Expression of the Eco RI restriction-modification system and the construction of positive-selection cloning vectors

Genetically modified microorganism Spingomonas paucimobilis UT26 for simultaneously degradation of methyl-parathion and γ-hexachlorocyclohexane

Bioremediation of pesticide residues by bacteria is an efficient and environmentally friendly method to deal with environmental pollution. In this study, a genetically modified microorganism (GMM) named UT26XEGM was constructed by introducing a parathion hydrolase gene into an initially γ-hexachlorocyclohexane (γ-HCH) degrading bacterium Spingomonas paucimobilis UT26. In order to reduce its potential risk of gene escaping into the environment for the public concern on biosafety, a suicide system was also designed that did not interfere with the performance of the GMM until its physiological function was activated by specific signal. The system was designed with circuiting suicide cassettes consisting of killing genes gef and ecoRIR from Escherichia coli controlled by Pm promoter and the xylS gene. The cell viability and original degradation characteristics were not affected by the insertion of exogenous genes. The novel GMM was capable of degrading methyl-parathion and γ-HCH simultaneously. In laboratory scale testing, the recombinant bacteria were successfully applied to the bioremediation of mixed pesticide residues with the activity of self-destruction after 3-methylbenzoate induction.

Regulation of gene expression in restriction-modification system Eco29kI

The Eco29kI restriction-modification (R-M) system consists of two partially overlapping genes, eco29kIR, encoding a restriction endonuclease and eco29kIM, encoding methyltransferase. The two genes are thought to form an operon with the eco29kIR gene preceding the eco29kIM gene. Such an organization is expected to complicate establishment of plasmids containing this R-M system in naive hosts, since common logic dictates that methyltransferase should be synthesized first to protect the DNA from cleavage by the endonuclease. Here, we characterize the Eco29kI gene transcription. We show that a separate promoter located within the eco29kIR gene is sufficient to synthesize enough methyltransferase to completely modify host DNA. We further show that transcription from two intragenic antisense promoters strongly decreases the levels of eco29kIR gene transcripts. The antisense transcripts act by preventing translation initiation from the bicistronic eco29kIR–eco29kIM mRNA and causing its degradation. Both eco29kIM and antisense promoters are necessary for Eco29kI genes establishment and/or stable maintenance, indicating that they jointly contribute to coordinated expression of Eco29kI genes.

[Regulation of gene expression in type II restriction-modification system]

Type II restriction-modification systems are comprised of a restriction endonuclease and methyltransferase. The enzymes are coded by individual genes and recognize the same DNA sequence. Endonuclease makes a double-stranded break in the recognition site, and methyltransferase covalently modifies the DNA bases within the recognition site, thereby down-regulating endonuclease activity. Coordinated action of these enzymes plays a role of primitive immune system and protects bacterial host cell from the invasion of foreign (for example, viral) DNA. However, uncontrolled expression of the restriction-modification system genes can result in the death of bacterial host cell because of the endonuclease cleavage of host DNA. In the present review, the data on the expression regulation of the type II restriction-modification enzymes are discussed.

Maintenance forced by a restriction-modification system can be modulated by a region in its modification enzyme not essential for methyltransferase activity

Several type II restriction-modification gene complexes can force their maintenance on their host bacteria by killing cells that have lost them in a process called postsegregational killing or genetic addiction. It is likely to proceed by dilution of the modification enzyme molecule during rounds of cell division following the gene loss, which exposes unmethylated recognition sites on the newly replicated chromosomes to lethal attack by the remaining restriction enzyme molecules. This process is in apparent contrast to the process of the classical types of postsegregational killing systems, in which built-in metabolic instability of the antitoxin allows release of the toxin for lethal action after the gene loss. In the present study, we characterize a mutant form of the EcoRII gene complex that shows stronger capacity in such maintenance. This phenotype is conferred by an L80P amino acid substitution (T239C nucleotide substitution) mutation in the modification enzyme. This mutant enzyme showed decreased DNA methyltransferase activity at a higher temperature in vivo and in vitro than the nonmutated enzyme, although a deletion mutant lacking the N-terminal 83 amino acids did not lose activity at either of the temperatures tested. Under a condition of inhibited protein synthesis, the activity of the L80P mutant was completely lost at a high temperature. In parallel, the L80P mutant protein disappeared more rapidly than the wild-type protein. These results demonstrate that the capability of a restriction-modification system in forcing maintenance on its host can be modulated by a region of its antitoxin, the modification enzyme, as in the classical postsegregational killing systems.

Negative regulation of the EcoRI restriction enzyme gene is associated with intragenic reverse promoters

Type II restriction-modification systems are expected to possess mechanisms for tight regulation of their expression to suppress the potential of lethal attack on their host bacteria when they establish and maintain themselves within them. Although the EcoRI restriction enzyme has been well characterized, regulation of its expression is still poorly understood. In this study, mutational analysis with lacZ gene fusion and primer extension assay identified a promoter for the transcription of the ecoRIR gene. Further analyses revealed that an intragenic region containing two overlapping reverse promoter-like elements acted as a negative regulator for ecoRIR gene expression. The activity of these putative reverse promoters was verified by transcriptional gene fusion, primer extension and in vitro transcription. Mutations in these reverse promoters resulted in increased gene expression in both translational and transcriptional gene fusions. An RNase protection assay revealed that the transcript level of the wild type relative to that of the reverse promoter mutant at the downstream regions was much lower than the level at the upstream regions. This suggests that these reverse promoter-like elements affect their downstream transcript level. The possible mechanisms of this kind of negative regulation, in addition to their possible biological roles, are discussed.

