一种高效、快速从凝胶中回收DNA的方法

目的:介绍了一种从普通琼脂糖电泳中回收DNA的简便、快捷、高效且廉价的方法.方法:利用0.5 mL离心管、1.5mL离心管、尼龙膜做成的一个小装置.把含有DNA的凝胶放在膜上,离心,收集从管底流出来的液体,用乙醇沉淀DNA.结果:最终回收率为60%左右,回收率大约为市售试剂盒的90%,接近市售DNA回收试剂盒.结论:该方法操作简单,回收率高,无其他试剂污染.     

利用机油提高琼脂糖凝胶中DNA片段的回收率

目的:发展一种简单快速经济的回收琼脂糖凝胶中DNA的方法.方法:将切的琼脂糖凝胶胶块放入嵌套Eppendorf管中捣碎,加入50μL机油,室温下12 000r/min离心5min,取大Eppendorf管中收集的液体跑胶检验,凝皎上包括代表100bp～2000bp不同大小DNA分子回收率的分子量标准DL2000.结果:DNA回收率可由加机油前的约35%提高为加机油后的45%-90%,回收效率的波动主要取决于DNA片段的大小、切下的含有DNA的胶块的大小及操作者的熟练程度.结论:该方法快速、简便、经济,具有良好的重复性与特异性,比许多国产的试剂盒更可靠.     

从琼脂糖凝胶中高效回收DNA技术的探讨

用两只离心管制成的凝胶过滤装置,从电泳后的琼脂糖凝胶中回收DNA片段的简易方法。它依次包括以下步骤：凝胶过滤装置的制作、凝胶切割、凝胶低温冷冻、低温高速离心、ddH20洗胶、DNA纯化和回收效果检测等。用此方法回收的DNA片段产率高、质量纯,可直接用于分子生物学实验的后续操作,如载体连接、PCR模板获得、DNA探针制备、基因测序等。其优点是：DNA片段的回收率高（90％以上）,质量好;操作简便,耗时短;回收装置简单,成本低廉,可进行商品化开发。     

四种土壤微生物总DNA的纯化方法的比较

比较了4种从土壤中直接抽提的微生物总DNA的纯化方法,实验结果表明1 %的琼脂糖凝胶电泳纯化方法及葡聚糖凝胶G 2 0 0离心层析纯化方法均不能完全纯化从土壤中抽提的微生物总DNA。若将直接抽提的总DNA先经葡聚糖凝胶G 2 0 0离心层析纯化,再用1 %的琼脂糖凝胶电泳纯化,则能取得较好的纯化效果。含2 %PVP的1 %琼脂糖凝胶电泳纯化,用DNA凝胶回收试剂盒回收后没有得到纯化后的土壤微生物总DNA。     

琼脂糖凝胶中DNA片段的挤压回收法

为了简化琼脂糖凝胶中DNA片段的回收,该文报道一种新的挤压回收法。将含有DNA片段的凝胶块放在折叠的封口膜之间,然后用一小塑料平板将凝胶块中的DNA溶液用力挤出,用移液枪把所有挤压出的DNA溶液放入effendorf管中,然后用常规的苯酚抽提法进行纯化。DNA回收率达到40-60%(w/w)。该方法简单而有效,且回收的DNA能够直接应用于酶切、连接及PCR等各种分子生物学操作。     

碳酸钙沉淀法回收琼脂糖凝胶中DNA的探讨

采用碳酸钙沉淀法回收琼脂糖凝胶中的DNA,达到分离纯化目的,回收后的DNA可用于重组、PCR等研究。首先将含有目的DNA的琼脂糖凝胶用Nal溶液融解,然后加入cacl2,和NaHCO3,生成CaCO3,沉淀,DNA与cac03形成复合物,通过离心分离出沉淀复合物,利用稀酸溶解沉淀,再用无水乙醇沉降,即可回收目标DNA。利用该方法回收了质粒、毛白杨和转基因羊基因组DNA,同收率为20％～50％,0D260／OD280,为1．7～19,最大回收了21kb片段,最小回收250bp片段,回收后的DNA样品进行了PCR扩增和限制性内切酶反应,PCR可以扩增出目的片段,同时限制性内切酶可以将回收后的DNA切开,表明DNA质量良好。利用碳酸钙沉淀法可以回收琼脂糖凝胶中的DNA,此法简单、易行,较为有效。     

琼脂糖胶中DNA片段的离心回收

从琼脂糖电泳中抽提单条限制性酶解的DNA片段,往往是DNA重组克隆的关键步骤。目前常用的方法不外是电泳洗脱,低熔点胶抽提及酚冷冻萃取等几种。这些方法一般都要经过酚/氯仿抽提和沉淀浓缩等额外的纯化步骤,从而导致DNA得率降低。 现介绍一种快速简便的一步法,能有效地从琼脂糖胶带中分离所需DNA片段。其过程主要是:取一只Eppendorf管,用注射针头在底部穿一小孔,在管内填上2—3 mm厚的硅化玻璃毛,将该管套在另一只Eppendorf管上,就组成了一个二连系统,用高压蒸汽     

