Construction of a restriction map of bacteriophage T3 DNA

A restriction endonuclease cleavage map of bacteriophage T3 DNA has been constructed. The enzymes used and, within parentheses, the number of their cleavage sites on T3 DNA are: HindIII (1), XbaI (1), BglII (1), KpnI (2), MboI (9), and HpaI (17). The size and the relative location of each fragment have been established, defining an accurate physical map of T3 DNA.     

New physical map of bacteriophage T5 DNA.

The locations of 103 cleavage sites, produced by 13 restriction endonucleases, were mapped on the DNA of bacteriophage T5. Single- and double-digest fragment sizes were determined by agarose gel electrophoresis, using restriction fragments of phi X174 DNA and lambda DNA as molecular weight standards. Map coordinates were determined by a computer-based least-squares procedures (J. Schroeder and F. Blattner, Gene [Amst] 4:167-174, 1978). The fragment sizes predicted by the final map are all within 2% of the measured values. Based on this analysis, T5st(+) DNA contains 121,300 base pairs (Mr, 80.3 X 10(6) and has a terminal repetition of 10,160 base pairs (Mr, 6.7 X 10(6)). Restriction endonuclease analysis after treatment with exonuclease III and a single-strand-specific endonuclease allowed precise localization of five of the natural single-chain interruptions in T5 DNA. Revised locations for several T5 deletions were also determined.     

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 map of bacteriophage phiX174 RF DNA by restriction enzymes.

phiX RF DNA was cleaved by restriction enzymes from Haemophilus influenzae Rf (Hinf I) and Haemophilus haemolyticus (Hha. I). Twenty one fragments of approximately 25 to 730 base pairs were produced by Hinf I and seventeen fragments of approximately 40 to 1560 base pairs by Hha I. The order of these fragments has been established by digestion on Haemophilus awgyptius (Hae III) and Arthrobacter luteus (Alu I) endonuclease fragments of phiX RF with Hinf I and Hha1. By this method of reciprocal digestion a detailed cleavage map of phiX RF DNA was constructed, which includes also the previously determined Hind II, Hae III and Alu I cleavage maps of phiX 174 RF DNA (1, 2). Moreover, 28 conditional lethal mutants of bacteriophage phiX174 were placed in this map using the genetic fragment assay (3).     

New map of bacteriophage lambda DNA.

A map of bacteriophage lambda was constructed, including accurate positions for all 41 cut sites made by 12 different restriction enzymes. Over 100 fragments from single, multiple, and partial enzyme digestions were measured versus standards that were calibrated with respect to DNA molecules of known sequence. The data were subjected to least-squares analysis to assign map coordinates. In no case did a fragment size predicted from the map differ from the measurement of the fragment by more than +/- 5%. This low error rate was consistent in all size ranges of fragments. The total length of lambda was calculated as 49,133 nucleotide pairs. This probably is accurate to within 500 base pairs.     

Physical mapping of bacteriophage T4

Summary The 134 positions of the cleavage sites of the restriction endonucleases XbaI, HaeII and EcoRI were determined for a cytosine-containing DNA of bacteriophage T4. This physical map was aligned with the genetic map. The T4 early regions were further identified by hybridization of RNA synthesized in vitro to the restriction fragments and two promoter regions were localized by filter binding tests and R-loop analysis.     

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.     

Cloning of bacteriophage T5 DNA fragments in plasmid pBR322 and bacteriophage lambda gtWES

Bacteriophage T5 was digested with the restriction endonucleases HindIII and EcoRI and the resulting fragments were inserted into the plasmid pBR322 and the bacteriophage lambda gtWES as vectors. Approx. 15% of the phage genome was recovered in recombinant clones. The recombinants were characterized by restriction analysis, DNA/DNA hybridization employing Southern blots, and ability to complement or recombine with amber mutants of T5. The results obtained allow revisions of the physical map of the T5 genome and partial correlation of the physical map with the genetic map.     

