Bending of DNA by gene-regulatory proteins: construction and use of a DNA bending vector

The binding of a protein to its specific sequence, borne on a DNA fragment, retards the mobility of the fragment in a characteristic way during gel electrophoresis. If the protein induces bending in the DNA, the contortion can also be monitored by gel electrophoresis, because the amount of retardation of the mobility of the DNA-protein complex is dependent upon the position and the degree of the bend induced in the DNA fragment [Wu and Crothers, Nature 308 (1984) 509-513]. We have constructed a plasmid, pBend2, which can generate a large number of DNA fragments of identical length in which the protein-binding nucleotide sequence is located in circular permutations. The vector contains two identical DNA segments containing 17 restriction sites in a direct repeat spanning a central region containing cloning sites. The protein-binding sequence is inserted at one of these cloning sites. To investigate the functional significance of bending, we have compared, using pBend2, the cAMP.cAMP-receptor protein (CPR)-induced bending of CRP-binding sites found in five different genes of Escherichia coli. We have also shown that the bacteriophage lambda 0R1 operator DNA is bent when complexed with the CI or Cro repressor of the phage.     

The impact of two-dimensional pulsed-field gel electrophoresis techniques for the consistent and complete mapping of bacterial genomes: refined physical map of Pseudomonas aeruginosa PAO.

The SpeI/DpnI map of the 5.9 Mb Pseudomonas aeruginosa PAO (DSM 1707) genome was refined by two-dimensional (2D) pulsed-field gel electrophoresis techniques (PFGE) which allow the complete and consistent physical mapping of any bacterial genome of interest. Single restriction digests were repetitively separated by PFGE employing different pulse times and ramps in order to detect all bands with optimum resolution. Fragment order was evaluated from the pattern of 2D PFGE gels: 1. Partial-complete digestion. A partial restriction digest was separated in the first dimension, redigested to completion, and subsequently perpendicularly resolved in the second dimension. 2D-gel comparisons of the ethidium bromide stain of all fragments and of the autoradiogram of end-labeled partial digestion fragments was nearly sufficient for the construction of the macrorestriction map. 2. Reciprocal gels. A complete restriction digest with enzyme A was run in the first dimension, redigested with enzyme B, and separated in the second orthogonal direction. The order of restriction digests was reverse on the second gel. In case of two rare-cutters, fragments were visualized by ethidium bromide staining or hybridization with genomic DNA. If a frequent and a rare cutter were employed, linking fragments were identified by end-labeling of the first digest. 3. A few small fragments were isolated by preparative PFGE and used as a probe for Southern analysis.--38 SpeI and 15 DpnI fragments were positioned on the map. The zero point was relocated to the 'origin of replication'. The anonymous mapping techniques described herein are unbiased by repetitive DNA, unclonable genomic regions, unfavourable location of restriction sites, or cloning artifacts as frequently encountered in other top-down or bottom-up approaches.     

Rapid shotgun cloning utilizing the two base recognition endonuclease CviJI.

A new approach has been developed for the rapid fragmentation and fractionation of DNA into a size suitable for shotgun cloning and sequencing. The restriction endonuclease CviJI normally cleaves the recognition sequence PuGCPy between the G and C to leave blunt ends. Atypical reaction conditions which alter the specificity of this enzyme (CviJI**) yield a quasi-random distribution of DNA fragments from the small molecule pUC19 (2686 base pairs). To quantitatively evaluate the randomness of this fragmentation strategy, a CviJI** digest of pUC19 was size fractionated by a rapid gel filtration method and directly ligated, without end repair, to a lacZ minus M13 cloning vector. Sequence analysis of 76 clones showed that CviJI** restricts PyGCPy and PuGCPu, in addition to PuGCPy sites, and that new sequence data is accumulated at a rate consistent with random fragmentation. Advantages of this approach compared to sonication and agarose gel fractionation include: smaller amounts of DNA are required (0.2-0.5 micrograms instead of 2-5 micrograms), fewer steps are involved (no preligation, end repair, chemical extraction, or agarose gel electrophoresis and elution are needed), and higher cloning efficiencies are obtained (CviJI** digested and column fractionated DNA transforms 3-16 times more efficiently than sonicated, end-repaired, and agarose fractionated DNA).     

Rapid and reliable dideoxy sequencing of double-stranded DNA

We report a simple and reliable protocol for nucleotide sequencing using the Sanger dideoxy technique on linearized double-stranded DNA molecules with specific oligonucleotide primers. The method is demonstrated for restriction fragments cloned into the plasmid vectors pSP64 and pSP65 using two vector-specific primers, the M 13 reverse primer and a new SP6 primer, flanking the multiple cloning site. Template DNA may be prepared by a rapid alkaline lysis procedure. Mild linearization conditions with the appropriate restriction endonuclease avoid the appearance of artifact bands.     

