Next Article in Journal
Is Early Oral Antimicrobial Switch Useful for Less Critically Ill Adults with Community-Onset Bacteraemia in Emergency Departments?
Next Article in Special Issue
Extended Spectrum Beta-Lactamase-Resistant Determinants among Carbapenem-Resistant Enterobacteriaceae from Beef Cattle in the North West Province, South Africa: A Critical Assessment of Their Possible Public Health Implications
Previous Article in Journal
λ Recombineering Used to Engineer the Genome of Phage T7
Previous Article in Special Issue
Molecular Epidemiology of Carbapenemases in Enterobacteriales from Humans, Animals, Food and the Environment
 
 
Font Type:
Arial Georgia Verdana
Font Size:
Aa Aa Aa
Line Spacing:
Column Width:
Background:
Article

Multiplicity of Carbapenemase-Producers Three Years after a KPC-3-Producing K. pneumoniae ST147-K64 Hospital Outbreak

1
UCIBIO, Faculdade de Farmácia, Universidade do Porto, 4050-313 Porto, Portugal
2
Centro Hospitalar Vila Nova de Gaia/Espinho, 4434-502 Vila Nova de Gaia, Portugal
*
Authors to whom correspondence should be addressed.
Submission received: 6 October 2020 / Revised: 5 November 2020 / Accepted: 7 November 2020 / Published: 13 November 2020
(This article belongs to the Special Issue Carbapenemase-Producing Enterobacterales)

Abstract

:
Carbapenem resistance rates increased exponentially between 2014 and 2017 in Portugal (~80%), especially in Klebsiella pneumoniae. We characterized the population of carbapanemase-producing Enterobacterales (CPE) infecting or colonizing hospitalized patients (2017–2018) in a central hospital from northern Portugal, where KPC-3-producing K. pneumoniae capsular type K64 has caused an initial outbreak. We gathered phenotypic (susceptibility data), molecular (population structure, carbapenemase, capsular type) and biochemical (FT-IR) data, together with patients’ clinical and epidemiological information. A high diversity of Enterobacterales species, clones (including E. coli ST131) and carbapenemases (mainly KPC-3 but also OXA-48 and VIM) was identified three years after the onset of carbapenemases spread in the hospital studied. ST147-K64 K. pneumoniae, the initial outbreak clone, is still predominant though other high-risk clones have emerged (e.g., ST307, ST392, ST22), some of them with pandrug resistance profiles. Rectal carriage, previous hospitalization or antibiotherapy were presumptively identified as risk factors for subsequent infection. In addition, our previously described Fourier Transform infrared (FT-IR) spectroscopy method typed 94% of K. pneumoniae isolates with high accuracy (98%), and allowed to identify previously circulating clones. This work highlights an increasing diversity of CPE infecting or colonizing patients in Portugal, despite the infection control measures applied, and the need to improve the accuracy and speed of bacterial strain typing, a goal that can be met by simple and cost-effective FT-IR based typing.

1. Introduction

The dissemination of carbapenemase-producing Enterobacterales (CPE) has been causing serious concerns in many EU countries due to the limited therapeutic options and ineffective infection control policies [1,2]. Portugal is one of the EU countries where the rates of carbapenems resistance amongst invasive isolates has been alarmingly rising (~80% between 2014 and 2017), especially among Klebsiella pneumoniae for which reported rates in 2018 were 11.7% [3,4]. Reporting of CPE from national laboratories is mandatory since 2013 and recommendations to control CPE spread that include identification of rectal carriers and improvement of infection control policies in the hospital setting have been officially launched in 2017 [5].
Available data on molecular epidemiology and population structure of CPE populations in the country represent scattered snapshots on particular species and/or small institutions. The ST147 K. pneumoniae clone exhibiting K-type K64 has been one of the first responsible for KPC-3 spread in diverse healthcare settings in the north of Portugal [6,7]. It was responsible for the first large outbreak of CPE in a reference hospital from the north of Portugal in 2015 [8] and it has been described in other regions [9,10]. Analysis of recent CPE collections is still scarce and there is limited analysis on risk factors and the effect of infection control policies in a single institution.
Considering that precise and timely bacterial typing information can make the difference in the effectiveness of infection control measures, we have recently proposed a quick and cost-effective approach for accurate K. pneumoniae typing based on an in-house database of Fourier-Transform Infrared (FT-IR) discriminatory spectra [11].
In the present study, we aim to understand the evolution of CPE population in a central hospital from northern Portugal three years after the onset of carbapenemases spread [8] in order to identify critical factors for the increasing burden of CPE in hospitalized patients. Moreover, we use this collection to evaluate the performance of our method for accurate subtyping of K. pneumoniae contemporaneous isolates.

2. Results

2.1. The Incresasing Diversity of CPE Population

Carbapenemase production was confirmed in 120 out of the 128 (94%) recovered isolates, that were subsequently characterized. The remaining ones were possible ESBL producers with permeability defects. These 120 isolates were identified in rectal swabs (n = 86) and clinical samples (n = 34) from 114 patients. Multiple Enterobacterales species were identified in either clinical samples or rectal swabs, though K. pneumoniae was by far the most frequent (n = 98; n = 66 from rectal swabs and n = 32 from clinical samples) (Table 1). While nearly all isolates from infection belonged to K. pneumoniae (n = 32/34; 94%), the isolates from fecal samples presented a greater diversity, including mostly K. pneumoniae (n = 66/86; 76.7%), but also E. coli (n = 10/86; 11.6%), different E. cloacae complex species including E. asburiae and E. hormaechei (n = 5/86; 5.8%), K. oxytoca (n = 4/86; 4.7%), and Citrobacter freundii complex (n = 1/86; 1.2%), the latter two appearing exclusively in colonization samples. E. coli was identified mainly from rectal swabs (n = 10/11; 91%). Most isolates produced KPC-3 (n = 118/120; 98.3%) including all K. pneumoniae, but OXA-48 and VIM-1 were also occasionally detected in 1 E. coli clinical isolate and 1 E. hormaechei identified as a gastrointestinal colonizer, respectively. mcr genes were not detected.
Simultaneous rectal carriage (in the same sample) by two different species of CPE (K. pneumoniae and E. coli) or two different K. pneumoniae clones was found in four and one patients, respectively. In all cases, both species/clones were KPC-3 producers, which may indicate the interspecies transfer of a KPC-3-encoding plasmid. In the only case where isolates from urine and blood were recovered from the same patient, they had identical phenotype and genotype.