In vivo restriction. Sequence and structure of endonuclease II-dependent cleavage sites in bacteriophage T4 DNA.

Endonuclease II of bacteriophage T4 is required for in vivo restriction of cytosine-containing DNA from its host, Escherichia coli, (as well as from phage mutants lacking cytosine modification), normally the first step in the reutilization of host DNA nucleotides for synthesis of phage DNA in infected cells. The phage cytosine-DNA is fragmented incompletely to yield genetically defined fragments. This restriction is different from that of type I, II, or III restriction enzymes. We have located seven major endonuclease II-dependent restriction sites in the T4 genome, of which three were analyzed in detail; in addition, abundant sites were cleaved in less than or equal to 5% of all molecules. Sites I, II, and III shared the sequence 5'-CCGNNTTGGC-3' and were cleaved in about 25% (I and III) and 65% (II) of all molecules, predominantly staggered around the first or second of the central unspecified base pairs to yield fragments with one 5' base. The less frequently cleaved sites I and III deviated from site II in predicted helical structure when viewed from the consensus strand, and in sequence when viewed from the opposite strand. Thus, interaction with a particular helical structure as well as recognition of the bases in DNA appears important for efficient cleavage.     

Map of restriction sites on bacteriophage T4 cytosine-containing DNA for endonucleases bamHI, BglII, KpnI, PvuI, SalI, and XbaI.

A complete map of the cleavage sites of restriction endonucleases BamHI, BglII, KpnI, PvuI, SalI, and XbaI was determined for the cytosine-containing DNA of a bacteriophage T4 alc mutant. The 56 sequence-specific sites were assigned map coordinates based on a least-squares analysis of measured fragment lengths. Altogether, the lengths of 118 fragments from single and double enzyme digestions were measured by electrophoresis of the fragments in agarose gels. DNA fragments of known sequence or DNA fragments calibrated with fragments of known sequence were used as standards. The greatest deviation between an experimentally measured fragment length and its computed map coordinates was 3.0%; the average deviation was 0.8%. The total length of the wild-type T4 genome was calculated to be 166,200 base pairs.     

A physical map of the group A streptococcal pyrogenic exotoxin bacteriophage T12 genome

A physical map of group A streptococcal bacteriophage T12 was constructed with restriction endonucleases Sal/I, PstI, and EcoRI. The map is circularly permuted with a total length of 36.0 kb. Sub-molar quantities of certain restriction fragments, some of very precise MW and some of heterogeneous MW, were observed. This observation, together with mapping data, suggests that DNA packaging is initiated at a precise site on a concatemeric precursor and proceeds for a limited number of rounds.     

Single-event analysis of the packaging of bacteriophage T7 DNA concatemers in vitro.

Bacteriophage T7 packages its double-stranded DNA genome in a preformed protein capsid (procapsid). The DNA substrate for packaging is a head-to-tail multimer (concatemer) of the mature 40-kilobase pair genome. Mature genomes are cleaved from the concatemer during packaging. In the present study, fluorescence microscopy is used to observe T7 concatemeric DNA packaging at the level of a single (microscopic) event. Metabolism-dependent cleavage to form several fragments is observed when T7 concatemers are incubated in an extract of T7-infected Escherichia coli (in vitro). The following observations indicate that the fragment-producing metabolic event is DNA packaging: 1) most fragments have the hydrodynamic radius (R(H)) of bacteriophage particles (+/-3%) when R(H) is determined by analysis of Brownian motion; 2) the fragments also have the fluorescence intensity (I) of bacteriophage particles (+/-6%); 3) as a fragment forms, a progressive decrease occurs in both R(H) and I. The decrease in I follows a pattern expected for intracapsid steric restriction of 4',6-diamidino-2-phenylindole (DAPI) binding to packaged DNA. The observed in vitro packaging of a concatemer's genomes always occurs in a synchronized cluster. Therefore, the following hypothesis is proposed: the observed packaging of concatemer-associated T7 genomes is cooperative.     