一种从琼脂糖凝胶中同步回收DNA和琼脂糖的方法

介绍一种从琼脂糖凝胶同步回收DNA和琼脂糖的方法。利用0.25 mol/L异硫氰酸胍溶液(p H 8.0)溶解含有目的 DNA片段的的凝胶条,胶条溶解后,静置冰上10 min再加入预冷的异丙醇,琼脂糖呈颗粒状析出,通过离心即可初步分离DNA和琼脂糖。上清液用异丙醇沉淀回收DNA片段,利用50%PEG溶液沉淀琼脂糖。分别对0.2 kb、1 kb和10 kb长度的DNA片段进行回收,回收率分别为19.44%、36.40%、13.49%,回收的DNA纯度高,电泳条带清晰。琼脂糖均回收率为62.52%,回收琼脂糖脱水后的状态为白色颗粒。该方法切实可行,回收成本低廉,回收的DNA和琼脂糖可用于后续实验。     

一种有效回收小分子DNA片段的方法

介绍了一种有效回收小于200bp DNA片段的方法。用改进的冻融-离心回收法对155bp的DNA片段进行回收,并且与常规冻融-离心回收、TaKaRa回收试剂盒的结果做对比,用琼脂糖凝胶电泳检测回收结果,紫外吸收法定量分析。结果证明:改进的方法是一种经济、方便、可靠的回收小分子DNA片段的方法。     

一种从琼脂糖凝胶上回收DNA的高效、快捷、经济的方法

目前在国内分子生物学实验室所采用的多种从琼脂糖凝胶上回收DNA的方法普遍存在着各种问题。本文介绍一种新的从琼脂糖凝胶上分离和提取DNA简易装置。实验表明用这种装置回收DNA具有高效、快捷和经济的优点,非常适合在国内实验室普及推广。     

Model and computer simulations of the motion of DNA molecules during pulse field gel electrophoresis

A model is presented for the motion of individual molecules of DNA undergoing pulse field gel electrophoresis (PFGE). The molecule is represented by a chain of charged beads connected by entropic springs, and the gel is represented by a segmented tube surrounding the beads. This model differs from earlier reptation/tube models in that the tube is allowed to leak in certain places and the chain can double over and flow out of the side of the tube in kinks. It is found that these kinks often lead to the formation of U shapes, which are a major source of retardation in PFGE. The results of computer simulations using this model are compared with real DNA experimental results for the following cases: steady field motion as seen in fluorescence microscopy, mobility in steady fields, mobility in transverse field alternation gel electrophoresis (TFAGE), mobility in field inversion gel electrophoresis (FIGE), and linear dichroism (LD) of DNA in agarose gels during PFGE. Good agreement between the simulations and the experimental results is obtained.     

Efficient cDNA cloning method using solid phase DNA probe.

We are now developing a novel and efficient method using solid phase DNA probe to isolate a particular recombinant cDNA from single stranded cDNA library. Target clone coding metapyrocatechase (MPC) and cDNA library constructed from mRNA of U-937 (human lymphoma cell line) were converted to single stranded form by superinfection of helper phage (M13KO7). Probe DNA (25 mer) composed of a portion of the target cDNA was synthesized, attached to an HPLC gel and used as a solid phase DNA probe. Hybridization between probe DNA and target clone was performed in an Eppendorf tube within a few hours. Competent cell (JM109) was transformed with about one-twentieth of hybridized and eluted fraction by Hanahan's method. From the mixture of 1 ng of MPC vector and 5 micrograms of cDNA library, we obtained 50 colonies containing MPC gene out of 63 transformed colonies.     

