Identification and Characterization of Conjugative Transposons CTn86 and CTn9343 in Bacteroides fragilis Strains

The related genetic elements flanking the Bacteroides fragilis pathogenicity island (PAI) in enterotoxigenic B. fragilis (ETBF) 86-5443-2-2 and also present in pattern III nontoxigenic B. fragilis (NTBF) NCTC 9343 were defined as putative conjugative transposons (CTns), designated CTn86 and CTn9343, respectively (A. A. Franco, J. Bacteriol. 181:6623-6633, 2004). CTn86 and CTn9343 have the same basic structures except that their encoded transposases have low similarity and CTn9343 lacks the B. fragilis PAI and contains an extra 7-kb region not present in CTn86. In this study, using DNA hybridization and PCR analysis, we characterized the genetic element flanking the PAI in a collection of ETBF strains and the related genetic elements in a collection of NTBF pattern III strains. We found that in all 123 ETBF strains, the PAI is contained in a genetic element similar to CTn86. Of 73 pattern III strains, 26 (36%) present a genetic element similar to CTn9343, 38 (52%) present a genetic element similar to CTn9343 but lack the 7-kb region that is also absent in CTn86 (CTn9343-like element), and 9 (12%) present a genetic element similar to CTn86 but lacking the PAI (CTn86-like element). In addition to containing CTn86, ETBF strains can also contain CTn9343, CTn9343-like, or CTn86-like elements. CTn86, CTn9343, CTn86-like, and CTn9343-like elements were found exclusively in B. fragilis strains and predominantly in division I, cepA-positive strains.     

Conjugative Transfer between Escherichia coli and Leptospira spp. as a New Genetic Tool

Our understanding of leptospiral pathogenesis, which remains poorly understood, depends on reliable genetic tools for functional analysis of genes in pathogenic strains. In this study, we report the first demonstration of conjugation between Escherichia coli and Leptospira spp. by using RP4 derivative conjugative plasmids. The DNA transfer described here was due to authentic conjugation, as shown by the requirement for cell-to-cell contact and the resistance of DNA transfers to the addition of DNase I. Transposition via conjugation of a plasmid delivering Himar1 yielded frequencies ranging from 1 × 10⁻⁶ to 8.5 × 10⁻⁸ transconjugants/recipient cell in the saprophyte L. biflexa and the pathogen L. interrogans, respectively. Analysis of mutants indicated that transposition occurs randomly, and at single sites in the genome of these strains, allowing the utilization of this system to generate libraries of transposon mutants.     

Conjugative transfer of plasmid pTO1 from Escherichia coli to Rhodococcus spp.

Summary We demonstrated the conjugative transfer of plasmid pTO1 from Escherichia coli S17-1 to different Rhodococcus spp. The plasmid contains the oriT fragment from RK2 and a fragment of Streptomyces C31 actinophage with the attachment site and the integration genes. Experiments on hybridization showed that plasmid pTO1 is chromosomally integrated into the Rhodococcus cells.     

Genetic and Biochemical Analyses of the tec Operon Suggest a Route for Evolution of Chlorobenzene Degradation Genes

The TecA broad-spectrum chlorobenzene dioxygenase of Burkholderia sp. strain PS12 catalyzes the first step in the mineralization of 1,2,4,5-tetrachlorobenzene. The catabolic genes were localized on a small plasmid that belongs to the IncPβ incompatibility group. PCR analysis of the genetic environment of the tec genes indicated high similarity to the transposon-organized catabolic tcb chlorobenzene degradation genes of Pseudomonas sp. strain P51. Sequence analysis of the regions flanking the tecA genes revealed an upstream open reading frame (ORF) with high similarity to the todF 2-hydroxy-6-oxo-2,4-heptadienoate hydrolase gene of Pseudomonas putida F1 and a discontinuous downstream ORF showing high similarity to the todE catechol 2,3-dioxygenase gene of strain F1. Both homologues in strain P51 exist only as deletion remnants. We suggest that different genetic events thus led to inactivation of the perturbing meta-cleavage enzymes in strains P51 and PS12 during the evolution of efficient chlorobenzene degradation pathways. Biochemical characterization of TodF-like protein TlpF and a genetically refunctionalized TodE-like protein, TlpE, produced in Escherichia coli provided data consistent with the proposed relationships.     

