Physical and genetic organization of the plasmid R15

The conjugative IncN plasmid R15 (SmrSurHgr, 62.3 kb) is cleaved by the hexanucleotide-specific endonucleases BglII, HindIII, EcoRI, BamHI, SmaI, SalI, PstI and XhoI into 9, 9, 6, 5, 4, 4, 4 and 2 fragments, respectively. The restriction sites were located on the physical map of the R15 genome. Distribution of the cleavage sites is strongly asymmetric. 28 of 32 sites for BamHI, EcoRI, HindIII, SalI, SmaI and PstI were located close to or within the sequences of transposable elements Tn2353 and Tn2354. According to the results of analysis of R15::Tn1756 deletion derivatives and recombinant plasmids harboring fragments of R15, the genetic determinants for resistance to Sm, Su and Hg were mapped, as well as the regions necessary for EcoRII restriction--modification and for plasmid replication and conjugation. The features of physical and genetic structures of R15 and other IncN plasmids are discussed.     

Restriction map of a capsule plasmid of Bacillus anthracis

The capsule plasmid pTE702 of Bacillus anthracis has been physically mapped with the restriction endonucleases HindIII, PstI, BamHI, SalI, and XhoI. A HindIII fragment map of pTE702 (96.5 kb) was obtained by analysis of the recombinant plasmids and cosmids containing overlapping fragments partially digested with HindIII. The physical map for PstI, BamHI, SalI, and XhoI was obtained by double digestion mapping of these sites in relation to the HindIII sites. The replication region of pTE702 was determined by in vitro genetic replicon labeling in B. subtilis.     

Physical and genetic analyses of the Inc-I alpha plasmid R64

A 126-kilobase (kb) physical and genetic map of the Inc-I alpha plasmid R64 was constructed by using the restriction enzymes, BamHI, SalI, XhoI, HindIII, and EcoRI. The replication (Rep) and incompatability (Inc) functions of this plasmid were located in a 1.75-kb segment of an EcoRI fragment, E10 (3.3 kb). In addition, the genes determining growth inhibition of phage BF23 (Ibf), suppression of dnaG ( Sog ), resistance to tetracycline (Tetr), and resistance to streptomycin ( Strr ) were located on the 5.5-kb HindIII-XhoI fragment, the 8.1-kb EcoRI fragment (E5), the 4.6-kb HindIII fragment (H8), and the 4.1-kb HindIII fragment (H10), respectively. The map of R64 was compared with that of ColIb, which belongs to the Inc-I alpha group.     

A physical and genetic map of the IncFI plasmid ColV2-K94

A restriction enzyme map of the IncFI plasmid ColV2-K94 was generated using EcoRI, BamHI, HindIII, and XhoI; the genetic features of this element were then mapped from previous heteroduplex studies.     

Restriction enzyme analysis of Bacillus subtilis bacteriophage phi 105 DNA

The recognition sites on phi 105 DNA for the restriction endonucleases EcoRI, Bg/II, SmaI, KpnI, SstI, SalI, XhoI, NcoI, PstI, HindIII, ClaI, EcoRV and MluI have been mapped. The sites for EcoRI are shown to be different from those published earlier. The DNA from phi 105 contains no recognition sites for the endonucleases BamHI and XbaI.     

Restriction mapping of the DNA of the Streptomyces temperate phage phi C31 and its derivatives

DNA of phi C31 propagated on Streptomyces lividans 66 contained no sites for the restriction enzymes BamHI, SalPI (=PstI) and XhoI; one for XbaI; three for HpaI; five for ClaI and KpnI; six for EcoRI; about 13 for HindIII; about 14 for BclI; and more than 15 for FspAI, HgiAI, SacI, SalGI and SmaI. A complete map of 20 sites (XbaI, HapI, ClaI, KpnI and EcoRI) was obtained using partial digestion and double digestion of DNA of the wild-type and deletion and insertion mutants. The total molecular size was estimated to be 41.2 kb.     

