Recovery of DNA from soils and sediments.

Experiments were performed to evaluate the effectiveness of two different methodological approaches for recovering DNA from soil and sediment bacterial communities: cell extraction followed by lysis and DNA recovery (cell extraction method) versus direct cell lysis and alkaline extraction to recover DNA (direct lysis method). Efficiency of DNA recovery by each method was determined by spectrophotometric absorbance and using a tritiated thymidine tracer. With both procedures, the use of polyvinylpolypyrrolidone was important for the removal of humic compounds to improve the purity of the recovered DNA; without extensive purification, various restriction enzymes failed to cut added target DNA. Milligram quantities of high-purity DNA were recovered from 100-g samples of both soils and sediments by the direct lysis method, which was a greater than 1-order-of-magnitude-higher yield than by the cell extraction method. The ratio of labeled thymidine to total DNA, however, was higher in the DNA recovered by the cell extraction method. than by the direct lysis method, suggesting that the DNA recovered by the cell extraction method came primarily from active bacterial cells, whereas that recovered by the direct lysis method may have contained DNA from other sources.     

DNA recovery from soils of diverse composition.

A simple, rapid method for bacterial lysis and direct extraction of DNA from soils with minimal shearing was developed to address the risk of chimera formation from small template DNA during subsequent PCR. The method was based on lysis with a high-salt extraction buffer (1.5 M NaCl) and extended heating (2 to 3 h) of the soil suspension in the presence of sodium dodecyl sulfate (SDS), hexadecyltrimethylammonium bromide, and proteinase K. The extraction method required 6 h and was tested on eight soils differing in organic carbon, clay content, and pH, including ones from which DNA extraction is difficult. The DNA fragment size in crude extracts from all soils was > 23 kb. Preliminary trials indicated that DNA recovery from two soils seeded with gram-negative bacteria was 92 to 99%. When the method was tested on all eight unseeded soils, microscopic examination of indigenous bacteria in soil pellets before and after extraction showed variable cell lysis efficiency (26 to 92%). Crude DNA yields from the eight soils ranged from 2.5 to 26.9 micrograms of DNA g-1, and these were positively correlated with the organic carbon content in the soil (r = 0.73). DNA yields from gram-positive bacteria from pure cultures were two to six times higher when the high-salt-SDS-heat method was combined with mortar-and-pestle grinding and freeze-thawing, and most DNA recovered was of high molecular weight. Four methods for purifying crude DNA were also evaluated for percent recovery, fragment size, speed, enzyme restriction, PCR amplification, and DNA-DNA hybridization. In general, all methods produced DNA pure enough for PCR amplification. Since soil type and microbial community characteristics will influence DNA recovery, this study provides guidance for choosing appropriate extraction and purification methods on the basis of experimental goals.     

Comparison of two bacterial DNA extraction methods from non-polluted and polluted soils

DNA extraction from soil samples is a critical step for molecular biology analyses. The present study compared the efficiency of two DNA isolation methods from non-polluted and polluted soils with or without the presence of a plant. Both applied methods used chemical and physical lyses, but method 1 had an additional physical disruption. The main difference between these two methods was the humic acid purification technique as it was carried out during cell lysis for method 1 and after cell lysis for method 2. Samples were assessed on the basis of their yield and DNA purity as well as their bacterial quantity and diversity. Based on our results, method 1 proved to be more effective at removing protein and RNA, whereas method 2 proved to be more effective at removing humic acids. Although no differences were obtained in terms of the DNA yield, both the bacterial quantity and community structure were affected by the method used. Method 1 allowed for the recovery of more information than method 2, and polluted soil was more sensitive to the DNA extraction procedure. We recommend carefully selecting the DNA extraction method, especially when soil is disturbed.     

Methods for DNA extraction from various soils: a comparison

Seven methods for bacterial DNA extraction and purification from soil samples were compared. Holben's direct lysis method recovered significantly greater amounts of DNA than the other methods tested, while CsCl-ethidium bromide density gradient ultracentrifugation was better than gel filtration at removing humic acid from crude DNA isolated from soil. When both these methods were combined, 5·94 μg of DNA (A_260/280 ratio around 1·754) was yielded g⁻¹ oven-dried sandstone shale alluvial soil; similarly satisfactory yields were obtained from Taiwan clay, and sandstone shale and slate alluvial soil managed under different farming practices. DNA obtained by these methods was readily digested by Eco R I and Hind III. When soil samples were stored for 3 weeks at 4 °C, the fraction of high-molecular-weight DNA was reduced significantly. Thus, DNA extraction should be carried out as soon as possible after a soil sample has been collected from the field. When hyphae of Pythium aphanidermatum and Fusarium solani were subjected to the above lysis method, DNA could not be detected in the extract.     

