Cleavage of Nonglucosylated Bacteriophage T4 deoxyribonucleic acid by Restriction Endonuclease Eco RI

In Vitro Characteristics of Phages to Guide 'Real Life' Phage Therapy Suitability

The increasing problem of antibiotic-resistant pathogens has put enormous pressure on healthcare providers to reduce the application of antibiotics and to identify alternative therapies. Phages represent such an alternative with significant application potential, either on their own or in combination with antibiotics to enhance the effectiveness of traditional therapies. However, while phage therapy may offer exciting therapeutic opportunities, its evaluation for safe and appropriate use in humans needs to be guided initially by reliable and appropriate assessment techniques at the laboratory level. Here, we review the process of phage isolation and the application of individual pathogens or reference collections for the development of specific or "off-the-shelf" preparations. Furthermore, we evaluate current characterization approaches to assess the in vitro therapeutic potential of a phage including its spectrum of activity, genome characteristics, storage and administration requirements and effectiveness against biofilms. Lytic characteristics and the ability to overcome anti-phage systems are also covered. These attributes direct phage selection for their ultimate application as antimicrobial agents. We also discuss current pitfalls in this research area and propose that priority should be given to unify current phage characterization approaches.

Type II restriction endonucleases--a historical perspective and more

This article continues the series of Surveys and Summaries on restriction endonucleases (REases) begun this year in Nucleic Acids Research. Here we discuss 'Type II' REases, the kind used for DNA analysis and cloning. We focus on their biochemistry: what they are, what they do, and how they do it. Type II REases are produced by prokaryotes to combat bacteriophages. With extreme accuracy, each recognizes a particular sequence in double-stranded DNA and cleaves at a fixed position within or nearby. The discoveries of these enzymes in the 1970s, and of the uses to which they could be put, have since impacted every corner of the life sciences. They became the enabling tools of molecular biology, genetics and biotechnology, and made analysis at the most fundamental levels routine. Hundreds of different REases have been discovered and are available commercially. Their genes have been cloned, sequenced and overexpressed. Most have been characterized to some extent, but few have been studied in depth. Here, we describe the original discoveries in this field, and the properties of the first Type II REases investigated. We discuss the mechanisms of sequence recognition and catalysis, and the varied oligomeric modes in which Type II REases act. We describe the surprising heterogeneity revealed by comparisons of their sequences and structures.

Specificity of restriction endonucleases and DNA modification methyltransferases a review (Edition 3)

The properties and sources of all known class-I, class-II and class-III restriction endonucleases (ENases) and DNA modification methyltransferases (MTases) are listed and newly subclassified according to their sequence specificity. In addition, the enzymes are distinguished in a novel manner according to sequence specificity, cleavage position and methylation sensitivity. Furthermore, new nomenclature rules are proposed for unambiguously defined enzyme names. In the various Tables, the enzymes are cross-indexed alphabetically according to their names (Table I), classified according to their recognition sequence homologies (Table II), and characterized within Table II by the cleavage and methylation positions, the number of recognition sites on the DNA of the bacteriophages lambda, phi X174, and M13mp7, the viruses Ad2 and SV40, the plasmids pBR322 and pBR328, and the microorganisms from which they originate. Other tabulated properties of the ENases include relaxed specificities (integrated within Table II), the structure of the generated fragment ends (Table III), interconversion of restriction sites (Table IV) and the sensitivity to different kinds of DNA methylation (Table V). Table VI shows the influence of class-II MTases on the activity of class-II ENases with at least partially overlapping recognition sequences. Table VII lists all class-II restriction endonucleases and MTases which are commercially available. The information given in Table V focuses on the influence of methylation of the recognition sequences on the activity of ENases. This information might be useful for the design of cloning experiments especially in Escherichia coli containing M.EcodamI and M.EcodcmI [H16, M21, U3] or for studying the level and distribution of site-specific methylation in cellular DNA, e.g., 5'- (M)CpG-3' in mammals, 5'-(M)CpNpG-3' in plants or 5'-GpA(M)pTpC-3' in enterobacteria [B29, E4, M30, V4, V13, W24]. In Table IV a cross index for the interconversion of two- and four-nt 5'-protruding ends into new recognition sequences is complied. This was obtained by the fill-in reaction with the Klenow (large) fragment of the E. coli DNA polymerase I (PolIk), or additional nuclease S1 treatment followed by ligation of the modified fragment termini [P3]. Interconversion of restriction sites generates novel cloning sites without the need of linkers. This should improve the flexibility of genetic engineering experiments [K56, P3].(ABSTRACT TRUNCATED AT 400 WORDS)

