Mapping of recognition sites for the restriction endonuclease from Escherichia coli K12 on bacteriophage PM2 DNA

Methods for recovering nucleic acid fragments from agarose gels

Agarose gel electrophoresis is a powerful technique for the separation of nucleic acids on the basis of their size and conformation. The development of methods to recover size-fractionated nucleic acids molecules from agarose gels has greatly facilitated recombinant DNA technologies. Although several methods for recovering DNA and RNA molecules have been developed during the past fifteen years, none of them has been universally accepted. In this review we describe, discuss and evaluate the most common procedures with which we have had experience. Our evaluation is based on the criteria of yield, purity, speed, simplicity and low cost. We have considered three different approaches to the problem of recovering nucleic acids: chemical gel dissolution, physical gel disruption and physical extrusion from intact gels.

A new method for the routine spreading of DNA in protein-free conditions

Electron microscopic studies of DNA are hampered by difficulties encountered with the spreading of DNA under protein-free conditions. The established and currently popular technique of spreading DNA on carbon membranes treated by glow discharge in an atmosphere of pentylamine is limited with regard to its reproducibility and the proper distribution of spread molecules on the surface of the membranes. A new, reliable, and highly reproducible technique using tri-L-(dimethylaminomethyl)phenol (DMP 30), a promotor factor for spreading circular DNA, linear DNA, and DNA-protein complexes, is described in this paper. Monolayers of DMP 30 are formed at the air-water interface by a microdiffusion procedure on droplets. DNA molecules that diffuse on this monolayer can easily be picked up on hydrophobic carbon membranes. This method, which is easy, reproducible, and fast, will facilitate electron microscopic studies of DNA-protein interactions.

Model for how type I restriction enzymes select cleavage sites in DNA

Under appropriate conditions, digestion of phage T7 DNA by the type I restriction enzyme EcoK produces an orderly progression of discrete DNA fragments. All details of the fragmentation pattern can be explained on the basis of the known properties of type I enzymes, together with two further assumptions: (i) in the ATP-stimulated translocation reaction, the enzyme bound at the recognition sequence translocates DNA toward itself from both directions simultaneously; and (ii) when translocation causes neighboring enzymes to meet, they cut the DNA between them. The kinetics of digestion at 37 degrees C indicates that the rate of translocation of DNA from each side of a bound enzyme is about 200 base pairs per second, and the cuts are completed within 15-25 sec of the time neighboring enzymes meet. The resulting DNA fragments each contain a single recognition site with an enzyme (or subunit) remaining bound to it. At high enzyme concentrations, such fragments can be further degraded, apparently by cooperation between the specifically bound and excess enzymes. This model is consistent with a substantial body of previous work on the nuclease activity of EcoB and EcoK, and it explains in a simple way how cleavage sites are selected.

Inhibition of the type I restriction-modification enzymes EcoB and EcoK by the gene 0.3 protein of bacteriophage T7

The gene 0.3 protein of bacteriophage T7 is a potent inhibitor of the restriction-modification enzymes EcoB and EcoK, both in vivo and in vitro. We have analyzed the ability of purified 0.3 protein to inhibit different steps in the reactions of EcoB and EcoK with DNA. Most of our experiments were done with EcoK, but selected tests with EcoB indicate that the two enzymes are affected by 0.3 protein in the same way. Purified 0.3 protein binds tightly to free enzyme, apparently to one of the small subunits, and prevents it from binding to DNA. If EcoK is allowed to form specific recognition complexes with unmodified DNA before 0.3 protein is added, relatively low levels of 0.3 protein prevent the nuclease activity that would otherwise appear upon addition of ATP, but considerably higher levels are needed to prevent formation of filter-binding complexes or ATPase activity. This, together with other results, suggests that the binding site for 0.3 protein is protected in recognition complexes and in the early stages of the ATP-stimulated reactions, but that it becomes accessible again before cleavage of the DNA, perhaps after the translocation step. If added after the nuclease reaction is substantially over, 0.3 protein has little effect on ATPase activity, and indeed, the subunit having the binding site for 0.3 protein apparently dissociates from the enzyme-DNA complex. The methylase activity of EcoK on hemi-methylated recognition sites is strongly inhibited by 0.3 protein added at any stage of the reaction.

Site-specific recombination by the bacteriophage P1 lox-Cre system. Cre-mediated synapsis of two lox sites

The bacteriophage P1-encoded recombinase Cre forms a simple DNA-protein complex at the specific recognition site loxP. Furthermore, Cre is able to mediate a synaptic union of two loxP sites. When two loxP sites are on the same linear DNA molecule, Cre binds the two sites together to form a circular protein-DNA complex. These complexes can be resolved into a linear DNA molecule and a closed circular DNA molecule, the end products of site-specific recombination.

R483 and F plasmid genes promoting RNA degradation: comparative restriction mapping

The gene promoting nucleic-acid degradation (pnd) on IncIa plasmid R483 was cloned into pBR322. It is located on a 0.85 kilobase (kb) EcoRI-SalI fragment and is close to Tn7. The pnd gene has similar properties to the srnB gene on the F plasmid. A cleavage map of the 0.85 kb pnd fragment was constructed and compared with that of the 1.18 kb EcoRI-BamHI fragment containing the srnB gene. These two regions showed marked heterogeneity as evidenced by their distinctly different restriction maps. This result suggests separate paths of evolution of the two genes for stable RNA degradation.

