Introduction

Methicillin-resistant Staphylococcus aureus (MRSA) is a hospital-acquired pathogen of great concern globally. Along with AIDS and viral hepatitis B, MRSA infection is regarded as one of three major infectious diseases threatening human health1. Vancomycin is currently used to treat MRSA infections, but the emergence of vancomycin-intermediateS. aureus(VISA), heterogeneous vancomycin-intermediateS. aureus(hVISA), and high-level vancomycin-resistantS. aureus(VRSA), is a cause for concern. Although it is known that the transitioning of vancomycin susceptible MRSA (VSSA) to VISA is linked to changes in DNA sequences and transcriptional regulations, the exact mechanism involved remains largely unknown.

The emergence of VISA from a previously vancomycin susceptible bacterial strain may be triggered either by exposure to vancomycin or other antibiotics, or when murF or pbpB is inactivated, resulting in up-regulated expression of relevant stimulatory factors such as the VrsSR two-component system, which subsequently affect cell wall biosynthesis2,3. Notably, reduced susceptibility to glycopeptide class of antibiotics and increased susceptibility to β-lactam antibiotics, has been observed during the transition of VISA from VSSA, a phenomenon referred to as the ‘see-saw effect’. However, the underlying mechanism of this phenomenon remains poorly understood4.

In this study, we report on five MRSA strains in which susceptibility to oxacillin decreased during transformation from vancomycin susceptible MRSA to VISA in vitro. In the most extreme case, the oxacillin minimum inhibitory concentration (MIC) for one strain decreased from 512 μg/ml to 1 μg/ml. Furthermore, the mecA gene was deleted in this particular strain, suggesting that loss of this gene may be involved in the acquisition of vancomycin resistance. However, it is plausible that other unknown mechanisms are involved. Induced strains were characterized genotypically and compared to parental strains.

Results

Bacterial strains

Details of all the bacterial strains used in this study are shown in Table 1.

Table 1 Staphylococcus aureus strains used in this study.

Vancomycin induction

Five MRSA strains were passaged through several low vancomycin concentrations. The vancomycin MICs for strains 3503-1, 3347, 3564, 4126-1 and 4180, all increased following induction by a series of increasing vancomycin concentrations (0.375–12 μg/ml) for 45 days, reaching 6 μg/ml by day 30 and the maximal value of 10 μg/ml by day 45 (Fig. 1). In order to ascertain the permanency of the newly acquired MICs, the induced strains were continuously passaged for 20 days on plates without any antibiotics. The vancomycin MICs of three strains (3347, 3564 and 4180) were restored to the pre-induced levels (2–3 μg/ml), whilst the other two strains (3503-1 and 4126-1) retained the acquired vancomycin MICs of 10 and 7 μg/ml, respectively. Specifically for strain 3503-1, two induced strains with vancomycin MIC of 6 μg/mL (identified as 3506V6), and MIC of 10 μg/mL (identified as 3506V10), produced after 20 and 45 days of induction, respectively, were further tested. Interestingly, the colonies of induced strains were smaller and drier than their parental strains (Fig. 2). The oxacillin MICs of all the five strains decreased by between 4- to 512-fold during vancomycin induction (data not shown). In particular, the oxacillin MIC of strain 3503-1 decreased from 512 μg/ml to 1 μg/ml during the 45-day passage, and was shown to have lost the mecA gene by PCR confirmation (see below). All the strains, except 3503-1 and its induced equivalents, were resistant to gentamicin. Further details on the drug susceptibilities of all the strains used in this study are shown in Table 1.

Figure 1
figure 1

Process of induction of VISA from MRSA.

Figure 2
figure 2

VISA colony morphology.

PFGE analysis of DNA fragment patterns

To gain further insights into the homology of parental and induced strains, the five MRSA strains and their induced VISA strains were further analyzed by PFGE. Each of the four strains (3347, 3564, 4126 and 4180) had a unique DNA fragment pattern which was similar to its induced equivalent. In contrast, strain 3503-1 had a different DNA fragment pattern compared to its induced equivalent strains 3503VR6 and 3503VR10 (Fig. 3). Restriction endonuclease digestion with SmaI revealed a distinct fragment at 200 kb for the four strains with similar DNA fragment pattern, but this fragment was shifted to 160 kb in strain 3503VR6. However, for strain 3503VR10, there was no band at 160 kb position, but instead there was one at 120 kb which was much brighter than that in 3503-1 and 3503VR6. Pattern differences were even more significantly shown by the PFGE of RsrII-digested DNA. Taken together, these results indicate that 40 kb and 80 kb fragments were deleted from strains 3503VR6 and 3503VR10, respectively.

