Contaminant eluted from solid-phase plasmid affinity-purification protocol columns is not found using liquid-phase methods and can be prevented.

The preparation of high quality plasmid DNA is a necessary requirement for most molecular biology applications. We compared four different large plasmid preparation protocols, which were based on either a liquid-phase approach (Triton lysis) or purification of alkaline lysis bacterial extracts followed by supercoiled plasmid purification on affinity columns. Two host Escherichia coli strains, JM 109 and INValphaF', were used to grow the test plasmids for comparison of product plasmid DNA produced from the four different plasmid isolation methods. While the DNA grown in E. coli strain JM109, prepared by liquid-phase Triton lysis was appropriately restricted by 12 restriction enzymes, this was not the case for any of the JM109-grown DNA purified by any of the affinity column solid-phase approaches. In contrast to this, when the plasmid DNA was grown in E. coli strain INValphaF', most restriction enzymes cut DNA appropriately, irregardless of the plasmid preparation protocol used. It seems that an impurity commonly eluted with the DNA from all three of the solid-phase DNA columns had an equal effect on the above enzymes using the common host strain JM109, but not strain INValphaF'.     

A Method for Preparing DNA Sequencing Templates Using a DNA-Binding Microplate

A DNA-binding matrix was immobilized on the surface of a 96-well microplate and used for plasmid DNA preparation for DNA sequencing. The same DNA-binding plate was used for bacterial growth, cell lysis, DNA purification, and storage. In a single step using one buffer, bacterial cells were lysed by enzymes, and released DNA was captured on the plate simultaneously. After two wash steps, DNA was eluted and stored in the same plate. Inclusion of phosphates in the culture medium was found to enhance the yield of plasmid significantly. Purified DNA samples were used successfully in DNA sequencing with high consistency and reproducibility. Eleven vectors and nine libraries were tested using this method. In 10 μl sequencing reactions using 3 μl sample and 0.25 μl BigDye Terminator v3.1, the results from a 3730xl sequencer gave a success rate of 90–95% and read-lengths of 700 bases or more. The method is fully automatable and convenient for manual operation as well. It enables reproducible, high-throughput, rapid production of DNA with purity and yields sufficient for high-quality DNA sequencing at a substantially reduced cost.     

Proposal for a better integration of bacterial lysis into the production of plasmid DNA at large scale

The paper addresses the question of how to achieve bacterial lysis in large-scale plasmid DNA production processes, where conventional alkaline lysis may become awkward to handle. Bacteria were grown in shaker flasks and a bioreactor. Suboptimal growth conditions were found advantageous for stable plasmid production at high copy numbers (up to 25mg/L could be achieved). Cells were harvested by filtration in the presence of a filter aid. A linear relationship between the biomass and the optimal filter aid concentration in terms of back pressure could be established. Bacteria-containing filter cakes were washed with isotonic buffer and lysis was achieved in situ by a two-step protocol calling for fragilisation of the cells followed by heat lysis in a suitable buffer. RNA and other soluble cell components where washed out of the cake during this step, while the plasmid DNA was retained. Afterwards a clear lysate containing relatively pure plasmid DNA could be eluted from the cake mostly as the desired supercoiled topoisomer, while cell debris and genomic DNA were retained. Lysis is, thus, integrated not only with cell capture but also with a significant degree of isolation/purification, as most impurities were considerably reduced during the procedure.     

Large-scale purification of plasmid DNA by fast protein liquid chromatography using a Hi-Load Q Sepharose column.

The large-scale purification of plasmid DNA was achieved using fast protein liquid chromatography on a Hi-Load Q Sepharose column. This method allows for the purification of plasmids starting from crude plasmid DNA, prepared by a simple alkaline lysis procedure, to pure DNA in less than 5 h. In contrast to the previously described plasmid purification methods of CsCl gradient centrifugation or high-pressure liquid chromatography, this method does not require the use of any hazardous or expensive chemicals. More than 100 plasmids varying in size from 3 to 15 kb have been purified using this procedure. A Mono Q Sepharose column was initially used to purify plasmids smaller than 8.0 kb; however, a Hi-Load Q Sepharose column proved more effective with plasmids larger than 8 kb. The loading of plasmids larger than 8 kb on the Mono Q column resulted in a high back pressure and the plasmid DNA could not be eluted from the column. Thus, for routine purification we utilize the Hi-Load Q Sepharose column. Plasmids purified by this method had purity, yield, and transfection efficiency in mammalian cells similar to those of plasmids purified by CsCl density gradient centrifugation.     

