EcoRI analysis of bacteriophage P22 DNA packaging.

Bacteriophage P22 linear DNA molecules are a set of circularly permuted sequences with ends located in a limited region of the physical map. This mature form of the viral chromosome is cut in headful lengths from a concatemeric precursor during DNA encapsulation. Packaging of P22 DNA begins at a specific site, which we have termed pac, and then proceeds sequentially to cut lengths of DNA slightly longer than one complete set of P22 genes (Tye et al., 1974b). The sites of DNA maturation events have been located on the physical map of EcoRI cleavage sites in P22 DNA. EcoRI digestion products of mature P22 wild-type DNA were compared with EcoRI fragments of two deletion and two insertion mutant DNAs. These mutations decrease or increase the length of the genome, but do not alter the DNA encapsulation mechanism. Thus the position of mature molecular ends relative to EcoRI restriction sites is different in each mutant, and comparison of the digests shows which fragments come from the ends of linear molecules. From the positions of the ends of molecules processed in sequential headfuls, the location of pac and the direction of encapsulation relative to the P22 map were deduced. The pac site lies in EcoRI fragment A, 4.1 × 10³ base-pairs from EcoRI cleavage site 1. Sequential packaging of the concatemer is initiated at pac and proceeds in the counterclockwise direction relative to the circular map of P22. One-third of the linears in a population are cut from the concatemer at pac, and most packaging sequences do not extend beyond four headfuls.Fragment D is produced by EcoRI cleavage at a site near the end of a linear chromosome which has been encapsulated starting at pac. The position of the pac site is therefore defined by one end of fragment D. The pac site is not located near genes 12 and 18, the only known site for initiation of P22 DNA replication, but lies among late genes at a position on the physical gene map approximately analogous to the cohesive end site (cos) of bacteriophage λ at which λ DNA is cleaved during encapsulation. Our results suggest that P22 and λ DNA maturation mechanisms have many common properties.     

Action of Escherichia coli P1 restriction endonuclease on simian virus 40 DNA

The P1 restriction endonuclease (EcoP1) prepared from a P1 lysogen of Escherichia coli makes one double-strand break in simian virus (SV40) DNA. In the presence of cofactors S-adenosylmethionine and ATP the enzyme cleaves 70% of the closed circular SV40 DNA molecules once to produce unit-length linear molecules and renders the remaining 30% resistant to further cleavage. No molecules were found by electron microscopy or by gel electrophoresis that were cleaved more than once. It would appear that the double-strand break is made by two nearly simultaneous single-strand breaks, since no circular DNA molecules containing one single-strand break were found as intermediates during the cleavage reaction. The EcoP1 endonuclease-cleaved linear SV40 DNA molecules are not cleaved at a unique site, as shown by the generation of about 65% circular molecules after denaturation and renaturation. These EcoP1 endonuclease-cleaved, renatured circular molecules are resistant to further cleavage by EcoP1 endonuclease.The EcoP1 endonuclease cleavage sites on SV40 DNA were mapped relative to the partial denaturation map and to the EcoRI and HpaII restriction endonuclease cleavage sites. These maps suggest there are a minimum of four unique but widely spaced cleavage sites at 0.09, 0.19, 0.52, and 0.66 SV40 units relative to the EcoRI site. The frequency of cleavage at any particular site differs from that at another site. If S-adenosylmethionine is omitted from the enzyme reaction mix, SV40 DNA is cleaved into several fragments.An average of 4.6 ± 1 methyl groups are transferred to SV40 DNA from S-adenosylmethionine during the course of a normal reaction containing the cofactors. Under conditions which optimize this methylation, 7 ± 1 methyl groups can be transferred to DNA. This methylation protects most of the molecules from further cleavage. The methyl groups were mapped relative to the Hemophilus influenzae restriction endonuclease fragments. The A fragment receives three to four methyl groups and the B and G fragments each receive one to two methyl groups. These fragments correspond to those in which cleavage sites are located.     

Functional cooperation between exonucleases and endonucleases--basis for the evolution of restriction enzymes

Many types of restriction enzymes cleave DNA away from their recognition site. Using the type III restriction enzyme, EcoP15I, which cleaves DNA 25–27 bp away from its recognition site, we provide evidence to show that an intact recognition site on the cleaved DNA sequesters the restriction enzyme and decreases the effective concentration of the enzyme. EcoP15I restriction enzyme is shown here to perform only a single round of DNA cleavage. Significantly, we show that an exonuclease activity is essential for EcoP15I restriction enzyme to perform multiple rounds of DNA cleavage. This observation may hold true for all restriction enzymes cleaving DNA sufficiently far away from their recognition site. Our results highlight the importance of functional cooperation in the modulation of enzyme activity. Based on results presented here and other data on well-characterised restriction enzymes, a functional evolutionary hierarchy of restriction enzymes is discussed.     

