Exogenous isolation of antibiotic resistance plasmids from piggery manure slurries reveals a high prevalence and diversity of IncQ-like plasmids

Antibiotic resistance plasmids were exogenously isolated in biparental matings with piggery manure bacteria as plasmid donors in Escherichia coli CV601 and Pseudomonas putida UWC1 recipients. Surprisingly, IncQ-like plasmids were detected by dot blot hybridization with an IncQ oriV probe in several P. putida UWC1 transconjugants. The capture of IncQ-like plasmids in biparental matings indicates not only their high prevalence in manure slurries but also the presence of efficiently mobilizing plasmids. In order to elucidate unusual hybridization data (weak or no hybridization with IncQ repB or IncQ oriT probes) four IncQ-like plasmids (pIE1107, pIE1115, pIE1120, and pIE1130), each representing a different EcoRV restriction pattern, were selected for a more thorough plasmid characterization after transfer into E. coli K-12 strain DH5alpha by transformation. The characterization of the IncQ-like plasmids revealed an astonishingly high diversity with regard to phenotypic and genotypic properties. Four different multiple antibiotic resistance patterns were found to be conferred by the IncQ-like plasmids. The plasmids could be mobilized by the RP4 derivative pTH10 into Acinetobacter sp., Ralstonia eutropha, Agrobacterium tumefaciens, and P. putida, but they showed diverse patterns of stability under nonselective growth conditions in different host backgrounds. Incompatibility testing and PCR analysis clearly revealed at least two different types of IncQ-like plasmids. PCR amplification of total DNA extracted directly from different manure samples and other environments indicated the prevalence of both types of IncQ plasmids in manure, sewage, and farm soil. These findings suggest that IncQ plasmids play an important role in disseminating antibiotic resistance genes.     

Manure Enhances Plasmid Mobilization and Survival of Pseudomonas putida Introduced into Field Soil

We report a field study on plasmid mobilization in an agricultural soil. The influence of pig manure on the mobilization of the IncQ plasmid pIE723 by indigenous plasmids or by the IncP(alpha) plasmid pGP527 into the recipient Pseudomonas putida UWC1 (Rif(supr) Nal(supr)) was studied in field soil. Six plots were prepared in duplicate, three of which were treated with manure prior to inoculation of the donor and recipient strains. As a donor strain, either Escherichia coli J53(pIE723) or E. coli 600(pIE723, pGP527) was used. Putative transconjugants obtained on a selective medium were confirmed by DNA hybridization and PCR. Plasmid mobilization by indigenous mobilizing plasmids was observed on two occasions in manured soil. Manuring of soil significantly enhanced the frequency of pIE723 mobilization by pGP527, since mobilization frequencies into P. putida UWC1 were at least 10-fold higher in manured soil than in nonmanured soil. Enhanced numbers of P. putida UWC1 transconjugant and recipient colonies could be observed in manured soil throughout the 79-day field test. Transfer of pIE723 or pG527 into indigenous soil or rhizosphere bacteria could not be detected when indigenous bacteria isolated by selective cultivation were screened for the presence of these plasmids by DNA hybridization. Furthermore, the presence of IncN-, IncP-, or IncQ-specific sequences was confirmed in total community DNA extracted directly from the manured or nonmanured soil by PCR. IncW plasmids were detectable only in manured soil, indicating entry of these plasmids into soil via manure.     

Nucleotide Sequence and Genetic Characterization of the Novel IncQ-like Plasmid pIE1107

The analysis of the complete nucleotide sequence of the small resistance plasmid pIE1107 revealed a close similarity to the well-known IncQ plasmids. Highly conserved replication proteins and nearly identical origins of replication (oriV) suggest equivalent functions in the related replication systems. However, pIE1107 contains two copies of IncQ-oriV-like DNA which are slightly different regarding the iterons. Upon deletion of a silent copy of IncQ-oriV-like DNA the resulting plasmid is fully compatible with IncQ plasmids, indicating that there is no mutual communication between the replication control of the respective replicons. Experiments with clonedoriV DNA strongly suggest that the replication initiation protein of pIE1107 has specialized into the distinct target-iterons of its ownoriV which differs only by a few nucleotides from theoriV of IncQ plasmids. Implications from the apparent highly specific protein–DNA recognition and from the incompatibility properties of pIE1107 for the evolution of a family of compatible, IncQ-like plasmids are discussed.     

