Hostname: page-component-78c5997874-lj6df Total loading time: 0 Render date: 2024-11-14T03:24:54.116Z Has data issue: false hasContentIssue false

Real-time genomic investigation underlying the public health response to a Shiga toxin-producing Escherichia coli O26:H11 outbreak in a nursery

Published online by Cambridge University Press:  19 September 2017

J. MORAN-GILAD*
Affiliation:
Faculty of Health Sciences, Ben-Gurion University of the Negev, Beer-Sheva, Israel Public Health Services, Ministry of Health, Jerusalem, Israel Southern District Health Office, Ministry of Health, Beer-Sheva, Israel European Society for Clinical Microbiology and Infectious Diseases (ESCMID) Study Group for Genomic and Molecular Diagnostics (ESGMD), Basel, Switzerland
A. ROKNEY
Affiliation:
Central Laboratories, Public Health Services, Ministry of Health, Jerusalem, Israel
D. DANINO
Affiliation:
Faculty of Health Sciences, Ben-Gurion University of the Negev, Beer-Sheva, Israel Soroka University Medical Center, Beer-Sheva, Israel
M. FERDOUS
Affiliation:
Department of Medical Microbiology, University of Groningen, University Medical Centre Groningen, Groningen, The Netherlands
F. ALSANA
Affiliation:
Southern District Health Office, Ministry of Health, Beer-Sheva, Israel
M. BAUM
Affiliation:
Central Laboratories, Public Health Services, Ministry of Health, Jerusalem, Israel
L. DUKHAN
Affiliation:
Southern District Health Office, Ministry of Health, Beer-Sheva, Israel
V. AGMON
Affiliation:
Central Laboratories, Public Health Services, Ministry of Health, Jerusalem, Israel
E. ANUKA
Affiliation:
Central Laboratories, Public Health Services, Ministry of Health, Jerusalem, Israel
L. VALINSKY
Affiliation:
Central Laboratories, Public Health Services, Ministry of Health, Jerusalem, Israel
R. YISHAY
Affiliation:
Department of Laboratories, Public Health Services, Ministry of Health, Jerusalem, Israel
I. GROTTO
Affiliation:
Faculty of Health Sciences, Ben-Gurion University of the Negev, Beer-Sheva, Israel Public Health Services, Ministry of Health, Jerusalem, Israel
J. W. A. ROSSEN
Affiliation:
European Society for Clinical Microbiology and Infectious Diseases (ESCMID) Study Group for Genomic and Molecular Diagnostics (ESGMD), Basel, Switzerland Department of Medical Microbiology, University of Groningen, University Medical Centre Groningen, Groningen, The Netherlands
M. GDALEVICH
Affiliation:
Faculty of Health Sciences, Ben-Gurion University of the Negev, Beer-Sheva, Israel Southern District Health Office, Ministry of Health, Beer-Sheva, Israel
*
*Author for correspondence: J. Moran-Gilad, M.D., M.P.H., Faculty of Health Sciences, Ben-Gurion University of the Negev, POB 653, Beer-Sheva 8410501, Israel. (Email: [email protected])
Rights & Permissions [Opens in a new window]

Summary

Shiga toxin-producing Escherichia coli (STEC) is a significant cause of gastrointestinal infection and the haemolytic-uremic syndrome (HUS). STEC outbreaks are commonly associated with food but animal contact is increasingly being implicated in its transmission. We report an outbreak of STEC affecting young infants at a nursery in a rural community (three HUS cases, one definite case, one probable case, three possible cases and five carriers, based on the combination of clinical, epidemiological and laboratory data) identified using culture-based and molecular techniques. The investigation identified repeated animal contact (animal farming and petting) as a likely source of STEC introduction followed by horizontal transmission. Whole genome sequencing (WGS) was used for real-time investigation of the incident and revealed a unique strain of STEC O26:H11 carrying stx2a and intimin. Following a public health intervention, no additional cases have occurred. This is the first STEC outbreak reported from Israel. WGS proved as a useful tool for rapid laboratory characterization and typing of the outbreak strain and informed the public health response at an early stage of this unusual outbreak.