Localization of the DNA segment coding for the synthesis of fraction I on the pYT plague pathogen plasmid]

Fragmentation of the pYT plasmid of the plague pathogen by ten restriction endonucleases has been studied. The evidence has been obtained in support of the possible presence of the movable genetic element containing a HindIII site within the plasmid pYT. The gene encoding the I fraction of the plague pathogen has been cloned. The physical map of the pYT plasmid has been constructed with the use of restriction endonucleases BamHI, XhoI, BstEII, SmaI, EcoRI, and HindIII. The fragment of the plasmid DNA coding for the synthesis of the plague pathogen fraction I has been mapped.     

Biochemical studies on bovine adenovirus type 3. III. Cleavage maps of viral DNA by restriction endoncleases EcoRI, BamHI, and HindIII.

Cleavage of bovine adenovirus type 3 (BAV3) DNA by restriction endonucleases EcoRI, BamHI, and HindIII yielded 7 (A to G), 5 (A to E), and 12 (A to L) fragments, respectively. The order of these fragments has been determined to be GDACBFE for EcoRI fragments, AEBDC for BamHI fragments, and JEBKACDHFGIL for HindIII fragments, and cleavage sites of these enzymes have been mapped on the genome of BAV3. BAV3 preparation contains incomplete virus whose genome has a deletion of about 13% of complete virus genome. Restriction endonuclease digestion of the incomplete virus DNA revealed that EcoRI E and F, BamHI C and HindIII G, I, and L fragments were deleted. Therefore, the deleted region of incomplete virus DNA is located near the right-hand end of the BAV3 DNA molecule, a result consistent with our previous electron-microscopic observations on heteroduplex molecules formed between complete and incomplete BAV3 DNA.     

Molecular cloning of gene xylS of the TOL plasmid: evidence for positive regulation of the xylDEGF operon by xylS.

The xylDEGF operon and the regulatory gene xylS of the TOL plasmid found in Pseudomonas putida mt-2 were cloned onto Escherichia coli vector plasmids. A 9.5-kilobase fragment, derived from the TOL segment of pTN2 deoxyribonucleic acid, carried the xyl genes D, E, G, and F, which encode toluate oxygenase, catechol 2,3-oxygenase, 2-hydroxymuconic semialdehyde dehydrogenase, and 2-hydroxymuconic semialdehyde hydrolase, respectively. The enzymes were noninducible unless a 3-kilobase PstI fragment, derived also from the TOL segment, was provided in either cis or trans. The PstI fragment appeared to contain the regulatory gene xylS, which produced a positive regulator. The regulator was activated by m-toluate or benzoate, but not by m-xylene or m-methylbenzyl alcohol. the map positions of xylG and xylF were also determined.     

A new selective phage cloning vector, lambda 2001, with sites for XbaI, BamHI, HindIII, EcoRI, SstI and XhoI

An improved bacteriophage lambda cloning vector, lambda 2001, has been constructed. The phage includes a 34-bp polylinker oligonucleotide which introduces cleavage sites for XbaI, SstI, XhoI, EcoRI, HindIII and BamHI, and can accommodate 10-kb to 23-kb fragments. Inserts that destroy the BamHI or XhoI cloning sites may be recovered by excision at flanking sites in the polylinker sequence. Insertion of foreign DNA into lambda 2001 generates phage with a Spi- phenotype. The recombinant phage are able to grow on P2 lysogens but the parental vector phages are not. In the course of this work, the polylinker sequence was also introduced into M13mp8. This produced a new vector, M13mp12, with cloning sites for EcoRI, SmaI, XbaI, SstI, XhoI, BamHI, and HindIII.     

Physical map of the origin of defective DNA in herpes simplex virus type 1 DNA.

