Detection and characterization of natural transformation in the marine bacterium Pseudomonas stutzeri strain ZoBell

Soil isolates of Pseudomonas stutzeri have been shown previously to acquire genes by natural transformation. In this study a marine isolate, Pseudomonas stutzeri strain ZoBell, formerly Pseudomonas perfectomarina, was also shown to transform naturally. Transformation was detected by the Juni plate method and frequencies of transformation were determined by filter transformation procedures. Maximum frequencies of transformation were detected for three independent antibiotic resistance loci. Transformation frequencies were on the order of 4×10^-5 transformants per recipient, a frequency over 100 times that of spontancous antibiotic resistance. Transfer of antibiotic resistance was inhibited by DNase I digestion. Marine isolates achieved maximum competence 14 h after transfer of exponential cultures to filters on solid media, although lower levels of competence were detected immediately following filter immobilization. Like soil isolates, P. stutzeri strain ZoBell is capable of cell contact transformation, but unlike soil isolates where transformation frequencies are greater for cell contact transformation as compared to transformation with purified DNA, the maximum frequency of transformation achieved by cell contact in the marine strain was approximately 10-fold less than transformation frequencies with purified DNA. These studies establish the first marine model for the study of natural transformation.This paper is dedicated to John L. Ingraham, Professor Emeritus of Microbiology at the University of California, Davis. Professor Ingraham was the first person to recognize natural transformation in Pseudomonas stutzeri and has continued to contribute to our understanding of the process over the past eight years. This understanding of the genetics of P. stutzeri is only one of the many areas of microbiology to which Professor Ingraham has contributed in his exceptional career     

Exchange of chromosomal markers by natural transformation between the soil isolate,Pseudomonas stutzeri JM300, and the marine isolate,Pseudomonas stutzeri strain ZoBell

Both the soil isolate,Pseudomonas stutzeri JM300, and the marine isolate,Pseudomonas stutzeri strain ZoBell, have been shown previously to be naturally transformable. This study reports the detection of genetic exchange by natural transformation between these two isolates. Transformation frequency was determined by filter transformation procedures. Three independent antibiotic resistance loci were used as chromosomal markers to monitor this exchange event: resistance to rifampicin, streptomycin, and nalidixic acid. The maximum frequencies of transformation were on the order of 3.1 to 3.8×10^-6 transformants per recipient; frequencies over an order of magnitude greater than those for spontaneous antibiotic resistance, although they are lower than those observed for soil: soil or marine: marine strain crosses. This exchange was inhibited by DNase I. Transformation was observed between soil and marine strains, both by filter transformation using purified DNA solutions and when transforming DNA was added in the form of viable donor cells. The results from this study support the close genetic relationship betweenP. stutzeri JM300 andP. stutzeri strain ZoBell. These results also further validate the utility ofP. stutzeri as a benchmark organism for modeling gene transfer by natural transformation in both soil and marine habitats.     

Natural transformation of Pseudomonas stutzeri by plasmids that contain cloned fragments of chromosomal deoxyribonucleic acid

Natural transformation of plasmids by Pseudomonas stutzeri was found to depend on their bearing inserts of chromosomal DNA. A set of plasmids derived from the nonconjugative broad host range plasmid pSa151 was constructed by integrating various chromosomal DNA fragments into the single EcoR1 site of pSa151. Selection for the kanamycin resistance determined by pSa151 demonstrated that the derivative plasmids were taken into the cells by natural transformation and stably maintained; each could be reisolated unchanged. Thirty-two different derivative plasmids, 14 to 31 kbase pairs in size, all transformed. The frequency of transformation increased with the size of the chromosomal insert over a twenty fold range. These results suggest that the mechanism of transformation of plasmids by the Gram-negative P. stutzeri is similar to those proposed to operate in Gram-positive bacteria.Dedicated to Prof. Dr. H.-G. Schlegel on the occasion of his 60 th birthday     