Regulation of the EcoRI restriction-modification system: Identification of ecoRIM gene promoters and their upstream negative regulators in the ecoRIR gene

Type II restriction-modification (R-M) systems are composed of linked restriction endonuclease and modification methyltransferase genes and serve as barriers to horizontal gene transfer even though they are mobile in themselves. Their products kill host bacterial cells that have lost the R-M genes, a process that helps to maintain the frequency of the R-M systems in the viable cell population. Their establishment and maintenance in a bacterial host are expected to involve fine regulation of their gene expression. In the present study, we analyzed transcription of the modification gene and its regulation within the EcoRI R-M system. Northern blotting revealed that the downstream ecoRIM gene is transcribed as a monocistronic mRNA and as part of a larger bicistronic mRNA together with the upstream ecoRIR gene. Primer extension, RNase protection, and mutational analysis using lacZ gene fusions identified two overlapping promoters for ecoRIM gene transcription within the ecoRIR gene. Further mutational analysis revealed that two upstream AT-rich elements within the ecoRIR gene, "AATAAA" and "ATTATAAATATA," function as negative regulators of these promoters. Simultaneous substitution of these two elements resulted in a four-fold increase in beta-galactosidase activity and a five-fold increase in transcript levels as measured by RNase protection assay. RNA measurements of the ecoRIM transcript suggested that these elements decreased ecoRIM expression by interfering with transcription initiation of the ecoRIM promoters. Possible roles for these ecoRIM promoters and their negative regulators in the EcoRI R-M system are discussed.

Stability of EcoRI restriction-modification enzymes in vivo differentiates the EcoRI restriction-modification system from other postsegregational cell killing systems

Certain type II restriction modification gene systems can kill host cells when these gene systems are eliminated from the host cells. Such ability to cause postsegregational killing of host cells is the feature of bacterial addiction modules, each of which consists of toxin and antitoxin genes. With these addiction modules, the differential stability of toxin and antitoxin molecules in cells plays an essential role in the execution of postsegregational killing. We here examined in vivo stability of the EcoRI restriction enzyme (toxin) and modification enzyme (antitoxin), the gene system of which has previously been shown to cause postsegregational host killing in Escherichia coli. Using two different methods, namely, quantitative Western blot analysis and pulse-chase immunoprecipitation analysis, we demonstrated that both the EcoRI restriction enzyme and modification enzyme are as stable as bulk cellular proteins and that there is no marked difference in their stability. The numbers of EcoRI restriction and modification enzyme molecules present in a host cell during the steady-state growth were estimated. We monitored changes in cellular levels of the EcoRI restriction and modification enzymes during the postsegregational killing. Results from these analyses together suggest that the EcoRI gene system does not rely on differential stability between the toxin and the antitoxin molecules for execution of postsegregational cell killing. Our results provide insights into the mechanism of postsegregational killing by restriction-modification systems, which seems to be distinct from mechanisms of postsegregational killing by other bacterial addiction modules.

A dual lethal system to enhance containment of recombinant micro-organisms

Active containment systems based on the controlled expression of a lethal gene are designed to increase containment of recombinant micro-organisms used for environmental applications. A major drawback in containment is the existence of mutations that generate surviving cells that cease to respond to the toxic effect of the lethal function. In this work the authors have developed for the first time a strategy to reduce the problem of mutations and increase the efficiency of containment based on the combination of two lethal functions acting on different cellular targets of major concern in containment, DNA and RNA, and whose expression is under control of different regulatory signals. To engineer the dual gene containment circuit, two toxin–antitoxin pairs, i.e. the colicin E3–immunity E3 and theEcoRI restriction–modification systems, were combined. The genes encoding the immunity E3 and theEcoRI methyltransferase proteins (antitoxins) were stably inserted into the chromosome of the host cell, whereas the broad-host-range lethal genes encoding the colicin E3 RNase and theEcoRI restriction endonuclease (toxins) were flanking the contained trait in a plasmid. This dual lethal cassette decreased gene transfer frequencies, through killing of the recipient cells, by eight orders of magnitude, which provides experimental evidence that the anticipated containment level due to the combination of single containment systems is generally achieved. Survivors that escaped killing were analysed and the mutational events involved were characterized.

Positive selection vectors

This review describes information concerning positive selection vectors on their mechanism, classification, property, and limitation. A total of 72 positive selection vectors collected were discussed. Positive selection vectors can reduce background and directly screen transformants containing cloned DNA fragments. The mechanisms to perform positive selection include insertional inactivation and the replacement of functional genes of the vectors. In general, the former is much more convenient than the latter. The functional genes are controlled either by their promoters or by heterologous promoters introduced. On the basis of the structures, positive selection vectors could be classified into five groups. The positive selection vectors are commonly based on the mechanisms of lethal genes and the sensitivity of compounds. The vectors, with molecular weights ranging from 2.6 to 17.0 kb, have diverse genetic markers and wide host ranges, including Escherichia coli, Bacillus, Streptomyces, lactic acid bacteria, yeasts, and mammalian cells. Although some limitations exist for using some positive selection vectors, they are useful in recombinant DNA experiments.

Plasmid-encoded phthalate catabolic pathway in Arthrobacter keyseri 12B

Several 2-substituted benzoates (including 2-trifluoromethyl-, 2-chloro-, 2-bromo-, 2-iodo-, 2-nitro-, 2-methoxy-, and 2-acetyl-benzoates) were converted by phthalate-grown Arthrobacter keyseri (formerly Micrococcus sp.) 12B to the corresponding 2-substituted 3,4-dihydroxybenzoates (protocatechuates). Because these products lack a carboxyl group at the 2 position, they were not substrates for the next enzyme of the phthalate catabolic pathway, 3,4-dihydroxyphthalate 2-decarboxylase, and accumulated. When these incubations were carried out in iron-containing minimal medium, the products formed colored chelates. This chromogenic response was subsequently used to identify recombinant Escherichia coli strains carrying genes encoding the responsible enzymes, phthalate 3,4-dioxygenase and 3,4-dihydroxy-3,4-dihydrophthalate dehydrogenase, from the 130-kbp plasmid pRE1 of strain 12B. Beginning with the initially cloned 8.14-kbp PstI fragment of pRE824 as a probe to identify recombinant plasmids carrying overlapping fragments, a DNA segment of 33.5 kbp was cloned from pRE1 on several plasmids and mapped using restriction endonucleases. From these plasmids, the sequence of 26,274 contiguous bp was determined. Sequenced DNA included several genetic units: tnpR, pcm operon, ptr genes, pehA, norA fragment, and pht operon, encoding a transposon resolvase, catabolism of protocatechuate (3,4-dihydroxybenzoate), a putative ATP-binding cassette transporter, a possible phthalate ester hydrolase, a fragment of a norfloxacin resistance-like transporter, and the conversion of phthalate to protocatechuate, respectively. Activities of the eight enzymes involved in the catabolism of phthalate through protocatechuate to pyruvate and oxaloacetate were demonstrated in cells or cell extracts of recombinant E. coli strains.

