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Exploitation of a -lactamase reporter gene fusion in the carbapenem antibiotic production operon to study adaptive evolution in Erwinia carotovora

Department of Biochemistry, University of Cambridge, Tennis Court Road, Cambridge CB2 1QW, UK

Correspondence
George P. C. Salmond
gpcs{at}mole.bio.cam.ac.uk

	ABSTRACT

TOP ABSTRACT INTRODUCTION METHODS RESULTS AND DISCUSSION REFERENCES

 
Erwinia carotovora subsp. carotovora strain ATTn10 produces the -lactam antibiotic 1-carbapen-2-em-3-carboxylic acid (carbapenem) by expressing the carABCDEFGH operon. Mutants exhibiting increased carbapenem gene transcription were positively selected using an engineered strain with a functional -lactamase translational fusion in carH, the last gene of the operon. However, spontaneous ampicillin-resistant mutants were isolated even when transcription of carH : : blaM was blocked by a strongly polar mutation in carE. The mechanism of resistance was shown to be due to cryptic IS10 elements transposing upstream of carH : : blaM, thereby providing new promoters enabling carH : : blaM transcription. Southern blots showed that IS10 was present in multicopy in ATTn10. In addition, a Tn10 genetic remnant was discovered. The results offer insights into the genetic archaeology of strain ATTn10 and highlight the powerful impacts of cryptic IS elements in bacterial adaptive evolution.

	INTRODUCTION

TOP ABSTRACT INTRODUCTION METHODS RESULTS AND DISCUSSION REFERENCES

 
Erwinia carotovora subsp. carotovora (Ecc) strain ATCC 39048 is a Gram-negative phytopathogenic member of the Enterobacteriaceae and a causal agent of potato soft rot. In our earlier development of genetic analysis tools for this strain, Tn10 was introduced by : : Tn10 mutagenesis into the genetically ‘virgin’ version of ATCC 39048, in the selection of a mutant defective in the endogenous DNA restriction system (McGowan et al., 1996). This restrictionless mutant strain was then subjected to fusaric acid eduction (Bochner et al., 1980) to yield the tetracycline (Tc)-sensitive derivative strain ATTn10, which was still restrictionless (McGowan et al., 1996). ATTn10 has subsequently been studied as a model genetically tractable phytopathogen with which to understand the regulation of bacterial virulence factors involved in plant disease.

ATTn10 is known to express the carABCDEFGH gene operon, which enables production of the -lactam antibiotic 1-carbapen-2-em-3-carboxylic acid (carbapenem, Car) (McGowan et al., 1996; reviewed by Coulthurst et al., 2005). The first three genes, carABC, are essential for Car biosynthesis (McGowan et al., 1997). carDE are also involved in Car biosynthesis, but are not essential, because when they are disrupted by in-frame deletions, Car is still produced, though at a reduced level. carFG are involved in Car intrinsic resistance via an uncharacterized, novel mechanism (McGowan et al., 1997). The presence of carFG does not confer cross-resistance to related -lactam antibiotics such as imipenem (McGowan et al., 1997). CarF and CarG both contain predicted signal peptides that direct their export to the periplasm (McGowan et al., 1997). The carH gene product has no known function, but is also exported to the periplasm (McGowan et al., 1997).

It has been shown recently that the ATTn10 carABCDEFGH gene cluster contains two promoters (McGowan et al., 2005). The first promoter (P1) is located immediately upstream of carA. Transcription from P1 is increased by the presence of the quorum-sensing signal molecule, N-(3-oxohexanoyl)-L-homoserine lactone (OHHL), produced by the CarI enzyme (McGowan et al., 1996). The OHHL signal molecule interacts with CarR with a dissociation constant of 1·8 µM (Welch et al., 2000). It is thought that the CarR : OHHL complex activates transcription of the carABCDEFGH operon, and that this leads to production of Car (McGowan et al., 1997). The second promoter (P2) is located within carD and is not regulated by quorum sensing (McGowan et al., 2005). P2 is a weak promoter that allows low levels of expression of a carG : : lacZ transcriptional fusion (McGowan et al., 2005). P2 is presumed to maintain auto-resistance to leaky production of Car by an individual cell or by its neighbours.