Substrate recognition by the EcoRI endonuclease

The EcoRI restriction endonuclease is one of the most widely used tools for recombinant DNA manipulations. Because the EcoRI enzyme has been extremely well characterized biochemically and its structure is known at 3 A resolution as an enzyme-DNA complex, EcoRI also serves as a paradigm for other restriction enzymes and as an important model of DNA-protein interactions. To facilitate a genetic analysis of the EcoRI enzyme, we devised an in vivo DNA scission assay based on our finding that DNA double-strand breaks induce the Escherichia coli SOS response and thereby increase beta-galactosidase expression from SOS::lacZ gene fusions. By site-directed mutagenesis, 50 of 60 possible point mutations were generated at three amino acids (E144, R145, and R200) implicated in substrate recognition by the crystal structure. Although several of these mutant enzymes retain partial endonuclease activity, none are altered in substrate specificity in vivo or in vitro. These findings argue that, in addition to the hydrogen bond interactions revealed by the crystal structure, the EcoRI enzyme must make additional contacts to recognize its substrate.

Cytosine-specific DNA modification interferes with plasmid establishment in Escherichia coli K12: involvement of rglB

Several chimeric pBR322/328 derivatives containing genes for cytosine-specific DNA methyltransferases (Mtases) can be transformed into the Escherichia coli K12/E. coli B hybrid strains HB101 and RR1 but not into other commonly used E. coli K12 strains. In vitro methylation of cytosine residues in pBR328 and other unrelated plasmids also reduces their potential to transform such methylation sensitive strains, albeit to a lesser degree than observed with plasmids containing Mtase genes. The extent of reduced transformability depends on the target specificity of the enzyme used for in vitro modification. The role of a host function in the discrimination against methylated plasmids was verified by the isolation of K12 mutants which tolerate cytosine methylated DNA. The mutations map in the vicinity of the serB locus. This and other data indicate that the host rglB function is involved in the discrimination against modified DNA.

End structure and mechanism of packaging of bacteriophage T4 DNA

We analyzed by restriction enzyme digestion the end structure of T4 phage DNA by comparing mature, concatemeric, first-packaged, and incompletely packaged DNAs. The structure of mature DNA was also studied using 3' end labeling with terminal transferase. Our data support the hypothesis that T4 DNA packaging is not initiated at specific packaging initiation sequences on the concatemeric precursor (cos or pac site mechanisms) but by a different packaging mechanism.

Cloning and expression of a chloramphenicol acetyltransferase gene in cytosine-substituted T4 bacteriophage

We have developed an efficient method for transferring foreign genes into the T4 phage genome. Any foreign genes inserted into the T4 uvsY gene cloned on plasmids can be transferred into a cytosine-substituted T4dC(delta NB5060) phage genome by a replacement type of recombination. To achieve this, we constructed chimeric plasmids which had a chloramphenicol acetyltransferase gene (cat) derived from transposon Tn9 inserted into the Bg/II site within the T4 uvsY gene on pBR322. The cat gene was then transferred by in vivo recombination into the T4dC(delta NB5060) phage genome. Moreover, it was demonstrated that the cat gene in the hybrid T4dC phage was expressed upon phage infection and development.

A comparison of the structural requirements for DNA cleavage by the isoschizomers HaeIII, BspRI and BsuRI

We have investigated the structural requirements for DNA cleavage by the isoschizomers HaeIII, BspRI and BsuRI which recognize the sequence -d(GGCC)-. For this purpose decadeoxynucleotides were synthesized by the solid-phase phosphotriester method and purified by high-performance liquid chromatography. The kinetics of cleavage of these oligodeoxynucleotides were determined for the three isoschizomers with the following results. The sequence adjacent to the recognition site strongly influences the rate of cleavage. The preference is qualitatively the same for all three enzymes: AGGCCT greater than TGGCCA greater than GGGCCC approximately equal to CGGCCG, and follows the thermal stability of the different decanucleotides. Substitutions within the recognition site, namely dI for dG and dU for dC, affect the rate of cleavage differently for the three enzymes. The results can be rationalized in terms of an interaction of HaeIII with the major and minor groove of the DNA, of BspRI mainly with the minor groove and of BsuRI with the major groove of DNA. It is obvious from our data that the mechanism of recognition of the same site is different for the three isoschizomers.