Engineering of Tellurite-Resistant Genetic Tools for Single-Copy Chromosomal Analysis of Burkholderia spp. and Characterization of the Burkholderia thailandensis betBA Operon

There are few appropriate single-copy genetic tools for most Burkholderia species, and the high level of antibiotic resistance in this genus further complicates the development of genetic tools. In addition, the utilization of resistance genes for clinically important antibiotics is prohibited for the bioterrorism agents Burkholderia pseudomallei and Burkholderia mallei, necessitating the development of additional nonantibiotic-based genetic tools. Three single-copy systems devoid of antibiotic selection based on two nonantibiotic selectable markers, tellurite resistance (Tel^r) and Escherichia coli aspartate-semialdehyde dehydrogenase (asd_Ec), were developed to facilitate genetic manipulation in Burkholderia species. These systems include one mariner transposon, a mini-Tn7-derived site-specific transposon, and six FRT reporter fusion vectors based on the lacZ, gfp, and luxCDABE reporter genes. Initially, we showed that the random mariner transposon pBT20-Δbla-Tel^r-FRT efficiently transposed within Burkholderia cenocepacia, Burkholderia thailandensis, B. pseudomallei, and B. mallei. We then utilized the mini-Tn7-Tel^r-based transposon vector (mini-Tn7-Tel^r-betBA) and a transposase-containing helper plasmid (pTNS3-asd_Ec) to complement the B. thailandensis ΔbetBA mutation. Next, one of the FRT-lacZ fusion vectors (pFRT1-lacZ-Tel^r) was integrated by Flp (encoded on a helper plasmid, pCD13SK-Flp-oriT-asd_Ec) to construct the B. thailandensis ΔbetBA::FRT-lacZ-Tel^r reporter fusion strain. The betBA operon was shown to be induced in the presence of choline and under osmotic stress conditions by performing β-galactosidase assays on the B. thailandensis ΔbetBA::FRT-lacZ-Tel^r fusion strain. Finally, we engineered B. thailandensis ΔbetBA::FRT-gfp-Tel^r and ΔbetBA::FRT-lux-Tel^r fusion strains by utilizing fusion vectors pFRT1-gfp-Tel^r and pFRT1-lux-Tel^r, respectively. The induction of the betBA operon by choline and osmotic stress was confirmed by performing fluorescent microscopy and bioluminescent imaging analyses.The genus Burkholderia, consisting of more than 40 different species, occupies diverse ecological niches ranging from the soil rhizosphere to the human respiratory tract (39). Within this genus, members exhibit considerable genetic diversity and broad metabolic capabilities (26, 39), facilitating their adaptation to a variety of environmental conditions including nutrient limitation, the presence of antibiotics and toxic compounds, and pH fluctuations. Many Burkholderia species are known plant pathogens, including Burkholderia caryophylli, B. plantarri, and B. glumae, while others (e.g., B. cepacia complex) cause opportunistic infections (39). In addition, Burkholderia pseudomallei and B. mallei are primary pathogens for humans and animals and are listed as category B select agents in the United States.To best exploit the genomic information available for several Burkholderia species, a wide array of tools is required for molecular genetic and pathogenesis studies of these bacteria. For Burkholderia species not classified as select agents, antibiotic-resistance-based tools could be used for genetic manipulation. However, the Centers for Disease Control and Prevention restricts the introduction of markers conferring resistance against clinically important antibiotics into the two select agents B. mallei and B. pseudomallei. At present, only gentamicin, kanamycin, and zeocin resistance markers are approved for limited use for B. pseudomallei, while only the kanamycin and zeocin resistance markers are approved for B. mallei (35). However, most wild-type strains of B. mallei and B. pseudomallei have high levels of resistance to all three antibiotics (7, 29, 36), and even at high concentrations, the selection is not tight, and spontaneous resistance still arises (10, 15, 32). Consequently, there is still a need to expand universal genetic tools based on nonantibiotic selectable markers, allowing broader applications in various Burkholderia species.Several nonantibiotic selection schemes have been used in bacteria including, but not limited to, resistance to various compounds (e.g., arsenate; bialaphos