When the crude plasmids were digested with RNase, the efficiency of stable transfection markedly decreased, indicating that the contaminating bacterial RNA in the crude plasmid preparations has a strong carrier effect during the electroporation. Even when salmon sperm DNA or genomic DNA from the recipient cells was used as the carrier of the purified plasmid, the efficiency was not higher than that using the crude preparations. This procedure is useful not only for screening a number of cDNAs but also for routinely introducing biologically active foreign genes into cultured mammalian cells.     

A simple procedure for the preparation of pure kinetoplast DNA network free of nuclear DNA from the kinetoplast hemoflagellate Leishmania donovani

A simple, inexpensive procedure for preparing pure kinetoplast DNA network from Leishmania donovani is described. L. donovani promastigotes were lysed by incubating with pronase in presence of sodium dodecylsulfate. Crude kinetoplast DNA networks were obtained by centrifugation of the lysate through a 20% sucrose solution. The pellet containing kinetoplast DNA was deproteinized by phenol extraction. Contaminating nuclear DNAs were removed by denaturation with alkali, neutralization, and addition of polyethylene glycol-8000 to a concentration of 10% to facilitate precipitation of kinetoplast DNA. kDNA isolated after centrifugation was deproteinized several times with phenol and finally precipitated with ethanol. The average yield by this procedure is 30-50 micrograms of kDNA per gram of wet cells. By slot-blot hybridization with a nuclear DNA probe, no nuclear DNA contamination of the kDNA networks could be detected.     

Direct construction of a chromosome-specific NotI linking library from flow-sorted chromosomes.

A linking library consists of genomic DNA fragments which contain a specific rare restriction enzyme site; such clones are very useful as probes in pulsed field gel electrophoresis and in mapping and cloning large regions of DNA. However, identifying those linking clones which map to a certain chromosomal region can be laborious. Therefore, we have developed a straightforward procedure for constructing a linking library directly from flow-sorted chromosomes. As a test of the approach, a NotI linking library was constructed from the chromosome 17 fraction of a flow-sort of human chromosomes, using only 70 ng of DNA. Thirteen of sixteen linking clones were mapped to chromosome 17, suggesting that the library is highly enriched for this chromosome. This method should be generally applicable to other chromosomes and enzymes as well.     

A rapid method for extracting DNA from agarose gels

A method for obtaining high recovery of deoxyribonucleic acid (DNA) from agarose gels using an agarase extraction procedure is presented. This DNA is physically intact and biologically active. The DNA obtained with this procedure should be useful for a wide range of applications.     

A rapid and inexpensive method for isolation of total DNA from Trichoderma spp (Hypocreaceae)

Extraction of high-quality genomic DNA for PCR amplification from filamentous fungi is difficult because of the complex cell wall and the high concentrations of polysaccharides and other secondary metabolites that bind to or co-precipitate with nucleic acids. We developed a modified sodium dodecyl sulfate/phenol protocol, without maceration in liquid nitrogen and without a final ethanol precipitation step. The A(260/280) absorbance ratios of isolated DNA were approximately 1.7-1.9, demonstrating that the DNA fraction is pure and can be used for analysis. Additionally, the A(260/230) values were higher than 1.6, demonstrating negligible contamination by polysaccharides. The DNA isolated by this protocol is of sufficient quality for molecular applications; this technique could be applied to other organisms that have similar substances that hinder DNA extraction. The main advantages of the method are that the mycelium is directly recovered from culture medium and it does not require the use of expensive and specialized equipment.