Analysis of the complete nucleotide sequence of an Actinobacillus pleuropneumoniae streptomycin-sulfonamide resistance plasmid, pMS260

pMS260 is an 8.1-kb non-conjugative but mobilizable plasmid that was isolated from Actinobacillus pleuropneumoniae and encodes streptomycin (SM) and sulfonamide (SA) resistances. The analysis of the complete nucleotide sequence of the plasmid revealed a high degree of similarity between pMS260 and the broad-host-range IncQ family plasmids. pMS260 had a single copy of an origin of vegetative replication (oriV). This sequence was identical to a functional oriV of the IncQ-like plasmid pIE1130 that had been exogenously isolated from piggery manure. However, pMS260 did not carry the second IncQ plasmid RSF1010-like oriV region present in pIE1130. A pIE1130-identical transfer origin was also found in pMS260. In addition, the deduced amino acid sequences from 10 open reading frames identified in pMS260 were entirely or nearly identical to those from genes for the replication, mobilization, and SM-SA resistance of pIE1130, indicating that pMS260 belongs to the IncQ-1 gamma subgroup. pMS260 is physically indistinguishable from pIE1130 apart from two DNA regions that contain the chloramphenicol and kanamycin resistance genes (catIII and aphI, respectively) and the second oriV-like region of pIE1130. The codon bias analysis of each gene of pIE1130 and the presence of potential recombination sites in the sulII-strA intergenic regions suggest that pIE1130 seems to have acquired the catIII and aphI genes more recently than the other genes of pIE1130. Therefore, pMS260 may be the ancestor of pIE1130. Information regarding the broad-host-range replicon of pMS260 will be useful in the development of genetic systems for a wide range of bacteria including A. pleuropneumoniae.     

Comparative biology of IncQ and IncQ-like plasmids.

Plasmids belonging to Escherichia coli incompatibility group Q are relatively small (approximately 5 to 15 kb) and able to replicate in a remarkably broad range of bacterial hosts. These include gram-positive bacteria such as Brevibacterium and Mycobacterium and gram-negative bacteria such as Agrobacterium, Desulfovibrio, and cyanobacteria. These plasmids are mobilized by several self-transmissible plasmids into an even more diverse range of organisms including yeasts, plants, and animal cells. IncQ plasmids are thus highly promiscuous. Recently, several IncQ-like plasmids have been isolated from bacteria found in environments as diverse as piggery manure and highly acidic commercial mineral biooxidation plants. These IncQ-like plasmids belong to different incompatibility groups but have similar broad-host-range replicons and mobilization properties to the IncQ plasmids. This review covers the ecology, classification, and evolution of IncQ and IncQ-like plasmids.     

Exogenous Isolation of Mobilizing Plasmids from Polluted Soils and Sludges

Exogenous plasmid isolation was used to assess the presence of mobilizing plasmids in several soils and activated sludges. Triparental matings were performed with Escherichia coli (a member of the γ subgroup of the Proteobacteria) as the donor of an IncQ plasmid (pMOL155, containing the heavy metal resistance genes czc: Co^r, Zn^r, and Cd^r), Alcaligenes eutrophus (a member of the β subgroup of the Proteobacteria) as the recipient, and indigenous microorganisms from soil and sludge samples as helper strains. We developed an assay to assess the plasmid mobilization potential of a soil ecosystem on the basis of the number of transconjugants obtained after exogenous isolations. After inoculation into soil of several concentrations of a helper strain (E. coli CM120 harboring IncP [IncP1] mobilizing plasmid RP4), the log numbers of transconjugants obtained from exogenous isolations with different soil samples were a linear function of the log numbers of helper strain CM120(RP4) present in the soils. Four soils were analyzed for the presence of mobilizing elements, and mobilizing plasmids were isolated from two of these soils. Several sludge samples from different wastewater treatment plants yielded much higher numbers of transconjugants than the soil samples, indicating that higher numbers of mobilizing strains were present. The mobilizing plasmids isolated from Gent-O sludge and one plasmid isolated from Eislingen soil hybridized to the repP probe, whereas the plasmids isolated from Essen soil did not hybridize to a large number of rep probes (repFIC, repHI1, repH12, repL/M, repN, repP, repT, repU, repW, repX). This indicates that in Essen soil, broad-host-range mobilizing plasmids belonging to other incompatibility groups may be present.     

