从植物细胞核分离大分子量核DNA

研究了从植物中分离百万碱基对级大分子量核DNA的方法。该方法利用差速离心分离植物细胞核,经低熔点琼脂糖块或低熔点琼脂糖微珠包埋,蛋白酶K原位裂解后制备大分子量核DNA。结果表明,选择不同生长时期的材料和不同的包埋细胞核方式对大分子量核DNA的制备有很大的影响,由黄化苗或幼嫩的绿叶为材料分离细胞核,进行胶块包埋是制备大分子量核DNA的最佳条件。利用该法获得的DNA分子量在200kb－5．7Mb之间,主要集中在2．2～5．7Mb之间;每一胶块DNAE量为18～20μg。与包埋原生质体制备大分子量核DNA的方法相比,该方法获得的DNA纯度较高,去除了大部分细胞器DNA的污染;易于被限制性内切酶部分和完全消化,其消化结果具可重复性。该方法操作简单、适用植物种类广泛,用该方法从水稻（OryzasativaL．）、苹果（MaluspumilaMill．）、大豆（Glycinemax（L．）Merr．）、玉米（ZeamaysL．）等多种植物材料中成功地制备了大分子量核DNA。该方法制备的核DNA适用于植物的脉冲交变电泳基因组分析和构建人工细菌染色体文库和人工酵母染色体文库。     

Preparation of HMW DNA from Plant Nuclei and Chromosomes Isolated from Root Tips

Simple, fast and cost-effective method for preparation of DNA with high molecular weight (HMW DNA) from plant nuclei and mitotic chromosomes has been developed. The technique involves mechanical homogenization of formaldehyde-fixed root tips, purification of nuclei and/or chromosomes on sucrose gradient, embedding in low-melting-point agarose, and DNA isolation in agarose plugs. Alternatively, nuclei and chromosomes may be purified using flow cytometry. Majority of DNA obtained is megabase-sized and well digestible by restriction endonucleases. The method is highly efficient as microgram amounts of DNA can be obtained from only several milligrams of plant tissue. Handling negligible amounts of plant material reduces the consumption of chemicals. Furthermore, the use of root tips makes it possible to obtain high-quality DNA even from plant species with leaves that are rigid or rich in secondary metabolites such as polyphenols. It is expected that preparation of HMW DNA from root tip nuclei will facilitate long-range mapping and construction of large-insert DNA libraries also in these species. Successful isolation of HMW DNA from flow-sorted chromosomes opens a way for construction of chromosome-specific large-insert libraries in plants. This revised version was published online in July 2006 with corrections to the Cover Date.     

Isolation of high molecular weight DNA from wholeEuglena cells

Summary A method for isolating high quality DNA from wholeEuglena cells is described. The procedure consists in: the weakening of the cell pellicle in glycerol avoiding the mechanical disruption of cells and shearing damage in DNA molecules; the decondensation ofEuglena compact chromatin directly inside the cells; the complete dissociation of cells and nucleoproteins in sarkosyl detergent; the optional digestion of proteins and RNA with DNase-free enzymes and the final purification of DNA by isopycnic banding in CsCl gradients. Degradation of DNA is prevented all along the extraction procedure by glycerol, antioxydants, EDTA and sarkosyl detergent. Using the enzymatic digestion step, DNA containing few single-stranded nicks is obtained with a yield approaching 100%. DNA with no single-stranded nick could be obtained with a 35% yield when the enzymatic digestion step was omitted. In both cases, the double-stranded DNA has an average molecular weight equal or greater than 6×10⁷. It is free of contaminants and could be easily digested with restriction enzymes. After digestion with Eco RI and size-fractionation in agarose gel this DNA has permitted specific hybridization of the rDNA sequences with a radioactive rRNA probe.Abbreviations Kbp kilobasepairs - Kb kilobases     

Isolation of HMW DNA from sunflower (Helianthus annuus L.) for BAC cloning

The cultivated sunflower (Helianthus annuus L.) is one of the most important oil crops in the world. The importance of sunflower oil in human nutrition and in the chemical industry makes the sunflower a major research interest. An essential element for genomic libraries is the preparation of high molecular weight (HMW) DNA. We developed 2 methods for isolating HMW sunflower DNA. We prepared the DNA from nuclei and from protoplasts isolated from mesophyll tissue with the enzymes cellulase RS and pectolyase Y23. The HMW DNA was digested with restriction endonucleases. The ethidium bromide-stained gel suggested the DNA to be completely digested. These results were confirmed by Southern analysis using a radiolabeled RFLP marker. Both methods made it possible to generate sufficient quantities of megabase-size sunflower DNA suitable for bacterial artificial chromosome (BAC) cloning.     