or its degradation product, phosphinothricin; mercury; and tellurite [Tel]) and metabolic markers (e.g., lactose utilization and purine and amino acid biosynthesis). Potential drawbacks to using arsenate and mercury are high toxicity levels and narrow selective concentration ranges (4, 16). Bialaphos and its degradation product, phosphinothricin, have been shown to be ineffective for Burkholderia select agents, requiring concentrations greater than 1,000 μg/ml, whereas these bacteria have been shown to be sensitive to Tel concentrations of less than 1 μg/ml (M. Frazier, K. Choi, A. Kumar, C. Lopez, R. R. Karkhoff-Schweizer, and H. P. Schweizer, presented at the American Society for Microbiology Biodefense and Emerging Diseases Research Meeting, Washington, DC, 2007). Therefore, the nonantibiotic selectable marker based on Tel resistance (Tel^r) could be useful for genetic manipulation in various Burkholderia species, particularly B. mallei and B. pseudomallei. The Tel^r marker, consisting of three genes (kilA, telA, and telB) (38), has been successfully employed as a nonantibiotic selectable marker originally in Pseudomonas putida (34), in several other gram-negative bacteria (25), and, more recently, in B. thailandensis (2). Additionally, the asd gene (a metabolic marker encoding aspartate-semialdehyde dehydrogenase for amino acid biosynthesis) has been used as a nonantibiotic selectable marker in Δasd backgrounds (2, 30). Combining the Tel^r marker and the asd gene may expand the repertoire of genetic tools available for Burkholderia species.Strategies and tools for the manipulation of genetic elements as a single copy on the chromosome have been developed, such as Himar1-based mariner transposons (22, 32), the mini-Tn7 site-specific transposition system (1, 9), and FRT-lacZ fusion vectors (12, 37). The random Himar1-based mariner transposon plasmid pBT20 was successfully used for mutant library construction in Pseudomonas aeruginosa (6, 19, 22) and has also been proven useful for transposition in a broad range of gram-negative bacteria (20). Similarly, the Himar1-based transposons carrying the Km^r cassette were proven to be useful in B. pseudomallei (32). The second single-copy system based on the mini-Tn7 site-specific transposon, when used in conjunction with the transposase-encoding helper plasmid, has broad applications for the introduction of single-copy chromosomal elements into gram-negative bacteria (9) and the select agent B. mallei (8). Lastly, after mutant construction with an FRT-flanked selectable marker and Flp excision, the introduction of an Flp-containing helper plasmid and an FRT-lacZ fusion vector allows for simple Flp-catalyzed recombination to the “FRT scar” at the target gene downstream of the native promoter, facilitating regulation studies without prior knowledge of the promoter sequence (12, 37). Nevertheless, there are disadvantages to these existing systems when used in Burkholderia species, particularly in the select agents B. pseudomallei and B. mallei, due to the antibiotic resistance markers used (e.g., gentamicin, kanamycin, ampicillin, and streptomycin) and the occurrence of spontaneously resistant mutants (10, 15, 32). Moreover, to our knowledge, no FRT-reporter fusion vectors based on reporter genes other than lacZ have been developed.In this study, genetic tools using the Tel^r marker for selection were developed for single-copy analyses of chromosomally targeted genetic elements. These include a Himar1-based random mariner transposon plasmid and a mini-Tn7 site-specific transposon vector. We also engineered FRT-reporter fusion vectors based on three common reporters, lacZ, gfp, and the luxCDABE operon, allowing for Flp-catalyzed recombination. These systems expand upon our previously published nonantibiotic selectable marker approach for allelic replacement (2) and will aid in routine genetic manipulations including transposon mutagenesis, complementation studies, and promoter regulation studies of Burkholderia species. Most importantly, all genetic tools presented here are completely devoid of antibiotic resistance selection and are in compliance with select-agent regulations. We utilized these tools to characterize the B. thailandensis betBA operon, encoding betaine aldehyde dehydrogenase (BetB) and choline dehydrogenase (BetA).     

