- Research article
- Open Access
Characterization of a novel chaperone/usher fimbrial operon present on KpGI-5, a methionine tRNA gene-associated genomic island in Klebsiella pneumoniae
© van Aartsen et al; licensee BioMed Central Ltd. 2012
- Received: 30 October 2011
- Accepted: 20 April 2012
- Published: 20 April 2012
Several strain-specific Klebsiella pneumoniae virulence determinants have been described, though these have almost exclusively been linked with hypervirulent liver abscess-associated strains. Through PCR interrogation of integration hotspots, chromosome walking, island-tagging and fosmid-based marker rescue we captured and sequenced KpGI-5, a novel genomic island integrated into the met56 tRNA gene of K. pneumoniae KR116, a bloodstream isolate from a patient with pneumonia and neutropenic sepsis.
The 14.0 kb KpGI-5 island exhibited a genome-anomalous G + C content, possessed near-perfect 46 bp direct repeats, encoded a γ1-chaperone/usher fimbrial cluster (fim2) and harboured seven other predicted genes of unknown function. Transcriptional analysis demonstrated expression of three fim2 genes, and suggested that the fim2A-fim2K cluster comprised an operon. As fimbrial systems are frequently implicated in pathogenesis, we examined the role of fim2 by analysing KR2107, a streptomycin-resistant derivative of KR116, and three isogenic mutants (Δfim, Δfim2 and ΔfimΔfim2) using biofilm assays, human cell adhesion assays and pair-wise competition-based murine models of intestinal colonization, lung infection and ascending urinary tract infection. Although no statistically significant role for fim2 was demonstrable, liver and kidney CFU counts for lung and urinary tract infection models, respectively, hinted at an ordered gradation of virulence: KR2107 (most virulent), KR2107∆fim2, KR2107∆fim and KR2107∆fim∆fim2 (least virulent). Thus, despite lack of statistical evidence there was a suggestion that fim and fim2 contribute additively to virulence in these murine infection models. However, further studies would be necessary to substantiate this hypothesis.
Although fim2 was present in 13% of Klebsiella spp. strains investigated, no obvious in vitro or in vivo role for the locus was identified, although there were subtle hints of involvement in urovirulence and bacterial dissemination from the respiratory tract. Based on our findings and on parallels with other fimbrial systems, we propose that fim2 has the potential to contribute beneficially to pathogenesis and/or environmental persistence of Klebsiella strains, at least under specific yet-to-be identified conditions.
- Genomic Island
- Fosmid Library
- Bladder Epithelial Cell
- Isogenic Mutant
- Major Fimbrial Subunit
Klebsiella pneumoniae is a Gram negative member of the Enterobacteriaceae family that commonly causes nosocomial pneumonia, bacteriaemia, urinary tract infections and wound infections . In recent years the treatment of K. pneumoniae infections has become more challenging due to the greater prevalence of multiple antibiotic resistant strains [2, 3]. Moreover, hypervirulent, pyogenic liver abscess-causing K. pneumoniae strains that infect otherwise healthy individuals have emerged from initial endemic foci in Taiwan and China, and are now spreading into North America and Europe [4–6]. This highlights the increasing threat that K. pneumoniae poses to public health and the importance of elucidating its mechanisms of pathogenesis.
Most K. pneumoniae strains possess a thick polysaccharide capsule which is involved in protection from opsonisation and phagocytosis and is a well recognized in vivo virulence factor . Various studies have also highlighted roles for surface-exposed lipopolysaccharides, multiple iron acquisition systems and adhesins in K. pneumoniae infection [1, 7, 8]. Several strain-specific virulence determinants of the pyogenic liver abscess-associated isolate K. pneumoniae NTUH-K2044 have been well characterised [9–11]. However, the functions of strain-specific genomic regions in K. pneumoniae strains associated with other types of infection remain poorly studied.
Comparative analyses using computational and in vitro experimental techniques have shown that K. pneumoniae strains possess an extremely plastic genome that consists of a conserved core genome interspersed by strain-specific accessory components [12–15]. This was further highlighted in a recent study which calculated that only 54.7% of known K. pneumoniae genes were shared by three sequenced isolates (Kp342, MGH78578, NTUH-K2044) . Genomic islands (GI), typically ranging from 10 kb to 200 kb in size and frequently inserted within tRNA gene (tRNA) hotspots, comprise a substantial proportion of the accessory genome. GI acquisition offers an efficient ‘quantum leap’ based route to gaining virulence factors, antibiotic resistance determinants and/or metabolic pathways pre-tailored for the exploitation of new environments [16, 17].
