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).     

The bacteriophage P1 restriction endonuclease

The bacteriophage P1 restriction endonuclease has been purified from Escherichia coli lysogenic for P1. This restriction endonuclease P has a sedimentation coefficient of 9.3 S. Unlike the E. coli K restriction endonuclease, endonuclease P does not require S-adenosylmethionine for breakage of DNA. S-adenosylmethionine does, however, stimulate the rate of double-strand breakage of DNA by endonuclease P. Hydrolysis of ATP by endonuclease P could not be detected under conditions in which the K restriction endonuclease massively degrades ATP.The enzyme makes a limited number of double-strand breaks in unmodified or heterologously modified λ DNA. In the presence of S-adenosylmethionine, it does not cut every DNA molecule to the same extent. Incubation of λ DNA with excess amounts of enzyme in the presence of S-adenosylmethionine results in less breakage of the DNA than with smaller amounts of enzyme. This effect is not seen in the absence of S-adenosylmethionine. The maximum amount of cutting in the absence of S-adenosylmethionine appears to be greater than the maximum amount of cutting in its presence. This is most likely due to the modification methylase activity of P1 restriction endonuclease.     

Mechanisms of increasing expression of a yeast gene in Escherichia coli

Escherichia coli strains with increased expression of the cloned yeast his3 gene were selected. In some mutants an E. coli chromosomal locus is altered; in others the yeast his3 sequence is affected. Alterations of the his3 sequence include a point mutation, deletion, and IS2 insertion. When IS2 inserts into the yeast sequence, all pre-existing copies of IS2 are maintained in their original location in the E. coli chromosome. The results indicate that E. coli can employ a variety of mechanisms to increase expression of a foreign gene.     

Molecular cloning and expression of a Bacillus subtilis β-glucanase gene in Escherichia coli

A Bacillus subtilis gene coding for an endo-β-1,3-1,4-glucanase has been transferred to Escherichia coli by molecular cloning using bacteriophage λ and plasmid vectors. The gene is contained within a 1.6-kb EcoRI-PvuI DNA fragment and directs the synthesis in E. coli of a β-glucanase which specifically degrades barley glucan and lichenan. A novel dye-staining method has been developed to detect β-glucanase activity in colonies on agar plates.     

ATP Hydrolysis by Restriction Endonuclease from <Emphasis Type="Italic">E. coli</Emphasis> K

We wish to report a puzzling ATPase activity associated with the DNA restriction endonuclease from E. coli strain K^1–3. This enzyme makes a limited number of double chain breaks in DNA molecules lacking the host-controlled modification imparted by strain K. Unmodified DNA molecules from bacteriophage λ, which serve as a convenient substrate, are broken into fragments with a weight average molecular weight of approximately 7 × 10⁶, about one-fifth the size of the intact λ chromosome. The reaction requires Mg2⁺, ATP and S-adenosylmethionine (SAM).     

Organization of African green monkey DNA at junctions between alpha-satellite and other DNA sequences

Segments of African green monkey DNA containing sequences of the highly reiterated cryptic satellite DNA called α-satellite were selected from a library in λ bacteriophage. This λ library was constructed to enrich for monkey segments that contain (1) irregular regions of α-satellite and (2) α-satellite linked to other monkey sequences. At least 11 of 15 cloned monkey segments between 13 × 10³ and 16 × 10³ base-pairs in length, selected by hybridization to α-satellite, also include other monkey sequences.In general, α-satellite sequences close to the junctions with non-α-satellite DNA contain an abundance of divergent forms compared to the average frequency of such forms within total α-satellite. Many of the cloned segments are missing some of the HinIII sites that occur once in most monomer units of α-satellite, and likewise several of the cloned segments contain restriction sites that rarely occur in α-satellite as a whole. In some segments HinIII sites occur that are spaced at distances other than the basic multiple of 172 base-pairs. At least one of the cloned segments, however, is composed mainly of typical 172 base-pair long α-satellite monomer units.Several of these cloned DNAs have been mapped by restriction endonuclease digestion and Southern blot analysis and the arrangements of α-satellite and non-α-satellite sequences have been determined. In addition to segments that contain a boundary where satellite meets other types of sequence, some contain two such boundaries and thus satellite flanks a non-α-satellite segment. Further, two different types of non-α-satellite sequence appear to be common to more than one phage, perhaps indicating some recurring organization at boundaries.     

