Method for the characterization of size-exclusion chromatography media for preparative purification of DNA restriction fragments

A protocol has been developed to characterize the potential of size exclusion chromatography media for the separation of DNA fragments at a preparative scale. A standard DNA mixture composed of -DNA cut with the restriction enzymes, AluI and HaeIII, was chromatographed on a column packed with the gel of interest. Fractions were collected and examined by PAGE. A digitized image of the gel was analyzed with the aid of a computer software program to determine the DNA fractionation range and selectivity curve for each chromatography gel. Four gels were characterized using this protocol. The effect of the elution buffer ionic strength on the fractionation of DNA was also investigated.The US Government right to retain a non-exclusive royalty-freelicense in and to any copyright is acknowledged.     

A simple method for filter hybridization of labeled restriction fragments excised from gels

Labeled DNA restriction fragments excised from agarose or bisacrylylcystamine-acrylamide gels can be used for hybridization to nitrocellulose-bound DNA without eliminating the gel matrix. A gel slice containing the labeled fragment is excised, dissolved by heating at 105 degrees C (in the presence of beta-mercaptoethanol for bisacrylylcystamine-acrylamide gels), and added to the hybridization mixture. The presence of agarose or polyacrylamide in the solution does not inhibit hybridization. The method is simple, rapid, and allows complete recovery of the probe.     

A new specific DNA endonuclease activity in yeast mitochondria

Summary Two group I intron-encoded proteins from the yeast mitochondrial genome have already been shown to have a specific DNA endonuclease activity. This activity mediates intron insertion by cleaving the DNA sequence corresponding to the splice junction of an intronless strain. We have discovered in mitochondrial extracts from the yeast strain 777-3A a new DNA endonuclease activity which cleaves the fused exon A3-exon A4 junction sequence of the COXI gene.     

Mapping the order of DNA restriction fragments

A straightforward method was designed for mapping the order of DNA restriction fragments obtained by a double and two single digestions, without the necessity of using a computer or a radioactive label. All possible solutions compatible with a pre-set level of error in the determination of sequence lengths are obtained. The primary assumptions are given, and the appropriate modifications of the algorithm are presented as a function of any assumptions one is unable (or unwilling) to make. Use of the method in connection with end-labeled fragments is also described.     

An automated sample preparation system with mini-reactor to isolate and process submegabase fragments of bacterial DNA

Existing methods for extraction and processing of large fragments of bacterial genomic DNA are manual, time-consuming, and prone to variability in DNA quality and recovery. To solve these problems, we have designed and built an automated fluidic system with a mini-reactor. Balancing flows through and tangential to the ultrafiltration membrane in the reactor, cells and then released DNA can be immobilized and subjected to a series of consecutive processing steps. The steps may include enzymatic reactions, tag hybridization, buffer exchange, and selective removal of cell debris and by-products of the reactions. The system can produce long DNA fragments (up to 0.5 Mb) of bacterial genome restriction digest and perform DNA tagging with fluorescent sequence-specific probes. The DNA obtained is of high purity and floating free in solution, and it can be directly analyzed by pulsed-field gel electrophoresis (PFGE) or used in applications requiring submegabase DNA fragments. PFGE-ready samples of DNA restriction digests can be produced in as little as 2.1 h and require less than 10⁸ cells. All fluidic operations are automated except for the injection of the sample and reagents.     

A multi-step strategy for BAC recombineering of large DNA fragments

Recombineering techniques have been developed to modify bacterial artificial chromosomes (BACs) via bacterial homologous recombination systems, simplifying the molecular manipulations of large DNA constructs. However, precise modifications of a DNA fragment larger than 2-3 kb by recombineering remain a difficult task, due to technical limitations in PCR amplification and purification of large DNA fragments. Here, we describe a new recombineering strategy for the replacement of large DNA fragments using the commonly utilized phage/Red recombination host system. This approach involved the introduction of rare restriction enzyme sites and positive selection markers into the ends of a large DNA fragment, followed by its release from the donor BAC construct and integration into an acceptor BAC. We have successfully employed this method to precisely swap a number of large DNA fragments ranging from 6 to 40 kb between two BAC constructs. Our results demonstrated that this new strategy was highly effective in the manipulations of large genomic DNA fragments and therefore should advance the conventional BAC recombineering technology to the next level.     

