Four-stranded DNA structure and DNA base methylation in the mechanism of action of restriction endonucleases

Circular dichroism spectra of DNA quadruplexes [d(G(5)T(5))](4) as formed with G(4) and T(4) tetrads and [d(G(5)T(5)). d(A(5)C(5))]2 as formed with Watson-Crick-like (G-C)(2) and (T-A)(2) tetrads

We utilize electrophoresis and find that a thermally treated equimolar mixture of the oligonucleotide d(G(5)T(5)) and its complementary oligonucleotide d(A(5)C(5)) exhibits either two bands or a single band in one lane, depending on the conditions of the incubation solutions. The thermally treated d(G(5)T(5)) solution loaded in a different lane exhibits a single band of the parallel quadruplex [d(G(5)T(5))](4), which is composed of homocyclic hydrogen-bonded G(4) and T(4) tetrads previously proposed. For the thermally treated equimolar mixture of d(G(5)T(5)) and d(A(5)C(5)), the fast band is assigned to a Watson-Crick d(G(5)T(5)). d(A(5)C(5)) duplex, so that the slow band with the same low mobility as that of [d(G(5)T(5))](4) may be assigned to either [d(G(5)T(5))](4) itself or a [d(G(5)T(5)). d(A(5)C(5))](2) quadruplex. If the latter compound is true, this may be the antiparallel quadruplex composed of the heterocyclic hydrogen-bonded G-C-G-C and T-A-T-A tetrads proposed previously. After removing these three bands for the duplex and two kinds of hypothetical quadruplexes, we electrophoretically elute the corresponding compounds in the same electrophoresis buffer using an electroeluter. The eluted compounds are ascertained to be stable by electrophoresis. The circular dichroism (CD) and UV absorption spectra measured for the three isolated compounds are found to be clearly different. For the electrophoretic elution of the hypothetical [d(G(5)T(5))](4) quadruplex, the result of the molecularity of n = 4 obtained from the CD melting curve analysis provides further support for the formation of the parallel [d(G(5)T(5))](4) quadruplex already proposed. For the thermally treated equimolar mixture of d(G(5)T(5)) and d(C(5)A(5)), the fast band with a molecularity of n = 2 corresponds to the Watson-Crick duplex, d(G(5)T(5)). d(A(5)C(5)). The slow band with a molecularity of n = 4 indicates the antiparallel quadruplex [d(G(5)T(5)). d(A(5)C(5))](2), whose observed CD and UV spectra are different from those of [d(G(5)T(5))](4). By electrophoresis, after reannealing the eluted compound [d(G(5)T(5)). d(A(5)C(5))](2), a distinct photograph showing the band splitting of this quadruplex band into the lower duplex and upper quadruplex bands is not possible; but by a transilluminator, we occasionally observe this band splitting with the naked eye. The linear response polarizability tensor calculations for the thus determined structures of the [d(G(5)T(5))](4) quadruplex, the McGavin-like [d(G(5)T(5)). d(A(5)C(5))](2) quadruplex, and the Watson-Crick d(G(5)T(5)). d(A(5)C(5)) duplex are found to qualitatively predict the observed CD and UV spectra.

Mechanism of the interaction of EcoRII restriction endonuclease with two recognition sites. Probing of modified DNA duplexes as activators of the enzyme

The efficiency of cleavage of DNA duplexes with single EcoRII recognition sites by the EcoRII restriction endonuclease decreases with increasing substrate length. DNA duplexes of more than 215 bp are not effectively cleaved by this enzyme. Acceleration of the hydrolysis of long single-site substrates by EcoRII is observed in the presence of 11-14-bp substrates. The stimulation of hydrolysis depends on the length and concentration of the second substrate. To study the mechanism of EcoRII endonuclease stimulation, DNA duplexes with base analogs and modified internucleotide phosphate groups in the EcoRII site have been investigated as activators. These modified duplexes are cleaved by EcoRII enzyme with different efficiencies or are not cleaved at all. It has been discovered that the resistance of some of them can be overcome by incubation with a susceptible canonical substrate. The acceleration of cleavage of long single-site substrates depends on the type of modification of the activator. The modified DNA duplexes can activate EcoRII catalyzed hydrolysis if they can be cleaved by EcoRII themselves or in the presence of the second canonical substrate. It has been demonstrated that EcoRII endonuclease interacts in a cooperative way with two recognition sites in DNA. The cleavage of one of the recognition sites depends on the cleavage of the other. We suggest that the activator is not an allosteric effector but acts as a second substrate.

RecA-DNA helical filaments in genetic recombination

Paul Howard-Flanders et al proposed a molecular model of RecA-mediated recombination reaction six years ago. How does this model stand at present? In answering this question, we focus on two leading ideas of the original model, namely the proposal of the coaxial arrangement of the aligned DNA molecules within helical RecA filaments and the proposal of the ATP independence of the pairing stage of the recombination reaction. Results obtained after the model was proposed are reviewed and compared with these original assumptions and postulates of the model. EM visualization of recombining DNA molecules, studies of the energetics of the RecA-mediated recombination reaction and biochemical analysis of deproteinized joint molecules are fully consistent with a triple-stranded DNA arrangement during the RecA-mediated recombination reaction and demonstrate the ATP independence of the pairing stage of the reaction.