Nucleotide sequence from the genetic left end of bacteriophage T7 DNA to the beginning of gene 4

The nucleotide sequence running from the genetic left end of bacteriophage T7 DNA to within the coding sequence of gene 4 is given, except for the internal coding sequence for the gene 1 protein, which has been determined elsewhere. The sequence presented contains nucleotides 1 to 3342 and 5654 to 12,100 of the approximately 40,000 base-pairs of T7 DNA. This sequence includes: the three strong early promoters and the termination site for Escherichia coli RNA polymerase: eight promoter sites for T7 RNA polymerase; six RNAase III cleavage sites; the primary origin of replication of T7 DNA; the complete coding sequences for 13 previously known T7 proteins, including the anti-restriction protein, protein kinase, DNA ligase, the gene 2 inhibitor of E. coli RNA polymerase, single-strand DNA binding protein, the gene 3 endonuclease, and lysozyme (which is actually an N-acetylmuramyl-l-alanine amidase); the complete coding sequences for eight potential new T7-coded proteins; and two apparently independent initiation sites that produce overlapping polypeptide chains of gene 4 primase. More than 86% of the first 12,100 base-pairs of T7 DNA appear to be devoted to specifying amino acid sequences for T7 proteins, and the arrangement of coding sequences and other genetic elements is very efficient. There is little overlap between coding sequences for different proteins, but junctions between adjacent coding sequences are typically close, the termination codon for one protein often overlapping the initiation codon for the next. For almost half of the potential T7 proteins, the sequence in the messenger RNA that can interact with 16 S ribosomal RNA in initiation of protein synthesis is part of the coding sequence for the preceding protein. The longest non-coding region, about 900 base-pairs, is at the left end of the DNA. The right half of this region contains the strong early promoters for E. coli RNA polymerase and the first RNAase III cleavage site. The left end contains the terminal repetition (nucleotides 1 to 160), followed by a striking array of repeated sequences (nucleotides 175 to 340) that might have some role in packaging the DNA into phage particles, and an A · T-rich region (nucleotides 356 to 492) that contains a promoter for T7 RNA polymerase, and which might function as a replication origin.     

Identity of a Chi site of Escherichia coli and Chi recombinational hotspots of bacteriophage λ

Chi sites in bacteriophage λ stimulate recombination promoted by the RecBC pathway of Escherichia coli. We have located a Chi site within the E. coli lacZ gene by deletion mapping and have isolated a mutation inactivating this Chi. Sequence analysis showed that the mutation arose by a single base-pair transition $\text{G}\text{C}\text{?}\text{→}\text{A}\text{T}\text{?}$ within an eight base-pair sequence (5′ G-C-T-G-G-T-G-G 3′) identical to that found at Chi sites in λ and in plasmid pBR322.     

Purification of a hybrid molecule composed of tyrosine transfer RNA and its complementary DNA sequence

The transducing bacteriophage φ80psu_III⁺ carries one structural Escherichia coli gene specifying tyrosine tRNA.The r strand of bacteriophage φ80psu_III⁺ was hybridized with E. coli transfer RNA and the hybrid digested with Neurospora crassa endonuclease. The analysis of the products of enzymic digestion demonstrated the release of a cistron-hybrid composed of tyrosine tRNA and its complementary DNA sequence. The cistron-hybrid was purified from unhybridized DNA by cesium sulphate density-gradient centrifugation and gel filtration.The ratio between tyrosine tRNA and its complementary DNA sequence in the final product was 1:1 as demonstrated by radioisotopic analysis. This purification represents a 30,000-fold enrichment of the E. coli genome for a specific DNA sequence.     

Isolation of β-globin-related genes from a human cosmid library

A human gene library was constructed using an improved cloning technique for cosmid vectors. Human placental DNA was partially digested with restriction endonuclease Mboi, size-fractionated and ligated to BamHI-cut and phosphatase-treated cosmid vector pJB8. After packaging in λ phage particles, the recombinant DNA was transduced into Escherichia coli 1400 or HB101 followed by selection on ampicillin for recombinant E. coli. 150000 recombinant-DNA-containing colonies were screened for the presence of the human β-globin related genes. Five recombinants were isolated containing the human β-globin locus and encompassing approx. 70 kb of human DNA.     