Methylation and cleavage sequences of the EcoP1 restriction-modification enzyme.

EcoP1 is a restriction modification enzyme encoded by bacteriophage P1. It requires ATP for cleavage and S-adenosyl methionine for methylation of DNA. We have mapped the sites of both cleavage and methylation in simian virus 40 DNA and determined their sequences. The enzyme methylates the sequence A-G-mA-C-C and cuts the DNA 25 to 27 base-pairs from the site of methylation in the 3′ direction, with a two to four base-pair stagger between cuts. Consistent with the fact that the methylation sequence is asymmetric, the enzyme methylates only one strand in vitro. One variant of simian virus 40 has acquired an additional EcoP1 methylation and cleavage site by changing a A-G-A-A-C sequence to A-G-A-C-C.     

Studies on the cleavage of bacteriophage lambda DNA with EcoRI restriction endonuclease

The five EcoRI² restriction sites in bacteriophage lambda DNA have been mapped at 0.445, 0.543, 0.656, 0.810, and 0.931 fractional lengths from the left end of the DNA molecule. These positions were determined electron-microscopically by single-site cleavage of hydrogen-bonded circular λ DNA molecules and by cleavage of various DNA heteroduplexes between λ DNA and DNA from well defined λ mutants. The DNA lengths of the EcoRI fragments are in agreement with their electrophoretic mobility on agarose gels but are not in agreement with their mobilities on polyacrylamide gels. These positions are different from those previously published by Allet et al. (1973). Partial cleavage of pure λ DNA by addition of small amounts of EcoRI endonuclease does not lead to random cleavage between molecules. Also, the first site cleaved is not randomly distributed among the five sites within a molecule. The site nearest the right end is cleaved first about ten times more frequently than either of the two center sites.     

Restriction and modification enzymes detect no allosteric changes in DNA with bound lac repressor or RNA polymerase

A 203 base-pair fragment containing the lac operator/promoter region of Escherichia coli was inserted into the EcoRI site of the plasmid vector pKC7. Rates of restriction endonuclease cleavage of the flanking EcoRI sites and of several other restriction sites on the DNA molecule were then compared in the presence and absence of bound RNA polymerase or lac repressor. The rates were identical whether or not protein had been bound, even for sites as close as 40 base-pairs from a protein binding site. No difference was detected using supercoiled, nicked circular, or linear DNA substrates. No apparent change in the rates of methylation of EcoRI sites by EcoRI methylase was produced by binding the regulatory proteins.     

Restriction insensitivity in bacteriophage T5. III. Characterization of EcoRI-sensitive mutants by restriction analysis.

Despite the fact that its DNA carries six EcoRI cleavage sites, bacteriophage T5 is able to grow on an EcoRI restricting host, suggesting that it specifies a restriction protection system. In the hope of identifying this protection system, mutants of T5 have been isolated which are unable to grow on an EcoRI restricting host. Analysis of the DNA of such mutants shows that they have each acquired two new EcoRI sites per molecule as a consequence of a single EcoRI site (ris) mutation located in the terminally repetitious, first step transfer (FST) region of the genome. The EcoRI sites generated by the ris mutations differ from the natural EcoRI sites in that the latter are situated on the second step transfer (SST) DNA, which suggests that the in vivo sensitivity of ris mutants is a consequence of having an EcoRI site on the FST DNA. This is understandable, if the hypothetical restriction protection genes are also located on the FST DNA. While expression of these genes would protect natural sites on the SST DNA, the ris sites would, on the contrary, enter an environment in which the protection, products had not yet been synthesized.Construction of double and triple ris mutants has allowed the ordering of the ris sites and the construction of an EcoRI restriction map of the FST region. In addition, the ris mutants allow estimation of the size of the terminal repetition of T5 DNA as 5.9 × 10⁶ to 6.0 × 10⁶ daltons. Correlation of the physical map of the FST region with the already established genetic map of this region allows orientation of the pre-early genes on the genetic and physical maps, and approximate localization of two amber mutations on the physical map.     

The nucleotide sequence recognized by the Escherichia coli K12 restriction and modification enzymes.

