Cleavage map of BK virus DNA with restriction endonucleases MboI and HaeIII.

Specific cleavage of BK virus (MM) DNA with restriction endonuclease MboI gives rise to 10 fragments. Two techniques were used to determine the location of these fragments on the viral genome with respect to the three known sites for HindIII cleavage. In the first method, reciprocal digestion, individual MboI fragments were digested with HindIII and individual HindIII fragments were digested with MboI. In the second method, single-end 32P-labeled HindIII subfragments were partially digested with MboI, and then the sizes of the radioactive partial products were used to deduce the nearest neighboring fragment. Information from these two methods is more than adequate to map all the MboI enzyme sites. Cleavage of BK virus (MM) DNA with restriction enzyme HaeIII produces 21 fragments. With the aid of the same two methods, these fragments have also been ordered with respect to the known map locations of the HindIII and MboI sites.     

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.     

Long interspersed repeated sequences of the mouse genome

Long interspersed repeated sequences of the mouse genome can be prepared by digesting reassociated DNA with single-strand nuclease. Length resolution reveals many discrete bands that can be assigned to 15 kbp and 6 kbp groups. The reassociated 6 kbp group (which we identify with the MIF-1 family) possesses significant sequence heterogeneity, evidenced by the production of several smaller fragments upon single-strand nuclease digestion of heteroduplexes. The sites of sequence heterogeneity are relatively few and can be mapped using additional restriction endonuclease cuts. We have mapped additional restriction sites into this group, particularly within a cloned HindIII 400 bp fragment, and have also clearly mapped one end of this relatively homogeneous long interspersed repeated sequence.     

Cleavage of adeno-associated virus DNA with Sali,Psti and Haeii restriction endonucleases.

Duplex AAV-2 DNA was digested with SalI, PstI or HaeII restriction endonucleases and the cleavage sites were mapped. SalI cleaves AAV DNA at 0.310 map units, PstI at 0.106, 0.422 and 0.914 and the five HaeII sites were mapped at 0.110. 0.156, 0.181, 0.536 and 0.600 map units. These cleavage products will be useful for the isolation of specific regions from the AAV DNA, located outside of the stably transcribed region of the genome, and will also help to map more complex restriction enzyme cleavages.     

Specific cleavage and physical mapping of simian-virus-40 DNA by the restriction endonuclease of Arthrobacter luteus.

Simian virus 40 (SV40) DNA (strain 776) is cleaved by the restriction endonuclease from Arthrobacter luteus into 32 specific fragments including 20 large pieces designated Alu-A through T as well as 12 minor products named Alu m1 through m8. These were mapped on the SV40 genome by double digestion experiments. Alu fragments were treated with Hind enzymes and vice versa. Similar reciprocal digestions were also carried out with Hae III enzyme. In this way a detailed cleavage map of the SV40 genome could be constructed.     

A NheI macrorestriction map of the Neisseria meningitidis B1940 genome

Abstract A macrorestriction map of the Neisseria meningitidis strain B1940 genome was constructed by two-dimensional pulsed-field gel electrophoresis (2D-PFGE) techniques. Digestion of the genomic DNA with the restriction endonuclease NHe I revealed 15 fragments between 10 kb and 450 kb. The sum of the fragments and resolution of the linearized chromosome yielded a total genome size of about 2.3 Mbp. By overlapping methylation with the Alu I-methylase six Nhe I recognition sites could be blocked. Fragments were ordered by partial/complete 2D-PFGE of genomic DNA with and without prior Alu I methylation, respectively. All nine Alu I-methylase/ Nhe I and 14 Nhe I restriction sites could be mapped on a single circular chromosome. This map will serve as a useful tool for further genetic analysis of meningococci and exemplifies the power of non-radioactive 2D-PFGE techniques to construct large physical genome maps with a single restriction enzyme.     

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.     

HindII, HindIII,and HpaI restriction fragment maps of the left arm of bacteriophage λ DNA

The sites on the left arm of bacteriophage λ DNA cleaved by the restriction endonucleases isolated from Hemophilus influenzae strain Rc (HincII) and Rd (HindII+III), and Hemophilus parainfluenzae (HpaI) were localized on the λ physical map, and the fragments resulting from these cleavages were identified by gel electrophoresis. The restriction sites within the b2 region of λ were mapped by analysis of the digestion profiles of deletion and substitution derivatives of λ, as well as by digesting individual fragments produced by one restriction endonuclease with another restriction endonuclease. The restriction sites on the λ genome between the left vegetative end and the b2 region were mapped entirely by successive digestion experiments. The restriction fragment map for the right arm of λ may be found in the accompanying paper (Robinson and Landy, 1977).     