The origin of defective DNA (dDNA) of the Patton strain of herpes simplex virus type 1 (HSV-1) was physically mapped with BamHI in the parental DNA. The dDNA obtained from virus passaged at high multiplicities of infection was resistant to cleavage with HindIII, whereas digestion with EcoRI yielded a cluster of fragments 5.4 to 5.7 megadaltons (Mdal) in size. Cleavage with BamHI gave a cluster of fragments 2.6 to 3.2 Mdal in size, plus two homogeneous, comigrating 1-Mdal fragments. One of the latter fragments contained the single EcoRI site approximately 65 base pairs from one end. Hybridization of in vitro labeled dDNA probe to EcoRI, HindIII, BamHI, and Hpa I digests of nondefective HSV-1 DNA demonstrated that, in addition to the S-region terminal repeat, only one end of the S region was involved in the generation of this class of dDNA. Thus, the dDNA probe did not hybridize to either the S region 3.0-Mdal HindIIIN fragment or a 3.0-Mdal BamHI fragment of the adjacent 8.7-Mdal HindIIIG fragment, but did hybridize to four BamHI fragments of HindIII G (approximately 5.7 Mdal). The cluster of 2.6- to 3.2-Mdal fragments obtained with BamHI digestion of dDNA appears to represent a novel junction between the termination of dDNA adjacent to the 3.0-Mdal BamHI fragment in HindIII G and the 2.0- to 2.3-Mdal BamHI fragment terminal in HSV-1 DNA.     

Cleavage maps of a tetracycline plasmid from Staphylococcus aureus

The cleavage maps of a Staphylococcus aureus plasmid, pSN1 (2.75 megadaltons), conferring tetracycline resistance, were determined. Cleavage maps are given for HpaI and HindIII restriction endonucleases by using the single HpaII site as a reference point. Nucleases EcoRI, BamHI, SalI, and HaeIII have no sites on this plasmid.     

Evolutionary conservation of genes coding for meta pathway enzymes within TOL plasmids pWW0 and pWW53.

Pseudomonas putida MT53 contains a TOL plasmid, pWW53, that encodes toluene-xylene catabolism. pWW53 is nonconjugative, is about 105 to 110 kilobase pairs (kbp) in size, and differs significantly in its restriction endonuclease digestion pattern and incompatibility group from the archetypal TOL plasmid pWW0. An RP4::pWW53 cointegrate plasmid, pWW53-4, containing about 35 kbp of pWW53 DNA, including the entire catabolic pathway genes, was formed, and a restriction map for KpnI, HindIII, and BamHI was derived. The entire regulated meta pathway genes for the catabolism of m-toluate were cloned into pKT230 from pWW53 on a 17.5-kbp HindIII fragment. The recombinant plasmid supported growth on m-toluate when mobilized into plasmid-free P. putida PaW130. A restriction map of the insert for 10 restriction enzymes was derived, and the locations of xylD, xylL, xylE, xylG, and xylF were determined by subcloning and assaying for their gene products in both Escherichia coli and P. putida hosts. Good induction of the enzymes by m-toluate and m-methylbenzyl alcohol but not by m-xylene was measured in P. putida, but little or no regulation was found in E. coli. The restriction map and the gene order showed strong similarities with published maps of the DNA encoding both the entire meta pathway operon (xylDLEGFJIH) and the regulatory genes xylS and xylR on the archetype TOL plasmid pWW0, suggesting a high degree of conservation in DNA structure for the catabolic operon on the two different plasmids.     

Molecular cloning of regulatory gene xylR and operator-promoter regions of the xylABC and xylDEGF operons of the TOL plasmid.