A gene containment strategy based on a restriction-modification system

Engineering barriers to the spread of specific genes are of great interest both to increase the predictability of recombinant microorganisms used for environmental applications and to study the role of gene transfer in the adaptation of microbial communities to changing environments. We report here a new gene containment circuit based on a toxin-antidote pair that targets the cell DNA, i.e. the type II EcoRI restriction-modification system. The set-up involved linkage of the ecoRIR lethal gene encoding the EcoRI endonuclease (toxin) to the contained character in a plasmid and chromosomal insertion of the ecoRIM gene encoding the cognate EcoRI methylase (antidote) that protects the target DNA from restriction. Transfer of the contained character to a recipient cell lacking the antidote caused EcoRI-mediated chromosomal breaks, leading to cell death, thereby preventing gene spread. Using transformation and conjugation as mechanisms of DNA transfer and different environmentally relevant bacteria as recipients, we have shown that the potentially universal EcoRI-based containment system decreases gene transfer frequencies by more than four orders of magnitude. Analyses of the survivors escaping killing revealed a number of possible inactivation mechanisms.

Role and mechanism of action of C. PvuII, a regulatory protein conserved among restriction-modification systems

The PvuII restriction-modification system is a type II system, which means that its restriction endonuclease and modification methyltransferase are independently active proteins. The PvuII system is carried on a plasmid, and its movement into a new host cell is expected to be followed initially by expression of the methyltransferase gene alone so that the new host's DNA is protected before endonuclease activity appears. Previous studies have identified a regulatory gene (pvuIIC) between the divergently oriented genes for the restriction endonuclease (pvuIIR) and modification methyltransferase (pvuIIM), with pvuIIC in the same orientation as and partially overlapping pvuIIR. The product of pvuIIC, C. PvuII, was found to act in trans and to be required for expression of pvuIIR. In this study we demonstrate that premature expression of pvuIIC prevents establishment of the PvuII genes, consistent with the model that requiring C. PvuII for pvuIIR expression provides a timing delay essential for protection of the new host's DNA. We find that the opposing pvuIIC and pvuIIM transcripts overlap by over 60 nucleotides at their 5' ends, raising the possibility that their hybridization might play a regulatory role. We furthermore characterize the action of C. PvuII, demonstrating that it is a sequence-specific DNA-binding protein that binds to the pvuIIC promoter and stimulates transcription of both pvuIIC and pvuIIR into a polycistronic mRNA. The apparent location of C. PvuII binding, overlapping the -10 promoter hexamer and the pvuIICR transcriptional starting points, is highly unusual for transcriptional activators.

p-Cymene catabolic pathway in Pseudomonas putida F1: cloning and characterization of DNA encoding conversion of p-cymene to p-cumate

Pseudomonas putida F1 utilizes p-cymene (p-isopropyltoluene) by an 11-step pathway through p-cumate (p-isopropylbenzoate) to isobutyrate, pyruvate, and acetyl coenzyme A. The cym operon, encoding the conversion of p-cymene to p-cumate, is located just upstream of the cmt operon, which encodes the further catabolism of p-cumate and is located, in turn, upstream of the tod (toluene catabolism) operon in P. putida F1. The sequences of an 11,236-bp DNA segment carrying the cym operon and a 915-bp DNA segment completing the sequence of the 2,673-bp DNA segment separating the cmt and tod operons have been determined and are discussed here. The cym operon contains six genes in the order cymBCAaAbDE. The gene products have been identified both by functional assays and by comparing deduced amino acid sequences to published sequences. Thus, cymAa and cymAb encode the two components of p-cymene monooxygenase, a hydroxylase and a reductase, respectively; cymB encodes p-cumic alcohol dehydrogenase; cymC encodes p-cumic aldehyde dehydrogenase; cymD encodes a putative outer membrane protein related to gene products of other aromatic hydrocarbon catabolic operons, but having an unknown function in p-cymene catabolism; and cymE encodes an acetyl coenzyme A synthetase whose role in this pathway is also unknown. Upstream of the cym operon is a regulatory gene, cymR. By using recombinant bacteria carrying either the operator-promoter region of the cym operon or the cmt operon upstream of genes encoding readily assayed enzymes, in the presence or absence of cymR, it was demonstrated that cymR encodes a repressor which controls expression of both the cym and cmt operons and is inducible by p-cumate but not p-cymene. Short (less than 350 bp) homologous DNA segments that are located upstream of cymR and between the cmt and tod operons may have been involved in recombination events that led to the current arrangement of cym, cmt, and tod genes in P. putida F1.

Reductase gene sequences and protein structures: p-cymene methyl hydroxylase

Oxygenases are critical to cycling carbon in the biosphere and dependent on reductase action, principally from flavoprotein enzymes. Oxygenase diversity among organisms and strains carries a common theme of protein sequence and folding. p-Cymene (para-isopropyl toluene) was chosen as a point of convergence in terpene-aromatic mineralization to characterize a methyl hydroxylase electron transport system with the aerobe Pseudomonas aureofaciens. The cymA hydroxylase reductase gene was isolated and sequenced and the protein primary structure deduced. Optimized amino acid sequence alignments of flavoprotein reductases revealed major similarities over protein length, in the binding domains for NAD(P)H, and the flavine centers of pro- and eukaryote systems.