Single-stranded circular DNA generated from broad host range plasmid R1162 and its derivatives

Extraction of R1162 plasmid DNA with the alkaline lysis method yields considerable amounts of single-stranded circular plasmid DNA. Destabilization of plasmid DNA is stimulated by the R1162 mob region in cis. The formation of single-stranded circular DNA is initiated at a specific site on the plasmid, presumably the origin of transfer (oriT).     

Isolation of a single-stranded plasmid from Clostridium acetobutylicum NCIB 6444

The cryptic plasmid pDM6 was isolated from late exponential-phase cells of Clostridium acetobutylicum NCIB 6444 by either alkaline lysis or electroporation. The application of high voltage during electroporation resulted in higher DNA yield than did the alkaline lysis procedure. However, electroporation-induced plasmid release generated high amounts of single-stranded DNA compared with the alkaline lysis procedure, which generated both double-stranded DNA (monomer and dimer forms) and single-stranded DNA.     

Isolation of a single-stranded plasmid from Clostridium acetobutylicum NCIB 6444.

The cryptic plasmid pDM6 was isolated from late exponential-phase cells of Clostridium acetobutylicum NCIB 6444 by either alkaline lysis or electroporation. The application of high voltage during electroporation resulted in higher DNA yield than did the alkaline lysis procedure. However, electroporation-induced plasmid release generated high amounts of single-stranded DNA compared with the alkaline lysis procedure, which generated both double-stranded DNA (monomer and dimer forms) and single-stranded DNA.     

High-throughput plasmid mini preparations facilitated by micro-mixing.

We have developed a reliable high-throughput plasmid isolation system using a 96-well plate format. This system combines a novel glass bead micro-mixing method with modified alkaline lysis and Sephacryl S-500 DNA purification procedures. Mechanical forces generated by vortexing glass beads inside each well of the 96-well plates ensure that the bacterial pellets are homogeneously resuspended, the cells are completely lyzed, and the resulting bacterial lysates are thoroughly mixed with the potassium acetate solution. The vortexing speed and duration for glass bead mixing have been standardized to facilitate plasmid DNA yields without significant adjustments.     

Automated alkaline lysis for industrial scale cGMP production of pharmaceutical grade plasmid-DNA

Plasmid DNA for biopharmaceutical applications is mainly produced in E. coli cells. The first and most crucial step for recovering the plasmid is the cell lysis. Governed by the physico-chemical properties of the polynucleotide, alkaline lysis has been the lysis-method of choice. This chemical disintegration technique was initially developed for the lab scale and non-pharmaceutical applications. A continuous, fully automated and closed system combining alkaline lysis, neutralization and clarification in one gentle and generic operation was developed. This system consists of a three units. One unit controls mixing and contact time during the alkaline treatment, another one controls the neutralization and the concurrent formation of flocs and a third one the separation of flocs and pDNA containing lysate. Based on optimization experiments the selected process parameters resulted in yields up to 100% and homogeneities comparable to that obtained by gentle manual lysis. The process does not need enzymes and it is scalable and routinely used for cGMP-production of pharmaceutical grade plasmid DNA from 200 L fermentations.     

Dideoxy sequencing method using denatured plasmid templates

The dideoxy sequencing method in which denatured plasmid DNA is used as a template was improved. The method is simple and rapid: the recombinant plasmid DNA is extracted and purified by rapid alkaline lysis followed by ribonuclease treatment. The plasmid DNA is then immediately denatured with alkali and subjected to a sequencing reaction utilizing synthetic oligonucleotide primers. It takes only several hours from the start of the plasmid extraction to the end of the sequencing reaction. We examined each step of the procedure, and several points were found to be crucial for making the method reproducible and powerful: (i) the plasmid DNA should be free from RNA and open circular (or linear) DNA; (ii) a heptadecamer rather than a pentadecamer is recommended as a primer; and (iii) the sequencing reaction should be done at 37 degrees C or higher rather than at room temperature. The method enabled us to determine the sequence of more than a thousand nucleotides from a single template DNA.     

