Isolation and characterization of lytic phage TUN1 specific for Klebsiella pneumoniae K64 clinical isolates from Tunisia

Background

Multidrug-resistant Klebsiella pneumoniae spp. (kp) are emerging agents of severe infections of the respiratory, urinary tract and wounds that can progress to fatal septicemia. The use of bacteriophages is currently being considered as an effective alternative or adjuvant to antibiotic therapy.

Results

In this study, we report capsule (K)-typing of 163 carbapenem-resistant Kp (CRKP) isolated 2014–2018 at the Military Hospital of Instruction of Tunis (MHT), Tunisia, by partial amplification and sequencing of the Kp wzi gene. The most prevalent K-type overall was K64 with 50.3% followed by K17 and K27 (22.7 and 11.0%, respectively). K64 Kp strains were most common and associated with increased case/fatality rates, especially at the intensive care unit (ICU). Using a K64 Kp strain we isolated and characterized a lytic Kp phage, vB_KpP_TUN1 (phage TUN1), from wastewater samples of the ICU at the MHT. TUN1 belongs to the Autographiviridae family and specifically digests K64 Kp capsules most probably via a depolymerase encoded by gp47. Furthermore, we successfully assembled phage TUN1 in a non-replicative host (E. coli) raising the possibility of in vitro assembly in the absence of live bacterial hosts. We propose that phage TUN1 is a promising candidate to be used as an adjuvant or an alternative to antibiotic therapy in CRKP infections, facilitating regulatory approval of phage therapy.

Conclusions

K64, K17 and K27 are the most common wzi capsule types in this geographical location in Northern Africa. The lytic phage TUN1 efficiently lyses K64 Kp strains associated with increased case/fatality rates at body temperature. Together with its ability to be rescued in a non-replicative host these features enhance the utility of this phage as an antibacterial agent.

The spread of multidrug-resistant bacteria (MDRB) is an increasing global problem [1]. With reduced treatment options, the risk of life-threatening infections, including septicemia, grows and therefore new therapeutic approaches are required.

Bacteriophages targeting specific bacteria are considered a promising alternative to standard broad-spectrum antibiotic therapy, or an adjuvant to more specific antibiotic therapies, especially in the case of MDRB infections.

The ESKAPEE group of bacterial pathogens comprising Enterococcus faecium, Staphylococcus aureus, Klebsiella pneumoniae, Acinetobacter baumannii, Pseudomonas aeruginosa, Enterobacter spp., and Escherichia coli [2] highlights the clinical impact of MDRB, and illustrates the prevalence of multidrug-resistant gram-negative bacteria (MRGN) [3]. MRGN including Klebsiella pneumoniae (Kp) are also a problem in the military setting, indicated by the prevalence of MRGN in role 1 to 3 military treatment facilities [4]. MRGN can be resistant to up to 4 groups of antibiotics, which is why they are classified as MRGN1 to − 4, respectively. Among others, MRGN4 are resistant to carbapenem/ertapenem leaving colistin as the only remaining treatment option [5]. The emergence of carbapenem-resistant Kp strains (CRKP) and their spread in hospitals is an alarming phenomenon reported to be correlated with high case/fatality rate of 40–70% [6, 7]. Therefore, CRKP are important nosocomial pathogens involved in serious and life-threatening infections, especially in the intensive care unit (ICU) [8] and of particular concern to clinicians [9].

Kp cells have typical polysaccharides capsules, which form biofilms, confer resistance to antibiotics, reduce phagocytosis, prevent a vigorous immune response and hence are a major Kp virulence factor [10]. Currently, more than 80 Kp capsular types (K-types) are known [11]. The Wzi protein connects the polysaccharide capsule to the cell membrane of Kp [12]. In 2013, Brisse et al. developed a PCR-based assay correlating a 580 bp sequence of genomic Kp wzi with high statistical significance to K-types [13].