Increased Abundance of IncP-1β Plasmids and Mercury Resistance Genes in Mercury-Polluted River Sediments: First Discovery of IncP-1β Plasmids with a Complex mer Transposon as the Sole Accessory Element

Although it is generally assumed that mobile genetic elements facilitate the adaptation of microbial communities to environmental stresses, environmental data supporting this assumption are rare. In this study, river sediment samples taken from two mercury-polluted (A and B) and two nonpolluted or less-polluted (C and D) areas of the river Nura (Kazakhstan) were analyzed by PCR for the presence and abundance of mercury resistance genes and of broad-host-range plasmids. PCR-based detection revealed that mercury pollution corresponded to an increased abundance of mercury resistance genes and of IncP-1β replicon-specific sequences detected in total community DNA. The isolation of IncP-1β plasmids from contaminated sediments was attempted in order to determine whether they carry mercury resistance genes and thus contribute to an adaptation of bacterial populations to Hg pollution. We failed to detect IncP-1β plasmids in the genomic DNA of the cultured Hg-resistant bacterial isolates. However, without selection for mercury resistance, three different IncP-1β plasmids (pTP6, pTP7, and pTP8) were captured directly from contaminated sediment slurry in Cupriavidus necator JMP228 based on their ability to mobilize the IncQ plasmid pIE723. These plasmids hybridized with the merRTΔP probe and conferred Hg resistance to their host. A broad host range and high stability under conditions of nonselective growth were observed for pTP6 and pTP7. The full sequence of plasmid pTP6 was determined and revealed a backbone almost identical to that of the IncP-1β plasmids R751 and pB8. However, this is the first example of an IncP-1β plasmid which had acquired only a mercury resistance transposon but no antibiotic resistance or biodegradation genes. This transposon carries a rather complex set of mer genes and is inserted between Tra1 and Tra2.     

Comparative Biology of Two Natural Variants of the IncQ-2 Family Plasmids,pRAS3.1 and pRAS3.2

Plasmids pRAS3.1 and pRAS3.2 are two closely related, natural variants of the IncQ-2 plasmid family that have identical plasmid backbones except for two differences. Plasmid pRAS3.1 has five 6-bp repeat sequences in the promoter region of the mobB gene and four 22-bp iterons in its oriV region, whereas pRAS3.2 has only four 6-bp repeats and three 22-bp iterons. Plasmid pRAS3.1 was found to have a higher copy number than pRAS3.2, and we show that the extra 6-bp repeat results in an increase in mobB and downstream mobA/repB expression. Placement of repB (primase) behind an arabinose-inducible promoter in trans resulted in an increase in repB expression and an approximately twofold increase in the copy number of plasmids with identical numbers of 22-bp iterons. The pRAS3 plasmids were shown to have a previously unrecognized toxin-antitoxin plasmid stability module within their replicons. The ability of the pRAS3 plasmids to mobilize the oriT regions of two other plasmids of the IncQ-2 family, pTF-FC2 and pTC-F14, suggested that the mobilization proteins pRAS3 are relaxed and can mobilize oriT regions with substantially different sequences. Plasmids pRAS3.1 and pRAS3.2 were highly incompatible with plasmids pTF-FC2 and pTC-F14, and this incompatibility was removed on inactivation of an open reading frame situated downstream of the mobCDE mobilization genes rather than being due to the 22-bp oriV-associated iterons. We propose that the pRAS3 plasmids represent a third, γ incompatibility group within the IncQ-2 family plasmids.Plasmids of the IncQ family are small (<20 kb), have a broad host range, and are highly promiscuous due to their ability to be mobilized very efficiently by self-transmissible plasmids such as the IncP plasmids. They have been divided into two families, IncQ-1 and IncQ-2, based on the amino acid sequence relatedness of their RepA (helicase), RepB (primase), and RepC (DNA-binding) replication proteins and because the mobilization proteins of the two families are unrelated, consisting of three or five genes, respectively (31). IncQ-1 group plasmids include RSF1010 and the near-identical R1162, pDN1, pIE1107, pIE1115, and pIE1130, while IncQ-2 plasmids include pTF-FC2, pTC-F14, and pRAS3.IncQ-2 plasmids pRAS3.1 and pRAS3.2 were isolated in Norway from the fish pathogens Aeromonas salmonicida subsp. salmonicida and atypical A. salmonicida, respectively, while investigating plasmids that conferred resistance to tetracycline (21). The two plasmids encode identical replication and mobilization proteins, with the most important differences in the plasmid backbone being that pRAS3.1 has four 22-bp iterons in its oriV region and five 6-bp repeat sequences upstream of its mobB gene, whereas pRAS3.2 has only three iterons and four 6-bp repeat sequences. No biological studies were carried out in the initial report of the pRAS3 plasmids. As a contribution to our studies on the evolution of IncQ plasmids, our longer-term aim is to address the question of why two natural versions of the plasmid exist. Here we report on the major differences in the biology of the two plasmids. In addition, we discovered the presence of repC and mobB genes that were not detected when the sequence of pRAS3 plasmids was previously reported. We also discovered a putative toxin-antitoxin (TA) postsegregational system different from that found in other members of the IncQ plasmids and tested it for functionality.The IncQ-1 plasmids are subdivided into incompatibility groups α, β, and γ, (31), whereas the IncQ-2 plasmids are subdivided into two incompatibility groups, α and β (14). In this work we also report on the incompatibility between the pRAS3 plasmids and other members of the IncQ-2 plasmid family as well as the IncQ-1 family plasmids. Furthermore, we compare the functional relatedness of the pRAS3 mobilization system with that of previously studied IncQ-2 plasmids.     

