Unité de Recherches Laitières et Génétique Appliquée, INRA, Domaine de Vilvert, 78352 Jouy en Josas CEDEX, France
Correspondence
Saulius Kulakauskas
Saulius.Kulakauskas{at}jouy.inra.fr
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ABSTRACT |
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Present address: Departamento de Microbiología Molecular, Centro de Investigaciones Biológicas (CSIC), Ramiro de Maeztu 9, 28040 Madrid, Spain.
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INTRODUCTION |
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S. pneumoniae polysaccharides have been classified into at least 90 different capsular types according to their structure and immunological properties (Henrichsen, 1995). It is believed that this diversity arose through horizontal transfer of capsular genes from unknown sources (Muñoz et al., 1997
, 1998
) or by capsular switching, mediated by recombinational replacement within capsular biosynthesis operons belonging to different types and their flanking regions (Caimano et al., 1998
; Coffey et al., 1998
, 1999
).
In most cases studied so far, capsule formation is encoded by the cps (cap) gene cluster. It comprises several genes, and is located in the pneumococcal chromosome between the dexB and aliA genes, which are not involved in CPS synthesis (García et al., 2000). Sequencing of cps/cap clusters of the 90 known pneumococcal types is in progress, and will provide new data confirming the involvement of these genes in each CPS biosynthetic process (http://www.sanger.ac.uk/Projects/S_pneumoniae/CPS). S. pneumoniae type 37 capsule formation constitutes a remarkable exception as the cap locus in these isolates is inactive and synthesis of CPS is assured by a single gene, tts, located apart from the cps locus on the genome (Llull et al., 1999
). Type 37 is the only homopolysaccharide described so far among pneumococcal CPSs, and is composed of sophorosyl units (
-D-glc-(12)-
-D-Glc) interlinked through
-(13) bonds (Adeyeye et al., 1988
). It was shown that a mutation in tts is sufficient to cause a CPS phenotype (Llull et al., 2000
). The capacity of a single gene to direct capsule production presents a convenient opportunity to map CPS mutations directly by DNA sequencing.
The experimental use of unencapsulated pneumococcal mutants may be valuable because of their reduced virulence, the exposure of other surface components and their increased transformability. Isolation of such mutants from clinical isolates is limited by the tedious genetic manipulations involved and/or the need to introduce genetic resistance markers by transformation (Pearce et al., 2002; Sung et al., 2001
; Trzcinski et al., 2003
). Furthermore, these treatments could change microbial physiology or have undesirable polar effects. We have used type 37 pneumococci to develop a novel approach for isolation of spontaneous capsule-negative mutants, which emerged from encapsulated parental strains that were immobilized in semi-liquid medium.
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METHODS |
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Pneumococcal strains used in this study were kindly provided by E. García (CSIC, Madrid, Spain) and are listed in Table 1. For construction of PN9, the non-encapsulated laboratory strain M24 (García et al., 1993
) was transformed as described previously (Barany & Tomasz, 1980
) with chromosomal DNA of the type 3 strain 406/90, and a mucous transformant was directly selected on blood agar plates (1 % THY agar containing 5 % defibrinated horse blood) according to its colony morphology. Type 3 CPS production was verified by immunoagglutination (see below) of transformant PN9 using specific type 3 anticapsular serum (Statens Seruminstitut, Denmark).
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Production of pneumococcal CPS-specific antisera.
Pneumococcal capsule-specific antisera were obtained from the Statens Seruminstitut (Denmark). We previously observed that type 37 CPS derivatives, like NR37-1, showed residual activity against commercial type 37 serum in certain culture conditions (unpublished observations). These derivatives are considered non-producers of type 37 CPS; however, they do not react with a serum obtained with the laboratory rough variants (Ravin, 1959). This was unexpected. Rough strains normally react with this type of antibody, as the absence of CPS allows access to cell-surface antigens. Absence of reaction with such antibodies suggests that type 37 CPSstrains may express an unknown surface substance that blocks access to antibodies. This substance may also be present on the surface of type 37 capsulated isolates. We considered that commercial type 37 serum, prepared using clinical type 37 isolates, may also contain antibodies against this unknown substance, which would react with mutants lacking type 37 CPS.