A restriction endonuclease cleavage map of mitochondrial DNA from transformed hamster cells.

Mitochondrial DNA from cultured C13/B4 hamster cells was cleaved by the restriction endonucleases Hpa II, Hind III, Eco RI and Bam HI into 7, 5, 3 and 2 unique fragments, respectively. The summed molecular weights of fragments obtained from electrophoretic mobilities in agarose-ethidium bromide gels (with Hpa I-cleaved T7 DNA as standard) and electron microscopic analysis of fragment classes isolated from gels (with SV40 DNA as standard) were in good agreement with the size of 10.37 +/- 0.22 x 10(6) daltons (15,700 +/- 330 nucleotide pairs) determined for the intact circular mitochondrial genome. Cyclization of all Hind III, Eco RI and Bam HI fragments was observed. A cleavage map containing the 17 restriction sites (+/- 1% s.d.) was constructed by electrophoretic analysis of 32P-labeled single- and double-enzyme digestion products and reciprocal redigestion of isolated fragments. The 7 Hpa II sites were located in one half of the genome. The total distribution of the 17 cleavages around the genome was relatively uniform. The position of the D-loop was determined from its location and expansion on 3 overlapping restriction fragments.     

Structure and synthesis of a lipid-containing bacteriophage. XIX. Reconstitution of bacteriophage PM2 in vitro.

In order to construct a physical map of the bacteriophage fd genome, the doubly closed replicative form (RFI) DNA of phage fd was cleaved into unique fragments by four different restriction endonucleases (Hap, Hga, HinH and Hind) prepared from Haemophilus strains H. aphirophilus, H. gallinarum, H. influenzae H-I and H. influenzae Rd, respectively. As Hind cleaved RFI DNA at a single site, this site was used as a reference point for mapping. HinH cleaved RFI DNA at three sites, Hga at six sites and Hap at 13 sites, respectively. The 5′-termini of the fragments produced by either HinH or Hga were labelled with ³²P in the polynucleotide kinase reaction. The labelled fragments were separated and further cleaved by other enzymes. The re-digestion products of partially digested fragments were also analysed. On the basis of these data and estimates of the size of each fragment, a cleavage map of the phage fd genome was constructed.     

Characterization of bacteriophage T3 DNA ligase

DNA ligases of bacteriophage T4 and T7 have been widely used in molecular biology for decades, but little is known about bacteriophage T3 DNA ligase. Here is the first report on the cloning, expression and biochemical characterization of bacteriophage T3 DNA ligase. The polyhistidine-tagged recombinant T3 DNA ligase was shown to be an ATP-dependent enzyme. The enzymatic activity was not affected by high concentration of monovalent cations up to 1 M, whereas 2 mM ATP could inhibit its activity by 50%. Under optimal conditions (pH 8.0, 0.5 mM ATP, 5 mM DTT, 1 mM Mg(2+) and 300 mM Na(+)), 1 fmol of T3 DNA ligase could achieve 90% ligation of 450 fmol of cohesive dsDNA fragments in 30 min. T3 DNA ligase was shown to be over 5-fold more efficient than T4 DNA ligase for ligation of cohesive DNA fragments, but less active for blunt-ended DNA fragments. Phylogenetic analysis showed that T3 DNA ligase is more closely related to T7 DNA ligase than to T4 DNA ligase.     

Survey and mapping of restriction endonuclease cleavage sites in bacteriophage T7 DNA.

A survey of restriction endonucleases having different cleavage specificities has identified 10 that do not cut wild-type bacteriophage T7 DNA, 11 that cut at six or fewer sites, four that cut at 18 to 45 sites, and 12 that cut at more than 50 sites. All the cleavage sites for the 13 enzymes that cut at 26 or fewer sites have been mapped. Cleavage sites for each of the 10 enzymes that do not cut T7 DNA would be expected to occur an average of 9 to 10 times in a random nucleotide sequence the length of T7 DNA. A possible explanation for the lack of any cleavage sites for these enzymes might be that T7 encounters enzymes having these specificities in natural hosts, and that the sites have been eliminated from T7 DNA by natural selection. Five restriction endonucleases were found to cut within the terminal repetition of T7 DNA; one of these, KpnI, cuts at only three additional sites in the T7 DNA molecule. The length of the terminal repetition was estimated by two independent means to be approximately 155 to 160 base-pairs.     