Epidemiological studies have suggested that K. pneumoniae infections are preceded by colonization of the gastrointestinal tract . Adhesion and colonization are essential steps in the infection process and are often mediated by fimbriae, which are small hair-like extensions on the bacterial cell surface that can interact with other surfaces via tip-located adhesin proteins . The majority of environmental and clinical K. pneumoniae isolates are known to express type 1 fimbriae and type 3 fimbriae, which have recently been classified into the γ1 and γ4-fimbrial subgroups using the Nuccio and Bäumler fimbrial classification system, which was created from a large scale phylogenetic analysis of fimbrial usher proteins [20–23]. Recent in vivo experiments have demonstrated a role for K. pneumoniae type 1 fimbriae in urinary tract infections . Although type 3 fimbriae have been shown to enhance biofilm formation and mediate attachment to bladder epithelium in vitro, the role of these structures in vivo has yet to be determined as an isogenic mrk knockout strain was as virulent as its wildtype parent in murine pneumonia and urinary tract infection models [23, 24].
K. pneumoniae type 1 and type 3 fimbriae are both thought to assemble via the chaperone/usher (CU) assembly pathway which has been characterised in detail for the archetypal E. coli type 1 and P fimbriae . Some CU fimbriae, such as the Kpc fimbriae of K. pneumoniae NTUH-K2044, are encoded by only a subset of strains and are thought to potentially correlate with tropism towards particular host tissues and infection types . Many strain-specific fimbriae are encoded on tRNA gene-associated GIs, best illustrated by the saf tcf sef std and stb fimbrial operons of Salmonella enterica serovar Typhi strain CT18. This latter strain encodes an arsenal of twelve putative CU fimbrial operons that are hypothesized to correlate with adaptation to the human host . The genomes of K. pneumoniae Kp342, MGH78578 and NTUH-K2044 contain nine, eleven and eight CU fimbrial operons, respectively, though the originally described type 1 and type 3 fimbrial operons are common to all three . Apart from the serotype K1-associated kpc operon, no studies have investigated the in vitro and/or in vivo role of other K. pneumoniae accessory fimbrial operons. We now describe the identification, genetic characterization and initial functional analysis of a novel CU fimbrial operon (fim2) that is encoded on a previously unidentified GI, KpGI-5, found inserted within the met56 tRNA gene of K. pneumoniae strain KR116.
The KpGI-5 genomic island codes for a novel predicted chaperone/usher fimbrial system
Whilst screening five tRNA gene insertion hotspots in sixteen clinical K. pneumoniae isolates for strain-specific DNA using a technique called tRIP-PCR [13, 14], we found that K. pneumoniae KR116 possessed an ‘occupied’ met56 tRNA locus. tRIP-PCR using primers PR601 and PR647, which were designed to amplify across the met56 tRNA locus, failed to amplify a product in KR116. Single genome-specific primer based walking from the conserved met56 upstream flank yielded ~3 kb of novel sequence.
To capture and sequence this entire strain-specific island, we tagged the known tRNA-proximal arm of the island with a kanamycin resistance cassette using allelic exchange. A fosmid library of this tagged strain (KR116 ∆fim2K::kan) was then created and used to isolate kanamycin resistance cassette-bearing inserts by marker rescue. Two overlapping fosmids, pJFos-1 and pJFos-4, shown by end-sequencing to span the entire strain-specific region were sequenced to define this novel KR116 met56-specific GI that we designated KpGI-5.
BLASTP homologs of proteins predicted to be encoded by KpGI-5
Coding region (bp)
Protein size (aaa)
Percentage identity (aaa)
100% (note: BLASTN)
K. pneumoniae MGH78578
Methionine tRNA [KPN_03476]
C. koseri ATCC BAA-895
Putative EAL domain protein [ABV14791.1]
K. pneumoniae sp15
Fimbrial adhesin (FimH) [ACL13802.1]
C. koseri ATCC BAA-895
Minor fimbrial subunit (FimG) [ABV14789.1]
C. koseri ATCC BAA-895
Minor fimbrial subunit (FimF) [ABV14788.1]
C. koseri ATCC BAA-895
Outer membrane usher protein (FimD) [ABV14787.1]
K. variicola At-22
Fimbrial chaperone protein (FimC) [ADC56706.1]
C. koseri ATCC BAA-895
Fimbrial protein (FimI) [ABV14784.1]
K. pneumoniae MGH 78578
Major fimbrial protein (FimA) [ABR78685.1]
S. aurantiaca DW4/3-1
Putative two component system regulatory protein [EAU69265.1]
S. odorifera DSM 4582
Putative transcriptional regulatory protein [EFE96725.1]
S. odorifera DSM 4582
Hypothetical protein [EFE96270.1]
Klebsiella sp. 1_1_55
Putative GCN5-related N-acetyltransferase [EFD84432.1]
K. pneumoniae 342
Hypothetical protein [ACI07992.1]
12616.. 12359 (234)
K. pneumoniae 342
Hypothetical protein [ACI06987.1]
K. pneumoniae 342
Metallo-beta-lactamase family protein [ACI07748.1]
The 7.9 kb left arm of KpGI-5 harboured a novel eight-gene cluster that exhibited sequence similarity and organizational-identity to the chromosomally-encoded fim operons of Citrobacter koseri ATCC BAA-895 (~60%) and K. pneumoniae C3091 (~51%). This cluster was named fim2. It encoded homologs of all structural and biosynthesis-associated components of the well-characterized C3091 type 1 fimbrial system, including a major fimbrial subunit (Fim2A), three minor fimbrial subunits (Fim2F, Fim2G and Fim2H), and a chaperone (Fim2C) and usher (Fim2D) protein . Downstream of fim2H was fim2K which encoded a FimK homolog that possessed a matching EAL domain but lacked a FimK-equivalent N-terminal helix-turn-helix domain. EAL domains have been implicated in the hydrolysis of c-di-GMP, an intracellular messenger that regulates important cellular functions including different forms of motility, adhesin and exopolysaccharide matrix synthesis, fimbrial expression and virulence [28–32]. Helix-turn-helix domains are associated with binding to specific DNA sequences and in the context of EAL domain-bearing proteins are hypothesized to modulate the c-di-GMP hydrolytic activity of these proteins . Amino acid sequence identities between cognate fim2 and fim products varied from 60 – 92%. However, no homologs of the C3091 fimB fimE or fimS invertible promoter switch could be identified upstream of fim2. K. pneumoniae KR116 also possessed the species-conserved fim and mrk operons, as shown by PCR screening for the fimH and mrkD adhesin genes using primer pairs PR1144-PR1145 and PR1150-PR1151, respectively. Of note, the G + C content of the fim2 operon (47.7%) was much lower than that of the K. pneumoniae fim operon (60.8%) and quite distinct from the G + C content of the four fully sequenced K. pneumoniae genomes (56.9% – 57.4%).