Assessment of [h]thymidine incorporation into DNA as a method to determine bacterial productivity in stream bed sediments

We performed several checks on the underlying assumptions and procedures of the thymidine technique applied to stream bed sediments. Bacterial production rates were not altered when sediments were mixed to form a slurry. Incubation temperature did affect production rates. Controls fixed and washed with formaldehyde had lower backgrounds than trichloroacetic acid controls. DNA extraction by base hydrolysis was incomplete and variable at 25 degrees C, but hydrolysis at 120 degrees C extracted 100% of the DNA, of which 84% was recovered upon precipitation. Production rates increased as thymidine concentrations were increased over 3 orders of magnitude (30 nM to 53 muM thymidine). However, over narrower concentration ranges, thymidine incorporation into DNA was independent of thymidine concentration. Elevated exogenous thymidine concentrations did not eliminate de novo synthesis. Transport of thymidine into bacterial cells occurred at least 5 to 20 times faster than incorporation of label into DNA. We found good agreement between production rates of bacterial cultures based upon increases in cell numbers and estimates based upon thymidine incorporation and amount of DNA per cell. Those comparisons emphasized the importance of isotopic dilution measurements and validated the use of the reciprocal plot technique for estimating isotopic dilution. Nevertheless, the thymidine technique cannot be considered a routine assay and the inability to measure the cellular DNA content in benthic communities restricts the accuracy of the method in those habitats.     

Assessment of [3H]Thymidine Incorporation into DNA as a Method To Determine Bacterial Productivity in Stream Bed Sediments

We performed several checks on the underlying assumptions and procedures of the thymidine technique applied to stream bed sediments. Bacterial production rates were not altered when sediments were mixed to form a slurry. Incubation temperature did affect production rates. Controls fixed and washed with formaldehyde had lower backgrounds than trichloroacetic acid controls. DNA extraction by base hydrolysis was incomplete and variable at 25°C, but hydrolysis at 120°C extracted 100% of the DNA, of which 84% was recovered upon precipitation. Production rates increased as thymidine concentrations were increased over 3 orders of magnitude (30 nM to 53 μM thymidine). However, over narrower concentration ranges, thymidine incorporation into DNA was independent of thymidine concentration. Elevated exogenous thymidine concentrations did not eliminate de novo synthesis. Transport of thymidine into bacterial cells occurred at least 5 to 20 times faster than incorporation of label into DNA. We found good agreement between production rates of bacterial cultures based upon increases in cell numbers and estimates based upon thymidine incorporation and amount of DNA per cell. Those comparisons emphasized the importance of isotopic dilution measurements and validated the use of the reciprocal plot technique for estimating isotopic dilution. Nevertheless, the thymidine technique cannot be considered a routine assay and the inability to measure the cellular DNA content in benthic communities restricts the accuracy of the method in those habitats.     

Culture-Independent Identification of Nontuberculous Mycobacteria in Cystic Fibrosis Respiratory Samples

Respiratory tract infections with nontuberculous mycobacteria (NTM) are increasing in prevalence and are a significant cause of lung function decline in individuals with cystic fibrosis (CF). NTM have been detected in culture-independent analyses of CF airway microbiota at lower rates than would be expected based on published prevalence data, likely due to poor lysing of the NTM cell wall during DNA extraction. We compared a standard bacterial lysis protocol with a modified method by measuring NTM DNA extraction by qPCR and NTM detection with bacterial 16S rRNA gene sequencing. The modified method improved NTM DNA recovery from spiked CF sputum samples by a mean of 0.53 log₁₀ copies/mL for M. abscessus complex and by a mean of 0.43 log₁₀ copies/mL for M. avium complex as measured by qPCR targeting the atpE gene. The modified method also improved DNA sequence based NTM detection in NTM culture-positive CF sputum and bronchoalveolar lavage samples; however, both qPCR and 16S rRNA gene sequencing remained less sensitive than culture for NTM detection. We highlight the limitations of culture-independent identification of NTM from CF respiratory samples, and illustrate how alterations in the bacterial lysis and DNA extraction process can be employed to improve NTM detection with both qPCR and 16S rRNA gene sequencing.     

