MLST genotypes of Campylobacter jejuni isolated from broiler products, dairy cattle and human campylobacteriosis cases in Lithuania

A total of 262 C. jejuni strains were included in this study. This C. jejuni strain collection was composed of 43 strains isolated from dairy cattle at farm level between May 2012 and August 2012, 102 strains isolated from retail broiler products collected between October 2011 and October 2012 and 117 clinical human C. jejuni strains that were collected at the Microbiological Laboratory of Kaunas Clinical Hospital between September 2011 and October 2012. All human Campylobacter strains were isolated from sporadic cases associated with gastroenteritis. Isolation of C. jejuni was performed by bacteriological standard procedures and species were verified by PCR according to Wang et al. (2002) [12]. The isolates were stored at −80 °C.

One μl loop of bacterial culture grown on blood agar plates was collected and suspended in 200 μl of PrepMan Ultra (Applied Biosystems, Foster City, USA). The suspension was vortexed for 10–30 s in order to dissolve the bacterial culture and subsequently heated at 100 °C for 10 min for lysis. Afterwards samples were centrifuged at 16000 g for 3 min. The supernatant containing bacterial DNA was used immediately or transferred to a new tube and stored at −20 °C until use.

MLST was carried out as described by Dingle et al. (2001) [8]. Amplifications of the seven housekeeping genes that are included in the MLST scheme (aspA, glnA, gltA, glyA, pgm, tkt, uncA) were performed in separate tubes in a final volume of 25 μl PCR reaction mix composed of 12.5 μl DreamTaqGreen PCR Master Mix (2X) (Thermo Scientific, Waltham, USA), 8.1 μl Milli-Q water, 1 μmol l⁻¹ (2.5 μl) of each forward and reverse primer mix and 2 μl of C. jejuni DNA (~40 ng). The amplified PCR products were purified with Thermo Scientific GeneJET PCR Purification Kit (Thermo Scientific). For the sequencing reaction, Thermo-Fast 96-well non-skirted plates were used in combination with adhesive PCR films. Each sequencing reaction was performed in a final volume of 10 μl, using 8.2 μl sequencing mastermix, 0.8 μl primer and 1.0 μl of purified PCR product. The sequencing mastermix contained 1.0 μl BigDye v1.1, 2.0 μl 5X BigDye sequencing buffer (both Thermo Fisher) and 5.2 μl ddH₂O. All of the used primers were diluted to 5 μmol l⁻¹ concentrations. Amplification of samples was carried out in a thermocycler using 25 cycles (denaturation at 96 °C 0.1 min, annealing at 50 °C for 0.05 min, and extension at 60 °C for 1.0 min). After this step, products were purified. To each well of the amplified products 45 μl SAMTM solution and 10 μl XTerminator solution (both Thermo Fisher) was added. The reaction plates were vortexed for 30 min at 1800 rpm and then centrifuged at 1000 x g for 2 min. Sequencing was done on an ABI 3500XL automated DNA sequencer in both orientations.

The obtained sequencing data were imported, checked for quality and analyzed with the BioNumerics v 7.1 software (Applied Maths, Sint-Martens-Latem, Belgium). Allele numbers for each housekeeping gene, sequence types (STs), and clonal complexes (CCs) were assigned by submitting the DNA sequences to the C. jejuni MLST database (http://​pubmlst.​org/​campylobacter).

Phylogenetic relationships of the isolates were calculated by MLST-based cluster analysis in Bionumerics using concatenated sequences. The Simpson’s index (D) described by Hunter (1990) [13] was used to determine the genetic diversity of C. jejuni genotypes:

N - number of isolates tested;

S - number of different genotypes;

nj - number of isolates belonging to type j.

The Czekanowski index or proportional similarity index (PSI) was calculated to compare STs proportional distribution among C. jejuni isolates from various sources [14, 15]. The PSI was calculated by:

p _i and q _i represent the proportion of strains belonging to ST i out of all strains typed from sources p and q. The values for PSI range between 1 for identical frequency distributions, to 0 for distributions with no common types.