一种利用Taq酶快速标记DNA探针的方法

目的：探索低成本、高效、快速的DNA探针标记方法。方法：以特定引物和16nler的随机引物作为延伸引物,利用Taq酶标记DNA探针。以大肠杆菌Klenow片断随机引物延伸标记法作为对照。点杂交方法检测探针标记效果。结果与结论：Taq酶标记法和大肠杆菌Klenow片段随机引物延伸标记法同样有较好的标记效果,且随机引物或特定引物作为延伸引物均可以合成足够有效的探针。Taq酶标记法是一种低成本、高效、快速的DNA探针标记方法。     

Subunit assembly for DNA cleavage by restriction endonuclease SgrAI

The SgrAI endonuclease usually cleaves DNA with two recognition sites more rapidly than DNA with one site, often converting the former directly to the products cut at both sites. In this respect, SgrAI acts like the tetrameric restriction enzymes that bind two copies of their target sites before cleaving both sites concertedly. However, by analytical ultracentrifugation, SgrAI is a dimer in solution though it aggregates to high molecular mass species when bound to its specific DNA sequence. Its reaction kinetics indicate that it uses different mechanisms to cleave DNA with one and with two SgrAI sites. It cleaves the one-site DNA in the style of a dimeric restriction enzyme acting at an individual site, mediating neither interactions in trans, as seen with the tetrameric enzymes, nor subunit associations, as seen with the monomeric enzymes. In contrast, its optimal reaction on DNA with two sites involves an association of protein subunits: two dimers bound to sites in cis may associate to form a tetramer that has enhanced activity, which then cleaves both sites concurrently. The mode of action of SgrAI differs from all restriction enzymes characterised previously, so this study extends the range of mechanisms known for restriction endonucleases.     

Detection of universal variable fragments as markers for genetic studies. A novel technology for DNA fingerprinting

A novel DNA technology enables the detection of universal variable fragments (UVF), thus revealing genetic variation without a priori sequence information. The detection of UVF markers is based on two amplifications of genomic DNA with the polymerase chain reaction. In the first amplification, two short oligonucleotide primers produce a large number of fragments. One primer is based on a microsatellite sequence, whereas the second primer can have any sequence. In the second amplification, the length of the primers is increased in order to decrease the number of amplicons. This enables the selection of polymorphic fragments. Restriction digestion can be used to further increase the number of polymorphisms. Until now, we have demonstrated UVF in several different species. In addition, with the present study we have contributed to the linkage map of the rabbit by localizing 11 UVF markers on different linkage groups. Mendelian inheritance was shown in this linkage study through a backcross of two inbred rabbit strains. The power of the UVF technique is based on the selection for microsatellite variation in combination with the detection of single-nucleotide polymorphisms. UVF thus offers the possibility of increasing the clustering of markers and localizing genes in species for which sequence information is either not present or only scarcely present.     

CONSTRUCTION AND PRIMAL APPLICATION OF A CLONED DNA PROBE FOR OEDALEUS ASIATICUS ENTOMOPOXVIRUS

Abstract  One fragment of the Oedaleus asiaticus entomopoxvirus (OaEPV) DNA cleaved with Bgl I was cloned into the EbmHI site of GEM-7zf(+) and then labeled by random oligonucletide primer to be a cloned DNA probe. This probe had species specificity to Dociostaurus kruussi EPV and Nosema to custae , but not to Calliptomus italicus EPV. The probe was able to detect Ing OaEPV DNA, 10² viral spheroids and OaEPV in the infected grasshopper homogenates.     

亚洲小车蝗Oedaleus asiaticus痘病毒DNA探针的构建和初步应用(英文)

用限制性内切酶酶切亚洲小车蝗痘病毒DNA,将酶切后的DNA片断克隆到质粒pGEM—7zf( )中。用随机引物法标记克隆的外源亚洲小车蝗痘病毒DNA片断为探针。经Southern及斑点杂交证明此探针对新疆戟纹蝗Dociostaurus kraussi及微孢子虫Nosema locusstae有特异性,对新疆意大利蝗Calliptomus italicus无特异性。构建的探针可检测1ng亚洲小车蝗痘病毒DNA及10~2病毒包含体,也可检测感染病虫匀浆液中的痘病毒。     

A new estimate of sequence divergence of mitochondrial DNA using restriction endonuclease mappings

Summary A new estimate of the sequence divergence of mitochondrial DNA in related species using restriction enzyme maps is constructed. The estimate is derived assuming a simple Posisson-like model for the evolutionary process and is chosen to maximize an expression which is a reasonable approximation to the true likelihood of the restriction map data. Using this estimate, four sets of mitochondrial DNA data are analyzed and discussed.     

