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PVL overexpression due to genomic rearrangements and mutations in the S. aureus reference strain ATCC25923

Abstract

Objective

ATCC25923 is a Staphylococcus aureus strain that is positive for the Panton Valentin leukocidin. It has been used for decades as reference strain. We observed that two separately maintained clones of ATCC25923 (“G477 and G478”) differed grossly in the expression of this toxin. For that reason, both clones were sequenced using an Illumina MiSeq instrument. After assembling, the final sequences were analyzed and mapped to a previously published ATCC25923 sequence (GenBank CP009361) using bl2seq from the NCBI Blast2 package.

Results

The genomes of G477 and G478 size 2778,859 and 2792,213 nucleotides, respectively. Both genomes include a circular plasmid of 27,490 nucleotides. The sequence of the G477 chromosome maps nearly exactly to CP009361. G478 has a slightly larger size because of the presence of an additional transposable element tnp13k. The second copy of that tnp13k element is located in an intergenic region between the genes mazF and rsbU. The sequences of the ATCC25923 clones G477 and G478 differ mainly in the insertion of a second tnp13k element between the genes mazF and rsbU. That insertion may lead to a different transcription of that genome region resulting in upregulation of the expression of the Panton-Valentine leukocidin in the ATCC25923 clone G478.

Introduction

Staphylococcus aureus (S. aureus) is a facultative pathogen that can colonize or infect humans as well as animals. The virulence of this bacterium is influenced by various virulence factors which are frequently localized on mobile genetic elements allowing horizontal gene transfer between strains. One example is the Panton-Valentine leukocidin (PVL). PVL is an exotoxin encoded by the genes lukF-PV and lukS-PV. The two genes are co-located on a prophage, and co-expressed [1] to form polymeric pores in leukocyte membranes and to trigger apoptosis. The toxin is associated with skin and soft tissue infections as well as with life-threatening diseases such as necrotizing pneumonia and necrotizing fasciitis [2].

ATCC25923 is a methicillin susceptible and PVL-positive laboratory strain. It belongs to clonal complex (CC) 30 and sequence type (ST) 243 that differs from parental ST30 by a single nucleotide mutation in the glpf gene. ATCC25923 was isolated in Seattle in 1945, i.e., before penicillin or other antibiotics widely entered clinical practice. Due to the absence of any resistance genes from this strain, it is frequently used as a susceptible control during antibiotic susceptibility tests. For that purpose, many laboratories have cultured and maintained this strain for decades and this might have given rise to locally distinct clonal lineages over time. One such lineage, purchased through Remel Inc., Lenexa, KS under license of the American Type Culture Collection, has already been sequenced in 2014 [3]. This sequence was placed in GenBank (Accession Numbers CP009361 for its chromosome and CP009362 for a plasmid) [http://www.ncbi.nlm.nih.gov/nuccore/CP009361; http://www.ncbi.nlm.nih.gov/nuccore/CP009362].

In our laboratory, two other local clones of ATCC25923 were investigated that differ remarkably in the expression and secretion of PVL as demonstrated in a previous study [4]. In order to identify genomic changes and/or mutations leading to this noticeable difference, the genomes of both ATCC25923 clonal lineages were sequenced and analyzed.

Main text

Materials and methods

Strains

One clone of ATCC25923 was maintained, used and passaged for at least 12 years at the Institute for Medical Microbiology and Hygiene, TU Dresden, Germany. This clone, named G478 hitherto, was found to be a PVL hyper-producer. A second clone, G477, was obtained from another bacteriological laboratory, Bioscientia MVZ Saarbrücken (courtesy of Dr. Stefan Weber).

Protein measurements

PVL production was measured using tube-mounted antibody arrays (Alere Technologies GmbH; cat. nr. 201010719). The method was previously described in detail [4]. In short, strains were cultured for 18 h in liquid broth as described by Kato and Noda [5]. Supernatants were added to arrays, on which dilution series of LukF-PV specific monoclonal antibodies were spotted and covalently immobilized. Subsequently, a biotin-labelled secondary antibody, streptavidin-horseradish-peroxidase and a precipitating dye (reagents from Protein Binding Kit by Alere Technologies; cat. nr. 245500100) were added. PVL concentrations were determined by mapping the resulting spot intensities to calibration curves that resulted from experiments with known concentrations of recombinant and purified LukF-PV. Experiments were repeated five times (G477) or six times (G478) using different batches of growth media.