Among the 262 C. jejuni strains included in the MLST analysis, 82 distinct sequence types (STs) were identified. Theses STs were assigned to 22 previously described clonal complexes (CCs) (Table 1). Forty (15.3%) strains were assigned to 19 STs which did not match any of the CCs of the MLST database. In addition, 51 (19.5%) C. jejuni strains representing 27 (32.9%) STs were previously unreported in the PubMLST database (http://​pubmlst.​org/​campylobacter). The calculated Simpson’s index of all C. jejuni isolates showed a high genetic diversity (D = 0.96).

Out of the 22 clonal complexes identified, eight CCs dominated (CC21, CC353, CC464, CC48, CC206, CC354, CC257 and CC443) (Fig. 1a) and 176 (67.2%) of our isolates were assigned to these clonal complexes (Table 2).

On ST-level, five sequence types (ST-5, ST-21, ST-464, ST-50 and ST-6410) were dominating and they accounted for 35.9% (n = 94) of our isolates (Table 2).

A minimal spanning tree was generated from the MLST data illustrating the phylogenetic relationships of the C. jejuni strains (Fig. 2). Two STs (ST-257 and ST-572) were identified only from dairy cattle and human clinical cases and 16 STs were identified only from broiler products and human clinical cases. Three sequence types (ST-19, ST-21 and ST-42) were identified in all three sources (i.e. human clinical samples, dairy cattle samples, broiler product samples) (Table 2).

The PSI was calculated to evaluate the proportional similarity and genetic relatedness of sequence types of human isolates and strains isolated from the different tested sources. This analysis showed that STs from broiler product isolates had the highest proportional similarity to STs from human clinical isolates (PSI = 0.32) (Table 3).

Among the 117 human isolates included in the study, 45 different STs were found and eight of them are reported for the first time (Table 1). Out of the 19 identified CCs, three CCs (CC21, CC353 and CC48) were dominant with 62 (53%) of our isolates attributable to these CCs (Fig. 1b). ST-5 and ST-50, which are linked to CC353 and CC21, were predominant in the pool of human isolates and they represent 20.5% and 9.4% of C. jejuni isolates from human clinical cases, respectively and these two CCs are genetically related to broiler products. The calculated Simpson’s index of human C. jejuni isolates showed a high genetic diversity (D = 0.94) (Table 3). Eight C. jejuni isolates from human samples were assigned to novel STs (Table 2). Two of these new STs (ST-6391 and ST-6392) were identified in C. jejuni isolates from broiler products as well (Table 2).

Forty-three C. jejuni strains from dairy cattle were included in the study and 16 different STs were found (Table 1). Twelve STs representing 35 isolates (81.4%) were assigned to nine previously described CCs. The remaining eight isolates (18.6%) were assigned to four different STs, which could not be assigned to any of the described CCs of PubMLST database. CC21 and ST-21 were dominant among C. jejuni isolates detected in dairy cattle, with 37.2% and 32.6% respectively (Fig. 1c, Table 2). Five C. jejuni isolates from dairy cattle were assigned to three novel STs (ST-7215, ST-7216 and ST-7318) (Table 2). ST-7215 was identified among C. jejuni isolates from broiler products as well (Fig. 1). The lowest diversity of the genotypes was identified among isolates from dairy cattle (D = 0.87) (Table 3).

Among the 102 C. jejuni strains isolated from broiler products, 46 distinct STs were identified (Table 1). These STs were assigned to 16 previously described CCs. Three CCs (CC21, CC353 and CC464) were predominating among C. jejuni isolates detected in broiler products and 41.2% of the strains were assigned to one of these three CCs (Fig. 1d). Three STs (ST-5, ST-464 and ST-6410) were dominating (with 8.8%, 14.7% and 11.8%, respectively) among C. jejuni isolates detected in broiler products (Table 2). Interestingly, ST-6410, which has not been described before, was one of the most prevalent STs among broiler products. The highest diversity of C. jejuni genotypes was found among isolates detected in broiler products (D = 0.95) (Table 3).