Natural Transformation of Acinetobacter calcoaceticus by Plasmid DNA Adsorbed on Sand and Groundwater Aquifer Material

It is known that plasmid DNA and linear duplex DNA molecules adsorb to chemically purified mineral grains of sand and to particles of several clay fractions. It seemed desirable to examine whether plasmid DNA would also adsorb to nonpurified mineral materials taken from the environment and, particularly, whether adsorbed plasmid DNA would be available for natural transformation of bacteria. Therefore, microcosms consisting of chemically pure sea sand plus buffered CaCl₂ solution were compared with microcosms consisting of material sampled directly from a groundwater aquifer (GWA) plus groundwater (GW) with respect to the natural transformation of Acinetobacter calcoaceticus by mineral-associated DNA. The GWA minerals were mostly sand with inorganic precipitates and organic material plus minor quantities of silt and clay (illite and kaolinite). The amount of plasmid DNA which adsorbed to GWA (in GW) was about 80% of the amount which adsorbed to purified sand (in buffered CaCl₂ solution). Plasmid DNA adsorbed on sand transformed A. calcoaceticus significantly less efficiently than did plasmid DNA in solution. In contrast, the transformation by sand-adsorbed chromosomal DNA was as high as that by DNA in solution. In GWA/GW microcosms, the efficiency of transformation by chromosomal DNA was similar to that in sand microcosms, whereas plasmid transformation was not detectable. However, plasmid transformants were found at a low frequency when GWA was loaded with both chromosomal and plasmid DNA. Reasons for the low transformation efficiency of plasmid DNA adsorbed to mineral surfaces are discussed. Control experiments showed that the amounts of plasmid and chromosomal DNA desorbing from sand during incubation with a cell-free filtrate of a competent cell suspension did not greatly contribute to transformation in sand microcosms, suggesting that transformation occurred by direct uptake of DNA from the mineral surfaces. Taken together, the observations suggest that plasmid DNA and chromosomal DNA fragments which are adsorbed on mineral surfaces in a sedimentary or soil habitat may be available (although with different efficiencies for the two DNA species) for transformation of a naturally competent gram-negative soil bacterium.     

Development of real time PCR assays for detection and quantification of transgene DNA of a <Emphasis Type="Italic">Bacillus thuringiensis</Emphasis> (Bt) corn hybrid in soil samples

Real time PCR assays were developed to detect and quantify the transgene DNA of a commercially released Bacillus thuringiensis (Bt) corn (Zea mays L.) hybrid (DKC42-23), which was derived from the event MON863 and also carried a neomycin phosphotransferase gene (the nptII gene). We applied the real time PCR assays to investigate the persistence of the transgene DNA in a field trial grown with DKC42-23 over 3 years, in combination with bacterial natural transformation. The results showed that under continuous cultivation of DKC42-23, its transgene DNA was detectable in the field plots all year around. Meanwhile, when soil DNA extracts from DKC42-23 plots were used as donor in bacterial natural transformation, successful recovery of kanamycin resistant (Km^R) transformants indicated that the nptII gene carried by DKC42-23 could be taken up and integrated into naturally competent Pseudomonas stutzeri pMR7 cells, leading to the restoration of the antibiotic resistance of P. stutzeri pMR7. However, after the cultivation of a soybean line in the same plots for the subsequent growing season, the presence of transgene DNA of DKC42-23 was reduced to undetectable levels at the end of that growing season. Therefore, existing corn-soybean crop rotation practices reduce the availability of transgene DNA in soil and thus minimize the risks that might be attributable to horizontal gene transfer. The real time PCR assays are useful for investigating the persistence of transgene DNA derived from the MON863 event in soil environments.     