DNA-array-based typing

Clones were genotyped by DNA-Microarrays (S. aureus Genotyping Kit 2.0 kit, Alere Technologies; cat. nr. 245200096). Microarray procedures have been previously described in detail [6, 7]. In addition, probes for plasmid-borne heavy metal resistance genes were used (see Additional file 1).

Furthermore, the sequences of the probes on the microarray were mapped against the previously published ATCC25923 sequence (CP009361 + CP009362) facilitating the prediction of its hybridization pattern.

Sequencing and analysis

One colony forming unit from visibly pure culture of each isolate was selected for whole genome sequencing. Genomic DNA was extracted by enzymatic lysis using the enzymes and buffers provided with the S. aureus Genotyping Kit 2.0 kit (Alere Technologies; cat. nr. 245200096) and the DNeasy Blood and Tissue Kit (Qiagen; cat. nr. 69506) according to the manufacturers’ instructions. A library was prepared using the Nextera XT kit (Illumina; cat. nr. FC-131-1024) according to the manufacturer’s instructions. Briefly, the purified genomic DNA quantified with a Qubit dsDNA BR (broad range; Thermofisher; cat. nr. Q32850) assay kit and a Qubit 2.0 Fluorimeter (Thermofisher) was diluted to 0.2 ng/µl and then the DNA concentration was measured again using this time Qubit dsDNA High Sensitivity assay kit (Thermofisher; cat. nr. Q32851). A total of 1 ng of DNA was tagmented at 55 °C for 5 min. PCR amplification to introduce Illumina index sequences was performed in PCR strip tubes in a BioRad T100 thermocycler. The size distribution of fragments was estimated with a 2200 TapeStation using the Agilent D1000 High Sensitivity kit (Agilent; cat. nr. 5067-5585) according to the manufacturer’s instructions. Fragments of 200 to 1000 bp were obtained. The library DNA fragments were size selected and purified using Agentcourt AMPure XP beads (Beckman Coultier Genomics; cat. nr. A63881). The indexed libraries were normalized, pooled and loaded onto an Illumina MiSeq reagent cartridge using MiSeq reagent kit v3 (Illumina; cat. nr. MS-102-3003) and 600 cycles. The paired-end 2× 300 bp sequencing was run on an Illumina MiSeq sequencer. The reads were assembled de novo utilizing the SeqMan NGen 12.1.0 software with the following assembly parameters: Match Size: 31; Match Spacing: 50; Minimum Match Percentage: 93; Match Score: 10; Mismatch Penalty: 20; Gap Penalty: 30; Max Gap: 6; Minimum read length: 150; Minimum sequences per contig: 100. The resulting contigs were ordered by using the Mauve Contig Mover [8] relative to the ATCC25923 reference genome (GenBank Accession Number CP009361). End-to-end alignment of contigs to find overlap between adjoining contigs was accomplished using the SeqMan Pro 12.1.0 software (DNAStar). It allowed merging the majority of the contigs in the draft genomes. Subsequently the gaps were closed by an extension of the contig ends using the reference-guided genome closure protocol and the SeqMan NGen software followed by merging contigs in the SeqMan Pro software.

Remaining gaps between contigs were closed by PCR amplification with primers flanking the gaps followed by Sanger or MiSeq sequencing (see Additional file 2).

The assembly files with the complete and closed genomes were exported as fasta files and used in further analyses.

Software procedures and analysis

The final sequences of G477 and G478 were mapped to the published ATCC25923 sequence (CP009361; [http://www.ncbi.nlm.nih.gov/nuccore/CP009361]) using bl2seq from the NCBI Blast2 package [9]. In order to identify single nucleotide polymorphisms (SNPs), co-linear regions were compared position by position with an in-house python script.

Results and discussion

Protein measurements

During a previous study [4] it was shown that G478 produced more PVL than any other strain tested with a mean of 41,000 ng/ml and a median of 22,000 ng/ml (range from 10,000 to 151,000 ng/ml). G477 yielded a mean and median of 1300 ng/ml (range from 400 to 2400 ng/ml), which was more in accordance to other CC30 strains tested during that study [4].

DNA-array-based typing

G477 and G478 appeared as typical CC30-MSSA as previously described [6] and were identical in all features covered by the microarray. They presented with PVL genes and the egc enterotoxin gene cluster. They lacked all other enterotoxin genes, tst1 and genes associated with beta-haemolysin-converting phages (sak, scn, chp, sea, see). Genes associated with antibiotic resistance were absent, but some genes for heavy metal resistances (mco, copA2, arsB, arsC and cadD) were detected using a new set of probes.