The regulatory gene xylR of the TOL plasmid, which functions positively on both xylABC and xylDEGF operons in the presence of m-xylene or m-methylbenzyl alcohol, was cloned onto an Escherichia coli vector, pACYC177. A fused operon consisting of the operator-promoter region of the xylABC operon and the xylE gene was cloned onto pBR322. The xylE product, catechol 2,3-dioxygenase, was induced by m-xylene or m-methylbenzyl alcohol in the cells containing the fused operon when a 2.8-kilobase segment of the TOL plasmid was provided in trans. Therefore, the segment appeared to contain the regulatory gene xylR. The xylR gene was mapped very close to the other regulatory gene, xylS, determined previously. The xylR gene was not effective on activation of the xylDEGF operon unless an additional region containing xylS was provided together with the inducer. These results indicate that both xylR and xylS are essential to the m-methylbenzyl alcohol-dependent induction of the xylDEGF operon. The map positions of xylR and xylS were precisely determined by subcloning or insertion inactivation. In addition, the operator-promoter regions of the xylABC and xylDEGF operons were mapped to the 0.6- and 0.4-kilobase regions of the TOL plasmid, respectively.     

Excision and integration of degradative pathway genes from TOL plasmid pWW0.

WR211 is a transconjugant resulting from transfer of the 117-kilobase (kb) TOL degradative plasmid pWW0 into Pseudomonas sp. strain B13. The plasmid of this strain, pWW01211, is 78 kb long, having suffered a deletion of 39 kb. We show that WR211 contains the 39 kb that is missing from its plasmid, together with at least an additional 17 kb of pWW0 DNA integrated in another part of the genome, probably the chromosome. The ability of WR211 to grow on the TOL-specific substrate m-toluate is the result of expression of the TOL genes in this alternative location, whereas its inability to grow on m-xylene is caused by insertional mutagenesis by 3 kb of DNA of unknown origin in the xylR gene of this DNA. The resident plasmid pWW01211 plays no part in the degradative phenotype of WR211 since it can be expelled by mating in incompatible IncP9 resistance plasmid R2 or pMG18 without loss of the phenotype. This alternatively located DNA can be rescued back into the R2 and pMG18 plasmids as R2::TOL and pMG18::TOL recombinants by mating out into plasmid-free recipients and selecting for Mtol+ transconjugants. In all cases examined, these plasmids contained the entire R plasmid into which is inserted 59 kb of DNA, made up of 56 kb of pWW0 DNA and the 3-kb xylR insertion. Selection for faster growth on benzoate can lead to precise excision of the 39 kb from the TOL region of an R2::TOL recombinant, leaving a residual and apparently cryptic 17-kb segment of pWW0 DNA in the R plasmid.     

Overproduction of Escherichia coli replication proteins by the use of runaway-replication plasmids.

A derivative of the runaway-replication plasmid was constructed. This plasmid, pSY343, has the gene for kanamycin resistance and single sites for EcoRI, BamHI, HindIII, KpnI, and XhoI that can be used as cloning sites without inactivating the kanamycin resistance gene or the replication genes. Three replication genes of Escherichia coli were cloned on the plasmid. The activity of dnaA, dnaZ, and ssb gene products were 200-, 90-, and 60-fold greater, respectively, in the cells containing these plasmids than in normal cells.     

Construction of new cloning vehicles with genes of the tryptophan operon of Escherichia coli as genetic markers

In vitro recombination techniques were used to construct a series of new cloning vehicles with genes of the tryptophan (trp) operon of Escherichia coli as selective marker. To construct these plasmids we have made a restriction cleavage map of the trp operon for the enzymes AosI, AvaI, BglI, BglII, HindIII, HpaI, PvuII, SalI, SstI and XhoI. The constructed plasmids pHP39, pEP392, pEP3921 and pEP3923 are derived from the amplifiable plasmid pBR345 and carry two or more genes of the trp operon, which are controlled by the trp regulatory elements. Plasmid pEP3921 (7.0 kb) carries intact trpE and trpA genes and contains single BglII and SstI sites in trpE, a single HindIII site located between trpE and trpA, and single EcoRI, SalI and XhoI sites located outside the trp genes. Plasmid pEP121 (12 kb) is similar to pEP3921, but has an extra selective marker conferring bacterial resistance to ampicillin. Plasmid pEP3923 (7.4 kb) comprises intact trpB and trpA genes and single BglII, HindIII, EcoRI, SalI and XhoI sites. Plasmids pHP39 (9.8 kb) and pEP392 (9.8 kb) carry an intact trp operon and have two and one EcoRI site, respectively. Plasmid pHP3 (18 kb) carries an intact trp operon and markers for tetracycline and ampicillin resistance.     