Restriction analysis of DNA from Treponema pallidum, the causative agent of syphilis

When purified DNA from pathogenic Treponema pallidum is digested with restriction endonucleases it results in the formation of discrete DNA fragments which range between 2.5 to 10 Kilobase pairs. No such precise fragmentation occurs with DNA isolated from nonpathogenic T. pallidum. The appearance of the discrete restriction fragments from the pathogenic T. pallidum DNA does not represent a contamination of satellite DNA from rabbit, the host in which the organism was propagated, but rather represents the presence of redundant DNA or DNA of less complexity in the pathogenic T. pallidum DNA preparation.

Nucleotide sequence of the lysozyme gene of bacteriophage T4. Analysis of mutations involving repeated sequences

The nucleotide sequence of the lysozyme (e) gene of bacteriophage T4 and approximately 130 additional nucleotides on each side has been determined. The 5'-end of the gene for internal protein III appears to be located about 70 base-pairs from the 3'-end of the lysozyme gene. Nucleotide sequence analysis of mutant e genes confirmed that three identified hotspots of frameshift mutations are runs of five A nucleotides in the wild-type gene. The endpoints of two deletions are direct repeats of eight base-pairs in the wild-type gene. Two frameshift mutations with high reversion frequencies are duplications of five or seven base-pairs. The cloning and nucleotide sequence determination of the lysozyme gene will facilitate further study of the molecular biology of T4 lysozyme.

Bacteriophage T4 as a generalized DNA-cloning vehicle

We have designed a method for inserting foreign DNA segments into bacteriophage T4. A plasmid containing T4 DNA is opened within the T4 sequence and the foreign DNA is inserted in vitro. Recombination in vivo, between T4 and the doubly chimeric plasmid, results in insertion of the foreign DNA into the genome of viable T4 phage. We have demonstrated the method by inserting a 203-bp DNA fragment from the lactose operon of Escherichia coli, into the dispensable region of the rIIB gene of T4. With minor modifications, the method should make possible the cloning of very large DNAs into any one of a large number of sites on the T4 chromosome.

Studies on sequence recognition by type II restriction and modification enzymes

Type II DNA restriction and modification systems are ideally suited for analysis of mechanisms by which proteins specifically recognize unique DNA sequences. Each system is comprised of a unique DNA recognition site and two enzymes, which in those cases examined in detail, are comprised of distinct polypeptide chains. Thus, not only are the DNA substrates extremely well defined, but each system affords the opportunity to compare distinct proteins which interact with a common DNA sequence. This review will focus only on those Type II systems which have been examined in sufficient molecular detail to permit some insight into modes of specific DNA-protein interaction.

Eco RI* specificity and hydrogen bonding

Under standard conditions, Eco RI endonuclease uniquely recognizes the inverted repeat GAATTC. However, this specificity breaks down under non-standard conditions into what has been termed Eco RI* specificity, wherein many other sequences are recognized. We show here that the hydrolysis rates at all known Eco RI* sites can be summarized by the hierarchies: G much greater than A greater than T much greater than C at the first position, A much greater than [G,C] much greater than T at the second and third position, and the corresponding complements at the last three positions. This is consistent with a recognition model which assumes that there are two specific hydrogen bonds per base pair under standard conditions. One or more of these are randomly replaced by water under Eco RI* conditions and the position of a sequence within the appropriate hierarchy is primarily determined by the number of retained hydrogen bonds. These retained hydrogen bonds are common recognition features that can be identified by examining the DNA. The recognition points thereby identified for Eco RI all fall within the major groove of the DNA.

