Cleavage map of bacteriophage T4 cytosine-containing DNA by sequence-specific endonucleases SalI and KpnI.

Cytosine-containing T4 DNA from endoII- endoIV- dCTPase- alc2 phage grown in a sup+ rB- mB- host is cleaved by endo R.EcoRI and endo R.HindIII to greater than 40 fragments and by endo R.SalI and endo R.KpnI to 8 and 6 fragments, respectively. The latter two fragment sets have been correlated to each other to produce a cleavage map of the genome. The sum of the molecular weights of the fragments calculated from electrophoretic mobility in agarose gels yields a genome molecular weight for cytosine-containing T4 DNA of 105 x 10(6).     

Correlation between genetic map and map of cleavage sites for sequence-specific endonucleases SalI, KpnI, BglI, and BamHI in bacteriophage T4 cytosine-containing DNA.

Cleavage sites for SalI, KpnI, BglI, and BamHI in cytosine-containing DNA from T4 alc10(alc) nd28(denA) D2a2(denB) amE51x5(56) amN55x5(42) have been mapped relative to each other, and the positions of deletions sa delta 9 (D1-stp), r1589(rII), del(39-56)12, and tk2(rI-tk) relative to these cleavage sites have been determined. Based on these analyses, a physical map of the T4 genome containing 166 kilobase pairs has been constructed.     

Physical mapping of the restriction fragments obtained from bacteriophage T4 dC-DNA with the restriction endonucleases SmaI, KpnI and BglII.

Summary The cytosine-containing DNA of a mutant of bacteriophage T4 was digested with restriction endonucleases SmaI, KpnI and BglII producing 5, 7 and 13 fragments respectively. Complete physical maps of the T4 genome were constructed with the enzymes SmaI and KpnI and an almost complete map with the enzyme BglII.     

The complete maps of BglII, SalI and XhoI restriction sites on T4 dC-DNA.

Summary T4 dC-DNA was digested with the restriction endonucleases BglII, SalI and XhoI. Overlaps in the three sets of fragments allowed the mapping of all restriction sites relative to each other along the T4 genome.     

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.     

Cleavage maps for human cytomegalovirus DNA strain AD169 for restriction endonucleases EcoRI, BglII, and HindIII.

We have used cloned EcoRI fragments of the human CMV (HCMV) genome, strain AD169, to prepare restriction endonuclease maps of the DNA. Individual 32P-labeled cloned fragments were hybridized to Southern blots of HCMV DNA cleaved to completion with the restriction endonucleases BglII and HindIII and cleaved partially with EcoRI. By determining which EcoRI fragments hybridized to the same band on a Southern blot, we were able to establish linkage groups. This information coupled with the data derived from digestion of the cloned fragments with the enzymes BglII and HindIII (Tamashiro et al., J. Virol. 42:547-557, 1982) provided the basis for the construction of detailed maps for the enzymes EcoRI, BglII, and HindIII. We also identified the EcoRI fragments derived from the termini of this genome and mapped them with respect to the BglII and HindIII terminal fragments. From our mapping data, we conclude that the genome of HCMV is approximately 240 kilobases in length and is divided into long (198 kilobases) and short (42 kilobases) regions. Both regions consist of a unique sequence bounded by inverted repeats (11 to 12 kilobases for the long region and 2 to 3 kilobases for the short region). Furthermore, the long and short regions can invert relative to each other.     

Digestion of highly modified bacteriophage DNA by restriction endonucleases.

The ability of thirty Type II restriction endonucleases to cleave five different types of highly modified DNA has been examined. The DNA substrates were derived from relatively large bacteriophage genomes which contain all or most of the cytosine or thymine residues substituted at the 5-position. These substituents were a proton (PBS1 DNA), a hydroxymethyl group (SP01 DNA), a methyl group (XP12 DNA), a glucosylated hydroxymethyl group (T4 DNA), or a phosphoglucuronated, glucosylated 4,5-dihydroxypentyl group (SP15 DNA). Although PBS1 DNA and SP01 DNA were digested by most of the enzymes, they were cleaved much more slowly than was normal DNA by many of them. 5-Methylcytosine-rich XP12 DNA and the multiply modified T4 and SP15 DNAs were resistant to most of these endonucleases. The only enzyme that cleaved all five of these DNAs was TaqI, which fragmented them extensively.     

A map of the sites on bacteriophage PM2 DNA for the restriction endonucleases HindIII and HpaII

The map of the seven sites for the restriction endonuclease HindIII³ and the single site for endo R.HpaII on PM2 DNA was determined. This map was oriented with respect to the denaturation map of this DNA (Brack et al., 1975) by partial denaturation mapping of the fragments. A new method for localizing restriction fragments by DNA-DNA hybridization and electron microscopy is described.     