Isolation of a new broad-host-range IncQ-like plasmid, pTC-F14, from the acidophilic bacterium Acidithiobacillus caldus and analysis of the plasmid replicon

A moderately thermophilic (45 to 50 degrees C), highly acidophilic (pH 1.5 to 2.5), chemolithotrophic Acidithiobacillus caldus strain, f, was isolated from a biooxidation process used to treat nickel ore. Trans-alternating field electrophoresis analysis of total DNA from the A. caldus cells revealed two plasmids of approximately 14 and 45 kb. The 14-kb plasmid, designated pTC-F14, was cloned and shown by replacement of the cloning vector with a kanamycin resistance gene to be capable of autonomous replication in Escherichia coli. Autonomous replication was also demonstrated in Pseudomonas putida and Agrobacterium tumefaciens LBA 4404, which suggested that pTC-F14 is a broad-host-range plasmid. Sequence analysis of the pTC-F14 replicon region revealed five open reading frames and a replicon organization like that of the broad-host-range IncQ plasmids. Three of the open reading frames encoded replication proteins which were most closely related to those of IncQ-like plasmid pTF-FC2 (amino acid sequence identities: RepA, 81%; RepB, 78%; RepC, 74%). However, the two plasmids were fully compatible and pTC-F14 represents a new IncQ-like plasmid replicon. Surprisingly, asymmetrical incompatibility was found with the less closely related IncQ plasmid R300B derivative pKE462 and the IncQ-like plasmid derivative pIE1108. Analysis of the pTC-F14 oriV region revealed five direct repeats consisting of three perfectly conserved 22-bp iterons flanked by iterons of 23 and 21 bp. Plasmid pTC-F14 had a copy number of 12 to 16 copies per chromosome in both E. coli, and A. caldus. The rep gene products of pTC-F14 and pTF-FC2 were unable to functionally complement each other's oriV regions, but replication occurred when the genes for each plasmid's own RepA, RepB, and RepC proteins were provided in trans. Two smaller open reading frames were found between the repB and repA genes of pTC-F14, which encode proteins with high amino acid sequence identity (PasA, 81%; PasB, 72%) to the plasmid addiction system of pTF-FC2. This is the second time a plasmid stability system of this type has been found on an IncQ-like plasmid.     

