Nucleotide sequence at the site of single-strand DNA breaks in Pseudomonas aeruginosa bacteriophage phi kF77

It is known that DNA molecules from the phage group phi k specific to Pseudomonas aeruginosa possess single-strand breaks (nicks). The sequences around the nicks in the bacteriophage phi kF77 DNA have been determined by various methods. In addition, an EcoRV-HindIII fragment, containing a nick, was cloned into the plasmid pUC9 and sequenced by Maxam-Gilbert technique. The sequence common for all nicks was CCTAohpCTCCGG.     

Physical map of Pseudomonas aeruginosa phage phi kF77 genome. Localization of sites sensitive to restriction endonucleases

A physical map of the P. aeruginosa bacteriophage phi kF77 has been constructed using the restriction endonucleases SalI, HindIII, EcoRI, EcoRV, MuI, XbaI, ClaI. The phi kF77 DNA is resistant to cleavage by the restriction endonucleases BamHI, BglII, HpaI, PstI, PvuII, SmaI, XhoI.     

Physical map of the DNA of bacteriophage tf of Pseudomonas putida

A physical map has been constructed for P. putida bacteriophage tf DNA containing single-strand breaks (nicks). Localization of cleavage sites for EcoRI, HindIII, HpaI ClaI, BamHI, SalI, XbaI and XhoI restriction endonucleases was determined. Position of single-strand breaks was mapped by electrophoretic analysis of denatured tf DNA and electron microscopy of partially denatured DNA samples. The tf genome is characterized by the presence of two classes of nicks differing in the frequency of their presence in population of bacteriophage DNA molecules.     

Isolation and characterization of Pseudomonas aeruginosa bacteriophage phikF77 mutants]

It was found that phage phi kF77 is resistant to all known Pseudomonas aeruginosa restriction systems. Three types of mutants (dc-) which were unable to grow on different restrictive strains were isolated. All of them belong to one complementation group. Some of these mutations affected also the number of nicks in phage phi kF77 DNA and increased phage resistance to temperature treatment. It may be supposed that genes responsible for antirestriction mechanisms and introduction of nicks into DNA are connected in definite way.     

A physical map of the genome of temperate phage phi 3T.

A physical map of the genome of Bacillus subtilis bacteriophage phi 3T was constructed by ordering the fragments produced by cleavage of phi 3T DNA with restriction endonucleases AvaII (2 fragments), BglI (2 fragments), SmaI (3 fragments), BamHI (6 fragments), SalI (7 fragments), AvaI (7 fragments), SacI (12 fragments), PstI (14 fragments), and BglII (26 fragments). Two techniques were used to order the fragments: (1) Sets of previously ordered restriction fragments were isolated and redigested with the endonuclease whose cleavage sites were to be mapped. (2) Fragments located near the ends of the genome or near the ends of other restriction fragments were ordered by treating the DNA with lambda exonuclease prior to restriction endonuclease cleavage. The susceptibility of phi 3T DNA to 15 other restriction endonucleases is also reported.     

Cleavage of Circular, Superhelical Simian Virus 40 DNA to a Linear Duplex by S1 Nuclease

S(1) nuclease, the single-strand specific nuclease from Aspergillus oryzae can cleave both strands of circular covalently closed, superhelical simian virus 40 (SV40) DNA to generate unit length linear duplex molecules with intact single strands. But circular, covalently closed, nonsuperhelical DNA, as well as linear duplex molecules, are relatively resistant to attack by the enzyme. These findings indicate that unpaired or weakly hydrogen-bonded regions, sensitive to the single strand-specific nuclease, occur or can be induced in superhelical DNA. Nicked, circular SV40 DNA can be cleaved on the opposite strand at or near the nick to yield linear molecules. S(1) nuclease may be a useful reagent for cleaving DNAs at regions containing single-strand nicks. Unlike the restriction endonucleases, S(1) nuclease probably does not cleave SV40 DNA at a specific nucleotide sequence. Rather, the sites of cleavage occur within regions that are readily denaturable in a topologically constrained superhelical molecule. At moderate salt concentrations (75 mM) SV40 DNA is cleaved once, most often within either one of the two following regions: the segments defined as 0.15 to 0.25 and 0.45 to 0.55 SV40 fractional length, clockwise, from the EcoR(I) restriction endonuclease cleavage site (defined as the zero position on the SV40 DNA map). In higher salt (250 mM) cleavage occurs preferentially within the 0.45 to 0.55 segment of the map.     