High Frequency of Natural Genetic Transformation of Pseudomonas stutzeri in Soil Extract Supplemented with a Carbon/Energy and Phosphorus Source

Agar medium (SME) prepared from aqueous soil extract was used to examine genetic transformation of Pseudomonas stutzeri JM302 (his-1) by homologous his⁺ DNA in a plate transformation assay. Growth studies indicated that SME was strongly limited in carbon and nitrogen sources. Transformation was observed on SME supplemented with pyruvate, phosphate, and ammonium. A 25-fold increase of the transformation frequency was obtained with nitrogen limitation when SME was supplemented with only pyruvate plus phosphate. Similar results were obtained with artificial soil extract medium prepared on the basis of the chemical analysis of the soil extract. On a standard minimal medium, transformation frequencies also increased (10- to 60-fold) when ammonium, phosphate, or pyruvate was growth limiting. Limitation of two or three nutrients did not stimulate transformation. The size of the inoculum (2 × 10³ to 2 × 10⁷ cells) was irrelevant to the enhanced transformation under nitrogen limitation on SME or standard minimal medium. We further show that P. stutzeri can use a variety of carbon and energy sources for competence development. It is concluded that genetic transformation of P. stutzeri is possible in the chemical environment of soil upon supply of nutrients and may be strongly stimulated by a growth-limiting concentration of single nutrients including sources of C, N, or P.     

Plasmid transformation of naturally competent Acinetobacter calcoaceticus in non-sterile soil extract and groundwater

The natural transformation of Acinetobacter calcoaceticus BD413 (trp E27) was characterized with respect to features that might be important for a possible gene transfer by extracellular DNA in natural environments. Transformation of competent cells with chromosomal DNA (marker trp ⁺) occurred in aqueous solutions of single divalent cations. Uptake of DNA into the DNase I-resistant state but not the binding of DNA to cells was strongly stimulated by divalent cations. An increase of transformation of nearly 3 orders of magnitude was obtained as a response to the presence of 0.25 mM Ca²⁺. With CaCl₂ solutions the transformation frequencies approached the highest values obtained under standard broth conditions, followed by MnCl₂ and MgCl₂. It is concluded that transformation requires divalent cations. DNA competition experiments showed that A. calcoaceticus does not discriminate between homologous and heterologous DNA. Furthermore, circular plasmid DNA competed with chromosomal DNA fragments and vice versa. The equally efficient transformation with plasmid pKT210 isolated from A. calcoaceticus or Escherichia coli indicated absence of DNA restriction in transformation. High efficiency plasmid transformation was obtained in samples of non-sterile natural groundwater and in non-sterile extracts of fresh and air-dried soil. Heat-treatment (10 min, 80°C) of the non-sterile liquid samples increased transformation only in the dried soil extract, probably by inactivation of DNases. The results presented suggest that competent cells of A. calcoaceticus can take up free high molecular weight DNA including plasmids of any source in natural environments such as soil, sediment or groundwater.     

Evaluation of possible horizontal gene transfer from transgenic plants to the soil bacterium Acinetobacter calcoaceticus BD413

 The use of genetically engineered crop plants has raised concerns about the transfer of their engineered DNA to indigenous microbes in soil. We have evaluated possible horizontal gene transfer from transgenic plants by natural transformation to the soil bacterium Acinetobacter calcoaceticus BD413. The transformation frequencies with DNA from two sources of transgenic plant DNA and different forms of plasmid DNA with an inserted kanamycin resistance gene, nptII, were measured. Clear effects of homology were seen on transformation frequencies, and no transformants were ever detected after using transgenic plant DNA. This implied a transformation frequency of less than 10^-13 (transformants per recipient) under optimised conditions, which is expected to drop even further to a minimum of 10^-16 due to soil conditions and a lowered concentration of DNA available to cells. Previous studies have shown that chromosomal DNA released to soil is only available to A. calcoaceticus for limited period of time and that A. calcoaceticus does not maintain detectable competence in soil. Taken together, these results suggest that A. calcoaceticus does not take up non-homologous plant DNA at appreciable frequencies under natural conditions. Received: 1 November 1996 / Accepted: 18 April 1997     

Spontaneous Transformation and Its Use for Genetic Mapping in Bacillus subtilis

Using a simple semi-synthetic competence and sporulation medium (CSM), we found evidence that Bacillus subtilis cells transformed in the competence phase can sporulate, indicating that genetic information acquired during the competence phase is inherited by the next generation after germination of the transformed spores. Moreover, the results from mixed cell culture experiments suggest that spontaneous genetic transformation can occur between competent cells and DNA released from lysed cells in the natural environment. We also found evidence that the spontaneous transformation system can be used for genetic mapping in B. subtilis.     