Type
Original Papers
Copyright
Copyright © Cambridge University Press 2017 

INTRODUCTION

Shiga toxin-producing Escherichia coli (STEC) is a significant cause of gastrointestinal infection, ranging from mild diarrhoea to severe bloody diarrhoea. Of STEC infections (O157:H7), 5–10% develop the haemolytic-uremic syndrome (HUS), which is a leading cause of paediatric renal failure [Reference Heiman1]. Progression to HUS occurs most commonly in younger children [Reference Karmali2]. Human STEC infection is commonly associated with exposure to contaminated food but the role of contact with infected animal excretions is increasingly being recognized [Reference Locking3].

STEC strains carry the stx1 and/or stx2 genes that encode for the respective Shiga toxin genes. There are three variants for stx1 and seven variants for stx2 [Reference Scheutz4], which contribute to the varying severity of STEC infection, together with other virulence determinants such as the eae gene encoding the intimin protein of the locus of enterocyte effacement [Reference Elliott5]. Culture-based screening for STEC using media such as SMAC or chromogenic agars is much less sensitive for non-O157 STECs, and therefore molecular detection assays for stx1 and stx2 in faecal samples have been widely implemented [Reference Parsons6].

STEC infections should prompt an epidemiological investigation aimed at identifying and controlling the source of infection. Recently, whole genome sequencing (WGS) has been shown to be very useful for the typing of STEC [Reference Franz7] with increased discriminatory power as compared with standard techniques such as pulsed-field gel electrophoresis (PFGE) and multi-locus variable number tandem repeats analysis [Reference Chattaway8]. Moreover, WGS also has the potential for replacing several frontline and reference microbiology assays as a ‘one-stop-shop’ for rapid pathogen characterization.

On 25–27 April 2016, admission to the regional hospital of two young infants with HUS (index cases) residing in the same rural community (Kibbutz) in Southern Israel and attending the same nursery at the local day-care centre, prompted an immediate epidemiological investigation by the Southern District Health Office. The aim of this paper is to describe the epidemiological and genomic investigation performed in real time during an unusual STEC outbreak, which is also the first being reported from Israel.

METHODS

Epidemiological investigation

Questioning, aiming at identifying plausible risk factors, involved parents of the two HUS cases as well as parents of other infants attending the nursery and the caregivers. Case finding in the community was carried out by alerting parents and staff members at the community as well as health personnel at local and regional primary care clinics and also the regional hospital. Possible risk factors and exposures were assessed using standard questionnaires, addressing close contacts, travel, food and water consumption and animal contact.

A case definition was subsequently constructed and classified into four groups: (1) a confirmed case was defined as any individual living in the community with a compatible gastrointestinal illness and/or HUS and laboratory evidence for STEC infection (PCR and/or culture) over the last month; (2) a probable case was defined as any individual with current or recent (up to 1 month) compatible and evident gastrointestinal illness but no laboratory evidence for STEC infection; (3) a possible case was defined as any individual with a reported history of gastrointestinal illness in the recent month; (4) laboratory-confirmed excretion of STEC in the absence of any reported illness was defined as carriage.

Laboratory investigation

Fresh stool samples obtained from patients and contacts (nursery, adjacent day-care centres and close contacts) were transported within 24 h to the Central Laboratories of the Ministry of Health (national reference laboratory for STEC) for a total of 120 samples. Samples were tested for the presence of STEC by means of standard culture on selective and non-selective agar plates (Sorbitol MacConkey, CHROMagar STEC, CHROMagar Orientation (CHROMagar Company, Paris, France)), colony picking and molecular screening of up to 15 suspected colonies using PCR for stx1 and stx2 and intimin (eae) [Reference Fagan9Reference Olsvik, Persing, Smith, Tenover and White12]. PFGE was performed per the PulseNet protocol using XbaI. In parallel, direct molecular testing of stool was performed using the same PCR assay following DNA extraction using the easyMAG platform (bioMerieux, France) and with the addition of an internal inhibition control (gfp). Faecal samples obtained from hospitalized patients linked to the outbreak and suspected to be positive for STEC were referred for confirmatory testing at the national laboratory.