Transposition of Tn4551 in Bacteroides fragilis: identification and properties of a new transposon from Bacteroides spp.

Tn4551, a clindamycin resistance (Ccr) transposon from the R plasmid pBI136, was cloned onto an Escherichia coli-Bacteroides shuttle vector which could replicate normally in E. coli but was maintained unstably in Bacteroides fragilis. To aid in cloning and to ensure maintenance of Tn4551 in E. coli, a kanamycin resistance determinant (Kmr) was inserted in the transposon. The transposon-bearing shuttle vector pFD197 was transformed into B. fragilis 638, and putative insertions of Tn4551::Kmr were identified by screening for resistance to clindamycin and plasmid content. Southern hybridization analyses were used to verify integration of the transposon in the B. fragilis chromosome, and the frequency of insertion was estimated at 7.8 X 10(-5) events per generation. In 57% of the isolates tested a second integration event also occurred. This second insertion apparently involved just a single copy of the 1.2-kilobase repeat sequence which flanks the transposon. In addition, Tn4551::Kmr appeared to function as a transposon in E. coli. Evidence for this was obtained by the isolation of transposon insertions into the bacteriophage P1 genome. Finally, the transposon vector, pFD197, could be mobilized to other B. fragilis strains in which transposition was detected. Mobilization from the strain 638 background was via a conjugation like process, but occurred in the absence of known conjugative elements or other detectable plasmids. This result suggested the presence of a host-encoded transfer system in this B. fragilis strain.     