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。     

Evaluation of the impact of DNA extraction methods on BAC bacterial community composition measured by denaturing gradient gel electrophoresis

Aims: The impact of DNA extraction methods on biological activated carbon (BAC) DNA yield and bacterial community was evaluated. Methods and Results: Three different DNA extraction methods were compared: method a, method b and method c. Method c with ultrasonic pretreatment improved cell lysis efficiency (from 34% to 87%) and DNA yield [from 10·58 μg g^?1 (dry wt) of carbon to 21·42 μg g^?1 (dry wt) of carbon]. denaturing gradient gel electrophoresis profiles obtained by method c recovered the five seeded bacteria (Bacillus subtilis Strain WSO 6, Pseudomonas putida Strain WSO 7, Acinetobacter lwoffii WSO 10, Pseudomonas pertucinogena WSO 11 and Brevibacterium mcbrellneri WSO 13). Conclusions: The results showed method c with ultrasonic pretreatment was the most successful for the analysis of BAC bacterial community because it was effective in the detachment of bacteria and cell lysis, thereby resulting in good yields. Significance and Impact of Study: These results must be taken into consideration when extracting DNA for analysing BAC bacterial community.     

Combination of biomolecular and stable isotope techniques to determine the origin of organic matter used by bacterial communities: application to sediment.

Natural isotopic composition is a good tool to trace organic matter in ecosystems. Recent studies used a combination of molecular and stable isotope techniques to determine the origin of the organic carbon used by bacteria in the water column. In our study, we show that this procedure can be used for analysis of sediment bacterial communities with few modifications. In the water column, bacterial recovery is done before DNA extraction. In the sediment, we tested qualitatively and quantitatively a direct and indirect extraction of DNA. The direct extraction was the most efficient. It recovered between 3.1 and 15.8 microg DNA g(-1) dry sediment and the contamination of field samples by eucaryotic DNA was less than 13%. In this preliminary study of the salt marsh ecosystem, the delta(13)C values of DNA (-26 to - 24%) recovered from the sediment were close to the delta(13)C values of halophytic plants (-26.4 and - 25.3%) showing a relationship between plants and microorganisms. Thus, this procedure can be used to trace the flow of carbon through the sediment microbial biomass and to understand the variation of bacterial activity according to the inputs of allocthonous and autochtonous organic matter.     

A method for obtaining DNA from compost

An effective cell lysis method for extraction of bacterial genomic DNA from compost was developed in this study. Enzymatic disruption method, physical–chemical combination method, and commercial kit method were used to extract DNA from compost samples and were compared by analyzing DNA yield and efficient cell lysis. The results showed that all the three methods can be used to extract high-quality DNA from compost, but the enzymatic method had better cell lysis efficiency and DNA yields than others without the use of special equipment and expensive spending. Comparison of different methods for lysing gram-positive bacteria Bacillus subtilis indicated that the enzymatic cell lysis is superior for destroying the gram-positive cell wall. Spin-bind DNA column was used for DNA purification, and the purity of the purified sample was checked by polymerase chain reaction to amplify a region of the 16S rRNA. Results indicated that the part of 16S rRNA were amplified from all the purified DNA samples, and all the amplification products could be digested by the restriction enzyme HhaI.     

Fate of heterotrophic bacteria in Lake Tanganyika (East Africa)

Bacterial mortality was studied using two complementary methods between 2002 and 2004 in the two main basins (north and south) of Lake Tanganyika. The disappearance of radioactivity from the DNA of natural assemblages of bacteria previously labeled with tritiated thymidine was used to estimate the mortality due to grazing by predators (72%) and due to the cell lysis (28%). Measurements of ingestion rate of bacteria by protozoa using fluorescent micro-particles yielded protozoan grazing rates similar to those provided by the thymidine method, and showed that heterotrophic nano-flagellates were responsible for most of the grazing pressure on the bacterial community of the pelagic zone (92-99%). Bacterial cell lysis was the second process involved in bacterial mortality, ranking before ciliate grazing. Overall, bacterial mortality was balanced with bacterial production. With regard to the assessment of the trophic role of bacteria, it was estimated that c. 5-8% of the organic carbon taken up by bacteria was converted into protozoan biomass and was thus available for metazoans.     