The KpGI-5 fim2 locus is found within several Klebsiella spp. and is globally distributed
To determine the prevalence of fim2 in Klebsiella spp., a total of 162 strains (123 K. pneumoniae, 19 undefined Klebsiella spp., 18 K. oxytoca, one K. ornithinolytica and one K. planticola) isolated from distinct sources were PCR screened for fim2K using primers PR615-PR616. In total, 21 out of 162 strains (13.0%) were identified to be fim2 positive, including 16 K. pneumoniae (16/123 = 13.0%), three undefined Klebsiella spp. (3/19 = 15.7%) and two K. oxytoca (2/18 = 11.1%). It must be noted that these species designations are based on biochemical species identifications, which can be problematic in this genus . 93.4% (15/16) of fim2-positive K. pneumoniae strains were also found to be mrk- and fim-positive by PCR analysis. However, the distribution of the latter were not investigated in other Klebsiella spp. due to recognized species-specific differences in fim and mrk operon sequences .
Prevalence of fim2 by specimen type
Pyogenic liver abscess aspirates
Fim2 genes are expressed under standard in vitro growth conditions
Heterologous expression of fim2 does not result in visualisable host fimbriation
Expression of fim2 in E. coli HB101 appears to enhance biofilm formation
As HB101/pFim2-Ptrc grew to a much lower OD595 at 48 h than the other two strains, we also analysed the biofilm data as a ratio of crystal violet staining intensity to the pre-wash OD595 measurement that reflected total growth. This analysis suggested that the proportion of HB101/pFim2-Ptrc cells comprising biofilm growth as opposed to total growth (biofilm and planktonic cells) was almost twice that of HB101 and the vector only control strain (Figure 4C). Indeed, based on this ratio, fim2 expression in HB101 exerted a highly significant positive impact on biofilm formation on both surfaces (P < 0.0001 in each case). By contrast when fim2 was expressed in the Mrk- and Fim-deficient strain C3091∆fim∆mrk using this same system, no statistically significant accentuation in biofilm formation on either surface was observed (data not shown).
Deletion of fim2 does not affect adhesion to human HCT-8 ileocaecal or 5637 bladder epithelial cells
Deletion of fim2 does not affect murine intestinal colonization
The fim2 locus is not a virulence factor in a murine lung infection model
Total liver and spleen CFU counts were used as a measure of the ability of bacteria to disseminate from the lungs into the bloodstream. Much lower numbers and greater mouse-to-mouse variation occurred in CFU counts for the livers (<15 – 1.6 × 104) and spleens (<20 – 200) of these mice. The median CFU count per liver for KR2107 (2.1 × 103) was elevated compared to that of KR2107∆fim2 (3.0 × 101), although this difference was not significant (P = 0.340). When liver CFU counts were examined individually for each mouse, two mice exhibited greater than 1-log more KR2107 than KR2107∆fim2, while the difference, though still hinting at an advantage for KR2107, was less than 0.5 log for two other mice (Figure 7B and C). The liver CFU counts in mouse 3 for both strains were equal to the lower limit of detection and extrapolated from a single colony each, thus preventing meaningful comparison of these values. No difference was found between the median CFU counts per liver for KR2107∆fim and KR2107∆fim∆fim2 (1.5 × 101). Thus, despite the absence of firm conclusions emanating from these data, the possibility that fim2 may play a role in systemic dissemination and/or survival of K. pneumoniae following murine lung infection cannot be dismissed entirely.