Functional Dissection of the Conjugative Coupling Protein TrwB

The conjugative coupling protein TrwB is responsible for connecting the relaxosome to the type IV secretion system during conjugative DNA transfer of plasmid R388. It is directly involved in transport of the relaxase TrwC, and it displays an ATPase activity probably involved in DNA pumping. We designed a conjugation assay in which the frequency of DNA transfer is directly proportional to the amount of TrwB. A collection of point mutants was constructed in the TrwB cytoplasmic domain on the basis of the crystal structure of TrwBΔN70, targeting the nucleotide triphosphate (NTP)-binding region, the cytoplasmic surface, or the internal channel in the hexamer. An additional set of transfer-deficient mutants was obtained by random mutagenesis. Most mutants were impaired in both DNA and protein transport. We found that the integrity of the nucleotide binding domain is absolutely required for TrwB function, which is also involved in monomer-monomer interactions. Polar residues surrounding the entrance and inside the internal channel were important for TrwB function and may be involved in interactions with the relaxosomal components. Finally, the N-terminal transmembrane domain of TrwB was subjected to random mutagenesis followed by a two-hybrid screen for mutants showing enhanced protein-protein interactions with the related TrwE protein of Bartonella tribocorum. Several point mutants were obtained with mutations in the transmembranal helices: specifically, one proline from each protein may be the key residue involved in the interaction of the coupling protein with the type IV secretion apparatus.Bacterial conjugation can be viewed mechanistically as a rolling-circle replication system linked to a type IV secretion process. The two processes come into contact through the activity of a protein that couples the plasmid replication machinery to the export system in the membrane, allowing horizontal dissemination of the replicating DNA molecule (35). This key protein is called “coupling protein” (here “T4CP” for “type IV CP”). It is present in all conjugative systems as well as in many type IV secretion systems (T4SS) involved in bacterial virulence (16). The secreted substrate in bacterial conjugation is the relaxase or pilot protein, attached to the DNA strand. The shoot-and-pump model for bacterial conjugation proposes that, after secretion of the protein through the T4SS, the T4CP works as a motor for export of the rest of the DNA molecule (36). In addition to its presumed role as a DNA transporter, TrwB is also required for transport of relaxase TrwC in the absence of DNA transfer (15).In accordance with its proposed coupling activity, early genetic experiments made patent that the function of conjugative T4CPs depended on interactions with both the cytoplasmic substrate complex (the relaxosome) and the T4SS (6, 7). Thus, T4CP interactions with other conjugation proteins are a key aspect of their function. There have been several reports of interactions between T4CPs from conjugative plasmids and either relaxosomal components—such as F-TraD with TraM (14, 38), RP4-TraG with TraI (49), and pCF10-PcfC with PcfF and PcfG (11)—or T4SS components such as R27-TraG with TrhB (17). T4CP-T4SS interactions have also been reported for the VirB/D4 T4SS involved in DNA transfer from Agrobacterium tumefaciens to plant cells (1, 9). Both sets of interactions have only been concurrently shown for TrwB, the T4CP of plasmid R388. TrwB interacts with proteins TrwA and TrwC, which form the R388 relaxosome, and with the R388 T4SS component TrwE (37). While the interaction with the relaxosome is highly specific for its cognate system (24, 37, 48), the interaction between the T4CP and the T4SS is less specific: a single T4CP can interact functionally with several conjugative T4SS. Interestingly, a correlation was observed between the strength of the T4CP-TrwE-like interaction and the efficiency of DNA transfer (37). T4CPs also interact with TrwE-like components of T4SS involved in virulence (13). In the case of the highly related Trw T4SS systems of plasmid R388 and the human pathogen Bartonella, it was further demonstrated that R388 TrwE could be functionally replaced by the Bartonella tribocorum TrwE homolog, TrwE_Bt (13).T4CPs are integral membrane proteins anchored to the inner membrane by an N-terminal transmembrane domain (TMD). The soluble cytoplasmic domain of TrwB (TrwBΔN70), lacking this TMD, has been biochemically and structurally analyzed in detail. It retains the ability to bind NTPs and to unspecifically bind DNA (42). The characterization of its DNA-dependent ATPase activity (53) strengthened the possibility that T4CPs work as DNA motors. This activity is also stimulated by the oriT-binding protein TrwA (52).The determination of the three-dimensional (3D) structure of TrwBΔN70 indicated a quaternary structure consisting of hexamers that form an almost spherical, orange-shaped structure with a 20-Å inner channel (ICH) (18, 19). Each monomer is composed of two main structural domains: the nucleotide-binding domain (NBD) and the all-alpha domain (AAD). The NBD has α/β topology and is reminiscent of RecA and DNA ring helicases. The AAD is facing the cytoplasmic side and bears significant structural similarity to the N-terminal domain of site-specific recombinase XerD and also to a 40-residue segment of the DNA binding domain of protein TraM, the component of the relaxosome of F-like plasmids that interacts with its cognate T4CP, TraD. The structure of the hexamer as a whole resembles that of the F₁-ATPase, raising interesting perspectives into the possible way of action of coupling proteins as molecular motors in conjugation (5).There have been several attempts to functionally dissect T4CPs. In F-TraD, it was determined that its C terminus is essential for relaxosomal specificity, probably through an interaction with TraM (4, 39, 48). The cytoplasmic domain of the related TraD protein of plasmid R1 stimulates both transesterase and helicase activities of its cognate relaxase, TraI (41, 51). A series of random mutations were shown to affect TraD oligomerization (23). In VirD4, the T4CP of the VirB T4SS of A. tumefaciens, both the periplasmic domain plus key residues of the NBD are required for its location at the cell poles (31); its interaction with the T4SS protein substrate VirE2 does not require the N-terminal TMD (2). Mutational analysis of R27 TraG showed that the periplasmic residues are essential for interaction with the T4SS (22). An N-terminal deletion variant of PcfC, the T4CP of the Enterococcus plasmid pCF10, loses its membrane localization but retains its ability to bind relaxosomal components (11). Biochemical analysis of full-length R388 TrwB showed that the N-terminal TMD stabilizes the protein, aids oligomerization, and affects nucleotide selection (25-27). This region is essential for T4SS interaction, but TrwBΔN70 retains the ability to interact with the relaxosomal components TrwA and TrwC (37). Taken together, these analyses suggested that the N-terminal TMD of the T4CPs is necessary for T4SS interaction, oligomerization, and cellular location and that the C-terminal cytoplasmic domain is necessary for relaxosomal interactions and ATPase activity associated with DNA transport.In this study, we set up different assays to search for mutants affecting TrwB function in DNA and protein transfer. We constructed a series of TrwB point mutants based on the 3D structure of TrwBΔN70. Most selected residues were essential for TrwB function in conjugation, especially under conditions where TrwB was in limiting quantities. We analyzed the in vivo properties of selected mutants with a battery of in vivo assays to map functional domains. Also, random mutants in the TMD were screened for improved interactions with the T4SS, which allowed mapping of the TrwB-TrwE interaction domain.     