Cloning and analysis of the genes encoding the type IIS restriction-modification system HphI from Haemophilus parahaemolyticus

The genomic region encoding the type IIS restriction-modification (R-M) system HphI (enzymes recognizing the asymmetric sequence 5'-GGTGA-3'/5'-TCACC-3') from Haemophilus parahaemolyticus were cloned into Escherichia coli and sequenced. Sequence analysis of the R-M HphI system revealed three adjacent genes aligned in the same orientation: a cytosine 5 methyltransferase (gene hphIMC), an adenine N6 methyltransferase (hphIMA) and the HphI restriction endonuclease (gene hphIR). Either methyltransferase is capable of protecting plasmid DNA in vivo against the action of the cognate restriction endonuclease. hphIMA methylation renders plasmid DNA resistant to R.Hindill at overlapping sites, suggesting that the adenine methyltransferase modifies the 3'-terminal A residue on the GGTGA strand. Strong homology was found between the N-terminal part of the m6A methyltransferasease and an unidentified reading frame interrupted by an incomplete gaIE gene of Neisseria meningitidis. The HphI R-M genes are flanked by a copy of a 56 bp direct nucleotide repeat on each side. Similar sequences have also been identified in the non-coding regions of H.influenzae Rd DNA. Possible involvement of the repeat sequences in the mobility of the HphI R-M system is discussed.

p-Cumate catabolic pathway in Pseudomonas putida Fl: cloning and characterization of DNA carrying the cmt operon

Pseudomonas putida F1 utilizes p-cumate (p-isopropylbenzoate) as a growth substrate by means of an eight-step catabolic pathway. A 35.75-kb DNA segment, within which the cmt operon encoding the catabolism of p-cumate is located, was cloned as four separate overlapping restriction fragments and mapped with restriction endonucleases. By examining enzyme activities in recombinant bacteria carrying these fragments and sub-cloned fragments, genes encoding most of the enzymes of the p-cumate pathway were located. Subsequent sequence analysis of 11,260 bp gave precise locations of the 12 genes of the cmt operon. The first three genes, cmtAaAbAc, and the sixth gene, cmtAd, encode the components of p-cumate 2,3-dioxygenase (ferredoxin reductase, large subunit of the terminal dioxygenase, small subunit of the terminal dioxygenase, and ferredoxin, respectively); these genes are separated by cmtC, which encodes 2,3-dihydroxy-p-cumate 3,4-dioxygenase, and cmtB, coding for 2,3-dihydroxy-2,3-dihydro-p-cumate dehydrogenase. The ring cleavage product, 2-hydroxy-3-carboxy-6-oxo-7-methylocta-2,4-dienoate, is acted on by a decarboxylase encoded by the seventh gene, cmtD, which is followed by a large open reading frame, cmtI, of unknown function. The next four genes, cmtEFHG, encode 2-hydroxy-6-oxo-7-methylocta-2,4-dienoate hydrolase, 2-hydroxypenta-2,4-dienoate hydratase, 4-hydroxy-2-oxovalerate aldolase, and acetaldehyde dehydrogenase, respectively, which transform the decarboxylation product to amphibolic intermediates. The deduced amino acid sequences of all the cmt gene products except CmtD and CmtI have a recognizable but low level of identity with amino acid sequences of enzymes catalyzing analogous reactions in other catabolic pathways. This identity is highest for the last two enzymes of the pathway (4-hydroxy-2-oxovalerate aldolase and acetaldehyde dehydrogenase [acylating]), which have identities of 66 to 77% with the corresponding enzymes from other aromatic meta-cleavage pathways. Recombinant bacteria carrying certain restriction fragments bordering the cmt operon were found to transform indole to indigo. This reaction, known to be catalyzed by toluene 2,3-dioxygenase, led to the discovery that the tod operon, encoding the catabolism of toluene, is located 2.8 kb downstream from and in the same orientation as the cmt operon in P. putida F1.

Formation of indigo and related compounds from indolecarboxylic acids by aromatic acid-degrading bacteria: chromogenic reactions for cloning genes encoding dioxygenases that act on aromatic acids

The p-cumate-degrading strain Pseudomonas putida F1 and the m- and p-toluate-degrading strain P. putida mt-2 transform indole-2-carboxylate and indole-3-carboxylate to colored products identified here as indigo, indirubin, and isatin. A mechanism by which these products could be formed spontaneously following dioxygenase-catalyzed dihydroxylation of the indolecarboxylates is proposed. Indolecarboxylates were employed as chromogenic substrates for identifying recombinant bacteria carrying genes encoding p-cumate dioxygenase and toluate dioxygenase. Dioxygenase gene-carrying bacteria could be readily distinguished as dark green-blue colonies among other colorless recombinant Escherichia coli colonies on selective agar plates containing either indole-2-carboxylate or indole-3-carboxylate.

Positive-selection vectors using the F plasmid ccdB killer gene

Plasmids pKIL18/19 are positive-selection cloning vectors containing an active cytotoxic ccdB gene under the control of the lacP promoter. They are derivatives of high-copy-number pUC18/19 plasmids in which the ccdB killer gene has been fused in phase downstream from the lacP MCS18 and MCS19 multiple cloning sites. When an Escherichia coli wild-type gyrA+ strain is transformed by such vectors, the ccdB gene product blocks bacterial growth. However, if ccdB is inactivated by insertion of a foreign DNA fragment, this recombinant plasmid no longer interferes with host viability. The positive selection of recombinant clones is highly efficient and bench manipulations are simplified to the utmost: E. coli transformants are plated on rich medium and only cells containing recombinant plasmids give rise to colonies. The CcdB protein is a potent poison of gyrase and the gyrA462 mutation confers total resistance to CcdB [Bernard and Couturier, J. Mol. Biol. 226 (1992) 735-745]. Therefore, pKIL18/19 vectors can be amplified and prepared in large quantities in a gyrA462 host. Like pUC vectors, pKIL vectors are designed for general cloning/sequencing procedures.

Accumulation and intracellular fate of tellurite in tellurite-resistant Escherichia coli: a model for the mechanism of resistance

The tellurite accumulation properties of three Escherichia coli strains containing different tellurium-resistance determinants of Gram-negative origin, from plasmids pMER610, pHH1508a and RK2, were compared. In all three cases membrane-associated tellurium crystallization was observed, and neither reduced uptake nor increased export contributed to the resistance. Specific membrane-proximal reduction is proposed as the mechanism of resistance to tellurite coded by all three determinants, despite their lack of sequence homology.