DNA fragmentation during apoptosis is caused by frequent single-strand cuts.

One of the hallmarks of apoptosis is the digestion of genomic DNA by an endonuclease, generating a ladder of small fragments of double-stranded DNA. We have examined the nature of the DNA breaks produced in mouse thymocytes triggered to undergo apoptosis by steroids or by stimulation of the T cell receptor. Whereas the typical ladder pattern of oligonucleosomal fragments was observed after agarose gel electrophoresis, numerous single-strand cuts were detected after electrophoresis under denaturing conditions. Single-strand nicks were found to be very frequent in the internucleosomal regions, but also to occur in the core particle-associated DNA. An identical pattern of single-strand nicks was obtained when chromatin DNA was exposed to the single-strand cleaving deoxyribonuclease I. The nicked DNA fragments, extracted from apoptotic thymocytes, were sensitive to the action of S1-nuclease. We propose that DNA fragmentation induced during apoptosis is not due to a double-strand cutting enzyme as previously postulated, but rather is the result of single-strand breaks. This ensures the dissociation of the DNA molecule at sites where cuts are found within close proximity.     

Characterization of a cloned ribosomal fragment from mouse which contains the 18S coding region and adjacent spacer sequences.

The large EcoRI fragment of mouse ribosomal genes containing parts of the non-transcribed spacer, the external transcribed spacer located at the 5' end of the precursor molecule and about two thirds of the 18S sequence has been cloned in bacteriophage lambda gtWES. A physical map of the DNA was constructed by cleavage with several restriction endonucleases and hybridization of the restriction fragments of the recombinant DNA with labelled 18S and 45S rRNA. The orientation of the inserted fragment as well as the length of the 18S sequence was determined by electron microscopy of R-loop containing molecules. The absence of hybridization of the cloned fragment to other fragments in the genome shows that the non-transcribed spacer does not have a significant length of sequences in common with other sequences in the genome.     

Processing of model single-strand breaks in phi X-174 RF transfecting DNA by Escherichia coli

The inactivation efficiency and repair of single-strand breaks was investigated using model strand breaks created by endonucleolytic incision of damaged DNA. Phi X-174 duplex transfecting DNA containing either thymine glycols, urea residues, or abasic (AP) sites was incubated with AP endonucleases that produce breaks on the 3' side, the 5' side, or both sides of the lesion. For each lesion, incubation with Escherichia coli endonuclease III results in a single-strand break containing a 3' alpha, beta-unsaturated aldehyde (4-hydroxy-2-pentenal), while treatment of AP- or urea-containing DNA with E. coli endonuclease IV results in a single-strand break containing a 5' deoxyribose or a 5' deoxyribosylurea moiety, respectively. Incubation of lesion-containing DNA with both enzymes results in a base gap. Ligatable nicks containing 3' hydroxyl and 5' phosphate moieties were produced by subjecting undamaged DNA to DNase I. When the biological activity of these DNAs was assessed in wild-type cells, ligatable nicks were not lethal, but each of the other strand breaks tested was lethal, having inactivation efficiencies between 0.12 and 0.14. These inactivation efficiencies are similar to those of the base lesions from which the strand breaks were derived. In keeping with the current model of base excision repair, when phi X duplex DNA containing strand breaks with a blocked 3' terminus was transfected into an E. coli double mutant lacking the major 5' cellular AP endonucleases, a greater than twofold decrease in survival was observed. Moreover, when this DNA was treated with a 5' AP endonuclease prior to transfection, the survival returned to that of wild type. As expected, when DNA containing strand breaks with a 5' blocked terminus or DNA containing base gaps was transfected into the double mutant lacking 5' AP endonucleases, the survival was the same as in wild-type cells. The decreased survival of transfecting DNA containing thymine glycols, urea, or AP sites observed in appropriate base excision repair-defective mutants was also obviated if the DNA was incubated with the homologous enzyme prior to transfection. Thus, in every case, with both base lesions and single-strand breaks, the lesion was repaired in the cell by the enzyme that recognizes it in vitro. Furthermore, the repair step in the cell could be eliminated if the appropriate enzyme was added in vitro prior to transfection.(ABSTRACT TRUNCATED AT 400 WORDS)     