Role of fim2 in a murine urinary tract infection model
To investigate potential genetic redundancy or functional masking between fim and fim2, the competition assay was repeated in a fim-negative background. Consistent with previous data , bacterial counts were considerably lower in this fim-negative background experiment as compared to the initial competition assay. Infection was established in the bladders of five out of six mice, with a median bacterial count of 1.35 × 102 in these five mice. At time of sacrifice, infection had ascended into nine of ten kidneys with a median CFU count of 2.7 × 102 (n = 10). However, in all cases no bacteria were isolated from the urine suggesting counts of less than 50 per ml. The median CI value obtained for bladder samples showed that CFU counts for KR2107∆fim and KR2107∆fim∆fim2 did not differ significantly (Figure 8A). However, the median kidney CFU counts were 5.6-fold higher for the KR2107∆fim (1.4 × 102) than KR2107∆fim∆fim2 mutant (2.5 × 101), and although similar to the results obtained in the fim-positive background these results were also not statistically significant (P = 0.066) (Figure 8B). These results have confirmed the importance of fim in K. pneumoniae-mediated urovirulence and further support the case for a potential but subtle accessory role for fim2 in this disease process.
The plastic nature of K. pneumoniae genomes is well described and an increasing number of studies have elucidated the function of various components of the accessory genome of the pyogenic liver abscess-associated strain K. pneumoniae NTUH-K2044. However, functional characterization of the accessory genome of strains associated with other types of infection is lacking. In order to investigate the plasticity of K. pneumoniae associated with other infections, we previously interrogated the pheV locus of sixteen clinical isolates from patients without pyogenic liver abscesses for the presence of foreign DNA elements . In this study, further tRIP-PCR interrogation of K. pneumoniae KR116 using met56-specific primers identified a novel GI, KpGI-5, inserted within its met56 gene. KR116 had been isolated from the blood of a patient with pneumonia and neutropenic septicaemia. KpGI-5 was sequenced in this study and found to encode a putative γ1-type CU fimbrial operon that has been named fim2.
The genetic organization of fim2 resembles that of the K. pneumoniae fim operon and contains homologs of all eight fim genes. fim2 is predicted to code for a major fimbrial subunit (Fim2A), three minor fimbrial subunits (Fim2F, Fim2G, Fim2H) and homologs of the FimC and FimD chaperone and usher proteins, respectively, thus classifying this locus as a novel γ1-type CU operon that putatively encodes a fimbrial appendage . A seventh predicted protein, Fim2I, exhibited 82% identity to FimI, a protein required for fimbrial biogenesis; however, the exact nature of this dependence remains unknown . Amino acid sequences of the eight fim2 gene products showed 60 to 92% identity to cognate Fim proteins. Indeed, the two clusters would appear to be pseudoparalogs, homologs that appear to be paralogous but have ended up in the same genome by both vertical and horizontal gene transfer . The unique evolutionary origins of the fim and fim2 cluster are further highlighted by differences in transcriptional control. The fim cluster is largely controlled by the FimB and FimE recombinases which together switch transcription on and off by inverting a 314 bp promoter-containing sequence called fimS that lies upstream of fimA. Exact copies, genetic remnants or potential functional-replacements of the 9 bp fimS-flanking inverted repeats could not be identified within the putative fim2 promoter region that lies upstream of fim2A. Furthermore, as KpGI-5 lacks homologs of the FimB and FimE recombinases we conclude that fim2 expression is not controlled via a fimS-like switch mechanism. Additionally, the fim2K gene within the fim2 cluster encodes an EAL domain-containing protein that is similar to FimK, which has previously been shown to regulate type 1 fimbrial expression . FimK was hypothesised to exert its influence via the hydrolysis of the intracellular messenger c-di-GMP, which is known to regulate expression of virulence genes, motility and biofilm formation in other bacteria . The in vitro and in vivo function of Fim2K is currently under investigation.
Bacterial adhesion to and colonization of host cells is frequently mediated by a diverse assortment of afimbrial and fimbrial adhesins, each thought to possess a particular tissue tropism . The vast majority of K. pneumoniae strains are able to produce type 1 fimbriae [37, 44]. These structures are associated with mannose-sensitive agglutination of guinea pig red blood cells, a phenotype caused by interaction of the adhesin subunit FimH with terminally-exposed mannose residues in N-linked oligosaccharides on cell surfaces . Previously it has been shown that the FimH residues partaking in binding to mono- and tri-mannose moieties are highly conserved . The specific binding properties of Fim2H, the putative Fim2 adhesin, remain to be identified but it is unlikely to bind to mannose since only four out of the 13 mono- and tri-mannose binding residues of FimH are strictly conserved in Fim2H . This is also in agreement with the inability of E. coli HB101 expressing fim2 to agglutinate guinea pig red blood cells (data not shown), though the relevance of these data remain uncertain given the lack of visualisable fimbriae in this model.