An efficient transformation method for <Emphasis Type="Italic">Bacillus subtilis</Emphasis> DB104

Bacillus subtilis strains are used for extracellular expression of enzymes (i.e., proteases, lipases, and cellulases) which are often engineered by directed evolution for industrial applications. B. subtilis DB104 represents an attractive directed evolution host since it has a low proteolytic activity and efficient secretion. B. subtilis DB104 is hampered like many other Bacillus strains by insufficient transformation efficiencies (≤10³ transformants/μg DNA). After investigating five physical and chemical transformation protocols, a novel natural competent transformation protocol was established for B. subtilis DB104 by optimizing growth conditions and histidine concentration during competence development, implementing an additional incubation step in the competence development phase and a recovery step during the transformation procedure. In addition, the influence of the amount and size of the transformed plasmid DNA on transformation efficiency was investigated. The natural competence protocol is “easy” in handling and allows for the first time to generate large libraries (1.5 × 10⁵ transformants/μg plasmid DNA) in B. subtilis DB104 without requiring microgram amounts of DNA.     

Reductive transformation of parathion and methyl parathion by Bacillus sp.

Based on the results of phenotypic features, phylogenetic similarity of 16S rRNA gene sequences and BIOLOG test, a soil bacterium was identified as Bacillus sp. DM-1. Using either growing cells or a cell-free extract, it transformed parathion and methyl parathion to amino derivatives by reducing the nitro group. Pesticide transformation by a cell-free extract was specifically inhibited by three nitroreductase inhibitors, indicating the presence of nitroreductase activity. The nitroreductase activity was NAD(P)H-dependent, O₂-insensitive, and exhibited the substrate specificity for parathion and methyl parathion. Reductive transformation significantly decreased the toxicity of pesticides.     

Biological denitrification by <Emphasis Type="Italic">Pseudomonas stutzeri</Emphasis> immobilized on microbial cellulose

This study demonstrated the feasibility of a biological denitrification process using immobilized Pseudomonas stutzeri. The microbial cellulose (MC) from Acetobacter xylinum was used as the support material for immobilization of the bacterium. Nitrate removal took place mainly in the anoxic system. The effects of various operating conditions such as the initial nitrate concentration, pH, and carbon source on biological denitrification were demonstrated experimentally. The system demonstrated a high capacity for reducing nitrate concentrations under optimum conditions. The denitrification rate increased up to a maximal value of 1.6 kg NO₃-N m⁻³ day⁻¹ with increasing nitrate loading rate. Because of its porosity and purity, MC may be considered as appropriate supports for adsorbed immobilized cells. The simplicity of immobilization and high efficiency in operation are the main advantages of such systems. To date, the immobilization of microorganisms onto MC has not been carried out. The results of this research shows that a pilot bioreactor containing P. stutzeri immobilized on MC exhibited efficient denitrification with a relatively low retention time.     