The aim of this research was to create and exploit a strain with a -lactamase translational fusion in the carH gene to enable the positive selection of mutants exhibiting increased transcription of the carABCDEFGH operon. We presumed that these spontaneous mutants would have point mutations within the P1 and P2 promoters that would lead to increased expression of the carABCDEFGH genes. In addition, we predicted that we might isolate a class of mutants with extra-operonic mutations defining new genes involved in carbapenem operon regulation. However, our results were surprisingly unexpected, and led to the discovery that Tn10 had not been entirely lost from the ATTn10 genome, highlighting the powerful role of mobile genetic elements in the adaptive evolution of bacteria that are challenged by a potentially lethal chemical selection pressure.

	METHODS

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Bacterial strains, plasmids and growth conditions.
All Ecc and Escherichia coli strains, bacteriophage and plasmids used in this study are listed in Table 1. Strains were routinely grown on Luria–Bertani broth agar (LBA) (Miller, 1972), at 30 °C for Ecc strains and 37 °C for E. coli strains, supplemented with antibiotics, as necessary. Liquid cultures of Ecc were grown in sterile conical flasks containing one-tenth volume Luria–Bertani broth (LB) at 30 °C at 300 r.p.m. in shaking water baths.

pir

Unfortunately, sequencing revealed that bp 823 of the original EZ TnBlaM transposon DNA was a cytosine residue rather than the documented thymine residue listed in the manufacturer's manual. This single base pair alteration had the effect of altering the blaM TAA stop codon to a CAA codon encoding glutamine. Furthermore, this base pair alteration extended the ORF of the blaM gene by an additional 23 codons.

To correct the T-C base pair alteration, a PCR strategy was devised. Briefly, primers CarF5' and INBlaM3' were used to amplify carFG, carH' : : blaM from pSMG45HBlaMCAA+ using the Hi Fi PCR kit supplied by Roche. The PCR product was digested with SpeI and KpnI and cloned into the 5·0 kb pSMG45HBlaMCAA+ SpeI/KpnI band to generate the plasmid pSMG45HBlaMTAA+. CC118pir (pSMG45HBlaMTAA+) grown on LBA had a MIC >500 µg Ap ml^–1, whilst CC118pir (pSMG45HBlaMCAA+) had an MIC of <50 µg Ap ml^–1, confirming that the altered stop codon was dramatically influencing CarHBlaM -lactamase activity in E. coli (data not shown).

Marker exchange.
Engineering of carE : : and carH : : blaM was carried out using the pKNG101-derived plasmids pSMG112 and pKNG101HBlaMTAA–, respectively, as described previously (Kaniga et al., 1991). To avoid selecting for unwanted mutations during the marker exchange process that could lead to enhanced -lactamase activity from the carH : : blaM mutation, Ap was not used to select for colonies containing the carH : : blaM marker. Instead, sucrose-resistant, streptomycin (Sm)-sensitive colonies were screened by patching onto LBA and LBA plus 5 µg Ap ml^–1. Any colonies that were able to grow on the LBA plus 5 µg Ap ml^–1 plates were then picked from the LBA-only plate, and the presence of the carH : : blaM marker was confirmed by PCR analysis.

Carbapenem plate assays.
Carbapenem production assays on overnight cultures of Ecc samples were carried out as described previously (McGowan et al., 1996), using the -lactam sensor strain ESS. The only alteration was that, in some experiments, freshly prepared stock solutions of clavulanate were added to the LBA overlay to the desired final concentration to inhibit carH : : blaM -lactamase activity (Reading & Cole, 1977).