Regions of broad-host-range plasmid RK2 which are essential for replication and maintenance.

The sites of cleavage on the map of the broad-host-range plasmid RK2 (56 kilobases) were determined for the BglII, PstI, and SmaI restriction enzymes, and the determinants for tetracycline and ampicillin resistance were localized. The cleavage sites were clustered at or near the drug resistance genes. To localize regions required for plasmid replication and maintenance in Escherichia coli, we deleted nonessential regions of RK2 by partial digestion with the restriction endonuclease HaeII to produce small derivatives. The smallest stable replicon obtained contained five HaeII fragments of RK2 which total 5.4 kilobases. These fragments were derived from three regions of RK2 that are separated from each other by antibiotic resistance genes. One of these HaeII fragments (0.75 kilobases) has the properties expected of the origin of replication. The outer four fragments, located in two separate regions of RK2, were found to provide, in trans, functions that permit the replication of the HaeII fragment carrying the origin of the replication. These results indicate that at least two plasmid-encoded genes, capable of acting in trans, and a replication origin are required for RK2 replication and maintenance.     

Construction of the genetic map of the polyoma genome.

Seven early mutants, three late mutants, and one plaque morphology mutant of polyoma have been mapped by marker rescue using wild-type restriction endonuclease fragments. The early mutants map between 1.0 and 26.4 units from the Eco RI site, a region previously shown to correspond to the 3'-OH termainal half of "early" RNA (Kamen et al., 1974). The late mutants as well as the plaque morphology mutant map between 26.6 and 45.4 map units, a region previously shown to correspond to the 3'-OH terminal half of "late" RNA (Kamen et al., 1974). Analysis of the genotype of rescued virus demonstrated that the modification of the mutant DNA during marker rescue was limited to the region of the genome covered by the wild-type restriction endonuclease fragment tested.     

Isolation of deletion and substitution mutants of adenovirus type 5

The infectivity of adenovirus type 5 DNA can be increased to about 5 x 10³ plaque-forming units per μg DNA if the DNA is isolated as a DNA-protein complex. Utilizing this improved infectivity, a method was developed for the selection of mutants lacking restriction endonuclease cleavage sites. The procedure involves three steps. First, the DNA-protein complex is cleaved with a restriction endonuclease. The Eco RI restriction endonuclease was used here. It cleaves adenovirus type 5 DNA to produce three fragments: fragment A (1–76 map units), fragment C (76–83 map units) and fragment B (10–83 map units). Second, the mixture of fragments is rejoined by incubating with DNA ligase, and, third, the modified DNA is used to infect cells in a DNA plaque assay. Mutants were obtained which lacked the endonuclease cleavage site at 0.83 map units. Such mutant DNAs were selected by this procedure because they were cleaved by the Eco RI endonuclease to produce only two fragments: a normal A fragment and a fused B/C fragment. These two fragments could be rejoined to produce a viable DNA molecule as a result of a bimolecular reaction with one ligation event; this exerted a strong selection for such molecules since a trimolecular reaction (keeping the C fragment in its proper orientation) and two ligation events were required to regenerate a wild-type molecule. The alterations resulting in the loss of the Eco RI endonuclease cleavage site at 0.83 map units include both deletion and substitution mutations. The inserted sequences in the substitution mutations are cellular in origin.     

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.     

Physical analysis and mapping of the Mycoplasma pneumoniae chromosome.

Field inversion gel electrophoresis was used for analysis of the chromosome of Mycoplasma pneumoniae. The restriction endonuclease SfiI (5'-GGCCNNNNNGGCC-3') generated 2 M. pneumoniae DNA fragments of approximately 437 and 357.5 kilobase pairs (kbp), whereas 13 restriction fragments ranging in size from 2.4 to 252.0 kbp resulted from digestion with ApaI (5'-GGGCCC-3'). Totaling the sizes of the individual restriction fragments from digestion with SfiI or ApaI yielded a genome size of 794.5 or 775.4 kbp, respectively. A physical map of the M. pneumoniae chromosome was constructed by using a combination of techniques that included analysis by sequential or partial restriction endonuclease digestions and use as hybridization probes of cloned M. pneumoniae DNA containing ApaI sites and hence overlapping adjacent ApaI fragments. Genetic loci for deoC, rrn, hmw3, and the P1 gene were identified by using cloned DNA to probe ApaI restriction fragment profiles.     

