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Journal of Bacteriology, February 2008, p. 1488-1490, Vol. 190, No. 4
0021-9193/08/$08.00+0     doi:10.1128/JB.01290-07
Copyright © 2008, American Society for Microbiology. All Rights Reserved.

A Transposase-Independent Mechanism Gives Rise to Precise Excision of IS256 from Insertion Sites in Staphylococcus epidermidis ^,

Susanne Hennig and Wilma Ziebuhr^*

Universität Würzburg, Institut für Molekulare Infektionsbiologie, Röntgenring 11, 97070 Würzburg, Germany

Received 9 August 2007/ Accepted 27 November 2007

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The mobile element IS256 causes phase variation of biofilm formation in Staphylococcus epidermidis by insertion and precise excision from the icaADBC operon. Precise excision, i.e., removal of the target site duplications (TSDs) and restoration of the original DNA sequence, occurs rarely but independently of functional transposase. Instead, the integrity of the TSDs is crucial for precise excision. Excision increased significantly when the TSDs were brought into closer spatial proximity, suggesting that excision is a host-driven process that might involve most likely illegitimate recombination.

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IS256 is an insertion sequence (IS) element occurring in the genomes of staphylococci and enterococci, either as an integral part of the composite transposon Tn4001 or in multiple free copies (3, 6, 17). Recent studies indicate that IS256 is particularly common in the genomes of multiresistant, biofilm-forming Staphylococcus epidermidis isolates resident in the hospital environment (13). S. epidermidis biofilm formation is mediated mainly by a polysaccharide intercellular adhesin (PIA) (16), whose synthesis enzymes are encoded by the icaADBC operon (11). We demonstrated earlier that ica operon expression and subsequent biofilm formation are subject to phenotypic variation (18). In approximately 30% of spontaneous biofilm-negative variants, the switch from on to off in biofilm formation is caused by insertion of IS256 into icaA or icaC (19). Typically, IS256 creates 8-bp target site duplications (TSDs) on either end upon active transposition. Reversion from off to on was detected after repeated passages of S. epidermidis ica::IS256 insertion mutants (19). Interestingly, restoration of PIA production was accompanied by precise excision of IS256, including the initially duplicated target site, from the ica sequence (19). While the insertion frequency of IS256 into the ica operon is about 10^–6 per cell generation, the excision frequency was reported to be considerably lower, at <10^–8 per cell generation, indicating that restoration of the PIA-mediated biofilm by IS excision must be a rare event (19). However, the molecular mechanism of precise excision—complete elimination of IS256, including the duplicated target site, and restoration of the original ica sequence—has not been elucidated so far.

Precise excision of IS256 from the icaC gene does not require a functional IS256 transposase. To test whether precise excision of IS256 from the ica operon is a transposase-driven process, we constructed two mutants of the biofilm-positive, IS256-negative strain S. epidermidis CSF41498 (Table 1). The first mutant, S. epidermidis CSF41498-1, carried a chromosomal copy of a previously described icaC::IS256 insertion (14), including an 8-bp TSD (GGTGGTTA), while the second, S. epidermidis CSF41498-2, carried an icaC::IS256 insertion with a 20-bp deletion within the tnp gene, rendering the transposase inactive (Table 1) (14). Both mutants exhibited a biofilm-negative phenotype. Since it was known from previous experiments that precise excision is a rare event (19), biofilm-positive revertants were enriched by serial passages in tissue culture flasks as described previously (19), with the following modification: at each passage step (every 24 h), the medium was discarded and flasks were washed with phosphate-buffered saline before new Trypticase soy broth was added. After 7 to 14 days, the adhering bacterial cells were scratched from the bottom and appropriate dilutions were plated onto Congo red agar (CRA). In all of three independent experiments, revertants could be detected as rough and black colonies on CRA, for both CSF41498-1 and CSF41498-2. Further analyses of these revertants by PCR using icaC-specific primers and by nucleotide sequencing revealed that the majority of them still carried the IS256 insertion (12), while others had lost the IS element completely and restored the original icaC sequence. IS256- and icaC-specific Southern hybridizations of eight members of the latter group demonstrated that the removal of the element was not accompanied by new IS256 insertions in the S. epidermidis chromosome (Fig. 1A and B). These results suggest that precise IS256 excision is not associated with transposition but is mediated by a transposase-independent mechanism.