Nitrocefin-based -lactamase assays.
Expression of carH : : blaM throughout growth was assayed using the chromogenic substrate nitrocefin (GlaxoSmithKline). Aliquots (1 ml) were extracted from liquid cultures of Ecc and resuspended in phosphate buffer, pH 7·0. The samples were then sonicated on ice for a total time of 3 min and 45 s, composed of eight 15 s periods of sonication with 15 s gaps between them. Cell debris was pelleted using a benchtop centrifuge at 13 000 r.p.m. for 5 min. To 800 µl of the sample incubated at 30 °C, 20 µl of 4 mg nitrocefin ml^–1 stock solution was added, and the change in OD₅₅₀ was recorded in a spectrophotometer over time and recorded relative to the OD₆₀₀ of the culture at each time-point.

Southern blotting using DIG-labelled probes.
Southern blotting experiments were carried out using standard procedures (Sambrook et al., 1989). DIG-labelled probes hybridizing to IS10 and jemC were created by PCR using the DIG-labelled dNTP mix supplied by Roche. The IS10 probe was PCR-amplified using primers IS105'2 and IS103'. DIG-labelled probes were detected using FAb fragments supplied by Roche. Peroxidase activity was detected using the CDP-star kit supplied by Roche.

	RESULTS AND DISCUSSION

TOP ABSTRACT INTRODUCTION METHODS RESULTS AND DISCUSSION REFERENCES

 
CarHBlaM is functionally expressed in Ecc throughout growth
A carH : : blaM translational fusion was constructed in the ATTn10 carA–H operon by marker exchange to generate strain SBE1 (Fig. 1b). To test whether the CarHBlaM protein was functional in vivo, ATTn10 and SBE1 Car production was assessed by spotting cultures onto ESS overlays supplemented with clavulanate (Fig. 2). Clavulanate was used to inhibit the -lactamase activity (Reading & Cole, 1977) conferred by CarHBlaM. In the absence of clavulanate, the zone of clearing on the ESS lawn around SBE1 was reduced compared to that of ATTn10 (Fig. 2a). However, addition of clavulanate to the ESS overlays restored the size of the Car haloes around SBE1 to the same as that of ATTn10 (Fig. 2b–e). These results confirmed that i) SBE1 was producing the same levels of Car as that of ATTn10, and ii) the CarHBlaM -lactamase was functional, as it could hydrolyse Car unless excess clavulanate was present as a competitive inhibitor.

View larger version (22K): [in this window] [in a new window]   Fig. 1. (a) Diagrammatic representation of the carA–H cluster in ATTn10. The P1 promoter enables transcription of carA–H and is regulated by the CarIR quorum-sensing system (McGowan et al. 1996). The P2 promoter is located within carD and enables weak expression of CarEFGH. (b) The carA–H cluster in SBE1 has a -lactamase translational fusion in the carH gene. (c) SBE7 has an identical carA–H gene cluster to that of SBE1, except that an interposon in carE prevents expression of CarF, CarG and CarHBlaM from the P1 and P2 promoters.

View larger version (92K): [in this window] [in a new window]   Fig. 2. Clavulanate inhibits carbapenem degradation by CarHBlaM -lactamase activity. Spots of ATTn10 (left hand side of each plate) and SBE1 (right hand side of each plate) were added to 0·7 % Luria broth top agar, which had been seeded with the -lactam sensor strain ESS, containing increasing concentrations of clavulanate: (a) 0 µg clavulanate ml–1, (b) 5 µg clavulanate ml–1, (c) 10 µg clavulanate ml–1, (d)25 µg clavulanate ml–1 and (e) 50 µg clavulanate ml–1, and incubated overnight at 30 °C. The zones of clearing are proportional to the levels of carbapenem secreted by ATTn10 and SBE1.

View larger version (11K): [in this window] [in a new window]   Fig. 3. Detection of -lactamase activity throughout growth using the chromogenic cephalosporin nitrocefin. The following are shown: log OD600 of SBE1 (diamonds, solid line) and SBE7 (triangles, solid line) grown at 30 °C in Luria broth at 300 r.p.m. in shaking water baths; -lactamase activity of SBE1 (diamonds, broken line) and SBE7 (triangles, broken line) throughout growth.