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.     

Molecular genetics of herpes simplex virus. III. Fine mapping of a genetic locus determining resistance to phosphonoacetate by two methods of marker transfer.

We have transferred a genetic locus determining resistance to phosphonoacetic acid (PAAr) from one herpes simplex viral genome to another by two methods of marker transfer. One method requires recombination between an intact DNA molecule and a restriction endonuclease DNA fragment, whereas the other requires repair of a partial heteroduplex formed between the two DNA molecules. These two methods mapped the PAAr locus between positions 0.45 and 0.53 map units on the physical map of the viral DNA. Fine mapping of the PAAr locus showed that it maps at or near an EcoRI restriction endonuclease site at either 0.46 or 0.49 map units. We also describe and compare the two methods of marker transfer.     

Transformation of hamster embryo fibroblasts by a specific fragment of the herpes simplex virus genome

Isolated restriction endonuclease fragments of the herpes simplex virus type 1 (HSV-1) genome were introduced into hamster embryo cells to identify DNA sequences capable of transforming the cells with respect to acquisition of properties correlated with tumorigenicity. One of the fragments generated by cleavage of HSV-1 DNA with the restriction endonuclease Xba I was found to induce transformation at a frequency of about 10 colonies per quantity of fragment recovered from 1 μg of uncut DNA; fractions containing the other Xba I fragments failed to induce transformation reproducibly, although occasional colonies were detected. The fragment with transforming activity (Xba I-F) is 15.5 × 10⁶ daltons in molecular weight and is located between 0.30 and 0.45 map units on the HSV-1 genome. The Xba I-F transformants obtained were selected for their ability to replicate in low concentrations of serum; in addition, they were found to attain high saturation densities in the presence of 10% serum and to form colonies in semisolid medium. Moreover, the transformed cells produced at least one of the viral gene products (a membrane glycoprotein) encoded in the fragment used for transformation, indicating not only that viral DNA was incorporated into the cells, but also that viral genes were expressed.     

Physical mapping of Streptomyces coelicolar A3(3) actinophages. III. Restriction analysis

It has been shown that endonucleases HindII, HindIII, SalI and BsuI treatment of phiC62, or phiC43 and phiC31 DNAs forms more than 20 fragments. EcoRI cleaves phiC62, phiC31, phiC31c5 and phiC31c28 into seven fragments, but phiC311yg33 into six fragments. Comparison of molecular weights of DNA restricts obtained after hydrolysis of phage DNAs containing deletions by endonuclease EcoRI made it possible to determine the location of four fragments on restriction map and to orientate this map in relation to the molecule's ends. BamHI cleaves phiC43 DNA into two fragments. By heteroduplexing BamHi site was mapped within the phiC43 insertion sequence.     

Structure of the heterogeneous L-S junction region of human cytomegalovirus strain AD169 DNA

The genome of human cytomegalovirus strain AD169 contains a region of heterogeneity located at the junction between the long (L) and short (S) components of the viral DNA. Twelve cloned L-S junction fragments were studied by using the restriction enzymes HaeII and XhoI. The region of heterogeneity was localized within a single HaeII restriction fragment. The enzyme XhoI was used to subdivide this region and revealed the presence of three types of heterogeneity within the junction fragments. Each of the cloned junction fragments contained one of the following fragments: 0.553, 0.95, or 1.35 kilobase pairs (referred to as class I heterogeneity). Class II heterogeneity was defined as the presence of tandem duplications of class I fragments. In addition, a variable number (0 to 5) of a 0.2-kbp fragment (class III heterogeneity) was observed. Mapping of these fragments with partial XhoI digestions revealed that the class I and class III heterogeneous fragments were adjacent. The DNA sequence of the smallest cloned L-S junction fragment was determined and analyzed. This junction fragment contained a single 0.553-kbp XhoI fragment and no copies of the 0.2-kbp fragment. The 0.553-kbp XhoI fragment was similar in structure to the a-sequences of herpes simplex virus types 1 and 2. In addition, a region of homology was found between the a sequences of herpes simplex virus types 1 and 2 and the 0.553-kbp XhoI fragment from the human cytomegalovirus junction.