The sites recognized by the Escherichia coli K12 restriction endonuclease were localized to defined regions on the genomes of phage φXsK1, φXsK2, and G4 by the marker rescue technique. Methyl groups placed on the genome of plasmid pBR322 by the E. coli K12 modification methylase were mapped in HinfI fragments 1 and 3, and HaeIII fragments 1 and 3. A homology of seven nucleotides in the configuration: 5′-A-A-C .. 6N .. G-T-G-C-3′, where 6N represents six unspecified nucleotides, was found among the DNA sequences containing the five EcoK sites of φXsK1, φXsK2, G4, and pBR322. Three lines of evidence indicate that this sequence constitutes the recognition site of the E. coli K12 restriction enzyme. The C in 5′-A-A-C and the T in 5′-G-T-G-C are locations of mutations leading to loss or gain of the site and thus are positions recognized by the enzyme. This sequence does not occur on φXam3cs70, simian virus 40 (SV40), and fd DNAs which do not possess EcoK sites, and occurs only once on φXsK1, φXsK2, and G4 DNAs, and twice on pBR322 DNA. In order to prove that all seven conserved nucleotides are essential for the recognition by the E. coli K12 restriction enzyme, the nucleotide sequences of φX174, G4, SV40, fd, and pBR322 were searched for sequences differing from the sequence 5′-A-A-C .. 6N .. G-TG-C-3′ at only one of the specified positions. It was found that sequences differing at each of the specified positions occur on DNA sequences that do not contain the EcoK sites. Thus, the recognition site of the E. coli K12 restriction enzyme has the same basic structure as that of the EcoB site (Lautenberger et al., 1978). In each case there are two domains, one containing three and the other four specific nucleotides, separated by a sequence of unspecified bases. However, the unspecified sequence in the EcoK site must be precisely six bases instead of the eight found in the EcoB site. Alignment of the EcoK and EcoB sites suggests that four of the seven specified nucleotides are conserved between the sequences recognized by these two allelic restriction and modification systems.     

An electron microscopic method for studying and mapping the region of weak sequence homology between simian virus 40 and polyoma DNAs.

A procedure for investigating the possibility of small amounts of partial DNA sequence homology between two defined DNA molecules has been developed and used to test for sequence homology between simian virus 40 and polyoma DNAs. This procedure, which does not necessitate the use of separated viral DNA strands, involves the construction of hybrid DNA molecules containing a simian virus 40 DNA molecule covalently joined to a polyoma DNA molecule, using the sequential action of EcoRI restriction endonuclease and Escherichia coli DNA ligase. Denaturation of such hybrid DNA molecules then makes it possible to examine intramolecularly rather than intermolecularly renatured molecules. Visualization of these intramolecularly renatured “snapback” molecules with duplex regions of homology by electron microscopy reveals a 15% region of weak sequence homology. This region is denatured at about 35 °C below the melting temperature of simian virus 40 DNA and therefore corresponds to about 75% homology. This region was mapped on both the simian virus 40 and polyoma genomes by the use of Hemophilus parainfluenzae II restriction endonuclease cleavage of the simian virus 40 DNA prior to EcoRI cleavage and construction of the hybrid molecule. The 15% region of weak homology maps immediately to the left of the EcoRI restriction endonuclease cleavage site in the simian virus 40 genome and halfway around from the EcoRI restriction endonuclease cleavage site in the polyoma genome.     

Triplication of a unique genetic segment in a simian virus 40-like virus of human origin and evolution of new viral genomes

The non-defective (heavy) virions from a simian virus 40-like virus (DAR virus) isolated from human brain have been serially passaged at high input multi-plicities in primary monkey kidney cells. The ³²P-labeled, progeny DAR-viral genomes have been purified and tested for sensitivity to the R_I restriction endouclease from Escherichia coli (Eco RI3 restriction nuclease). The parental DAR-viral genomes share many physical properties with “standard” simian virus 40 DNA and are cleaved once by the Eco RI restriction nuclease. After the fourth serial passage, three populations of genomes could be distinguished: Eco RI resistant, Eco RI sensitive (one cleavage site) and Eco RI “supersensitive” (three, symmetrically-located, cleavage sites). The Eco RI cleavage product of the “supersensitive” form is one-third the physical size (10.4 S) of simian virus 40 DNA and reassociates about three times more rapidly than sheared, denatured simian virus 40 DNA. From the fourth to the eighth serial passages, the genomes containing this specific triplication of viral DNA sequences were selected for and became the predominant viral DNA species.     