Despite multiple attempts we were unable to visualize fimbrial structures using electron microscopy when the fim2 operon was over-expressed in E. coli HB101 and K. pneumoniae C3091ΔfimΔmrk. Paradoxically, biofilm forming ability appeared to be enhanced in this fim2-expressing E. coli strain. These results are similar to those of a study in which constitutive expression of four of seven E. coli CU fimbrial operons was shown to cause phenotypic alternations despite the fact that fimbrial appendages could not be visualized by electron microscopy . Difficulty in visualisation of fimbriae by electron microscopy has also been described for the enterotoxigenic E. coli fimbriae CS3 and CS6 and the putative Stg fimbriae of Salmonella enterica serovar Typhi [46–48]. Most interestingly, when the latter was expressed in a bald E. coli strain an enhanced ability to adhere to INT-407 epithelial cells was noted despite the absence of EM-observable fimbriae . It is possible that the fim2 operon may code for a short and/or thin fimbrial structure that is not readily visualized by electron microscopy, or one that is extremely fragile. Conceivably, the hypothesized Fim2 appendages may be best expressed under biofilm-forming conditions, potentially explaining the enhanced biofilm-forming phenotype exhibited by HB101/pFim2-Ptrc, or in other specific in vivo environments. Alternatively, the putative phosphodiesterase Fim2K may regulate fim2 transcription and/or that of an unknown E. coli adherence factor via a c-di-GMP-dependent pathway. Indeed, heterologous expression of fim2K has been shown to complement a mutant lacking an EAL-bearing protein (van Aartsen and Rajakumar, unpublished data). Proposed future anti-Fim2A-based immunofluorescence and immunogold electron microscopy studies in addition to detailed characterisation of Fim2K will ultimately help determine the mechanism by which fim2 contributes to biofilm formation.
The genomes of E. coli K-12, E. coli O157:H7 and Salmonella Typhi possess numerous cryptic CU fimbrial operons that are tightly regulated and not expressed under the majority of in vitro conditions tested [35, 36, 49]. In this work, fim2-specific transcript was identified in standard laboratory culture but the amount detected was 30- to 90-fold lower than that identified for fim and mrk, respectively. Compared to the K. pneumoniae genome-averaged A + T content (~43%), fim2 is AT-rich (53%) and the putative promoter region upstream of fim2A possesses an even higher AT-content (73%). As moderate-to-marked upregulation of seven CU fimbrial operons has been reported in an E. coli K-12 H-NS mutant , the finding of an AT-rich fim2 promoter region suggests that the H-NS protein may play a role in controlling this operon as well. Moreover, H-NS has been shown to bind preferentially to regions of horizontally-acquired DNA in Salmonella Typhimurium and it is therefore possible this also occurs with KpGI-5 . Furthermore, in addition to Fim2K, KpGI-5 also encodes two other potential regulators one or more of which could alter fim2 expression. By analogy with other CU systems, we propose that upregulation of fim2 expression and biosynthesis of Fim2 fimbriae is likely to be triggered by specific environmental conditions and involve a complex interplay of multiple transcriptional regulators such as H-NS, Fim2K and/or FimK, and levels of expression of other surface components, such as the capsule [31, 36, 38, 51]. It is important to note that even though fim2 lacks an invertible promoter switch, it may still be stochastically controlled by a bistable regulatory circuit such as the DNA methylation-based system described in detail for E. coli Pap fimbriae and it is therefore possible that single cell variants expressing fim2 may exist .
Analysis of three sequenced K. pneumoniae strains revealed that, in addition to the fim and mrk operons, these genomes collectively encode at least six other CU fimbrial systems [22, 23], one or more of which may perform an as-yet uncharacterised role in adhesion to target tissues. To investigate the role of fim2 in virulence, isogenic fim2 mutants were constructed and examined in three murine models, each focussed on primary infection of a distinct clinically-relevant anatomical site. Surprisingly, despite many fimbrial systems having been clearly implicated in virulence, we detected no clear evidence of attenuation (murine lung and urinary tract infection models) or reduction in colonizing ability (murine intestinal colonization model) in the fim2-negative strains studied.
Intriguingly, examination of bladder CFU count-based CIs for the urinary tract infection experiments hinted at a subtle role for fim2 in the colonization of bladder and kidney tissues. In both tissues, median wildtype CFU counts were approximately ten-fold higher than those of the fim2 mutant, although when performed in a fim negative background this difference was reversed and reduced in bladder and kidney samples, respectively. Nevertheless, the latter conflicting results may due to the markedly lower CFU counts obtained in the fim negative background. As shown by neutral CI values in the lung tissue but an approximately 100-fold higher median liver CFU count for KR2107 as compared to its isogenic fim2 mutant, the fim2 locus would appear to be involved in systemic dissemination and/or survival of K. pneumoniae following primary infection of the respiratory tract. However, given the noted lack of statistical significance, low numbers of mice examined and substantial mouse-to-mouse variation for these liver CFU data, no firm conclusions can be derived at present. As an aside, the previously demonstrated dramatic positive contribution of fim to urovirulence in this murine model was also shown to be the case in the KR2107 background [22, 23]. At an overview level, based on total CFU counts per liver and per kidney for the lung infection and ascending urinary tract infection models, respectively, there was a suggestion, though not supported statistically, of an ordered gradation amongst the four isogenic strains with the most-to-least virulent as follows: KR2107, KR2107∆fim2, KR2107∆fim and KR2107∆fim∆fim2. We speculate this relates to a Fim2-mediated enhancement of bacterial biofilm-forming-, adhesive- and/or invasive-potential under the in vivo conditions tested. In addition, the predicted influence of Fim2K on the c-di-GMP regulatory circuit, may itself impact on virulence via regulation of Fim2, Fim and/or other virulence factors.
