PlasmaDNA: a free, cross-platform plasmid manipulation program for molecular biology laboratories

Background

Most molecular biology experiments, and the techniques associated with this field of study, involve a great deal of engineering in the form of molecular cloning. Like all forms of engineering, perfect information about the starting material is crucial for successful completion of design and strategies.

Results

We have generated a program that allows complete in silico simulation of the cloning experiment. Starting with a primary DNA sequence, PlasmaDNA looks for restriction sites, open reading frames, primer annealing sequences, and various common domains. The databases are easily expandable by the user to fit his most common cloning needs. PlasmaDNA can manage and graphically represent multiple sequences at the same time, and keeps in memory the overhangs at the end of the sequences if any. This means that it is possible to virtually digest fragments, to add the digestion products to the project, and to ligate together fragments with compatible ends to generate the new sequences. Polymerase Chain Reaction (PCR) fragments can also be virtually generated using the primer database, automatically adding to the fragments any 5' extra sequences present in the primers.

Conclusion

PlasmaDNA is a program available both on Windows and Apple operating systems, designed to facilitate molecular cloning experiments by building a visual map of the DNA. It then allows the complete planning and simulation of the cloning experiment. It also automatically updates the new sequences generated in the process, which is an important help in practice. The capacity to maintain multiple sequences in the same file can also be used to archive the various steps and strategies involved in the cloning of each construct. The program is freely available for download without charge or restriction.     

A program for the graphic representation and manipulation of DNA sequences

We have developed a program for the graphic representation andmanipulation of DNA sequences. The program (named CARTE fromthe French for ‘map’) is intended as a tool in theplanning and analysis of recombinant DNA experiments. DNA sequencesare represented as standard restriction maps, using any desiredcombination of restriction enzymes. Features of interest, suchas promoters or coding sequences, can be highlighted. The sequencecan be manipulated to mimic cloning, using deletions, insertionsor replacements at specified sites. This process is facilitatedby the simultaneous display of a graphic map of the entire sequence,a detailed picture of the work in progress, and a menu of functions. Received on November 17, 1986; accepted on March 12, 1987     

A modular assembly cloning technique (aided by the BIOF software tool) for seamless and error-free assembly of long DNA fragments

ABSTRACT: BACKGROUND: Molecular cloning of DNA fragments >5 kbp is still a complex task. When no genomic DNA library is available for the species of interest, and direct PCR amplification of the desired DNA fragment is unsuccessful or results in an incorrect sequence, molecular cloning of a PCR-amplified region of the target sequence and assembly of the cloned parts by restriction and ligation is an option. Assembled components of such DNA fragments can be connected together by ligating the compatible overhangs produced by different restriction endonucleases. However, designing the corresponding cloning scheme can be a complex task that requires a software tool to generate a list of potential connection sites. FINDINGS: The BIOF program presented here analyzes DNA fragments for all available restriction enzymes and provides a list of potential sites for ligation of DNA fragments with compatible overhangs. The cloning scheme, which is called modular assembly cloning (MAC), is aided by the BIOF program. MAC was tested on a practical dataset, namely, two non-coding fragments of the translation elongation factor 1 alpha gene from Chinese hamster ovary cells. The individual fragment lengths exceeded 5 kbp, and direct PCR amplification produced no amplicons. However, separation of the target fragments into smaller regions, with downstream assembly of the cloned modules, resulted in both target DNA fragments being obtained with few subsequent steps. CONCLUSIONS: Implementation of the MAC software tool and the experimental approach adopted here has great potential for simplifying the molecular cloning of long DNA fragments. This approach may be used to generate long artificial DNA fragments such as in vitro spliced cDNAs.     

C.U.R.R.F. (Codon Usage regarding Restriction Finder): A Free Java?-Based Tool to Detect Potential Restriction Sites in Both Coding and Non-Coding DNA Sequences

The synthesis of complete genes is becoming a more and more popular approach in heterologous gene expression. Reasons for this are the decreasing prices and the numerous advantages in comparison to classic molecular cloning methods. Two of these advantages are the possibility to adapt the codon usage to the host organism and the option to introduce restriction enzyme target sites of choice. C.U.R.R.F. (Codon Usage regarding Restriction Finder) is a free Java(?)-based software program which is able to detect possible restriction sites in both coding and non-coding DNA sequences by introducing multiple silent or non-silent mutations, respectively. The deviation of an alternative sequence containing a desired restriction motive from the sequence with the optimal codon usage is considered during the search of potential restriction sites in coding DNA and mRNA sequences as well as protein sequences. C.U.R.R.F is available at http://www.zvm.tu-dresden.de/die_tu_dresden/fakultaeten/fakultaet_mathematik_und_naturwissenschaften/fachrichtung_biologie/mikrobiologie/allgemeine_mikrobiologie/currf .     