Subunit structure of chromatin and the organization of eukaryotic highly repetitive DNA: indications of a phase relation between restriction sites and chromatin subunits in African green monkey and calf nuclei.

The periodicities of the restriction enzyme cleavage sites in highly repetitive DNAs of six mammalian species (monkey, mouse, sheep, human, calf and rat) appear related to the length of DNA contained in the nucleosome subunit of chromatin. We suggest that the nucleosome structure is an essential element in the generation and evolution of repeated DNA sequences in mammals (Brown et al., 1978; Maio et al., 1977). The possibility of a phase relation between DNA repeat sequences and associated nucleosome proteins is consistent with this hypothesis and has been tested by restriction enzyme and micrococcal nuclease digestions of repetitive DNA sequences in isolated, intact nuclei.Sites for four different restriction enzyme activities, EcoRI, EcoRI¹, HindIII and HaeIII have been mapped within the repeat unit of component α DNA, a highly repetitive DNA fraction of the African green monkey. The periodicity of cleavage sites for each of the enzymes (176 ± 4 nucleotide base-pairs) corresponds closely to the periodicity (about 185 nucleotide base-pairs) of the sites attacked in the initial stages of micrococcal nuclease digestion of nuclear chromatin. In intact monkey nuclei, EcoRI-RI¹ sites are accessible to restriction enzyme cleavage; the HindIII and HaeIII sites are not. The results suggest (1) that, in component α chromatin, the EcoRI-RI¹ sites are found at the interstices of adjacent nucleosomes and (2) the HindIII and HaeIII sites are protected from cleavage by their location on the protein core of the nucleosome. This interpretation was confirmed by experiments in which DNA segments of mononucleosomes and nucleosome cores released from CV-1 nuclei by micrococcal nuclease were subsequently treated with EcoRI, EcoRI¹ and HindIII. A major secondary segment of component α, about 140 nucleotide base-pairs in length, was released only by treatment with HindIII, in keeping with the location of the HindIII sites in the restriction map and their resistance to cleavage in intact nuclei.EcoRI reduces calf satellite I DNA to a segment of about 1408 nucleotide basepairs. In contrast, restriction of calf satellite I DNA with EcoRI¹ produces six prominent segments ranging in size from 176 to 1408 nucleotide base-pairs. Treatment of isolated calf nuclei with either EcoRI or EcoRI¹ did not produce segments shorter than 1408 base-pairs, indicating that while canonical EcoRI sites are accessible to attack, the irregularly spaced EcoRI¹ sites are specifically blocked. The results are consistent with a phase relation between the repeat sequence of calf satellite I DNA and an octameric array of nucleosomes.     

Sequence specificity of the P1 modification methylase (M.Eco P1) and the DNA methylase (M.Eco dam) controlled by the Escherichia coli dam gene.

Labeled oligonucleotides have been fractionated from pancreatic DNase digests of DNA that had been methylated in vitro with the P1 modification enzyme (M·Eco P1) or with the DNA-adenine methylase (M·Eco dam) controlled by the Escherichia coli dam gene. The sequences of methylated oligonucleotides were established for M·Eco dam modification of calf thymus DNA. The results show that M·Eco dam inethylates adenine residues contained in the twofold symmetrical sequence, 5′ … G-A-T-C … 3′. The sequence for the site methylated by M·Eco P1 has also been deduced; we propose that M·Eco P1 modification produces the following methylated pentameric sequence: 5′ … A-G-A¹-C-Py … 3′ (where $\text{A}{}^1\text{= N}{}^6$ methyladenine and Py is C or T).     

The DNA sequence on bacteriophage G4 recognized by the Escherichia coli B restriction enzyme.

Bacteriophage G4 possesses a single EcoB site located in the overlap between restriction fragments HinfI-12 and HaeIII-6. The sequence 5′-T-G-A … 8N … T-G-C-T occurs once in this segment and nowhere else in the DNA sequence of G4. Four independent G4 mutants that were not restricted by Escherichia coli B possessed the sequence 5′-T-G-A … 8N … T-G-C-C. The common sequence shared by the previously mapped EcoB sites on φXsB1, simian virus 40, f1, and fd DNAs is 5′-T-G-A … 8N … T-G-C-T … 9N … T. However, the sequence in the region of the G4 EcoB site contains an A instead of the final T conserved in these other examples. When the G4 EcoB site is aligned with the other EcoB sites, there are no conserved residues within 50 bases of the common sequence, 5′-T-G-A … 8N … T-G-C-T, except for those seven residues. The analysis of the EcoB site on G4 provides further evidence that only those seven bases are recognized by the E. coli B restriction enzyme.     