Evaluation and Optimization of DNA Extraction and Purification Procedures for Soil and Sediment Samples

We compared and statistically evaluated the effectiveness of nine DNA extraction procedures by using frozen and dried samples of two silt loam soils and a silt loam wetland sediment with different organic matter contents. The effects of different chemical extractants (sodium dodecyl sulfate [SDS], chloroform, phenol, Chelex 100, and guanadinium isothiocyanate), different physical disruption methods (bead mill homogenization and freeze-thaw lysis), and lysozyme digestion were evaluated based on the yield and molecular size of the recovered DNA. Pairwise comparisons of the nine extraction procedures revealed that bead mill homogenization with SDS combined with either chloroform or phenol optimized both the amount of DNA extracted and the molecular size of the DNA (maximum size, 16 to 20 kb). Neither lysozyme digestion before SDS treatment nor guanidine isothiocyanate treatment nor addition of Chelex 100 resin improved the DNA yields. Bead mill homogenization in a lysis mixture containing chloroform, SDS, NaCl, and phosphate-Tris buffer (pH 8) was found to be the best physical lysis technique when DNA yield and cell lysis efficiency were used as criteria. The bead mill homogenization conditions were also optimized for speed and duration with two different homogenizers. Recovery of high-molecular-weight DNA was greatest when we used lower speeds and shorter times (30 to 120 s). We evaluated four different DNA purification methods (silica-based DNA binding, agarose gel electrophoresis, ammonium acetate precipitation, and Sephadex G-200 gel filtration) for DNA recovery and removal of PCR inhibitors from crude extracts. Sephadex G-200 spin column purification was found to be the best method for removing PCR-inhibiting substances while minimizing DNA loss during purification. Our results indicate that for these types of samples, optimum DNA recovery requires brief, low-speed bead mill homogenization in the presence of a phosphate-buffered SDS-chloroform mixture, followed by Sephadex G-200 column purification.     

Evaluation and optimization of DNA extraction and purification procedures for soil and sediment samples.

We compared and statistically evaluated the effectiveness of nine DNA extraction procedures by using frozen and dried samples of two silt loam soils and a silt loam wetland sediment with different organic matter contents. The effects of different chemical extractants (sodium dodecyl sulfate [SDS], chloroform, phenol, Chelex 100, and guanadinium isothiocyanate), different physical disruption methods (bead mill homogenization and freeze-thaw lysis), and lysozyme digestion were evaluated based on the yield and molecular size of the recovered DNA. Pairwise comparisons of the nine extraction procedures revealed that bead mill homogenization with SDS combined with either chloroform or phenol optimized both the amount of DNA extracted and the molecular size of the DNA (maximum size, 16 to 20 kb). Neither lysozyme digestion before SDS treatment nor guanidine isothiocyanate treatment nor addition of Chelex 100 resin improved the DNA yields. Bead mill homogenization in a lysis mixture containing chloroform, SDS, NaCl, and phosphate-Tris buffer (pH 8) was found to be the best physical lysis technique when DNA yield and cell lysis efficiency were used as criteria. The bead mill homogenization conditions were also optimized for speed and duration with two different homogenizers. Recovery of high-molecular-weight DNA was greatest when we used lower speeds and shorter times (30 to 120 s). We evaluated four different DNA purification methods (silica-based DNA binding, agarose gel electrophoresis, ammonium acetate precipitation, and Sephadex G-200 gel filtration) for DNA recovery and removal of PCR inhibitors from crude extracts. Sephadex G-200 spin column purification was found to be the best method for removing PCR-inhibiting substances while minimizing DNA loss during purification. Our results indicate that for these types of samples, optimum DNA recovery requires brief, low-speed bead mill homogenization in the presence of a phosphate-buffered SDS-chloroform mixture, followed by Sephadex G-200 column purification.     

Underestimation of DNA synthesis by [h]thymidine incorporation in marine bacteria

A direct comparison of [H]thymidine incorporation with DNA synthesis was made by using an exponentially growing estuarine bacterial isolate and the naturally occurring bacterial populations in a eutrophic subtropical estuary and in oligotrophic offshore waters. Simultaneous measurements of [H]thymidine incorporation into DNA, fluorometrically determined DNA content, and direct counts were made over time. DNA synthesis estimated from thymidine incorporation values was compared with fluorometrically determined changes in DNA content. Even after isotope dilution, nonspecific macromolecular labeling, and efficiency of DNA recovery were accounted for, [H]thymidine incorporation consistently underestimated DNA synthesized by six- to eightfold. These results indicate that although the relationship of [H]thymidine incorporation to DNA synthesis appears consistent, there are significant sources of thymine bases incorporated into DNA which cannot be accounted for by standard [H]thymidine incorporation and isotope dilution assays.     