Enzymatic processing of DNA containing tandem dihydrouracil by endonucleases III and VIII

Endonuclease III from Escherichia coli, yeast (yNtg1p and yNtg2p) and human and E.coli endonuclease VIII have a wide substrate specificity, and recognize oxidation products of both thymine and cytosine. DNA containing single dihydrouracil (DHU) and tandem DHU lesions were used as substrates for these repair enzymes. It was found that yNtg1p prefers DHU/G and exhibits much weaker enzymatic activity towards DNA containing a DHU/A pair. However, yNtg2p, E.coli and human endonuclease III and E.coli endonuclease VIII activities were much less sensitive to the base opposite the lesion. Although these enzymes efficiently recognize single DHU lesions, they have limited capacity for completely removing this damaged base when DHU is present on duplex DNA as a tandem pair. Both E.coli endonuclease III and yeast yNtg1p are able to remove only one DHU in DNA containing tandem lesions, leaving behind a single DHU at either the 3′- or 5′-terminus of the cleaved fragment. On the other hand, yeast yNtg2p can remove DHU remaining on the 5′-terminus of the 3′ cleaved fragment, but is unable to remove DHU remaining on the 3′-terminus of the cleaved 5′ fragment. In contrast, both human endonuclease III and E.coli endonuclease VIII can remove DHU remaining on the 3′-terminus of a cleaved 5′ fragment, but are unable to remove DHU remaining on the 5′-terminus of a cleaved 3′ fragment. Tandem lesions are known to be generated by ionizing radiation and agents that generate reactive oxygen species. The fact that these repair glycosylases have only a limited ability to remove the DHU remaining at the terminus suggests that participation of other repair enzymes is required for the complete removal of tandem lesions before repair synthesis can be efficiently performed by DNA polymerase.     

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.     

Processing of bacteriophage lambda DNA during its assembly into heads

DNA purified from bacteriophage λ added to a cell-free extract derived from induced λ lysogens can be packaged into infectious phage particles (Kaiser & Masuda, 1973). In this paper the structure of the DNA which is the substrate for in vitro packaging and head assembly is described. The active precursor is a multichromosomal polymer that contains covalently closed cohesive end sites. Neither circular or linear DNA monomers nor polymers with unsealed cohesive ends are packaged efficiently into heads. The unit length monomer is packaged when it is either contained in the interior of a polymer (both of its ends are in cos sites) or when it has a free left end and a cos site on its right. The monomer unit with a free right end is not a substrate for packaging.A procedure is given for the purification of λ DNA fragments that contain either the left or the right cohesive end. The fragments are produced by digesting λ DNA with the site-specific Escherichia coli R₁ endonuclease; the left and right ends are separated by sedimentation through a sucrose gradient. These fragments are used to construct small polymers that have a unit length λ monomer with (1) a free left end and a closed right end, (2) a free right end and a closed left end, or (3) both ends closed in cos sites.     

Location of the T4 gene 32 protein-binding site on polyoma virus DNA

Three easily denatured regions can be demonstrated in polyoma virus DNA. T4 gene 32 protein which binds to single stranded DNA, but not to duplex DNA, will specifically bind to any of these sites when viral DNA is in its superhelical configuration. These sites were mapped relative to a unique E. coli R_I endonuclease cleavage site by electron microscopy.     

A specific endonuclease from Brevibacterium albidum

A new restriction-like endonuclease, BalI, has been partially purified from Brevibacterium albidum. This enzyme cleaves bacteriophage λ DNA at least 18 times and adenovirus-2 DNA at least 16 times, but does not cleave simian virus 40 DNA. All sites cleaved by BalI are also cut by the specific endonuclease HaeIII from Haemophilus aegyptius. The recognition sequence of BalI is 5′-T-G-G ↓ C-C-A-3′ 3′-A-C-C ↓ G-G-T-5′ and the cleavage site is indicated by the arrows.