2.2. Epidemiological and Clinical Data of Patients Carrying CPE Isolates

Patient’s age ranged from 20 years to 96 years, with mean age of 74 ± 14 years (median 78 years) and female patients were predominant (59% female versus 41% male). They were mostly located in medical (n = 55, 48%) or surgical (n = 51; 45%) wards, whereas seven (6%) of them were patients attending the emergency room, and 1 (0.9%) was at intensive care unit. Clinical isolates (n = 34) were identified mostly at surgical units (n = 17/34; 50%), whereas isolates from rectal screenings were obtained mostly from medical wards (n = 50/86; 58%).
The clinical isolates were identified in urine (n = 20; 57%) and pus (n = 7; 21%) but also in blood (n = 3; 9%), biologic liquid (n = 2; 6%), or respiratory samples (n = 2; 6%). The majority of them were K. pneumoniae (n = 32/34; 94%), but also E. cloacae (n = 1/34; 3%) or E. coli (n = 1/34; 3%). Clinical isolates were identified in 4 medical units (internal medicine was the most frequent, 55%) and 7 surgical units (many from women’s surgery department, 35%). Only ten of the patients with clinical isolates were primarily diagnosed with infectious diseases at ICU, emergency or medical units, whereas in many of the other patients, infection occurred during hospitalization for a median of 30 days (Table 2). Most infected patients (93%) were previous colonized (0–421 days, mean 44 days), most of them in the month previous to infection. Isolates from outpatients (n = 6; 74–94 years old) were collected from urine (n = 5/7; 71%) and blood (n = 2/7; 2.9%). Three of these outpatients were previous CPE carriers from previous hospitalizations, and two of the other three patients had been hospitalized in the last month, all of this suggesting nosocomial acquisition. Most of these patients (70%) received antibiotherapy in the three months prior to infection, even most (87%) of those that were not diagnosed with infectious diseases.
Isolates from rectal swabs were collected from patients at 9 medical (n = 56; 65%) or 7 surgical units (n = 29, 34%). Internal medicine (n = 24; 43%) and unit III (a satellite hospital at a 23Km distance, n = 10; 18%) were the most frequent units within the medical department, whereas orthopedics and women’s surgery (n = 8; 23% each) were the most common units within surgical departments. Of highlight, a portion of isolates (n = 22, 26%) from both medical and surgical units were recovered from 20 patients identified as CPE carriers that were selected for decolonization protocol by gentamicin use. Eight of them were being followed for long periods of time (between 2016 and mid 2017). From these, most (87.5%) had at least one negative CPE screening, on average, 208 days after initial gentamicin treatment though 3 negative rectal screenings are needed to consider a successful decolonization.
In total, from the 81 patients screened for CPE in rectal swabs, 26 (32%) patients had positive screenings from previous hospitalizations at this hospital. From the 42 (52%) de novo CPE carriers, most had long (>14 days) hospitalization periods (n = 22; 52%) or had had previous antibiotherapy treatments (n = 17; 40%). The remaining 13 screening samples belonged to patients (16%) with no history of screenings.
In relation to antibiotic exposure, 39 from the 42 de novo colonized patients (93%) were exposed to antimicrobials in the previous three months. The main antibiotics administered were piperacillin plus tazobactam (27%), amoxicillin plus clavulanic acid (20%), and broad spectrum cephalosporins (10% ceftriaxone).
K. pneumoniae isolates were distributed among all origins (50% medical, 41% surgical, 8% emergency room, 1% ICU), whereas six out of the 11 E. coli isolates were recovered from patients under decolonization protocol (n = 6/11, 55%) and E. cloacae complex, K. oxytoca, and C. freundii complex were identified mainly or exclusively in surgical units (83%, 75%, and 100%, respectively).

2.3. Multiplicity of Clonal Lineages and Emergence of Other International High-Risk Clones

Using our FT-IR spectral workflow and database (11), we were able to predict the capsular type of 94% of the K. pneumoniae isolates (6 isolates were not predicted by our model). From those, we grouped isolates in 9 clones. Four of them had identity with capsular types included in our model and identified as K64 (ST147), KL112 (ST15), K19 (ST15), and KL105 (ST11). The remaining five were predicted as not belonging to any of the 19 classes (K-types) included in our model. Indeed, they were subsequently identified as K9 (ST22), KL27 (ST392), KL102 (ST307), KL15/KL17/KL51/KL52 (not typed by MLST), or K53 (not typed by MLST). Only two isolates (2%) were incorrectly predicted (Table 3).
Three years after the initial outbreak, ST147-K64 is still the predominant K. pneumoniae clone (55% overall) responsible for 62.5% of CPE infections and also the most frequent K. pneumoniae colonizer (52%). They were recovered from patients at several medical or surgical units (50% vs 39%, respectively) and also in patients at emergency room (11%). The second most represented clone was ST392-KL27 (20.4%) that was mainly identified in medical wards (85%) in February 2018 (Table 3). A diversity of other clones including ST22-K9 (5.1%), ST307-KL102 (4.1%), ST15-K19 (3%), ST15-KL112 (2%), or others were identified as colonizers before or after infections (Table 3).
The carbapenem resistant E. coli isolates belonged to distinct phylo-groups, being B2 the most prevalent one (n = 5; 46%), followed by groups A (n = 2; 18%), E (n = 2; 18%), B1 (n = 1, 9%), and F (n = 1, 9%). One of the B2 E. coli producing KPC-3 belonged to the worldwide disseminated clone ST131 (Table 4).