The fim2 cluster was also assessed for its ability to contribute to biofilm formation. Gene knock-out experiments in KR2107 failed to reveal a role for fim2 in biofilm formation. However, the function of the product of fim2 may have been masked due to physical interference by the K. pneumoniae capsule, a phenomenon previously observed with type 1 fimbriae [38, 39]. Alternatively, it may be a function of limited fim2 expression under the in vitro conditions examined. Therefore, heterologous expression of fim2 in the afimbriate E. coli strain HB101 and the bald fim2-negative K. pneumoniae C3091∆fim∆mrk mutant was pursued. Yet again evidence of a fim2-associated phenotype was elusive and only apparent in HB101 and then too only when crystal violet-staining data were standardised for total pre-wash cell numbers. Attempts to alleviate the observed growth retardation associated with over-expression of fim2 in a HB101 background by reducing incubation temperature to 30°C and by providing rare tRNAs in trans were unsuccessful. Furthermore, the observed growth retardation was highly reproducible even when newly generated HB101 strains possessing independently-constructed pFim2-Ptrc plasmids were used instead (van Aartsen and Rajakumar, unpublished data). Thus, it would appear that over-expression of fim2 in HB101 was specifically responsible for this phenotype, though no comparable effect occurred with over-expression of fim.
The presence of fim2 in more than one species and its global spread suggests that this horizontally acquired locus has been maintained within a subset of the Klebsiella population due to positive selection. Hence, although the role fim2 remains elusive, given the glimpses of functionality hinted at by our data and the evolutionary survival of this multi-gene entity, we hypothesize that putative Fim2 contributes to pathogenesis of infection and/or environmental persistence, at least under highly specific conditions.
In conclusion, we have described the KpGI-5 island which possessed a novel γ1-type CU operon called fim2. Although fim2 was shown to be expressed at an mRNA level and its function was investigated using three distinct murine infection models, tissue culture experiments and biofilm assays, no obvious in vitro or in vivo role for the fim2 locus was identified, although there were subtle hints of involvement in urovirulence and in bacterial dissemination from the respiratory tract. Nevertheless, as fim2 was found in approximately 13% of Klebsiella spp. isolates examined, we propose that fim2 has the potential to contribute beneficially to its host Klebsiella strains at least under specific conditions.
Bacterial strains, plasmids, and growth media
Bacterial strains and plasmids used in this study
Bacterial strain or plasmid
Reference or Source
F- φ80dlacZ∆M15 ∆(lacZYA-argF)U169 deoR recA1 endA1 hsdR17(rK-mK+) phoA supE44 λ- thi-1 gyrA96 relA1
F- mcrB mrr hsdS20(rB- mB-) recA13 leuB6 ara-14 proA2 lacY1 galK2 xyl-5 mtl-1 rpsL20(SmR) glnV44 λ-
Δ(are-leu) araD ΔlacX74 galE galK phoA20 thi-1 rpsE rpoB argE(Am) recA1 λpir
F’ recA hsdR RP4-2 (Tc::Mu) (Km::Tn7) λpir
F- mcrA Δ(mrr-hsdRMS-mcrBC) φ80dlacZΔM15
ΔlacX74 recA1 endA1 araD139 Δ(ara-leu)7697
galU galK λ- rpsL nupG trfA tonA dhfr
Clinical urinary tract infection isolate; StR
C3091 with fim and mrk clusters deleted; StR, TetR, KanR
Clinical blood stream infection isolate
KR116 with an insertion-deletion mutation in fim2K where 125 bp has been replaced by a kanamycin resistance cassette; KanR
Spontaneous streptomycin resistant derivative of KR116; StR
KR2107 with fim deleted; StR, TetR
KR2107 with fim2 deleted; StR, KanR
KR2107 with fim and fim2 deleted; StR, TetR, KanR
Lambda pir-based suicide vector; CmlR
pBluescript II KS+
High copy number cloning vector; AmpR
Low copy number cloning vector; KanR
Lambda Red expression plasmid, PBAD promoter; AprR
Source of KanR cassette; KanR
Fosmid cloning vector; CmlR
IPTG inducible expression vector with PTRC promoter and lacI q ; AmpR
Derivate of pTRC99a with an added NotI cut site in multiple the cloning site; AmpR
pDS132 with SOE-PCR fragment for tagging of fim2K (fim2K::Kan); CmlR, KanR
40.6 kb fim2K::Kan-containing fragment cloned into pCC2FOS; CmlR, KanR
26.1 kb fim2K::Kan-containing fragment cloned into pCC2FOS; CmlR, KanR
9.4 kb PCR fragment containing the fim2 locus cloned into the NotI site of pBluescript II KS+; AmpR
9.4 kb PCR fragment containing the fim2 locus cloned into the NotI site of pWSK129; AmpR
9.0 kb PCR fragment containing the fim2 locus cloned into the NotI/SbfI site of pJTOOL-7. IPTG inducible; AmpR
DNA analysis and manipulations
Restriction enzymes and T4 DNA ligase were obtained from New England Biolabs and/or Promega and used according to manufacturer’s instructions. Genomic DNA and plasmid DNA were extracted using the ArchivePure DNA Purification Kit (5 PRIME) and GenElute™ Plasmid Miniprep Kit (Sigma), respectively. Primers used in this study are listed in Additional file 2: Table S1. Standard PCR amplification was carried out using GoTaq (Promega).