As mentioned above, there is an urgent need for therapeutic approaches for CRKP infections alternative to antibiotic treatment. Recently, the use of bacteriophages was shown to be effective in the treatment of MDRB in a landmark clinical study [14]. Bacteriophages specific for Kp have been isolated previously [15,16,17,18], including phage specific for capsule type K24 [19]. Kp phages contain K-type-specific enzymes that depolymerize the polysaccharides. Thereby the phage can reach the host surface and thus bind to a secondary receptor e.g. outer membrane proteins [20,21,22].

But, considering the wide variety of K-types, Klebsiella phages have to be isolated and characterized in large numbers to be used in therapeutic cocktails active against diverse Kp capsule types.

In this collaborative study between the Bundeswehr Institute of Microbiology (IMB) in Munich and the Military Hospital of Instruction of Tunis (MHT), we K-typed 168 CRKP obtained from a collection of strains, which were isolated from patients of different medical services at the MHT, Tunisia, between 2014 and 2018 [23] via wzi sequencing. Furthermore, we identified and characterized the lytic phage TUN1, a T7-type bacteriophage specific for Kp with the predominant capsule type K64 associated with increased case/fatality rates.

The majority of Kp strains analyzed in this study (70.2%) were isolated from patients in the MHT intensive care unit (ICU) followed by the unit for neonatology (10.7%). With < 3% each the remaining isolates were achieved from 13 other medical services at the MHT [23].

The predominant capsule-type K64 is associated with increased case/fatality rates

To determine the K-type for each Kp strain, wzi gene sequencing was performed as described by Brisse et al. 2013 [13]. One hundred sixty-three of 168 Kp strains yielded the respective amplicon and 15 different K-types were found (Table 1). With 50.3% (82 CRKP strains), the most prevalent K-type was K64 followed by K17 and K27 (22.7 and 11.0%, respectively). For five Kp strains no amplification of the wzi gene locus could be achieved.

With 27 CRKP-related deaths, the overall case/fatality rate of CRKP infections at the MHT lies at 18.0%. Looking at the pathogenicity of the three most common K-types, only K64 was associated with increased case/fatality especially at the ICU. With 63% in all units and 70.3% at the ICU almost two thirds of all CRKP-related deaths are therefore associated with Kp K64 infections (Fig. 1).

Case/fatality rates associated with Kp K-types K64, K17 and K27. Overall case/fatality rates (black) and case/fatality rates at the ICU (grey) in relation to CRKP-related deaths caused by Kp K64, K17 or K27 strains

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Kp bacteriophage TUN1

To isolate bacteriophages specific for the Tunisian CRKP strains wastewater was collected from locations at the MHT. For phage enrichment the Kp host strain 7984, exhibiting the most predominant capsule type K64, identified in this study, was used. However, plaque-forming phages could only be found in the wastewater collected from the ICU. One of them, vB_KpP_TUN1 (phage TUN1), was further characterized in this study. Initial experiments showed that this phage forms central clear plaques (⌀ 1.5–2 mm) each surrounded by a halo (⌀ 5–6 mm after 12 h at 37 °C) on Kp 7984 (Fig. 2a). The growth curve showed that phage TUN1 has a replication cycle of 20 min and a burst size of 76 phage particles/cell (Fig. 2b).

Initial characterization of phage TUN1 with its host Kp 7984. (a) Plaque assay revealing clear plaques each surrounded by a translucent halo. Scale bar: 50 mm (b) Growth curve of phage TUN1 was carried out at MOI = 1. Data is shown as mean from three biological experiments. Error bars represent standard deviation

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Phage TUN1 – a member of the Autographiviridae family – contains one putative depolymerase

Analyzing the genome of phage TUN1 using high-throughput sequencing revealed a linear genome with short direct terminal repeats consisting of 41,181 bp with a GC content of 52.9% and 53 predicted open reading frames (ORFs) as shown in Fig. 3 and Supplementary Table S1.