The carH : : blaM fusion strain can give rise to ampicillin-resistant mutants, despite the interposon insertion
The survival frequency of ATTn10 and SBE1 in response to increasing concentrations of Ap is recorded in Fig. 4. As a negative control we also included Ecc strain SBE7, which cannot transcribe the carH : : blaM gene because of the carE : : mutation, as described above. Surprisingly, SBE7 had an e.o.p. on LBA supplemented with 5 µg Ap ml^–1 of 1x10^–5, which was significant, because ATTn10 could not grow on this medium. Ecc growth on LBA supplemented with 25 µg Ap ml^–1 was undetectable after 24 h at 30 °C, with the exception of SBE1, which had an e.o.p. of 1x10^–7 relative to that in the absence of Ap.

View larger version (11K): [in this window] [in a new window]   Fig. 4. Survival efficiency of SBE1 (black bars), SBE7 (grey bars) and ATTn10 (white bars) in response to different Ap concentrations.

Expression of CarHBlaM can occur spontaneously in SBE7 because of the action of mobile DNA providing functional promoters
To determine the nature of the SBE7 Ap^R mutants, 10 of the colonies (SBE7 5.1–5.10) that grew on 5 µg Ap ml^–1 were selected at random for further investigation. The most likely explanation for Ap^R in SBE7 5.1–5.10 was that a genetic alteration (presumably insertions or deletions) had occurred immediately upstream of carH : : blaM. Therefore, the region between carH : : blaM and carE : : in these mutants was amplified by PCR analysis using primers Sp2 and BlaRP1 (Fig. 5a). It was clear that, in the Ap^R SBE7 mutants, the size of the 1871 bp region (Fig. 5a, lane F) between carH : : blaM and carE : : had increased. In most cases, the increase in size was approximately 1·3 kb. In the case of SBE7 5.5, the increase in size was approximately 1·8 kb (Fig. 5a, lane E). Sequencing of four of the PCR products from SBE7 5.1 to 5.4 revealed that IS10R from the transposon Tn10 had inserted in the region between carH : : blaM and carE : : (Fig. 5b). The site of the IS10 insertion in strains SBE7 5.1, 5.3 and 5.4 was identical in each case, suggesting that they could be siblings. In all cases, the IS10R P_out promoter was orientated in the correct direction to enable transcription of the downstream carH : : blaM gene (Fig. 5c). Previous data has shown that both IS10 elements possess a fairly strong P_out promoter (Simons et al., 1983) that is capable of allowing expression of adjacent ORFs (Ciampi et al., 1982). It seems that, due to these random insertions, the P_out promoter from IS10 has enabled SBE7 5.1–5.10 to drive transcription of the otherwise cryptic carH : : blaM fusion.

View larger version (78K): [in this window] [in a new window]   Fig. 5. (a) Colony PCR analysis of the following strains using primers BlaRP1 and SP2: A, SBE7 5.1; B, SBE7 5.2; C, SBE7 5.3; D, SBE7 5.4; E, SBE7 5.5; F, SBE7; G, SBE7 5.6; H, SBE7 5.7; I, SBE7 5.8; J, SBE7 5.9; K, SBE7 5.10. The lanes designated M are GibcoBRL Life Sciences 1 kb ladders. (b) Diagrammatic representation of IS10R transposition upstream of carH : : blaM but downstream of carE : : , leading to the IS10R Pout promoter becoming correctly orientated to enable transcription of carH : : blaM. (c) The DNA sequence of carF and carG from GenBank accession number U17224. Boxed ‘atg’ sequences indicate the start codons of carF and carG. The stop codons for carF and carG are underlined and in italics. The bold sequences in upper-case type represent the sites of the IS10 insertions in SBE7 5.1–5.5. Three of the mutants, SBE7 5.1, 5.3 and 5.4, had IS10 insertions that duplicated bp 7074–7082. One of the mutants, SBE7 5.2, had an insertion that duplicated bp 6985–6993. The last mutant, SBE7 5.5, had an enlarged IS10 insertion that duplicated bp 6832–6840.