Environmental testing was performed on freshly voided animal faeces obtained from potential sources using the same approach, for a total of 111 samples. Sampling of the petting zoo involved freshly voided animal faeces and covered the entire area of the zoo premises as well as the different animal species present in the zoo. Sampling of cowsheds involved collection of fresh cow manure from all farms and cowsheds in the local area, including but not restricted to those identified through questionnaires. Water sampling was performed by obtaining drinking water from the main water line and testing for the presence of coliforms using standard water quality methods.

WGS analysis

Starting in the second week of the outbreak (10 May 2016), all STEC isolates were analysed by rapid WGS. DNA extraction was carried out with a manual kit (Geneaid, Taiwan). DNA libraries were prepared at the University Medical Centre Groningen, The Netherlands, using Nextera XT according to manufacturer's protocols (Illumina, San Diego, California, USA) and then run on a Miseq (Illumina) for generating paired-end 250-bp reads aiming at a coverage of at least 50-fold. Data analysis was performed as previously described [Reference Ferdous13]. Raw reads were quality checked and trimmed, followed by de novo assembly using CLC Genomic Workbench v. 9.5.2 (CLC bio, Denmark) and gene annotation using RAST v.2. O and H serogrouping, determination of eae and stx variants and additional virulence genes, and calling of in silico multi-locus sequence type (MLST) [Reference Wirth14] was performed using online tools (SerotypeFinder 1.1, VirulenceFinder 1.5 and MLST Finder 1.8) at the Center for Genomic Epidemiology server (http://www.genomicepidemiology.org/). For the CGE server, the threshold of ID was set to 85% and the percentage of minimum overlapping gene length to 60%.

Fifteen genomes were included in the phylogenetic analysis, consisting of 11 isolates sequenced in this study and four additional STEC O26:H11 genomes downloaded from NCBI which represent different geographical regions, isolation dates, genotype and pathotype (Table 1). Phylogenetic analysis performed using the gene-by-gene approach was carried out in SeqSphere+ v3.0 (Ridom GmbH, Münster, Germany). For this, an ad hoc core genome MLST (cgMLST) scheme was used as described previously [Reference Ferdous13]. Briefly, the genome of E. coli O26:H11 strain (NC_013361·1) was taken as a reference genome and 12 additional E. coli genomes were used as query genomes to extract open reading frames (ORFs) using the MLST+ Target Definer 2.1.0 of SeqSphere+. The list of genomes appears in a Supplementary File. Only the ORFs without premature stop codon and ambiguous nucleotides from contigs of assembled genomes were included. The genes shared by the genomes of all isolates analysed in this study, as listed in Table 1 and shown in Figure 2, were defined as the core genome for phylogenetic analysis. According to the sequence identity of the genes, a numerical allele type was assigned by SeqSphere and the allelic profiles generated by the combination of all alleles in each genome were considered for constructing the minimum-spanning tree and measure allelic differences between the isolates. Genomic sequences have been deposited (accession numbers appear in Table 1).

Table 1. Escherichia coli isolates analysed by whole genome sequencing in this study

HUS, haemolytic-uremic syndrome; ST, sequence type; cgMLST, core genome multi-locus sequence typing; NA, not applicable.

An additional analysis of single nucleotide polymorphisms (SNPs) was performed for the six isolates belonging to the outbreak strain and using the O26:H11 NC_013361 reference genome. The analysis was carried out by CSI Phylogeny with the following settings: a minimum depth of 10 at SNP positions, a minimum relative depth of 10% at SNP positions, a minimum distance of 10 bp between SNPs (prune), a minimum quality of 30, a minimum SNP quality of 25 and a minimum Z-score of 1·96. The percentage of the reference genome covered by all isolates was 88·2% (5 022 775 bp).