A method for isolation and purification of peanut genomic DNA suitable for analytical applications

Numerous methods are available for isolation of plant genomic DNA, but in practice these procedures are empirical due to variability in plant tissue composition. Consistent isolation of quality DNA from peanut (Arachis hypogaea L.) is particularly problematic due to the presence of phenolic compounds and polysaccharides. Inconsistencies in extraction results can be attributed to the age and growth stage of the plant material analyzed. Mature leaves have higher quantities of polyphenols, tannins, and polysaccharides that can contaminate DNA during isolation. We show that four published protocols could not be used to isolate peanut DNA of sufficient quality for PCR amplification or Southern hybridization. We have devised a new protocol that uses DEAE-cellulose purification to isolate peanut DNA useful for downstream applications.     

一种简便、高效、经济的从凝胶中回收DNA的方法

目的:尝试一种简便、高效的从凝胶中回收DNA的方法。方法:在Eppendorf管的管底用注射器扎孔,将一小团用Eppendorf管融化后拉成的细丝放入管中,把含有DNA的凝胶放在细丝上,离心,收集从管底流出的液体,经酚氯仿抽提后用乙醇沉淀DNA。结果:经过简单的离心即可近乎100%地回收凝胶中的DNA。结论:使用该方法从琼脂糖凝胶回收DNA,操作简单,回收率高,无其他试剂污染。     

A new packing for separation of DNA restriction fragments by high performance liquid chromatography

TSK-GEL SW was found to be useful as a packing in high performance liquid chromatography for the separation of double-stranded DNA restriction fragments. DNA fragments smaller than 300 base pairs were separated as discrete peaks depending solely upon difference in chain length. The recovery of DNA fragments was higher than 90%.     

In-gel multiple displacement amplification of long DNA fragments diluted to the single molecule level

The isolation and multiple genotyping of long individual DNA fragments are needed to obtain haplotype information for diploid organisms. Limiting dilution of sample DNA followed by multiple displacement amplification is a useful technique but is restricted to short (<5 kb) DNA fragments. In the current study, a novel modification was applied to overcome these problems. A limited amount of cellular DNA was carefully released from intact cells into a mildly heated alkaline agarose solution and mixed thoroughly. The solution was then gently aliquoted and allowed to solidify while maintaining the integrity of the diluted DNA. Exogenously provided Phi29 DNA polymerase was used to perform consistent genomic amplification with random hexameric oligonucleotides within the agarose gels. Simple heat melting of the gel allowed recovery of the amplified materials in a solution of the polymerase chain reaction (PCR)-ready form. The haplotypes of seven SNPs spanning 240 kb of the DNA surrounding the human ATM gene region on chromosome 11 were determined for 10 individuals, demonstrating the feasibility of this new method.     

System for DNA sequencing with resolution of up to 600 base pairs

A system capable of resolving about 500 bases is of interest for sequencing of longer DNA molecules. Studies on further optimization of resolution on DNA sequencing gels were carried out. The effect of physico-chemical properties of gels and buffers on resolution were tested, e.g. ionic strength and pH of buffers, different buffer systems, acrylamide concentration, crosslinker concentration, type of crosslinker, temperature of polymerization, denaturing conditions, gel length and thickness. Tested were as well different running conditions like electric field, gel temperature, dimension of sample slots. Gels 0.1-0.2 mm thick and up to 1.2 m long were cast and tested routinely. Gel lengths of 60-70 cm (for sequencing up to 350-400 bases) to about 100 cm (above 400 bases) are practicable. Little is gained in resolution by increasing the gel length from 1 to 1.2 m. Resolution was improved using 0.1 mm thick gels, at a higher pH value of 8.6-8.8, and molarity increased to 0.2 M. The sequencing pattern in the region of higher bases could be better resolved on a twice-magnified picture of that region on the autoradiogram. With the long gels (70-120 cm), it is advantageous to obtain the sequence overlap by running in parallel gels of different concentrations, without re-application of samples, all loaded at the same time. Buffer chamber for running of two of three gels and thermostating plates up to 1.2 m long were designed. In this way four to six thermostated gels can be run from a power supply with two inputs. Three 1 m long gels (concentrations: 4%, 6%, 12-16%) are loaded with several samples of DNA to be sequenced and run in parallel without re-application of the samples. With good samples, the sequence overlap from the gels could be counted up to 500 base pairs, with exceptionally good samples closer to 600 bases. At present this number seems to be near the limit of the resolving power of the polyacrylamide gels.