In vivo cleavage of cytosine-containing bacteriophage T4 DNA to genetically distinct, discretely sized fragments

Mutants of bacteriophage T4D that are defective in genes 42 (dCMP hydroxymethylase), 46 (DNA exonuclease), and 56 (dCTPase) produce limited amounts of phage DNA in Escherichia coli B. In this DNA, glucoylated 5-hydroxymethylcytosine is completely replaced by cytosine. We found that this DNA rapidly becomes fragmented in vivo to at least 16 discrete bands as visualized on agarose gels subjected to electrophoresis. The sizes of the fragments ranged from more than 20 to less than 2 kilobase pairs. When DNAs from two of these bands were radioactively labeled in vitro by nick translation and hybridized to XbaI restriction fragments of cytosine-containing T4 DNA, evidence was obtained that the two bands are genetically distinct, i.e., they contain DNA from different parts of the T4 genome. Mutational inactivation of T4 endonuclease II (gene denA) prevented the fragmentation. Three different mutations in T4 endonuclease IV (gene denB) caused the same minor changes in the pattern of fragments. We conclude that T4 endonuclease II is required, and endonuclease IV is involved to a minor extent, in the in vivo production of these cytosine-containing T4 DNA fragments. We view these DNA fragments as "restriction fragments" since they represent degradation products of DNA "foreign" to T4, they are of discrete size, and they are genetically distinct. Thus, this report may represent the first, direct in vivo demonstration of discretely sized genetically distinct DNA restriction fragments.     

Physical mapping of cleavage sites recognized by restriction endonucleases on the genome of bacteriophage T5

The DNA of bacteriophage T5 has been treated with restriction endonucleases EcoRi, HindIII, BamI, SmaI, PstI, SalI, KpnI and the electrophoretic pattern obtained in agarose gel has been analyzed in order to localize the specific cleavage sites on the T5 DNA. The localization of cleavage sites has been deduced from the electrophoretic pattern of double and partial digests, the digests of isolated restriction fragments and the digests of deletion mutant T5st(o) DNA.Four BamI cleavage sites have been found and localized on the physical map of T5 DNA at 0.21, 0.225, 0.685 and 0.725 fractional length. Endonuclease SmaI cleaves at 0.39, 0.59 and 0.69 fractional length. Endonuclease PstI cuts T5 DNA at 11 sites: 0.090, 0.210, 0.320, 0.510, 0.635, 0.670, 0.705, 0.770, 0.815, 0.840, 0.875 fractional length. Six KpnI cleavage sites have been mapped at 0.170, 0.215, 0.525, 0.755, 0.830, 0.850 fractional length. A complete cleavage map of the phage genome is presented for seven restriction enzymes.     

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.     

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.     

alpha-Putrescinylthymine and the sensitivity of bacteriophage phi W-14 DNA to restriction endonucleases.

The modified base alpha-putrescinylthymine (putT) in phi W-14 DNA blocks cleavage of the DNA by 17 of 32 Type II restriction endonucleases. The enzymes cleaving the DNA do so to widely varying extents. The frequencies of cleavage of three altered forms of the DNA show that putT blocks recognition sites either when it occurs within the site or when it is in a sequence flanking the site. The blocking is dependent on both charge and steric factors. The charge effects can be greater than the steric effects for some of the enzymes tested. All the enzymes cleaving phi W-14 DNA release discrete fragments, showing that the distribution of putT is ordered. The cleavage frequencies for different enzymes suggest that the sequence CAputTG occurs frequently in the DNA. Only TaqI of the enzymes tested appeared not to be blocked by putT, but it was slowed down. TaqI generated fragments are joinable by T4 DNA ligase.     

XbaI, PstI, and BglII restriction enzyme maps of the two orientations of the varicella-zoster virus genome.

Cleavage of varicella-zoster virus DNA with the restriction endonucleases PstI, XbaI, and BglII resulted in 18, 22, and 20 fragments, respectively. Based on the molecular weights and molarities of these fragments, a molecular weight of 84 x 10(6) could be calculated for the varicella-zoster virus genome. In both the XbaI and the BglII patterns, four 0.5 M fragments were identified. The arrangement of the fragments was determined by molecular hybridization techniques, and the terminal fragments were identified by lambda exonuclease digestion. The 0.5 M fragments, of which two were located at the same terminus of the genome, contained repeated sequences: one terminally and one inverted internally. These results were in agreement with the existence of two equimolar subpopulations of the varicella-zoster virus genome, differing in the relative orientation of a short region of unique sequences. This region was bounded by the repeated sequences. From the molecular weights of the submolar fragments, a maximal molecular weight of 5 x 10(6) for the repeated region and a minimal molecular weight of 3.5 x 10(6) for the short unique sequence could be calculated.     

Cloning of the DNA BglII fragments of bacteriophage T4 in the vector plasmid pSCC31

An attempt has been made to clone six BglII fragments of T4 DNA in the range of 3.3-8.1 kb in the vector plasmid pSCC31 containing a single BglII site within the gene for endonuclease EcoRI and pL promoter of phage lambda. DNA fragments were extracted from the corresponding bands of agarose gel. The following BglII fragments were cloned: the 3.3 kb fragment No. 9 containing a portion of gene 20, the gene 21 and a portion of gene 22; the 4.2 kb fragment No. 8.1 with genes 17, 18, 19 and a portion of gene 20; the 5.2 kb fragment No. 7.1 with genes 25-29 and a portion of gene 48. In the case of the fragment No. 7.1, the recombinant plasmids pRL705 and pRL707 with different orientation of phage DNA fragment were obtained. An attempt to clone the fragments No. 8.2 (4.2 kb), No. 7.2 (5.45 kb) and No. 6 (8.1 kb) was unsuccessful and this probably indicates the presence of the genes, whose products are deleterious to the growth of bacterial cell.