Isolation and characterization of DNA fragments containing the dihydrofolate-reductase gene of coliphage T4

DNA of a mutant of the bacteriophage T4, which contains cytosine instead of glucosylated hydroxymethylcytosine, was shown to direct the synthesis of enzymatically active dihydrofolate reductase in a coupled in vitro transcription-translation system. The DNA-directed synthesis of the enzyme was used to localize the dihydrofolate-reductase gene frd on a 2300 bp long restriction-nuclease-generated DNA fragment. Fine structure mapping showed that the gene is encoded on a segment of less than 1850 bp but more than 700 bp length. The enzyme, which is synthesized in vitro from the DNA fragment, has a molecular weight of 18 500 to 19 500. A restriction map was constructed which extends about 10 kb to both sides of the reductase gene and which covers the T4 genome between the genes 55 and 63. The two genes which flank the frd gene, genes 32 and td (thymidylate synthetase), were mapped in detail. A correlation between the physical and genetic maps was established.

Two sequence-specific endonucleases from Xanthomonas oryzae. Characterization and unusual properties

XorI and XorII, two sequence-specific endonucleases, have been partially purified from Xanthomas oryzae. XorI and XorII were shown to be isoschizomers of PstI and PuvI, respectively. X. oryzae is a particularly good source of this PvuI isoschizomer because of the high yield of XorII, its simple purification scheme, and its relative stability. Furthermore, XorII was shown to cleave at different positions in its recognition sequence than do at least two of its known isochizomers; XorII cleaves between the C and the G at the 3'-end of its palindromic recognition sequence, 5'-CGATC G-3'. There is a single XorII site in each of the plasmid-cloning vehicles pBR313 and pBR322. Two unusual aspects of XorII digestion are discussed, namely, the kinetics of digestion of pBR313 and pBR322 and the resistance of human DNA to XorII.

Structures and mechanisms of DNA restriction and modification enzymes

DNA restriction and modification enzymes are responsible for the hostspecific barriers to interstrain and interspecies transfer of genetic information that have been observed in a variety of bacterial cell types. Although the phenomenon of host specificity was initially observed in the early 1950s (Luria & Human, 1952; Bertani & Weigle, 1953), it was nearly a decade later that Arber and his colleagues accurately predicted the molecular basis of the phenomenon. Their experiments with bacteriophage λ demonstrated that a given host-specificity system imparts a specific modification to the viral DNA, and further, that restriction of DNA lacking the appropriate modification is s consquence of nucleolytic hydrolysis upon entry into the host cell (Arber & Dussoix, 1962; Dussoix & Arber, 1962; Arber, Hattman & Dussoix, 1963).

Isolation of the transfer RNA genes of bacteriophage T4 and transfer RNA synthesis in vitro

Non-glucosylated T4 DNA was restricted with the endonuclease EcoRI and the mixture of DNA fragments separated by gel electrophoresis and transcribed with purified Escherichia coli RNA polymerase. Three purified fragments were shown to act as templates for tRNA synthesis. A smaller fragment, shown to be hybridizable to 32P-labeled T4 tRNA was not transcribable. It was concluded that the promoter for T4 tRNA synthesis had been separated from the structural genes in the smaller fragment by EcoRI and that the distal portion of the tRNA gene cluster lacks internal promoters which display in vitro activity. Preparations of non-glucosylated T4 DNA were never fully restricted with EcoRI and when the larger purified fragments carrying the tRNA were restricted with excess enzyme only a slight cleavage to yield the smaller fragments was obtained. The property of the DNA-limiting complete restriction is not know.

Studies of viable T4 bacteriophage containing cytosine-substituted DNA (T4dC phage). II. Cleavage of T4dC DNA by endonuclease SalI and bam HI

Digestion of non-glucosylated and cytosine-substituted T4 phage (T4dC) DNA with SalI restriction endonuclease showed that the DNA had nine SalI-sensitive sites. There were eight SalI sites in DNA from a strain which had a deletion in the rII-denB-ndd region. The comparison of two digestion patterns indicated that one of the SalI-sensitive sites was present in the deleted region and that the SalI-F fragments (8.4 x 10(6) daltons) was located adjacent to the SalI-C or SalI-D fragments (15.5 x 10(6) daltons) on the T4 chromosome. The DNA gave no detectable cleavage product when digested with BamHI endonuclease alone, while, when digested successively with BamHI and SalI, the DNA yielded two new digestion products in place of one fragment formed by SalI alone. The BamHI-sensitive site was in the SalI-A fragment (25.2 x 10(6) daltons). The usefulness of this information for making cleavage maps of T4 phage chromosome is discussed.