Agarose Gel Electrophoresis for the Separation of DNA Fragments

Agarose gel electrophoresis is the most effective way of separating DNA fragments of varying sizes ranging from 100 bp to 25 kb¹. Agarose is isolated from the seaweed genera Gelidium and Gracilaria, and consists of repeated agarobiose (L- and D-galactose) subunits². During gelation, agarose polymers associate non-covalently and form a network of bundles whose pore sizes determine a gel''s molecular sieving properties. The use of agarose gel electrophoresis revolutionized the separation of DNA. Prior to the adoption of agarose gels, DNA was primarily separated using sucrose density gradient centrifugation, which only provided an approximation of size. To separate DNA using agarose gel electrophoresis, the DNA is loaded into pre-cast wells in the gel and a current applied. The phosphate backbone of the DNA (and RNA) molecule is negatively charged, therefore when placed in an electric field, DNA fragments will migrate to the positively charged anode. Because DNA has a uniform mass/charge ratio, DNA molecules are separated by size within an agarose gel in a pattern such that the distance traveled is inversely proportional to the log of its molecular weight³. The leading model for DNA movement through an agarose gel is "biased reptation", whereby the leading edge moves forward and pulls the rest of the molecule along⁴. The rate of migration of a DNA molecule through a gel is determined by the following: 1) size of DNA molecule; 2) agarose concentration; 3) DNA conformation⁵; 4) voltage applied, 5) presence of ethidium bromide, 6) type of agarose and 7) electrophoresis buffer. After separation, the DNA molecules can be visualized under uv light after staining with an appropriate dye. By following this protocol, students should be able to: 1. Understand the mechanism by which DNA fragments are separated within a gel matrix 2. Understand how conformation of the DNA molecule will determine its mobility through a gel matrix 3. Identify an agarose solution of appropriate concentration for their needs 4. Prepare an agarose gel for electrophoresis of DNA samples 5. Set up the gel electrophoresis apparatus and power supply 6. Select an appropriate voltage for the separation of DNA fragments 7. Understand the mechanism by which ethidium bromide allows for the visualization of DNA bands 8. Determine the sizes of separated DNA fragments       

Single long DNA molecule analysis using fluorescence microscopy.

Single long DNA molecule (T4 DNA) in agarose gel was visualized with a fluorescence microscope. We confirmed alternating current electric fields is effective for stretching of single DNA molecule in agarose gel. This stretching phenomenon was observed with wide range of agarose gel concentration from 0.5%(W/V) to 1.5%. From this observation, the presence of agarose gel fiber is essential for this stretching phenomenon. The stretching process of several DNA molecules in gel shows discontinuity, which is never observed in polymer systems. It would be based on topological restriction from gel fibers.     

Simple DNA elution from agarose gels

We developed a simple DNA elution method from agarose gels. After electrophoresis of DNA in an agarose gel, the DNA fragment to be recorved was excised out of gel with a scalpel. The excised gel was placed in the middle of small Parafilm piece, and the Parafilm was folded over the gel piece. Using the petriplate, or thumb, the gel piece was pressed between the Parafilm. Upon squeezing, the DNA inside of the gel gets extruded along with the buffer. The droplets were collected with a pipet. The DNA was then purified by conventional phenol: chloroform extraction method. Typical yields are greater than 50% as determined by UV absorbance.     

Preparation of large quantities of separated strands from simian virus 40 DNA restriction fragments by low-temperature low-salt agarose gel electrophoresis.

We have used agarose gel electrophoresis to separate complementary DNA strands obtained from simian virus 40 DNA restriction fragments produced by HindII and III or by EcoRI and HpaII digestion. By modifying existing methods we have virtually eliminated the problematic renaturation of DNA during electrophoresis. This has allowed us to recover large quantities of separated DNA strands (approximately 20 μg of DNA per 12-mm-diameter preparative tube gel). By using a combination of low temperature and low buffer concentration during electrophoresis, we have also significantly improved the resolution of DNA strands.     

Electrophoretic elution of nucleic acids from acrylamide and agarose gels

A simple method for electrophoretic elution of nucleic acids from gel slices is described. The procedure utilizes a standard tube gel system and can be completed in as little as one hour. Nucleic acids are recovered in a small volume with almost 100% efficiency. The procedure is applicable equally to acrylamide and agarose gels, and small as well as large RNA and DNA molecules. The eluted nucleic acids are essentially undegraded and are suitable for a variety of structural and biological analyses.     

从琼脂糖电泳凝胶中回收DNA的几种简便方法

介绍两类从普通琼脂糖电泳凝胶中回收ＤＮＡ的简便、快捷、高效且廉价的方法．第一类为电泳洗脱法．方法ａ：利用１．５ｍＬ微量离心管、ｌｍＬ吸头、尼龙网膜和透析膜做成的一个小装置,快速有效回ＤＮＡ,最终回收率为７０％左右．方法ｂ：不用ＤＥＡＥ－纤维素膜,而用透析膜在凝胶中作出横隔挡在ＤＮＡ条带前,最终回收率为５０％左右;第二类为冰冻融解法,最终回收率也在５０％左右．如果联合使用冰冻融解法和电泳洗脱法,回收率可进一步提高至９０％．     

PCR特异产物回收纯化方法的比较

方法：采用三种方法对苹果褪绿叶斑病毒RT-PCR的特异DNA产物进行回收纯化。目的：针对不同情况,选择适宜的回收纯化方法。结果：用普通琼脂糖替代低融点琼脂糖,回收纯化后产物的浓度及纯度与低融点琼脂糖法基本一致,完全可以用普通琼脂糖替代低融点琼脂糖进行DNA片段的回收纯化,从而降低成本,简化操作。玻璃奶法的回收纯度明显高于低融点琼脂糖法和普通琼脂糖法,且更快速安全,是采用普通琼脂糖法还是采用玻璃奶法回收纯化DAN片段应以实际需要而定。