2.4. A Variety of Multidrug Resistance Profiles

All isolates showed multidrug resistance (MDR) phenotypes and were resistant to third generation cephalosporins (100%) and beta-lactam/beta-lactamase inhibitors (100%) and the vast majority was resistant to ciprofloxacin (90%). All carbapenemase producers tested were nonsusceptible to ertapenem (97% resistant, 3% intermediate) and demonstrated susceptible (S), intermediate (I), or resistance (R) phenotypes to imipenem (61% R, 32% I, 7% S) and meropenem (54% R, 31% I, 15% S). Conversely, amikacin (94%), as well as tigecycline (95%), tetracycline (80%), chloramphenicol (80%), or fosfomycin (78%) had the highest susceptibility rates.
Susceptibility patterns varied according to species and clone. Besides third generation cephalosporins, carbapenems and ciprofloxacin, ST307 and ST22 K. pneumoniae were resistant or intermediate to all aminoglycosides (except amikacin), and ST22 additionally to trimethoprim/trimethoprim-sulfamethoxazole and chloramphenicol. ST147 and ST392 were variably resistant to aminoglycosides (ST147-29%; ST392-57%) other than amikacin, trimethoprim-sulfamethoxazole (ST147-46%; ST392-43%). The clinical E. cloacae isolate was the most susceptible in this study (susceptibility to all aminoglycosides, ciprofloxacin, chloramphenicol, tetracycline, tigecycline, trimethoprim, and trimethoprim-sulfamethoxazole). On the contrary, the clinical OXA-48-producing E. coli was susceptible only to meropenem/imipenem, tetracycline, tigecycline, and chloramphenicol.

3. Discussion

This study highlights a high multiplicity of species, clones, and carbapenemases three years after the initial outbreak by KPC-3-producing K. pneumoniae ST147, irrespective of the infection control measures applied. This information, together with epidemiological and patients’ data is critical to understand galloping carbapenems resistance rates in our country and support the revision of infection control measures. To our knowledge, this is the first study providing a comprehensive analysis of the molecular epidemiology of CPE in a single institution in our country in two different time-points of CPE spread, towards a comprehension of factors driving their extraordinary increase. The multiplicity of carbapenemase-producing clones and Enterobacterales species, together with data from previous studies in Portugal [7,9,10,12], highlights successful horizontal transfer of carbapenemases that might occur during gastrointestinal colonization, which represents an additional challenge for infection control.
In contrast to previous studies [9,10,12], ST147-K64 K. pneumoniae is still the predominant clone in different healthcare settings in our area. Its identification in patients that are colonized or infected in multiple occasions throughout time, and its dispersion in other community-based healthcare-associated settings suggests possible reintroductions of this highly transmissible clone in the hospital. The emergence of other KPC-3-producing high-risk K. pneumoniae clones with recognized worldwide expansion (ST392, ST307) and additional enhanced virulence and/or antibiotic resistance (ST307, ST22) is of concern. The ST392 clone has been recently reported in other countries (China, Italy, Mexico) [13,14,15] but to our knowledge this is the first study to describe KPC-3-producing K. pneumoniae ST392 isolates in Portugal. Although detected in small numbers, the identification of 4 ST307 isolates producing KPC-3 among medical and surgical units is of great concern because of its higher resistance profile and the recognized virulence potential (high resistance to complement-mediated killing) of this high-risk clone reported worldwide [16,17]. Our data confirms the absence of ST258 K. pneumoniae in our country, a clone that is well-established in other neighboring European countries [18,19]. Furthermore, the detection of ST131 E. coli producing KPC-3 especially as rectal colonizers poses a major threat to public health, since it has the potential to cause widespread resistance to carbapenems in the community setting.
We demonstrated an excellent performance of our FT-IR based approach for subtyping multidrug resistant K. pneumoniae populations, that was corroborated by reference genotypic molecular methods. Isolates relationships’ were correctly established for 98% of the isolates and, for some of them, it was possible to identify previously circulating K. pneumoniae lineages (e.g., ST147-K64, ST15-K19) for which epidemiological data and resistance patterns are well-known [7,11]. This information is useful for infection control teams in order to more quickly and effectively implement measures to control the spread of problematic lineages and eventually guide antibiotic therapy. Thus, the high accuracy of the method, together with its simplicity and extremely short time-to-response (we can provide results from 1-3h after standardized growth conditions) represent ideal features for routine implementation and a real-time support to infection control in the context of outbreak detection [8] or epidemiological surveillance (this study). New K-types and clones were introduced in our spectral database for further improvement of the model and correct predictions of future unknown isolates.
Besides establishing the potential for diversification of the CPE population, the data obtained in this study were critical to support more targeted infection approaches in the most affected units (medical and surgical wards) and to control the spread of ST392 in medical units (data now shown). The high number of CPE in internal medicine (22.5%) is in agreement with previous data [9], and occurs due to the higher burden of elderly patients, long hospitalization periods and the higher frequency of invasive procedures [20]. Besides, reinforcement of medical equipment, surfaces’ cleaning and contact precautions between patients and healthcare professionals is critical to control the situation [21]. From the data presented, it can be concluded that nearly all de novo CPE carriers (n = 43; 96%) became colonized by CPE after hospital admission which strongly supports nosocomial acquisition. Previous colonization and exposure to antibiotics in the previous three months were also recognized as risk factors for development of CPE infections, as previously [20]. Patients maintained carrier status over 200 days, raising questions about the effectiveness of routine decolonization protocols that would need to be evaluated in a longer period and a larger sample. In any case, it is known that available data varies according to decolonization strategy and the benefits are still questionable, and for that reason routine decolonization of CPE is not recommended [22].
In conclusion, this work highlights an increasing diversity of CPE infecting or colonizing hospitalized patients in a central hospital from the north of Portugal, even after implementation of recommended infection control measures guided by clinical and epidemiological data and routine rectal screening results. These results alert for the need to improve the accuracy and speed of bacterial strain typing information, a goal that can be met by simple and cost-effective FT-IR based typing. We strongly believe that, together with epidemiological data and antibiotic resistance patterns, it can be an asset to support infection control and patient’s management in real-time.