Figure 3: PFGE analysis of strain 3503-1 and their induced strains.
figure 3

The PFGE DNA ladder is shown. Lanes 1 and 4 = strain 3503-1. Lanes 2 and 5 = strain 3503VR6. Lanes 4 and 6 = strain 3503VR10. Lanes 1–3 = DNA digested by SmaI. Lanes 3–6 = DNA digested by RsrII.

Confirmation of the staphylococcal cassette chromosome mec (SCCmec) deletion sites in strain 3503-1

Based on the SCCmec gene sequence of strain MRSA N315 downloaded from GenBank, 18 previously published5 and newly designed, primer pairs were used to investigate the deleted regions of induced strains 3506VR6 and 3503VR10, with strain 3503-1 used as a positive control. A series of primers listed in Table 2 were used to amplify the target fragments. No PCR products were generated from strain 3503VR6 by five sets of primers (map2, map4, map7, map8 and map9), while PCR products could only be amplified from 3503VR10 by primers map10 and map16. Based on the gene map of fragments from ORFX to spa of reference strain MRSA N315, these results suggested that the SCCmec element deletion sites in 3503VR6 and 3503VR10 may be located between the binding sites of primers map11 and map10, and map11 and map16, respectively. A 4-kb fragment designated 11R10F was successfully amplified with primers map10F and map11R from strain 3503VR6 (Fig. 4). Likewise, another 4-kb fragment (11 R16RFAN) was amplified from strain 3503VR10 using primers map11R and map16RFAN (Fig. 5).

Table 2 Primers used in this study.
Figure 4
figure 4

SCCmec conjunction PCR product of 3503VR6.

Figure 5
figure 5

SCCmec conjunction PCR product of 3503VR10.

SCCmec deletion mapping

The first 2-kb sequences (between fragments 11R10F and 11R16RFAN) of the deleted regions were identical to the reference sequence of MRSA N315 downloaded from the Genbank database. Deletion fragment 11R10F started at position 37,166 bp, which is 56 bp upstream of the gene SA0026 (IS431), and ended at position 81,168 bp which is within the kdpC gene, whereas fragment 11R16RFAN ended at position 116,954 bp, within gene SA0102 (Figure S1. SCCmec deletion site in 3503VR6 and 3503VR10). The deletions in strains 3503VR6 and 3503VR10 were 44,003 bp and 79,789 bp long, respectively. Both deleted regions included ccrAB, Tn554, and part of the mecA gene of the SCCmec region (Figure S2. Schematic diagram showing the deletion regions of strains 3503VR6 and 3503VR10). Furthermore, both deletions included SA0102 that encodes a 67-kDa myosin-cross-reactive streptococcal antigen. To confirm the results of deletion mapping, 3503-1 and 3503VR10 were sent to whole-genome sequencing (WGS). The deletion region was demonstrated by the syntany analysis (Fig. 6A). Details of the deletion region are shown in Fig. 6B. No further deletions were detected between 3503-1 and 3503VR10. Additionally, few Single-nucleotide polymorphisms (SNPs) were identified between 3503-1 and 3503VR10 (Table 3). Of note, one of SNPs located within tagH gene encoding a teichoic acid export ATP-binding protein.

Figure 6: Syntany analysis of the region containing the SCCmec.
figure 6

(A) The region containing the SCCmec highlighted in the box was absent in 3503VR10. (B) Details of the region deleted in 3503VR10. Flanking regions are shown in box with dash lines.

Table 3 SNPs detected between strains 3501 and 3503VR10.

Single-nucleotide polymorphisms (SNPs) associated with vancomycin resistance in 4126-1

As no deletions were detected between 4126-1 and 4126VR10, we further inspected the potential mechanisms involved in the vancomycin resistance. These two strains were send to WGS, and in total of 11 high-quality SNPs were identified between them (Table 4). Notably, two non-synonymous SNPs resulting in nonsense mutations were detected in genes murA and gad, respectively. murA gene encodes UDP-N-acetylglucosamine 1-carboxyvinyltransferase catalyzing the first committed step on peptidoglycan synthesis, and gad gene encodes mannosyl-glycoprotein endo-beta-N-acetylglucosaminidase catalyzing the hydrolysis of the N,N’-diacetylchitobiose moiety of asparagine-linked oligosaccharides of various glycoproteins.

