Fertility factors in Pseudomonas putida: selection and properties of high-frequency transfer and chromosome donors.

The octane plasmid (OCT) in Pseudomonas putida strains has been shown to be transferred at low frequency. However, bacteria which had newly received this plasmid showed a transient increase in donor ability. Using Octane+ P. putida as the donor, the transfer of most chromosomal markers was shown to be independent of OCT transfer, whereas the mobilization of the octanoate catabolism genes (octanoic and acetate) was dependent on OCT plasmid transfer. The presence of a fertility factor termed FPo has been postulated to explain these results. Strains carrying only this fertility factor have been obtained from strains carrying both OCT and FPo plasmids. Strains in which the OCT plasmid was transferred at high frequencies have also been isolated, and chromosome mobilization by OCT and FPo has been compared. A different gradient of transmission by OCT and FPo has been observed. It has also been shown that chromosome transfer by OCT was dependent on the bacterial recombination system, whereas the chromosome transfer by FPo was unaffected by the presence of a rec mutation in the donor strain.     

R6K Plasmid Replication: Influence of Chromosomal Genotype in Minicell-Producing Strains of Escherichia coli K-12

Alkaline sucrose velocity sedimentation and cesium chloride-ethidium bromide equilibrium centrifugation have been used to determine the number of copies per chromosomal equivalent of the relaxedly replicating R6K plasmid (a conjugative plasmid conferring ampicillin and streptomycin resistance) in two minicell-producing strains of Escherichia coli K-12. In one strain, the average number of covalently closed circular R6K molecules per chromosomal equivalent is 13 in log-phase and 35 in stationary-phase cells. In the other strain, there is an average of six covalently closed circular R6K molecules per chromosomal equivalent in both log- and stationary-phase cells. Selection from this strain of spontaneously occurring mutants resistant to high concentrations of ampicillin has been accomplished and such mutants show a two- to threefold increase in the number of R6K copies per chromosomal equivalent. Relative to the parental strain, mutants display the following properties: (i) elevated streptomycin resistance, (ii) a 10-fold increase in R6K conjugal transfer, (iii) a 10-fold increase in the amount of R6K plasmid deoxyribonucleic acid segregated into minicells, and (iv) a two- to threefold increase in R6K-specified beta-lactamase. The mutation(s) responsible for the increase in the number of R6K molecules per chromosomal equivalent is located on the bacterial chromosome. No R6K-linked mutations conferring the above phenotypes have been obtained. The mutations are presumed to be in chromosomal genes which play a role in the regulation of R6K replication in this strain.     

Contribution of different segments of the par region to stable maintenance of the broad-host-range plasmid RK2.