RESULTS

Investigation of the outbreak setting identified 14 young infants at age range of 6–18 months, which were regularly attending the nursery. In total, there were four definite cases (three of whom had HUS), one probable case, two possible cases and five carriers (three in the nursery and two in adjacent classes). Faecal samples obtained from the two index HUS cases were PCR-positive for stx2, one of whom was also culture-positive (the other patient had received empirical antibiotics). Out of the 14 infants, two had a recent history of gastroenteritis which resolved 1–2 weeks earlier and were thus classified as possible cases. An additional three infants had symptomatic gastroenteritis and were subsequently admitted to the hospital for further diagnosis and treatment. Two symptomatic infants were STEC stx2-positive, one of whom later developed HUS during the hospital course and the third was a probable case. A sixth infant had a very brief gastrointestinal episode reported but was STEC-negative (possible case). The timeline of the outbreak is depicted in Figure 1 and the clinical features of hospitalized cases are summarized in Table 2. Notably, all three HUS cases resolved with supportive therapy without sequelae.

Fig. 1. Description of the outbreak. The illustration includes 14 infants attending the affected nursery and additional two children attending other day-care centres found to be carriers, including three cases of haemolytic-uremic syndrome, one definite, one probable and three possible cases with symptomatic diarrhoea, five carriers (one of whom was a sibling – carrier-S) and three negative individuals. Gastrointestinal symptoms (yellow), hospital stay (amber) and faecal excretion of the outbreak strain (purple) are shown over time. Red and white circles correspond with first positive and first negative stool samples, respectively.

Fig. 2. Phylogenetic analysis using a gene-by-gene approach. A minimum spanning tree of 15 STEC isolates subject to WGS, generated using an ad hoc core genome of 2962 genes. The analysis included clinical and environmental isolates (green) recovered during the outbreak, an isolate from a historic HUS case in the region (blue, #440) and international O26:H11 reference strains (pink). All O26 isolates belonging to the outbreak strain are tightly clustered together (red). Isolates found during environmental sampling and comprising three bovine isolates are indicated in green.

Table 2. Characteristics of symptomatic infants hospitalized during the outbreak

HUS, haemolytic-uremic syndrome; ICU, intensive care unit; LOS, length of hospital stay; AH, anti-hypertensive therapy; FFP, fresh frozen plasma; PC, packed cells; IV, intravenous fluids; D, diuretics.

The public health response to the STEC outbreak was mounted within 2 days following the reporting of HUS cases to local health authorities over the weekend. It included immediate closure of all local day-care centres, active case finding and microbiological surveillance. Upon questioning, possible risk factors included extensive contact with various animals at a local petting zoo, inhabited by different animal species, and frequent contact with animal husbandry, particularly calves and young cattle in dairy farms (several hundred heads of cattle) situated in proximity with residential premises. This appeared to have occurred directly through farm visits that took place at least once per week and in which all nursery infants participated. Visits involved direct animal contact at cowsheds. Family members of some infants were also working in the local animal farms. No suspected foodborne exposure was evident, especially since infant nutrition largely involved baby formula. Tests of drinking water revealed no faecal contamination.

Stool samples obtained from the six asymptomatic infants in the nursery revealed three STEC-positive infants (carriers). Eight women working as caregivers in the nursery were asymptomatic and tested negative, as were 10 sampled adults, including four with inconsistent gastrointestinal symptoms and six relatives of the nursery infants. Microbiological surveillance also included 39 children aged 2–5 years attending the adjacent day-care centres, of whom two were STEC-positive. One of those was a sibling of a carrier from the nursery. Of 25 representative samples obtained from the petting zoo, covering most of its area and resident animals, one sample (related to a calf) was STEC-positive. Of 86 samples obtained from three local cowsheds, two samples obtained from two different farm locations were STEC-positive.

An educational intervention was performed, starting 1 May 2016, focusing on proper personal and hand hygiene, elimination of direct animal contact through temporary prohibition of farm and zoo visits and reiteration of hygiene practices among the farm workers. After thorough cleansing, the day-care system was re-opened. STEC-positive children were followed up clinically and microbiologically at least twice weekly and were excluded from the nursery until two consecutive stool samples taken at least 48 h apart were PCR-negative for STEC. The duration of asymptomatic STEC shedding in those individuals ranged between 2 and 6 weeks (Fig. 1).