Complex transcription of an operon encoding the SalI restriction-modification system of Streptomyces albus G

High-resolution S1 nuclease mapping of mRNA synthesised in vivo, in vitro run-off transcription with RNA polymerase from Streptomyces lividans and gene fusions were used to analyse the transcriptional organization of the SalI restriction-modification system of Streptomyces albus G. The salIR and salIM genes that encode the restriction endonuclease and its cognate methyltransferase constitute an operon which is mainly transcribed from sal-pR1, a promoter located immediately upstream of salIR, with two possible minor promoters further upstream. Another promoter, sal-pM, is within the 3' end of the salIR coding region, and allows expression of the modification gene in the absence of sal-pR1. The sal-pM promoter might be involved in the establishment of modification prior to restriction endonuclease activity. Sequences upstream of the apparent transcriptional start sites for sal-pR1 and sal-pM show similarity with the -10 region of typical vegetatively expressed eubacterial promoters, but appropriately centered -35 regions are absent.

Bacterial metabolism of naphthalene: construction and use of recombinant bacteria to study ring cleavage of 1,2-dihydroxynaphthalene and subsequent reactions

The reactions involved in the bacterial metabolism of naphthalene to salicylate have been reinvestigated by using recombinant bacteria carrying genes cloned from plasmid NAH7. When intact cells of Pseudomonas aeruginosa PAO1 carrying DNA fragments encoding the first three enzymes of the pathway were incubated with naphthalene, they formed products of the dioxygenase-catalyzed ring cleavage of 1,2-dihydroxynaphthalene. These products were separated by chromatography on Sephadex G-25 and were identified by 1H and 13C nuclear magnetic resonance spectroscopy and gas chromatography-mass spectrometry as 2-hydroxychromene-2-carboxylate (HCCA) and trans-o-hydroxybenzylidenepyruvate (tHBPA). HCCA was detected as the first reaction product in these incubation mixtures by its characteristic UV spectrum, which slowly changed to a spectrum indicative of an equilibrium mixture of HCCA and tHBPA. Isomerization of either purified product occurred slowly and spontaneously to give an equilibrium mixture of essentially the same composition. tHBPA is also formed from HCCA by the action of an isomerase enzyme encoded by plasmid NAH7. The gene encoding this enzyme, nahD, was cloned on a 1.95-kb KpnI-BglII fragment. Extracts of Escherichia coli JM109 carrying this fragment catalyzed the rapid equilibration of HCCA and tHBPA. Metabolism of tHBPA to salicylaldehyde by hydration and aldol cleavage is catalyzed by a single enzyme encoded by a 1-kb MluI-StuI restriction fragment. A mechanism for the hydratase-aldolase-catalyzed reaction is proposed. The salicylaldehyde dehydrogenase gene, nahF, was cloned on a 2.75-kb BamHI fragment which also carries the naphthalene dihydrodiol dehydrogenase gene, nahB. On the basis of the identification of the enzymes encoded by various clones, the gene order for the nah operon was shown to be p, A, B, F, C, E, D.

Functional complementation between chromosomal and plasmid mutagenic DNA repair genes in bacteria

The umuDC operons of Escherichia coli and Salmonella typhimurium and the analogous plasmid operons mucAB and impCAB have been previously characterized in terms of their roles in DNA repair and induced mutagenesis by radiation and many chemicals. The interrelationships of these mutagenic DNA repair operons were examined in vivo in functional tests of interchangeability of operon subunits in conferring UV resistance and UV mutability phenotypes to wild-type S. typhimurium and umu mutants of E. coli. This approach was combined with DNA and protein sequence comparisons between the four operons and a fifth operon, samAB, from the S. typhimurium LT2 cryptic plasmid. Components of the E. coli and S. typhimurium umu operons were reciprocally interchangeable whereas impCA and mucA could not function with umuC in either of these species. mucA and impB could also combine to give a mutagenic response to UV. These active combinations were associated with higher degrees of conservation of protein sequence than in other heterologous gene combinations and related to specific regions of sequence that may specify subunit interactions. The dominance of the E. coli umuD44 mutation over umuD was revealed in both wild-type E. coli and S. typhimurium and also demonstrated against impCAB. Finally interspecies transfer showed that the apparently poor activity of the S. typhimurium umuD gene in situ is not the result of an inherent defect in umuD but is due to the simultaneous presence of the S. typhimurium umuC sequence. It is suggested that the limitation of umuD activity by umuC in S. typhimurium is the basis of the poor induced mutability of this organism.

Novel mercury resistance determinants carried by IncJ plasmids pMERPH and R391

HgCl2 resistance (Hgr) in a strain of Pseudomonas putrefaciens isolated from the River Mersey was identified as plasmid-borne by its transfer to Escherichia coli in conjugative matings. This plasmid, pMERPH, could not be isolated and was incompatible with the chromosomally integrated IncJ Hgr plasmid R391. pMERPH and R391 both express inducible, narrow-spectrum mercury resistance and detoxify HgCl2 by volatilization. The cloned mer determinants from pMERPH (pSP100) and R391 (pSP200) have very similar restriction maps and express identical polypeptide products. However, these features show distinct differences from those of the Tn501 family of mer determinants. pSP100 and pSP200 failed to hybridize at moderate stringency to merRTPA and merC probes from Tn501 and Tn21, respectively. We conclude that the IncJ mer determinants are only distantly related to that from Tn501 and its closely homologous relatives and that it identifies a novel sequence which is relatively rare in bacteria isolated from natural environments.

Cloning the BstVI restriction-modification system in Escherichia coli

A standard DNA modification methyltransferase (MTase) selection protocol was followed to clone the BstVI restriction and modification system from Bacillus stearothermophilus in Escherichia coli. Both genes were contained in a 4.4-kb EcoRI fragment from B. stearothermophilus V chromosomal DNA. The heterologous expression of these genes did not depend on their orientation in the vector, suggesting that the genes are expressed in E. coli under the control of promoters located on the cloned fragment. Subcloning experiments demonstrated that the bstVIR gene was expressed in the absence of its cognate MTase.