Schematic overview of the genome of phage TUN1. ORF coding for RNA polymerase is shown in yellow, while the ORF encoding a DNA polymerase is shown in red. ORFs coding for proteins involved in phage particle assembly and packaging are marked in green, and ORFs coding for enzymes involved in host lysis are marked in blue. Other functional ORFs are marked in purple while ORFs of hypothetical proteins are marked in grey. Arrows indicate the direction of transcription

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BlastN analysis found the most related genome sequence in the database to be Klebsiella phage 066037 (Accession No: MW042800.1, query coverage: 92 and 93.2% identity) belonging to the Przondovirus (Kp32virus) genus of the family Autographiviridae in the order of Caudovirales [24].

Examining the phage’s morphology using transmission electron microscopy (TEM), an icosahedral capsid with short tails could be observed (Fig. 4).

TEM of phage TUN1. Four TEM images showing one TUN1 phage particle each reveal the characteristic morphology of podoviruses. Scale bar: 100 nm

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It has been described previously, that translucent halos surrounding phage plaques indicate the presence of phage-derived depolymerases [25]. Depolymerase activity of bacteriophages commonly lies within their tail fibers or tail spike proteins on the baseplate [26]. Nucleotide BLAST analysis revealed that the tail fiber protein, located downstream of internal virion protein D and upstream of class II holin (ORF 47 or gp47; Fig. 3, Supplementary Table S1), exhibits the highest similarity (query coverage: 97%; identity 96%) with the tail fibers protein of Klebsiella phage P509. This phage also exhibits specific depolymerase activity against K64 Kp strains [27]. Therefore, the tail fiber protein is most likely to exhibit depolymerase activity.

Phage TUN1 shows a narrow host range restricted to K64 Kp strains

Since phage TUN1 was enriched on Kp 7984 a capsule type K64 strain, its specificity was investigated by testing 81 remaining Tunisian K64 Kp strains (Table 1) as well as representatives of other K-types as putative hosts. Eight representative strains are shown in Fig. 5. Phage TUN1 exhibits a narrow host range, as it was only able to lyse K64 Kp strains. Out of 82 K64 Kp strains 57 were lysed by phage TUN1, 25 were not, including strain 6096 shown as example in Fig. 5. None of the non-K64 capsule types were lysed.

Lytic activity of phage TUN1 against Kp strains with different K-types. Upper panel: Growth experiments with phage TUN1 and four different Kp K64 strains. TUN1 lyses its host strain used for enrichment: Kp 7984 (written in bold) as well as Kp 8338 and 8971 with different efficiencies while Kp 6096 is not affected. Lower panel: Effect of phage TUN1 on Kp with the capsule types K27, K52, K17 and K25. Here, no lysis of Kp by phage TUN1 could be observed. Green: Kp strain alone. Red: Kp strain supplemented with phage TUN1

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Rescue of phage TUN1 in non-pathogenic E. coli cells

For a potential therapeutic approach, genetic modification (e.g. to remove unwanted genetic elements like toxins, or genes allowing integration and a lysogenic state) and in vitro packing methods may be required, to facilitate regulatory approval. As a proof of principle that phage TUN1 can be rescued in a non-replicative host we transformed purified phage DNA into non-pathogenic E. coli NEBstable® 3040 cells. Although no plaque formation on E. coli could be observed (not shown), phage TUN1 assembly within the cells was successful, proven by subsequent plaque assays with Kp hosts. Here, 100 μl of a 10^− 2 dilution of the supernatant of the transformation product containing TUN1 DNA resulted in 30 plaques. (Supplementary Figure S1).

The increasing spread of MRGN is a global problem [1]. Especially carbapenem-resistant K. pneumoniae (CRKP) pose a high risk in hospitals and other medical facilities. Liangfei Xu et al., reported 2-fold increased mortality among CRKP infected patients compared to those infected with carbapenem-susceptible K. pneumoniae (CSKP) [7].

Thus, alternative therapeutic approaches to antibiotic treatment are required. For CRKP infections, capsule-specific lytic bacteriophages are promising candidates [14, 17,18,19]. Knowledge of the K-type of the respective K. pneumoniae strains is therefore imperative.