To obtain antibodies specific to type 37 capsulated pneumococci, we immunized rabbits with the type 37 laboratory transformant DN2 (Llull et al., 1999), following the procedure described by Lund & Henrichsen (1978)
. Non-capsular antibodies were eliminated by suspending cells of parental non-encapsulated strain M24 in the type 37 serum and incubating overnight at 4 °C with gentle shaking. Serum obtained using DN2 was highly specific for type 37 CPS as it only reacted with type 37 clinical strains (SSISP37/2) and laboratory type 37 transformants (DN2) but not with non-encapsulated derivatives NR37-1 or M24.
Immunostaining.
An overnight culture was centrifuged and washed twice with PBS (130 mM sodium chloride, 10 mM sodium phosphate buffer, pH 7·2). Cells were fixed with paraformaldehyde (Amann et al., 1990), washed twice and resuspended in PBS. Cells were stored in PBS/ethanol (1 : 1, v/v) at 20 °C for up to 1 week. Fixed PBS-suspended cells were incubated with 1000-fold diluted rabbit anti-CPS antibodies for 1 h, washed twice in PBS and incubated for 1 h with 1000-fold diluted goat anti-rabbit Alexa Fluor 555 coupled IgG antibodies (Molecular Probes). After antibody treatment, cells were washed twice in PBS and spread on gelatin-coated glass slides, air-dried and rinsed with water. For gelatin coating, clean slides were immersed in a solution of 10 % KOH in 95 % ethanol for 1 h, air-dried, dipped in a hot (70 °C) 0·075 % gelatin (Merck) solution with 0·01 % chromium potassium sulphate dodecahydrate (Merck) and air-dried. Slides with the cells were covered with mounting solution (Citifluor) containing 2·5 µg ml1 4',6-diamidino-2-phenylindole (DAPI; Sigma). Images were taken with an epifluorescence microscope (x60 objective; Nikon) equipped with an image analysis system (Visiolab 1000; Biocom).
Immunoagglutination.
Half volume of specific capsular serum was added to pneumococcal cells previously washed once and suspended in PBS. The mixture was incubated at 4 °C for 23 h and the agglutination reaction was directly observed using a phase contrast microscope.
DNA techniques, nucleotide sequencing and data analysis.
Isolation of chromosomal and plasmid DNA from pneumococcal strains was performed as described previously (Muñoz et al., 1997). The pneumococcal tts gene was PCR-amplified using 5'-TGAATGAATCTACCTAGGCTACC-3' (forward) and 5'-TTGAAGCTGGTTGCTTGTAGGC-3' (reverse) primers. Reactions for DNA sequence determination were performed for both strands according to the protocol of the DYEnamic ET terminator cycle sequencing kit (Amersham Biosciences Europe), using a MegaBACE 1000 automated capillary sequencer (Molecular Dynamics). The previously reported sequence of tts was used as a reference to map mutations (EMBL/GenBank/DDBJ accession number AJ131985).
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RESULTS |
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Transformation of fast-sedimenting mutants VES2585VES2587 with pDLP49, encoding tts (Llull et al., 2001), gave rise to strains VES2591VES2593, respectively (Table 1
). The presence of pDLP49 restored the wild-type sedimentation pattern (round colonies, Fig. 1e
), indicating that a mutation in the capsular tts locus may alone be responsible for the faster-sedimenting phenotype. Moreover, we observed that colonies of plasmid-carrying strains (Fig. 1e
) were slightly more round than those of the initial clinical isolate SSISP37/2 (Fig. 1a
). We attribute this phenotype to increased tts gene expression in strains carrying the multicopy plasmid.
Immunostaining and immunoagglutination with type 37 CPS-specific antibodies
We used specific DN2 type 37 serum (see Methods) to compare its reactivity with wild-type (SSISP37/2) and faster-sedimenting derivatives VES2585VES2587. In the immunostaining test, the parental SSISP37/2 strain showed a CPS+ red-staining phenotype (Fig. 2a), as expected for a type 37 clinical strain. In contrast, the control CPS strain NR37-1 and the VES2585VES2587 mutants did not give any signal under the same conditions, thus confirming the CPS phenotype of the isolated mutants (Fig. 2a
). The results of the immunoagglutination assays were consistent and confirmed that the fast-sedimenting mutants displayed a CPS phenotype (Fig. 2b
).