4. Materials and Methods

4.1. Study Design and CPE sample

The hospital studied is a central and reference hospital located in the north of Portugal that includes 3 units and 1 rehabilitation center that serves 700.000 inhabitants of that region. It contains capacity for 580-beds, and offers healthcare specialties within medical, surgical, and emergency (adults and pediatric) wards as well as attendance to outpatients.
In this hospital, the first noticed outbreak by CPE occurred in 2015 by a multidrug resistant KPC-3 producing K. pneumoniae ST147 clone with capsular (K)-type 64, that caused the death of 3 patients [8]. From then, the hospital implemented standard infection control measures (including active screening, isolation and contact precautions for infected or colonized patients) that are still in use; however, CPE increased throughout time.
At the hospital, suspected CPE isolates (n = 128) identified from either clinical samples (n = 35, November 2017-February 2018) or from rectal swabs (n = 93 in February 2018) from hospitalized patients were collected. Screenings of CPE in rectal swabs were performed: (i) at admission in high-risk patients, i.e. those with hospitalizations longer than 72 h in the last 6 months or transferred from another healthcare institution; (ii) at 48 h of hospitalization when the result is negative at admission; (iii) each 7 days of hospitalization if the prior result is negative.
At admission, CPE colonizers were detected by molecular biology using Xpert CarbaR (Cepheid), whereas subsequent screenings on hospitalized patients were performed using a cultural method. Rectal swabs (positive for Xpert CarbaR and subsequent screenings) were plated on the chromogenic agar chromID Carba Smart (bioMérieux) for recovery of carbapenem resistant isolates. Presumptive Enterobacterales isolates (pink colonies for E. coli and bluish-green colonies for Klebsiella, Enterobacter, Serratia or Citrobacter sp.) were selected for further characterization (>1 isolate per sample was studied when representing different morphotypes or species).
All patients with positive results were transferred to cohort areas and submitted to infection control measures. We collected patients’ data (age, gender, underlying conditions), hospitalization, and rectal screening history and previous antibiotherapy.

4.2. CPE Identification and Antibiotic Susceptibility Testing

Isolates from clinical samples were identified and preliminarily tested for antibiotic susceptibility by VITEK®2 system (bioMérieux). When necessary, species identification was confirmed by MALDI-TOF MS (VITEK MS, bioMérieux) and further sequencing of leuS for speciation within Enterobacter cloacae species [23].
Extended antibiotic susceptibility profiles were subsequently obtained by disk diffusion for 20 antibiotics (cefotaxime, ceftazidime, cefepime, ertapenem, meropenem, imipenem, amoxicillin-clavulanic acid, piperacillin-tazobactam, amikacin, tobramycin, gentamicin, kanamycin, netilmicin, ciprofloxacin, tetracycline, tigecycline, fosfomycin, trimethoprim, trimethoprim-sulfamethoxazole, and chloramphenicol), according to EUCAST guidelines (www.eucast.org) and CLSI [24].

4.3. Molecular Characterization of CPE Producers

Carbapenemase production was confirmed by the Blue-Carba test [25] and the type of carbapenemase was identified by PCR directed to the most frequent carbapenemase gene families (blaKPC, blaOXA-48, blaIMP; blaVIM, blaNDM) and further sequencing [7,26]. mcr genes (mcr-1 to mcr-5) were sought by a multiplex PCR previously described [27] in representative isolates from different clones and species.

4.4. FT-IR for Subtyping of K. pneumoniae Carbapenemase Producers

The relationship between K. pneumoniae isolates was established by Fourier Transform Infrared (FT-IR) spectroscopy using our previously described workflow [11]. Briefly, bacterial spectra were acquired in standardized conditions and compared with those from our in-house K. pneumoniae database (including 19 international clones/K-types) for identification of capsular (K) types and because of established K-type and clone relationships, presumptive clonal identification. These FT-IR-based assignments were confirmed by PCR and sequencing of wzi gene [11,28] and multi-locus sequence typing (MLST) using the seven housekeeping genes (gapA, infB, pgi, mdh, phoE, rpoB, tonB) proposed in Pasteur MLST scheme in representative isolates of clones with >3 isolates each (https://bigsdb.pasteur.fr/klebsiella/klebsiella.html).
E. coli phylogenetic groups were identified by PCR, according to the quadriplex method described by Clermont et al. [29]. E. coli ST131 was presumptively identified by a specific PCR in isolates belonging to the phylogenetic group B2 and fumC sequencing [30].

Author Contributions

A.M.G. was responsible for the experimental work and wrote the paper. A.L. (Agostinho Lira), A.L. (Angelina Lameirão), A.S., G.A., P.L. and M.M. were responsible for screening and preliminary identification of CPE isolates, and provided the epidemiological and clinical data. Â.N., together with L.P., designed the study, supervised the experimental work and revised the paper. All authors have read and agreed to the published version of the manuscript.