A total of 11 non-duplicate isolates were subject to rapid NGS and are summarized in Table 1. The mean coverage, N50 value and number of contigs were 76 (49–126), 92 297 (range 52 061–126 505) and 213 (range 128–249), respectively. WGS revealed the outbreak strain was an O26:11 STEC strain, harbouring the stx2a toxin variant encoding gene and the intimin gene (eae). A list of additional virulence genes appears in the Supplementary Table S1. MLST performed in silico revealed that the outbreak strain was a new sequence type (allelic profile: X, 4, 12 ,16, 9, 7, 7), being a single-locus variant of the ST21 international clone. The combination of O26/stx2a/ST21-like has not been previously reported.

Analysis of isolates by cgMLST is presented in Figure 2. All isolates belonging to the outbreak strain (all stool isolates from symptomatic and asymptomatic individuals) tightly clustered together, showing up to one allele difference. These isolates also belonged to the same pulsotype per PFGE. A historical isolate from a case of HUS reported a year before the outbreak from an adjacent village was found to be unrelated (an O71:H8, ST6). The three bovine isolates recovered through environmental sampling were also unrelated to the outbreak strain (O17:H21/ST677; O171:H29/ST515 and O177:H25/ST659). Interestingly, the STEC recovered from one of two carriers found among older children was an O157:H7, ST11 strain. During 6 months of follow-up, no additional STEC cases were reported in the area.

Apart from the gene-by-gene approach, a SNP analysis on the core genome of the six outbreak isolates was performed. Within the shared genome (5 022 775 nt), 7–35 SNPs were found between the outbreak isolates, indicating that they were almost identical given the extremely dynamic nature of STEC.

DISCUSSION

We report an investigation of an outbreak of STEC in a nursery at a rural community, involving a high attack rate of HUS among symptomatic individuals. HUS related to STEC infection is very uncommon in Israel with only a handful of cases reported annually [15]. Notably, this is the first outbreak of STEC documented in Israel. An epidemiological investigation implicated contact with animal husbandry as a likely source of introduction of STEC into the nursery and outbreak initiation and the dynamics of the outbreak suggest an important role for secondary person-to-person transmission in propagation of the outbreak.

STEC O26:H11 is one of the ‘big six’ STEC serotypes and the most common non-O157 STEC causing infection in Europe [Reference Germinario16]. It is a highly diverse group containing inter-mixed clusters of isolates from human and animal origin [Reference Norman17]. Over recent decades, a shift between stx1-positive and stx2-positive STEC O26 strains has been noted, with stx2-positive STEC O26 being considered highly virulent [Reference Bielaszewska18] and showing a predilection for causing diarrhoea and HUS, especially in young children [Reference Germinario16, Reference Allerberger19]. Moreover, strains harbouring the stx2a variant in combination with intimin are more likely associated with HUS [Reference Boerlin20].

STEC outbreaks involving nurseries or child day-care centres have been reported with varying rates of HUS. There are several reports of STEC O26:H11 infection in day-care centres, including the USA, UK, Germany and Japan [Reference Brown21Reference Dallman24]. Clusters of paediatric STEC occurring in day-care settings emphasize the role of secondary transmission in those centres as well as within families [Reference Hoffmann10, Reference Kanayama25, Reference Al-Jader26]. Such STEC outbreaks have been reported to involve prolonged shedding of STEC among clinical cases [Reference Shah27] but less is known about the duration of shedding in asymptomatic carriers. In the outbreak reported herein, shedding among asymptomatic carriers lasted 3–5 weeks and exclusion of excreting carriers from the nursery was associated with significant parental distress, as reflected through communications to the District health office directly by parents and indirectly by staff of local authorities, but was probably instrumental in curbing the outbreak and preventing further infections.

