Gene escape model: transfer of heavy metal resistance genes from Escherichia coli to Alcaligenes eutrophus on agar plates and in soil samples.

Conjugal transfer from Escherichia coli to Alcaligenes eutrophus of the A. eutrophus genes coding for plasmid-borne resistance to cadmium, cobalt, and zinc (czc genes) was investigated on agar plates and in soil samples. This czc fragment is not expressed in the donor strain, E. coli, but it is expressed in the recipient strain, A. eutrophus. Hence, expression of heavy metal resistance by cells plated on a medium containing heavy metals represents escape of the czc genes. The two plasmids into which this DNA fragment has been cloned previously and which were used in these experiments are the nonconjugative, mobilizable plasmid pDN705 and the nonconjugative, nonmobilizable plasmid pMOL149. In plate matings at 28 to 30 degrees C, the direct mobilization of pDN705 occurred at a frequency of 2.4 x 10(-2) per recipient, and the mobilization of the same plasmid by means of the IncP1 conjugative plasmids RP4 or pULB113 (present either in a third cell [triparental cross] or in the recipient strain itself [retromobilization]) occurred at average frequencies of 8 x 10(-4) and 2 x 10(-5) per recipient, respectively. The czc genes cloned into the Tra- Mob- plasmid pMOL149 were transferred at a frequency of 10(-7) to 10(-8) and only by means of plasmid pULB113. The direct mobilization of pDN705 was further investigated in sandy, sandy-loam, and clay soils. In sterile soils, transfer frequencies at 20 degrees C were highest in the sandy-loam soil (10(-5) per recipient) and were enhanced in all soils by the addition of easily metabolizable nutrients.(ABSTRACT TRUNCATED AT 250 WORDS)     

Gene transfer of Alcaligenes eutrophus JMP134 plasmid pJP4 to indigenous soil recipients.

This study evaluated the potential for gene transfer of a large catabolic plasmid from an introduced organism to indigenous soil recipients. The donor organism Alcaligenes eutrophus JMP134 contained the 80-kb plasmid pJP4, which contains genes that code for mercury resistance. Genes on this plasmid plus chromosomal genes also allow degradation of 2,4-dichloruphenoxyacetic acid (2,4-D). When JMP134 was inoculated into a nonsterile soil microcosm amended with 1,000 micrograms of 2,4-D g-1, significant (10(6) g of soil-1) populations of indigenous recipients or transconjugants arose. These transconjugants all contained an 80-kb plasmid similar in size to pJP4, and all degraded 2,4-D. In addition, all transconjugants were resistant to mercury and contained the tfdB gene of pJP4 as detected by PCR. No mercury-resistant, 2,4-D-degrading organisms with large plasmids or the tfdB gene were found in the 2,4-D-amended but uninoculated control microcosm. These data clearly show that the plasmid pJP4 was transferred to indigenous soil recipients. Even more striking is the fact that not only did the indigenous transconjugant population survive and proliferate but also enhanced rates of 2,4-D degradation occurred relative to microcosms in which no such gene transfer occurred. Overall, these data indicate that gene transfer from introduced organisms is an effective means of bioaugmentation and that survival of the introduced organism is not a prerequisite for biodegradation that utilizes introduced biodegradative genes.     

Retromobilization of heavy metal resistance genes in unpolluted and heavy metal polluted soil

Abstract: Retromobilization of the nonconjugative (Tra⁻Mob⁺) IncQ vector, pMOL155, and the non-mobilizable (Tra⁻Mob⁻) vector, pMOL149, by means of the IncP plasmids RP4 and pULB113 (RP4::Mu3A), was studied in plate matings and in soil microcosms, and compared with direct and triparental mobilization. Both vectors harbour the czc genes, originating from Alcaligenes eutrophus , which code for resistance to Co, Zn, and Cd. The donor of the czc genes was Escherichia coli which did not express these genes. The recipient, Alcaligenes eutrophus , expressed the czc genes very well. Retromobilization, direct and triparental mobilization of pMOL155 was observed in sterile soil. Both the addition of nutrients and heavy metals significantly enhanced the number of (retro)transconjugants. Retromobilization was also detected in nutrient amended nonsterile soil, but the presence of the autochthonous soil biota strongly reduced the number of retrotransconjugants and also prevented their increase upon application of heavy metals to the soil. Retromobilization of the czc genes, cloned in pMOL149, by using pULB113 was also observed, yet only in sterile, nutrient amended, heavy metal polluted soil.     