Isolation,Characterization, and Transfer of Cryptic Gene-Mobilizing Plasmids in the Wheat Rhizosphere

A set of self-transmissible plasmids with IncQ plasmid-mobilizing capacity was isolated by triparental exogenous isolation from the wheat rhizosphere with an Escherichia coli IncQ plasmid host and a Ralstonia eutropha recipient. Three plasmids of 38 to 45 kb, denoted pIPO1, pIPO2, and pIPO3, were selected for further study. No selectable traits (antibiotic or heavy-metal resistance) were identified in these plasmids. The plasmids were characterized by replicon typing via PCR and hybridization with replicon-specific probes and other hybridizations. pIPO1 and pIPO3 were similar to each other, whereas pIPO2 was different. None of these plasmids belonged to any known incompatibility group. pIPO2 was selected for further work, and a mini-Tn5-tet transposon was inserted to confer selectability. Plasmid pIPO2 had a broad IncQ plasmid mobilization and self-transfer range among the alpha, beta, and gamma subclasses of the Proteobacteria but did not show productive transfer to gram-positive bacteria. Plasmid pIPO2 mobilized IncQ plasmid pIE723 from Pseudomonas fluorescens to diverse indigenous proteobacteria in the rhizosphere of field-grown wheat. Transfer of pIE723 to indigenous bacteria was not observed in the absence of added pIPO2. A specific PCR primer system and a probe were developed for the detection of pIPO2-type plasmids in soil and rhizosphere. Analysis of soil DNA provided evidence for the presence of pIPO2 in inoculated wheat rhizosphere soil in the field study, as well as in the rhizosphere of uninoculated wheat plants growing in soil microcosms. The system failed to identify major reservoirs of pIPO2 in a variety of other soils.Conjugation is an important gene transfer mechanism for bacteria in the soil and rhizosphere (7, 27, 28), and the genes responsible for mating-aggregate formation and DNA transfer are often carried by self-transmissible plasmids. Such conjugative plasmids are known to be capable of recruiting chromosomal genes as well as mobilizing non-self-transmissible plasmids and hence can provide genetic plasticity to bacterial populations. In cases in which highly promiscuous plasmids are involved, such genetic interactions may occur between a broad range of bacteria (27, 28, 34). Plasmid transfer between introduced bacteria via conjugation in soil has been unequivocally shown in numerous microcosm experiments with different mating combinations including taxonomically diverse ones (15, 21, 27, 28, 31, 44).However, the abundance and putative role of plasmids present in indigenous bacterial populations in in situ genetic mobilization has so far been rarely studied (11, 19, 36). Hence, the extent to which natural bacterial communities are capable of providing gene-mobilizing capacity under the prevailing conditions in the soil and rhizosphere is still poorly understood. In a pioneering study, Top et al. were able to roughly quantify the prevalence of gene-mobilizing elements in soil by a quantitative exogenous isolation method (36). However, the elements that confer genetic plasticity to bacterial populations, in particular self-transmissible plasmids and conjugative transposons, may occur in fluctuating quantities in soil. Moreover, their prevalence may change as a result of dominating soil ecological factors such as the presence of a rhizosphere or chemical stress (29, 45). To assess such bacterial community responses, a molecular approach assessing the prevalence of plasmid-specific sequences in soil-extracted microbial DNA can be used (29).Fry and Day suggested a novel approach to directly obtain plasmids with mobilizing capacity from the environment (7). The method, denominated triparental exogenous isolation, involves the coincubation of a selectable plasmid recipient strain with a mixed soil bacterial community in the presence of another strain containing a mobilizable plasmid. Simultaneous selection for the recipient and for a marker(s) of the mobilizable element allows the isolation of indigenous plasmids with plasmid-mobilizing capacity as a result of comobilization (7, 36). As suggested by Top et al. (36), the application of a transfer system consisting of an Escherichia coli plasmid donor strain containing an IncQ plasmid with heavy-metal (Cd, Zn, Co)-resistance genes which are not expressed and a Ralstonia eutropha recipient strain in which they can be expressed to a mixed soil bacterial community allows for the exogenous isolation of plasmid-mobilizing elements with broad-host-range capacity (gene escape system).The objectives of this study were to gain insight into the natural conjugal gene flow in gram-negative bacterial communities in soil and rhizosphere. For that purpose, plasmids with gene-mobilizing capacity were isolated from soil bacterial populations via the Escherichia coli-Ralstonia eutropha triparental exogenous isolation system. The plasmids obtained, denoted pIPO1, pIPO2, and pIPO3, were characterized by phenotypic and molecular methods. Furthermore, the possible role of one selected plasmid, pIPO2, in in situ mobilization of an IncQ plasmid, as well as its prevalence in soil and the wheat rhizosphere, was assessed by using a plasmid-specific PCR system.     