A 3.2-kb region of the broad-host-range plasmid RK2 has been shown to encode a highly efficient plasmid maintenance system that functions in a vector-independent manner. This region, designated par, consists of two divergently arranged operons: parCBA and parDE. The 0.7-kb parDE operon promotes plasmid stability by a postsegregational killing mechanism that ensures that plasmid-free daughter cells do not survive after cell division. The 2.3-kb parCBA operon encodes a site-specific resolvase protein (ParA) and its multimer resolution site (res) and two proteins (ParB and ParC) whose functions are as yet unknown. It has been proposed that the parCBA operon encodes a plasmid partitioning system (M. Gerlitz, O. Hrabak, and H. Schwabb, J. Bacteriol. 172:6194-6203, 1990; R. C. Roberts, R. Burioni, and D. R. Helinski, J. Bacteriol. 172:6204-6216, 1990). To further define the role of this region in promoting the stable maintenance of plasmid RK2, the parCBA and parDE operons separately and the intact (parCBA/DE) par region (3.2 kb) were reintroduced into an RK2 plasmid deleted for par and assayed for plasmid stability in two Escherichia coli strains (MC1061K and MV10delta lac). The intact 3.2-kb region provided the highest degree of stability in the two strains tested. The ability of the parCBA or parDE region alone to promote stable maintenance in the E. coli strains was dependent on the particular strain and the growth temperature. Furthermore, the insertion of the ColE1 cer site into the RK2 plasmid deleted for the par region failed to stabilize the plasmid in the MC1061K strain, indicating that the multimer resolution activity encoded by parCBA is not by itself responsible for the stabilization activity observed for this operon. To examine the relative contributions of postsegregational cell killing and a possible partitioning function encoded by the intact 3.2-kb par region, stability assays were carried out with ParD provided in trans by a compatible (R6K) minireplicon to prevent postsegregational killing. In E. coli MV10delta lac, postsegregational killing appeared to be the predominant mechanism for stabilization since the presence of ParD substantially reduced the stability of plasmids carrying either the 3.2- or 0.7-kb region. However, in the case of E. coli MC1061K, the presence of ParD in trans did not result in a significant loss of stabilization by the 3.2-kb region, indicating that the putative partitioning function was largely responsible for RK2 maintenance. To examine the basis for the apparent differences in postsegregational killing between the two E. coli strains, transformation assays were carried out to determine the relative sensitivities of the strains to the ParE toxin protein. Consistent with the relatively small contribution of the postsegregational killing to plasmid stabilization in MC1061K, we found that this strain was substantially more resistant to killing by ParE in comparison to E. coli MV10delta lac. A transfer-deficient mutant of thepar-deleted plasmid was constructed for the stable maintenance studies. This plasmid was found to be lost from E. coli MV10delta lac at a rate three times greater than the rate for the transfer-proficient plasmid, suggesting that conjugation can also play a significant role in the maintenance of plasmid RK2.     

Molecular Structure of an R Factor, Its Component Drug-Resistance Determinants and Transfer Factor

Plasmid DNA from Escherichia coli strains harboring drug resistance either of the infectious or noninfectious kind has been separated by CsCl centrifugation of crude cell lysates in the presence of ethidium bromide and examined by electron microscopy. Plasmid deoxyribonucleic acid (DNA) from an S(+) strain (which has the property of noninfectious streptomycin-sulfonamide resistance) consists of a monomolecular covalently closed circular species of 2.7 mum in contour length (5.6 x 10(6) atomic mass units; amu). DNA from a strain carrying a transfer factor, termed Delta, but no determinant for drug resistance, is a monomolecular covalently closed circular species of 29.3 mum in contour length (61 x 10(6) amu). DNA from either Delta(+)A(+) or Delta(+)S(+) strains, (which are respectively ampicillin or streptomycin-sulfonamide resistant, and can transfer this drug resistance), shows a bimodal distribution of molecules of contour lengths 2.7 mum and 29.3 mum, whereas DNA from a (Delta-T)(+) strain (showing infectious tetracycline resistance) contains only one species of molecule measuring 32.3 mum (67 x 10(6) amu). We conclude that ampicillin resistance is carried by a DNA molecule (the A determinant) of 2.7 mum, and streptomycin-sulfonamide resistance is carried by an independent molecule (the S determinant) of similar size. These molecules are not able to effect their own transfer, but can be transmitted to other cells due to the simultaneous presence of the transfer factor, Delta, which also constitutes an independent molecule, of size 29.3 mum. In general, there appears to be little recombination or integration of the A or S molecules into that of Delta, although a small proportion (5-10%) of recombinant molecules cannot be excluded. In contrast, the third drug-resistance determinant, that for tetracycline resistance (denoted as T), is integrated in the Delta molecule to form the composite structure Delta-T of size 32.3 mum, which determines infectious tetracycline resistance. The Delta(+)A(+) and Delta(+)S(+) strains are defined as harboring plasmid aggregates, and the (Delta-T)(+) strain is defined as carrying a plasmid cointegrate; the properties of all three strains are characteristic of strains harboring R factors. These results are compatible with the previously published genetic data. The number of Delta molecules per cell appears to be equal to the chromosomal number irrespective of growth phase, and this plasmid can thus be defined as stringently regulated in DNA replication. In contrast, S and A exist as multiple copies, probably in at least a 10-fold excess of chromosomal copy number. S and A can thus be defined as relaxed in the regulation of their DNA replication.     