Cloning and comparison of the DNA encoding ammelide aminohydrolase and cyanuric acid amidohydrolase from three s-triazine-degrading bacterial strains

DNA encoding the catabolism of the s-triazines ammelide and cyanuric acid was cloned from Pseudomonas sp. strain NRRLB-12228 and Klebsiella pneumoniae 99 with, as a probe, a 4.6-kb PstI fragment from a third strain, Pseudomonas sp. strain NRRLB-12227, which also encodes these activities. In strains NRRLB-12228 and 99 the ammelide aminohydrolase (trzC) and cyanuric acid amidohydrolase (trzD) genes are located on identical 4.6-kb PstI fragments which are part of a 12.4-kb DNA segment present in both strains. Strain NRRLB-12227 also carries this 12.4-kb DNA segment, except that a DNA segment of 0.8 to 1.85 kb encoding a third enzyme, ammeline aminohydrolase (trzB), has been inserted next to the ammelide aminohydrolase gene with the accompanying deletion of 1.1 to 2.15 kb of DNA. In addition, the s-triazine catabolic genes are flanked in strain NRRLB-12227 by apparently identical 2.2-kb segments that are not present in the other two strains and that seem to cause rearrangements in adjacent DNA.

Cloning and analysis of s-triazine catabolic genes from Pseudomonas sp. strain NRRLB-12227

Pseudomonas sp. strain NRRLB-12227 degrades the s-triazine melamine by a six-step pathway which allows it to use melamine and pathway intermediates as nitrogen sources. With the plasmid pLG221, mutants defective in five of the six steps of the pathway were generated. Tn5-containing-EcoRI fragments from these mutants were cloned and identified by selection for Tn5-encoded kanamycin resistance in transformants. A restriction fragment from ammelide-negative mutant RE411 was used as a probe in colony hybridization experiments to identify cloned wild-type s-triazine catabolic genes encoding ammeline aminohydrolase, ammelide aminohydrolase, and cyanuric acid amidohydrolase. These genes were cloned from total cellular DNA on several similar, but not identical, HindIII fragments, as well as on a PstI fragment and a BglII fragment. Restriction mapping and Southern hybridization analyses of these cloned DNA fragments suggested that these s-triazine catabolic genes may be located on a transposable element, the ends of which are identical 2.2-kb insertion sequences.

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)

Cytosine methylation enhances Z-DNA formation in vivo

The influence of cytosine methylation on the supercoil-stabilized B-Z equilibrium in Escherichia coli was analyzed by two independent assays. Both the M.EcoRI inhibition assay and the linking-number assay have been used previously to establish that dC-dG segments of sufficient lengths can exist as left-handed helices in vivo. A series of dC-dG plasmid inserts with Z-form potential, ranging in length from 14 to 74 base pairs, was investigated. Complete methylation of cytosine at all HhaI sites, including the inserts, was obtained by coexpression of the HhaI methyltransferase (M.HhaI) in cells also carrying a dC-dG-containing plasmid. Both assays showed that for all lengths of dC-dG inserts, the relative amounts of B and Z helices were shifted to more Z-DNA in the presence of M.HhaI than in the absence of M.HhaI. These results indicate that cytosine methylation enhances the formation of Z-DNA helices at the superhelix density present in E. coli. The B-Z equilibrium, in combination with site-specific base methylation, may constitute a concerted mechanism for the modulation of DNA topology and DNA-protein interactions.

Purification, cloning and sequence analysis of RsrI DNA methyltransferase: lack of homology between two enzymes, RsrI and EcoRI, that methylate the same nucleotide in identical recognition sequences

RsrI DNA methyltransferase (M-RsrI) from Rhodobacter sphaeroides has been purified to homogeneity, and its gene cloned and sequenced. This enzyme catalyzes methylation of the same central adenine residue in the duplex recognition sequence d(GAATTC) as does M-EcoRI. The reduced and denatured molecular weight of the RsrI methyltransferase (MTase) is 33,600 Da. A fragment of R. sphaeroides chromosomal DNA exhibited M.RsrI activity in E. coli and was used to sequence the rsrIM gene. The deduced amino acid sequence of M.RsrI shows partial homology to those of the type II adenine MTases HinfI and DpnA and N4-cytosine MTases BamHI and PvuII, and to the type III adenine MTases EcoP1 and EcoP15. In contrast to their corresponding isoschizomeric endonucleases, the deduced amino acid sequences of the RsrI and EcoRI MTases show very little homology. Either the EcoRI and RsrI restriction-modification systems assembled independently from closely related endonuclease and more distantly related MTase genes, or the MTase genes diverged more than their partner endonuclease genes. The rsrIM gene sequence has also been determined by Stephenson and Greene (Nucl. Acids Res. (1989) 17, this issue).

Nucleotide sequence and genetic organization of the NgoPII restriction-modification system of Neisseria gonorrhoeae

The NgoPII restriction endonuclease, which recognizes the sequence 5'-GG decreases CC-3', differs from its isoschizomer HaeIII in being sensitive to methylation at the external cytosine residue. The entire nucleotide sequence of a cloned 3.3 kb segment of Neisseria gonorrhoeae strain P9 chromosomal DNA which harbours the NgoPII restriction-modification system has been determined. This data, coupled with sub-cloning experiments, indicates that the restriction endonuclease (R.NgoII) and modification (M.NgoII) genes are transcribed from separate promoters but are arranged in tandem, with the R.NgoPII gene being located on the 5' side of the M.NgoPII gene. Unlike all previously reported restriction systems the 3' end of the endonuclease open reading frame overlaps the 5' end of the methylase open reading frame by 8 codons. This overlap may have implications for the regulation of the NgoPII restriction-modification system.