WGS is increasingly being used as a highly discriminative tool for investigating STEC outbreaks [Reference Rowell28], mainly as a retrospective tool either corroborating standard typing techniques or offering improved typing resolution [Reference Dallman24, Reference Holmes29, Reference Underwood30]. WGS utilized via rapid protocols may be performed in comparable or even faster turnaround times such as standard techniques (e.g. PFGE or MLST) but is advantageous, not only due to its improved resolution but also as it allows to extract additional important information from the genomes. This may prove helpful for both clinical and reference settings. The current investigation utilized rapid WGS performed in real time at a very early stage of the outbreak in a non-reference microbiology setting. The use of WGS generated timely information including calling of the serotype and ST in silico, typing of the stx toxin, assessment of over 20 virulence genes as well as phylogenetic analysis for genomic epidemiology using cgMLST and SNP methods. Such information is usually produced at later stages of outbreak investigation, only at reference laboratory level and requires multiple laborious tests to be performed over a longer timeframe. In the current outbreak, rapidly refuting the association between the nursery cases and a case that have occurred in that area a year before was important for risk communication purposes and obviated the need for performing additional surveillance at the adjacent village. While other methods (e.g. PFGE) may be used to rule out epidemiological links, performing WGS is advantageous as in cases of identical PFGE, it provides an immediate higher resolution that could inform public health measures.

Contact with farm animals, such as calves and lambs, has repeatedly been implicated in STEC outbreaks [Reference Rowell28, Reference Underwood30, Reference Crump31]. STEC outbreaks involving direct animal contact have also been reported to be associated with increased rates of HUS [Reference Heiman1] but the persistence of STEC strains, particularly O26 in cow manure and slurries [Reference Fremaux32] may contribute to transmission. Using WGS we were able to demonstrate co-circulation of several unrelated clones of STEC in that rural community, suggesting multiple transmission opportunities repeatedly occurred in this ecological niche. This is in agreement with previous reports of multi-source STEC infections [Reference Luna-Gierke33]. The occurrence of an HUS case in a similar adjacent community a year earlier suggests circulation of STEC in that setting is not new. That one particular virulent clone may become successful in establishing ongoing transmission and illness has been demonstrated in similar settings [Reference Underwood30]. This phenomenon may be related to virulence and pathogenicity features yet to be discovered, the inoculum, number of introduction/transmission opportunities, the susceptibility to infection of patient groups such as young infants and/or nursery hygiene practices (contributing to secondary transmission). In our case, the very close proximity between premises and farm animals, continuous movement of vehicles and people to and from the farms and inadequate environmental control measures were possible contributing factors to the outbreak.

WGS is transforming public health microbiology with its unprecedented capability for epidemiological typing and has been successfully used for investigating the genomic epidemiology of STEC. Nevertheless, WGS remains to be validated and standardized before it could be globally implemented for routine use in public health [Reference Moran-Gilad34]. Several pioneering examples already exist for using WGS routinely for surveillance and these should pave the way for integration of WGS even in frontline settings. The use of WGS to characterize STEC outbreak strains, by combining rapid epi- and patho-typing, has a great potential for shortening laboratory turnaround and decision-making times in outbreak settings and favours its application in real time during investigations.

SUPPLEMENTARY MATERIAL

The supplementary material for this article can be found at https://doi.org/10.1017/S0950268817001923.

ACKNOWLEDGEMENTS

The authors thank all staff members of the Ministry of Health Central Laboratories, South District Health Office and Soroka University Medical Centre for supporting the investigation and incident management and Sigrid Rosema (UMCG) for preparing the cgMLST scheme.

DECLARATION OF INTEREST

None.