Funding

This work received financial support from Applied Molecular Biosciences Unit UCIBIO, which is supported by national funds from Fundação para a Ciência e a Tecnologia (FCT)/MCTES [UID/Multi/ UIDB/04378/2020]. Ângela Novais is supported by national funds through FCT, I.P., in the context of the transitional norm [DL57/2016/CP1346/CT0032]. We are also grateful to BioMerieux for the support in microbiological media used in this study.

Conflicts of Interest

The authors declare no conflict of interest.

References

  1. Cassini, A.; Högberg, L.D.; Plachouras, D.; Quattrocchi, A.; Hoxha, A.; Simonsen, G.S.; Colomb-Cotinat, M.; E Kretzschmar, M.; Devleesschauwer, B.; Cecchini, M.; et al. Attributable deaths and disability-adjusted life-years caused by infections with antibiotic-resistant bacteria in the EU and the European Economic Area in 2015: A population-level modelling analysis. Lancet Infect. Dis. 2019, 19, 56–66. [Google Scholar] [CrossRef] [Green Version]
  2. A Bonomo, R.; Burd, E.M.; Conly, J.; Limbago, B.M.; Poirel, L.; A Segre, J.; Westblade, L.F. Carbapenemase-Producing Organisms: A Global Scourge. Clin. Infect. Dis. 2017, 66, 1290–1297. [Google Scholar] [CrossRef] [PubMed]
  3. European Centre for Disease Prevention and Control. Surveillance of Antimicrobial Resistance in Europe—Annual Report of the European Antimicrobial Resistance Surveillance Network (EARS-Net) 2017; ECDC: Stockholm, Sweden, 2018.
  4. Direção-Geral da Saúde. Infeções e Resistências aos Antimicrobianos: Relatório Anual do Programa Prioritário. 2018. Available online: https://www.dgs.pt/portal-da-estatistica-da-saude/diretorio-de-informacao/diretorio-de-informacao/por-serie-1003038-pdf.aspx?v=%3d%3dDwAAAB%2bLCAAAAAAABAArySzItzVUy81MsTU1MDAFAHzFEfkPAAAA (accessed on 21 June 2020).
  5. Direção-Geral da Saúde. Vigilância Epidemiológica das Resistências aos Antimicrobianos; Norma nº 004/2013. 2013. Available online: https://www.dgs.pt/directrizes-da-dgs/normas-e-circulares-normativas/norma-n-0042013-de-21022013-jpg.aspx (accessed on 21 June 2020).
  6. Rodrigues, C.; Machado, E.; Ramos, H.; Peixe, L.; Novais, Â. Expansion of ESBL-producing Klebsiella pneumoniae in hospitalized patients: A successful story of international clones (ST15, ST147, ST336) and epidemic plasmids (IncR, IncFIIK). Int. J. Med. Microbiol. 2014, 304, 1100–1108. [Google Scholar] [CrossRef] [PubMed]
  7. Rodrigues, C.; Bavlovič, J.; Machado, E.; Amorim, J.; Peixe, L.; Novais, Â. KPC-3-Producing Klebsiella pneumoniae in Portugal Linked to Previously Circulating Non-CG258 Lineages and Uncommon Genetic Platforms (Tn4401d-IncFIA and Tn4401d-IncN). Front. Microbiol. 2016, 7, 1000. [Google Scholar] [CrossRef] [Green Version]
  8. Silva, L.; Rodrigues, C.; Lira, A.; Leão, M.; Mota, M.; Lopes, P.; Novais, Â.; Peixe, L. Fourier transform infrared (FT-IR) spectroscopy typing: A real-time analysis of an outbreak by carbapenem-resistant Klebsiella pneumoniae. Eur. J. Clin. Microbiol. Infect. Dis. 2020, 1–5. [Google Scholar] [CrossRef]
  9. Aires-De-Sousa, M.; De La Rosa, J.M.O.; Gonçalves, M.L.; Pereira, A.L.; Nordmann, P.; Poirel, L. Epidemiology of Carbapenemase-Producing Klebsiella pneumoniae in a Hospital, Portugal. Emerg. Infect. Dis. 2019, 25, 1632–1638. [Google Scholar] [CrossRef] [Green Version]
  10. Perdigão, J.; Modesto, A.; Pereira, A.L.; Neto, O.; Matos, V.; Godinho, A.; Phelan, J.; Charleston, J.; Spadar, A.; De Sessions, P.F.; et al. Whole-genome sequencing resolves a polyclonal outbreak by extended-spectrum beta-lactam and carbapenem-resistant Klebsiella pneumoniae in a Portuguese tertiary-care hospital. Microb. Genom. 2020, 10, mgen000349. [Google Scholar] [CrossRef]
  11. Rodrigues, C.; Sousa, C.; Lopes, J.A.; Novais, Â.; Peixe, L. One the front line of Klebsiella pneumoniae surface structures understanding: Establishment of Fourier Transform Infrared (FT-IR) spectroscopy as a capsule typing method. mSystems 2020. [Google Scholar] [CrossRef] [Green Version]
  12. Manageiro, V.; Romão, R.; Moura, I.B.; Sampaio, D.A.; Vieira, L.; Ferreira, E.; Caniça, M.; EuSCAPE-Portugal, the N. Molecular Epidemiology and Risk Factors of Carbapenemase-Producing Enterobacteriaceae Isolates in Portuguese Hospitals: Results from European Survey on Carbapenemase-Producing Enterobacteriaceae (EuSCAPE). Front. Microbiol. 2018, 9, 2834. [Google Scholar] [CrossRef] [Green Version]
  13. Bocanegra-Ibarias, P.; Garza-González, E.; Morfín-Otero, R.; Barrios, H.; Villarreal-Treviño, L.; Rodríguez-Noriega, E.; Garza-Ramos, U.; Petersen-Morfin, S.; Silva-Sanchez, J. Molecular and microbiological report of a hospital outbreak of NDM-1-carrying Enterobacteriaceae in Mexico. PLoS ONE 2017, 12, e0179651. [Google Scholar] [CrossRef]