Transcription of bacteriophage T4 DNA in vitro: selective initiation with dinucleotides

The transcription products of phage T4 DNA in vitro are separated on polyacrylamide gels. The influence of salt, polymerase, triphosphate concentration and glucosylation on the RNA synthesis are shown. Individual transcripts are initiated selectively with dinucleotides and a single triphosphate. This technique allows the prediction of the initiation sequences of several T4 transcripts.

Hybrid plasmids containing the araBAD genes of Escherichia coli B/r

The DNA fragments generated by restriction endonuclease BamI which contain the araCBAD genes from E.coli B/r have been cloned. The DNA fragments containing ara genes were idenified by a compairson of the BamI fragments of lambdah80dara phages containing different ara deletion mutations. The ara genes were cloned into the plasmid pBR317, a derivative of ColE1. The cloned DNA fragments were analyzed by digestion with pairs of restriction endonucleases to determine the molecular weight of the chimeras and to identify the cloned ara DNA fragments. The cloned ara fragments were also identified by genetic complementation and recombination tests.

Molecular cloning of fragments of bacteriophage T4 DNA

Non-glucosylated T4 DNA was digested with R.EcoRI and the resulting fragments covalently joined to lambda vectors. The genetic content of each lambda-T4 hybrid was determined by marker-rescue tests. The isolation of many recombinants containing partial-digestion products of T4 DNA provided the overlapping sequences necessary to order fragments within the T4 genome. The present analyses include parts of the "early" region between genes 42 and 46, and much of the "late" region between genes 50 and 29. T4 cytosine-DNA digested to completion by R.EcoRI was used to identify the fragments of DNA within the lambda-T4 recombinants. The T4 cytosine-DNA was also sensitive to R.HindIII and R.Xho but not to R.BamH1.

Genetic identification of cloned fragments of bacteriophage T4 DNA and complementation by some clones containing early T4 genes

Bacteriophage T4 DNA containing cytosine has been obtained from cells infected with phage mutant in genes 42, 56, denA and denB. This DNA can be cut by a number of restriction endonucleases. Fragments obtained by digestion of this DNA with EcoRI have been cloned using the vector plasmid pCR1. Clones containing T4 DNA were identified by hybridization with radioactive early and late T4 RNA. A simple marker rescue technique is described for the genetic identification of the cloned T4 fragments. Some of the T4-hybrid plasmids which contain entire T4 genes can complement temperature sensitive and amber mutants of T4.

Restriction endonucleases

This review provides a comprehensive account of the current status of the biology and biochemistry of restriction endonucleases. Both Class I and Class II restriction endonucleases will be considered. However, emphasis will be placed on the Class II group, which recognizes and cleaves a specific duplex DNA sequence. Their occurrence, purification, and characterization is discussed in detail. The characterization includes physical mapping information and determination of recognition sequences. In addition to detailed discussions of the biochemical properties of the enzymes, considerable attention is paid to the uses of these enzymes as tools for research in molecular biology. These uses include physical mapping of genomes and their transcripts, genetic analysis (marker rescue, etc.), DNA sequence analysis, analysis of complex genomes, and genetic engineering. Specific examples of each use are outlined. Practical aspects of both the isolation and use of the restriction endonucleases form the major theme of this review.

In vitro construction of bacteriophage lambda and plasmid DNA molecules containing DNA fragments from bacteriophage T4

Restriction endonucleases EcoRI and HindIII generated fragments of T4 cytosine-containing DNA were inserted into bacteriophage vector lambdagtSuIII and plasmid vectors pMB9 and pBR313. Resulting clones were screened for hybridization with 32P labeled T4 tRNA. Recombinant bacteriophages and plasmids were isolated which contained a T4 fragment coding for T4 RNA species 1 and 2 and T4 tRNA Arg. Selected lambda-T4 hybrid bacteriophages were grown to high titer and their DNA analyzed by gel electrophoresis.