Physical map of the bacteriophage T5 genome based on the cleavage products of the restriction endonucleases SalI, SmaI, BamI, and HpaI.

A physical map of the bacteriophage T5 genome was constructed by ordering the fragments produced by cleavage of T5 DNA with the restriction endonucleases SalI (4 fragments), SmaI (4 fragments), BamI (5 fragments), and HpaI (28 fragments). The following techniques were used to order the fragments. (i) Digestion of DNA from T5 heat-stable deletion mutants was used to identify fragments located in the deletable region. (ii) Fragments near the ends of the T5 DNA molecule were located by treating T5 DNA with lambda exonuclease before restriction endonuclease cleavage. (iii) Fragments spanning other restriction endonuclease cleavage sites were identified by combined digestion of T5 DNA with two restriction endonucleases. (iv) The general location of some fragments was determined by isolating individual restriction fragments from agarose gels and redigesting the isolated fragments with a second restriction enzyme. (v) Treatment of restriction digests with lambda exonuclease before digestion with a second restriction enzyme was used to identify fragments near, but not spanning, restriction cleavage sites. (vi) Exonucleases III treatment of T5 DNA before restriction endonuclease cleavage was used to locate fragments spanning or near the natural T5 single-chain interruptions. (vii) Analysis of the products of incomplete restriction endonuclease cleavage was used to identify adjacent fragments.     

水稻叶绿体DNA克隆片段的分析和rbcL基因在重组质粒上的定位

杂交灿稻(珍汕97B)的叶绿体DNA克隆到pBR 322载体上后,从克隆库中筛选出含核酮糖1.5-二磷酸羧化酶/加氧酶大亚基基因(rbcL)的重组子(19.3kb),用10种限制性内切酶分析了这个重组质粒并制作了完整的物理图谱,rbcL基因被定位在这个物理图谱上。     

Restriction endonuclease map of Euglena gracilis chloroplast DNA.

A physical map of the Euglena gracilis chloroplast genome has been constructed, based on cleavage sites of Euglena gracilis chloroplast DNA treated with bacterial restriction endonucleases. Covalently close, circular chloroplast DNA is cleaved by restriction endonuclease SalI into three fragments and by restriction endonuclease BamHI into six fragments. These nine cleavage sites have been ordered by fragment molecular weight analysis, double digestions, partial digestions, and by digestion studies of isolated DNA fragments. A fragment pattern of the products of EcoRI restriction endonuclease digestion of Euglena chloroplast DNA is also described. One of these fragments has been located on the cleavage site map.     

Physical map of the Rhodobacter sphaeroides bacteriophage phi RsG1 genome and location of the prophage on the host chromosome.

We constructed a physical map of the 50-kilobase-pair (kb) DNA of the temperate Rhodobacter sphaeroides bacteriophage phi RsG1, with the relative positions of the cleavage sites for the nine restriction endonucleases KpnI, HindIII, XbaI, ClaI, BclI, EcoRV, EcoRI, BglII, and BamHI indicated. Using biotinylated phi RsG1 DNA as a probe in hybridization studies, we detected homologies with virus DNA and fragments of restriction endonuclease-digested host chromosomal DNA but not with plasmid DNA. This indicates that the prophage is integrated into the host chromosome. In addition, the use of specific probes such as the 10.4-kb BglII A fragment and the 2.65-kb BamHI H fragment allowed the determination of the position of phage attachment site (attP).     