Investigation of horizontal gene transfer potential from Bt176 maize to phytopathogenic bacterium Erwinia stewartii 1082

To analyse the frequency of natural gene transfer from genetically modified maize to phytopathogenic bacterium Erwinia stewartii 1082, a marker rescue system based on the restoration of ampicillin resistance gene was used in in vitro and in planta transformation experiments. A set of three vectors containing defined deletions of the blaTEM116 ampicillin resistance gene in pBR322 was constructed. Recombinant strains of Erw. stewartii 1082 harboring these mutant plasmids were used for infection of transgenic maize plants. Restoration of ampicillin resistance was observed only in transformed electro-competent Erw. stewartii 1082 cells. Frequency of the resistance restoration was found to be dependent on the size of the transforming DNA. In addition, highly active non-specific endodeoxyribonuclease was detected in cell-free lysates of Erw. stewartii 1082, rapidly degrading linear DNA fragments. No ampicillin resistant Erw. stewartii 1082 transformants were observed during in planta experiments indicating that this pathogenic bacterium is not naturally transformable under the conditions tested in this study.     

Enhancing electro-transformation competency of recalcitrant Bacillus amyloliquefaciens by combining cell-wall weakening and cell-membrane fluidity disturbing

Bacillus amyloliquefaciens has been a major workhorse for the production of a variety of commercially important enzymes and metabolites for the past decades. Some subspecies of this bacterium are recalcitrant to exogenous DNA, and transformation with plasmid DNA is usually less efficient, thereby limiting the genetic manipulation of the recalcitrant species. In this work, a methodology based on electro-transformation has been developed, in which the cells were grown in a semicomplex hypertonic medium, cell walls were weakened by adding glycine (Gly) and dl-threonine (dl-Thr), and the cell-membrane fluidity was elevated by supplementing Tween 80. After optimization of the cell-loosening recipe by response surface methodology (RSM), the transformation efficiency reached 1.13 ± 0.34 × 10⁷ cfu/μg syngeneic pUB110 DNA in a low conductivity electroporation buffer. Moreover, by temporary heat inactivation of the host restriction enzyme, a transformation efficiency of 8.94 ± 0.77 × 10⁵ cfu/μg DNA was achieved with xenogeneic shuttle plasmids, a 10³-fold increase compared to that reported previously. The optimized protocol was also applicable to other recalcitrant B. amyloliquefaciens strains used in this study. This work could shed light on the functional genomics and subsequent strain improvement of the recalcitrant Bacillus, which are difficult to be transformed using conventional methods.     

Release of transforming plasmid and chromosomal DNA from two cultured soil bacteria

The release of chromosomal and plasmid DNA from Acinetobacter calcoaceticus and Bacillus subtilis cultivated in minimal medium and broth over a period of 50 h was monitored and related to growth phase, autolysis, DNase production and natural competence. The released DNAs were biologically active in natural transformation. In addition, the circular integrity of a released B. subtilis shuttle vector (pHV14) was demonstrated by artificial transformation of Escherichia coli. In cultures of both strains high molecular weight DNA accumulated, particularly during the stationary and death phase (up to 30 g ml^-1). Generally, despite the presence in culture fluids of DNase activity (and of an intracellular enzyme, catalase, indicating some cell lysis) there was high transforming activity of chromsomal and plasmid DNA even 40 h after the cultures reached the stationary phase. In cultures of B. subtilis in minimal medium a presumably active release of intact plasmids and chromsomal DNA occurred during the competence phase. The release of biologically functional DNA during essentially all growth phases of a gram-positive and a gram-negative member of soil bacteria might facilitate horizontal gene transfer by transformation in natural habitats.     

Silver,copper, lead and zinc accumulation byPseudomonas stutzeri AG259 andStreptomyces albus : electron microscopy and energy dispersive X-ray studies

Metal accumulation by a silver-resistant Pseudomonas stutzeri AG259 strain and a Streptomyces albus strain was investigated in a mixed metal solution of silver, copper, lead and zinc. The location of silver, lead and copper on cells was determined by transmission electron microscopy coupled with an X-ray analysis system. In P. stutzeri cells silver was detected as dense deposits on the cells. Copper and lead were distributed over the cells. S. albus accumulated these metals only on part of cells with a higher concentration per cell than in P. stutzeri.     