  14. Esposito, E.P.; Cervoni, M.; Bernardo, M.; Crivaro, V.; Cuccurullo, S.; Imperi, F.; Zarrilli, R. Molecular Epidemiology and Virulence Profiles of Colistin-Resistant Klebsiella pneumoniae Blood Isolates from the Hospital Agency “Ospedale dei Colli”, Naples, Italy. Front. Microbiol. 2018, 9, 1463. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  15. Yang, J.; Ye, L.; Guo, L.; Zhao, Q.; Chen, R.; Luo, Y.; Chen, Y.; Tian, S.; Zhao, J.; Shen, D.; et al. A nosocomial outbreak of KPC-2-producing Klebsiella pneumoniae in a Chinese hospital: Dissemination of ST11 and emergence of ST37, ST392 and ST395. Clin. Microbiol. Infect. 2013, 19, E509–E515. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  16. Castanheira, M.; Farrell, S.E.; Wanger, A.; Rolston, K.V.; Jones, R.N.; Mendes, R.E. Rapid Expansion of KPC-2-Producing Klebsiella pneumoniae Isolates in Two Texas Hospitals due to Clonal Spread of ST258 and ST307 Lineages. Microb. Drug Resist. 2013, 19, 295–297. [Google Scholar] [CrossRef] [PubMed]
  17. Villa, L.; Feudi, C.; Fortini, D.; Brisse, S.; Passet, V.; Bonura, C.; Endimiani, A.; Mammina, C.; Ocampo, A.M.; Jimenez, J.N.; et al. Diversity, virulence, and antimicrobial resistance of the KPC-producing Klebsiella pneumoniae ST307 clone. Microb. Genom. 2017, 3, e000110. [Google Scholar] [CrossRef]
  18. Soria-Segarra, C.; González-Bustos, P.; López-Cerero, L.; Fernández-Cuenca, F.; Rojo-Martín, M.D.; Fernández-Sierra, M.A.; Gutiérrez-Fernández, J. Tracking KPC-3-producing ST-258 Klebsiella pneumoniae outbreak in a third-level hospital in Granada (Andalusia, Spain) by risk factors and molecular characteristics. Mol. Biol. Rep. 2019, 47, 1089–1097. [Google Scholar] [CrossRef]
  19. David, S.; The EuSCAPE Working Group; Reuter, S.; Harris, S.R.; Glasner, C.; Feltwell, T.; Argimon, S.; AbuDahab, K.; Goater, R.; Giani, T.; et al. Epidemic of carbapenem-resistant Klebsiella pneumoniae in Europe is driven by nosocomial spread. Nat. Microbiol. 2019, 4, 1919–1929. [Google Scholar] [CrossRef]
  20. Mathers, A.; Vegesana, K.; German-Mesner, I.; Ainsworth, J.; Pannone, A.; Crook, D.; Sifri, C.; Sheppard, A.; Stoesser, N.; Peto, T.; et al. Risk factors for Klebsiella pneumoniae carbapenemase (KPC) gene acquisition and clinical outcomes across multiple bacterial species. J. Hosp. Infect. 2020, 104, 456–468. [Google Scholar] [CrossRef] [Green Version]
  21. De Rosa, F.G.; Corcione, S.; Cavallo, R.; Di Perri, G.; Bassetti, M. Critical issues for Klebsiella pneumoniae KPC-carbapenemase producing K. pneumoniae infections: A critical agenda. Future Microbiol. 2015, 10, 283–294. [Google Scholar] [CrossRef]
  22. Tacconelli, E.; Mazzaferri, F.; De Smet, A.M.; Bragantini, D.; Eggimann, P.; Huttner, B.D.; Kuijper, E.J.; Lucet, J.-C.; Mutters, N.T.; Sanguinetti, M.; et al. ESCMID-EUCIC clinical guidelines on decolonization of multidrug-resistant Gram-negative bacteria carriers. Clin. Microbiol. Infect. 2019, 25, 807–817. [Google Scholar] [CrossRef] [Green Version]
  23. Miyoshi-Akiyama, T.; Hayakawa, K.; Ohmagari, N.; Shimojima, M.; Kirikae, T. Multilocus Sequence Typing (MLST) for Characterization of Enterobacter cloacae. PLoS ONE 2013, 8, e66358. [Google Scholar] [CrossRef] [Green Version]
  24. Clinical and Laboratory Standards Institute. Performance Standards for Antimicrobial Susceptibility Testing: M100-S27; Clinical and Laboratory Standards Institute: Wayne, PA, USA, 2017. [Google Scholar]
  25. Pires, J.; Novais, A.; Peixe, L. Blue-Carba, an Easy Biochemical Test for Detection of Diverse Carbapenemase Producers Directly from Bacterial Cultures. J. Clin. Microbiol. 2013, 51, 4281–4283. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  26. Bogaerts, P.; Rezende de Castro, R.; de Mendonça, R.; Huang, T.D.; Denis, O.; Glupczynski, Y. Validation of carbapebemase and extended-spectrum β-lactamase multiplex endpoint PCR assays according to ISO 15189. J. Antimicrob. Chemother. 2013, 68, 1576–1582. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  27. Rebelo, A.R.; Bortolaia, V.; Kjeldgaard, J.S.; Pedersen, S.K.; Leekitcharoenphon, P.; Hansen, I.M.; Guerra, B.; Malorny, B.; Borowiak, M.; Hammerl, J.A.; et al. Multiplex PCR for detection of plasmid-mediated colistin resistance determinants, mcr-1, mcr-2, mcr-3, mcr-4 and mcr-5 for surveillance purposes. Eurosurveillance 2018, 23, 17-00672. [Google Scholar] [CrossRef] [PubMed]
  28. Brisse, S.; Passet, V.; Haugaard, A.B.; Babosan, A.; Kassis-Chikhani, N.; Struve, C.; Decré, D. wzi Gene Sequencing, a Rapid Method for Determination of Capsular Type for Klebsiella Strains. J. Clin. Microbiol. 2013, 51, 4073–4078. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  29. Clermont, O.; Christenson, J.K.; Denamur, E.; Gordon, D.M. The ClermontEscherichia coliphylo-typing method revisited: Improvement of specificity and detection of new phylo-groups. Environ. Microbiol. Rep. 2012, 5, 58–65. [Google Scholar] [CrossRef]
  30. Rodrigues, C.; Machado, E.; Fernandes, S.; Peixe, L.; Novais, Â. An update on faecal carriage of ESBL-producing Enterobacteriaceae by Portuguese healthy humans: Detection of theH30 subclone of B2-ST131Escherichia coliproducing CTX-M-27. J. Antimicrob. Chemother. 2016, 71, 1120–1122. [Google Scholar] [CrossRef] [Green Version]
Table 1. Enterobacterales species identified as carbapenemase producers.
Table 1. Enterobacterales species identified as carbapenemase producers.
MicroorganismColonizationInfectionTotal
No.%No.%No.%
Klebsiella pneumoniae667732949882
Escherichia coli101113119
Enterobacter cloacaecomplex561365
Klebsiella oxytoca45--43
Citrobacter freundiicomplex11-- 1
Total8610034100120100
Table 2. Epidemiological data on clinical CPE isolates.