The predicted hybridization pattern for CP009361 + CP009362 fully matched the results observed for G477 and G478 (see Additional file 1).

Sequencing

Sequencing yielded an average genome coverage of 146× (minimum 7× and maximum 2188×) and 355× (minimum 11× and maximum 4648×) for G477 and G478, respectively. The complete genome of G477 was assembled from the sequencing reads, yielding a circular bacterial chromosome (size 2,778,859 nt) and a circular plasmid (size 27,490 nt). The assembled genome of G478 consists of a circular bacterial chromosome (size 2,792,213 nt) and a circular plasmid (size 27,490 nt) (see Table 1). The circular chromosomal and plasmidic sequences were linearized at the same positions as GenBank entries CP009361.1 and CP009362.1. The plasmid sequences of G477 and G478 were proven to be 100% identical over their entire length, whereas the chromosomal sequences differ by about 13,500 nt in size. The shorter chromosome of G477 is nearly equal in size to CP009361.1 (difference only 5 nt).

Table 1 Full genome sizes of ATCC25923 derivatives

The increased size of G478 is caused by a single insertion event where an additional stretch of about 13,500 nt is integrated near position 2,108,925 (see Fig. 1). This corresponded to a gap between G478 contigs that was closed by sequencing of a PCR product. This additional stretch of DNA was identified to be an exact copy of a transposable element tnp13k which is present with a single copy in the G477 and CP009361.1 chromosomes near position 989,942.

Fig. 1
figure 1

Insertion of the additional tnp13k element in G478. The insertion site of the additional tnp13k element in the S. aureus clone G478 of the strain ATCC25923 near position 2,108,925 nt. The insertion is located in an intergenic region between the genes mazF and rsbU

Comparison of the G477 and G478 chromosomal sequences allows mapping the insertion site precisely. The insertion site has a very low GC content and the insertion causes a duplication of 3 nucleotides (TAA). A similar observation has been made by Schijffelen et al. [10] who found two copies of the 13 K conjugative transposon in the strain S0385 (CC398-MRSA-V), GenBank AM990992. However, the sequences of the two copies differed substantially from each other in that case [10].

Beside the duplication of tnp13k, the chromosomes of G477 and G478 are co-linear and differ by only 9 SNP. No further insertions or deletions were found.

These 9 SNPs are listed in Table 2. SNPs 1 and 6 are located in intergenic regions, and thus they cannot be associated with any changes in amino acid sequences. SNPs 2 and 5 do not cause a change in amino acid sequences of the respective gene products and thus they cannot influence metabolic pathways such as, e.g., toxin expression. SNPs 3, 4, 7, 8 and 9 cause changes in amino acid sequences, but the functions of the proteins in question (fatty-acid-binding protein, homoserine kinase, RNA binding proteins and isopentenyl-diphosphate delta-isomerase; see Table 2) do not suggest that these changes might be related to the different PVL expressions in the two clones.

Table 2 Single nucleotide polymorphisms (SNPs) of G478

The sequences of integrated PVL-phage and PVL genes were also compared for CP009361, G477 and G478. Data showed identical sequences in all three ATCC25923 derivatives. Therefore, neither the PVL genes (lukF-PV and lukS-PV) nor the phage-located promotor could be the reason for the different PVL expressions in G477 and G478 indicating that differences in the core genome might be responsible. This also ruled out the possibility that the apparent difference in PVL expression was caused by different binding affinities of the antibodies due to slightly different sequences of LukF-PV.

Thus, special attention was paid to the additional tnp13k element in G478 which is inserted into the intergenic region between the core chromosomal genes rsbU and mazF (Fig. 1).

MazF is part of the chromosomally encoded and well characterized MazE (antitoxin)/MazF (toxin) system. It encodes an endoribonuclease which specifically cleaves mRNA at the pentad sequence UACAU. This sequence was identified in several genes for virulence factors of S. aureus, e.g., in the gene of SraP, which mediates the adhesion of the bacteria to host cells [11]. A further study showed that MazF cuts also spa and rsbW at UACAU sites whereas the expression of these proteins was unaffected by the mRNA cleavage. These findings suggest that MazF plays a role in S. aureus gene regulation [12].

The other neighboring gene, rsbU, encodes a phosphatase that positively controls sigmaB, which itself downregulates the expression of agr. Agr is a well-known regulator of S. aureus virulence and a transcriptional factor that plays a central role in stress response and persistence of infection. Moreover, RsbU is able to dephosphorylate a global transcriptional regulator, MgrA, controlling expression of virulence genes [13,14,15].