This study reports the use of a rapid method to predict the K-type of Kp first described by Brisse et al. [13]. In total, 163 CRKP strains from a previously described Tunisian clinical specimen collection [Error! Reference source not found.] were capsule-typed. K-type K64 was not only identified as the most predominant K-type, but also as the K-type associated with the highest case/fatality rates of CRKP infected patients (> 70% in patients treated at the MHT ICU). This fits recent observations, both regarding the high case/fatality [6, 7] as well as the increased virulence of capsule type K64 [28].

However, the following limitations to this analysis have to be considered: i. the clinical specimen collection available lacks power in differentiating death caused by CRKP from any other factors, and it is difficult to draw definitive conclusions from current evidence because of the residual confounding factors and small sample sizes in many studies; ii. the study is retrospective in nature and thus susceptible to selection bias.

Kp can be found ubiquitously not only in human tissues but also in non-clinical sources, such as soil, drinking or surface waters and sewage [29]. This indicates that Kp phages should also be present in such environments and therefore easy to be isolated from nature.

In search of a potent tool to fight CRKP infections we looked for Klebsiella phages present at the MHT. Thereby we were able to obtain the lytic phage TUN1 from wastewater samples at the ICU using CRKP 7984 as a host strain. Based on BlastN analysis of the complete genome as well as morphologic characteristics phage TUN1 could be classified as bacteriophage of the genus Przondovirus, family Autographiviridae order Caudovirales, according to the newest species demarcation criteria set by the International Committee on Taxonomy of Viruses (ICTV) [23].

Phage TUN1 exhibited lysis specificity for Tunisian K64-type Kp strains. The replication cycle of 20 min and the burst size of 76 phage particles/cell are within the range described elsewhere [15,16,17,18,19]. The growth curve indicates that MOI = 1 reached approximately 60% of Kp cells, leading to a three-phased growth curve. While not classical, the three phases are distinguishable and similar enough to each other, to support the interpretation as a growth curve with 3 steps of 20 min, each, and a burst size of 76 particles per cell. As K64 was the most predominant K-type at the MHT, especially in the ICU, and all experiments were performed at 37 °C representing human body temperature, phage TUN1 appears to be a good candidate for phage therapy. Furthermore, unlike e.g. the mycobacterium abscessus phage used for therapy by Dedrick et al. [14] TUN1 is a purely lytic phage and therefore does not need removal of lysogenic elements form the genome.

However, with ~ 10 min, the latent time of phage TUN1 was found to be relatively short and the burst size with 76 phage particles/cell was on the lower end of productivity. Furthermore, the putative depolymerase seems to be very specific for K64 Kp strains.

Phage TUN1 was able to lyse more than two thirds but not all Kp strains of capsule type 64. Here, most probably factors other than capsule type like e.g. alternative receptor-binding proteins are involved in the process of phage-host recognition.

For future phage therapy applications, in addition to screening for naturally occurring broad-range bacteriophages, all desirable features such as strong lytic activity, absence of virulence factors and high phage stability could be combined via genetic engineering. The use of genetic elements with depolymerase activity, targeting additional clinically relevant capsule types, may lead to phages with broader host ranges, and therefore more promising candidates for phage therapy based on phage TUN1.

Conducting initial proof-of-principle experiments, we were able to show that phage TUN1 can be rescued in a non-replicative host (E. coli). In vitro assembly of therapeutic bacteriophages in the absence of live bacterial hosts would simplify the regulatory approval as the most common factors of concern like the presence of endotoxins or the possibility of host-DNA contamination, would be absent by default. A collaboration with the Walter Reed Army Institute of Research (WRAIR) is aiming for the development of technical approaches to field deployable therapeutic phage cocktails [30, 31].

The future goals of our current project at the Bundeswehr Institute of Microbiology are to i. identify and characterize bacteriophages against a broad range of Kp K-types found in German/Tunisian military and civilian hospitals; ii. develop technical approaches that allow genetic modification for the removal of unwanted genetic/lysogenic phage genome elements, possibly the addition of capsule specific factors and iii. Work out a pipeline for therapeutic phage production, that implements the highest safety standards, facilitating regulatory approval.

Such a pipeline could then be applied in both civilian and military hospitals, and eventually extended to products able to withstand the harsher conditions in military field settings.