Stability of plasmid DNA of Escherichia coli C600 and Alcaligenes eutrophus CH34 inoculated in desiccating soil

Abstract Molecular methods based on detection of specific DNA sequences are increasingly used to monitor microbial strains and communities in soils. Here, we report that desiccation of soil, a condition that frequently occurs in nature, may contribute considerably to dissimilarity between DNA levels and colony forming units of introduced bacteria. Three types of soil samples were supplemented with Escherichia coli or Alcaligenes eutrophus suspensions and incubated at 30°C in the presence or absence of dehydrating silica gel. Alternatively, seeded soil samples were desiccated by freeze-drying. At regular time points cells and total DNA were extracted and colony forming units and plasmid DNA were determined, respectively. These analyses showed that the decrease of the number of colony forming units was faster in desiccating than in control soil. Both in desiccating and in control soil, plasmid DNA levels were more stable than culturable counts. Long-term incubation experiments showed that in desiccating soil but not in control soil E. coli plasmid DNA remained intact and biologically active for at least 17 days after disappearance of E. coli culturable counts.     

Modeling surface growth of Escherichia coli on agar plates

Surface growth of Escherichia coli cells on a membrane filter placed on a nutrient agar plate under various conditions was studied with a mathematical model. The surface growth of bacterial cells showed a sigmoidal curve with time on a semilogarithmic plot. To describe it, a new logistic model that we presented earlier (H. Fujikawa et al., Food Microbiol. 21:501-509, 2004) was modified. Growth curves at various constant temperatures (10 to 34 degrees C) were successfully described with the modified model (model III). Model III gave better predictions of the rate constant of growth and the lag period than a modified Gompertz model and the Baranyi model. Using the parameter values of model III at the constant temperatures, surface growth at various temperatures was successfully predicted. Surface growth curves at various initial cell numbers were also sigmoidal and converged to the same maximum cell numbers at the stationary phase. Surface growth curves at various nutrient levels were also sigmoidal. The maximum cell number and the rate of growth were lower as the nutrient level decreased. The surface growth curve was the same as that in a liquid, except for the large curvature at the deceleration period. These curves were also well described with model III. The pattern of increase in the ATP content of cells grown on a surface was sigmoidal, similar to that for cell growth. We discovered several characteristics of the surface growth of bacterial cells under various growth conditions and examined the applicability of our model to describe these growth curves.     

Occurrence of deletion plasmids at high rates after conjugative transfer of the plasmids RP4 and RK2 from Escherichia coli to Alcaligenes eutrophus H16

The broad host-range IncP-1 plasmids RP4 and RK2 were transferred by conjugation from Escherichia coli to Alcaligenes eutrophus H16. Among the transconjugants selected on media containing tetracycline, a considerable number did not express kanamycin resistance. By comparing restriction patterns of plasmids isolated from a large number of transconjugants a variety of different deletion derivatives were found. All of these possess more or less extended deletions always including parts of the tra 1-region. The plasmids RP4 and RK2, once established in A. eutrophus H16 showed a high stability and it can be concluded that deletion formation is connected with the conjugation process. Evidence is given that degradation of DNA entering an A. eutrophus recipient cell during the conjugative transfer process may be involved in deletion formation. Furthermore, the finding of a small deletion derivative of RP4 lacking the transacting replication function trfB and the entire kil-kor-system may allow the assumption that these gene functions are not essential for replication and maintenance of RP4 in A. eutrophus hosts.     

Cloning and expression in Escherichia coli of the Alcaligenes eutrophus H16 poly-beta-hydroxybutyrate biosynthetic pathway.

The poly-beta-hydroxybutyrate (PHB) biosynthetic pathway from Alcaligenes eutrophus H16 has been cloned and expressed in Escherichia coli. Initially, an A. eutrophus H16 genomic library was constructed by using cosmid pVK102, and cosmid clones that encoded the PHB biosynthetic pathway were sought by assaying for the first enzyme of the pathway, beta-ketothiolase. Six enzyme-positive clones were identified. Three of these clones manifested acetoacetyl coenzyme A reductase activity, the second enzyme of the biosynthetic pathway, and accumulated PHB. PHB was produced in the cosmid clones at approximately 50% of the level found in A. eutrophus. One cosmid clone was subjected to subcloning experiments, and the PHB biosynthetic pathway was isolated on a 5.2-kilobase KpnI-EcoRI fragment. This fragment, when cloned into small multicopy vectors, can direct the synthesis of PHB in E. coli to levels approaching 80% of the bacterial cell dry weight.     