Tn4351 transposes in Bacteroides spp. and mediates the integration of plasmid R751 into the Bacteroides chromosome.

The gene for resistance to erythromycin and clindamycin, which is carried on the conjugative Bacteroides plasmid, pBF4, has been shown previously to be part of an element (Tn4351) that transposes in Escherichia coli. We have now introduced Tn4351 into Bacteroides uniformis 0061 on the following two suicide vectors: (i) the broad-host-range IncP plasmid R751 (R751::Tn4351) and (ii) pSS-2, a chimeric plasmid which contains 33 kilobases of pBF4 (including Tn4351) cloned into the IncQ plasmid RSF1010 and which is mobilized by R751. When E. coli HB101, carrying either R751::Tn4351 or R751 and pSS-2, was mated with B. uniformis under aerobic conditions, Emr transconjugants were detected at a frequency of 10(-6) to 10(-5) (R751::Tn4351) or 10(-8) to 10(-6) (R751 and pSS-2). In matings involving pSS-2, all Emr transconjugants contained simple insertions of Tn4351 in the chromosome, whereas in matings involving R751::Tn4351, about half of the Emr transconjugants had R751 cointegrated with Tn4351 in the chromosome. Of the Emr transconjugants, 13% were auxotrophs. Bacteroides spp. which had R751 cointegrated with Tn4351 in the chromosome did not transfer R751 or Tn4351 to E. coli HB101 or to isogenic B. uniformis, nor did the intergrated R751 mobilize pE5-2, an E. coli-Bacteroides shuttle vector that contains a transfer origin that is recognized by R751.     

Coselection of Cadmium and Benzalkonium Chloride Resistance in Conjugative Transfers from Nonpathogenic Listeria spp. to Other Listeriae

Resistance to the quaternary ammonium disinfectant benzalkonium chloride (BC) may be an important contributor to the ability of Listeria spp. to persist in the processing plant environment. Although a plasmid-borne disinfectant resistance cassette (bcrABC) has been identified in Listeria monocytogenes, horizontal transfer of these genes has not been characterized. Nonpathogenic Listeria spp. such as L. innocua and L. welshimeri are more common than L. monocytogenes in food processing environments and may contribute to the dissemination of disinfectant resistance genes in listeriae, including L. monocytogenes. In this study, we investigated conjugative transfer of resistance to BC and to cadmium from nonpathogenic Listeria spp. to other nonpathogenic listeriae, as well as to L. monocytogenes. BC-resistant L. welshimeri and L. innocua harboring bcrABC, along with the cadmium resistance determinant cadA2, were able to transfer resistance to other nonpathogenic listeriae as well as to L. monocytogenes of diverse serotypes, including strains from the 2011 cantaloupe outbreak. Transfer among nonpathogenic Listeria spp. was noticeably higher at 25°C than at 37°C, whereas acquisition of resistance by L. monocytogenes was equally efficient at 25 and 37°C. When the nonpathogenic donors were resistant to both BC and cadmium, acquisition of cadmium resistance was an effective surrogate for transfer of resistance to BC, suggesting coselection between these resistance attributes. The results suggest that nonpathogenic Listeria spp. may behave as reservoirs for disinfectant and heavy metal resistance genes for other listeriae, including the pathogenic species L. monocytogenes.     