The insertion site of the additional 13K element into the intergenic region between MazF and rsbU may affect the transcription of the neighboring genes (see Fig. 1). A previous study showed the transcription of a large mRNA starting at the promotor of the mazE gene and then continuing through mazF, rsbU, rsbV, rsbW and sigB (a 3.7 kb transcript). MazE, mazF and rsbU are transcribed together, despite that there is a 350-nt intergenic region between them [16].

However, there are two further promotors immediately upstream of rsbU and rsbV, respectively, as well as a weak transcriptional terminator downstream of mazF. Presumably, two further transcription products of different length are formed [16]. The tnp13k element was inserted 195 nt upstream from the rsbU translation start site and might interfere with transcriptional activation of the rsbU promoter leading to up-regulation of PVL expression.

The analyzed sequences of the ATCC25923 clones G477 and G478 differ mainly in the additional insertion of a second copy of the tnp13k element in G478. The insertion between the genes rsbU and mazF seems to affect the usual transcription and leads to the previously detected up-regulation of the PVL expression and secretion in G478.

Limitations

It was assumed that the insertion of a tnp13k element upstream from the rsbU translation start site lead to an up-regulation of PVL expression. However, the exact pathway still needs to be determined. Further evidence for this hypothesis should be added by deleting the second tnp13k element from the G478 genome followed by a measurement of PVL expression, or by introducing such an insert at the same localization into another well-characterized strain.

Abbreviations

A:

adenine (in DNA sequences), alanine (as amino acid)

AA:

amino acid

ATCC:

American Type Culture Collections

Bp:

base pair(s)

C:

cytosine

cat. nr.:

catalogue number

CC:

clonal complex

DNA:

deoxyribonucleic acid

G:

guanine

Kb:

kilobase, 1000 nucleotides

L:

leucine

M:

methionine

mRNA:

messenger ribonucleic acid

MRSA:

methicillin-resistant Staphylococcus aureus

MVZ:

“Medizinisches Versorgungszentrum”, outpatient health centre (in Germany)

NA:

nucleic acid

NCBI:

National Center for Biotechnology Information

ng/ml:

nanogram per milliliter

NGS:

next-generation sequencing

Nt:

nucleotides

P:

proline

PCR:

polymerase chain reaction

PVL:

Panton-Valentine leukocidin

S:

serine

S. aureus :

Staphylococcus aureus

SCC:

Staphylococcal cassette chromosome

SNP:

single nucleotide polymorphism

ST:

sequence type

T:

thymine (in DNA sequences), threonine (as amino acid)

V:

valine

References

  1. Kaneko J, Kamio Y. Bacterial two-component and hetero-heptameric pore-forming cytolytic toxins: structures, pore-forming mechanism, and organization of the genes. Biosci Biotechnol Biochem. 2004;68(5):981–1003.

    Article  CAS  PubMed  Google Scholar 

  2. Boyle-Vavra S, Daum RS. Community-acquired methicillin-resistant Staphylococcus aureus: the role of Panton-Valentine leukocidin. Lab Invest. 2006;87(1):3–9.

    Article  PubMed  Google Scholar 

  3. Treangen TJ, Maybank RA, Enke S, Friss MB, Diviak LF, Karaolis DKR, Koren S, Ondov B, Phillippy AM, Bergman NH, et al. Complete genome sequence of the quality control strain Staphylococcus aureus subsp. aureus ATCC 25923. Genome Announc. 2014;2(6):e01110–4.

    Article  PubMed  PubMed Central  Google Scholar 

  4. Stieber B, Monecke S, Müller E, Baier V, Coombs GW, Ehricht R. Development and usage of protein microarrays for the quantitative measurement of Panton-Valentine leukocidin. Mol Cell Probes. 2014;28(4):123–32.

    Article  CAS  PubMed  Google Scholar 

  5. Noda M, Kato I. Purification and crystallization of staphylococcal leukocidin. Methods Enzymol. 1988;165:22–32.

    Article  CAS  PubMed  Google Scholar 

  6. Monecke S, Slickers P, Ehricht R. Assignment of Staphylococcus aureus isolates to clonal complexes based on microarray analysis and pattern recognition. FEMS Immunol Med Microbiol. 2008;53(2):237–51.

    Article  CAS  PubMed  Google Scholar 

  7. Monecke S, Coombs G, Shore AC, Coleman DC, Akpaka P, Borg M, Chow H, Ip M, Jatzwauk L, Jonas D, et al. A field guide to pandemic, epidemic and sporadic clones of methicillin-resistant Staphylococcus aureus. PLoS ONE. 2011;6(4):e17936.