Cloning of the Alcaligenes eutrophus genes for synthesis of poly-beta-hydroxybutyric acid (PHB) and synthesis of PHB in Escherichia coli.

Eight mutants of Alcaligenes eutrophus defective in the intracellular accumulation of poly-beta-hydroxybutyric acid (PHB) were isolated after transposon Tn5 mutagenesis with the suicide vector pSUP5011. EcoRI fragments which harbor Tn5-mob were isolated from pHC79 cosmid gene banks. One of them, PPT1, was used as a probe to detect the intact 12.5-kilobase-pair EcoRI fragment PP1 in a lambda L47 gene bank of A. eutrophus genomic DNA. In six of these mutants (PSI, API, GPI, GPIV, GPV, and GPVI) the insertion of Tn5-mob was physically mapped within a region of approximately 1.2 kilobase pairs in PP1; in mutant API, cointegration of vector DNA has occurred. In two other mutants (GPII and GPIII), most probably only the insertion element had inserted into PP1. All PHB-negative mutants were completely impaired in the formation of active PHB synthase, which was measured by a radiometric assay. In addition, activities of beta-ketothiolase and of NADPH-dependent acetoacetyl coenzyme A (acetoacetyl-CoA) reductase were diminished, whereas the activity of NADPH-dependent acetoacetyl-CoA reductase was unaffected. In all PHB-negative mutants the ability to accumulate PHB was restored upon complementation in trans with PP1. The PHB-synthetic pathway of A. eutrophus was heterologously expressed in Escherichia coli. Recombinant strains of E. coli JM83 and K-12, which harbor pUC9-1::PP1, pSUP202::PP1, or pVK101::PP1, accumulated PHB up to 30% of the cellular dry weight. Crude extracts of these cells had significant activities of the enzymes PHB synthase, beta-ketothiolase, and NADPH-dependent acetoacetyl-CoA reductase. Therefore, PP1 most probably encodes all three genes of the PHB-synthetic pathway in A. eutrophus. In addition to PHB-negative mutants, we isolated mutants which accumulate PHB at a much lower rate than the wild type does. These PHB-leaky mutants exhibited activities of all three PHB-synthetic enzymes; Tn5-mob had not inserted into PP1, and the phenotype of the wild type could not be restored with fragment PP1. The rationale for this mutant type remains unknown.     

Expression of the Escherichia coli pfkA gene in Alcaligenes eutrophus and in other gram-negative bacteria.

The Escherichia coli pfkA gene has been cloned in the non-self-transmissible vector pVK101 from hybrid plasmids obtained from the Clarke and Carbon clone bank, resulting in the plasmids pAS300 and pAS100; the latter plasmid also encoded the E. coli tpi gene. These plasmids were transferred by conjugation to mutants of Alcaligenes eutrophus which are unable to grow on fructose and gluconate due to lack of 2-keto-3-deoxy-6-phosphogluconate aldolase activity. These transconjugants recovered the ability to grow on fructose and harbored pAS100 or pAS300. After growth on fructose, the transconjugants contained phosphofructokinase at specific activities between 0.73 and 1.83 U/mg of protein, indicating that the E. coli pfkA gene is readily expressed in A. eutrophus and that the utilization of fructose occurs via the Embden-Meyerhof pathway instead of the Entner-Doudoroff pathway. In contrast, transconjugants of the wild type of A. eutrophus, which are potentially able to catabolize fructose via both pathways, grew at a decreased rate on fructose and during growth on fructose did not stably maintain pAS100 or pAS300. Indications for a glycolytic futile cycling of fructose 6-phosphate and fructose 1,6-bisphosphate are discussed. Plasmid pA 100 was also transferred to 14 different species of gram-negative bacteria. The pfkA gene was expressed in most of these species. In addition, most transconjugants of these strains and of A. eutrophus exhibited higher specific activities of triosephosphate isomerase than did the corresponding parent strains.     