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TABLE 1. Strains and plasmids used in this studya

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FIG. 1. Genetic analysis of biofilm-forming revertants derived from S. epidermidis CSF41498 icaC::IS256 insertion mutants. Southern hybridizations of EcoRI-restricted chromosomal DNA were performed using icaC-specific (A) and IS256-specific (B) DNA fragments as probes (19). Lanes 1, S. epidermidis RP62A; lanes 2, S. epidermidis CSF41498 wild type; lanes 3, S. epidermidis CSF41498-1; lanes 4, S. epidermidis CSF41498-2; lanes 5 to 8, S. epidermidis CSF41498-1-derived revertants; lanes 9 to 12, S. epidermidis CSF41498-2-derived revertants.

Alteration of TSD homology abolishes precise excision. In the next step, we tested whether precise excision from the chromosome might occur as a result of a recombination process, with the 8-bp TSDs serving as homologous regions. To answer this question, we introduced a 3-bp deletion (GGT) into the right TSDs of CSF41498-1 and CSF41498-2, thereby reducing the homology between the TSDs to 3 bp (GGTGGTTA/GGTTACAT). After serial passages of the corresponding mutant strains CSF41498-3 and CSF41498-4 (Table 1), biofilm-positive revertants were isolated as black, rough colonies on CRA. However, despite extensive PCR screening in seven independent experiments, we could not detect precise excision of IS256 in any of the biofilm-forming revertants. Analyses of these strains indicated that they had switched from PIA-mediated biofilm formation to the expression of a protein-mediated biofilm, which is described elsewhere (12). Our data demonstrate that a reduction of TSD homology abolishes precise excision or at least diminishes the process to a point below the detection limit of this experimental setup.

Quantification of IS256 excision events. To quantify the rate of excision events, we constructed shuttle plasmid pTH1, carrying a spectinomycin resistance cassette (spc) inactivated by an artificial IS256 insertion, including 8-bp TSDs (Table 1). The plasmid was transformed into the spectinomycin-sensitive S. epidermidis CSF41498 background, and the resulting strain was screened for the occurrence of spectinomycin-resistant colonies that had lost the IS256 insertion. This positive selection approach allowed us to analyze a considerably larger number of colonies than in the previous approach and to calculate the precise excision rates per cell and generation. The data underline that precise excision is a rare event, on the order of magnitude of 10^–11 per cell and generation when using vector pTH1 (Table 2). This low excision rate suggests that a host-mediated recombination process is behind precise IS256 excision. Also, Southern blot analysis revealed no new IS256 insertions in the chromosome in these strains (data not shown).

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TABLE 2. Excision rates of IS256 from the spc gene, using a plasmid-based system

Next, we wanted to analyze the minimal homology requirement of the IS256 TSDs for precise excision. Therefore, we introduced deletions into the right-hand TSD of spc::IS256, leading to mismatches of two, three, and four base pairs and resulting in plasmids pTH3, pTH4, and pTH5, respectively (Table 1). No precise excision event was detected in any of the TSD mutants, and the probability of precise IS256 excision was calculated to be <10^–13 per cell and generation (Table 2).

These data support the hypothesis that the microhomologies at either end of the element are a necessary prerequisite for excision. At the present stage of experimental work, we cannot decide unambiguously how TSD-dependent IS256 excision proceeds on the molecular level. However, the data collected so far strongly imply a host-mediated recombination process as the underlying mechanism. Since RecA-dependent recombination requires sequence homologies of 300 bp or more and site-specific recombination relies on site-specific integrases along with defined DNA recognition sites (2, 10), it is rather unlikely that one of these mechanisms mediates precise IS256 excision. In contrast, illegitimate recombination by so-called replicational slippage would provide a model for this phenomenon. Precise excision was described for other transposons as well (5, 9), and for Tn10, replicational slippage was suggested to be the underlying mechanism (7). Replicational slippage requires short homologous DNA stretches located in close vicinity to each other on the same DNA molecule. In Escherichia coli, eight nucleotides appears to be the minimal length required for slippage (1, 8), and slight sequence differences were already shown to reduce the deletion frequency dramatically (15). The same seems to hold true for IS256 in S. epidermidis in this report, as eight homologous base pairs was sufficient for precise excision, while reduction to six base pairs abolished the process to a point below the detection limit.