DNA electron microscopy

In recent years DNA electron microscopy has become a tool of increasing interest in the fields of molecular genetics and molecular and cell biology. Together with the development of in vitro recombination and DNA cloning, new electron microscope techniques have been developed with the aim of studying the structural and functional organization of genetic material. The most important methods are based on nucleic acid hybridizations: DNA-DNA hybridization (heteroduplex, D-loop), RNA-DNA hybridization (R-loop), or combinations of both (R-hybrid). They allow both qualitative and quantitative analysis of gene organization, position and extension of homology regions, and characterization of transcription. The reproducibility and resolution of these methods make it possible to map a specific DNA region within 50 to 100 nucleotides. Therefore they have become a prerequisite for determining regions of interest for subsequent nucleotide sequencing. Special methods have been developed also for the analysis of protein-DNA interaction: e.g., direct visualization of specific protein-DNA complexes (enzymes, regulatory proteins), and analysis of structures with higher complexity (chromatin, transcription complexes).

DNA translocation by the restriction enzyme from E. coli K

The restriction endonuclease Eco K binds to a host specificity site and then proceeds to cleave the DNA at sites that may to several thousand bases away. It does this by translocating the DNA past the enzyme in an ATP-dependent reaction that results in the formation of highly twisted loop intermediates. DNA cleavage can occur on either side of the host specificity site.

Plasmid vectors containing the tryptophan operon promoter suitable for efficient regulated expression of foreign genes

Derivatives of plasmid pBR322 that are suitable for high-level expression of foreign genes have been constructed. The vectors contain the Escherichia coli tryptophan promoter, the trpE gene, and about 15% of the trpD gene. To obtain expression, foreign genes are fused to the trpD gene fragment. After induction of the trp operon with 3 beta-indolylacrylic acid, trp gene products increase at least 50-fold, to account for 55% of the newly synthesised protein and 30% of total protein in the cell.

Electron microscopic visualization of restriction sites on DNA molecules

DNA molecules were adsorbed to a polylysine-treated carbon film and digested directly on the film by restriction enzymes. After washing the film with 1 M NaCl, 0.4% Kodak Photo-Flo and 9% formamide, each cleavage site introduced was visualized as a gap under the electron microscope. By measuring the gapped positions on linear DNA molecules induced by other enzymes, a single EcoRI site on a lambda dv1 molecule and three HinHI sites on an fd1RF molecule were mapped at the positions expected from the cleavage maps, respectively. This electron-microscopic procedure may be useful for the construction of a cleavage map.

Structures and mechanisms of DNA restriction and modification enzymes

DNA restriction and modification enzymes are responsible for the hostspecific barriers to interstrain and interspecies transfer of genetic information that have been observed in a variety of bacterial cell types. Although the phenomenon of host specificity was initially observed in the early 1950s (Luria & Human, 1952; Bertani & Weigle, 1953), it was nearly a decade later that Arber and his colleagues accurately predicted the molecular basis of the phenomenon. Their experiments with bacteriophage λ demonstrated that a given host-specificity system imparts a specific modification to the viral DNA, and further, that restriction of DNA lacking the appropriate modification is s consquence of nucleolytic hydrolysis upon entry into the host cell (Arber & Dussoix, 1962; Dussoix & Arber, 1962; Arber, Hattman & Dussoix, 1963).

Physical map of PM2 DNA

The cleavage sites of the restriction nucleases HpaI, HpaII, HindII, HindIII, and PstI have been mapped on the DNA of the bacteriophage PM2. This map has been used for the localization of two strong binding sites of Escherichia coli RNA polymerase on PM2 DNA.

The control region of the F sex factor DNA transfer cistrons: restriction mapping and DNA cloning

A restriction endonuclease map of EcoRI fragment f6 of F sex factor DNA was constructed and aligned with pre-existing physical and genetic maps. Results of genetic complementation tests and analysis of proteins synthesized in minicells from PstI and BglII sub-fragment clones, or from a specific BglII fragment deletion, have allowed mapping of the locations of the origin of DNA transfer and many of the transfer genes known to lie on f6. The proteins detected account for 78% of the coding capacity of fragment f6.

The presence of ovalbumin mRNA coding sequences in multiple restriction fragments of chicken DNA

Chicken DNA has been digested with restriction enzymes and the size distribution of the DNA fragments containing ovalbumin specific sequences has been examined after separation of the fragments on agarose gels and transfer to nitrocellulose sheets. Hybridisation with terminally 32P-labelled ovalbumin mRNA fragments or with RNA populations transcribed from the DNA of a hybrid plasmid containing ovalbumin sequences was used to locate the DNA fragments coding for ovalbumin. Digestion with enzymes which do not cut within the portion of the ovalbumin gene synthesised from ovalbumin messenger RNA in vitro has shown the presence of several defined fragments carrying ovalbumin specific sequences. Possible explanations of these observations are discussed.

Involvement of IS1 in the dissociation of the r-determinant and RTF components of the plasmid R100.1

The formation of the r-determinant pLC1 and of the RTF pAR132 from the composite plasmid R100.1 was investigated. The general location of IS1 sequences on the three plasmids was established by hybridization of lambdar14 CII::IS1 DNA to EcoRI generated fragments of the various plasmids separated by agarose gel electrophoresis and transferred directly to nitrocellulose filters. The position of IS1 sequences on these fragments and the homologies between fragments were analyzed by electron microscopy of heteroduplex molecules. The results show that the excision of both pLC1 and pAR132 occurred by an exchange between the two IS1 sequences present on R100.1.