Table 4 SNPs detected between 4126-1 and 4126VR10.

Quantitative PCR analysis

To determine the role of IS431 in the vancomycin-induced deletion of SCCmec, the expression level of IS431 was compared between three strains (3503-1, 4126, 4180) and their associated induced variants using the 16 s rRNA gene as the reference (Fig. 7). IS431 expression increased significantly in 3503V6 and 3503V10 comparing to their parent strain 3503-1 (p < 0.01), while no significant differences were observed for strains 4126 and 4180 and their induced equivalents.

Figure 7
figure 7

Relative quantification of IS431 expression using 16 s rRNA genes for normalization under different experimental conditions.

Discussion

It has been reported that MRSA is resistant to all β-lactam antibiotics due to acquisition of the SCCmec element from related organisms, possibly via horizontal gene transfer. However, the mechanism involved is still unclear. The stability of the SCCmec element in an organism may be affected by long-term storage and exposure to high temperatures, ultraviolet, and antibiotics. In a report by Sieradzki et al., an MRSA strain lost resistance to oxacillin after acquisition of vancomycin resistance. In this strain, mecA function was lost due to the insertion of a replicon4. Similarly, in the present study, mecA was not detected in VISA strains 3503VR6 or 3503VR10 by PCR, and PFGE and WGS confirmed that indeed mecA was deleted in both strains due to an endonuclease fragment jump at 190 kb (Fig. 3).

Deletion of the SCCmec cassette from VISA has been reported previously6,7. Specifically, Bhateja et al. found that mecA was deleted following induction of vancomycin resistance in one of eight VISA-induced strains6. Likewise, in the present study, only one out of 5 strains (3503-1) induced, lost the mecA gene.

Deletion of mecA is dependent on several factors. The type of SCCmec involved may be important; Wong et al. demonstrated that deletions were common in isolates harboring SCCmecII. However, in the present study, strain 4126-1, which like strain 3503-1 possessed the SCCmecII element, did not exhibit mecA gene deletion, suggesting that further studies involving more bacterial strains are needed before conclusions can be drawn.

Previous studies also indicate that deletion of ccrA and ccrB genes may also play a role in mecA deletion as reported by Adhikari et al. in a study involving 49 induced strains, some of which exhibited decreased resistance to oxacillin, and one of which had undergone mecA deletion8. Likewise, ccrA and ccrB was lost together with the SCCmec in strain 3503VR10 (Fig. 6).

Insertion of transposon IS431 may also be responsible for mecA gene deletion. Findings from our study seem to confirm this as PCR analysis revealed that the 3′-end of SCCmec was deleted in strains 3503VR6 and 3503VR10, and that the deletion was 56-bp upstream of transposon IS431. This transposon which is ubiquitous in all SCCmec regions studied to date, is always located downstream of mecA, and may play an important role in the movement and stability of mecA9. In vitro VISA-induced strains may undergo deletion of part of SCCmec during insertion of transposon IS431, as observed by Reipert et al. who identified a VISA strain with a mecA deletion located downstream of transposon IS43110. In the present study, MRSA strains were successfully induced by vancomycin, and a vancomycin MIC of 6 μg/ml was associated with the deletion of a 40-kb fragment containing the SCCmec element. Further vancomycin induction resulted in the deletion of a further fragment upstream of SCCmec. These findings suggest that transposon IS431 may not only involving in the deletion of SCCmec fragment, but also splice other fragments in the Staphylococcus aureus genome. Additionally, the higher expression of IS431 detected in the 3503 induced variants (3503V6 and 3503V10) suggest that IS431 may trigger the degradation function, resulting in loss of 40-kb fragment in 3503V6 and 80-kb in 3503V10, although the degradation mechanism remains unclear.