Multi-site binding of human nuclear protein to the Alu-family repeated DNA

Nuclear protein which selectively binds to the Alu-family DNA repeat (AFR, Blur8) is partially purified from human HeLa cells using a gel retention assay. At low protein concentrations only a single complex of the protein with AFR is formed (CII). Increasing protein concentrations lead to the gradual disappearance of CII, being replaced by complexes with higher (CI) and lower (CIII, CIV) electrophoretic mobilities. Differential binding of AFR restriction subfragments indicates that multiple protein-binding sites are present within AFR. We discuss two models explaining the anomalous electrophoretic mobility of CII by DNA bending or looping upon cooperative multi-site binding of the protein to AFR.     

A rapid two-dimensional fractionation of DNA restriction fragments

Genomic DNA that has been digested with a restriction endonuclease and fractionated by electrophoresis on an agarose gel can be recovered on glass-fiber filters by a new blotting scheme. The DNA fragments in each fraction are then digested with a second restriction nuclease and then separated on a slab gel, resulting in a two-dimensional display of the restriction fragments. This rapid fingerprinting technique is useful in the analysis of complex genomes and in the isolation and cloning of particular sequences.     

South western blot mapping: a procedure for simultaneous characterization of DNA binding proteins and their specific genomic DNA target sites

A method called "South Western blot mapping" for rapid characterization of both DNA binding proteins and their specific sites on genomic DNA is described. Proteins are separated on a sodium dodecyl sulfate (SDS) polyacrylamide gel, renatured by removing SDS in the presence of urea, and blotted onto nitrocellulose by diffusion. The genomic DNA region of interest is digested by restriction enzymes selected to produce fragments of appropriate but different sizes, which are subsequently end-labeled and allowed to bind to the separated proteins. The specifically bound DNA is eluted from each individual protein-DNA complex and analyzed by acrylamide gel electrophoresis. Evidence that tissue-specific DNA binding proteins may be detected by this technique is presented. Moreover, their sequence-specific binding allows the purification of the corresponding selectively bound DNA fragments and may improve protein-mediated cloning of DNA regulatory sequences.     

Detection and mapping of homologous, repeated and amplified DNA sequences by DNA renaturation in agarose gels.

A new molecular hybridization approach to the analysis of complex genomes has been developed. Tracer and driver DNAs were digested with the same restriction enzyme(s), and tracer DNA was labeled with 32P using T4 DNA polymerase. Tracer DNA was mixed with an excess amount of driver, and the mixture was electrophoresed in an agarose gel. Following electrophoresis, DNA was alkali-denatured in situ and allowed to reanneal in the gel, so that tracer DNA fragments could hybridize to the driver only when homologous driver DNA sequences were present at the same place in the gel, i.e. within a restriction fragment of the same size. After reannealing, unhybridized single-stranded DNA was digested in situ with S1 nuclease. The hybridized tracer DNA was detected by autoradiography. The general applicability of this technique was demonstrated in the following experiments. The common EcoRI restriction fragments were identified in the genomes of E. coli and four other species of bacteria. Two of these fragments are conserved in all Enterobacteriaceae. In other experiments, repeated EcoRI fragments of eukaryotic DNA were visualized as bands of various intensity after reassociation of a total genomic restriction digest in the gel. The situation of gene amplification was modeled by the addition of varying amounts of lambda phage DNA to eukaryotic DNA prior to restriction enzyme digestion. Restriction fragments of lambda DNA were detectable at a ratio of 15 copies per chicken genome and 30 copies per human genome. This approach was used to detect amplified DNA fragments in methotrexate (MTX)-resistant mouse cells and to identify commonly amplified fragments in two independently derived MTX-resistant lines.     

Quantitation of specific fragments in DNA restriction digests: application to the cohesive fragments in lambda DNA digests

A procedure for the quantitation of reactions between specific members of a set of DNA restriction fragments is presented. Quantitation of the cohesive fragments in NruI nuclease digests of lambda DNA is used as an example. Restriction fragments are resolved on agarose gels and their amounts are estimated from densitometer scans of photographic negatives of ethidium bromide-stained gels. A linear relationship is found between the peak height of given fragment on the scan and the logarithm of the molecular weight of the fragment, arising in part from the stoichiometry of the digest; this relationship allows simple interpolation between the peak heights of the nonreacting fragments in each gel lane to determine the theoretical maximal amount of each reactive fragment in that gel lane. Similar procedures should be applicable to enzymatic ligation or to site-specific cleavage of specific restriction fragments or to autoradiographic detection of the fragments. Since each lane of the gel is analyzed independently, the method is largely self-correcting for variations in amounts applied to the gel.     

Analysis of Mycoplasma hyorhinis genome by use of restriction endonucleases and by electron microscopy.

The chromosome of Mycoplasma hyorhinis was analyzed by using different restriction endonucleases and electron microscopy. It was found that restriction enzymes BstEII, XhoI, and SacI are the enzymes of choice for analysis and characterization of M. hyorhinis. The bands resulting from digestion of M. hyorhinis DNA with BstEII had apparent molecular weights ranging from 1.2 X 10(6) to 75 X 10(6). The apparent total molecular weight of DNA was calculated from the molecular weights of the individual bands and found to be 251 X 10(6). Electron microscopic contour length measurements of the largest DNA fragments verified the molecular weight values calculated from gel analysis. Electron microscopic contour length measurements of intact DNA of M. hyorhinis revealed a molecular weight of 5.4 +/- 5 X 10(8). The discrepancy between the values of molecular weight of M. hyorhinis DNA as determined by restriction enzyme analysis and contour length measurement is based on the fact that some of the DNA fragments which migrate as an apparent single band in the agarose gel really are double or multiple DNA fragments.     