Automatic construction of restriction site maps.

A computer program is described which constructs maps of restriction endonuclease cleavage sites in DNA molecules, given only the fragment lengths. The program utilizes fragment length data from single and double restriction enzyme digests to generate maps for linear or circular molecules. The search for a map can be limited to the unknown (insert) region of a recombinant phage or plasmid. Typical restriction maps with four or five enzymes which cut at three to five unknown sites can be calculated in a few minutes.     

Enhanced recovery and restriction mapping of DNA fragments cloned in a new lambda vector.

In this paper we describe a modification to the lambda vector EMBL3 which greatly expedites the construction of restriction maps of cloned DNA sequences. In the modified vector, EMBL3cos, all the phage coding sequences are placed to the right of the cloning sites so that the left cohesive end is separated by only 200bp, rather than 20kb (as in conventional lambda vectors), from the inserted DNA fragment. We show that reliable restriction maps can be rapidly constructed from partial digests of clones made in this vector by labelling the left cohesive end with a complementary 32P-labelled oligonucleotide. In addition, we quantify the restriction of clones containing human DNA by the McrA and McrB systems of E. coli and show that the use of Mcr- plating strains can increase the yield of recombinant phage up to tenfold, to give cloning efficiencies of greater than or equal to 10(7) pfu/microgram of human DNA.     

Walking, cloning, and mapping with yeast artificial chromosomes: a contig encompassing D21S13 and D21S16.

Chromosome 21 has often been used as a model system for the development of genome mapping and cloning strategies in humans. In this report methods for systematic chromosome walking, cloning, and mapping are exemplified in the construction of a 1.5-Mb yeast artificial chromosome (YAC) contig encompassing and extending 400 kb beyond each of the genetic loci D21S13 and D21S16. Isolation of insert-terminal sequences from YACs in this contig provides a set of closely spaced physical markers. These have been used to generate a long-range genomic restriction map.     

Restriction endonucleases and their applications

Restriction endonucleases are deoxyribonucleases which cleave double-stranded DNA into fragments. With only one exception, all restriction endonucleases recognize short, non-methylated DNA sequences. Restriction endonucleases can be divided into two groups based on the position of the cleavage site relative to the recognition sequence. Class I restriction endonucleases cleave double-stranded DNA at positions outside the recognition sequence and generate fragments of random size. The cleavage sites of Class II restriction endonucleases are located, in most cases, within the recognition sequence. Most of the Class II restriction endonucleases recognize 4, 5, or 6 base pair palindromes and generate fragments with either flush ends or staggered ends. DNA fragments with staggered ends contain 3, 4, or 5 nucleotide single-stranded tails called ‘sticky ends’. DNA fragments produced by Class II restriction endonuclease cleavage can be separated on gels according to their molecular weight. The fragments can be isolated from the gel and used for sequence analysis to elucidate genetic information stored in DNA. Further, an isolated fragment can be inserted into a small extrachromosomal DNA, e.g. plasmid, phage or viral DNA, and its replication and expression can be studied in clones of prokaryotic or eukaryotic cells. Restriction endonucleases and cloning technology are powerful modern tools for attacking genetic problems in medicine, agriculture and industrial microbiology.     

REMA: A computer-based mapping tool for analysis of restriction sites in multiple DNA sequences

REMA is an interactive web-based program which predicts endonuclease cut sites in DNA sequences. It analyses multiple sequences simultaneously and predicts the number and size of fragments as well as provides restriction maps. The users can select single or paired combinations of all commercially available enzymes. Additionally, REMA permits prediction of multiple sequence terminal fragment sizes and suggests suitable restriction enzymes for maximally discriminatory results. REMA is an easy to use, web based program which will have a wide application in molecular biology research. Availability: REMA is written in Perl and is freely available for non-commercial use. Detailed information on installation can be obtained from Jan Szubert (jan.szubert@gmail.com) and the web based application is accessible on the internet at the URL http://www.macaulay.ac.uk/rema Contact: b.singh@macaulay.ac.uk.     