This study has some limitations. First, some phenotypic changes that occurred during the acquisition of vancomycin resistance cannot be directly linked to loss of SCCmec. Specifically, strain 3503-1 lost resistance to oxacillin upon acquiring vancomycin resistance (MIC of 6 μg/ml). However, this strain exhibited resistance to vancomycin prior to loss of the SCCmec-associated oxacillin resistance. It is thus difficult to directly attribute the loss of SCCmec-associated oxacillin resistance to the acquisition of vancomycin resistance from the existing data. We postulate that the loss of SCCmec (and associated methicillin resistance) is adaptive for bacteria acquiring vancomycin resistance. Additionally, a SNP was detected in tagH gene encoding a teichoic acid export ATP-binding protein, and it is known that changes of teichoic acid can affect the susceptibility to vancomycin in S. aureus11. Whether the mutation of tagH involved in the alteration of vacomycin susceptibility should be determined in the future.

Furthermore, we did not analyze methicillin -sensitive VISA at the MIC of 6 μg/ml, and this should be performed in the future. The loss of SCCmec-associated drug resistance was induced by two rounds of deletions, which to our knowledge is the first this has been reported. Although strains 4126 and 3503 were identical in the regions sequenced, their resistance to gentamicin was different, and we hypothesize that this may be SCCmec-associated. Second, despite confirming that aac(6′)-aph(2w″) was present in strain 4126, we did not determine whether this gene was localized chromosomally or on a plasmid, and thus further genetic analysis of these strains is needed. It has been reported that MRSA containing penicillin resistance plasmids may have increased mecA stability12, which needs further investigation.

An understanding of the mechanism by which bacterial strains with higher levels of vancomycin resistance lose resistance to methicillin/oxacillin is important for clinical diagnosis. Bacterial isolates resistant to vancomycin may affect drug resistance to oxacillin and even induce resistance in β-lactam-sensitive strains. Currently, the isolation rate of MRSA from clinical samples is much higher than that of MSSA, and β-lactam antibiotics are increasingly unsuitable for treatment of MRSA infections. The results presented here suggest that treating MRSA with vancomycin may ultimately lead to vancomycin resistance, but may also enhance or even restore susceptibility to methicillin/oxacillin, which suggests that there may be potential for effective combination therapies.

Materials and Methods

Bacterial strains

All bacterial strains used in this study are listed in Table 1. Strain N315, which is the MRSA prototype strain for SCCmec type II and positive for the HVR-IS431-pUB110-IS431-dcsorfx structure, was used as positive control. Strain Mu50, which is the referred strain for ST5-MRSA-II and positive for VISA. Details of the 45-day serial passage selection process have been previously reported8. Briefly, the strains were inoculated on blood agar plates, and single colonies were re-suspended in 0.9% NaCl solution to a McFarland standard of 105 CFU/ml. After this, 10 μl of the suspension was inoculated on brain heart infusion (BHI) plates containing 0.375 μg/ml vancomycin and incubated overnight at 37 oC. Vancomycin-adapted colonies were subsequently cultured on BHI agar plates (Oxoid, Basingstoke, England) containing 2, 4, 6, 8 and 12 μg/ml vancomycin. Vancomycin MIC values were determined every four days using the broth microdilution method. E-tests were used to confirm MICs ≥ 4 μg/ml during the serial passage.

For the stability assay, VISA strains were cultured on BHI agar plates without vancomycin once per two days, and the passage was continuous for 20 days.

In vitro susceptibility assay

The broth microdilution method was used to determine MICs for vancomycin, oxacillin, and gentamicin13. Concentrations used for vancomycin MIC determination were 10, 8, 7, 6, 5, 4, 3, 2 and 1 μg/ml, and 512, 256, 128, 64, 32, 16, 8, 4 and 2 μg/ml, for oxacillin. Bacteria were cultured at 37 °C for 24 h, and S. aureus ATCC29213 was used as a control.

SCCmec typing and mecA gene detection

The primers used for SCCmec typing and mecA gene detection were acquired from previous study14 and showed in Table 5. SCCmec PCR amplification reaction conditions: 94 °C denaturation for 5 mins, 94 °C denaturation for 45 s, 65 °C annealing for 45 s, 72 °C extension for 1.5 mins, the above steps for 10 cycles. Then 94 °C denaturation for 45 s, 55 °C annealing for 45 s, 72 °C extension for 1.5 mins, the above steps for 25 cycles, and finally 72 °C extending for 10 mins.

Table 5 Primers used for classification of SCCmec.