    Article  CAS  PubMed  PubMed Central  Google Scholar 

  8. Rissman AI, Mau B, Biehl BS, Darling AE, Glasner JD, Perna NT. Reordering contigs of draft genomes using the Mauve aligner. Bioinformatics. 2009;25(16):2071–3.

    Article  CAS  PubMed  PubMed Central  Google Scholar 

  9. Tatusova TA, Madden TL. BLAST 2 sequences, a new tool for comparing protein and nucleotide sequences. FEMS Microbiol Lett. 1999;174:247–50.

    Article  CAS  PubMed  Google Scholar 

  10. Schijffelen MJ, Boel CHE, van Strijp JAG, Fluit AC. Whole genome analysis of a livestock-associated methicillin-resistant Staphylococcus aureus ST398 isolate from a case of human endocarditis. BMC Genom. 2010;11(1):376.

    Article  Google Scholar 

  11. Zhu L, Inoue K, Yoshizumi S, Kobayashi H, Zhang Y, Ouyang M, Kato F, Sugai M, Inouye M. Staphylococcus aureus MazF specifically cleaves a pentad sequence, UACAU, which is unusually abundant in the mRNA for pathogenic adhesive factor SraP. J Bacteriol. 2009;191(10):3248–55.

    Article  CAS  PubMed  PubMed Central  Google Scholar 

  12. Schuster CF, Mechler L, Nolle N, Krismer B, Zelder M-E, Götz F, Bertram R. The MazEF toxin-antitoxin system alters the β-lactam susceptibility of Staphylococcus aureus. PLoS ONE. 2015;10(5):e0126118.

    Article  PubMed  PubMed Central  Google Scholar 

  13. Gupta RK, Luong TT, Lee CY. RNAIII of the Staphylococcus aureus agr system activates global regulator MgrA by stabilizing mRNA. Proc Natl Acad Sci USA. 2015;112(45):14036–41.

    Article  CAS  PubMed  PubMed Central  Google Scholar 

  14. Luong TT, Newell SW, Lee CY. Mgr, a novel global regulator in Staphylococcus aureus. J Bacteriol. 2003;185(13):3703–10.

    Article  CAS  PubMed  PubMed Central  Google Scholar 

  15. Truong-Bolduc Q, Hooper DC. Phosphorylation of MgrA and its effect on expression of the NorA and NorB efflux pumps of Staphylococcus aureus. J Bacteriol. 2010;192(10):2525–34.

    Article  CAS  PubMed  PubMed Central  Google Scholar 

  16. Donegan NP, Cheung AL. Regulation of the mazEF toxin-antitoxin module in Staphylococcus aureus and its impact on sigB expression. J Bacteriol. 2009;191(8):2795–805.

    Article  CAS  PubMed  PubMed Central  Google Scholar 

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Authors’ contributions

RE, SM and AF designed the study. BS, SM, RE and PS wrote the manuscript. AS performed sequencing. BS, EM and VA performed other experiments. AS and PS analyzed sequence data. SM, RE and AF proofread and edited the manuscript. All authors read and approved the final manuscript.

Acknowledgements

We acknowledge Antje Ruppelt for excellent technical assistance. We thank Dr. Stefan Weber (Abu Dhabi, formerly Saarbrücken) for providing the second ATCC 25923 clone G477.

Competing interests

B. Stieber, S. Monecke, P. Slickers, E. Müller and R. Ehricht are employees of Alere Technologies GmbH (Abbott Rapid Diagnostics). The other authors have no competing interests to declare.

Availability of data and materials

The genome sequences are published in GenBank under the following accession numbers: G477-chromosome: CP021905, G477-plasmid: CP021906, G478-chromosome: CP021907, G478-plasmid: CP021908.

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Correspondence to Bettina Stieber.

Additional files

13104_2017_2891_MOESM1_ESM.docx

Additional file 1. (1) Core genomic markers, sorted by position in genome; (2) Mobile genetic elements; phage-associated markers; (3) Mobile genetic elements; other virulence markers; (4) Mobile genetic elements; SCC-associated markers; (5) Mobile genetic elements; other resistance markers.

Additional file 2. Primers used for filling the gaps between the NGS contigs by sequencing of PCR products.

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Stieber, B., Sabat, A., Monecke, S. et al. PVL overexpression due to genomic rearrangements and mutations in the S. aureus reference strain ATCC25923. BMC Res Notes 10, 576 (2017). https://doi.org/10.1186/s13104-017-2891-3

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