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Laboratory type 3 transformant PN9 originates from the M24 strain, a late descendant of the type 2 strain D39. It was constructed to produce a type 3 capsule by transformation with chromosomal DNA from the type 3 strain 406/90 (see Methods). Isolation of faster-sedimenting, non-capsulated mutants from both PN9 and 406/90 shows that immobilization depends mostly on capsule formation, as we can assume that they both produce the same CPS, despite their different genetic backgrounds.
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DISCUSSION |
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Mutations were identified in the tts gene encoding the type 37 polysaccharide synthase. We noted that strains carrying tts on multicopy plasmid pDLP49 (VES2591VES2593) formed somewhat rounder colonies (Fig. 1e) than the wild-type S37 strain, in which tts was present as a single copy on the chromosome (Fig. 1a
). More capsule production in the plasmid-carrying strain is likely to account for this immobilization effect.
The versatility of this method was confirmed using other isolates belonging to types 2, 3 and 6A (Fig. 1fi, Table 1
). Our results demonstrate that the use of semi-liquid medium for detection and isolation of CPS derivatives is not restricted to type 37 pneumococci. Nevertheless, a slight variation of the method (i.e. increasing the agar concentration) was necessary to select mutants from the type 6A strain.
The ability to select CPS mutants from strains producing the same type 3 capsule in different genetic backgrounds (e.g. PN9 and 406/90), or from strains producing different capsule types within the same genetic background (D39, type 2 and PN9, type 3), suggests that the capsule plays a major role in immobilization of pneumococci in semi-liquid medium.
Screening approaches have been used in the past to isolate CPS mutants. For example, type 3 or 37 pneumococcal mutants are easily distinguishable on blood agar plates by smooth or rough colony morphology. However, obtaining mutants by such an approach is not always successful. It requires repeated subculture and observation of a large number of colonies and therefore is not a straightforward screening method. Moreover, obtaining CPS mutants for other less mucous serotypes is hardly possible by simple subculture. Isolation of CPS mutants may be facilitated by addition of anti-pneumococcal antibodies and exploiting the changes in bacterial sedimentation in liquid medium due to immunoagglutination (Avery et al., 1944). CPS strain variants can also be identified through their increased surface hydrophobicity (Granlund-Edstedt et al., 1993
). Finally, efficient enrichment procedures based on buoyant density-gradient centrifugation (Sellin et al., 1995
) or use of Sorbarod biofilms (Waite et al., 2001
, 2003
) have greatly facilitated isolation of spontaneous capsule-negative mutants. However, while these methods allow separation of a mixture of different phenotypic CPS forms, they may not all correspond to mutants. In the system described here, round CPS+ colonies give rise to CPS roots. Roots arising from separate colonies would necessarily originate from independent mutations. Therefore the method presented here greatly facilitates isolation of independent CPS mutants.
The use of a dilute agar medium for differentiation of phenotypic characteristics of bacteria is not new. It was previously employed in studies of staphylococci (Finkelstein & Sulkin, 1957) and streptococci (Narikawa et al., 1995
). However, in those publications, the appearance of faster-sedimenting forms (tails) was not attributed to the emergence of mutants. To our knowledge the method presented here is the first application of immobilization in agar for isolation of capsule-negative mutants.
The capsule is a key virulence factor in S. pneumoniae, since non-capsulated derivatives have been shown to be practically avirulent (Griffith, 1928). On the other hand, the capsule decreases adherence to host cells (Adamou et al., 1998
) and trafficking across the bloodbrain barrier seems to be easier for non-capsulated pneumococcal derivatives (Ring et al., 1998
). Capsule phase variation seems to be a necessary mechanism for pneumococcal survival and mobility in the host. An interesting mechanism of capsule phase variation has been described for types 3, 8 and 37, where spontaneous sequence duplications within their capsular loci switched capsule production off, whereas reversion restored capsule production (Waite et al., 2001
, 2003
). Remarkably, duplications causing capsule loss were isolated from immobilized bacteria on Sorbarod biofilms. We noted that a similar heptanucleotide duplication in strain VES2587 causing loss of capsule production was also isolated under immobilization conditions (Fig. 3
). Moreover, the duplication occurred at the site that already carries duplication of the same, albeit degenerated, heptanucleotide (TTACATT TTAAATT), which could suggest the existence of a duplication-based capsule switch mechanism in this pneumococcal isolate.
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ACKNOWLEDGEMENTS |
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REFERENCES |
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Received 3 January 2005;
revised 15 March 2005;
accepted 22 March 2005.
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