Table 2. Epidemiological data on clinical CPE isolates.
UnitPatient Nº (Sex/Age)Clone (MLST)SpeciesIsolation DateDiagnosis of Infectious Diseases ProductPrevious Antibiotherapy (3 months)Previous HospitalizationsDuration of HospitalizationPrevious Colonization a
Emergency2 (M/79)ST147K. pneumoniae19/11/17NUYY (this hospital, 2 months)7 days+ (2 months)
Emergency3 (M/87)ST147K. pneumoniae20/11/17YUYY (this hospital, 1 month)6 daysNot tested
Emergency10 (F/94)ST147K. pneumoniae07/12/17NUNY (this hospital, >3 months)13 days+ (7 months)
Emergency15 (F/79)ST392K. pneumoniae18/12/17YBYY (this hospital; 15 days)6 days+ (14 days)
Emergency19 (F/79)ST147K. pneumoniae29/12/17YUNY (this hospital; 1 month)13 days- (2 months)
Emergency30 (M/74)ST147K. pneumoniae12/02/18YUYN10 daysNot tested
30 (M/74)ST147K. pneumoniae13/02/18
Medical11 (F/96)ST307K. pneumoniae12/12/17NUYY (this hospital, 1 month)16 days+ (1 month)
Medical18 (F/66)ST15K. pneumoniae28/12/17NUYN45 days+ (12 days)
Medical20 (F/82)ST22K. pneumoniae09/01/18YUYN36 days- (6 days)
Medical22 (F/86)ST147K. pneumoniae12/01/18YUYN26 days+ (1 day)
Medical24 (M/85)ST147K. pneumoniae22/01/18YWYN28 days+ (2 months)
Medical31 (F/81)ST392K. pneumoniae12/02/18YUYN19 days+ (2 days)
Medical31 (F/75)ST392K. pneumoniae21/02/18NUYN6 daysNot tested
Medical6 (F/84)ST392K. pneumoniae29/11/17NUNY (this hospital, 1 month)29 days+ (1 month)
Medical25 (M/42)ST131E. coli25/01/18NWYY (another hospital)50 days+ (20 days)
Surgical4 (F/60)ST147K. pneumoniae21/11/17NWYN45 days+ (7 days)
Surgical5 (M/32)ST147K. pneumoniae28/11/17NWYY (this hospital, 2 months)22 days+ (3 months)
Surgical8 (F/91)ST359K. pneumoniae04/12/17NRYN16 days- (3 days)
Surgical9 (F/48)ST11K. pneumoniae05/12/17NUYN62 days+ (5 days)
Surgical12 (F/78)ST147K. pneumoniae12/12/17NWYY (another hospital)59 days+ (1 month)
Surgical13 (F/61)ST147K. pneumoniae15/12/17NUNN17 days+ (1 day)
Surgical14 (F/92)ST147K. pneumoniae16/12/17NWYN36 days+ (5 days)
Surgical16 (M/69)ST147K. pneumoniae19/12/17NBYN30 days+ (1 day)
Surgical17 (M/60)ST147K. pneumoniae26/12/17NUYN25 days+ (7 days)
Surgical21 (F/82)ST147K. pneumoniae11/01/18NUYN80 days+ (1 month)
Surgical23 (F/68)ST147K. pneumoniae12/01/18NRYN40 days+ (7 days)
Surgical26 (M/73)NDK. pneumoniae31/01/18NWYN30 days+ (5 days)
Surgical27 (F/82)ST147K. pneumoniae03/02/18NWYY (this hospital, 2 months)30 days+ (1 month)
Surgical28 (M/78)-E. cloacae complex07/02/18NWYY (another hospital)15 days+ (1 day)
Surgical29 (M/77)ST147K. pneumoniae08/02/18NUYN39 days+ (9 days)
Surgical32 (M/78)ST392K. pneumoniae12/02/18YUYN57 days+ (15 days)
Surgical1 (M/79)ST147K. pneumoniae04/11/17NUYY (another hospital)41 days+ (2 days)
UCI7 (M/61)NDK. pneumoniae03/12/17YUYY (this hospital, 2 months)8 days+ (2 months)
a Date of last colonization (when tested). ND = Not Done. N = No; Y = Yes; B = Blood; U = Urine; W = Wound; R = Respiratory.
Table 3. Performance of Fourier Transform infrared (FT-IR) typing and epidemiological data of carbapenemase-producing K. pneumoniae isolates from the studied hospital.
Table 3. Performance of Fourier Transform infrared (FT-IR) typing and epidemiological data of carbapenemase-producing K. pneumoniae isolates from the studied hospital.
n (%)wzi AlelleK-Type by wzi SequencingK-Type by FT-IR aMLSTSource bHospital Ward
54 (55)wzi64K14/K64KL64ST147S (n = 34)
C (n = 20)
MU (n = 25)
SU (n = 23)
ER (n = 6)
20 (20.4)wzi187KL27FT1, 1 NTST392S (n = 15)
C (n = 5)
MU (n = 15)
SU (n=3)
ER (n = 2)
5 (5.1)wzi9K9FT2ST22S (n = 4)
C (n = 1)
MU (n = 4)
SU (n = 1)
4 (4.1)wzi173KL102FT3ST307S (n = 3)
C (n = 1)
MU (n = 3)
SU (n = 1)
3 (3.1)wzi19K191 K19, KL107 *, 1 NTST15S (n = 3)SU (n = 3)
2 (3.1)wzi93K60/KL112KL112ST15S (n = 1)
C (n = 1)
MU (n = 1)
SU (n = 1)
2 (2)wzi53K53FT4NDS (n = 1)
C (n = 1)
SU (n = 2)
2 (2)wzi50KL15/KL17/KL51/KL52FT5NDS (n = 1)
C (n = 1)
MU (n = 1)
ICU (n = 1)
2 (2)wzi461NANTNDS (n = 2)SU (n = 2)
2 (2) wzi236KL10NTST359C (n = 1)
S (n=1)
SU (n = 2)
1 (1)wzi75KL105NTST11C (n = 1)SU (n = 1)
1 (1)wzi102K31KL62 *NDS (n = 1)SU (n = 1)
a FT-IR types not recognized by the model were attributed arbitrary designations (FT1-FT5). b S = Rectal Screening; C = Clinical isolate; NT = Not Typeable; NA = Not attributable; ND = Not Done; * Incorrect prediction. MU = Medical Units; SU = Surgical Units; ER = Emergency Room; ICU = Intensive Care Unit.
Table 4. Characterization of CPE producers other than K. pneumoniae.
Table 4. Characterization of CPE producers other than K. pneumoniae.
SpeciesE. coli Phylogenetic Group (Nº)Carbapenemase (Nº)Source (Nº)Hospital Ward
E. coliB2 (5) aKPC-3 (3)
OXA-48 (1)
S (4)
C (1)
n = 2 SU
n = 3 MU
A (2)KPC-3 (2)S (2)n = 2 MU
E (2)KPC-3 (2)S (2)n = 1 MU
n = 1 SU
B1 (1)KPC-3 (1)S (1)n = 1 MU
F (1)KPC-3 (1)S (1)n = 1 MU
K. oxytocaNA (4)KPC-3 (4)S (4)n = 3 SU
n = 1 MU
E. cloacae complexNA (6)KPC-3 (5)
VIM-1 (1)
S (4), C (1)
S
n = 5 SU
n = 1 MU
C. freundii complexNA (1)KPC-3 (1)Sn = 1 SU
a B2 E. coli producing KPC-3 belongs to ST131; S = Rectal Screening; C = Clinical Isolate; MU = Medical Units; SU = Surgical units; NA = Not applicable.
Publisher’s Note: MDPI stays neutral with regard to jurisdictional claims in published maps and institutional affiliations.