Degradation of Ethylbenzene by Pseudomonas putida Harboring OCT Plasmid

We have investigated the utilization of a variety of alkylbenzenes by P. putida strains and found that a strain harboring the OCT plasmid assimilated ethylbenzene. The linkage between the determinant for the degradation of ethylbenzene (Etb⁺ phenotype) and the OCT plasmid was inferred from conjugation experiments. The growth characteristics of the strains carrying mutations in the alk genes of the OCT plasmid which determine the assimilation of /t-alkanes indicated that alkB, alkA, and alkR should be responsible for the degradation of ethylbenzene. The exposure of ethylbenzene to the P. putida strain harboring the CAM-OCT plasmid resulted in the accumulation of β-phenylethyl alcohol. A possible degradation pathway for ethylbenzene including the terminal oxidation of the alkyl side chain was proposed.     

Genetic heteroduplex analysis of the R6K plasmid]

The results of genetic studies of R6K Tra1- and R6Kdelta[Sm1] mutants of R6K plasmid and those of heteroduplex analysis of DNAs have shown that DNA of this drug-resistant factor contains three loops flanked by the inverted repeats. The latter are designated as IR1, IR2 and IR3 and are of 50, 100 and 120 nucleotides in size respectively. IR1 is inserted into the loop flanked by IR2. Loops with these two repeats are located in major EcoR1 fragment, IR3 having been found in minor EcoRI fragment of the plasmid. The evidence obtained from the analysis of heteroduplex R6K/RSF2124 has shown that the loop with IR1 is corresponding to transposon Tn3. The extent of the deletion deltaSm1 indicates that IR2 may be a part of a transposon bearing the resistance to streptomycin. By comparing present data with those obtaine from the analysis of the RSF1040 factor of DNA replication initiation sites (Grosa et al., 1976), it has been suggested that the loop with IR3 represents a transposon with replicative functions (TnRep). The deletion of the mutant plasmid R6Kdelta[Sm1] (7.2 . 10(6) daltons in size) which affected one of the EcoRI sites not only confers the sensitivity to streptomycin but enhances also the efficiency of conjugational transfer and results in the loss of the R6K ability to bring about integrative suppression and to inhibit the fertility of the plasmids from IncP and IncN groups. The deletion mutant proved to have lost the property of incompatibility with the initial plasmid R6K and with itself.     

Plasmid required for virulence of Agrobacterium tumefaciens.

The irreversible loss of crown gall-inducing ability of Agrobacterium tumefaciens strain C-58 during growth at 37 C is shown to be due to loss of a large plasmid (1.2 X 10-8 daltons). The gene responsible for this high rate of plasmid loss at elevated temperatures seems to be located on the plasmid. In addition, another spontaneous avirulent variant, A. tumefaciens strain IIBNV6 is shown to lack the virulence plasmid which its virulent sibling strain, IIBV7, possesses. Deoxyribonucleic acid reassociation measurements prove that the plasmid is eliminated, not integrated into the chromosome, in both of the avirulent derivatives. Transfer of virulence from donor strain C-58 to avirulent recipient strain A136 results from the transfer of a plasmid, which appears identical to the donor plasmid by deoxyribonucleic acid reassociation measurements. The transfer of virulence in another cross, K27 X A136, was also shown to result from the transfer of a large plasmid. These findings establish unequivocally that the large plasmid determines virulence. Two additional genetic determinants have been located on the virulence plasmid of A. tumefaciens strain C-58: the ability to utilize nopaline and sensitivity to a bacteriocin produced by strain 84. The latter trait can be exploited for selection of avirulent plasmid-free derivatives of strain C-58. The trait of nopaline utilization appears to be on the virulence plasmid also in strains IIBV7 and K27.     