Induction of double-strand breaks by S1 nuclease, mung bean nuclease and nuclease P1 in DNA containing abasic sites and nicks.

Defined DNA substrates containing discrete abasic sites or paired abasic sites set 1, 3, 5 and 7 bases apart on opposite strands were constructed to examine the reactivity of S1, mung bean and P1 nucleases towards abasic sites. None of the enzymes acted on the substrate containing discrete abasic sites. Under conditions where little or no non-specific DNA degradation was observed, all three nucleases were able to generate double-strand breaks when the bistranded abasic sites were 1 and 3 base pairs apart. However, when the abasic sites were further apart, the enzymes again failed to cleave the DNA. These results indicate that single abasic sites do not cause sufficient denaturation of the DNA to allow incision by these single-strand specific endonucleases. The reactivity of these enzymes was also investigated on DNA substrates that were nicked by DNasel or more site-specifically by endonuclease III incision at the discrete abasic sites. The three nucleases readily induced a strand break opposite such nicks.     

Organization of ribosomal protein genes in Escherichia coli: II. Mapping of ribosomal protein genes by in vitro synthesis of ribosomal proteins using DNA fragments of a transducing phage as templates

The structural genes for six ribosomal proteins (r-proteins) located in the str-spc region around 64 minutes on the Escherichia coli chromosome have been mapped physically with respect to each other and the neighboring genes aroE and trkA. The genes code for the 30 S r-proteins S4 (ram), S5 (spc), S8, S11, S13 and S14. Furthermore, regions coding for unidentified 50 S r-proteins have been indicated.The mapping was performed by biochemical methods employing DNA from the specialized transducing phage λspc1, which carries the aroE-trkA-spc region of the E. coli chromosome. The phage DNA was cleaved by restriction endonucleases, and the generated DNA fragments used as templates for synthesis of r-proteins in a DNA-dependent cell-free system. Since the relative order of the DNA fragments created by the restriction endonucleases is known, a genetic map could be constructed.     

Adriamycin-mediated introduction of a limited number of single-strand breaks into supercoiled DNA

It was reported previously that Adriamycin converts form I covalently closed circular, supercoiled bacteriophage PM2 DNA to the relaxed circular form II DNA; no form III linear DNA was produced as a result of the extracellular action of Adriamycin in the presence of NADH-dehydrogenase. When form II DNA, produced by the action of Adriamycin, was treated with the BAL 31 nuclease, a single sharp DNA band after agarose gel electrophoresis indicated the presence of only full-length linear form III DNA. As one of its activities, the BAL 31 nuclease introduces a single-strand break in the complementary strand opposite a preexisting single-strand break. When form II DNA, produced by the action of gamma irradiation, was reacted with the BAL enzyme, the resulting linear DNA molecules exhibited a broad range of molecular weights, indicating the presence of many single-strand breaks in the substrate form II DNA. When the Adriamycin-produced form II DNA was treated with restriction endonucleases that cleave PM2 DNA at a single site, either with or without pretreatment with the BAL enzyme, the formation of only full-length linear DNA was observed. Thus, the drug is capable of introducing one or only a very limited number of single-strand breaks into supercoiled DNA; furthermore, these breaks are introduced at random sites along the DNA molecules.     