Isolation of TOL and RP4 recombinants by integrative suppression.

We obtained genetic and molecular evidence of non-thermosensitive recombinants of RP4 (Kmr Tcr Cbr/Apr) and the thermosensitive TOL plasmid. As first isolated in Pseudomonas aeruginosa PAO, the recombinant plasmid pTN1 specified noninducible synthesis of TOL enzymes and was transmissible to Escherichia coli on selection for the transfer of kanamycin resistance. The phenotypic expression of TOL genes of pTN1 in E. coli was low and also noninducible. A spontaneous segregant, pTN2, appearing from pTN1, conferred inducible synthesis of TOL enzymes. These plasmids carry all of the TOL determinants as evidenced by the ability of Pseudomonas putida carrying recombinant plasmids to grow on toluene, xylene, and m-toluate. In E. coli the expression of TOL genes with normal regulation (pTN2) appears to be extremely low without induction, and the induced expression is comparable to that with defective regulation (pTN1). The measurement of the molecular weight of pTN2 by electron microscopy gave a value of about 74 X 10(6).     

Localization and functional analysis of transposon mutations in regulatory genes of the TOL catabolic pathway.

Mutant derivatives of the TOL plasmid pWW0-161, containing Tn5 insertions in the xylS and xylR regulatory genes of the catabolic pathway, have been identified and characterized. The two genes are located together on a 1.5- to 3.0-kilobase segment of TOL, just downstream of genes of the enzymes of the meta-cleavage pathway. As predicted by a current model for regulation of the TOL catabolic pathway, benzyl alcohol dehydrogenase, a representative enzyme of the upper (hydrocarbon leads to carboxylic acid) pathway, was induced by m-methylbenzyl alcohol in xylS mutant bacteria but not in a xylR mutant, whereas catechol 2,3-oxygenase, a representative enzyme of the lower (meta-cleavage) pathway, was induced by m-toluate in a xylR mutant but not in the xylS mutants. Unexpectedly, however, catechol 2,3-oxygenase was not induced by m-methylbenzyl alcohol in xylS mutants but was induced by benzyl alcohol and benzoate. These results indicate that expression of the TOL plasmid-encoded catabolic pathway is regulated by at least three control elements, two of which (the products of the xylS and xylR genes) interact in the induction of the lower pathway by methylated hydrocarbons and alcohols and one of which responds only to nonmethylated substrates.     

Restriction endonuclease mapping and mutagenesis of the F sex factor replication region.

The plasmids pSC138 and pML31 each contain the EcoRI-generated f5 replicator fragment of the conjugative plasmid F in addition to an EcoRI fragment encoding antibiotic resistance: ampicillin resistance derived from Staphylococcus aureus in pSC138 and kanamycin resistance from Escherichia coli in pML31. We have mapped one HindIII and two BamHI restriction sites in the f5 region of these plasmids and one HindIII site in the antibiotic resistance region of each plasmid. The HindIII site in the Km region of pML31 occurs in the kan gene whereas the HindIII site in the Ap region of pSC138 appears to occur in an area important for the regulation of beta-lactamase production. By means of in vitro recombinant DNA manipulation of plasmids pML31 and pSC138, we have shown that approximately 1.9 X 10(6) daltons of the 6.0 X 10(6) dalton f5 fragment can be deleted without disrupting plasmid stability. In addition, we have used these same techniques to isolate a novel F-controlled Ap plasmid cloning vehicle which contains a single restriction site for each of the enzymes EcoRI, HindIII, and BamHI. This cloning vehicle has been linked via either its EcoRI or HindIII site to a ColE1 plasmid replicon to yield stable recombinants.