Transfer and expression of PCB-degradative genes into heavy metal resistantAlcaligenes eutrophus strains

Sites polluted with organic compounds frequently contain inorganic pollutants such as heavy metals. The latter might inhibit the biodegradation of the organics and impair bioremediation. Chromosomally located polychlorinated biphenyl (PCB) catabolic genes ofAlcaligenes eutrophus A5,Achromobacter sp. LBS1C1 andAlcaligenes denitrificans JB1 were introduced into the heavy metal resistantAlcaligenes eutrophus strain CH34 and related strains by means of natural conjugation. Mobile elements containing the PCB catabolic genes were transferred fromA. eutrophus A5 andAchromobacter sp. LB51C1 intoA. eutrophus CH34 after transposition onto their endogenous IncP plasmids pSS50 and pSS60, respectively. The PCB catabolic genes ofA. denitrificans JB1 were transferred intoA. eutrophus CH34 by means of RP4::Mu3A mediated prime plasmid formation. TheA. eutrophus CH34 transconjugant strains expressed both catabolic and metal resistance markers. Such constructs may be useful for the decontamination of sites polluted by both organics and heavy metals.     

In vivo transfer of genes from Escherichia coli to Bacillus subtilis

Summary Escherichia coli cells, carrying plasmid pRD1 with (a) drug resistance markers from Pseudomonas (km^r, carb^r, tc^r) and (b) the nif-gene group from Klebsiella, were incubated together with Bacillus subtilis cells (str^r), whose cell wall had been disintegrated with lysozyme. Upon plating the cell mixtures onto appropriately supplemented selective medium, multiple drug resistant Bacillus subtilis cells were obtained. Their nature was verified by suitable biochemical tests and checking for the presence of additional genetic markers. The majority of the isolates was unstable. Some however retained multiple drug resistance for longer periods of time, and several produced nitrogenase activity. The data are interpreted as evidence not only for the transfer of the respective genes but also for their expression in the gram-positive recipient cells.Abbreviations pRD1 a hybrid plasmid, renamed by Ray Dixon - pRP4 plasmid from Pseudomonas, originally described by Datta et al., J. Bacteriol 108, 1244 (1971) - km ^r, carb ^r, tc ^r, str ^r resistance against kanamycin, carbenicillin, tetracyclin and streptomycin, respectively - r restriction negative. For other bacterial markers refer to Bachmann, B.J. et al., Bacteriological Reviews 40, 116 (1976)     

Cloning of plasmid genes encoding resistance to cadmium, zinc, and cobalt in Alcaligenes eutrophus CH34.

A 238-kilobase-pair plasmid, pMOL30, confers resistance to cadmium, zinc, and cobalt salts in Alcaligenes eutrophus CH34. After Tn5 mutagenesis, restriction nuclease analysis, and Southern DNA-DNA hybridization, a 9.1-kilobase-pair EcoRI fragment was found to harbor all of these resistance properties and was cloned into the broad-host-range hybrid plasmid pRK290. When transferred to a plasmid-free derivative of CH34, the hybrid plasmid conferred the same degree of resistance as the parent plasmid pMOL30. In two other Alcaligenes strains, the hybrid plasmid was expressed, but to a lower degree than in CH34 derivatives.     

Cloning of pMOL28-encoded nickel resistance genes and expression of the genes in Alcaligenes eutrophus and Pseudomonas spp.

The 163-kilobase-pair (kb) plasmid pMOL28, which determines inducible resistance to nickel, cobalt, chromate, and mercury salts in its native host Alcaligenes eutrophus CH34, was transferred to a derivative of A. eutrophus H16 and subjected to cloning procedures. After Tn5 transposon mutagenesis, restriction endonuclease analysis, and DNA-DNA hybridization, two DNA fragments, a 9.5-kb KpnI fragment and a 13.5-kb HindIII fragment (HKI), were isolated. HKI contained EK1, the KpnI fragment, as a subfragment flanked on both sides by short regions. Both fragments were ligated into the suicide vector pSUP202, the broad-host-range vector pVK101, and pUC19. Both fragments restored a nickel-sensitive Tn5 mutant to full nickel and cobalt resistance. The hybrid plasmid pVK101::HKI expressed full nickel resistance in all nickel-sensitive derivatives, either pMOL28-deficient or -defective, of the native host CH34. The hybrid plasmid pVK101::HKI also conferred nickel and cobalt resistance to A. eutrophus strains H16 and JMP222, Alcaligenes hydrogenophilus, Pseudomonas putida, and Pseudomonas oleovorans, but to a lower level of resistance. In all transconjugants the metal resistances coded by pVK101::HKI were expressed constitutively rather than inducibly. The hybrid plasmid metal resistance was not expressed in Escherichia coli. DNA sequences responsible for nickel resistance in newly isolated strains showed homology to the cloned pMOL28-encoded nickel and cobalt resistance determinant.     