PFGE analysis

Bacteria were re-suspended in 12 mM Tris buffer to a final concentration of 105 CFU/ml. The resulting suspensions were mixed with 2% low melting agarose (1:1) to prepare mini gels that were subsequently incubated with 20 U of lysostaphin overnight, and digested with 40 U of protein kinase K for 16 h. DNA was digested by SmaI and RsrII for 6 h, and the resulting DNA fragments compared for parental and induced strains as previously reported15.

Analysis of the region upstream and downstream of mecA gene

Primer design

Based on the SCCmec gene sequence of MRSA N315 downloaded from the GenBank (Accession number: D86934.2), primers were designed and synthesized (Table 2). Fourteen primer pairs were used to map the fragments from ORFX to spa as per reference strain MRSA N315. Primer pairs map2, map4, map7, map8, map9 were acquired from the previous study16, and the others were designed in this study using the primer walking strategy. The order of the primers was map 11, map 2, map 4, map 7, map 8, map 9, map 10, map 12, map 13, map 14, map 15, map 18, map 17 and map 16. Primers used for sequencing the aminoglycoside resistance genes aac (6′)-aph (2″), ant(4)-Ia, and aph(3)-IIIa, were as described previously17.

PCR confirmation

PCRs were performed using the following parameters: initial denaturation at 95 °C for 5 min, followed by 30 cycles of denaturation at 94 °C for 30 s, annealing at 50–60 °C for 30 s, extension at 72 °C for 1 min, and a final extension at 72 °C for 5 min. Sequencing was performed by BGI Tech (Shenzhen, China), and sequences were compared with the genome of MRSA N315.

Reverse-transcription quantitative PCR (qPCR)

To gain some insights into expression of IS431, reverse-transcription qPCRwas performed. RNA was extracted by using 100 μL lysozyme solution (25 mg/mL lysozyme, Sigma) and Trizol (TaKaRa). The RNA was quantified by Nanodrop 2000 C, and reverse transcribed into cDNA using a PrimeScriptTM 1st strand cDNA Synthesis Kit (TaKaRa), following manufacturer’s instructions. Real-time PCR was performed using the IS431 primer in an IQTM 5 multicolor Real-Time PCR Detection System (BIO-RAD, USA). Each sample was assayed in triplicate. The primer pairs used were S. aureus_16 s F: 5′-GTGTCGTGAGATGTTGGGTT-3′ and S. aureus_16 s R: 5′-GTGTCGTGAGATGTTGGGTT-3′, IS431-F: 5′-TTAATATGACGGTGATCTTGC-3′ and IS431-R: 5′-GCCATTGATGCAGAGGGAC-3′. Amplification was carried out with an IQTM 5 multicolor Real-Time PCR Detection System (BIO-RAD, USA) under the following conditions: 95 °C for 2 min, followed by 40 cycles of 95 °C for 15 s, 60 °C for 60 s, and 65 °C for 60 s. Amplification data were collected and analyzed.

Whole-genome sequencing (WGS) and data analysis

DNA libraries were prepared using the TruSeq LT kit (Illumina, San Diego, CA, USA) according to the manufacturer’s instructions and then run on a Miseq (Illumina) for generating paired-end 300-bp reads. Briefly, de novo assembly was performed using CLC Genomics Workbench v8.0.5 (CLC bio A/S, Aarhus, Denmark) after quality trimming with optimal word sizes based on the maximum N50 value. Contigs were oriented and ordered using Mauve16 against the reference N315 chromosome. In-silicoMLST was performed by submitting the assembled contigs to CGE server (https://cge.cbs.dtu.dk/). Syntany analysis was performed via ACT18. Reads were mapped to the chromosome of N315 by CLC Genomics Workbench v6.05 with default settings. Candidate SNPs were called by the algorithm basic variant detection of CLC Genomics Workbench. To acquire reliable SNPs, SNPs were filtered as previously described19.

Accession numbers

This whole-genome shotgun project has been deposited in NCBI under BioProject PRJNA328893. The GenBank accession numbers of the isolates analyzed in this study are MBTB00000000 (3503-1), MBTC00000000 (3503VR10), MBTD00000000 (4126-1), MBTE00000000 (4126VR10).

Additional Information

How to cite this article: Wang, A. et al. A potential role of transposon IS431 in the loss of mecA gene. Sci. Rep. 7, 41237; doi: 10.1038/srep41237 (2017).

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