An 8.2 kb region containing the fim2 operon (fim2A-fim2K) was amplified from KR116 with primers PR937 and PR938 using KOD Hot Start polymerase (Merck), and cloned into the NotI site of pBluescript II KS + and pWSK129 to create high (pFim2-HCN) and low copy number (pFim2-LCN) plasmid clones, respectively. Additionally, the fim2 locus was amplified using primers PR1224 and PR1222 and was cloned into pJTOOL-7, a pTRC99a derivative, to create pFim2-Ptrc. A fosmid library representative of KR116 ∆fim2K::kan was constructed using the Epicentre Copy Control Fosmid Library Production kit, with some minor modifications. Briefly, 2.5 μg of genomic DNA was sheared to ~40 kb fragments by pipetting through a 200 μl tip. After end repair, the DNA was ligated into pCC2FOS and packaged into phages using MaxPlax Lambda Packaging Extracts (Epicentre) which were then used to infect E. coli EPI300-T1R. Marker rescue of kanamycin resistant fosmid clones was performed by plating infected EPI300-T1R cells on LB plates supplemented with chloramphenicol and kanamycin. Selected fosmids were subjected to approximately 60-fold coverage Roche 454 pyrosequencing (University of Leicester NUCLEUS Genomics Core Facility).
Construction of mutant strains
K. pneumoniae KR2107, a spontaneous streptomycin-resistant mutant of KR116, was used as the parent strain for all isogenic mutants. It possessed a 24 h growth curve identical to KR116 and agglutinated guinea pig red blood cells in a similar manner. fim2 was exchanged for a kanamycin resistance cassette by lambda Red-mediated recombination. KR2107 was transformed with pKOBEG-Apra, a temperature-sensitive plasmid encoding the lambda Red recombinase system, and grown at 30°C in LB media supplemented with apramycin and 0.2% arabinose. Electrocompetent KR2107/pKOBEG-Apra cells were prepared according to standard methods and electroporated with an SOE-PCR product comprising a kanamycin resistance gene cassette and targeting flanking homologous sequences (Additional file 1: Figure S1). The KR2107∆fim2 mutant was obtained by selecting on LB media plus kanamycin at 37°C. Loss of pKOBEG-Apra was confirmed by reversion to apramycin sensitivity and a negative PCR with primers EBGNHe and EBGh3. The KR2107∆fim2 mutant was validated by PCR analysis using primer pairs PR1103-Kn2 (2590 bp) and Kn1-PR1104 (3903 bp). The 2095 bp ∆fim::tet fragment was amplified from C3091∆fim::tet∆mrk::kan using primers UpfimB-F and DwfimK-R and electroporated into arabinose-induced KR2107/pKOBEG-Apra to construct the fim mutant . KR2107∆fim∆fim2 was constructed similarly from a KR2107∆fim/pKOBEG-Apra intermediate strain. KR116 ∆fim2K::kan was constructed by conjugative transfer of the suicide construct pJKO-4a to facilitate allelic exchange (; Additional file 1: Figure S1).
Transcriptional analysis of fim2
Total RNA was prepared from KR2107 after growing for 16 h in LB liquid medium (37°C, 200 rpm) using the Norgen Total RNA Purification Kit. The Ambion TURBO DNA-free kit was used to remove residual DNA and cDNA libraries synthesised using the QuantiTect Reverse Transcription kit (Qiagen) as recommended by the manufacturer. An identical reaction without reverse transcriptase was performed to assess DNA contamination. Regions corresponding to fim2A, fim2H and fim2K were PCR amplified using primers pairs PR1607-PR1608, PR1609-PR1610, and PR1611-PR1612, respectively. Regions linking 116met56-10 to fim2A and fim2H to fim2K were detected using primer pairs PR1626-PR1627 and PR16268-PR1629, respectively. Amplicons were visualised on 1.5% agarose gels.
Transmission electron microscopy
Five μl of sample was applied to a hydrophilic Formvar-carbon coated copper grid (Agar Scientific) and allowed to adsorb for 5 min. After wicking excess liquid, the grid was washed once using distilled deionised water and then negative-stained for 15 s with a droplet of 1% uranyl acetate (pH 4.5). Electron microscopy was performed on a JEOL JEM-1400 microscope at 80 kV.