Exploitation of plasmid pMRC01 to direct transfer of mobilizable plasmids into commercial lactococcal starter strains

Genetic analysis of the 60.2-kb lactococcal plasmid pMRC01 revealed a 19.6-kb region which includes putative genes for conjugal transfer of the plasmid and a sequence resembling an origin of transfer (oriT). This oriT-like sequence was amplified and cloned on a 312-bp segment into pCI372, allowing the resultant plasmid, pRH001, to be mobilized at a frequency of 3.4 x 10(-4) transconjugants/donor cell from an MG1363 (recA mutant) host containing pMRC01. All of the resultant chloramphenicol-resistant transconjugants contained both pRH001 and genetic determinants responsible for bacteriocin production and immunity of pMRC01. This result is expected, given that transconjugants lacking the lacticin 3147 immunity determinants (on pMRC01) would be killed by bacteriocin produced by the donor cells. Indeed, incorporation of proteinase K in the mating mixture resulted in the isolation of transformants, of which 47% were bacteriocin deficient. Using such an approach, the oriT-containing fragment was exploited to mobilize pRH001 alone to a number of lactococcal hosts. These results demonstrate that oriT of pMRC01 has the potential to be used in the development of mobilizable food-grade vectors for the genetic enhancement of lactococcal starter strains, some of which may be difficult to transform.     

Enterococcus faecalis PrgJ, a VirB4-like ATPase, mediates pCF10 conjugative transfer through substrate binding

The Enterococcus faecalis prg and pcf genes of plasmid pCF10 encode a type IV secretion system (T4SS) required for conjugative transfer. PrgJ is a member of the VirB4 family of ATPases that are universally associated with T4SSs. Here, we report that purified PrgJ dimers displayed ATP binding and hydrolysis activities. A PrgJ nucleoside triphosphate (NTP) binding site mutation (K471E) slightly diminished ATP binding but abolished ATP hydrolysis in vitro and blocked pCF10 transfer in vivo. As shown with affinity pulldown assays, PrgJ and the K471E mutant protein interacted with the substrate receptor PcfC and with relaxase PcfG and accessory factor PcfF, which together form the relaxosome at the oriT sequence to initiate plasmid processing. The purified PrgJ and K471E proteins also bound single- and double-stranded DNA substrates without sequence specificity in vitro, and both PrgJ derivatives bound pCF10 in vivo by a mechanism dependent on an intact oriT sequence and cosynthesis of PcfC, PcfF, and PcfG, as shown by a formaldehyde-cross-linking assay. Our findings support a model in which the PcfC receptor coordinates with the PrgJ ATPase to drive early steps of pCF10 processing/transfer: (i) PcfC first binds the pCF10 relaxosome through contacts with PcfF, PcfG, and DNA; (ii) PcfC delivers the plasmid substrate to PrgJ; and (iii) PrgJ catalyzes substrate transfer to the membrane translocase. Substrate engagement with a VirB4-like subunit has not been previously described; consequently, our studies point to a novel function for these signature T4SS ATPases in mediating early steps of type IV secretion.     

Characteristics of Klebsiella pneumoniae plasmid bearing the markers of drug resistance and antilysozyme activity

Electrophoretic study of the profile of plasmid DNA in agarose gel has shown the presence of a plasmid with a molecular weight of 55-60 MD in K. pneumoniae strains possessing antilysozyme activity. Plasmid pAlz60 of K. pneumoniae 22-110, isolated from the blood of a septicemia patient, is a fi- type conjugative plasmid. This plasmid is transferred to recipient strains of different species of enterobacteria with a frequency of 1 X 10(-5) to 1 X 10(-7). Simultaneously with the transfer of the plasmid, recipient cells inherit the antilysozyme markers and resistance to a number of drugs. The discovered plasmid has one restriction site for each of endonucleases EcoRI and XhoI and 16-20 sites for restrictases KpNI, BglII and Hind III.     

Amplification of plasmid (L factor) DNA and increased production of a plasmid gene product (gamma-interferon) in mouse L cells.