The potential use of DNA probes to identify and type strains within the Mycobacterium tuberculosis complex

DNA was extracted and purified from 11 strains of Mycobacterium bovis isolated from cattle in Ireland. After digestion with restriction endonuclease PvuII and electrophoresis on an agarose gel, the separated DNA fragments were transferred to a nylon membrane and sequentially hybridized with three DNA probes derived from BCG.
None of the three probes detected restriction fragment length polymorphism (RFLP) within the 11 M. bovis strains, indicating a very close genetic relationship. One probe, pBCG12, detected RFLPs between the M. bovis strains and a reference PvuII digest of DNA from M. tuberculosis R37Rv, confirming that M. bovis and M. tuberculosis are closely related though genetically distinct.     

Alu-family repeat binding protein from HeLa cells which interacts with regulatory region of SV40 virus genome

Using a gel retardation assay the protein which binds selectively to the Alu-family repeat (AFR) has been identified and partially purified from HeLa cell nuclear extract. The protein (AFR-binding protein, ABP) forms multiple discrete complexes with AFR even in the presence of 200 to 2000-fold excess of non-specific (E. coli) DNA. The most stable complex has a relative mobility in 4% polyacrylamide gel (as compared to the free Alu-fragment) of 0.54. Heterogeneity of protein-DNA bands seen in the polyacrylamide gel suggests that ABP is able to form multimeric complexes with AFR. Competition experiments show that ABP do not interact with the RNA polymerase III promoter and with the TGGCA-sequence, but a high affinity binding site for ABP was found within a 660 bp restriction fragment containing the SV40 virus promoter and replication origin.     

Trapping DNA-protein binding reactions with neutral osmolytes for the analysis by gel mobility shift and self-cleavage assays

We take advantage of our previous observation that neutral osmolytes can strongly slow down the rate of DNA–protein complex dissociation to develop a method that uses osmotic stress to ‘freeze’ mixtures of DNA–protein complexes and prevent further reaction enabling analysis of the products. We apply this approach to the gel mobility shift assay and use it to modify a self-cleavage assay that uses the nuclease activity of the restriction endonucleases to measure sensitively their specific binding to DNA. At sufficiently high concentrations of neutral osmolytes the cleavage reaction can be triggered at only those DNA fragments with initially bound enzyme. The self-cleavage assay allows measurement of binding equilibrium and kinetics directly in solution avoiding the intrinsic problems of gel mobility shift and filter binding assays while providing the same sensitivity level. Here we compare the self-cleavage and gel mobility shift assays applied to the DNA binding of EcoRI and BamHI restriction endonucleases. Initial results indicate that BamHI dissociation from its specific DNA sequence is strongly linked to water activity with the half-life time of the specific complex increasing ~20-fold from 0 to 1 osmolal betaine.     

An enzymatic procedure for the purification of DNA restriction fragments without gel electrophoresis and ethidium bromide staining

A rapid and simple enzymatic method for the purification of a DNA fragment from a restriction digest was developed. The method is based on the two features of exonuclease III activity: digestion of DNA from a 3'-OH at blunt or recessed ends and failure to initiate digestion at DNA ends with four-base 3' overhangs. Herein, we establish a method for purification of a DNA restriction fragment without any physical separation via gel electrophoresis. The elimination of the ethidium bromide staining and ultraviolet irradiation steps should increase the quality and the safety of the purified DNA, a matter of major concern in the perspective of human gene therapy. In addition, since the method described does not use the visualization of the restriction fragments or their difference in size it can be used to purify a DNA fragment from a pool of DNA fragments with the same size even when microquantities of material are available.     

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 new pair of M13 vectors for selecting either DNA strand of double-digest restriction fragments

The strategy of shotgun cloning with M13 is based on obtaining random fragments used for the rapid accumulation of sequence data. A strategy, however, is sometimes needed for obtaining subcloned sequences preferentially out of a mixture of fragments. Shotgun sequencing experiments have shown that not all DNA fragments are obtained with the same frequency and that the redundant information increases during the last third of a sequencing project. In addition, experiments have shown that particular fragments are obtained more frequently in one orientation, allowing the use of only one of the two DNA strands as a template for M13 shotgun sequencing. Two new M13 vectors, M13mp8 and M13mp9, have been constructed that permit the cloning of the same restriction fragment in both possible orientations. Consequently, each of the two strands becomes a (+) strand in a pair of vectors. The fragments to be cloned are cleaved with two restriction enzymes to produce a fragment with two different ends. The insertion of such a fragment into the vector can occur only in one orientation. Since M13mp8 and M13mp9 have their array of cloning sites in an antiparallel order, either orientation for inserting a double-digest fragment can be selected by the choice of the vector.