Pseudomonas stutzeri YPL-1 Genetic Transformation and Antifungal Mechanism against Fusarium solani, an Agent of Plant Root Rot

An actively antagonistic bacterium that could be used as a biocontrol agent against Fusarium solani, which causes root rots with considerable losses in many important crops, was isolated from a ginseng rhizosphere and identified as a strain of Pseudomonas stutzeri. In several biochemical tests with culture filtrates of P. stutzeri YPL-1 and in mutational analyses of antifungal activities of reinforced or defective mutants, we found that the anti-F. solani mechanism of the bacterium may involve a lytic enzyme rather than a toxic substance or antibiotic. P. stutzeri YPL-1 produced extracellular chitinase and laminarinase when grown on different polymers such as chitin, laminarin, or F. solani mycelium. These lytic extracellular enzymes markedly inhibited mycelial growth rather than spore germination and also caused lysis of F. solani mycelia and germ tubes. Scanning electron microscopy revealed degradation of the F. solani mycelium. Abnormal hyphal swelling and retreating were caused by the lysing agents from P. stutzeri YPL-1, and a penetration hole was formed on the hyphae in the region of interaction with the bacterium; the walls of this region were rapidly lysed, causing leakage of protoplasm. Genetically bred P. stutzeri YPL-1 was obtained by transformation of the bacterium with a broad-host-range vector, pKT230. Also, the best conditions for the transformation were investigated.     

A new isolate of <Emphasis Type="Italic">Pseudomonas stutzeri</Emphasis>that degrades 2-chloronitrobenzene

A strain of Pseudomonas stutzeri ZWLR2-1 was isolated from soil contaminated with chloronitrobenzenes and identified by 16S rDNA sequencing. This bacterium released chloride and nitrite into the medium when grown on 0.5mm 2-chloronitrobenzene. PCR amplification and DNA sequencing revealed a DNA fragment encoding a polypeptide homologous to the -subunit of ring-hydroxylating dioxygenasesRevisions requested 01 December 2004; Revisions received 9 December 2004     

Genotypic Characterization and Phylogenetic Relations of Pseudomonas sp. (Formerly P. stutzeri) OX1

Pseudomonas sp. OX1, an aromatic compound-degrading bacterium that was tentatively identified by conventional biochemical methods as P. stutzeri, has now been investigated at the molecular level to clarify its taxonomic position. Amplified ribosomal DNA restriction analysis and multiple enzyme restriction fragment length polymorphism (MERFLP) analysis suggested that Pseudomonas sp. OX1 could not be classified as P. stutzeri. Phylogenetic analyses based on 16S rRNA and gyrB genes further confirmed that this strain belongs to the Pseudomonas (sensu stricto) genus, but not to the stutzeri species. The data obtained demonstrated that Pseudomonas sp. OX1 belongs to intrageneric cluster II and is related to the P. fluorescens–P. syringae complex.     

Membrane-bound <Emphasis Type="SmallCaps">l</Emphasis>- and <Emphasis Type="SmallCaps">d</Emphasis>-lactate dehydrogenase activities of a newly isolated <Emphasis Type="Italic">Pseudomonas stutzeri</Emphasis> strain

Pseudomonas stutzeri SDM was newly isolated from soil, and two stereospecific NAD-independent lactate dehydrogenase (iLDH) activities were detected in membrane of the cells cultured in a medium containing dl-lactate as the sole carbon source. Neither enzyme activities was constitutive, but both of them might be induced by either enantiomer of lactate. P. stutzeri SDM preferred to utilize lactate to growth, when both l-lactate and glucose were available, and the consumption of glucose was observed only after lactate had been exhausted. The Michaelis–Menten constant for l-lactate was higher than that for d-lactate. The l-iLDH activity was more stable at 55°C, while the d-iLDH activity was lost. Both enzymes exhibited different solubilization with different detergents and different oxidation rates with different electron acceptors. Combining activity staining and previous proteomic analysis, the results suggest that there are two separate enzymes in P. stutzeri SDM, which play an important role in converting lactate to pyruvate. Ma and Gao contributed equally to this work.