It has previously been reported that composite DNAs derived from L factor, a polyoma-related mammalian plasmid, can be established in several mouse cell lines after transfection. Here, we report that the copy number of a plasmid composite DNA consisting of L factor, pBR DNA, dihydrofolate reductase (dhfr) gene, and gamma-interferon (gamma-IFN) gene was increased more than 10-fold after two successive adaptations of the plasmid-bearing mouse L cells to increasing concentrations of methotrexate (MTX), an inhibitor of dhfr. The structure of the amplified L factor plasmid remained intact during prolonged cell culture, but the copy number remained to be amplified only when the selective pressure (presence of MTX in the medium) has been exerted during the culture. Cells bearing the amplified plasmid produced a higher level of gamma-IFN compared with the original clone, which was likely to be derived from the plasmid gamma-IFN gene amplified along with L factor and the dhfr gene.     

Interactions of the origin of replication (oriV) and initiation proteins (TrfA) of plasmid RK2 with submembrane domains of Escherichia coli.

It has been possible to locate a submembrane domain representing less than 10% of the total membrane that appears to be responsible for sequestering some essential components required for plasmid RK2 DNA replication. This subfraction, whose cellular location in the membrane prior to extraction is still unknown, is derived from the inner membrane fraction, since it possesses enzyme marker activity (NADH oxidase) exclusively associated with the inner membrane. The subfraction was detected by a modification of the methods of Ishidate et al. (K. Ishidate, E. S. Kreeger, J. Zrike, S. Deb, B. Glauner, T. MacAlister, and L. I. Rothfield, J. Biol. Chem. 261:428-443, 1986) in which low pressure in a French pressure cell and lysozyme were used to preserve the supercoil plasmid DNA template during cell disruption. This was followed by successive cycles of sucrose gradient sedimentation and flotation density gradient centrifugation to reveal a number of subfractions, including the one of interest. The characteristics of plasmid interaction with the subfraction include the presence of supercoil DNA after extraction, the binding of the origin of plasmid replication (oriV) in vitro, and the association of the two plasmid-encoded initiation (TrfA) proteins (encoded by overlapping genes). However, another peak, the outer membrane fraction, also binds oriV in vitro, contains plasmid DNA in vivo, and associates with the TrfA initiation proteins. Nevertheless, it contains much less of the initiation proteins, and the specific activity of binding oriV is also much reduced compared with the other subfraction. There is a strong correlation between the association of the TrfA initiation proteins with a particular membrane fraction and the binding of oriV in vitro or plasmid DNA in vivo. Since the proteins are known to bind to repeated sequences in oriV (S. Perri, D. R. Helinski, and A. Toukdarian, J. Biol. Chem. 266:12536-1254, 1991; M. Pinkney, R. Diaz, E. Lanka, and C. M. Thomas, J. Mol. Biol. 203: 927-938, 1988), it appears that the initiation proteins themselves could be responsible, at least in part, for the association of plasmid DNA to the membrane.     

Infectivity and complete nucleotide sequence of the genome of a South African isolate of maize streak virus.

The complete infectious genome of a South African isolate of the geminivirus maize streak (MSV-S) has been cloned, characterized, and sequenced. Using an A. tumefaciens Ti plasmid delivery system, the cloned -2.7 kb single circular MSV component was shown to be necessary and sufficient for infection of maize. Based on sequence analysis of the infectious clone, MSV-S is highly homologous to the previously characterized Kenyan and Nigerian isolates. While the genomic organization of MSV-S has elements in common with each of these previously characterized isolates, it is identical to neither and its analysis addresses the discrepancies between them. The result is a somewhat simplified and unified picture of the viral genome, the structural organization of which is essentially identical to that of wheat dwarf virus.     