重组大肠杆菌碱裂解方法的改进

为了降低质粒DNA的生产成本,对经典碱裂解法中的溶液III进行了改进,以表达溶菌酶基因的pcDNKLYZ重组质粒转化的大肠杆菌DH5α为指示菌,用标准碱裂解和改进碱裂解法提取质粒pcDNKLYZ,以提取的质粒产量和质量为指标,判断优化碱性裂解法的性价比,结果显示,用改进后的碱裂解法裂解重组菌,提取的pcDNKLYZ质粒产量和质量等指标与标准方法接近,而成本仅为标准方法的1/4,可用于重组质粒的大规模制备。     

A novel method of plasmid isolation using laundry detergent

Since the discovery of plasmid, various methods have been developed to isolate plasmid DNA. All the methods have one common and important target of isolating plasmid DNA of high quality and quantity in less time. These methods are not completely safe because of use of toxic chemicals compounds. The developed protocol for plasmid extraction is based on the alkaline lysis method of plasmid preparation (extraction atpH 8.0) with slight modifications. Cell lysis reagent sodium dodecyl sulfate is replaced by lipase enzyme present in laundry detergent. A good plasmid preparation can be made, which is well suited for subsequent molecular biology applications. By taking safety measures on count, contaminants like, RNA and protein can be completely avoided with maximized plasmid yield. The resultant plasmid quality and quantity can be well comparable to other prevalent methods.     

Evidence for the presence of plasmids in four therapeutically important strains of Lactobacillus acidophilus

Four therapeutically important strains of Lactobacillus acidophilus designated as R, 301, 1899 and NCFM were screened for the presence of plasmids. Two lysis methods were used for the isolation of plasmid DNA: an alkaline method and a more gentle technique. It was found that the gentle lysis method yielded better plasmid DNA both quantitatively and qualitatively. All four strains studied apparently possess plasmids. The strains 301 and NCFM possessed one plasmid each, with a size of 4.2 kb, whereas R possessed three plasmids (3.5, 2.4 and 2.1 kb) and 1899 possessed two plasmids (4.1 and 4.2 kb). Restriction analysis revealed that the plasmid DNA from strain R was cleaved by Bam HI but not by Hin d III and Eco RI. The plasmid DNA from the remaining three strains was cleaved by all three restriction enzymes used.     

A continuous cell alkaline lysis, neutralization, and clarification combination process for production of plasmid pUDK-HGF

Plasmid DNA for biopharmaceutical applications is produced easily in Escherichia coli bacteria. The cell lysis is the most crucial step for purification of plasmid DNA. In this paper, we describe a continuous cell alkaline lysis, neutralization, and clarification combination process for production of plasmid pUDK-HGF using hollow fiber ultrafiltration column as a lysis chamber and compare the plasmid DNA yield and homogeneity with the T-connector and manual processes, respectively. The results show that the plasmid pUDK-HGF yield of the combination process is 13% higher than manual lysis, twice higher than using T-connector. When the proportion of lysed cells and neutralization solution is 3:1, the plasmid pUDK-HGF yield can improve by 70%. This process could be easily scaled up to meet the industrial scale for cell lysis.     

Affinity purification of plasmid DNA by temperature-triggered precipitation

This protocol presents a new method to purify plasmid DNA using temperature-triggered precipitation. The principle is based on the specific DNA-binding affinity of a bacterial metalloregulatory (MerR) protein to its cognate DNA sequence and the temperature responsiveness of elastin-like protein (ELP). A bifunctional ELP-MerR fusion protein is created to enable the precipitation of plasmid DNA, designed to contain the MerR recognition sequence, by a simple temperature trigger. The protocol covers all stages of the process from the design of ELP-MerR fusion proteins and MerR-binding plasmids, to the isolation of plasmid DNA from Escherichia coli cultures after boiling lysis, the subsequent temperature-triggered precipitation of plasmid DNA-fusion protein complexes and final elution of plasmid DNA by mild heating. This protocol is well suited to laboratory research-scale applications, producing plasmid DNA of better purity and similar yield as one of the most commonly used laboratory methods, standard alkaline lysis (known as the midiprep procedure). The protocol takes approximately 30 min to obtain pure plasmid DNA from cell cultures using the temperature-triggered precipitation method.     