Pathogenomics of the Virulence Plasmids of Escherichia coli

Summary: Bacterial plasmids are self-replicating, extrachromosomal elements that are key agents of change in microbial populations. They promote the dissemination of a variety of traits, including virulence, enhanced fitness, resistance to antimicrobial agents, and metabolism of rare substances. Escherichia coli, perhaps the most studied of microorganisms, has been found to possess a variety of plasmid types. Included among these are plasmids associated with virulence. Several types of E. coli virulence plasmids exist, including those essential for the virulence of enterotoxigenic E. coli, enteroinvasive E. coli, enteropathogenic E. coli, enterohemorrhagic E. coli, enteroaggregative E. coli, and extraintestinal pathogenic E. coli. Despite their diversity, these plasmids belong to a few plasmid backbones that present themselves in a conserved and syntenic manner. Thanks to some recent research, including sequence analysis of several representative plasmid genomes and molecular pathogenesis studies, the evolution of these virulence plasmids and the implications of their acquisition by E. coli are now better understood and appreciated. Here, work involving each of the E. coli virulence plasmid types is summarized, with the available plasmid genomic sequences for several E. coli pathotypes being compared in an effort to understand the evolution of these plasmid types and define their core and accessory components.     

Characterization of a mobile and multiple resistance plasmid isolated from swine manure and its detection in soil after manure application

Aims: To isolate and characterize multiple antibiotic resistance plasmids found in swine manure and test for plasmid‐associated genetic markers in soil following manure application to an agricultural field. Methods and Results: Plasmids were isolated from an erythromycin enrichment culture that used liquid swine manure as an inoculant. Plasmids were transformed into Escherichia coli DH10β for subsequent characterization. We isolated and DNA sequenced a 22 102‐bp plasmid (pMC2) that confers macrolide, and tetracycline resistances, and carries genes predicted to code for mercury and chromium resistance. Conjugation experiments using an pRP4 derivative as a helper plasmid confirm that pMC2 has a functional mobilization unit. PCR was used to detect genetic elements found on pMC2 in DNA extracted from manure amended soil. Conclusions: The pMC2 plasmid has a tetracycline‐resistant core and has acquired additional resistance genes by insertion of an accessory region (12 762 bp) containing macrolide, mercury and chromium resistance genes, which was inserted between the truncated DDE motifs within the Tn903/IS102 mobile element. Significance and Impact of the Study: Liquid swine manure used for manure spreading contains multiple antibiotic resistance plasmids that can be detected in soil following manure application.     

FabV/Triclosan Is an Antibiotic-Free and Cost-Effective Selection System for Efficient Maintenance of High and Medium -Copy Number Plasmids in Escherichia coli

Antibiotic resistance genes and antibiotics are frequently used to maintain plasmid vectors in bacterial hosts such as Escherichia coli. Due to the risk of spread of antibiotic resistance, the regulatory authorities discourage the use of antibiotic resistance genes/antibiotics for the maintenance of plasmid vectors in certain biotechnology applications. Overexpression of E. coli endogenous fabI gene and subsequent selection on Triclosan has been proposed as a practical alternative to traditional antibiotic selection systems. Unfortunately, overexpression of fabI cannot be used to select medium –copy number plasmids, typically used for the expression of heterologous proteins in E. coli. Here we report that Vibrio cholera FabV, a functional homologue of E. coli FabI, can be used as a suitable marker for the selection and maintenance of both high and medium -copy number plasmid vectors in E. coli.     

Transfer of IncP Plasmids to Extremely Acidophilic Thiobacillus thiooxidans

The broad-host-range IncP plasmids RP4, R68.45, RP1::Tn501, and and pUB307 were transferred directly to extremely acidophilic Thiobacillus thiooxidans from Escherichia coli by conjugation at frequencies of 10^-5 to 10^-7 per recipient. The ability of T. thiooxidans to receive and express the antibiotic resistance markers was examined. The plasmid RP4 was transferred back to E. coli from T. thiooxidans at a frequency of 1.0 × 10^-3 per recipient.     