Identification and mapping of the replication genes of an R factor, R100-1, integrated into the chromosome of Escherichia coli K-12

A stable Hfr strain of Escherichia coli K-12 was obtained by integrative suppression by an R factor, R100-1. The R factor was integrated into the right of 81 min, and chromosome transfer occurred counterclockwise. Mating experiments revealed two linkage groups of genes on the R factor. Drug-resistant transductants of a dnaA-ts recipient from an R-factor Hfr and from an R(+) strain differ in their drug resistance patterns, temperature sensitivity, and transferability of drug resistance as well as chromosome markers. Transductants that transferred chromosome markers were further classified as to the origin and direction of chromosome transfer. For temperature-sensitive transductants, the reversion frequency to temperature resistance was determined, and these revertants were scored for transfer of drug resistance as well as chromosome markers. Two genes responsible for integrative suppression (designated as repA) and the other for autonomous replication (designated as repB) were identified and mapped. The arrangement of genes on the R factor is... (sul, str, cml)... repA... tra... (tet, repB).... The map of the autonomously replicating R factor is probably a circle connecting both sides of this linear map. Thus, a method has been established to map a plasmid that could not finely be analyzed under autonomous state by transduction. It also permits genetic analysis of genes responsible for replication of the plasmid without making use of a conditional mutant of itself but with that of the host, dnaA.     

n-Alkane dissimilation by Rhodopseudomonas sphaeroides transferred OCT plasmid

The OCT plasmid from Pseudomonas maltophilia N246-1 was transferred to Rhodopseudomonas sphaeroides M1 with very low frequency (1.4–1.9 × 10^–5 per recipient cell at pH 7–8 for a 3-hour reaction time). P. maltophilia N246-1 was able to utilize C₈-C₁₄ of n-alkanes, whereas R. gas-liquid chromatography determined that the broad range of carbon numbers of n-alkanes in crude oil was remarkably degraded by the transconjugant, R. sphaeroides M1-C1, compared with donor strain N246-1. The fact that donor and transconjugant strains simultaneously lost the capacity to utilize n-alkanes on L-broth medium suggests that the OCT plasmids are unstable. It was found that the OCT plasmid of P. maltophilia N246 was incompatible with the IncP-2 group of P. aeruginosa KCTC 11245. Offprint requests to: K.-H. Min, Sookmyung Women's University.     

Amplification and purification of exonuclease I from Escherichia coli K12

Employing the recombinant runaway replication plasmid pDPK13 [sbcB+], an exonuclease I-overproducing derivative of Escherichia coli K12 has been constructed. The strain SK4258 has exonuclease I activity 140-400-fold higher than wild type control levels. A new purification procedure has been developed such that the protein can be purified to near homogeneity and is free of endonuclease and RNase activities. The specific activity of the purified enzyme is 10-fold higher than reported previously (Ray, R.K., Reuben, R., Molineux, I., and Gefter, M. (1974) J. Biol. Chem. 249, 5379-5381). Native exonuclease I is a single polypeptide having Mr = 55,000 with a Stokes radius of 3.12 nm.     

Thermal degradation of allicin in garlic extracts and its implication on the inhibition of the in-vitro growth of Helicobacter pylori

Allicin, the main active principle related to Allium sativum chemistry, is considered to be responsible for the bacteriostatic properties of garlic. The work described here has demonstrated the direct implication of the allicin present in solvent-free garlic extracts obtained with ethanol (ethanolic garlic extract, EGE) and acetone (acetonic garlic extract, AGE) in the inhibition of the in-vitro growth of Helicobacter pylori (Hp), the bacterium responsible for serious gastric diseases such as ulcers and even gastric cancer. The evolution of allicin concentration as a function of time and temperature has been the subject of a kinetic study. The reaction order, activation energy, and preexponential factor (in accordance with Arrhenius theory) have been determined for the decomposition process of allicin in these organic media. First-order decomposition, an activation energy of 97.4 kJ/mol, and an Arrhenius preexponential factor of 8.9 x 10(10) s(-1) have been determined for allicin in EGE. For allicin in AGE the kinetic order determined was 1.5, the activation energy 184.5 kJ/mol, and the preexponential factor 3.1 x 10(24) s(-1) (mg/L)(-0.5). The presence or absence of allicin in these garlic products was found to be crucial for the inhibition of the in-vitro growth of Hp, as demonstrated by microbiological analysis for AGE. A relationship has been identified between the effectiveness and durability of the anti-Hp properties shown by AGE and the allicin content of these products. The bacteriostatic properties were active for up to 10 months if the samples were maintained at 6 degrees C.