Genetic engineering of EcoRI mutants with altered amino acid residues in the DNA binding site: physicochemical investigations give evidence for an altered monomer/dimer equilibrium for the Gln144Lys145 and Gln144Lys145Lys200 mutants

We have genetically engineered the Arg200----Lys mutant, the Glu144Arg145----GlnLys double mutant, and the Glu144Arg145Arg200----GlnLysLys triple mutant of the EcoRI endonuclease in extension of previously published work on site-directed mutagenesis of the EcoRI endonuclease in which Glu144 had been exchanged for Gln and Arg145 for Lys [Wolfes et al. (1986) Nucleic Acids Res. 14, 9063]. All these mutants carry modifications in the DNA binding site. Mutant EcoRI proteins were purified to homogeneity and characterized by physicochemical techniques. All mutants have a very similar secondary structure composition. However, whereas the Lys200 mutant is not impaired in its capacity to form a dimer, the Gln144Lys145 and Gln144Lys145Lys200 mutants have a very much decreased propensity to form a dimer or tetramer depending on concentration as shown by gel filtration and analytical ultracentrifugation. This finding may explain the results of isoelectric focusing experiments which show that these two mutants have a considerably more basic pI than expected for a protein in which an acidic amino acid was replaced by a neutral one. Furthermore, while wild-type EcoRI and the Lys200 mutant are denatured in an irreversible manner upon heating to 60 degrees C, the thermal denaturation process as shown by circular dichroism spectroscopy is fully reversible with the Gln144Lys145 double mutant and the Gln144Lys145Lys200 triple mutant. All EcoRI endonuclease mutants described here have a residual enzymatic activity with wild-type specificity, since Escherichia coli cells overexpressing the mutant proteins can only survive in the presence of EcoRI methylase. The detailed analysis of the enzymatic activity and specificity of the purified mutant proteins is the subject of the accompanying paper [Alves et al. (1989) Biochemistry (following paper in this issue)].

In vivo existence of left-handed DNA

A genetic-biochemical assay has been developed to investigate the in vivo existence and consequences of unusual DNA structures. Left-handed DNA was shown to exist in living Escherichia coli. The EcoRI methyltransferase gene (temperature-sensitive) was cloned to serve as a probe for perturbed GAATTC sites in vivo. This plasmid was cotransformed with different plasmids containing inserts that had varying capacities to form left-handed helices or cruciforms with a target EcoRI site in the center or at the ends of the inserts. Inhibition of methylation in vivo was found for the stable inserts with the longest left-handed helices. In vitro methylation with the purified M.EcoRI enzyme agreed with the in vivo results.

Restriction pattern and polypeptide homology among plasmid-borne mercury resistance determinants

The structural and functional properties of mercury resistance determinants cloned from a series of independently isolated conjugative plasmids were compared with those of the prototype HgR determinants from Tn501 and plasmid R100 (containing Tn21). Restriction endonuclease mapping classified the HgR determinants into at least three different but related structural groups which are distantly related to those from Tn501 and R100. These relationships were confirmed by the functional analysis of sub-clones and gamma delta insertion mutations and from the polypeptides specified by the cloned HgR determinants. Each mercury resistance clone synthesized polypeptides equivalent in size to the merA, merT, and merP gene products. However, those for merA and merT showed considerable size variation. No polypeptide equivalent to merD or merC of R100 was detected.

The nucleotide sequence of a plasmid determinant for resistance to tellurium anions

The plasmid pMJ606 contains a 5-kb insert specifying resistance to tellurium salts (TeR) which was cloned from the large conjugative plasmid pMER610. Nucleotide sequence analysis of this insert has identified five open reading frames (ORFs). ORFs 1, 2, 4 and 5 correspond in terms of their predicted polypeptide products to the 41, 15.5, 22 and 23-kDa polypeptides, respectively, which are synthesised by the resistance determinant in maxicells. An additional ORF, ORF3, whose product has not been identified is predicted by the sequence data. The sequence of the presumptive polypeptide specified by ORF3 indicates a membrane location. The nucleotide and predicted amino acid sequences of ORF4 and ORF5 show considerable homology which is consistent with the duplication and minor divergence of an ancestral gene. ORFs 4 and 5 appear to retain the same function and while each can function separately and contribute to the resistance mechanism, the full level of wild-type resistance requires both genes to function. The transcriptional signals for the TeR determinant may be located beyond and 5' of the sequences cloned in pMJ606.

Left-handed DNA in vivo

Left-handed DNA is shown to exist and elicit a biological response in Escherichia coli. A plasmid encoding the gene for a temperature-sensitive Eco RI methylase (MEco RI) was cotransformed with different plasmids containing inserts that had varying capacities to form left-handed helices or cruciforms with a target Eco RI site in the center or at the ends of the inserts. Inhibition of methylation in vivo was found for the stable inserts with the longest left-handed (presumably Z) helices. In vitro methylation with the purified MEco RI agreed with the results in vivo. Supercoil-induced changes in the structure of the primary helix in vitro provided confirmation that left-handed helices were responsible for this behavior. The presence in vivo of left-handed inserts elicits specific deletions and plasmid incompatibilities in certain instances.

Highly repressible expression system for cloning genes that specify potentially toxic proteins

A highly repressible expression vector system that allows the cloning of potentially deleterious genes has been constructed. Undesired expression of a cloned gene was prevented (i) at the level of initiation of transcription, by the presence of the strong but highly repressible leftward promoter of bacteriophage lambda, lambda pL, and (ii) at the level of transcript elongation or translation, through synthesis of antisense RNA complementary to the mRNA of the cloned gene. The system was tested by measuring the inhibition of expression of traT, the gene for the TraT major outer membrane lipoprotein. Direct detection and functional assays indicated that an essentially complete inhibition of traT expression was obtained. As a further test of the system, the gene encoding the EcoRI restriction endonuclease was cloned in the absence of the gene of the corresponding protective EcoRI modification methylase. Transformants harboring this construct were only viable when both repression controls were operational.