Physical mapping of the virion and the prophage DNAs of a temperate Lactobacillus phage phi FSW

We analysed the physical structure of the DNA of phi FSW, which is a temperate phage of Lactobacillus casei S-1. A circular restriction map of the virion DNA has been constructed with three restriction endonucleases, BamHI, SalI and XhoI. Other data indicated that the phage genome was circularly permuted. In lysogens, the DNA of the prophage was found to be linearized at a specific site and integrated into a specific locus of the host genome, with the same orientation in each case, as evidenced by Southern filter hybridization. We compared the physical structure of phi FSW with its three virulent mutants. One of them had a restriction map indistinguishable from that of phi FSW and two of them contained host-derived DNA sequence(s) in a specific region of the phi FSW genome (V-region). The prophage integration site was mapped on a different segment of the phage genome to the V-region. Derivation of virulent mutants from phi FSW is discussed in relation to the physical structure of the phage genome.     

The organization of ribosomal RNA genes in the mitochondrial DNA of Tetrahymena pyriformis strain ST.

1. We have constructed a physical map of the mtDNA of Tetrahymena pyriformis strain ST using the restriction endonucleases EcoRI, PstI, SacI, HindIII and HhaI. 2. Hybridization of mitochondrial 21 S and 14 S ribosomal RNA to restriction fragments of strain ST mtDNA shows that this DNA contains two 21-S and only one 14-S ribosomal RNA genes. By S1 nuclease treatment of briefly renatured single-stranded DNA the terminal duplication-inversion previously detected in this DNA (Arnberg et al. (1975) Biochim. Biophys. Acta 383, 359--369) has been isolated and shown to contain both 21-S ribosomal RNA genes. 14 S ribosomal RNA hybridizes to a region in the central part of the DNA, about 8000 nucleotides or 20% of the total DNA length apart from the nearest 21 S ribosomal RNA gene. 3. We have confirmed this position of the three ribosomal RNA genes by electron microscopical analysis of DNA . RNA hybrid molecules and R-loop molecules. 4. Hybridization of 21 S ribosomal RNA with duplex mtDNA digested either with phage lambda-induced exonuclease or exonuclease III of Escherichia coli, shows that the 21-S ribosomal RNA genes are located on the 5'-ends of each DNA strand. Electron microscopy of denaturated mtDNA hybridized with a mixture of 14-S and 21-S ribosomal RNAs show that the 14 S ribosomal RNA gene has the same polarity as the nearest 21 S ribosomal RNA gene. 5. Tetrahymena mtDNA is (after Saccharomyces mtDNA) the second mtDNA in which the two ribosomal RNA cistrons are far apart and the first mtDNA in which one of the ribosomal RNA cistrons is duplicated.     

Physical mapping of the immunity region of phage phi 80

Mapping of the sites of cleavage of five restriction endonucleases (BglI, BglII, EcoRV, KpnI and PvuII) in the immunity region of bacteriophage phi 80 DNA is described. The order of the 27 restriction sites was established. This helped to localize the phi 80 cI gene within the 640 bp fragment of the immunity region. Recombinant plasmids carrying phi 80 "kil" function were constructed. The function is suppressed by the cI-coded repressor. The deletion AB43 which is present in the phi 80 vir mutant is located within the phi 80 DNA fragment carrying the cI gene.     

Physical mapping of a large-plaque mutation of adenovirus type 2.

We have developed a simple method based on cotransfection of overlapping DNA restriction fragments for construction of recombinants of adenovirus type 2 (Ad2) and Ad5. When Ad2 DNA digested with restriction endonuclease EcoRI was cotransfected with Ad5 DNA digested with SalI, recombination occurred between Ad2 EcoRI-A (map position 0 to 59) and Ad5 SalI-A (map position 45 to 100). Analysis of the recombinant DNAs by digestion with EcoRI or BamHI restriction endonucleases indicated that, as expected, recombination had occurred in overlapping sequences (map position 45 to 59) between the Ad2 EcoRI-A fragment and the Ad5 SalI-A fragment. By using this method, several recombinants were constructed between a large-plaque (lp) mutant of Ad2 and wild-type Ad5. Cleavage of the recombinant genomes with restriction endonucleases BamHI, EcoRI, and HindIII revealed that the lp mutation is located within the left 41% of Ad2 genome.