In conclusion, 163 carbapenem-resistant K. pneumonia strains from a previously published MHT collection were capsule-typed. Furthermore, a lytic phage, vB_KpP_TUN1, specific for Kp capsule type K64 was isolated from wastewater samples and analyzed for its host range, morphology and genomic characteristics. K64, K17 and K27 were the most common wzi capsule types in this geographical location in Northern Africa, at the MHT, with K64 being predominant overall and in the ICU, were it caused increased case fatality rates. Geographical prevalence of K-types is a rationale behind priority phage production for therapy. Therefore, compassionate use of GMP-produced K64 Kp-specific bacteriophages at the MHT to control infections caused by multidrug-resistant K. pneumonia as adjuvant to antibiotic therapy is considered to be the next step forward. The genome of vB_KpP_TUN1 is devoid of lysogenic elements or toxins and therefore safe for use according to current standards in phage therapy. Future studies will focus on further improving the effectiveness in terms of host range and safety, of Kp-specific bacteriophages, for example by identification and removal of non-essential genes.

Clinical Kp strains used in this study

One hundred sixty-eight clinical Kp strains were isolated and characterized as described elsewhere following the operating procedure of the Military Hospital of Tunis [23]. Isolates were recovered from anal swabs (n = 32), axillary swabs (n = 2), a swab from a not-further defined location (n = 1), materials from broncho-alveolar lavages (BAL) (n = 5), blood cultures (n = 43), cytobacteriological examinations of sputum (CBES) (n = 5), cerebrospinal fluid (CSF) (n = 1), exudates from the ear (n = 2), biofilms at endotracheal tubes (n = 2), gastric samples (n = 1), catheters (n = 19), oral swabs (n = 1), protected tracheal sampling materials (PTS) (n = 12), PUS (n = 15), a medical device (n = 1), and urine (n = 26). A list of the different sample sources linked to the 163 identified capsule types can be found in Supplementary Table S2.

Kp capsule typing

To determine Kp capsular types (K-types), PCR-amplification of a 580-bp fragment of the wzi gene was performed according to Brisse et al., 2013 [13]. The respective PCR product was gel purified (QIAquick Gel Extraction Ki, Qiagen, Germany) and subsequently sent for sequencing (Eurofins Genomics, Germany).

wzi sequences were analyzed against the NCBI Genbank using BLASTN and the K-type alignments with the highest scores selected.

Bacteriophage isolation

Bacteriophages were isolated from wastewater samples from different locations in the MHT. To select bacteriophages, 10 mL of the sample was clarified by centrifugation at 7000 x g for 10 min at 4 °C, followed by filtration of the supernatant through a 0.2 μm pore size filter. 6.5 ml of the water sample was then mixed with 6 ml LB + 1 mM CaCl₂ solution and 60 μl of host bacterium using the strain 7984 (a K64-type Kp, the most common type found in the Tunis military hospital). For the host an over night (O/N) culture of the chosen host strain was diluted 1:100 in LB medium and grown until it reached an OD₆₀₀ of 0.4–0.5.

Subsequently, the mixture was incubated at 37 °C for 42 h. After 42 h the bacteria phage mixture was centrifuged at 7000 x g for 10 min at 4 °C to spin down most bacteria. The supernatant was then filtrated through a 0.2 μm pore size filter using a 20 ml syringe into a sterile tube. The filtrate, containing possible phages, was stored at 4 °C until further use.

Plaque assay and plaque purification

Plaque assays were conducted as described elsewhere [31]. In brief, 100 μl filtrated phage-solution were mixed with 350 μl of host Kp (OD₆₀₀nm = 0.4–0.6). 2.5 ml of 0.6% LB-agar (40 °C) containing 1 mM CaCl₂ were added and poured on a pre-prepared 2% (w/v) LB-agar plate. When the top-layer has hardened the plates were inverted and incubated O/N at 37 °C.