Biofilm, growth curve and epithelial adhesion assays
Biofilm assays were performed using a modified microtiter plate-based method . Briefly, strains were grown for 16 h (37°C, 200 rpm) in LB broth with antibiotics if necessary and subcultured 1:100 into 100 μl LB medium with 0.05 mM IPTG and ampicillin, when required, in 96-well microtiter plates (Nunc). Plates were incubated statically for 48 h at 37°C and OD595 (optical density at 595 nm) readings obtained at the end of incubation. Following incubation the medium was removed and the plate washed once with distilled water. 125 μl of 0.1% (v/v) crystal violet was added to each well and left to stain for 10 min. The plate was then washed twice with distilled water, dried thoroughly and the stain eluted with 200 μl of 95% ethanol per well and the absorbance measured at 595 nm (BioRad Model 680 Microplate reader). Each was strain tested in eight wells and three replicate experiments were performed.
Growth curves were performed similarly to biofilm assays with a few minor modifications. Plates were incubated statically for 24 h at 37°C in a Varioskan (Thermo Scientific) instrument. The plates were subjected to a brief vigorous shake every 10 min immediately prior to the absorbance being measured at 600 nm (OD600). Each strain was tested in seven wells and two duplicate experiments were performed.
Quantitative assessment of bacterial adhesion to epithelial cells was performed using human HCT-8 ileocaecal and 5637 bladder cells. HCT-8 cells were subcultivated (1:10) twice a week in RPMI 1640 medium containing 25 mM HEPES, 2 mM glutamine, 1 mM pyruvate, 10% fetal calf serum, 0.002% neomycin and 0.01% streptomycin. 5637 cells were cultivated similarly but no pyruvate was added to the medium. Epithelial cells were seeded into two 24-well tissue culture plates (Nunc) and grown to confluent monolayers. After carefully washing each well three times with warm PBS, 1 ml of fresh supplement-free RPMI 1640 was added and inoculated with ~2 × 106 CFU from an overnight culture. Plates were incubated for 3 h at 37°C. One plate was then used to determine the total number of bacteria at the end of 3 h incubation, as described previously . The wells in the second plate were carefully washed three times with PBS and then used to determine the total number of adherent bacteria. All assays were performed in duplicate and repeated independently four times.
Murine models of infection
Six- to eight-week-old female CFW1 mice (Harlan) were used for intestinal colonization experiments as described previously . Briefly, mice were provided with drinking water containing 5 g/l streptomycin sulphate for 24 h and fed a 100 μl suspension containing ~109 CFU of each strain in 20% sucrose. On indicated days, faecal pellets were collected, weighed and homogenised in 0.9% NaCl and dilutions plated onto MacConkey agar supplemented with appropriate antibiotics for faecal CFU counts.
A previously described intranasal infection model was used in a co-infection format . Six- to eight-week-old female NMRi mice (Harlan) were anaesthetized and hooked on a string by their front teeth. 50 μl of bacterial suspension containing ~5 × 107 CFU of each strain was dropped onto the nares to allow for aspiration. Mice were left hooked on the string for 10 min before being returned to their cages. At sacrifice lungs, spleen and liver were collected in 0.9% NaCl and homogenised. Serial dilutions were plated on selective media for CFU counts.
The ascending urinary tract infection model in which C3H mice (Harlan) were inoculated transurethrally with 50 μl of bacterial suspension containing ~5 × 108 CFU bacteria has been described in detail previously [22, 65]. All animal experiments were conducted under the auspices of the Animal Experiments Inspectorate, the Danish Ministry of Justice.
Data analysis, statistics and nucleotide accession number
Nucleotide sequences were annotated and analysed using the Integrative Services for Genomic Analysis software and manually curated . The competitive index (CI) was calculated by dividing the ratio of fim2-positive to fim2-negative bacteria recovered from infected organs by the ratio of the corresponding bacteria in the initial inoculum. The non-parametric Mann–Whitney U test was used to analyse infection data. Biofilm and cell-adhesion data were analysed using the non-parametric Kruskal-Wallis test and Dunn’s posthoc analysis. The nucleotide sequence of KpGI-5 has been deposited online [GenBank: JN181158].
We thank Jean-Marc Ghigo, Unité de Génétique des Biofilms, Institut Pasteur, France, for providing pKOBEG-Apra and Stefan Hyman, Centre for Core Biotechnology Services, University of Leicester, for electron microscopy analysis. This study was supported by a Medisearch research grant. JJvA was supported by a University of Leicester, 50th Anniversary PhD Scholarship. SGS was partially supported by the Danish Research Agency grant 2101-06-0009. HYO was supported by the National Natural Science Foundation of China (30871345), the Program for New Century Excellent Talents in University, MOE, China (NCET-10-0572) and the Program for Chen Xing Scholars, Shanghai Jiaotong University.
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