Cartographie de Restriction Comparée du Satellite DNA chez l'Homme et le Chimpanzé

Highly repeated DNA satellite α sequences from man and chimpanzee (Pan troglodytes) have been compared, using restriction endonucleases. The two species share a 340 base pairs tandemly represented DNA, that is cut once by EcoRt. Pan troglodytes differ from man by loss of the two MboI and EcoRI star sites and by the gain of an Hae III site in the repeated sequence.     

Characterization of small plasmids from Staphylococcus aureus.

Small molecular weight plasmids from Staphylococcus aureus were characterized with respect to size, restriction enzyme cleavage pattern and transforming capacity. The plasmids pS194 and pC194 which encode streptomycin and chloramphenicol resistance respectively contained 3.0 and 2.0 megadaltons of DNA as determined by zonal rate centrifugation and electron-microscopy. Both plasmids transformed S. aureus with high efficiency. Plasmid pC194 contained only one cleavage site for endonuclease HindIII and pS194 contained single cleavage sites for HindIII and EcoRI. A natural recombinant between these two plasmids, pSC194, shared the high transforming capacity of the parental plasmids and contained one EcoRI site And two HindIII sites. pSC194 DNA also transformed B. subtilis with high efficiency. The recombinant plasmid pSC194 may be used as an EcoRI vector for construction and propagation of hybrid DNA in S. aureus as shown in the following paper (Löfdahl et al., 1978).     

Influence of phage T3 and T7 gene functions on a type III(EcoP1) DNA restriction-modification system in vivo

Summary The ocr ⁺ gene function (gp 0.3) of bacteriophages T3 and T7 not only counteracts type I (EcoB, EcoK) but also type III restriction endonucleases (EcoP1). Despite the presence of recognition sites, phage DNA as well as simultaneously introduced plasmid DNA are protected by ocr ⁺ expression against both the endonucleolytic and the methylating activities of the EcoP1 enzyme. Nevertheless, the EcoP1 protein causes the exclusion of T3 and T7 in P1-lysogenic cells, apparently by exerting a repressor-like effect on phage gene expression. T3 which induces an S-adenosylmethionine hydrolase is less susceptible to the repressor effect of the SAM-stimulated EcoP1 enzyme. The abundance of EcoP1 recognition sites in the T7 genome is explained by their near identity with the T7 DNA primase recognition site.Abbreviations d.p.m. decompositions per min - EcoB, EcoK, EcoP1, EcoP15, EcoRII, EcoR124, HinfIII restriction endonucleases coded by Escherichia coli strains B or K, E. coli plasmids P1, P15, RII or R124, and Haemophilus influenzae Rf 232, resp. - e.o.p. efficiency of plating - gp gene product (in the sense of protein) - m.o.i. multiplicity of infection (phage/cell) - ocr ⁺ gene function which overcomes classical restriction - p.f.u. plaque-forming units - SAM S-adenosylmethionine - sam ⁺ gene function with S-adenosylmethionine-cleaving enzyme (SAMase) activity - UV ultraviolet light Dedicated to Professor Konstantin Spies on the occasion of his sixtieth birthday     

Site-directed mutagenesis in DNA: Generation of point mutations in cloned β globin complementary DNA at the positions corresponding to amino acids 121 to 123

We have utilized the principle of site-directed mutagenesis, previously applied to the RNA of bacteriophage Qβ, to generate nucleotide transitions in a predetermined region of DNA. Plasmid PβG, which contains an almost complete DNA copy of rabbit β globin messenger RNA, was nicked at the EcoRI site which is located within the globin gene, in a region corresponding to amino acids 121 and 122. Substrate-limited nick translation using DNA polymerase I and N⁴-hydroxydCTP, dCTP and dATP led to the replacement of TMP residues by the nucleotide analog in the immediate vicinity of the nicks. The substituted DNA was amplified in vivo, treated with EcoRI and retransfected. 1.9% of the amplified DNA was found to be EcoRI-resistant. Nucleotide sequence analysis of the critical region of six EcoRI-resistant isolates revealed that two plasmids had one, three had two and one had three A · T → G · C transitions, all located within the substituted region. No point mutations (< 3 × 10^?3%) were found in control preparations; however, a small number of deletion mutants, lacking the EcoRI site, were isolated.