Recycling Isolation of Plant DNA,A Novel Method

DNA is one of the most basic and essential genetic materials in the field of molecular biology.To date,isolation of sufficient and good-quality DNA is still a challenge for many plant species,though various DNA extraction methods have been published.In the present paper,a recycling DNA extraction method was proposed.The key step of this method was that a single plant tissue sample was recycled for DNA extraction for up to four times,and correspondingly four DNA precipitations(termed as the 1st,2nd,3rd and 4th DNA sample, respectively) were conducted.This recycling step was integrated into the conventional CTAB DNA extraction method to establish a recycling CTAB method.This modified CTAB method was tested in eight plant species,wheat,sorghum,barley,corn,rice,Brachypodium distachyon,Miscanthus sinensis and tung tree.The results showed that high-yield and good-quality DNA samples could be obtained by using this new method in all the eight plant species.The DNA samples were good templates for PCR amplification of both ISSR and SSR markers.The recycling method can be used in multiple plant species and can be integrated with multiple conventional DNA isolation methods,and thus is an effective and universal DNA isolation method.     

卷象科昆虫无损形态的DNA提取方法

提取DNA是所有分子生物学实验的第一步,但在昆虫分子生物学研究中,常规提取总DNA的方法不能保留昆虫所有的形态特征。显然,这不适用于对于体形较小的珍稀标本。以鞘翅目卷象科(Coleoptera:Attelabidae)昆虫为实验材料,提供了一种新的取材方法,取下整个腹部,消化其肌肉组织后收回骨化腹板。该方法可在提取昆虫总DNA的同时保存全部外形特征及其生殖器。     

Asymmetric field inversion gel electrophoresis: a new method for detecting DNA double-strand breaks in mammalian cells

A new method is described for detecting DNA double-strand breaks (DSBs) that utilizes asymmetric field inversion gel electrophoresis (AFIGE). DNA purified from cells in agarose plugs is subjected to AFIGE and DNA breakage quantitated by the fraction of DNA released from the plug. To test the specificity of the method for DNA DSBs, purified DNA in agarose plugs was treated for increasing times with restriction endonuclease, XhoI. After an initial time period, the fraction of DNA released increased in direct proportion to time. This correlates with the expected response for a randomly broken DNA molecule. In contrast, treatment with the single-strand breaking agent, hydrogen peroxide, over a 1000-fold range produced no release of DNA from the plug. Thus the assay appears to be specific for DNA DSBs and was used to measure DNA breaks induced by gamma radiation. Purified DNA, irradiated in agarose plugs, exhibited a log-linear dose response up to doses that release greater than 90% DNA from the plug. When live cells were irradiated in agarose, a similar linear dose response was observed up to 40 Gy and a significant signal as low as 2.5 Gy. Also in live cells, a threefold lower percentage of DNA was released from the plug over the same dose range. However, less DNA per gray is released at doses above 40 Gy and may reflect a crosslinking effect produced by the irradiation of DNA in live cells. DNA which was "pulse-labeled" was used to test the effect of DNA replication on the ability of AFIGE to detect DNA DSBs. Replicating DNA irradiated in the cell or after purification exhibited a reduced rate of release from the plug per dose of irradiation. Overall, the above results indicate that AFIGE is a sensitive method for detecting DSBs in DNA.     

Recovery, purification, and cloning of high-molecular-weight DNA from soil microorganisms

We describe here an improved method for isolating, purifying, and cloning DNA from diverse soil microbiota. Soil microorganisms were extracted from soils and embedded and lysed within an agarose plug. Nucleases that copurified with the metagenomic DNA were removed by incubating plugs with a high-salt and -formamide solution. This method was used to construct large-insert soil metagenomic libraries.     

Extraction of DNA from soil using nanoparticles by magnetic bioseparation

Aims: To develop a simple, rapid and inexpensive soil DNA extraction protocol. Methods and Results: The protocol relies on the use of superparamagnetic silica‐magnetite nanoparticles for the isolation and purification of DNA from soil samples. DNA suitable for use in molecular biology applications was obtained from a number of soil samples. Conclusions: The DNA extracted using the tested method successfully permitted the PCR amplification of a fragment of the bacterial 16S rDNA gene. The extracted DNA could also be restriction endonuclease digested. Significance and Impact of the Study: The protocol reported here is simple and permits rapid isolation of PCR‐ready soil DNA. The method requires only small quantities of soil sample, is scalable and suitable for automation.     