Survival and detection of Bacteroides spp., prospective indicator bacteria.

Preliminary experiments were performed to assess the use of intestinal Bacteroides spp. as indicators of fecal contamination of water. Viable counts of Bacteroides fragilis, an anaerobic bacterium, declined more rapidly than those of Escherichia coli and Streptococcus faecalis. However, a fluorescent antiserum prepared against B. fragilis successfully detected high proportions (18 to greater than 50%) of B. fragilis cells suspended for 8 days in aerobic water in dialysis bags at the ambient temperature. These percentages were higher than the percent viable recoveries of the two indicator bacteria used for comparison. Thus, the fluorescent antiserum test for B. fragilis might serve as a useful indicator of fecal contamination of water. An advantage of this approach over coliform analysis is the rapidity at which the test can be performed.     

Evidence for extensive resistance gene transfer among Bacteroides spp. and among Bacteroides and other genera in the human colon

Transfer of antibiotic resistance genes by conjugation is thought to play an important role in the spread of resistance. Yet virtually no information is available about the extent to which such horizontal transfers occur in natural settings. In this paper, we show that conjugal gene transfer has made a major contribution to increased antibiotic resistance in Bacteroides species, a numerically predominant group of human colonic bacteria. Over the past 3 decades, carriage of the tetracycline resistance gene, tetQ, has increased from about 30% to more than 80% of strains. Alleles of tetQ in different Bacteroides species, with one exception, were 96 to 100% identical at the DNA sequence level, as expected if horizontal gene transfer was responsible for their spread. Southern blot analyses showed further that transfer of tetQ was mediated by a conjugative transposon (CTn) of the CTnDOT type. Carriage of two erythromycin resistance genes, ermF and ermG, rose from <2 to 23% and accounted for about 70% of the total erythromycin resistances observed. Carriage of tetQ and the erm genes was the same in isolates taken from healthy people with no recent history of antibiotic use as in isolates obtained from patients with Bacteroides infections. This finding indicates that resistance transfer is occurring in the community and not just in clinical environments. The high percentage of strains that are carrying these resistance genes in people who are not taking antibiotics is consistent with the hypothesis that once acquired, these resistance genes are stably maintained in the absence of antibiotic selection. Six recently isolated strains carried ermB genes. Two were identical to erm(B)-P from Clostridium perfringens, and the other four had only one to three mismatches. The nine strains with ermG genes had DNA sequences that were more than 99% identical to the ermG of Bacillus sphaericus. Evidently, there is a genetic conduit open between gram-positive bacteria, including bacteria that only pass through the human colon, and the gram-negative Bacteroides species. Our results support the hypothesis that extensive gene transfer occurs among bacteria in the human colon, both within the genus Bacteroides and among Bacteroides species and gram-positive bacteria.     