Conjugal mobility of the multicopy plasmids NTP1 and NTP16

Mobilization of the multicopy plasmid NTP16, like that of ColE1, is promoted by a range of conjugal plasmids. However, the mechanisms employed for NTP16 mobilization differ between groups. Mobilization by the IncI1 plasmid R64 requires trans-acting products from NTP16 plus a cis-acting region of the small plasmid. In contrast, this system is used inefficiently by the F plasmid and instead, a high-frequency conduction process occurs. Analysis of exconjugant cells reveals that F-mediated mobilization of NTP16 frequently involves rearrangements of NTP16 DNA, promoted by the Tn1000 transposon of F and/or by the kanamycin resistance transposon (Tn4352) of NTP16. Possible mechanisms for the high-frequency F-mediated mobilization of NTP16 are discussed. The plasmid NTP1, which is closely related to NTP16, is also mobilized efficiently by R64. It is not however efficiently mobilized by F, demonstrating the requirement for the Tn4352 element, which is not present in this plasmid, for effective F-mediated transfer.

Genetic and physical analysis of plasmid genes expressing inducible resistance of tellurite in Escherichia coli

A large (greater than 250 kb) conjugative plasmid, pMER610, specifying resistance to tellurium and mercury was isolated from an Alcaligenes strain and transferred by conjugation to Escherichia coli AB1157. The acquisition of pMER610 by AB1157 increased the resistance to both telurite and tellurate by 100-fold. Expression of tellurite resistance by pMER610 and the cloned Ter determinant was inducible by prior exposure to tellurite at levels sub-toxic to the sensitive AB1157. Physical analysis of the cloned Ter fragment located the resistance determinant to a 3.55 kb region. Insertion of Tn 1000 (gamma delta) into this region produced two classes of sensitive mutations, fully sensitive and intermediate or hyposensitive, which map in adjacent regions and form two complementation groups. Maxicell analysis identified four polypeptides (15.5, 22, 23 and 41 kDa) expressed by the Ter clone. The 23 kDa polypeptide may not be required for resistance since tellurium-sensitive gamma delta insertion mutations were not detected in the 23 kDa coding region.

Characterization of the drug resistance plasmid NTP16

A functional and physical analysis of the multicopy plasmid NTP16 is presented. The plasmid-encoded drug resistance determinants are located, as are regions encoding the origin of replication, incompatibility functions, copy number determinants, and mobility functions. It is demonstrated that NTP16 probably arose from the closely related plasmid NTP1 by the acquisition of a novel kanamycin resistance transposon, Tn4352, followed by deletion of some NTP1 sequences. The incompatibility behavior of NTP16 derivatives indicates a system of control rather more complex than that which operates in ColE1. In addition to the RNA I/primer RNA system, the production of a further trans-acting product is demonstrated and its site of action located. A series of derivative plasmids have been created which may prove useful as vectors for genetic engineering.

Phage T1-mediated transduction of a plasmid containing the T1 pac site

The T1 pac site has been cloned into a plasmid vector. This recombinant plasmid was tested for T1-mediated transduction efficiency in comparison with a plasmid containing the phage lambda T1-pac-like site esp-lambda, plasmids containing T1 sequences other than the pac site, and plasmids containing neither T1 sequences nor known pac sites. The data obtained indicate that there are at least two distinct mechanisms of T1-mediated plasmid transduction. One requires the presence of any T1 sequence on the plasmid and probably takes place via cointegrate formation with the homologous region of an infecting T1 genome. The other is specifically dependent on the presence of a pac site on the plasmid. Plasmids are packaged as head-to-tail multimers that have one heterogeneous molecular end and the other terminated at pac, and the direction of packaging with respect to the pac site is the same for plasmids as for T1. Possible roles of pac in plasmid packaging and their implications with regard to the packaging of phage DNA are discussed.

Cloning the DdeI restriction-modification system using a two-step method

DdeI, a Type II restriction-modification system from the gram-negative anaerobic bacterium Desulfovibrio desulfuricans, recognizes the sequence CTNAG. The system has been cloned into E. coli in two steps. First the methylase gene was cloned into pBR322 and a derivative expressing higher levels was constructed. Then the endonuclease gene was located by Southern blot analyses; BamHI fragments large enough to contain the gene were cloned into pACYC184, introduced into a host containing the methylase gene, and screened for endonuclease activity. Both genes are stably maintained in E. coli on separate but compatible plasmids. The DdeI methylase is shown to be a cytosine methylase. DdeI methylase clones decrease in viability as methylation activity increases in E. coli RR1 (our original cloning strain). Therefore the DdeI system has been cloned and maintained in ER1467, a new E. coli cloning strain engineered to accept cytosine methylases. Finally, it has been demonstrated that a very high level of methylation was necessary in the DdeI system for successful introduction of the active endonuclease gene into E. coli.

Characterization of a plasmid-specified pathway for catabolism of isopropylbenzene in Pseudomonas putida RE204

A Pseudomonas putida strain designated RE204, able to utilize isopropylbenzene as the sole carbon and energy source, was isolated. Tn5 transposon mutagenesis by means of the suicide transposon donor plasmid pLG221 yielded mutant derivatives defective in isopropylbenzene metabolism. These were characterized by the identification of the products which they accumulated when grown in the presence of isopropylbenzene and by the assay of enzyme activities in cell extracts. Based on the results obtained, the following metabolic pathway is proposed: isopropylbenzene----2,3-dihydro -2,3-dihydroxyisopropylbenzene----3-isopropylcatechol----2 -hydroxy-6-oxo-7-methylocta-2,4-dienoate----isobutyrate + 2-oxopent-4-enoate----amphibolic intermediates. Plasmid DNA was isolated from strain RE204 and mutant derivatives and characterized by restriction enzyme cleavage analysis. Isopropylbenzene-negative isolates carried a Tn5 insert within a 15-kilobase region of a 105-kilobase plasmid designated pRE4. DNA fragments of pRE4 carrying genes encoding isopropylbenzene catabolic enzymes were cloned in Escherichia coli with various plasmid vectors; clones were identified by (i) selection for Tn5-encoded kanamycin resistance in the case of Tn5 mutant plasmids, (ii) screening for isopropylbenzene dioxygenase-catalyzed oxidation of indole to indigo, and (iii) use of a Tn5-carrying restriction fragment, derived from a pRE4::Tn5 mutant plasmid, as a probe for clones carrying wild-type restriction fragments. These clones were subsequently used to generate a transposon insertion and restriction enzyme cleavage map of the isopropylbenzene metabolic region of pRE4.