Share and Cite

MDPI and ACS Style

Guerra, A.M.; Lira, A.; Lameirão, A.; Selaru, A.; Abreu, G.; Lopes, P.; Mota, M.; Novais, Â.; Peixe, L. Multiplicity of Carbapenemase-Producers Three Years after a KPC-3-Producing K. pneumoniae ST147-K64 Hospital Outbreak. Antibiotics 2020, 9, 806. https://0-doi-org.brum.beds.ac.uk/10.3390/antibiotics9110806

AMA Style

Guerra AM, Lira A, Lameirão A, Selaru A, Abreu G, Lopes P, Mota M, Novais Â, Peixe L. Multiplicity of Carbapenemase-Producers Three Years after a KPC-3-Producing K. pneumoniae ST147-K64 Hospital Outbreak. Antibiotics. 2020; 9(11):806. https://0-doi-org.brum.beds.ac.uk/10.3390/antibiotics9110806

Chicago/Turabian Style

Guerra, Ana Margarida, Agostinho Lira, Angelina Lameirão, Aurélia Selaru, Gabriela Abreu, Paulo Lopes, Margarida Mota, Ângela Novais, and Luísa Peixe. 2020. "Multiplicity of Carbapenemase-Producers Three Years after a KPC-3-Producing K. pneumoniae ST147-K64 Hospital Outbreak" Antibiotics 9, no. 11: 806. https://0-doi-org.brum.beds.ac.uk/10.3390/antibiotics9110806

Note that from the first issue of 2016, this journal uses article numbers instead of page numbers. See further details here.

Article Metrics

Back to TopTop