Construction and screening of BAC libraries made from Brachypodium genomic DNA

Bacterial artificial chromosome (BAC) libraries are the large DNA insert libraries of choice and valuable tools for the map-based cloning of target quantitative trait loci, physical mapping, molecular cytogenetics and comparative genomics. The protocol reported here is a simplified method used to produce and screen BAC libraries from Brachypodium species and other related grasses. Intact nuclei, containing high molecular weight (HMW) DNA, are isolated and embedded in agarose plugs. The HMW DNA is digested using an appropriate restriction enzyme and size-fractionated using pulsed-field gel electrophoresis. The DNA is isolated by dialysis, ligated into pre-prepared vector and electroporated into competent Escherichia coli cells. A PCR-based method for screening the library is also described. The entire protocol takes at least 6 weeks to complete.     

An effective protocol to solve the problem in genomic DNA isolation of tung tree

Tung tree (Vernicia fordii) is a native and oil-producing woody plant in China. The oil is industrially important and promising biodiesel raw material. However, until recently the lack of effective protocols for the extraction of genomic DNA had made DNA-based molecular studies of tung tree difficult. Here, four conventional protocols and one novel protocol were compared for their capacity in isolating DNA from tung tree leaves of different age. Our results showed that all the four conventional protocols could isolate DNA from old leaves, two from matured leaves, but none from young leaves. However, the detectable DNA samples contained many contaminations, leading to overestimation of DNA concentration measured by ultraviolet spectrophotometer, also interfering with the downstream PCR reaction. The novel protocol could produce high-yield and good-quality DNA from tung tree leaves regardless of leaf age. Its key steps were that a single leaf tissue sample could be recycled for DNA extraction for up to four times, and correspondingly four DNA precipitations (termed as the 1st, 2nd, 3rd and 4th DNA sample, respectively) were conducted. All the four DNA samples of a single tissue were good template for PCR reaction. The novel protocol is an effective method for genomic DNA isolation of tung tree.     

Comparison of methods for total community DNA extraction and purification from compost

The differences on DNA yield and purity of three different DNA extraction protocols were compared with regard to the use for PCR and other molecular analyses. Total DNA was extracted from compost by the three protocols, and then was purified by spin-bind cartridges after being precipitated by PEG8000. The detection performed on a nucleic acid and protein analyzer showed that all three methods produced high DNA yields. The agarose gel electrophoresis showed that the fragments of crude and purified DNA had a length of about 23 kb. A eubacterial 16S rRNA gene-targeted primer pair was used for PCR amplification, and full length 16S rDNAs were amplified from all the purified DNA samples. After being digested by restriction endonucleases, the restriction map of amplified rDNA showed identical genetic diversity. The products of PCR using primer pair GC341F and 907R were also used for denaturing gradient gel electrophoresis analysis. The results indicated that high-quality DNA was extracted from compost by the three protocols, and each of the protocols is adapted to extract microbial genome DNA from compost expediently and cheaply.     

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.     

Isolation of megabase-size DNA from sorghum and applications for physical mapping and bacterial and yeast artificial chromosome library construction

A method was developed for the isolation of megabase-size DNA fromSorghum bicolor. Sorghum protoplasts were isolated from young leaf tissue, embedded in an agarose matrix as microbeads or plugs, followed by cell lysis and protein degradation. The DNA prepared by this method was larger than 1 Mb in size and readily digestible with restriction enzymes. The DNA was shown to be suitable for physical mapping, and was successfully used for the construction of BAC and YAC libraries.     

Isolation of high molecular weight DNA suitable for BAC library construction from woody perennial soft-fruit species

We have developed a novel nuclei extraction method that allows for the extraction of high molecular weight DNA from leaves of woody perennial soft-fruit species that contain high levels of carbohydrates and polyphenolics. The method utilizes a modified buffer system including 4% (w/v) polyvinylpyrrolidone (PVP)-10 and a combination of nylon filters and Percoll gradients to purify nuclei extracts prior to embedding in agarose plugs. The effectiveness of the method was demonstrated on leaves of red raspberry (Rubus idaeus) and blackcurrant (Ribes nigrum), two soft-fruit species that have shown to be recalcitrant to standard genomic DNA extraction methods. Extracted DNA was readily digested by restriction enzymes and, as shown for raspberry, suitable for bacterial artificial chromosome (BAC) library construction.     