Contribution of the Earthworm Lumbricus rubellus (Annelida,Oligochaeta) to the Establishment of Plasmids in Soil Bacterial Communities

The contribution of the carthworm Lumbricus rubellus in spreading plasmids from a nonindigenous bacterial species to the soil microbial community was studied with Escherichia coli strains as donor organisms. The selected donor strains harbored marker-gene tagged plasmids with different transfer properties and host ranges. Prototrophic benzoate degrading indigenous bacteria were analyzed as potential recipients. In filter-mating experiments, donor strains were mixed with bacterial cell consortia extracted from earthworm casts (feces) and incubated on nutrient agar at 28°C. Transfer was detected with the broad host range IncP plasmid pRP4luc; with the IncQ plasmid, pSUP104luc, but only when it was present in a mobilizing donor strain; and with the transposon delivery vector pUTlux. No transfer was detected with the nonmobilizable pUCluc and the mobilizable pSUP202luc, both of narrow host range. In microcosm studies with E. coli inoculated soil incubated at 12°C, transconjugants were only detected in casts of L. rubellus but not in bulk soil, indicating that the gut passage was a precondition for plasmid transfer. Plasmid pRP4luc was transferred at higher frequencies than detected in filter mating. Results of the filter matings were confirmed except that transfer of pUTlux could not be detected. The majority of transconjugants isolated in this study lost their acquired plasmid upon further cultivation. Stable transconjugants, however, were obtained and identified at the 16S rRNA gene level as members of the β- and γ-subgroups of Proteobacteria. Incubation of E. coli and selected transconjugants in soil microcosms with L. rubellus demonstrated that the gut passage resulted in a slight but significant reduction of ingested cells. In contrast to the donor strains, however, the population sizes of transconjugants in bulk soil and in casts did not decrease over time. This demonstrated that the transferred plasmids had established themselves in the soil microbial community.     

Increased Abundance and Transferability of Resistance Genes after Field Application of Manure from Sulfadiazine-Treated Pigs

Spreading manure containing antibiotics in agriculture is assumed to stimulate the dissemination of antibiotic resistance in soil bacterial populations. Plant roots influencing the soil environment and its microflora by exudation of growth substrates might considerably increase this effect. In this study, the effects of manure from pigs treated with sulfadiazine (SDZ), here called SDZ manure, on the abundance and transferability of sulfonamide resistance genes sul1 and sul2 in the rhizosphere of maize and grass were compared to the effects in bulk soil in a field experiment. In plots that repeatedly received SDZ manure, a significantly higher abundance of both sul genes was detected compared to that in plots where manure from untreated pigs was applied. Significantly lower abundances of sul genes relative to bacterial ribosomal genes were encountered in the rhizosphere than in bulk soil. However, in contrast to results for bulk soil, the sul gene abundance in the SDZ manure-treated rhizosphere constantly deviated from control treatments over a period of 6 weeks after manuring, suggesting ongoing antibiotic selection over this period. Transferability of sulfonamide resistance was analyzed by capturing resistance plasmids from soil communities into Escherichia coli. Increased rates of plasmid capture were observed in samples from SDZ manure-treated bulk soil and the rhizosphere of maize and grass. More than 97% of the captured plasmids belonged to the LowGC type (having low G+C content), giving further evidence for their important contribution to the environmental spread of antibiotic resistance. In conclusion, differences between bulk soil and rhizosphere need to be considered when assessing the risks associated with the spreading of antibiotic resistance.     

Self-Transmissible Mercury Resistance Plasmids with Gene-Mobilizing Capacity in Soil Bacterial Populations: Influence of Wheat Roots and Mercury Addition