Transposon Tn10 has been extensively degraded in the ATTn10 genome
Mutant SBE7 5.5 was particularly interesting, because the PCR product from this mutant was enlarged by approximately 1·8 kb instead of 1·3 kb (Fig. 5a, lane E). Sequencing of the enlarged PCR product showed that this mutant contained genetic remnants of Tn10 orientated such that the IS10L end was closest to carH : : blaM. In SBE7 5.5, transcription of carH : : blaM appears to be from the P_out promoter of IS10L, as this promoter is in the correct orientation. The Tn10 sequence in this IS element was severely degraded, however, by the presence of two large deletions in its sequence (Fig. 6). Both deletions are defined by the Tn10 sequence accession number AF162223 (Chalmers et al., 2000), and are as follows: deletion 1 removes bp 340–4426, which includes most of IS10L and ends in the 5' end of jemC, removing jemAB in the process; deletion 2 removes bp 4698–7818. Deletion 2 removes the 3' end of the jemC gene and the entire tetRACD gene cluster, and ends precisely at the point at which the IS10R inverted repeat sequence begins. This 1939 bp Tn10 genetic remnant will from now on be referred to as Tn10.

View larger version (24K): [in this window] [in a new window]   Fig. 6. (a) Diagrammatic representation of the regions of Tn10 that have been deleted in Tn10. Genes and IS10 elements are represented as grey rectangles; deletions are represented as black rectangles. (b) Representation of Tn10 insertion upstream of carH : : blaM in Ecc strain SBE7 5.5. Transcription of carH : : blaM is likely to occur from the Pout promoter of the IS10L fragment within Tn10 which is represented by a black bent arrow. All genes are drawn approximately to scale, with the exception of carH : : blaM.

Deletion 2 terminates with a 5 bp imperfect direct repeat, ATGC(T/A), and therefore may have formed by a strand misalignment mechanism (Farabaugh et al., 1978; Albertini et al., 1982; Singer & Westlye, 1988; Marvo et al., 1983; Uematsu et al., 1999). However, the direct transition of the IS10R inverted repeat sequence that defines the boundaries of the mobile genetic element to the site of a deletion is characteristic of an IS10 adjacent deletion, as described elsewhere (Roberts et al., 1991; Chalmers & Kleckner, 1996). It seems very likely that deletion 2 has been generated by an IS10-mediated adjacent deletion. Two lines of evidence support this hypothesis: i) deletion 2 is immediately flanked at the 3' end by the IS10 inside end, and ii) deletion 2 is immediately flanked at the 5' end by a 5'-GGTTATGCT-3' sequence which closely matches the 5'-NGCTNAGCN-3' IS10 transposition consensus sequence (Halling & Kleckner, 1982).

The Tc^S phenotype of the ATTn10 strain can be explained by the presence of deletion 2. This is because deletion 2 has led to the complete loss of the tetRACD gene cluster from Tn10. Furthermore, a Southern blot to probe for jemC in ATTn10 genomic DNA cut with BsiEI, which cuts either end of Tn10, generated only one hybridizing band that corresponded to the size expected for Tn10, confirming that the tetRACD and jemAB genes are absent in the ATTn10 genome (data not shown). Deletion 2 would offer a selective advantage when Tn10-containing strains were exposed to fusaric acid because it removes the tetA gene that encodes the TetA efflux pump which confers fusaric acid sensitivity. An example of how fusaric acid treatment can lead to the generation of hybrid IS elements in strains containing Tn10 has been documented in E. coli (Bogosian et al., 1993). The IS10R fusion in the strain under study generated a 1329 bp element (designated IS10L/R1) that contained sequence from IS10R as well as sequence from IS10L. The Tn10 element isolated in strain SBE7 5.5 is a new example of how the strong selection pressure exacted by fusaric acid treatment of Tn10-containing strains can encourage the evolution of novel, hybrid IS elements.