Preparation of megabase-size DNA from plant nuclei

A novel technique has been developed for the preparation of high molecular weight (HMW) DNA from plant nuclei. This technique involves physical homogenization of plant tissues, nuclei isolation, embedding of the nuclei in low-melting-point agarose microbeads or plugs, and DNA purification in situ . This technique is simple, rapid, and economical, and the majority of the DNA prepared is over 5.7 Mb in size. The genomic DNA content of the HMW DNA prepared by this technique is enriched by at least threefold and the chloroplast DNA content is reduced by over twofold relative to that prepared from plant protoplasts by existing methods. The DNA is readily digestible with different restriction enzymes and partial digestions of the DNA could be reproducibly performed. This method has been successfully used for the preparation of HMW DNA from a wide range of plant taxa, including grasses, legumes, vegetables, and trees. These results demonstrate that the DNA prepared by this technique is suitable for plant genome analysis by pulsed-field gel electrophoresis and for the construction of yeast and bacterial artificial chromosomes.     

A Rapid DNA Minipreparation Method Suitable for AFLP and Other PCR Applications

A rapid DNA minipreparation method was developed for rice and other plant species. This method uses an Eppendorf tube and 1-ml pipette tip to grind plant tissues, and requires only one transfer for DNA isolation. In a single day, one person can complete DNA isolation from more than 120 leaf samples. The yields of the DNA samples ranged from 2.3 to 5.2 g from 25–50 mg fresh leaf tissue. DNA samples extracted using this method from rice were completely digested with five restriction enzymes (EcoR I, EcoR V, Hind III, Mse I and Pst I) and were successfully used for AFLP and other PCR applications.     

DNA extraction techniques for DNA barcoding of minute gall-inhabiting wasps

DNA extraction from minute hymenopterans and their larvae is difficult and challenging because of their small size indicating a low amount of starting material. Hence, 11 DNA extraction methods were compared to determine their efficacy in isolating DNA. Success of each method was scored on a 2% agarose gel after PCR of the cox 1 mitochondrial locus. A silica-membrane-based approach was the most successful, followed by a method using a combination of incubation buffers and a method using magnetic beads. The method using buffers was the most cost- and time effective. Using this method, larvae from Eucalyptus seed capsule galls could be assigned a role (parasitoid, gall former or inquiline) in the gall-inhabiting complex.     

植物总DNA样品的快速制备

利用Ｑｉａｇｅｎ微量植物ＤＮＡ提取试剂盒,在１小时内即可从植物组织获得总ＤＮＡ,提取过程中勿需酚／氯仿和ＳＤＳ抽提,操作简便、快捷。所得ＤＮＡ样品的ＯＤ２６０／ＯＤ２８０值在１．７－１．９之间。样品纯度高;该样品不含ＰＣＲ反应抑制剂及其他酶反应抑制剂,可被各种限制性内酶完全降解,适合于ＰＣＲ、印迹、ＲＡＰＤ、ＡＦＬＰ和ＲＦＬＰ分析等各种下游应用。     

Unidirectional pulsed-field electrophoresis of single- and double-stranded DNA in agarose gels: analytical expressions relating mobility and molecular length and their application in the measurement of strand breaks

Unidirectional pulsed-field electrophoresis improves the separation of single-stranded DNA molecules longer than 20 kilobases (kb) in alkaline agarose gels compared to static-field electrophoresis. The greatest improvement in separation is for molecules longer than 100 kb. The improved resolution of long molecules with unidirectional pulsed-field electrophoresis makes possible the measurement of lower frequencies of single-strand breaks. The analytical function that relates the length and mobility of single-stranded DNA electrophoresed with a static field also applies to unidirectional pulsed field separations. Thus, the computer programs used to measure single-strand breaks are applicable to both undirectional pulsed- and static-field separations. Unidirectional pulsed-field electrophoresis also improves the separation of double-stranded DNA in neutral agarose gels. The function relating molecular length and mobility for double-stranded DNA separated by unidirectional pulsed-field electrophoresis is a superset of the function for single-stranded DNA. The coefficients of this function can be determined by iterative procedures.