References

REFERENCES

1. Heiman, KE, et al. Escherichia coli O157 outbreaks in the United States, 2003–2012. Emerging Infectious Diseases 2015; 21: 12931301.Google Scholar
2. Karmali, MA. Host and pathogen determinants of verocytotoxin-producing Escherichia coli-associated hemolytic uremic syndrome. Kidney International 2009; 112: S4S7.Google Scholar
3. Locking, ME, et al. Risk factors for sporadic cases of Escherichia coli O157 infection: the importance of contact with animal excreta. Epidemiology and Infection 2001; 127: 215220.Google Scholar
4. Scheutz, F, et al. Multicenter evaluation of a sequence-based protocol for subtyping Shiga toxins and standardizing Stx nomenclature. Journal of Clinical Microbiology 2012; 50: 29512963.Google Scholar
5. Elliott, SJ, et al. The locus of enterocyte effacement (LEE)-encoded regulator controls expression of both LEE and non-LEE-encoded virulence factors in enteropathogenic and enterohemorrhagic Escherichia coli . Infection and Immunity 2000; 68: 61156126.Google Scholar
6. Parsons, BD, et al. Detection, characterization, and typing of Shiga toxin-producing Escherichia coli . Frontiers in Microbiology 2016; 7: 478.Google Scholar
7. Franz, E, et al. Exploiting the explosion of information associated with whole genome sequencing to tackle Shiga toxin-producing Escherichia coli (STEC) in global food production systems. International Journal of Food Microbiology 2014; 187: 5772.Google Scholar
8. Chattaway, MA, et al. Whole genome sequencing for public health surveillance of ShigaToxin-producing Escherichia coli otherthanserogroupO157. Frontiers in Microbiology 2016; 3: 258.Google Scholar
9. Fagan, PK, et al. Detection of Shiga-like toxin (stx1 and stx2), intimin (eaeA), and enterohemorrhagic Escherichia coli (EHEC) hemolysin (EHEC hlyA) genes in animal feces by multiplex PCR. Applied and Environmental Microbiology 1999; 65: 868872.Google Scholar
10. Hoffmann, B, et al. A universal heterologous internal control system for duplex real-time RT-PCR assays used in a detection system for pestiviruses. Journal of Virological Methods 2006; 136: 200209.Google Scholar
11. Nguyen, TV, et al. Detection and characterization of diarrheagenic Escherichia coli from young children in Hanoi, Vietnam. Journal of Clinical Microbiology 2005; 43: 755760.Google Scholar
12. Olsvik, O. PCR detection of heat-stable, heatlabile, and Shiga-like toxin genes in Escherichia coli . In: Persing, DH, Smith, TF, Tenover, FC, White, TJ, eds. Diagnostic Molecular Microbiology. Principles and Application. Rochester: Mayo Foundation, 1993, pp. 271276.Google Scholar
13. Ferdous, M, et al. Molecular characterization and phylogeny of Shiga toxin-producing E. coli (STEC) isolates obtained from two Dutch regions using whole genome sequencing. Clinical Microbiology and Infection 2016; 22: 642. e1–e9.Google Scholar
14. Wirth, T, et al. Sex and virulence in Escherichia coli: an evolutionary perspective. Molecular Microbiology 2016; 60: 11361151.CrossRefGoogle Scholar
15. Israeli Ministry of Health. Notifiable Infectious Diseases in Israel: 60 years of surveillance 1951–2010. Ministry of Health, 2012 (https://www.health.gov.il/PublicationsFiles/Disease1951_2010.pdf).Google Scholar
16. Germinario, C, et al. Community-wide outbreak of haemolytic uraemic syndrome associated with Shiga toxin 2-producing Escherichia coli O26:H11 in southern Italy, summer 2013. Eurosurveillance 2016; 21: pii=30343.Google Scholar
17. Norman, KN, et al. Comparison of whole genome sequences from human and non-human Escherichia coli O26 strains. Frontiers in Cellular Infection and Microbiology 2015; 5: 21.Google Scholar
18. Bielaszewska, M, et al. Enterohemorrhagic Escherichia coli O26:H11/H-: a new virulent clone emerges in Europe. Clinical Infectious Diseases 2013; 56: 13731381.Google Scholar
19. Allerberger, F, et al. Hemolytic-uremic syndrome associated with enterohemorrhagic Escherichia coli O26:H infection and consumption of unpasteurized cow's milk. International Journal of Infectious Diseases 2003; 7: 4245.CrossRefGoogle ScholarPubMed
20. Boerlin, P, et al. Associations between virulence factors of Shiga toxin-producing Escherichia coli and disease in humans. Journal of Clinical Microbiology 1999; 37: 497503.Google Scholar
21. Brown, JA, et al. Outbreak of Shiga toxin-producing Escherichia coli serotype O26: H11 infection at a child care center in Colorado. Pediatric Infectious Diseases Journal 2012; 31: 379383.Google Scholar
22. Sonoda, C, et al. An enterohemorrhagic Escherichia coli O26 outbreak at a nursery school in Miyazaki, Japan. Japanese Journal of Infectious Diseases 2008; 61: 9293.Google Scholar
23. Werber, D, et al. A multistate outbreak of Shiga toxin producing Escherichia coli O26:H11 infections in Germany, detected by molecular subtyping surveillance. Journal of Infectious Diseases 2002; 186: 419422.Google Scholar
24. Dallman, T, et al. The utility and public health implications of PCR and whole outbreak of Shiga toxin-producing Escherichia coli serogroup O26:H11. Epidemiology and Infection 2015; 143: 16721680.Google Scholar
25. Kanayama, A, et al. Enterohemorrhagic Escherichia coli outbreaks related to childcare facilities in Japan, 2010–2013. BMC Infectious Diseases 2015; 15: 539.Google Scholar
26. Al-Jader, L, et al. Outbreak of Escherichia coli O157 in a nursery: lessons for prevention. Archives of Diseases of Childhood 1999; 81: 6063.Google Scholar
27. Shah, S, et al. Prolonged fecal shedding of Escherichia coli O157:H7 during an outbreak at a day care center. Clinical Infectious Diseases 1996; 23: 835836.Google Scholar
28. Rowell, S, et al. An outbreak of Shiga toxin-producing Escherichia coli serogroup O157 linked to a lamb-feeding event. Epidemiology and Infection 2016; 144: 24942500.Google Scholar
29. Holmes, A, et al. Utility of whole-genome sequencing of Escherichia coli O157 for outbreak detection and epidemiological surveillance. Journal of Clinical Microbiology 2015; 53: 35653573.Google Scholar
30. Underwood, AP, et al. Public health value of next-generation DNA sequencing of enterohemorrhagic Escherichia coli isolates from an outbreak. Journal of Clinical Microbiology 2013; 51: 232237.Google Scholar
31. Crump, JA, et al. An outbreak of Escherichia coli O157:H7 infections among visitors to a dairy farm. New England Journal of Medicine 2002; 347: 555560.Google Scholar
32. Fremaux, B, et al. Persistence of Shiga toxin-producing Escherichia coli O26 in cow slurry. Letters of Applied Microbiology 2007; 45: 5561.Google Scholar
33. Luna-Gierke, RE, et al. Multiple-aetiology enteric infections involving non-O157 Shiga toxin-producing Escherichia coli – FoodNet, 2001–2010. Zoonoses and Public Health 2014; 61: 492498.Google Scholar
34. Moran-Gilad, J. Whole genome sequencing (WGS) for food-borne pathogen surveillance and control – taking the pulse. Eurosurveillance 2017; 22: pii=30547.Google Scholar
Figure 0