ATTn10 contains multiple copies of IS10
Genomic DNA from SBE7, SBE9 and SBE7 5.1–5.10 was analysed by Southern blot experiments using DIG-labelled probes to the transposase gene of IS10 (Fig. 7). No hybridizing bands were detected in SBE9 DNA. SBE9 is not derived from ATTn10, and therefore has never been exposed to Tn10. However, it was clear from the SBE7 sample, which does derive from ATTn10, that there were at least 15 independent hybridizing bands. A band approximately 6·8 kb in size, corresponding to an IS10 insertion in carFG, was present in all the Ap^R SBE7 mutants except SBE7 5.5 (Fig. 7), supporting the PCR and DNA sequencing data (Fig. 5). A band at the predicted 7·4 kb was present in the SBE7 5.5 genomic DNA sample, but this co-migrated with at least one other band that was present in SBE7 and all the derived mutant strains. The 7·4 kb band was more distinguishable in SBE7 5.5 than in the other strains when probing for the presence of jemC (data not shown).

View larger version (89K): [in this window] [in a new window]   Fig. 7. Southern blot to detect the IS10 transposase gene from chromosomal DNA of several Ecc strains digested with AatII. The lanes are as follows: A, SBE7 5.1; B, SBE7 5.2; C, SBE7 5.3; D, SBE7 5.4; E, SBE7 5.5; F, SBE7; G, SBE9; H, SBE7 5.6; I, SBE7 5.7; J, SBE7 5.8; K, SBE7 5.9; L, SBE7 5.10. All marker band sizes are approximate values. The dashed arrow shows the predicted 6·8 kb band that corresponds to an IS10 insertion in carFG in SBE7, which is also indicated with a circle inlane H. Examples of unique IS10 hybridizing bands present in some of the SBE7 ampicillin-resistant mutants are boxed within rectangles.

It is possible to differentiate SBE7 5.1–5.10 from each other by the number and size of their IS10R hybridizing bands, which in many cases were different from each other. As an example, SBE7 5.10 contains an easily distinguishable hybridizing band at around 2·2 kb that is absent in SBE7 and the rest of the Ap^R SBE7 mutants. Whether these IS10 hybridizing bands were generated before or after selection on Ap is not known. It has been shown that growth in the presence of -lactams can induce the SOS response (Miller et al., 2004). The SOS response in turn has been shown to induce IS10 transposition (Eichenbaum & Livneh, 1998). Therefore, any colonies that are initially able to grow in the presence of Ap may undergo increased rates of IS10R transposition that may explain the high level of heterogeneity among SBE7 5.1–5.10.

One observation from Fig. 7 is that none of the IS10 hybridizing bands present in the SBE7 parental strain is absent in SBE7 5.1–5.10. As IS10R has been shown previously to transpose by a non-replicative mechanism (Bender & Kleckner, 1986; Kleckner et al., 1995), it seems clear that during transposition, IS10R is maintained in our strains at the donor molecule site. Mechanisms for how this can occur have been described elsewhere (Bender et al., 1991), and our results agree with a model in which intramolecular rejoining to lose IS10R from the donor molecule site is an uncommon event.

Final summary
This research has generated a functionally expressed -lactamase translational fusion in carH, and shown that in the absence of a functional promoter, this construct can serve as an effective mobile promoter trap. This has led to the identification of cryptic IS10 elements in the ATTn10 chromosome. This finding was initially surprising, as it was assumed that IS10 might have been lost from the chromosome during fusaric acid treatment to cure Tn10-dependent Tc^R in the progenitor strain. This promoter trap offered insights into the molecular events that may have led to ATTn10 Tc^S with the discovery of the Tn10 genetic remnant Tn10 in the SBE7 Ap^R mutant SBE7 5.5. Southern blot experiments subsequently demonstrated that ATTn10 contains at least 15 copies of IS10. These data show that ATTn10 may be a useful model strain in which to study adaptive evolution, and our recent observations that ATTn10 may be hypermutable are consistent with this notion (S. D. Bowden and G. P. C. Salmond, unpublished data).

	ACKNOWLEDGEMENTS

 
This work was carried out under DEFRA licence number PHL 177A/4995 (01/2005) and funded by a BBSRC research grant. We would also like to thank Mr Ian Foulds for excellent technical support.

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Received 6 October 2005; revised 12 December 2005; accepted 14 December 2005.

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