To purify a phage plaque. Kp strains were grown in LB-broth containing 1 mM CaCl₂ (37 °C, shaking) to OD₆₀₀ = 0.4–0.6. A single plaque from a previous plaque assay (based on size, reachability, representativeness) was picked with a sterile pipette tip, resuspended in a 15 mL Falcon with 350 μl bacteria and filled up with LB-broth to 5 ml. The tube was incubated (37 °C, shaking) for 3–6 h. To remove the remaining bacteria the tube was centrifuged at > 7000 g, for 10 min, ate 4 °C. The supernatant was filtrated through a 0.2 μm pore size filter under sterile conditions. The stock was stored at 4 °C until further use.

Tem

The purified phage solution was added to glow-discharged formvar-supported carbon-coated Cu400 TEM grids (FCF400-CU, Science Services, Munich, Germany) for 30 s, followed by a negative stain using a 2% aqueous uranyl formate solution with 25 mM sodium hydroxide for 45 s. This step is followed by a drying step under vacuum for 30 min. For imaging a Philips CM100 transmission electron microscope at 100 kV was used. For acquiring images an AMT 4 megapixel CCD camera was used and was performed at a magnification between × 15,500 and × 21,000. For image processing the plugin Scale Bar Tools for Microscopes for Java-based software ImageJ was used (version 1.80).

Host-range determination

Single colonies of Kp strains from a LB-agar-plate were resuspended in 5 mL LB-broth and 100 μl each were transferred into wells of a 96-well plate.

The phage stock was diluted to 10⁴ pfu/ml and 100 μl of phage or LB-broth were added to the bacteria. Bacterial growth was then monitored by measuring the OD_600nm every 60 min for 16 h at 37 °C under static conditions using a TECAN Spark Multireader.

TUN1 growth curve

Growth experiments were done as described by Delbrück and Ellis in 1939 [32]. Briefly, all Kp strains were grown in LB-broth containing 1 mM CaCl₂ (37 °C, shaking) to OD₆₀₀nm = 0.4–0.6. Klebsiella cells were counted in a haemocytometer and an infection with a MOI = 1 was prepared using a concentration of 1 × 10⁴ in 10 mL LB-broth.

Every 10–30 min a plaque assay with different dilutions (10⁰–10^− 2) using the top-layer method with LB-agar (0.6%, 40 °C), containing 1 mM CaCl₂, was performed. The plates were inverted and incubated overnight. On the next day titer and burst size were calculated by counting the plaque forming units (PFUs) using the formula: median number of plaques of t_{end of the replication cycle}/t_{start of the replication cycle} for MOI = 1.

Genome analysis

The phage DNA was prepared with Lucigen MasterPure™ Complete DNA and RNA Purification Kit (Cat.No. MC85200). Approximately 1 μg of DNA was used in library preparation for minION sequencing using the ligation sequencing kit (SQK-LSK109) following the manufacturer’s instructions (Oxford Nanopore Technology, UK). Base-calling was carried out with guppy v3.4.3. Genome assembly was carried out with Unicycler v0.4.5 [33] using all reads > 5 kb in length, with further polishing using Medaka. The genome was initially annotated with Prokka, with further annotation using the RAST server [34], followed by manual curation. Genomic termini were established using PhageTerm [35]. As the inbuilt aligner of PhageTerm does not map long reads a work around was developed. Reads were with mininmap2 v2.1 with the map-ont option and the start position and strand of each read extracted from the PAF file. This information was used to create pseudo set of short reads, by truncation of all reads to 150 nucleotides in length whilst maintaining the start position extracted from the long read data, required to determine the termini. This data was used input into PhageTerm using the –f option.

Sequencing was conducted from DNA samples by the MWG Eurofins GATC sequencing service.

Phage DNA transformation

Five μl of purified phage DNA were added to E. coli NEBstable C3040 and transformed by heatshock (42 °C for 90 s). Subsequently, 1 ml LB-broth was added and the bacteria were grown at 37 °C, shaking. After 2 h, 500 μl of the transformed bacteria solution were centrifuged and the supernatant was kept at 4 °C to perform subsequent plaque and spot assays on Kp strains.