Sequence analysis of the chromosomal and plasmid genes encoding phosphoribulokinase from Alcaligenes eutrophus

Two DNA fragments encoding the chromosomal and plasmid copies of the gene (cfxP) encoding phosphoribulokinase (PRK) from the chemoautotrophic bacterium Alcaligenes eutrophus, were sequenced and found to be highly homologous. The gene (cfxF) of another Calvin cycle enzyme, fructose-1,6-bisphosphatase (FBPase), was identified as terminating immediately upstream of cfxP, but was not completely contained on both fragments. A hypothetical, also incompletely contained, open reading frame starts closely downstream from cfxP. Genes cfxF, cfxP, and the third hypothetical gene seem to belong to the same operon. The cfxP genes encode highly homologous PRK isoenzyme subunits consisting of 292 aa residues with calculated Mrs of 33 319 (chromosomal PRKc) and 33 164 (plasmid-encoded PRKp). There is little overall sequence similarity between the bacterial and plant (spinach) PRK, apart from some structural motifs.     

质粒介导的大肠埃希菌对喹诺酮类抗菌药物耐药机制的研究

目的了解临床分离的耐环丙沙星的大肠埃希菌质粒介导的喹诺酮类耐药基因的携带情况,并进行相关耐药机制的分析。方法采用VITEK-2全自动微生物检测系统鉴定细菌,用K-B法检测细菌对16种常用抗生素的敏感性,采用聚合酶链反应检测喹诺酮类耐药基因qnrS、qnrA、qnrB、qepA和aac（6′）-Ib,并对阳性的aac（6′）-Ib结果进行测序分析。结果 30株耐环丙沙星的大肠埃希菌中,2株（6.67%）检出qepA基因,8株（26.67%）检出aac（6′）-Ib基因,经测序证实其中6株为aac（6）′-Ib-cr（20.0%）。未检出qnrS、qnrA和qnrB基因。结论对环丙沙星耐药的大肠埃希菌携带aac（6′）-Ib-cr和qepA基因,引起质粒介导的对喹诺酮类抗菌药物的低水平耐药。     

Expression of Alcaligenes eutrophus Flavohemoprotein and Engineered Vitreoscilla Hemoglobin-Reductase Fusion Protein for Improved Hypoxic Growth of Escherichia coli

Expression of the vhb gene encoding hemoglobin from Vitreoscilla sp. (VHb) in several organisms has been shown to improve microaerobic cell growth and enhance oxygen-dependent product formation. The amino-terminal hemoglobin domain of the flavohemoprotein (FHP) of the gram-negative hydrogen-oxidizing bacterium Alcaligenes eutrophus has 51% sequence homology with VHb. However, like other flavohemoglobins and unlike VHb, FHP possesses a second (carboxy-terminal) domain with NAD(P)H and flavin adenine dinucleotide (FAD) reductase activities. To examine whether the carboxy-terminal redox-active site of flavohemoproteins can be used to improve the positive effects of VHb in microaerobic Escherichia coli cells, we fused sequences encoding NAD(P)H, FAD, or NAD(P)H-FAD reductase activities of A. eutrophus in frame after the vhb gene. Similarly, the gene for FHP was modified, and expression cassettes encoding amino-terminal hemoglobin (FHPg), FHPg-FAD, FHPg-NAD, or FHP activities were constructed. Biochemically active heme proteins were produced from all of these constructions in Escherichia coli, as indicated by their ability to scavenge carbon monoxide. The presence of FHP or of VHb-FAD-NAD reductase increased the final cell density of transformed wild-type E. coli cells approximately 50 and 75%, respectively, for hypoxic fed-batch culture relative to the control synthesizing VHb. Approximately the same final optical densities were achieved with the E. coli strains expressing FHPg and VHb. The presence of VHb-FAD or FHPg-FAD increased the final cell density slightly relative to the VHb-expressing control under the same cultivation conditions. The expression of VHb-NAD or FHPg-NAD fusion proteins reduced the final cell densities approximately 20% relative to the VHb-expressing control. The VHb-FAD-NAD reductase-expressing strain was also able to synthesize 2.3-fold more recombinant β-lactamase relative to the VHb-expressing control.