Purification of plasmids by triplex affinity interaction.

Production of pharmaceutical grade plasmid DNA is an important issue in gene therapy. We developed a method for affinity purification of plasmids by triple helix interaction. This method is based on sequence-specific binding of an oligonucleotide immobilized on a large pore chromatography support to a target sequence on the plasmid. Using design criteria derived from thermodynamic data, we produced a 15mer target sequence which binds strongly to the affinity support under mildly acidic conditions. Plasmid DNA was purified from clarified Escherichia coli lysate by incubation with the affinity beads at pH 5.0 and high NaCl concentration. After extensive washing of the beads, purified plasmid DNA was eluted with alkaline buffer. The purified plasmid showed no RNA or cell DNA contamination in HPLC analysis and total protein concentration was reduced considerably. Due to its mechanical stability and porosity this support can be used in a continuous affinity purification process, which has a high potential for scale up.     

碱裂解提取质粒DNA的改进

碱裂解提取质粒DNA是分子生物学实验中常用的方法,但通常方法所提取的质粒往往含有大量的RNA和其他杂质.本文适时加入较高浓度的RNA酶和适当延长冰浴时间,结果得到了几乎没有RNA和其他杂质的高纯质粒DNA,不仅达到了分子生物学实验要求,而且可用作抗原检测抗dsDNA抗体.该法操作简单、经济、实用.     

An improved alkaline lysis method for minipreparation of plasmid DNA

This study is to improve the digestion pattern of miniprepped plasmid analyzed on gel. Frequently, some ambiguous DNA bands, which are suspected to be denatured DNA molecules, appear during electrophoresis of enzyme digested miniprepped plasmids. By employing Southern hybridization of two identical gels, one had been treated with denaturation-neutralization step and another without such treatment, we confirmed that many of these ambiguous DNA bands were single-stranded (SS) DNA molecules. The presence of SS DNA was due to the use of excess amount of NaOH during plasmid DNA purification with the conventional alkaline lysis method. We, therefore, modified the procedure and recommend that a half amount of NaOH (0.1N instead of 0.2N) should be used when isolating small quantity of plasmid DNA with the method.     

重组质粒pVAX1-PENK大规模制备研究

目的：建立质粒pVAX1-PENK的大规模制备2--艺。方法：对大肠杆菌工程菌DH5α-pVAX1-PENK进行补料发酵,利用自行发明的连续碱裂解过程对菌体进行裂解,经超滤浓缩后,用Sepharnse 6 Fast Flow层析柱分离DNA与RNA,再经Plasmidselect Xtra层析柱分离超螺旋质粒DNA与开环或线性质粒DNA,最后经Source 15Q层析柱精制质粒DNA。结果：发酵获得质粒pVAX1-PENK的产率为182mg／L,经碱裂解及层析分离后,最终制备的质粒DNA超螺旋比例大于98％,总回收率为60.5％,纯度（D260nm／D280nm）为1.8～2.0。结论：建立的质粒DNA生产工艺可以制备大量高纯度的质粒DNA,并避免了使用动物源性的酶及有毒试剂。     

Purification of plasmid DNA by tangential flow filtration

A simple, scalable method for purification of plasmid DNA is described. The method includes modification of the classical alkaline-lysis-based plasmid extraction method by extending the solubilization step from less than 30 min to 24 h. The extraction is followed by the novel use of tangential flow filtration (TFF) for purification of the remaining contaminants. The method does not include the use of any organic solvents, RNase, high-speed centrifugation, or column chromatography steps. The method typically yields 15 to 20 mg of plasmid DNA per liter of bacterial culture and results in removal of >99% of RNA and >95% of the protein that remains after the modified alkaline lysis procedure. The procedure has been demonstrated to be effective in the isolation of seven different plasmids. Plasmids isolated using this method had comparable transfection capability relative to plasmid isolated using a classical, cesium chloride gradient-based method.