Amplified fragment length polymorphism (AFLP): a review of the procedure and its applications

Amplified fragment length polymorphism (AFLP) is a novel molecular fingerprinting technique that can be applied to DNAs of any source or complexity. Total genomic DNA is digested using two restriction enzymes. Double-stranded nucleotide adapters are ligated to the DNA fragments to serve as primer binding sites for PCR amplification. Primers complementary to the adapter and restriction site sequence, with additional nucleotides at the 3′-end, are used as selective agents to amplify a subset of ligated fragments. Polymorphisms are identified by the presence or absence of DNA fragments following analysis on polyacrylamide gels. This technique has been extensively used with plant DNA for the development of high-resolution genetic maps and for the positional cloning of genes of interest. However, its application is rapidly expanding in bacteria and higher eukaryotes for determining genetic relationships and for epidemiological typing. This review describes the AFLP procedure, and recent, novel applications in the molecular fingerprinting of DNA from both eukaryotic and prokaryotic organisms. Received 19 December 1997/ Accepted in revised form 3 June 1998     

Physical mapping of the rice genome with BACs

The development of genetics in this century has been catapulted forward by several milestones: rediscovery of Mendel's laws, determination of DNA as the genetic material, discovery of the double-helix structure of DNA and its implications for genetic behavior, and most recently, analysis of restriction fragment length polymorphisms (RFLPs). Each of these milestones has generated a huge wave of progress in genetics. Consequently, our understanding of organismal genetics now extends from phenotypes to their molecular genetic basis. It is now clear that the next wave of progress in genetics will hinge on genome molecular physical mapping, since a genome physical map will provide an invaluable, readily accessible system for many detailed genetic studies and isolation of many genes of economic or biological importance. Recent development of large-DNA fragment (>100 kb) manipulation and cloning technologies, such as pulsed-field gel electrophoresis (PFGE), and yeast artificial chromosome (YAC) and bacterial artificial chromosome (BAC) cloning, has provided the powerful tools needed to generate molecular physical maps for higher-organism genomes. This chapter will discuss (1) an ideal physical map of plant genome and its applications in plant genetic and biological studies, (2) reviews on physical mapping of the genomes of Caenorhabditis elegans, Arabidopsis thaliana, and man, (3) large-insert DNA libraries: cosmid, YAC and BAC, and genome physical mapping, (4) physical mapping of the rice genome with BACs, and (5) perspectives on the physical mapping of the rice genome with BACs.     

VIRS: A visual tool for identifying restriction sites in multiple DNA sequences

VIRS (A visual tool for identifying restriction sites in multiple DNA sequences) is an interactive web‐based program designed for restriction endonuclease cut sites prediction and visualization. It can afford to analyze multiple DNA sequences simultaneously and produce visual restriction maps with several useful options intended for users' customization. These options also perform in‐depth analysis of the restriction maps, such as providing virtual electrophoretic result for digested fragments. Different from other analytical tools, VIRS not only displays visual outputs but also provides the detailed properties of restriction endonucleases that are commercially available. All the information of these enzymes is stored in our internal database, which is updated monthly from the manufacturers' web pages. It is freely available online at http://bis.zju.edu.cn/virs/index.html . © 2009 American Institute of Chemical Engineers Biotechnol. Prog., 2009     

Creation of a convenient vector for transformation of Drosophila with functional FRT-pFRT sites

Modification of Drosophila transformation vector pCaSper3 with the P element was used to construct a new vector, pFRT. The vector contains two tandem FRT sites flanked with several unique restriction sites and separated by a polylinker of five restriction sites, and allows easy cloning of DNA fragments between or close to the FRT sites. FRT-mediated excision of DNA sequences cloned between the FRT sites was demonstrated in vivo. The vector was proposed for molecular genetic studies of the position effect variegation, structural and molecular organization of Drosophila polytene chromosomes, etc.     

CLONING: a microcomputer program for cloning simulations

A comprehensive computational tool is presented that performs cloning simulations using IBM PC/XT/AT or compatible microcomputers. The CLONING program contains a specific data base for restriction sites, gene markers, fragment sources and reference comments. It draws complete linear or circular maps either on the screen or employing conventional dot-matrix printers. The design of new recombinant molecules is a totally interactive process.     