The pattern of restriction enzyme-induced banding in the chromosomes of chimpanzee, gorilla, and orangutan and its evolutionary significance

The pattern of banding induced by five restriction enzymes in the chromosome complement of chimpanzee, gorilla, and orangutan is described and compared with that of humans. The G banding pattern induced by Hae III was the only feature common to the four species. Although hominid species show almost complete chromosomal homology, the restriction enzyme C banding pattern differed among the species studied. Hinf I did not induce banding in chimpanzee chromosomes, and Rsa I did not elicit banding in chimpanzee and orangutan chromosomes. Equivalent amounts of similar satellite DNA fractions located in homologous chromosomes from different species or in nonhomologous chromosomes from the same species showed different banding patterns with identical restriction enzymes. The great variability in frequency of restriction sites observed between homologous chromosome regions may have resulted from the divergence of primordial sequences changing the frequency of restriction sites for each species and for each chromosomal pair. A total of 30 patterns of banding were found informative for analysis of the hominid genealogical tree. Using the principle of maximum parsimony, our data support a branching order in which the chimpanzee is more closely related to the gorilla than to the human.

Processive cleavage of concatemer DNA duplexes by Eco RII restriction endonuclease

Eco RII restriction endonuclease cleaves synthetic DNA-duplexes in which the recognition sites of this enzyme (5'...CCATGG...) are repeated every 9 base pairs with the alternating orientation of the central AT pair. It operates in a processive mode, i.e. the bound enzyme molecule slides along the substrate toward neighboring recognition sites. Nona-nucleotides are the main products of the cleavage. The data obtained neighboring recognition sites. Nona-nucleotides are the main products of the cleavage. The data obtained point to the capability of Eco RII endonuclease to recognize and cleave the substrate under both possible orientations of the central AT-pair of the recognition site with respect to the bound enzyme molecule. These data also show the close similarity of DNA structures in a complex with the enzyme and without.

'Interactive' recognition in EcoRI restriction enzyme-DNA complex

A solution study of interaction between DNA and EcoRI restriction enzyme shows that there is a definite distortion of DNA in the specific recognition complexes but no measurable DNA distortion in the non-specific interaction.

Construction and use of models designed to demonstrate some topological properties of multistranded nucleic acid structure and its possible bearing on recombination

A description is given of the construction and use of a simple model designed to show the consequences of association between duplexes to form some kind of four strand structure in recombination. The model was first devised to help in consideration of the work of Nash et al. (1980). Conclusions drawn from it may however be of wider interest. The model was designed with a detailed molecular model in mind (McGavin, 1971a, 1979). It could however apply to any close juxtaposition of duplexes. A close juxtaposition of duplexes is a feature of several models for recombination, although this is not often referred to explicitly as four strand structure.

Eukaryotic DNA methylation

Eukaryotic genomes contain 5-methylcytosine (5mC) as a rare base.5mC arises by postsynthetic modification of cytosine and occurs, at least in animals, predominantly in the dinucleotide CpG. The base is not distributed randomly in these genomes but conforms to a pattern. This pattern varies between taxa but appears to be inherited in a semi-conservative fashion. At the level of the genome, gross changes in the level of DNA methylation have been noted. This has encouraged speculation that the modification may play a role in cellular differentiation. Tissue-specific patterns of DNA methylation, predicted by various models of differentiation, have been found for most vertebrate genes so far examined. A correlation has emerged between the undermethylation of these regions and their transcription, but this is not always the case. While data for eukaryotic viral sequences are less equivocal, studies of this kind cannot in isolation distinguish between undermethylation being a cause or a consequence of gene activity. If it were a cause, it is probable that the demethylation of specific CpG sites would be a necessary yet not a sufficient condition for transcription to occur. The introduction of artificially methylated DNA sequences into individual eukaryotic cells by microinjection or transformation may provide the means to elucidate these questions in the future. In the meantime, the study of eukaryotic DNA methylation promises to contribute much to our understanding of the regulation of gene expression in these organisms.

Studies on sequence recognition by type II restriction and modification enzymes

Type II DNA restriction and modification systems are ideally suited for analysis of mechanisms by which proteins specifically recognize unique DNA sequences. Each system is comprised of a unique DNA recognition site and two enzymes, which in those cases examined in detail, are comprised of distinct polypeptide chains. Thus, not only are the DNA substrates extremely well defined, but each system affords the opportunity to compare distinct proteins which interact with a common DNA sequence. This review will focus only on those Type II systems which have been examined in sufficient molecular detail to permit some insight into modes of specific DNA-protein interaction.