Structure and restriction enzyme maps of the circularly permuted DNA of staphylococcal bacteriophage phi 11.

One restriction enzyme map of Staphylococcus aureus bacteriophage phi 11 DNA was established by reciprocal double digestions with the enzymes EcoRI, HaeII, and KpnI. The sequential order of the EcoRI fragments was thereafter established by a novel approach involving blotting of DNA partially cleaved with EcoRI and the probing the blots with nick-translated terminal fragments. A circular map of the phi 11 DNA was established, and the phage genome was circularly permuted based on the failure to end label mature viral DNA, restriction maps of replicating DNA, and finally, homoduplex analysis in the electron microscope. A restriction enzyme map of the prophage form of phi 11 DNA was obtained by analysis of chromosomal DNA from a lysogenic strain.     

HindII, HindIII, and HpaI restriction fragment maps of bacteriophage lambda DNA

The site-specific restriction endonucleases isolated from Hemophilus influenzae strains Rc (HincII) and Rd (HindII + III), and Hemophilus parainfluenzae (HpaI) were used to digest bacteriophage lambda DNA into 34, 40, and 15 specific fragments, respectively. The sites cleaved by each of these enzymes were localized on the lambda physical map and the fragments resulting from these cleavages were electrophoretically identified on gels by (1) analysis of the digestion profiles of deletion and transducing derivatives of lambda; and (2) digesting individual fragments produced by one restriction endonuclease with another restriction endonuclease. This paper presents the HindII, HindIII, and HpaI restriction fragment maps for the entire lambda genome, and the data used to derive these maps for the region of the lambda genome between the attachment site (at 57.3% lambda) and the right vegetative end (100% lambda). The data for mapping the left arm of lambda may be found in the accompanying paper (Robinson and Landy, 1977).     

Genetic and physical mapping in the early region of bacteriophage T7 DNA.

A detailed physical map of the early region of bacteriophage T7 DNA has been constructed. This map contains: locations for all the cuts made by the restriction endonucleases HindII, HpaII, HaeIII and HaeII, and many of the cuts by HhaI; the approximate end points for each of 61 different deletions; initiation sites and the termination site for RNAs made by Escherichia coli RNA polymerase; an initiation site for RNA made by T7 RNA polymerase; the five primary RNase III cleavage sites of the early region; and the coding sequences for perhaps nine different early proteins. Virtually all of the non-overlapping coding capacity of the five early messenger RNAs is used, except for untranslated stretches of perhaps 30 or so nucleotides at the ends. It seems likely that each of the nine early proteins is made from its own ribosome-binding and initiation site. The mapped restriction cuts provide fixed reference points, and allow DNA fragments containing specific genetic signals to be identified and isolated.The nucleotide sequences around the ends of three different T7 deletions have been determined. Each deletion eliminated a segment of DNA between repeated sequences of seven, eight or ten base-pairs, located 578 to 2100 base-pairs apart in the wild-type sequence. In each case, one copy of the repeated sequence was retained in the deletion mutant. This is consistent with the deletions having arisen by a genetic crossover between the repeated sequences. The approximate frequency of genetic recombination per base-pair has been estimated within two early genes; in both cases, the value was close to 0.01% recombination per base-pair, consistent with the value expected from the total length of the T7 genetic map. Genetic recombination between non-overlapping deletions appears to be severely depressed when the distance between the deletions is closer than about 40 to 50 base-pairs, but recombination between a point mutation and a deletion does not appear to be similarly depressed. This suggests that efficient genetic recombination in T7 may require a base-paired “synapse” of some minimum size between the recombining DNA molecules.