Evidence for Extensive Resistance Gene Transfer among Bacteroides spp. and among Bacteroides and Other Genera in the Human Colon

Transfer of antibiotic resistance genes by conjugation is thought to play an important role in the spread of resistance. Yet virtually no information is available about the extent to which such horizontal transfers occur in natural settings. In this paper, we show that conjugal gene transfer has made a major contribution to increased antibiotic resistance in Bacteroides species, a numerically predominant group of human colonic bacteria. Over the past 3 decades, carriage of the tetracycline resistance gene, tetQ, has increased from about 30% to more than 80% of strains. Alleles of tetQ in different Bacteroides species, with one exception, were 96 to 100% identical at the DNA sequence level, as expected if horizontal gene transfer was responsible for their spread. Southern blot analyses showed further that transfer of tetQ was mediated by a conjugative transposon (CTn) of the CTnDOT type. Carriage of two erythromycin resistance genes, ermF and ermG, rose from <2 to 23% and accounted for about 70% of the total erythromycin resistances observed. Carriage of tetQ and the erm genes was the same in isolates taken from healthy people with no recent history of antibiotic use as in isolates obtained from patients with Bacteroides infections. This finding indicates that resistance transfer is occurring in the community and not just in clinical environments. The high percentage of strains that are carrying these resistance genes in people who are not taking antibiotics is consistent with the hypothesis that once acquired, these resistance genes are stably maintained in the absence of antibiotic selection. Six recently isolated strains carried ermB genes. Two were identical to erm(B)-P from Clostridium perfringens, and the other four had only one to three mismatches. The nine strains with ermG genes had DNA sequences that were more than 99% identical to the ermG of Bacillus sphaericus. Evidently, there is a genetic conduit open between gram-positive bacteria, including bacteria that only pass through the human colon, and the gram-negative Bacteroides species. Our results support the hypothesis that extensive gene transfer occurs among bacteria in the human colon, both within the genus Bacteroides and among Bacteroides species and gram-positive bacteria.     

Genetic diversity of bradyrhizobial populations from diverse geographic origins that nodulate Lupinus spp. and Ornithopus spp

The genetic diversity of 45 bradyrhizobial isolates that nodulate several Lupinus and Ornithopus species in different geographic locations was investigated by 16S rDNA PCR-RFLP and sequence analysis, 16S-23S rDNA intergenic spacer (IGS) PCR-RFLP analysis, and ERIC-PCR genomic fingerprinting. Reference strains of Bradyrhizobium japonicum, B. liaoningense and B. elkanii and some Canarian isolates from endemic woody legumes in the tribe Genisteae were also included. The 16S rDNA-RFLP analysis resolved 9 genotypes of lupin isolates, a group of fourteen isolates presented restriction-genotypes identical or very similar to B. japonicum, while another two main groups of isolates (69%) presented genotypes that clearly separated them from the reference species of soybean. 16S rDNA sequencing of representative strains largely agreed with restriction analysis, except for a group of six isolates, and showed that all the lupin isolates are relatives of B. japonicum, but different lineages were observed. The 16S-23S IGS-RFLP analysis showed a high resolution level, resolving 19 distinct genotypes among 30 strains analysed, and so demonstrating the heterogeneity of the 16S-RFLP groups. ERIC-PCR fingerprint analysis showed an enormous genetic diversity producing a different pattern for each but two of the isolates. Phylogeny of nodC gene was independent from the 16S rRNA phylogeny, and showed a tight relationship in the symbiotic region of the lupin isolates with isolates from Canarian genistoid woody legumes, and in concordance, cross-nodulation was found. We conclude that Lupinus is a promiscuous host legume that is nodulated by rhizobia with very different chromosomal genotypes, which could even belong to several species of Bradyrhizobium. No correlation among genomic background, original host plant and geographic location was found, so, different chromosomal genotypes could be detected at a single site and in a same plant species, on the contrary, an identical genotype was detected in very different geographical locations and plants.     

Genetic Analyses of the Polarity Alleles in Recombinants from Mitochondrial Genetic Crosses

A number of minority recombinant and parental types from a heterosexual cross were analyzed for the omega allele they carry. It was found that recombinant progeny can be omega(-), that minority parental types among the progeny can be omega(+) rather than omega(-), and, finally, that certain of the results suggest that the omega locus may not be at the proximal end of the mitochondrial genetic map (Bolotin et al., 1971; Grivell et al., 1973) but rather may lie between the [cap1-r/cap-s] and [ery1-r/ery-s] loci.