可用于微生物群落分子生态学研究的活性污泥总DNA提取方法研究

活性污泥样品经液氮速冻、沸水浴融化、溶菌酶处理和 SDS裂解后 ,99%以上细胞裂解。所提取的 DNA经琼脂糖凝胶电泳检测和荧光法浓度测定 ,其片断大小在 2 0 kb左右 ,产量可达 1 .75 6± 0 .1 mg/g MLSS。样品 ABS2 6 0 nm/ABS2 80 nm的比值为 1 .96± 0 .2。以提取的总 DNA为模板 ,进行细菌核糖体小亚基 1 6Sr DNA基因 V3区和多组分苯酚羟化酶大亚基基因 (Lm PHs)的 PCR扩增 ,均获得成功 ,为活性污泥中微生物群落的分子生态学研究提供了一种简便、可靠的 DNA提取方法。     

DNA extraction procedure: a critical issue for bacterial diversity assessment in marine sediments

In order to evaluate whether different DNA extraction procedures can affect estimates of benthic bacterial diversity, based on 16S rRNA gene terminal restriction fragment length polymorphism (T-RFLP) fingerprinting technique, we compared two in situ lysis procedures (a SDS-based protocol and a commercial kit for DNA recovery) and one cell-extraction protocol on a variety of marine sediments. Despite the two in situ lysis procedures resulted in significantly different DNA yields (highest with the SDS in situ lysis), estimates of bacterial diversity provided a not significantly different ribotype richness, as well as similar values of the Shannon-Wiener (H') and Margalef (d) indices of biodiversity and of evenness (Pielou index, J). Conversely, the cell-extraction procedure for DNA extraction resulted always in a significantly lower ribotype richness and diversity. The analysis of similarities (anosim) among the T-RFLP electropherograms allowed concluding that ribotypes composition did not change significantly using different protocols. However, the analysis of beta-diversity (turnover diversity) revealed that a large number of ribotypes was observed exclusively with one of the three protocols utilized. When unshared ribotypes from in situ lysis and cell extraction were pooled together, total ribotype richness resulted much higher (up to 80%). Our results indicate that estimates of ribotype diversity based on a single protocol of DNA extraction can significantly underestimate the total number of bacterial ribotypes present in the benthic domain. We recommend that future studies will not only integrate different DNA extraction procedures, but also will explore the possibility of integrating two or more different genetic markers in order to increase our ability to detect the actual bacterial diversity in environmental samples.     

A method for determination of iododeoxyuridine substitution of thymidine using reversed-phase high-performance liquid chromatography

An assay for thymidine substitution by iododeoxyuridine (IdUrd) using reversed-phase high-performance liquid chromatography (HPLC) has been developed. Three principal steps in this procedure are: extraction of DNA from cell or tissues, hydrolysis of DNA into deoxynucleosides and separation using HPLC. Approximately 1 microgram of DNA was recovered from 10(5) cells by phenol extraction, and subjected to hydrolysis into deoxynucleosides which required a three-stage DNA digestion using enzymes DNAse I. phosphodiesterase I and alkaline phosphatase. The deoxynucleosides were separated on the Microsorb C18 column with isocratic elution; 90-100% of the DNA was recovered as deoxynucleosides on the column. The method was used to determine quantitatively the percent IdUrd substitution of thymidine in Chinese hamster lung cells in vitro and BA1112 rhabdomyosarcoma in WAG/Rij rats perfused with IdUrd. It was possible to determine the thymidine substitution by IdUrd as small as 1% using a few micrograms of DNA. The close correspondence between the percent substitutions determined by HPLC and those determined by radioactive assay using [125I]-labelled IdUrd, confirmed the accuracy of our HPLC method. The HPLC analysis is especially suitable for the determination of percent IdUrd substitution of thymidine in tissue biopsies from animals used in in vivo experiments or humans undergoing radiation treatment.     

Ultrasonication as a rapid and high yield DNA extraction method for bacterial gene quantification by NanoGene assay

We demonstrated ultrasonication as a rapid and high yield DNA extraction method suitable for bacterial gene quantification by NanoGene assay. The NanoGene assay utilizes DNA hybridization in solution and a combination of magnetic beads and quantum dot nanoparticles. Unlike the existing gene quantification assays, the NanoGene method is capable of quantifying genes in the presence of environmental inhibitors and cell materials. The performance of the ultrasonication was compared with heating and freeze-thaw. They first were evaluated for their cell lysis capability in humic acids laden sand samples, via EtBr assay. Using autoclaved samples as a bench mark, their cell lysis capability were 106 ± 3, 68 ± 5, and 48 ± 15%, respectively. Morphological changes of cells for each method were also observed by FE-SEM. More importantly, ultrasonication performed significantly better (more than 3× fluorescence signal) than commercial DNA extraction methods during bacterial gene quantification in humic acids laden sand samples.