Table 1. Escherichia coli isolates analysed by whole genome sequencing in this study

Figure 1

Fig. 1. Description of the outbreak. The illustration includes 14 infants attending the affected nursery and additional two children attending other day-care centres found to be carriers, including three cases of haemolytic-uremic syndrome, one definite, one probable and three possible cases with symptomatic diarrhoea, five carriers (one of whom was a sibling – carrier-S) and three negative individuals. Gastrointestinal symptoms (yellow), hospital stay (amber) and faecal excretion of the outbreak strain (purple) are shown over time. Red and white circles correspond with first positive and first negative stool samples, respectively.

Figure 2

Fig. 2. Phylogenetic analysis using a gene-by-gene approach. A minimum spanning tree of 15 STEC isolates subject to WGS, generated using an ad hoc core genome of 2962 genes. The analysis included clinical and environmental isolates (green) recovered during the outbreak, an isolate from a historic HUS case in the region (blue, #440) and international O26:H11 reference strains (pink). All O26 isolates belonging to the outbreak strain are tightly clustered together (red). Isolates found during environmental sampling and comprising three bovine isolates are indicated in green.

Figure 3

Table 2. Characteristics of symptomatic infants hospitalized during the outbreak

Supplementary material: Image

Moran-Gilad et al. supplementary material

Moran-Gilad et al. supplementary material 1

Download Moran-Gilad et al. supplementary material(Image)
Image 314.8 KB
Supplementary material: File

Moran-Gilad et al. supplementary material

Moran-Gilad et al. supplementary material 2

Download Moran-Gilad et al. supplementary material(File)
File 12.1 KB