A set of mercury resistance plasmids was obtained from wheat rhizosphere soil amended or not amended with mercuric chloride via exogenous plasmid isolation by using Pseudomonas fluorescens R2f, Pseudomonas putida UWC1, and Enterobacter cloacae BE1 as recipient strains. The isolation frequencies were highest from soil amended with high levels of mercury, and the isolation frequencies from unamended soil were low. With P. putida UWC1 as the recipient, the isolation frequency was significantly enhanced in wheat rhizosphere compared to bulk soil. Twenty transconjugants were analyzed per recipient strain. All of the transconjugants contained plasmids which were between 40 and 50 kb long. Eight selected plasmids were distributed among five groups, as shown by restriction digestion coupled with a similarity matrix analysis. However, all of the plasmids formed a tight group, as judged by hybridization with two whole-plasmid probes and comparisons with other plasmids in dot blot hybridization analyses. The results of replicon typing and broad-host-range incompatibility (Inc) group-specific PCR suggested that the plasmid isolates were not related to any previously described Inc group. Although resistance to copper, resistance to streptomycin, and/or resistance to chloramphenicol was found in several plasmids, catabolic sequences were generally not identified. One plasmid, pEC10, transferred into a variety of bacteria belonging to the β and γ subdivisions of the class Proteobacteria and mobilized as well as retromobilized the IncQ plasmid pSUP104. A PCR method for detection of pEC10-like replicons was used, in conjunction with other methods, to monitor pEC10-homologous sequences in mercury-polluted and unpolluted soils. The presence of mercury enhanced the prevalence of pEC10-like replicons in soil and rhizosphere bacterial populations.The potential use of genetically modified bacteria in agriculture has raised questions pertaining to the spread of introduced recombinant DNA through soil bacterial communities. Gene transfer in soil via conjugation has received much attention, and the focus of most studies has been the transfer and fate of introduced plasmids (6, 22, 27–29, 39). Under favorable conditions, in specific soil microhabitats, or under selection conditions, both self-transmissible and mobilizable plasmids present in introduced hosts can be transferred to introduced recipients, as well as to a variety of indigenous bacteria (15, 20, 27, 28, 33). In particular, rhizospheres of crop plants, such as wheat and sugar beet, provide conditions conducive to conjugal plasmid transfer between bacterial inhabitants (15, 36). When genetically modified bacteria are developed as inoculants for the rhizosphere, insertion of heterologous DNA into non-self-transmissible plasmids or the chromosome might restrict conjugal transfer of this DNA to members of the indigenous bacterial community. However, mobilizing or retromobilizing (33) plasmids present in indigenous soil bacteria could potentially still effect the transfer of the less mobile heterologous DNA via chromosome or plasmid mobilization, which may involve cointegration (9, 19, 31). Such plasmids might thus be responsible for the escape of heterologous DNA from genetically modified bacteria introduced into soil.There is a paucity of knowledge concerning the incidence of plasmids with mobilizing capacity in soils and rhizospheres, as well as concerning the effects of soil factors, such as stresses resulting from pollution or from natural causes (e.g., rhizosphere acidity), on plasmid prevalence and transfer (e.g., reference 38). Whereas it has been suggested that chemical stress often does not enhance plasmid incidence in selected soil bacterial populations (40), pollution in river water or mines (in particular mercury pollution) has been found to exert a selective (enhancing) effect (4, 13).Plasmids of environmental bacteria have classically been obtained by endogenous isolation procedures (20). Endogenous isolation implies that putative plasmid hosts with the phenotype of interest are isolated from soil, after which plasmids are extracted from pure cultures of these strains. On the other hand, pioneering studies performed with river stone epilithon (9) and later extended to soil and sediment (32) have shown that plasmids can be obtained directly from indigenous bacterial communities in new hosts by exogenous isolation. In this approach, plasmids are captured in selectable recipient strains by using mating between these strains and the total bacterial community obtained from an environmental sample. Following incubation, the mating mixture is plated with selection for the recipient and an additional marker gene presumedly located on a plasmid present in the indigenous bacteria (6). The advantage of the exogenous isolation procedure is that no culturing step is required in the mating, which thus allows isolation of plasmids from nonculturable hosts. Furthermore, plasmids are directly selected for their transfer capacity, in addition to the presence of a specific selectable marker.In this study, exogenous plasmid isolation was employed to obtain transferable plasmids from soil bacteria by using mercury resistance as the selectable marker. The objective of this work was to gain insight into the potential present in soil bacterial populations to (retro)mobilize genes out of introduced bacteria into members of the soil bacterial community. Since the incidence of plasmids in soil bacteria is likely influenced by soil ecological factors and selection pressure, the presence of wheat roots and selection by mercury (25) were studied as experimental variables.