Sequencing the DNA of recombinant chromosomes

With contemporary molecular cloning and DNA sequencing techniques, deriving the primary structure of higher cell genes is now routine. This publication reviews the chemical DNA sequencing method, and suggests strategies for sequencing recombinant DNA, whether arising naturally by chromosome rearrangement in vivo or created experimentally by gene splicing in vitro. One such strategy prepares end-labeled restriction fragments from an inserted or rearranged DNA region, for sequencing by the chemical method. Another maps the point at which the sequences of two related DNA regions diverge, and indicates which restriction endonucleases would be useful for sequencing across that point. These techniques can facilitate sequencing of DNA integrations, excisions, translocations, inversions, and introns in cloned chromosomal segments.     

Genetic structure and origin of t haplotypes of mice, analyzed with H-2 cDNA probes

We investigated the genetic organization and evolutionary origin of t chromosomes of mice by examining the restriction fragment patterns of DNA from t haplotypes and normal chromosomes with cDNA probes to H-2 class I genes. On genomic DNA blots, the restriction fragments containing H-2-related sequences were highly variable among different inbred strains of mice, whereas they were very similar among different t haplotypes even when the t haplotypes carried serologically different H-2 haplotypes. These observations suggest that all t haplotypes have a common origin and are not products of independent mutational events. We also mapped the position of several restriction fragments characteristic of t DNA by using a battery of recombinant t haplotypes, defined with respect to their t-lethal factors and H-2 haplotypes. We thus show that restriction fragments containing H-2-related sequences map to the left of the H-2 class I genes in t chromosomes, a region in which the tw32 b-lethal factor also maps. The cloning of these fragments can be expected to provide an entry for the structural analysis of t DNA.     

Haplotype inference from diploid sequence data: evaluating performance using non-neutral MHC sequences

The direct sequencing of PCR products from diploid organisms is problematic because of ambiguities associated with phase inference in multi-site heterozygotes. Several molecular methods such as cloning, SSCP, and DGGE have been developed to empirically reduce diploid sequences to their constitutive haploid components, but in theory these empirical approaches can be supplanted by analytical treatment of diploid sequences. Analytical approaches are more desirable than molecular methods because of the added time and expense required to generate molecular data. A variety of analytical methods have been developed to address this issue, but few have been rigorously evaluated with empirical data. Furthermore, they all assume that the sequences under consideration are evolving in a neutral fashion and assume a moderate number of heterozygous sites. Here, we use non-neutral major histocompatibility complex (MHC) sequences comprised of large numbers of heterozygous sites that are under strong balancing selection to evaluate the performance of the popular Bayesian algorithm implemented by the program PHASE. Our results suggest that PHASE performs admirably with non-neutral sequences of moderate length with numerous heterozygous sites typical of MHC class II sequences. We conclude that analytical approaches to haplotype inference have great potential in large-scale population genetic assays, but recommend groundtruthing analytical results using empirical (molecular) approaches at the outset of population-level analyses.     

Autoscreening of Restriction Endonucleases for PCR-Restriction Fragment Length Polymorphism Identification of Fungal Species, with Pleurotus spp. as an Example

A molecular method based on PCR-restriction fragment length polymorphism (RFLP) analysis of internal transcribed spacer (ITS) ribosomal DNA sequences was designed to rapidly identify fungal species, with members of the genus Pleurotus as an example. Based on the results of phylogenetic analysis of ITS sequences from Pleurotus, a PCR-RFLP endonuclease autoscreening (PRE Auto) program was developed to screen restriction endonucleases for discriminating multiple sequences from different species. The PRE Auto program analyzes the endonuclease recognition sites and calculates the sizes of the fragments in the sequences that are imported into the program in groups according to species recognition. Every restriction endonuclease is scored through the calculation of the average coefficient for the sequence groups and the average coefficient for the sequences within a group, and then virtual electrophoresis maps for the selected restriction enzymes, based on the results of the scoring system, are displayed for the rapid determination of the candidate endonucleases. A total of 85 haplotypes representing 151 ITS sequences were used for the analysis, and 2,992 restriction endonucleases were screened to find the candidates for the identification of species. This method was verified by an experiment with 28 samples representing 12 species of Pleurotus. The results of the digestion by the restriction enzymes showed the same patterns of DNA fragments anticipated by the PRE Auto program, apart from those for four misidentified samples. ITS sequences from 14 samples (of which nine sequences were obtained in this study), including four originally misidentified samples, confirmed the species identities revealed by the PCR-RFLP analysis. The method developed here can be used for the identification of species of other living microorganisms.