The phage genome datasets generated and analysed during the current study are available at the European Nucleotide Archive (ENA) - https://www.ebi.ac.uk/ena/browser/view/PRJEB37291; sequence ID ERZ1741895. Furthermore, the assembly is also available at NCBI under the accession number HG994092.1 (https://0-www-ncbi-nlm-nih-gov.brum.beds.ac.uk/nuccore/HG994092.1).

CRKP:

Carapenem-resistant Klebsiella pneumoniae

CSKP:

Carbapenem-susceptible Klebiella pneumoniae

ICU:

Intensive care unit

IMB:

Bundeswehr Institute of Microbiology

K-type:

Capsule type

K64:

Capsule type 64

Kp :

Klebsiella pneumoniae

MDRB:

Multidrug-resistant bacteria

MHT:

Military Hospital of Instruction of Tunis

MOI:

Multiplicity of infection

MRGN:

Multidrug-resistant gram-negative bacteria

ORF:

Open reading frame

TEM:

Transmission electron microscopy

The authors thank Dr. Brett E. Swierczewski, CIDR/WRAIR, Silverspring, MD, U.S.A., Professor Christian Willy, Bundeswehrkrankenhaus Berlin, Germany, and members of the Bundeswehr Institute of Microbiology for critical reading of the manuscript.

This study was funded by the Medical Biological Defense Research Program of the Bundeswehr Medical Service.

1. Simone Eckstein, Jana Stender and Sonia Mzoughi contributed equally to this work.

Authors and Affiliations

1. Bundeswehr Institute of Microbiology, Munich, Germany

   Simone Eckstein, Jana Stender, Jana Kühn, Daniela Friese, Christina Bugert, Susann Handrick, Roman Wölfel & Joachim J. Bugert

2. Department of Virology, Military Hospital of Instruction of Tunis, Tunis, Tunisia

   Sonia Mzoughi & Mohamed Ben Moussa

3. Faculty of Pharmacy, Monastir, Tunisia

   Sonia Mzoughi

4. Department of Physics, Technical University of Munich, Garching, Germany

   Kilian Vogele

5. Department of Anesthesiology and Reanimation, Military Hospital of Instruction of Tunis, Tunis, Tunisia

   Mustapha Ferjani

6. Department of Genetics and Genome Biology, University of Leicester, Leicester, UK

   Andrew Millard

Contributions

Conceptualization: J.J.B. Methodology: J.J.B., S.M., J.S, K.V., J.K., D.F., C.B., and A.M. Software S.E. and A.M. Validation: S.E., J.S., and J.J.B. Formal analysis, S.E., J.S., S.M., A.M., and J.J.B. Investigation: J.J.B. Resources: J.J.B., S.H., A.M., and R.W. Data curation: J.S., A.M. and D.F. Writing—original draft preparation: S.E., J.S., S.M., and J.J.B. Writing—review and editing: S.E., J.S. A.M. and J.J.B. Visualization: S.E., J.S. and J.J.B. Supervision in hospital and lab: J.J.B. (IMB), M.F. and M.B.M. (MHT). Project administration: J.J.B. Funding acquisition: R.W., S.H. and J.J.B. All authors have read and agreed to the published version of the manuscript.

Corresponding author

Correspondence to Joachim J. Bugert.

Ethics approval and consent to participate

The clinical material used in this study was part of the retrospective and investigator-blinded study previously published by Kollenda et al. 2019 [23] for which ethical approval was waived by the Ethics Committee of the Medical Association of Hamburg, Germany (registration number WF-023/18). All procedures to obtain the bacterial isolate collection for this study were in accordance with the national Tunisian and German ethical standards and with the 1964 Helsinki declaration and its later amendments or comparable ethical standards. Informed consent for the study using the anonymized Kp isolate collection was waived as part of the vote of the Ethics Committee of the Medical Association of Hamburg, Germany (registration number WF-023/18).

The use of the Kp strains was authorized by the Tunisian coauthors of the study (S.M., M.F., and M.B.M.) in a MTA between IMB and MHT.

Consent for publication

Not applicable.

Competing interests

The authors declare that they have no competing interests.

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