Narrowing the distance between the TSDs results in an increase of precise excision rates. Last, we tested whether the spatial distance between the target site homologies has an impact on excision frequencies. To this end, we constructed pTH2 (Table 1). In this case, we truncated the IS256 copy on pTH1 considerably, leaving only the noncoding regions (NCRs) of the element on either end (containing the left and right inverted repeats [IR_L and IR_R, respectively]) as well as the 8-bp TSDs intact, separated by 166 bp of DNA consisting of the 101-bp left NCR, a 15-bp transposase gene remnant, and the 50-bp right NCR. The excision frequency of this truncated IS256 version in pTH2 (Table 2) showed a significant increase compared to that for pTH1 carrying a full-length IS256 copy (one-tailed Mann-Whitney U test; P < 0.025). From other studies, it is known that a decrease of the distance between repeats increases replicational slippage rates significantly (2, 4). Apparently, this also applies to IS256. Thus, the model of replicational slippage provides an interesting hypothesis for future experimental work to investigate precise IS256 excision in molecular detail.

Concluding remarks. Our data substantiate that IS256-mediated phase variation involves two distinct processes, namely, transposition of IS256 and transposase-independent precise excision. The frequencies of these processes differ dramatically, by at least 5 orders of magnitude, with precise excision being an extremely rare event. Interestingly, we found that with respect to biofilm formation, S. epidermidis CSF41498 is obviously able to compensate for the low reversion rate due to precise excision by frequent switching to an alternative, protein-mediated biofilm, highlighting again the functional importance of the biofilm lifestyle for S. epidermidis (12). Thus, the latter mechanism appears to be of more biological significance than precise excision of IS256. Taken together, the data obtained in this study add to our understanding of IS activity and function in bacterial genomes and their impact on the generation of genetic and phenotypic variety.

 
We are grateful to Katja Dietrich, Elena Katzowitsch, and Katharina Schlereth for excellent technical assistance, and we thank James P. O'Gara (University College Dublin, Ireland) for providing strain Staphylococcus epidermidis CSF41498.

This study was funded by Deutsche Forschungsgemeinschaft grants IGK 587/2, SFB479, and SFB/TR34 as well as by the Federal Ministry of Education and Research (Network Pathogenomics-Plus; grant PTJ-BIO//03U213B).

 
* Corresponding author. Present address: School of Biomedical Sciences, The Queen's University of Belfast, 97 Lisburn Road, Belfast BT9 7BL, Northern Ireland, United Kingdom. Phone: 44 (1)28-9097-2073. Fax: 44 (1)28-9097-2124. E-mail: w.ziebuhr{at}qub.ac.uk

Published ahead of print on 7 December 2007.

Supplemental material for this article may be found at http://jb.asm.org/.

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Journal of Bacteriology, February 2008, p. 1488-1490, Vol. 190, No. 4
0021-9193/08/$08.00+0     doi:10.1128/JB.01290-07
Copyright © 2008, American Society for Microbiology. All Rights Reserved.

This Article Abstract Full Text (PDF) Supplemental material Alert me when this article is cited Alert me if a correction is posted Services Similar articles in this journal Similar articles in PubMed Alert me to new issues of the journal Download to citation manager Reprints and Permissions Copyright Information Books from ASM Press MicrobeWorld Citing Articles Citing Articles via Google Scholar Google Scholar Articles by Hennig, S. Articles by Ziebuhr, W. Search for Related Content PubMed PubMed Citation Articles by Hennig, S. Articles by Ziebuhr, W.